Utilizing a Sleep Mask to Reduce Patient Anxiety During Nail Surgery

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Article
Changed
Mon, 07/19/2021 - 09:49
Author(s)
Jose W. Ricardo, MD
Shari R. Lipner, MD, PhD

 

 

Practice Gap

Perioperative anxiety is common in patients undergoing nail surgery. Patients might worry about seeing blood; about the procedure itself, including nail avulsion; and about associated pain and disfigurement. Nail surgery causes a high level of anxiety that correlates positively with postoperative pain1 and overall patient dissatisfaction. Furthermore, surgery-related anxiety is a predictor of increased postoperative analgesic use2 and delayed recovery.3

Therefore, implementing strategies that reduce perioperative anxiety may help minimize postoperative pain. Squeezing a stress ball, hand-holding, virtual reality, and music are tools that have been studied to reduce anxiety in the context of Mohs micrographic surgery; these strategies have not been studied for nail surgery.

The Technique

Using a sleep mask is a practical solution to reduce patient anxiety during nail surgery. A minority of patients will choose to watch their surgical procedure; most become unnerved observing their nail surgery. Using a sleep mask diverts visual attention from the surgical field without physically interfering with the nail surgeon. Utilizing a sleep mask is cost-effective, with disposable sleep masks available online for less than $0.30 each. Patients can bring their own mask, or a mask can be offered prior to surgery.

If desired, patients are instructed to wear the sleep mask during the entirety of the procedure, starting from anesthetic infiltration until wound closure and dressing application. Any adjustments can be made with the patient’s free hand. The sleep mask can be offered to patients of all ages undergoing nail surgery under local anesthesia, except babies and young children, who require general anesthesia.

Practical Implications

Distraction is an important strategy to reduce anxiety and pain in patients undergoing surgical procedures. In an observational study of 3087 surgical patients, 36% reported that self-distraction was the most helpful strategy for coping with preoperative anxiety.4 In a randomized, open-label clinical trial of 72 patients undergoing peripheral venous catheterization, asking the patients simple questions during the procedure was more effective than local anesthesia in reducing the perception of pain.5

It is crucial to implement strategies to reduce anxiety in patients undergoing nail surgery. Using a sleep mask impedes direct visualization of the surgical field, thus distracting the patient’s sight and attention from the procedure. Furthermore, this technique is safe and cost-effective.

Controlled clinical trials are necessary to assess the efficacy of this method in reducing nail surgery–related anxiety in comparison to other techniques.

References
  1. Navarro-Gastón D, Munuera-Martínez PV. Prevalence of preoperative anxiety and its relationship with postoperative pain in foot nail surgery: a cross-sectional study. Int J Environ Res Public Health. 2020;17:4481. doi:10.3390/ijerph17124481
  2. Ip HYV, Abrishami A, Peng PWH, et al. Predictors of postoperative pain and analgesic consumption: a qualitative systematic review. Anesthesiology. 2009;111:657-677. doi:10.1097/ALN.0b013e3181aae87a
  3. Mavros MN, Athanasiou S, Gkegkes ID, et al. Do psychological variables affect early surgical recovery? PLoS One. 2011;6:E20306. doi:10.1371/journal.pone.0020306
  4. Aust H, Rüsch D, Schuster M, et al. Coping strategies in anxious surgical patients. BMC Health Serv Res. 2016;16:250. doi:10.1186/s12913-016-1492-5
  5. Balanyuk I, Ledonne G, Provenzano M, et al. Distraction technique for pain reduction in peripheral venous catheterization: randomized, controlled trial. Acta Biomed. 2018;89(suppl 4):55-63. doi:10.23750/abmv89i4-S.7115
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From the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Shari R. Lipner, MD, PhD
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From the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Author and Disclosure Information

From the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Article PDF
CT108001036.PDF
Article PDF
CT108001036.PDF

 

 

Practice Gap

Perioperative anxiety is common in patients undergoing nail surgery. Patients might worry about seeing blood; about the procedure itself, including nail avulsion; and about associated pain and disfigurement. Nail surgery causes a high level of anxiety that correlates positively with postoperative pain1 and overall patient dissatisfaction. Furthermore, surgery-related anxiety is a predictor of increased postoperative analgesic use2 and delayed recovery.3

Therefore, implementing strategies that reduce perioperative anxiety may help minimize postoperative pain. Squeezing a stress ball, hand-holding, virtual reality, and music are tools that have been studied to reduce anxiety in the context of Mohs micrographic surgery; these strategies have not been studied for nail surgery.

The Technique

Using a sleep mask is a practical solution to reduce patient anxiety during nail surgery. A minority of patients will choose to watch their surgical procedure; most become unnerved observing their nail surgery. Using a sleep mask diverts visual attention from the surgical field without physically interfering with the nail surgeon. Utilizing a sleep mask is cost-effective, with disposable sleep masks available online for less than $0.30 each. Patients can bring their own mask, or a mask can be offered prior to surgery.

If desired, patients are instructed to wear the sleep mask during the entirety of the procedure, starting from anesthetic infiltration until wound closure and dressing application. Any adjustments can be made with the patient’s free hand. The sleep mask can be offered to patients of all ages undergoing nail surgery under local anesthesia, except babies and young children, who require general anesthesia.

Practical Implications

Distraction is an important strategy to reduce anxiety and pain in patients undergoing surgical procedures. In an observational study of 3087 surgical patients, 36% reported that self-distraction was the most helpful strategy for coping with preoperative anxiety.4 In a randomized, open-label clinical trial of 72 patients undergoing peripheral venous catheterization, asking the patients simple questions during the procedure was more effective than local anesthesia in reducing the perception of pain.5

It is crucial to implement strategies to reduce anxiety in patients undergoing nail surgery. Using a sleep mask impedes direct visualization of the surgical field, thus distracting the patient’s sight and attention from the procedure. Furthermore, this technique is safe and cost-effective.

Controlled clinical trials are necessary to assess the efficacy of this method in reducing nail surgery–related anxiety in comparison to other techniques.

 

 

Practice Gap

Perioperative anxiety is common in patients undergoing nail surgery. Patients might worry about seeing blood; about the procedure itself, including nail avulsion; and about associated pain and disfigurement. Nail surgery causes a high level of anxiety that correlates positively with postoperative pain1 and overall patient dissatisfaction. Furthermore, surgery-related anxiety is a predictor of increased postoperative analgesic use2 and delayed recovery.3

Therefore, implementing strategies that reduce perioperative anxiety may help minimize postoperative pain. Squeezing a stress ball, hand-holding, virtual reality, and music are tools that have been studied to reduce anxiety in the context of Mohs micrographic surgery; these strategies have not been studied for nail surgery.

The Technique

Using a sleep mask is a practical solution to reduce patient anxiety during nail surgery. A minority of patients will choose to watch their surgical procedure; most become unnerved observing their nail surgery. Using a sleep mask diverts visual attention from the surgical field without physically interfering with the nail surgeon. Utilizing a sleep mask is cost-effective, with disposable sleep masks available online for less than $0.30 each. Patients can bring their own mask, or a mask can be offered prior to surgery.

If desired, patients are instructed to wear the sleep mask during the entirety of the procedure, starting from anesthetic infiltration until wound closure and dressing application. Any adjustments can be made with the patient’s free hand. The sleep mask can be offered to patients of all ages undergoing nail surgery under local anesthesia, except babies and young children, who require general anesthesia.

Practical Implications

Distraction is an important strategy to reduce anxiety and pain in patients undergoing surgical procedures. In an observational study of 3087 surgical patients, 36% reported that self-distraction was the most helpful strategy for coping with preoperative anxiety.4 In a randomized, open-label clinical trial of 72 patients undergoing peripheral venous catheterization, asking the patients simple questions during the procedure was more effective than local anesthesia in reducing the perception of pain.5

It is crucial to implement strategies to reduce anxiety in patients undergoing nail surgery. Using a sleep mask impedes direct visualization of the surgical field, thus distracting the patient’s sight and attention from the procedure. Furthermore, this technique is safe and cost-effective.

Controlled clinical trials are necessary to assess the efficacy of this method in reducing nail surgery–related anxiety in comparison to other techniques.

References
  1. Navarro-Gastón D, Munuera-Martínez PV. Prevalence of preoperative anxiety and its relationship with postoperative pain in foot nail surgery: a cross-sectional study. Int J Environ Res Public Health. 2020;17:4481. doi:10.3390/ijerph17124481
  2. Ip HYV, Abrishami A, Peng PWH, et al. Predictors of postoperative pain and analgesic consumption: a qualitative systematic review. Anesthesiology. 2009;111:657-677. doi:10.1097/ALN.0b013e3181aae87a
  3. Mavros MN, Athanasiou S, Gkegkes ID, et al. Do psychological variables affect early surgical recovery? PLoS One. 2011;6:E20306. doi:10.1371/journal.pone.0020306
  4. Aust H, Rüsch D, Schuster M, et al. Coping strategies in anxious surgical patients. BMC Health Serv Res. 2016;16:250. doi:10.1186/s12913-016-1492-5
  5. Balanyuk I, Ledonne G, Provenzano M, et al. Distraction technique for pain reduction in peripheral venous catheterization: randomized, controlled trial. Acta Biomed. 2018;89(suppl 4):55-63. doi:10.23750/abmv89i4-S.7115
References
  1. Navarro-Gastón D, Munuera-Martínez PV. Prevalence of preoperative anxiety and its relationship with postoperative pain in foot nail surgery: a cross-sectional study. Int J Environ Res Public Health. 2020;17:4481. doi:10.3390/ijerph17124481
  2. Ip HYV, Abrishami A, Peng PWH, et al. Predictors of postoperative pain and analgesic consumption: a qualitative systematic review. Anesthesiology. 2009;111:657-677. doi:10.1097/ALN.0b013e3181aae87a
  3. Mavros MN, Athanasiou S, Gkegkes ID, et al. Do psychological variables affect early surgical recovery? PLoS One. 2011;6:E20306. doi:10.1371/journal.pone.0020306
  4. Aust H, Rüsch D, Schuster M, et al. Coping strategies in anxious surgical patients. BMC Health Serv Res. 2016;16:250. doi:10.1186/s12913-016-1492-5
  5. Balanyuk I, Ledonne G, Provenzano M, et al. Distraction technique for pain reduction in peripheral venous catheterization: randomized, controlled trial. Acta Biomed. 2018;89(suppl 4):55-63. doi:10.23750/abmv89i4-S.7115
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Recommendations for Pregnant Members of Dermatology Health Care Teams During the COVID-19 Pandemic

Article Type
Article
Changed
Thu, 08/26/2021 - 15:47
Author(s)
Jose W. Ricardo, MD
Shari R. Lipner, MD, PhD

 

Information is scarce regarding the impact of COVID-19 on pregnant women and newborns; health care workers (HCWs), particularly pregnant women,1 who are caring for patients during the pandemic might experience concern and uncertainty. The American College of Obstetricians and Gynecologists (ACOG) released recommendations, based on expert consensus, regarding pregnant HCWs on December 14, 2020.2 We propose an appropriation of the ACOG recommendations for dermatologists and their teams caring for patients during the COVID-19 pandemic.

Risks to Pregnant HCWs

Worldwide, viral pneumonia is a leading cause of death during pregnancy,3 with higher mortality documented among pregnant patients during the 1918 influenza pandemic and the 2003 severe acute respiratory syndrome–associated coronavirus pandemic,3 and an increased rate of hospital admission documented among these patients compared to the general population during the 2009 H1N1 influenza pandemic.4

Data from the Centers for Disease Control and Prevention (CDC) suggest that pregnant women with symptomatic COVID-19 (n=30,415) are at increased risk for the following (compared to nonpregnant women with symptomatic COVID-19 [n=431,410])5:

• Admission to the intensive care unit (10.5 of every 1000 cases vs 3.9 of every 1000 cases; adjusted risk ratio [aRR]=3.0; 95% CI, 2.6-3.4)

• Receipt of invasive ventilation (2.9 of every 1000 cases vs 1.1 of every 1000 cases; aRR=2.9; 95% CI, 2.2-3.8)

• Receipt of extracorporeal membrane oxygenation (0.7 of every 1000 cases vs 0.3 of every 1000 cases; aRR=2.4; 95% CI, 1.5-4.0)

• Death (1.5 of every 1000 cases vs 1.2 of every 1000 cases; aRR=1.7; 95% CI, 1.2-2.4).

Although the absolute risk of severe COVID-19–related outcomes is low, the CDC includes pregnant women in its increased risk category for COVID-19. Furthermore, in a systematic review of 61 studies comprising 790 COVID-19–positive pregnant women and 548 newborns, the rates of cesarean delivery, premature birth, low birth weight, and adverse pregnancy events (the latter comprising preterm birth, death or stillbirth, and early termination of pregnancy) were estimated to be 72%, 23%, 7%, and 27%, respectively.6 In a systematic review of 39 studies (case series and cohort studies), comprising 936 SARS-CoV-2–tested newborns of mothers with COVID-19, mother-to-fetus transmission of SARS-CoV-2 occurred during the third trimester in approximately 3.2% of infected mothers.7

In pregnant women with COVID-19 who develop cytokine storm syndrome, a fetal inflammatory response syndrome can ensue, which has been shown to cause ventricular expansion and bleeding in animal models.8 In addition, underlying conditions, such as cardiovascular disease, diabetes mellitus, pre-existing lung disease, and obesity, which are well-established risks factors for severe COVID-19 in nonpregnant patients, can increase the severity of COVID-19 in pregnant women.5,9-11

Recommendations From ACOG for Pregnant HCWs

The American College of Obstetricians and Gynecologists recommends that health care facilities consider limiting the exposure of pregnant HCWs to patients with confirmed or suspected COVID-19. They also recommend that pregnant women continue to work in patient-facing roles if they want to, if recommended personal protective equipment (PPE) is available for them to wear.2 The US Food and Drug Administration issued an Emergency Use Authorization for 2 messenger RNA COVID-19 vaccines. Although these vaccines have not been tested in pregnant women, ACOG recommends that COVID-19 vaccines not be withheld from pregnant women who fulfill the criteria for vaccination; pregnant women who decline vaccination should be supported in their decision.12 In dermatology, telemedicine is an effective alternative to face-to-face visits, reducing the risk of transmitting SARS-CoV-2 to physicians and patients.

Ideally, pregnant dermatology attending physicians and residents can continue to provide care through teledermatology. They also can continue to provide in-person care, if they choose to; however, higher-risk procedures should be avoided.12 In dermatology, that might include ablative laser procedures to the face, prolonged surgery, such as hair transplantation, and intraoral or intranasal procedures. Alternatively, pregnant dermatology residents can be allocated to clinical rotations in which face-to-face contact with patients is not required such as dermatopathology and a research rotation. Likewise, telework options can be encouraged for other pregnant members of dermatology teams, including front-desk staff, nurses, medical assistants, and remaining ancillary staff.

Guidance on Face Masks for Pregnant HCWs

Universal masking of HCWs has been shown to reduce the rate of health care–related acquisition of SARS-CoV-2.13 However, extended use or reuse of N95 respirators might contribute to SARS-CoV-2 transmission.14 The American College of Obstetricians and Gynecologists recommends that all HCWs wear a face mask at all times while working in a health care facility, even if patients are wearing a face covering or face mask.2 Based on CDC guidelines,15 HCWs in regions where community transmission is moderate or substantial should wear eye protection in addition to a face mask, and they should wear an N95, N95-equivalent, or higher-level respirator instead of a face mask when performing aerosol-generating procedures and surgical procedures. If working in a patient-facing role caring for patients with suspected or confirmed COVID-19, HCWs should wear an N95, N95-equivalent, or higher-level respirator; gown; gloves; and eye protection (goggles or a disposable face shield).15

Final Thoughts

COVID-19 has brought about acute and likely permanent changes to the US health care system. Dermatologists are integral members of that system and are essential to the treatment of patients with skin, hair, and nail disorders. Pregnant dermatologists and residents should refrain from patient-facing roles when feasible; however, when all recommended PPE are available, they may continue to work in patient-facing roles until they give birth if they desire to do so. Alternatively, teledermatology and non–face-to-face rotations should be encouraged. Higher-risk and aerosol-generating procedures are of particular concern regarding the risk for transmitting SARS-CoV-2 and should be avoided. Correct and universal use of PPE is paramount; when all recommended PPE is not available, pregnant HCWs should avoid exposure to patients with suspected or confirmed COVID-19. These recommendations will help safeguard pregnant members of dermatology teams during the COVID-19 pandemic while maximizing patient care.

References
  1. Rashidi Fakari F, Simbar M. Coronavirus pandemic and worries during pregnancy; a letter to editor. Arch Acad Emerg Med. 2020;8:E21.
  2. The American College of Obstetricians and Gynecologists. COVID-19 FAQs for obstetrician-gynecologists, obstetrics. 2020. Accessed April 21, 2021. https://www.acog.org/clinical-information/physician-faqs/covid-19-faqs-for-ob-gyns-obstetrics
  3. Schwartz DA, Graham AL. Potential maternal and infant outcomes from (Wuhan) coronavirus 2019-nCoV infecting pregnant women: lessons from SARS, MERS, and other human coronavirus infections. Viruses. 2020;12:194. doi:10.3390/v12020194
  4. Yan J, Guo J, Fan C, et al. Coronavirus disease 2019 in pregnant women: a report based on 116 cases. Am J Obstet Gynecol. 2020;223:111.e1-111.e14. doi:10.1016/j.ajog.2020.04.014
  5. Zambrano LD, Ellington S, Strid P, et al; CDC COVID-19 Response Pregnancy and Infant Linked Outcomes Team. Update: characteristics of symptomatic women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–October 3, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:1641-1647. doi:10.15585/mmwr.mm6944e3
  6. Dubey P, Reddy SY, Manuel S, et al. Maternal and neonatal characteristics and outcomes among COVID-19 infected women: an updated systematic review and meta-analysis. Eur J Obstet Gynecol Reprod Biol. 2020;252:490-501. doi:10.1016/j.ejogrb.2020.07.034
  7. Kotlyar AM, Grechukhina O, Chen A, et al. Vertical transmission of coronavirus disease 2019: a systematic review and meta-analysis. Am J Obstet Gynecol. 2020;224:35-53.e3. doi:10.1016/j.ajog.2020.07.049
  8. Mitchell T, MacDonald JW, Srinouanpranchanh S, et al. Evidence of cardiac involvement in the fetal inflammatory response syndrome: disruption of gene networks programming cardiac development in nonhuman primates. Am J Obstet Gynecol. 2018;218:438.e1-438.e16. doi:10.1016/j.ajog.2018.01.009
  9. Ellington S, Strid P, Tong VT, et al. Characteristics of women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–June 7, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:769-775. doi:10.15585/mmwr.mm6925a1
  10. Panagiotakopoulos L, Myers TR, Gee J, et al. SARS-CoV-2 infection among hospitalized pregnant women: reasons for admission and pregnancy characteristics—eight U.S. health care centers, March 1–May 30, 2020. 2020. doi:10.15585/mmwr.mm6938e2
  11. Knight M, Bunch K, Vousden N, et al; UK Obstetric Surveillance System SARS-CoV-2 Infection in Pregnancy Collaborative Group. Characteristics and outcomes of pregnant women admitted to hospital with confirmed SARS-CoV-2 infection in UK: national population based cohort study. BMJ. 2020;369:m2107. doi:10.1136/bmj.m2107
  12. The American College of Obstetricians and Gynecologists. Vaccinating pregnant and lactating patients against COVID-19. December 2020. Updated March 24, 2021. Accessed April 28, 2021. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2020/12/vaccinating-pregnant-and-lactating-patients-against-covid-19
  13. Seidelman JL, Lewis SS, Advani SD, et al. Universal masking is an effective strategy to flatten the severe acute respiratory coronavirus virus 2 (SARS-CoV-2) healthcare worker epidemiologic curve. Infect Control Hosp Epidemiol. 2020;41:1466-1467. doi:10.1017/ice.2020.31314.
  14. Degesys NF, Wang RC, Kwan E, et al. Correlation between N95 extended use and reuse and fit failure in an emergency department. JAMA. 2020;324:94-96. doi:10.1001/jama.2020.9843
  15. Centers for Disease Control and Prevention. Interim infection prevention and control recommendations for healthcare personnel during the coronavirus disease 2019 (COVID-19) pandemic 2020. Updated February 23, 2021. Accessed April 21, 2021. https://www.cdc.gov/coronavirus/2019-ncov/hcp/infection-control-recommendations.html?CDC_AA_refVal=https%3A%2F%2Fwww.cdc.gov%2Fcoronavirus%2F2019-ncov%2Finfection-control%2Fcontrol-recommendations.html
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The authors report no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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The authors report no conflict of interest.

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The authors report no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Information is scarce regarding the impact of COVID-19 on pregnant women and newborns; health care workers (HCWs), particularly pregnant women,1 who are caring for patients during the pandemic might experience concern and uncertainty. The American College of Obstetricians and Gynecologists (ACOG) released recommendations, based on expert consensus, regarding pregnant HCWs on December 14, 2020.2 We propose an appropriation of the ACOG recommendations for dermatologists and their teams caring for patients during the COVID-19 pandemic.

Risks to Pregnant HCWs

Worldwide, viral pneumonia is a leading cause of death during pregnancy,3 with higher mortality documented among pregnant patients during the 1918 influenza pandemic and the 2003 severe acute respiratory syndrome–associated coronavirus pandemic,3 and an increased rate of hospital admission documented among these patients compared to the general population during the 2009 H1N1 influenza pandemic.4

Data from the Centers for Disease Control and Prevention (CDC) suggest that pregnant women with symptomatic COVID-19 (n=30,415) are at increased risk for the following (compared to nonpregnant women with symptomatic COVID-19 [n=431,410])5:

• Admission to the intensive care unit (10.5 of every 1000 cases vs 3.9 of every 1000 cases; adjusted risk ratio [aRR]=3.0; 95% CI, 2.6-3.4)

• Receipt of invasive ventilation (2.9 of every 1000 cases vs 1.1 of every 1000 cases; aRR=2.9; 95% CI, 2.2-3.8)

• Receipt of extracorporeal membrane oxygenation (0.7 of every 1000 cases vs 0.3 of every 1000 cases; aRR=2.4; 95% CI, 1.5-4.0)

• Death (1.5 of every 1000 cases vs 1.2 of every 1000 cases; aRR=1.7; 95% CI, 1.2-2.4).

Although the absolute risk of severe COVID-19–related outcomes is low, the CDC includes pregnant women in its increased risk category for COVID-19. Furthermore, in a systematic review of 61 studies comprising 790 COVID-19–positive pregnant women and 548 newborns, the rates of cesarean delivery, premature birth, low birth weight, and adverse pregnancy events (the latter comprising preterm birth, death or stillbirth, and early termination of pregnancy) were estimated to be 72%, 23%, 7%, and 27%, respectively.6 In a systematic review of 39 studies (case series and cohort studies), comprising 936 SARS-CoV-2–tested newborns of mothers with COVID-19, mother-to-fetus transmission of SARS-CoV-2 occurred during the third trimester in approximately 3.2% of infected mothers.7

In pregnant women with COVID-19 who develop cytokine storm syndrome, a fetal inflammatory response syndrome can ensue, which has been shown to cause ventricular expansion and bleeding in animal models.8 In addition, underlying conditions, such as cardiovascular disease, diabetes mellitus, pre-existing lung disease, and obesity, which are well-established risks factors for severe COVID-19 in nonpregnant patients, can increase the severity of COVID-19 in pregnant women.5,9-11

Recommendations From ACOG for Pregnant HCWs

The American College of Obstetricians and Gynecologists recommends that health care facilities consider limiting the exposure of pregnant HCWs to patients with confirmed or suspected COVID-19. They also recommend that pregnant women continue to work in patient-facing roles if they want to, if recommended personal protective equipment (PPE) is available for them to wear.2 The US Food and Drug Administration issued an Emergency Use Authorization for 2 messenger RNA COVID-19 vaccines. Although these vaccines have not been tested in pregnant women, ACOG recommends that COVID-19 vaccines not be withheld from pregnant women who fulfill the criteria for vaccination; pregnant women who decline vaccination should be supported in their decision.12 In dermatology, telemedicine is an effective alternative to face-to-face visits, reducing the risk of transmitting SARS-CoV-2 to physicians and patients.

Ideally, pregnant dermatology attending physicians and residents can continue to provide care through teledermatology. They also can continue to provide in-person care, if they choose to; however, higher-risk procedures should be avoided.12 In dermatology, that might include ablative laser procedures to the face, prolonged surgery, such as hair transplantation, and intraoral or intranasal procedures. Alternatively, pregnant dermatology residents can be allocated to clinical rotations in which face-to-face contact with patients is not required such as dermatopathology and a research rotation. Likewise, telework options can be encouraged for other pregnant members of dermatology teams, including front-desk staff, nurses, medical assistants, and remaining ancillary staff.

Guidance on Face Masks for Pregnant HCWs

Universal masking of HCWs has been shown to reduce the rate of health care–related acquisition of SARS-CoV-2.13 However, extended use or reuse of N95 respirators might contribute to SARS-CoV-2 transmission.14 The American College of Obstetricians and Gynecologists recommends that all HCWs wear a face mask at all times while working in a health care facility, even if patients are wearing a face covering or face mask.2 Based on CDC guidelines,15 HCWs in regions where community transmission is moderate or substantial should wear eye protection in addition to a face mask, and they should wear an N95, N95-equivalent, or higher-level respirator instead of a face mask when performing aerosol-generating procedures and surgical procedures. If working in a patient-facing role caring for patients with suspected or confirmed COVID-19, HCWs should wear an N95, N95-equivalent, or higher-level respirator; gown; gloves; and eye protection (goggles or a disposable face shield).15

Final Thoughts

COVID-19 has brought about acute and likely permanent changes to the US health care system. Dermatologists are integral members of that system and are essential to the treatment of patients with skin, hair, and nail disorders. Pregnant dermatologists and residents should refrain from patient-facing roles when feasible; however, when all recommended PPE are available, they may continue to work in patient-facing roles until they give birth if they desire to do so. Alternatively, teledermatology and non–face-to-face rotations should be encouraged. Higher-risk and aerosol-generating procedures are of particular concern regarding the risk for transmitting SARS-CoV-2 and should be avoided. Correct and universal use of PPE is paramount; when all recommended PPE is not available, pregnant HCWs should avoid exposure to patients with suspected or confirmed COVID-19. These recommendations will help safeguard pregnant members of dermatology teams during the COVID-19 pandemic while maximizing patient care.

 

Information is scarce regarding the impact of COVID-19 on pregnant women and newborns; health care workers (HCWs), particularly pregnant women,1 who are caring for patients during the pandemic might experience concern and uncertainty. The American College of Obstetricians and Gynecologists (ACOG) released recommendations, based on expert consensus, regarding pregnant HCWs on December 14, 2020.2 We propose an appropriation of the ACOG recommendations for dermatologists and their teams caring for patients during the COVID-19 pandemic.

Risks to Pregnant HCWs

Worldwide, viral pneumonia is a leading cause of death during pregnancy,3 with higher mortality documented among pregnant patients during the 1918 influenza pandemic and the 2003 severe acute respiratory syndrome–associated coronavirus pandemic,3 and an increased rate of hospital admission documented among these patients compared to the general population during the 2009 H1N1 influenza pandemic.4

Data from the Centers for Disease Control and Prevention (CDC) suggest that pregnant women with symptomatic COVID-19 (n=30,415) are at increased risk for the following (compared to nonpregnant women with symptomatic COVID-19 [n=431,410])5:

• Admission to the intensive care unit (10.5 of every 1000 cases vs 3.9 of every 1000 cases; adjusted risk ratio [aRR]=3.0; 95% CI, 2.6-3.4)

• Receipt of invasive ventilation (2.9 of every 1000 cases vs 1.1 of every 1000 cases; aRR=2.9; 95% CI, 2.2-3.8)

• Receipt of extracorporeal membrane oxygenation (0.7 of every 1000 cases vs 0.3 of every 1000 cases; aRR=2.4; 95% CI, 1.5-4.0)

• Death (1.5 of every 1000 cases vs 1.2 of every 1000 cases; aRR=1.7; 95% CI, 1.2-2.4).

Although the absolute risk of severe COVID-19–related outcomes is low, the CDC includes pregnant women in its increased risk category for COVID-19. Furthermore, in a systematic review of 61 studies comprising 790 COVID-19–positive pregnant women and 548 newborns, the rates of cesarean delivery, premature birth, low birth weight, and adverse pregnancy events (the latter comprising preterm birth, death or stillbirth, and early termination of pregnancy) were estimated to be 72%, 23%, 7%, and 27%, respectively.6 In a systematic review of 39 studies (case series and cohort studies), comprising 936 SARS-CoV-2–tested newborns of mothers with COVID-19, mother-to-fetus transmission of SARS-CoV-2 occurred during the third trimester in approximately 3.2% of infected mothers.7

In pregnant women with COVID-19 who develop cytokine storm syndrome, a fetal inflammatory response syndrome can ensue, which has been shown to cause ventricular expansion and bleeding in animal models.8 In addition, underlying conditions, such as cardiovascular disease, diabetes mellitus, pre-existing lung disease, and obesity, which are well-established risks factors for severe COVID-19 in nonpregnant patients, can increase the severity of COVID-19 in pregnant women.5,9-11

Recommendations From ACOG for Pregnant HCWs

The American College of Obstetricians and Gynecologists recommends that health care facilities consider limiting the exposure of pregnant HCWs to patients with confirmed or suspected COVID-19. They also recommend that pregnant women continue to work in patient-facing roles if they want to, if recommended personal protective equipment (PPE) is available for them to wear.2 The US Food and Drug Administration issued an Emergency Use Authorization for 2 messenger RNA COVID-19 vaccines. Although these vaccines have not been tested in pregnant women, ACOG recommends that COVID-19 vaccines not be withheld from pregnant women who fulfill the criteria for vaccination; pregnant women who decline vaccination should be supported in their decision.12 In dermatology, telemedicine is an effective alternative to face-to-face visits, reducing the risk of transmitting SARS-CoV-2 to physicians and patients.

Ideally, pregnant dermatology attending physicians and residents can continue to provide care through teledermatology. They also can continue to provide in-person care, if they choose to; however, higher-risk procedures should be avoided.12 In dermatology, that might include ablative laser procedures to the face, prolonged surgery, such as hair transplantation, and intraoral or intranasal procedures. Alternatively, pregnant dermatology residents can be allocated to clinical rotations in which face-to-face contact with patients is not required such as dermatopathology and a research rotation. Likewise, telework options can be encouraged for other pregnant members of dermatology teams, including front-desk staff, nurses, medical assistants, and remaining ancillary staff.

Guidance on Face Masks for Pregnant HCWs

Universal masking of HCWs has been shown to reduce the rate of health care–related acquisition of SARS-CoV-2.13 However, extended use or reuse of N95 respirators might contribute to SARS-CoV-2 transmission.14 The American College of Obstetricians and Gynecologists recommends that all HCWs wear a face mask at all times while working in a health care facility, even if patients are wearing a face covering or face mask.2 Based on CDC guidelines,15 HCWs in regions where community transmission is moderate or substantial should wear eye protection in addition to a face mask, and they should wear an N95, N95-equivalent, or higher-level respirator instead of a face mask when performing aerosol-generating procedures and surgical procedures. If working in a patient-facing role caring for patients with suspected or confirmed COVID-19, HCWs should wear an N95, N95-equivalent, or higher-level respirator; gown; gloves; and eye protection (goggles or a disposable face shield).15

Final Thoughts

COVID-19 has brought about acute and likely permanent changes to the US health care system. Dermatologists are integral members of that system and are essential to the treatment of patients with skin, hair, and nail disorders. Pregnant dermatologists and residents should refrain from patient-facing roles when feasible; however, when all recommended PPE are available, they may continue to work in patient-facing roles until they give birth if they desire to do so. Alternatively, teledermatology and non–face-to-face rotations should be encouraged. Higher-risk and aerosol-generating procedures are of particular concern regarding the risk for transmitting SARS-CoV-2 and should be avoided. Correct and universal use of PPE is paramount; when all recommended PPE is not available, pregnant HCWs should avoid exposure to patients with suspected or confirmed COVID-19. These recommendations will help safeguard pregnant members of dermatology teams during the COVID-19 pandemic while maximizing patient care.

References
  1. Rashidi Fakari F, Simbar M. Coronavirus pandemic and worries during pregnancy; a letter to editor. Arch Acad Emerg Med. 2020;8:E21.
  2. The American College of Obstetricians and Gynecologists. COVID-19 FAQs for obstetrician-gynecologists, obstetrics. 2020. Accessed April 21, 2021. https://www.acog.org/clinical-information/physician-faqs/covid-19-faqs-for-ob-gyns-obstetrics
  3. Schwartz DA, Graham AL. Potential maternal and infant outcomes from (Wuhan) coronavirus 2019-nCoV infecting pregnant women: lessons from SARS, MERS, and other human coronavirus infections. Viruses. 2020;12:194. doi:10.3390/v12020194
  4. Yan J, Guo J, Fan C, et al. Coronavirus disease 2019 in pregnant women: a report based on 116 cases. Am J Obstet Gynecol. 2020;223:111.e1-111.e14. doi:10.1016/j.ajog.2020.04.014
  5. Zambrano LD, Ellington S, Strid P, et al; CDC COVID-19 Response Pregnancy and Infant Linked Outcomes Team. Update: characteristics of symptomatic women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–October 3, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:1641-1647. doi:10.15585/mmwr.mm6944e3
  6. Dubey P, Reddy SY, Manuel S, et al. Maternal and neonatal characteristics and outcomes among COVID-19 infected women: an updated systematic review and meta-analysis. Eur J Obstet Gynecol Reprod Biol. 2020;252:490-501. doi:10.1016/j.ejogrb.2020.07.034
  7. Kotlyar AM, Grechukhina O, Chen A, et al. Vertical transmission of coronavirus disease 2019: a systematic review and meta-analysis. Am J Obstet Gynecol. 2020;224:35-53.e3. doi:10.1016/j.ajog.2020.07.049
  8. Mitchell T, MacDonald JW, Srinouanpranchanh S, et al. Evidence of cardiac involvement in the fetal inflammatory response syndrome: disruption of gene networks programming cardiac development in nonhuman primates. Am J Obstet Gynecol. 2018;218:438.e1-438.e16. doi:10.1016/j.ajog.2018.01.009
  9. Ellington S, Strid P, Tong VT, et al. Characteristics of women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–June 7, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:769-775. doi:10.15585/mmwr.mm6925a1
  10. Panagiotakopoulos L, Myers TR, Gee J, et al. SARS-CoV-2 infection among hospitalized pregnant women: reasons for admission and pregnancy characteristics—eight U.S. health care centers, March 1–May 30, 2020. 2020. doi:10.15585/mmwr.mm6938e2
  11. Knight M, Bunch K, Vousden N, et al; UK Obstetric Surveillance System SARS-CoV-2 Infection in Pregnancy Collaborative Group. Characteristics and outcomes of pregnant women admitted to hospital with confirmed SARS-CoV-2 infection in UK: national population based cohort study. BMJ. 2020;369:m2107. doi:10.1136/bmj.m2107
  12. The American College of Obstetricians and Gynecologists. Vaccinating pregnant and lactating patients against COVID-19. December 2020. Updated March 24, 2021. Accessed April 28, 2021. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2020/12/vaccinating-pregnant-and-lactating-patients-against-covid-19
  13. Seidelman JL, Lewis SS, Advani SD, et al. Universal masking is an effective strategy to flatten the severe acute respiratory coronavirus virus 2 (SARS-CoV-2) healthcare worker epidemiologic curve. Infect Control Hosp Epidemiol. 2020;41:1466-1467. doi:10.1017/ice.2020.31314.
  14. Degesys NF, Wang RC, Kwan E, et al. Correlation between N95 extended use and reuse and fit failure in an emergency department. JAMA. 2020;324:94-96. doi:10.1001/jama.2020.9843
  15. Centers for Disease Control and Prevention. Interim infection prevention and control recommendations for healthcare personnel during the coronavirus disease 2019 (COVID-19) pandemic 2020. Updated February 23, 2021. Accessed April 21, 2021. https://www.cdc.gov/coronavirus/2019-ncov/hcp/infection-control-recommendations.html?CDC_AA_refVal=https%3A%2F%2Fwww.cdc.gov%2Fcoronavirus%2F2019-ncov%2Finfection-control%2Fcontrol-recommendations.html
References
  1. Rashidi Fakari F, Simbar M. Coronavirus pandemic and worries during pregnancy; a letter to editor. Arch Acad Emerg Med. 2020;8:E21.
  2. The American College of Obstetricians and Gynecologists. COVID-19 FAQs for obstetrician-gynecologists, obstetrics. 2020. Accessed April 21, 2021. https://www.acog.org/clinical-information/physician-faqs/covid-19-faqs-for-ob-gyns-obstetrics
  3. Schwartz DA, Graham AL. Potential maternal and infant outcomes from (Wuhan) coronavirus 2019-nCoV infecting pregnant women: lessons from SARS, MERS, and other human coronavirus infections. Viruses. 2020;12:194. doi:10.3390/v12020194
  4. Yan J, Guo J, Fan C, et al. Coronavirus disease 2019 in pregnant women: a report based on 116 cases. Am J Obstet Gynecol. 2020;223:111.e1-111.e14. doi:10.1016/j.ajog.2020.04.014
  5. Zambrano LD, Ellington S, Strid P, et al; CDC COVID-19 Response Pregnancy and Infant Linked Outcomes Team. Update: characteristics of symptomatic women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–October 3, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:1641-1647. doi:10.15585/mmwr.mm6944e3
  6. Dubey P, Reddy SY, Manuel S, et al. Maternal and neonatal characteristics and outcomes among COVID-19 infected women: an updated systematic review and meta-analysis. Eur J Obstet Gynecol Reprod Biol. 2020;252:490-501. doi:10.1016/j.ejogrb.2020.07.034
  7. Kotlyar AM, Grechukhina O, Chen A, et al. Vertical transmission of coronavirus disease 2019: a systematic review and meta-analysis. Am J Obstet Gynecol. 2020;224:35-53.e3. doi:10.1016/j.ajog.2020.07.049
  8. Mitchell T, MacDonald JW, Srinouanpranchanh S, et al. Evidence of cardiac involvement in the fetal inflammatory response syndrome: disruption of gene networks programming cardiac development in nonhuman primates. Am J Obstet Gynecol. 2018;218:438.e1-438.e16. doi:10.1016/j.ajog.2018.01.009
  9. Ellington S, Strid P, Tong VT, et al. Characteristics of women of reproductive age with laboratory-confirmed SARS-CoV-2 infection by pregnancy status—United States, January 22–June 7, 2020. MMWR Morb Mortal Wkly Rep. 2020;69:769-775. doi:10.15585/mmwr.mm6925a1
  10. Panagiotakopoulos L, Myers TR, Gee J, et al. SARS-CoV-2 infection among hospitalized pregnant women: reasons for admission and pregnancy characteristics—eight U.S. health care centers, March 1–May 30, 2020. 2020. doi:10.15585/mmwr.mm6938e2
  11. Knight M, Bunch K, Vousden N, et al; UK Obstetric Surveillance System SARS-CoV-2 Infection in Pregnancy Collaborative Group. Characteristics and outcomes of pregnant women admitted to hospital with confirmed SARS-CoV-2 infection in UK: national population based cohort study. BMJ. 2020;369:m2107. doi:10.1136/bmj.m2107
  12. The American College of Obstetricians and Gynecologists. Vaccinating pregnant and lactating patients against COVID-19. December 2020. Updated March 24, 2021. Accessed April 28, 2021. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2020/12/vaccinating-pregnant-and-lactating-patients-against-covid-19
  13. Seidelman JL, Lewis SS, Advani SD, et al. Universal masking is an effective strategy to flatten the severe acute respiratory coronavirus virus 2 (SARS-CoV-2) healthcare worker epidemiologic curve. Infect Control Hosp Epidemiol. 2020;41:1466-1467. doi:10.1017/ice.2020.31314.
  14. Degesys NF, Wang RC, Kwan E, et al. Correlation between N95 extended use and reuse and fit failure in an emergency department. JAMA. 2020;324:94-96. doi:10.1001/jama.2020.9843
  15. Centers for Disease Control and Prevention. Interim infection prevention and control recommendations for healthcare personnel during the coronavirus disease 2019 (COVID-19) pandemic 2020. Updated February 23, 2021. Accessed April 21, 2021. https://www.cdc.gov/coronavirus/2019-ncov/hcp/infection-control-recommendations.html?CDC_AA_refVal=https%3A%2F%2Fwww.cdc.gov%2Fcoronavirus%2F2019-ncov%2Finfection-control%2Fcontrol-recommendations.html
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Practice Points

  • Pregnant women are at an increased risk for severe illness due to COVID-19 compared with nonpregnant women; therefore, it is important to protect pregnant health care workers who are caring for patients during the current pandemic.
  • Although currently available COVID-19 vaccines have not been tested in pregnant women, they should not be withheld from pregnant individuals.
  • Pregnant attending physicians and residents in dermatology can continue to provide care through telemedicine; if they choose to, and if all recommended personal protective equipment (PPE) are available, they can continue to provide in-person care.
  • Correct and comprehensive use of PPE by pregnant health care workers is paramount to minimizing exposure to SARS-CoV-2.
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Head to Toe: Recommendations for Physician Head and Shoe Coverings to Limit COVID-19 Transmission

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Author(s)
Jade Conway, BA
Shari R. Lipner, MD, PhD

 

Personal protective equipment (PPE) is an important component in limiting transmission of SARS-CoV-2. The World Health Organization and Centers for Disease Control and Prevention issued guidelines for appropriate PPE use, but recommendations for head and shoe coverings are lacking. In this article, we analyze the literature on pathogen transmission via hair and shoes and make evidence-based recommendations for PPE selection during the COVID-19 pandemic.

Pathogens on Shoes and Hair

Hair and shoes may act as vehicles for pathogen transmission. In a study that simulated contamination of uncovered skin in health care workers after intubating manikins in respiratory distress, 8 (100%) had fluorescent markers on the hair, 6 (75%) on the neck, and 4 (50%) on the shoes.1 In another study of postsurgical operating room (OR) surfaces (517 cultures), uncovered shoe tops and reusable hair coverings had 10-times more bacterial colony–forming units compared to other surfaces. On average, disposable shoe covers/head coverings had less than one-third bacterial colony–forming units compared with uncovered shoes/reusable hair coverings.2

Hair characteristics and coverings may affect pathogen transmission. Exposed hair may collect bacteria, as Staphylococcus aureus and Staphylococcus epidermidis attach to both scalp and facial hair. In one case, β-hemolytic streptococci cultured from the scalp of a perioperative nurse was linked to postsurgical infections in 20 patients.3 Hair coverings include bouffant caps and skullcaps. The bouffant cap is similar to a shower cap; it is relatively loose and secured around the head with elastic. The skullcap, or scrub cap, is tighter but leaves the neck nape and sideburns exposed. In a study comparing disposable bouffant caps, disposable skullcaps, and home-laundered cloth skullcaps worn by 2 teams of 5 surgeons, the disposable bouffant caps had the highest permeability, penetration, and microbial shed of airborne particles.4

Physicians’ shoes may act as fomites for transmission of pathogens to patients. In a study of 41 physicians and nurses in an acute care hospital, shoe soles were positive for at least one pathogen in 12 (29.3%) participants; methicillin-resistant Staphylococcus aureus was most common. Additionally, 98% (49/50) of shoes worn outdoors showed positive bacterial cultures compared to 56% (28/50) of shoes reserved for the OR only.5 In a study examining ventilation effects on airborne pathogens in the OR, 15% of OR airborne bacteria originated from OR floors, and higher bacterial counts correlated with a higher number of steps in the OR.2 In another study designed to evaluate SARS-CoV-2 distribution on hospital floors, 70% (7/10) of quantitative polymerase chain reaction assays performed on floor samples from intensive care units were positive. In addition, 100% (3/3) of swabs taken from hospital pharmacy floors with no COVID-19 patients were positive for SARS-CoV-2, meaning contaminated shoes likely served as vectors.6 Middle East respiratory syndrome, SARS-CoV-2, and influenza viruses may survive on porous and nonporous materials for hours to days.7Enterococcus, Candida, and Aspergillus may survive on textiles for up to 90 days.3

Recommendations for Hair and Shoe Coverings

We recommend that physicians utilize disposable skullcaps to cover the hair and consider a hooded gown or coverall for neck/ear coverage. We also recommend that physicians designate shoes that remain in the workplace and can be easily washed or disinfected at least weekly; physicians may choose to wash or disinfect shoes more often if they frequently are performing procedures that generate aerosols. Additionally, physicians should always wear shoe coverings when caring for patients (Table 1).

Our hair and shoe covering recommendations may serve to protect dermatologists when caring for patients. These protocols may be particularly important for dermatologists performing high-risk procedures, including facial surgery, intraoral/intranasal procedures, and treatment with ablative lasers and facial injectables, especially when the patient is unmasked. These recommendations may limit viral transmission to dermatologists and also protect individuals living in their households. Additional established guidelines by the American Academy of Dermatology, American Society for Dermatologic Surgery, and World Health Organization are listed in Table 2.8-10

Current PPE recommendations that do not include hair and shoe coverings may be inadequate for limiting SARS-CoV-2 exposure between and among physicians and patients. Adherence to head covering and shoe recommendations may aid in reducing unwanted SARS-CoV-2 transmission in the health care setting, even as the pandemic continues.

References
  1. Feldman O, Meir M, Shavit D, et al. Exposure to a surrogate measure of contamination from simulated patients by emergency department personnel wearing personal protective equipment. JAMA. 2020;323:2091-2093. doi:10.1001/jama.2020.6633
  2. Alexander JW, Van Sweringen H, Vanoss K, et al. Surveillance of bacterial colonization in operating rooms. Surg Infect (Larchmt). 2013;14:345-351. doi:10.1089/sur.2012.134
  3. Blanchard J. Clinical issues—August 2010. AORN Journal. 2010;92:228-232. doi:10.1016/j.aorn.2010.06.001 
  4. Markel TA, Gormley T, Greeley D, et al. Hats off: a study of different operating room headgear assessed by environmental quality indicators. J Am Coll Surg. 2017;225:573-581. doi:10.1016/j.jamcollsurg.2017.08.014
  5. Kanwar A, Thakur M, Wazzan M, et al. Clothing and shoes of personnel as potential vectors for transfer of health care-associated pathogens to the community. Am J Infect Control. 2019;47:577-579. doi:10.1016/j.ajic.2019.01.028
  6. Guo ZD, Wang ZY, Zhang SF, et al. Aerosol and surface distribution of severe acute respiratory syndrome coronavirus 2 in hospital wards, Wuhan, China, 2020. Emerg Infect Dis. 2020;26:1583-1591. doi:10.3201/eid2607.200885
  7. Otter JA, Donskey C, Yezli S, et al. Transmission of SARS and MERS coronaviruses and influenza virus in healthcare settings: the possible role of dry surface contamination. J Hosp Infect. 2016;92:235-250. doi:10.1016/j.jhin.2015.08.027
  8. Centers for Disease Control and Prevention. Science Brief: SARS-CoV-2 and Surface (Fomite) Transmission for Indoor Community Environments. https://www.cdc.gov/coronavirus/2019-ncov/more/science-and-research/surface-transmission.html#ref10
  9. American Academy of Dermatology. Clinical guidance for COVID-19. Accessed March 15, 2021. https://www.aad.org/member/practice/coronavirus/clinical-guidance
  10. Narla S, Alam M, Ozog DM, et al. American Society of Dermatologic Surgery Association (ASDSA) and American Society for Laser Medicine & Surgery (ASLMS) guidance for cosmetic dermatology practices during COVID-19. Updated January 11, 2021. Accessed March 15, 2021. https://www.asds.net/Portals/0/PDF/asdsa/asdsa-aslms-cosmetic-reopening-guidance.pdf
  11. World Health Organization. Country & technical guidance—coronavirus disease (COVID-19). Accessed March 15, 2021. https://www.who.int/emergencies/diseases/novel-coronavirus-2019/technical-guidance-publications
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Ms. Conway is from New York Medical College, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

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Author and Disclosure Information

Ms. Conway is from New York Medical College, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

Author and Disclosure Information

Ms. Conway is from New York Medical College, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

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Personal protective equipment (PPE) is an important component in limiting transmission of SARS-CoV-2. The World Health Organization and Centers for Disease Control and Prevention issued guidelines for appropriate PPE use, but recommendations for head and shoe coverings are lacking. In this article, we analyze the literature on pathogen transmission via hair and shoes and make evidence-based recommendations for PPE selection during the COVID-19 pandemic.

Pathogens on Shoes and Hair

Hair and shoes may act as vehicles for pathogen transmission. In a study that simulated contamination of uncovered skin in health care workers after intubating manikins in respiratory distress, 8 (100%) had fluorescent markers on the hair, 6 (75%) on the neck, and 4 (50%) on the shoes.1 In another study of postsurgical operating room (OR) surfaces (517 cultures), uncovered shoe tops and reusable hair coverings had 10-times more bacterial colony–forming units compared to other surfaces. On average, disposable shoe covers/head coverings had less than one-third bacterial colony–forming units compared with uncovered shoes/reusable hair coverings.2

Hair characteristics and coverings may affect pathogen transmission. Exposed hair may collect bacteria, as Staphylococcus aureus and Staphylococcus epidermidis attach to both scalp and facial hair. In one case, β-hemolytic streptococci cultured from the scalp of a perioperative nurse was linked to postsurgical infections in 20 patients.3 Hair coverings include bouffant caps and skullcaps. The bouffant cap is similar to a shower cap; it is relatively loose and secured around the head with elastic. The skullcap, or scrub cap, is tighter but leaves the neck nape and sideburns exposed. In a study comparing disposable bouffant caps, disposable skullcaps, and home-laundered cloth skullcaps worn by 2 teams of 5 surgeons, the disposable bouffant caps had the highest permeability, penetration, and microbial shed of airborne particles.4

Physicians’ shoes may act as fomites for transmission of pathogens to patients. In a study of 41 physicians and nurses in an acute care hospital, shoe soles were positive for at least one pathogen in 12 (29.3%) participants; methicillin-resistant Staphylococcus aureus was most common. Additionally, 98% (49/50) of shoes worn outdoors showed positive bacterial cultures compared to 56% (28/50) of shoes reserved for the OR only.5 In a study examining ventilation effects on airborne pathogens in the OR, 15% of OR airborne bacteria originated from OR floors, and higher bacterial counts correlated with a higher number of steps in the OR.2 In another study designed to evaluate SARS-CoV-2 distribution on hospital floors, 70% (7/10) of quantitative polymerase chain reaction assays performed on floor samples from intensive care units were positive. In addition, 100% (3/3) of swabs taken from hospital pharmacy floors with no COVID-19 patients were positive for SARS-CoV-2, meaning contaminated shoes likely served as vectors.6 Middle East respiratory syndrome, SARS-CoV-2, and influenza viruses may survive on porous and nonporous materials for hours to days.7Enterococcus, Candida, and Aspergillus may survive on textiles for up to 90 days.3

Recommendations for Hair and Shoe Coverings

We recommend that physicians utilize disposable skullcaps to cover the hair and consider a hooded gown or coverall for neck/ear coverage. We also recommend that physicians designate shoes that remain in the workplace and can be easily washed or disinfected at least weekly; physicians may choose to wash or disinfect shoes more often if they frequently are performing procedures that generate aerosols. Additionally, physicians should always wear shoe coverings when caring for patients (Table 1).

Our hair and shoe covering recommendations may serve to protect dermatologists when caring for patients. These protocols may be particularly important for dermatologists performing high-risk procedures, including facial surgery, intraoral/intranasal procedures, and treatment with ablative lasers and facial injectables, especially when the patient is unmasked. These recommendations may limit viral transmission to dermatologists and also protect individuals living in their households. Additional established guidelines by the American Academy of Dermatology, American Society for Dermatologic Surgery, and World Health Organization are listed in Table 2.8-10

Current PPE recommendations that do not include hair and shoe coverings may be inadequate for limiting SARS-CoV-2 exposure between and among physicians and patients. Adherence to head covering and shoe recommendations may aid in reducing unwanted SARS-CoV-2 transmission in the health care setting, even as the pandemic continues.

 

Personal protective equipment (PPE) is an important component in limiting transmission of SARS-CoV-2. The World Health Organization and Centers for Disease Control and Prevention issued guidelines for appropriate PPE use, but recommendations for head and shoe coverings are lacking. In this article, we analyze the literature on pathogen transmission via hair and shoes and make evidence-based recommendations for PPE selection during the COVID-19 pandemic.

Pathogens on Shoes and Hair

Hair and shoes may act as vehicles for pathogen transmission. In a study that simulated contamination of uncovered skin in health care workers after intubating manikins in respiratory distress, 8 (100%) had fluorescent markers on the hair, 6 (75%) on the neck, and 4 (50%) on the shoes.1 In another study of postsurgical operating room (OR) surfaces (517 cultures), uncovered shoe tops and reusable hair coverings had 10-times more bacterial colony–forming units compared to other surfaces. On average, disposable shoe covers/head coverings had less than one-third bacterial colony–forming units compared with uncovered shoes/reusable hair coverings.2

Hair characteristics and coverings may affect pathogen transmission. Exposed hair may collect bacteria, as Staphylococcus aureus and Staphylococcus epidermidis attach to both scalp and facial hair. In one case, β-hemolytic streptococci cultured from the scalp of a perioperative nurse was linked to postsurgical infections in 20 patients.3 Hair coverings include bouffant caps and skullcaps. The bouffant cap is similar to a shower cap; it is relatively loose and secured around the head with elastic. The skullcap, or scrub cap, is tighter but leaves the neck nape and sideburns exposed. In a study comparing disposable bouffant caps, disposable skullcaps, and home-laundered cloth skullcaps worn by 2 teams of 5 surgeons, the disposable bouffant caps had the highest permeability, penetration, and microbial shed of airborne particles.4

Physicians’ shoes may act as fomites for transmission of pathogens to patients. In a study of 41 physicians and nurses in an acute care hospital, shoe soles were positive for at least one pathogen in 12 (29.3%) participants; methicillin-resistant Staphylococcus aureus was most common. Additionally, 98% (49/50) of shoes worn outdoors showed positive bacterial cultures compared to 56% (28/50) of shoes reserved for the OR only.5 In a study examining ventilation effects on airborne pathogens in the OR, 15% of OR airborne bacteria originated from OR floors, and higher bacterial counts correlated with a higher number of steps in the OR.2 In another study designed to evaluate SARS-CoV-2 distribution on hospital floors, 70% (7/10) of quantitative polymerase chain reaction assays performed on floor samples from intensive care units were positive. In addition, 100% (3/3) of swabs taken from hospital pharmacy floors with no COVID-19 patients were positive for SARS-CoV-2, meaning contaminated shoes likely served as vectors.6 Middle East respiratory syndrome, SARS-CoV-2, and influenza viruses may survive on porous and nonporous materials for hours to days.7Enterococcus, Candida, and Aspergillus may survive on textiles for up to 90 days.3

Recommendations for Hair and Shoe Coverings

We recommend that physicians utilize disposable skullcaps to cover the hair and consider a hooded gown or coverall for neck/ear coverage. We also recommend that physicians designate shoes that remain in the workplace and can be easily washed or disinfected at least weekly; physicians may choose to wash or disinfect shoes more often if they frequently are performing procedures that generate aerosols. Additionally, physicians should always wear shoe coverings when caring for patients (Table 1).

Our hair and shoe covering recommendations may serve to protect dermatologists when caring for patients. These protocols may be particularly important for dermatologists performing high-risk procedures, including facial surgery, intraoral/intranasal procedures, and treatment with ablative lasers and facial injectables, especially when the patient is unmasked. These recommendations may limit viral transmission to dermatologists and also protect individuals living in their households. Additional established guidelines by the American Academy of Dermatology, American Society for Dermatologic Surgery, and World Health Organization are listed in Table 2.8-10

Current PPE recommendations that do not include hair and shoe coverings may be inadequate for limiting SARS-CoV-2 exposure between and among physicians and patients. Adherence to head covering and shoe recommendations may aid in reducing unwanted SARS-CoV-2 transmission in the health care setting, even as the pandemic continues.

References
  1. Feldman O, Meir M, Shavit D, et al. Exposure to a surrogate measure of contamination from simulated patients by emergency department personnel wearing personal protective equipment. JAMA. 2020;323:2091-2093. doi:10.1001/jama.2020.6633
  2. Alexander JW, Van Sweringen H, Vanoss K, et al. Surveillance of bacterial colonization in operating rooms. Surg Infect (Larchmt). 2013;14:345-351. doi:10.1089/sur.2012.134
  3. Blanchard J. Clinical issues—August 2010. AORN Journal. 2010;92:228-232. doi:10.1016/j.aorn.2010.06.001 
  4. Markel TA, Gormley T, Greeley D, et al. Hats off: a study of different operating room headgear assessed by environmental quality indicators. J Am Coll Surg. 2017;225:573-581. doi:10.1016/j.jamcollsurg.2017.08.014
  5. Kanwar A, Thakur M, Wazzan M, et al. Clothing and shoes of personnel as potential vectors for transfer of health care-associated pathogens to the community. Am J Infect Control. 2019;47:577-579. doi:10.1016/j.ajic.2019.01.028
  6. Guo ZD, Wang ZY, Zhang SF, et al. Aerosol and surface distribution of severe acute respiratory syndrome coronavirus 2 in hospital wards, Wuhan, China, 2020. Emerg Infect Dis. 2020;26:1583-1591. doi:10.3201/eid2607.200885
  7. Otter JA, Donskey C, Yezli S, et al. Transmission of SARS and MERS coronaviruses and influenza virus in healthcare settings: the possible role of dry surface contamination. J Hosp Infect. 2016;92:235-250. doi:10.1016/j.jhin.2015.08.027
  8. Centers for Disease Control and Prevention. Science Brief: SARS-CoV-2 and Surface (Fomite) Transmission for Indoor Community Environments. https://www.cdc.gov/coronavirus/2019-ncov/more/science-and-research/surface-transmission.html#ref10
  9. American Academy of Dermatology. Clinical guidance for COVID-19. Accessed March 15, 2021. https://www.aad.org/member/practice/coronavirus/clinical-guidance
  10. Narla S, Alam M, Ozog DM, et al. American Society of Dermatologic Surgery Association (ASDSA) and American Society for Laser Medicine & Surgery (ASLMS) guidance for cosmetic dermatology practices during COVID-19. Updated January 11, 2021. Accessed March 15, 2021. https://www.asds.net/Portals/0/PDF/asdsa/asdsa-aslms-cosmetic-reopening-guidance.pdf
  11. World Health Organization. Country & technical guidance—coronavirus disease (COVID-19). Accessed March 15, 2021. https://www.who.int/emergencies/diseases/novel-coronavirus-2019/technical-guidance-publications
References
  1. Feldman O, Meir M, Shavit D, et al. Exposure to a surrogate measure of contamination from simulated patients by emergency department personnel wearing personal protective equipment. JAMA. 2020;323:2091-2093. doi:10.1001/jama.2020.6633
  2. Alexander JW, Van Sweringen H, Vanoss K, et al. Surveillance of bacterial colonization in operating rooms. Surg Infect (Larchmt). 2013;14:345-351. doi:10.1089/sur.2012.134
  3. Blanchard J. Clinical issues—August 2010. AORN Journal. 2010;92:228-232. doi:10.1016/j.aorn.2010.06.001 
  4. Markel TA, Gormley T, Greeley D, et al. Hats off: a study of different operating room headgear assessed by environmental quality indicators. J Am Coll Surg. 2017;225:573-581. doi:10.1016/j.jamcollsurg.2017.08.014
  5. Kanwar A, Thakur M, Wazzan M, et al. Clothing and shoes of personnel as potential vectors for transfer of health care-associated pathogens to the community. Am J Infect Control. 2019;47:577-579. doi:10.1016/j.ajic.2019.01.028
  6. Guo ZD, Wang ZY, Zhang SF, et al. Aerosol and surface distribution of severe acute respiratory syndrome coronavirus 2 in hospital wards, Wuhan, China, 2020. Emerg Infect Dis. 2020;26:1583-1591. doi:10.3201/eid2607.200885
  7. Otter JA, Donskey C, Yezli S, et al. Transmission of SARS and MERS coronaviruses and influenza virus in healthcare settings: the possible role of dry surface contamination. J Hosp Infect. 2016;92:235-250. doi:10.1016/j.jhin.2015.08.027
  8. Centers for Disease Control and Prevention. Science Brief: SARS-CoV-2 and Surface (Fomite) Transmission for Indoor Community Environments. https://www.cdc.gov/coronavirus/2019-ncov/more/science-and-research/surface-transmission.html#ref10
  9. American Academy of Dermatology. Clinical guidance for COVID-19. Accessed March 15, 2021. https://www.aad.org/member/practice/coronavirus/clinical-guidance
  10. Narla S, Alam M, Ozog DM, et al. American Society of Dermatologic Surgery Association (ASDSA) and American Society for Laser Medicine & Surgery (ASLMS) guidance for cosmetic dermatology practices during COVID-19. Updated January 11, 2021. Accessed March 15, 2021. https://www.asds.net/Portals/0/PDF/asdsa/asdsa-aslms-cosmetic-reopening-guidance.pdf
  11. World Health Organization. Country & technical guidance—coronavirus disease (COVID-19). Accessed March 15, 2021. https://www.who.int/emergencies/diseases/novel-coronavirus-2019/technical-guidance-publications
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Practice Points

  • Consistent use of personal protective equipment, including masks, face shields, goggles, and gloves, may limit transmission of SARS-CoV-2.
  • Hair and shoes also may transmit SARS-CoV-2, but recommendations for hair and shoe coverings to prevent SARS-CoV-2 are lacking.
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Comparison of Dermatologist Ratings on Health Care–Specific and General Consumer Websites

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Article
Changed
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Author(s)
Bukhtawar Waqas, BA
Victoria Cooley, MS
Shari R. Lipner, MD, PhD

Health care–specific (eg, Healthgrades, Zocdoc, Vitals, WebMD) and general consumer websites (eg, Google, Yelp) are popular platforms for patients to find physicians, schedule appointments, and review physician experiences. Patients find ratings on these websites more trustworthy than standardized surveys distributed by hospitals, but many physicians do not trust the reviews on these sites. For example, in a survey of both physicians (n=828) and patients (n=494), 36% of physicians trusted online reviews compared to 57% of patients.1 The objective of this study was to determine if health care–specific or general consumer websites more accurately reflect overall patient sentiment. This knowledge can help physicians who are seeking to improve the patient experience understand which websites have more accurate and trustworthy reviews.

Methods

A list of dermatologists from the top 10 most and least dermatologist–dense areas in the United States was compiled to examine different physician populations.2 Equal numbers of male and female dermatologists were randomly selected from the most dense areas. All physicians were included from the least dense areas because of limited sample size. Ratings were collected from websites most likely to appear on the first page of a Google search for a physician name, as these are most likely to be seen by patients. Descriptive statistics were generated to describe the study population; mean and median physician rating (using a scale of 1–5); SD; and minimum, maximum, and interquartile ranges. Spearman correlation coefficients were generated to examine the strength of association between ratings from website pairs. P<.05 was considered statistically significant, with analyses performed in R (3.6.2) for Windows (the R Foundation).

Results

A total of 167 representative physicians were included in this analysis; 141 from the most dense areas, and 26 from the least dense areas. The lowest average ratings for the entire sample and most dermatologist–dense areas were found on Yelp (3.61 and 3.60, respectively), and the lowest ratings in the least dermatologist–dense areas were found on Google (3.45)(Table 1). Correlation coefficient values were lowest for Zocdoc and Healthgrades (0.263) and highest for Vitals and WebMD (0.963)(Table 2). The health care–specific sites were closer to the overall average (4.06) than the general consumer sites (eFigure).

Comment

Although dermatologist ratings on each site had a broad range, we found that patients typically expressed negative interactions on general consumer websites rather than health care–specific websites. When comparing the ratings of the same group of dermatologists across different sites, ratings on health care–specific sites had a higher degree of correlation, with physician ratings more similar between 2 health care–specific sites and less similar between a health care–specific and a general consumer website. This pattern was consistent in both dermatologist-dense and dermatologist-poor areas, despite patients having varying levels of access to dermatologic care and medical resources and potentially different regional preferences of consumer websites. Taken together, these findings imply that health care–specific websites more consistently reflect overall patient sentiment.

Although one 2016 study comparing reviews of dermatology practices on Zocdoc and Yelp also demonstrated lower average ratings on Yelp,3 our study suggests that this trend is not isolated to these 2 sites but can be seen when comparing many health care–specific sites vs general consumer sites.

Our study compared ratings of dermatologists among popular websites to understand those that are most representative of patient attitudes toward physicians. These findings are important because online reviews reflect the entire patient experience, not just the patient-physician interaction, which may explain why physician scores on standardized questionnaires, such as Press Ganey surveys, do not correlate well with their online reviews.4 In a study comparing 98 physicians with negative online ratings to 82 physicians in similar departments with positive ratings, there was no significant difference in scores on patient-physician interaction questions on the Press Ganey survey.5 However, physicians who received negative online reviews scored lower on Press Ganey questions related to nonphysician interactions (eg, office cleanliness, interactions with staff).

The current study was subject to several limitations. Our analysis included all physicians in our random selection without accounting for those physicians with a greater online presence who might be more cognizant of these ratings and try to manipulate them through a reputation-management company or public relations consultant.

Conclusion

Our study suggests that consumer websites are not primarily used by disgruntled patients wishing to express grievances; instead, on average, most physicians received positive reviews. Furthermore, health care–specific websites show a higher degree of concordance than and may more accurately reflect overall patient attitudes toward their physicians than general consumer sites. Reviews from these health care–specific sites may be more helpful than general consumer websites in allowing physicians to understand patient sentiment and improve patient experiences.

References
  1. Frost C, Mesfin A. Online reviews of orthopedic surgeons: an emerging trend. Orthopedics. 2015;38:e257-e262. doi:10.3928/01477447-20150402-52
  2. Waqas B, Cooley V, Lipner SR. Association of sex, location, and experience with online patient ratings of dermatologists. J Am Acad Dermatol. 2020;83:954-955.
  3. Smith RJ, Lipoff JB. Evaluation of dermatology practice online reviews: lessons from qualitative analysis. JAMA Dermatol. 2016;152:153-157. doi:10.1001/jamadermatol.2015.3950
  4. Chen J, Presson A, Zhang C, et al. Online physician review websites poorly correlate to a validated metric of patient satisfaction. J Surg Res. 2018;227:1-6.
  5. Widmer RJ, Maurer MJ, Nayar VR, et al. Online physician reviews do not reflect patient satisfaction survey responses. Mayo Clinic Proc. 2018;93:453-457.
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Author and Disclosure Information

From Weill Cornell Medical College, New York, New York. Ms. Cooley is from the Clinical and Translational Science Center. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

Funding partially supported by a Clinical and Translational Science Center grant at Weill Cornell Medical College (1-UL1-TR002384-01).

The eFigure is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

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Bukhtawar Waqas, BA
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Shari R. Lipner, MD, PhD
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Victoria Cooley, MS
Shari R. Lipner, MD, PhD
Author and Disclosure Information

From Weill Cornell Medical College, New York, New York. Ms. Cooley is from the Clinical and Translational Science Center. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

Funding partially supported by a Clinical and Translational Science Center grant at Weill Cornell Medical College (1-UL1-TR002384-01).

The eFigure is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

Author and Disclosure Information

From Weill Cornell Medical College, New York, New York. Ms. Cooley is from the Clinical and Translational Science Center. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

Funding partially supported by a Clinical and Translational Science Center grant at Weill Cornell Medical College (1-UL1-TR002384-01).

The eFigure is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

Article PDF
CT107004181.PDF
Article PDF
CT107004181.PDF

Health care–specific (eg, Healthgrades, Zocdoc, Vitals, WebMD) and general consumer websites (eg, Google, Yelp) are popular platforms for patients to find physicians, schedule appointments, and review physician experiences. Patients find ratings on these websites more trustworthy than standardized surveys distributed by hospitals, but many physicians do not trust the reviews on these sites. For example, in a survey of both physicians (n=828) and patients (n=494), 36% of physicians trusted online reviews compared to 57% of patients.1 The objective of this study was to determine if health care–specific or general consumer websites more accurately reflect overall patient sentiment. This knowledge can help physicians who are seeking to improve the patient experience understand which websites have more accurate and trustworthy reviews.

Methods

A list of dermatologists from the top 10 most and least dermatologist–dense areas in the United States was compiled to examine different physician populations.2 Equal numbers of male and female dermatologists were randomly selected from the most dense areas. All physicians were included from the least dense areas because of limited sample size. Ratings were collected from websites most likely to appear on the first page of a Google search for a physician name, as these are most likely to be seen by patients. Descriptive statistics were generated to describe the study population; mean and median physician rating (using a scale of 1–5); SD; and minimum, maximum, and interquartile ranges. Spearman correlation coefficients were generated to examine the strength of association between ratings from website pairs. P<.05 was considered statistically significant, with analyses performed in R (3.6.2) for Windows (the R Foundation).

Results

A total of 167 representative physicians were included in this analysis; 141 from the most dense areas, and 26 from the least dense areas. The lowest average ratings for the entire sample and most dermatologist–dense areas were found on Yelp (3.61 and 3.60, respectively), and the lowest ratings in the least dermatologist–dense areas were found on Google (3.45)(Table 1). Correlation coefficient values were lowest for Zocdoc and Healthgrades (0.263) and highest for Vitals and WebMD (0.963)(Table 2). The health care–specific sites were closer to the overall average (4.06) than the general consumer sites (eFigure).

Comment

Although dermatologist ratings on each site had a broad range, we found that patients typically expressed negative interactions on general consumer websites rather than health care–specific websites. When comparing the ratings of the same group of dermatologists across different sites, ratings on health care–specific sites had a higher degree of correlation, with physician ratings more similar between 2 health care–specific sites and less similar between a health care–specific and a general consumer website. This pattern was consistent in both dermatologist-dense and dermatologist-poor areas, despite patients having varying levels of access to dermatologic care and medical resources and potentially different regional preferences of consumer websites. Taken together, these findings imply that health care–specific websites more consistently reflect overall patient sentiment.

Although one 2016 study comparing reviews of dermatology practices on Zocdoc and Yelp also demonstrated lower average ratings on Yelp,3 our study suggests that this trend is not isolated to these 2 sites but can be seen when comparing many health care–specific sites vs general consumer sites.

Our study compared ratings of dermatologists among popular websites to understand those that are most representative of patient attitudes toward physicians. These findings are important because online reviews reflect the entire patient experience, not just the patient-physician interaction, which may explain why physician scores on standardized questionnaires, such as Press Ganey surveys, do not correlate well with their online reviews.4 In a study comparing 98 physicians with negative online ratings to 82 physicians in similar departments with positive ratings, there was no significant difference in scores on patient-physician interaction questions on the Press Ganey survey.5 However, physicians who received negative online reviews scored lower on Press Ganey questions related to nonphysician interactions (eg, office cleanliness, interactions with staff).

The current study was subject to several limitations. Our analysis included all physicians in our random selection without accounting for those physicians with a greater online presence who might be more cognizant of these ratings and try to manipulate them through a reputation-management company or public relations consultant.

Conclusion

Our study suggests that consumer websites are not primarily used by disgruntled patients wishing to express grievances; instead, on average, most physicians received positive reviews. Furthermore, health care–specific websites show a higher degree of concordance than and may more accurately reflect overall patient attitudes toward their physicians than general consumer sites. Reviews from these health care–specific sites may be more helpful than general consumer websites in allowing physicians to understand patient sentiment and improve patient experiences.

Health care–specific (eg, Healthgrades, Zocdoc, Vitals, WebMD) and general consumer websites (eg, Google, Yelp) are popular platforms for patients to find physicians, schedule appointments, and review physician experiences. Patients find ratings on these websites more trustworthy than standardized surveys distributed by hospitals, but many physicians do not trust the reviews on these sites. For example, in a survey of both physicians (n=828) and patients (n=494), 36% of physicians trusted online reviews compared to 57% of patients.1 The objective of this study was to determine if health care–specific or general consumer websites more accurately reflect overall patient sentiment. This knowledge can help physicians who are seeking to improve the patient experience understand which websites have more accurate and trustworthy reviews.

Methods

A list of dermatologists from the top 10 most and least dermatologist–dense areas in the United States was compiled to examine different physician populations.2 Equal numbers of male and female dermatologists were randomly selected from the most dense areas. All physicians were included from the least dense areas because of limited sample size. Ratings were collected from websites most likely to appear on the first page of a Google search for a physician name, as these are most likely to be seen by patients. Descriptive statistics were generated to describe the study population; mean and median physician rating (using a scale of 1–5); SD; and minimum, maximum, and interquartile ranges. Spearman correlation coefficients were generated to examine the strength of association between ratings from website pairs. P<.05 was considered statistically significant, with analyses performed in R (3.6.2) for Windows (the R Foundation).

Results

A total of 167 representative physicians were included in this analysis; 141 from the most dense areas, and 26 from the least dense areas. The lowest average ratings for the entire sample and most dermatologist–dense areas were found on Yelp (3.61 and 3.60, respectively), and the lowest ratings in the least dermatologist–dense areas were found on Google (3.45)(Table 1). Correlation coefficient values were lowest for Zocdoc and Healthgrades (0.263) and highest for Vitals and WebMD (0.963)(Table 2). The health care–specific sites were closer to the overall average (4.06) than the general consumer sites (eFigure).

Comment

Although dermatologist ratings on each site had a broad range, we found that patients typically expressed negative interactions on general consumer websites rather than health care–specific websites. When comparing the ratings of the same group of dermatologists across different sites, ratings on health care–specific sites had a higher degree of correlation, with physician ratings more similar between 2 health care–specific sites and less similar between a health care–specific and a general consumer website. This pattern was consistent in both dermatologist-dense and dermatologist-poor areas, despite patients having varying levels of access to dermatologic care and medical resources and potentially different regional preferences of consumer websites. Taken together, these findings imply that health care–specific websites more consistently reflect overall patient sentiment.

Although one 2016 study comparing reviews of dermatology practices on Zocdoc and Yelp also demonstrated lower average ratings on Yelp,3 our study suggests that this trend is not isolated to these 2 sites but can be seen when comparing many health care–specific sites vs general consumer sites.

Our study compared ratings of dermatologists among popular websites to understand those that are most representative of patient attitudes toward physicians. These findings are important because online reviews reflect the entire patient experience, not just the patient-physician interaction, which may explain why physician scores on standardized questionnaires, such as Press Ganey surveys, do not correlate well with their online reviews.4 In a study comparing 98 physicians with negative online ratings to 82 physicians in similar departments with positive ratings, there was no significant difference in scores on patient-physician interaction questions on the Press Ganey survey.5 However, physicians who received negative online reviews scored lower on Press Ganey questions related to nonphysician interactions (eg, office cleanliness, interactions with staff).

The current study was subject to several limitations. Our analysis included all physicians in our random selection without accounting for those physicians with a greater online presence who might be more cognizant of these ratings and try to manipulate them through a reputation-management company or public relations consultant.

Conclusion

Our study suggests that consumer websites are not primarily used by disgruntled patients wishing to express grievances; instead, on average, most physicians received positive reviews. Furthermore, health care–specific websites show a higher degree of concordance than and may more accurately reflect overall patient attitudes toward their physicians than general consumer sites. Reviews from these health care–specific sites may be more helpful than general consumer websites in allowing physicians to understand patient sentiment and improve patient experiences.

References
  1. Frost C, Mesfin A. Online reviews of orthopedic surgeons: an emerging trend. Orthopedics. 2015;38:e257-e262. doi:10.3928/01477447-20150402-52
  2. Waqas B, Cooley V, Lipner SR. Association of sex, location, and experience with online patient ratings of dermatologists. J Am Acad Dermatol. 2020;83:954-955.
  3. Smith RJ, Lipoff JB. Evaluation of dermatology practice online reviews: lessons from qualitative analysis. JAMA Dermatol. 2016;152:153-157. doi:10.1001/jamadermatol.2015.3950
  4. Chen J, Presson A, Zhang C, et al. Online physician review websites poorly correlate to a validated metric of patient satisfaction. J Surg Res. 2018;227:1-6.
  5. Widmer RJ, Maurer MJ, Nayar VR, et al. Online physician reviews do not reflect patient satisfaction survey responses. Mayo Clinic Proc. 2018;93:453-457.
References
  1. Frost C, Mesfin A. Online reviews of orthopedic surgeons: an emerging trend. Orthopedics. 2015;38:e257-e262. doi:10.3928/01477447-20150402-52
  2. Waqas B, Cooley V, Lipner SR. Association of sex, location, and experience with online patient ratings of dermatologists. J Am Acad Dermatol. 2020;83:954-955.
  3. Smith RJ, Lipoff JB. Evaluation of dermatology practice online reviews: lessons from qualitative analysis. JAMA Dermatol. 2016;152:153-157. doi:10.1001/jamadermatol.2015.3950
  4. Chen J, Presson A, Zhang C, et al. Online physician review websites poorly correlate to a validated metric of patient satisfaction. J Surg Res. 2018;227:1-6.
  5. Widmer RJ, Maurer MJ, Nayar VR, et al. Online physician reviews do not reflect patient satisfaction survey responses. Mayo Clinic Proc. 2018;93:453-457.
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  • Online physician-rating websites are commonly used by patients to find physicians and review experiences.
  • Health care–specific sites may more accurately reflect patient sentiment than general consumer sites.
  • Dermatologists can use health care–specific sites to understand patient sentiment and learn how to improve patient experiences.
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Are There Mobile Applications Related to Nail Disorders?

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Changed
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Stephanie Ishack, PhD
Shari R. Lipner, MD, PhD

The use of mobile devices in health care settings has enhanced clinical practice through real-time communication and direct patient monitoring.1 With advancements in technology, improving the accessibility and quality of patient care using mobile devices is a hot topic. In 2018, 261.34 million people worldwide used smartphones compared to 280.54 million in 2021—a 7.3% increase.2 Revenue from sales of mobile applications (apps) is projected to reach $693 billion in 2021.3

A range of apps targeted to patients is available for acne, melanoma, and teledermatology.4-6 Nail disorders are a common concern, representing 21.1 million outpatient visits in 2007 to 2016,7 but, to date, the availability of apps related to nail disorders has not been explored. In this study, we investigated iOS (Apple’s iPhone Operating System) and Android apps to determine the types of nail health apps that are available, using psoriasis and hair loss apps as comparator groups.

Methods

A standard app analytics and market data tool (App Annie; https://www.appannie.com/en/) was utilized to search for iOS and Android nail mobile apps.4,5 The analysis was performed on a single day (March 23, 2020), given that app searches can change on a daily basis. Our search included the following keywords: nail, nail health, toenail fungus, nail tumor, brittle nails, onychomycosis, onycholysis, subungual melanoma, nail melanoma, paronychia, and nail squamous cell carcinoma. App Annie app descriptions were assessed to determine the type of each app (Lifestyle, Medical, Health & Fitness) and target audience (patient, physician, or both). Psoriasis and hair loss topics were chosen as controls for comparison, based on a prior study.8 For psoriasis, the keywords psoriasis and chronic skin disease were searched. Hair loss was searched using the keywords alopecia, hair loss, hair health, and scalp.

Results

Nail-Related Apps
Using keywords for nail-related terms on iOS and Android platforms, our search returned few specific and informative apps related to nail disorders (Table 1). When the terms brittle nails, nail, nail health, nail squamous cell carcinoma, and nail tumor were searched, all available nail apps were either nail games or virtual nail salons for entertainment purposes. For the terms nail melanoma and subungual melanoma, there were no specific nail apps that appeared in the search results; rather, the App Annie search yielded only general dermatology and melanoma apps. The terms onycholysis and paronychia both yielded 0 hits for iOS and Android.

The only search terms that returned specific nail apps were onychomycosis and toenail fungus. Initially, when onychomycosis was searched, only 1 Google Play Medical category app was found: “Nail fungal infection (model onychomycosis).” Although this app recently was removed from the app store, it previously allowed the user to upload a nail photograph, with which a computing algorithm assessed whether the presentation was a fungal nail infection. Toenail fungus returned 1 iOS Medical category app and 5 Android Health & Fitness category apps with reference material for patients. Neither of the 2 medical apps for onychomycosis and toenail fungus referenced a physician involved in the app development.

Psoriasis Comparator
On the contrary, a search for psoriasis yielded 22 hits for iOS and 34 hits for Android within the Health & Fitness, Medical, and Social Networking categories (Table 2). The search term chronic skin disease returned 18 apps for iOS and 60 apps for Android related to psoriasis; 100% were classified as Medical apps.



Hair Loss Comparator
Search terms related to hair conditions—specifically, alopecia—yielded 0 apps for iOS and 10 for Android platforms (Table 2). Using the search term hair loss, 12 apps for iOS and 50 apps for Android were found within the Health & Fitness, Medical, and Beauty categories. The search terms hair health and hair loss resulted in 2 and 12 apps in both iOS and Android, respectively. In addition, the search term scalp was associated with 6 related apps in iOS and 7 in Android, both in the Health & Fitness and Medical categories.



Other Findings
Most apps for psoriasis and hair health were identified as patient focused. Although iOS and Android are different operating systems, some health apps overlapped: subungual melanoma and toenail fungus had a 20% overlap; psoriasis, 19%; chronic skin disease, 2%; alopecia, 0%; hair loss and hair health, 10%; and scalp, 18%. iOS and Android nail entertainment games had approximately a 30% overlap. Tables 1 and 2 also compare the number of free and paid apps; most available apps were free.

 

 

Comment

With continued growth in mobile device ownership and app development has been parallel growth in the creation and use of apps to enhance medical care.1 In a study analyzing the most popular dermatology apps, 62% (18/29) and 38% (11/29) of apps targeted patients and physicians, respectively.6 Our study showed that (1) there are few nail disorder apps available for patient education and (2) there is no evidence that a physician was consulted for content input. Because patients who can effectively communicate their health concerns before and after seeing a physician have better self-reported clinical outcomes,9 it is important to have nail disorder apps available to patients for referencing. The nail health app options differ notably from psoriasis and hair loss apps, with apps for the latter 2 topics found in Medical and Health & Fitness categories—targeting patients who seek immediate access to health care and education.

Although there are several general dermatology apps that contain reference information for patients pertaining to nail conditions,6 using any of those apps would require a patient to have prior knowledge that dermatologists specialize in nail disorders and necessitate several steps to find nail-relevant information. For example, the patient would have to search dermatology in the iOS and Android app stores, select the available app (eg, Dermatology Database), and then search within that app for nail disorders. Therefore, a patient who is concerned about a possible subungual melanoma would not be able to easily find clinical images and explanations using an app.



Study Limitations
This study was subject to several limitations. Android and iOS app stores have undisclosed computing algorithms that might have filtered apps based on specific word inquiry. Also, our queries were based on specific relevant keywords for nail conditions, psoriasis, and hair loss; use of different keywords might have yielded different results. Additionally, app options change on a daily basis, so a search today (ie, any given day) might yield slightly different results than it did on March 23, 2020.

Conclusion

Specific nail disorder apps available for patient reference are limited. App developers should consider accessibility (ie, clear language, ease of use, cost-effectiveness, usability on iOS- and Android-operated devices) and content (accurate medical information from experts) when considering new apps. A solution to this problem is for established medical organizations to create nail disorder apps specifically for patients.10 For example, the American Academy of Dermatology has iOS and Android apps that are relevant to physicians (MyDermPath+, Dialogues in Dermatology, Mohs Surgery Appropriate Use Criteria) but no comparable apps for patients; patient-appropriate nail apps are necessary.11 In addition, it would be beneficial to patients if established app companies consulted with dermatologists on pertinent nail content.

In sum, we found few available nail health apps on the iOS or Android platforms that provided accessible and timely information to patients regarding nail disorders. There is an immediate need to produce apps related to nail health for appropriate patient education.

References
  1. Wallace S, Clark M, White J. ‘It’s on my iPhone’: attitudes to the use of mobile computing devices in medical education, a mixed-methods study. BMJ Open. 2012;2:e001099.
  2. O’Dea S. Number of smartphone users in the United States from 2018 to 2024 (in millions). Statista website. April 21, 2020. Accessed February 19, 2021. https://www.statista.com/statistics/201182/forecast-of-smartphone-users-in-the-us/
  3. Clement J. Worldwide mobile app revenues in 2014 to 2023. Statista website. Published February 4, 2021. Accessed February 19, 2021.https://www.statista.com/statistics/269025/worldwide-mobile-app-revenue-forecast/
  4. Poushter J, Bishop C, Chwe H. Social media use continues to rise in developing countries but plateaus across developed ones. Pew Research Center Washington DC. Published June 19, 2018. Accessed February 19, 2021. https://www.pewresearch.org/global/2018/06/19/social-media-use-continues-to-rise-in-developing-countries-but-plateaus-across-developed-ones/
  5. Flaten HK, St Claire C, Schlager E, et al. Growth of mobile applications in dermatology—2017 update. Dermatol Online J. 2018 February;24:1-4. Accessed February 19, 2021. https://escholarship.org/uc/item/3hs7n9z6
  6. Tongdee E, Markowitz O. Mobile app rankings in dermatology. Cutis. 2018;102:252-256.
  7. Lipner SR, Hancock J, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatol Treat. doi:10.1080/09546634.2019
  8. Gu L, Lipner SR. Analysis of education on nail conditions at the American Academy of Dermatology annual meetings. Cutis. 2020;105:259-260.
  9. King A, Hoppe RB. “Best practice” for patient-centered communication: a narrative review. J Grad Med Educ. 2013;3:385-393.
  10. Larson RS. A path to better-quality mHealth apps. JMIR Mhealth Uhealth. 2018;6:E10414.
  11. Academy apps. American Academy of Dermatology website. Accessed February 19, 2021. https://www.aad.org/member/publications/apps
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Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Shari R. Lipner, MD, PhD
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Shari R. Lipner, MD, PhD
Author and Disclosure Information

Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Author and Disclosure Information

Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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The use of mobile devices in health care settings has enhanced clinical practice through real-time communication and direct patient monitoring.1 With advancements in technology, improving the accessibility and quality of patient care using mobile devices is a hot topic. In 2018, 261.34 million people worldwide used smartphones compared to 280.54 million in 2021—a 7.3% increase.2 Revenue from sales of mobile applications (apps) is projected to reach $693 billion in 2021.3

A range of apps targeted to patients is available for acne, melanoma, and teledermatology.4-6 Nail disorders are a common concern, representing 21.1 million outpatient visits in 2007 to 2016,7 but, to date, the availability of apps related to nail disorders has not been explored. In this study, we investigated iOS (Apple’s iPhone Operating System) and Android apps to determine the types of nail health apps that are available, using psoriasis and hair loss apps as comparator groups.

Methods

A standard app analytics and market data tool (App Annie; https://www.appannie.com/en/) was utilized to search for iOS and Android nail mobile apps.4,5 The analysis was performed on a single day (March 23, 2020), given that app searches can change on a daily basis. Our search included the following keywords: nail, nail health, toenail fungus, nail tumor, brittle nails, onychomycosis, onycholysis, subungual melanoma, nail melanoma, paronychia, and nail squamous cell carcinoma. App Annie app descriptions were assessed to determine the type of each app (Lifestyle, Medical, Health & Fitness) and target audience (patient, physician, or both). Psoriasis and hair loss topics were chosen as controls for comparison, based on a prior study.8 For psoriasis, the keywords psoriasis and chronic skin disease were searched. Hair loss was searched using the keywords alopecia, hair loss, hair health, and scalp.

Results

Nail-Related Apps
Using keywords for nail-related terms on iOS and Android platforms, our search returned few specific and informative apps related to nail disorders (Table 1). When the terms brittle nails, nail, nail health, nail squamous cell carcinoma, and nail tumor were searched, all available nail apps were either nail games or virtual nail salons for entertainment purposes. For the terms nail melanoma and subungual melanoma, there were no specific nail apps that appeared in the search results; rather, the App Annie search yielded only general dermatology and melanoma apps. The terms onycholysis and paronychia both yielded 0 hits for iOS and Android.

The only search terms that returned specific nail apps were onychomycosis and toenail fungus. Initially, when onychomycosis was searched, only 1 Google Play Medical category app was found: “Nail fungal infection (model onychomycosis).” Although this app recently was removed from the app store, it previously allowed the user to upload a nail photograph, with which a computing algorithm assessed whether the presentation was a fungal nail infection. Toenail fungus returned 1 iOS Medical category app and 5 Android Health & Fitness category apps with reference material for patients. Neither of the 2 medical apps for onychomycosis and toenail fungus referenced a physician involved in the app development.

Psoriasis Comparator
On the contrary, a search for psoriasis yielded 22 hits for iOS and 34 hits for Android within the Health & Fitness, Medical, and Social Networking categories (Table 2). The search term chronic skin disease returned 18 apps for iOS and 60 apps for Android related to psoriasis; 100% were classified as Medical apps.



Hair Loss Comparator
Search terms related to hair conditions—specifically, alopecia—yielded 0 apps for iOS and 10 for Android platforms (Table 2). Using the search term hair loss, 12 apps for iOS and 50 apps for Android were found within the Health & Fitness, Medical, and Beauty categories. The search terms hair health and hair loss resulted in 2 and 12 apps in both iOS and Android, respectively. In addition, the search term scalp was associated with 6 related apps in iOS and 7 in Android, both in the Health & Fitness and Medical categories.



Other Findings
Most apps for psoriasis and hair health were identified as patient focused. Although iOS and Android are different operating systems, some health apps overlapped: subungual melanoma and toenail fungus had a 20% overlap; psoriasis, 19%; chronic skin disease, 2%; alopecia, 0%; hair loss and hair health, 10%; and scalp, 18%. iOS and Android nail entertainment games had approximately a 30% overlap. Tables 1 and 2 also compare the number of free and paid apps; most available apps were free.

 

 

Comment

With continued growth in mobile device ownership and app development has been parallel growth in the creation and use of apps to enhance medical care.1 In a study analyzing the most popular dermatology apps, 62% (18/29) and 38% (11/29) of apps targeted patients and physicians, respectively.6 Our study showed that (1) there are few nail disorder apps available for patient education and (2) there is no evidence that a physician was consulted for content input. Because patients who can effectively communicate their health concerns before and after seeing a physician have better self-reported clinical outcomes,9 it is important to have nail disorder apps available to patients for referencing. The nail health app options differ notably from psoriasis and hair loss apps, with apps for the latter 2 topics found in Medical and Health & Fitness categories—targeting patients who seek immediate access to health care and education.

Although there are several general dermatology apps that contain reference information for patients pertaining to nail conditions,6 using any of those apps would require a patient to have prior knowledge that dermatologists specialize in nail disorders and necessitate several steps to find nail-relevant information. For example, the patient would have to search dermatology in the iOS and Android app stores, select the available app (eg, Dermatology Database), and then search within that app for nail disorders. Therefore, a patient who is concerned about a possible subungual melanoma would not be able to easily find clinical images and explanations using an app.



Study Limitations
This study was subject to several limitations. Android and iOS app stores have undisclosed computing algorithms that might have filtered apps based on specific word inquiry. Also, our queries were based on specific relevant keywords for nail conditions, psoriasis, and hair loss; use of different keywords might have yielded different results. Additionally, app options change on a daily basis, so a search today (ie, any given day) might yield slightly different results than it did on March 23, 2020.

Conclusion

Specific nail disorder apps available for patient reference are limited. App developers should consider accessibility (ie, clear language, ease of use, cost-effectiveness, usability on iOS- and Android-operated devices) and content (accurate medical information from experts) when considering new apps. A solution to this problem is for established medical organizations to create nail disorder apps specifically for patients.10 For example, the American Academy of Dermatology has iOS and Android apps that are relevant to physicians (MyDermPath+, Dialogues in Dermatology, Mohs Surgery Appropriate Use Criteria) but no comparable apps for patients; patient-appropriate nail apps are necessary.11 In addition, it would be beneficial to patients if established app companies consulted with dermatologists on pertinent nail content.

In sum, we found few available nail health apps on the iOS or Android platforms that provided accessible and timely information to patients regarding nail disorders. There is an immediate need to produce apps related to nail health for appropriate patient education.

The use of mobile devices in health care settings has enhanced clinical practice through real-time communication and direct patient monitoring.1 With advancements in technology, improving the accessibility and quality of patient care using mobile devices is a hot topic. In 2018, 261.34 million people worldwide used smartphones compared to 280.54 million in 2021—a 7.3% increase.2 Revenue from sales of mobile applications (apps) is projected to reach $693 billion in 2021.3

A range of apps targeted to patients is available for acne, melanoma, and teledermatology.4-6 Nail disorders are a common concern, representing 21.1 million outpatient visits in 2007 to 2016,7 but, to date, the availability of apps related to nail disorders has not been explored. In this study, we investigated iOS (Apple’s iPhone Operating System) and Android apps to determine the types of nail health apps that are available, using psoriasis and hair loss apps as comparator groups.

Methods

A standard app analytics and market data tool (App Annie; https://www.appannie.com/en/) was utilized to search for iOS and Android nail mobile apps.4,5 The analysis was performed on a single day (March 23, 2020), given that app searches can change on a daily basis. Our search included the following keywords: nail, nail health, toenail fungus, nail tumor, brittle nails, onychomycosis, onycholysis, subungual melanoma, nail melanoma, paronychia, and nail squamous cell carcinoma. App Annie app descriptions were assessed to determine the type of each app (Lifestyle, Medical, Health & Fitness) and target audience (patient, physician, or both). Psoriasis and hair loss topics were chosen as controls for comparison, based on a prior study.8 For psoriasis, the keywords psoriasis and chronic skin disease were searched. Hair loss was searched using the keywords alopecia, hair loss, hair health, and scalp.

Results

Nail-Related Apps
Using keywords for nail-related terms on iOS and Android platforms, our search returned few specific and informative apps related to nail disorders (Table 1). When the terms brittle nails, nail, nail health, nail squamous cell carcinoma, and nail tumor were searched, all available nail apps were either nail games or virtual nail salons for entertainment purposes. For the terms nail melanoma and subungual melanoma, there were no specific nail apps that appeared in the search results; rather, the App Annie search yielded only general dermatology and melanoma apps. The terms onycholysis and paronychia both yielded 0 hits for iOS and Android.

The only search terms that returned specific nail apps were onychomycosis and toenail fungus. Initially, when onychomycosis was searched, only 1 Google Play Medical category app was found: “Nail fungal infection (model onychomycosis).” Although this app recently was removed from the app store, it previously allowed the user to upload a nail photograph, with which a computing algorithm assessed whether the presentation was a fungal nail infection. Toenail fungus returned 1 iOS Medical category app and 5 Android Health & Fitness category apps with reference material for patients. Neither of the 2 medical apps for onychomycosis and toenail fungus referenced a physician involved in the app development.

Psoriasis Comparator
On the contrary, a search for psoriasis yielded 22 hits for iOS and 34 hits for Android within the Health & Fitness, Medical, and Social Networking categories (Table 2). The search term chronic skin disease returned 18 apps for iOS and 60 apps for Android related to psoriasis; 100% were classified as Medical apps.



Hair Loss Comparator
Search terms related to hair conditions—specifically, alopecia—yielded 0 apps for iOS and 10 for Android platforms (Table 2). Using the search term hair loss, 12 apps for iOS and 50 apps for Android were found within the Health & Fitness, Medical, and Beauty categories. The search terms hair health and hair loss resulted in 2 and 12 apps in both iOS and Android, respectively. In addition, the search term scalp was associated with 6 related apps in iOS and 7 in Android, both in the Health & Fitness and Medical categories.



Other Findings
Most apps for psoriasis and hair health were identified as patient focused. Although iOS and Android are different operating systems, some health apps overlapped: subungual melanoma and toenail fungus had a 20% overlap; psoriasis, 19%; chronic skin disease, 2%; alopecia, 0%; hair loss and hair health, 10%; and scalp, 18%. iOS and Android nail entertainment games had approximately a 30% overlap. Tables 1 and 2 also compare the number of free and paid apps; most available apps were free.

 

 

Comment

With continued growth in mobile device ownership and app development has been parallel growth in the creation and use of apps to enhance medical care.1 In a study analyzing the most popular dermatology apps, 62% (18/29) and 38% (11/29) of apps targeted patients and physicians, respectively.6 Our study showed that (1) there are few nail disorder apps available for patient education and (2) there is no evidence that a physician was consulted for content input. Because patients who can effectively communicate their health concerns before and after seeing a physician have better self-reported clinical outcomes,9 it is important to have nail disorder apps available to patients for referencing. The nail health app options differ notably from psoriasis and hair loss apps, with apps for the latter 2 topics found in Medical and Health & Fitness categories—targeting patients who seek immediate access to health care and education.

Although there are several general dermatology apps that contain reference information for patients pertaining to nail conditions,6 using any of those apps would require a patient to have prior knowledge that dermatologists specialize in nail disorders and necessitate several steps to find nail-relevant information. For example, the patient would have to search dermatology in the iOS and Android app stores, select the available app (eg, Dermatology Database), and then search within that app for nail disorders. Therefore, a patient who is concerned about a possible subungual melanoma would not be able to easily find clinical images and explanations using an app.



Study Limitations
This study was subject to several limitations. Android and iOS app stores have undisclosed computing algorithms that might have filtered apps based on specific word inquiry. Also, our queries were based on specific relevant keywords for nail conditions, psoriasis, and hair loss; use of different keywords might have yielded different results. Additionally, app options change on a daily basis, so a search today (ie, any given day) might yield slightly different results than it did on March 23, 2020.

Conclusion

Specific nail disorder apps available for patient reference are limited. App developers should consider accessibility (ie, clear language, ease of use, cost-effectiveness, usability on iOS- and Android-operated devices) and content (accurate medical information from experts) when considering new apps. A solution to this problem is for established medical organizations to create nail disorder apps specifically for patients.10 For example, the American Academy of Dermatology has iOS and Android apps that are relevant to physicians (MyDermPath+, Dialogues in Dermatology, Mohs Surgery Appropriate Use Criteria) but no comparable apps for patients; patient-appropriate nail apps are necessary.11 In addition, it would be beneficial to patients if established app companies consulted with dermatologists on pertinent nail content.

In sum, we found few available nail health apps on the iOS or Android platforms that provided accessible and timely information to patients regarding nail disorders. There is an immediate need to produce apps related to nail health for appropriate patient education.

References
  1. Wallace S, Clark M, White J. ‘It’s on my iPhone’: attitudes to the use of mobile computing devices in medical education, a mixed-methods study. BMJ Open. 2012;2:e001099.
  2. O’Dea S. Number of smartphone users in the United States from 2018 to 2024 (in millions). Statista website. April 21, 2020. Accessed February 19, 2021. https://www.statista.com/statistics/201182/forecast-of-smartphone-users-in-the-us/
  3. Clement J. Worldwide mobile app revenues in 2014 to 2023. Statista website. Published February 4, 2021. Accessed February 19, 2021.https://www.statista.com/statistics/269025/worldwide-mobile-app-revenue-forecast/
  4. Poushter J, Bishop C, Chwe H. Social media use continues to rise in developing countries but plateaus across developed ones. Pew Research Center Washington DC. Published June 19, 2018. Accessed February 19, 2021. https://www.pewresearch.org/global/2018/06/19/social-media-use-continues-to-rise-in-developing-countries-but-plateaus-across-developed-ones/
  5. Flaten HK, St Claire C, Schlager E, et al. Growth of mobile applications in dermatology—2017 update. Dermatol Online J. 2018 February;24:1-4. Accessed February 19, 2021. https://escholarship.org/uc/item/3hs7n9z6
  6. Tongdee E, Markowitz O. Mobile app rankings in dermatology. Cutis. 2018;102:252-256.
  7. Lipner SR, Hancock J, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatol Treat. doi:10.1080/09546634.2019
  8. Gu L, Lipner SR. Analysis of education on nail conditions at the American Academy of Dermatology annual meetings. Cutis. 2020;105:259-260.
  9. King A, Hoppe RB. “Best practice” for patient-centered communication: a narrative review. J Grad Med Educ. 2013;3:385-393.
  10. Larson RS. A path to better-quality mHealth apps. JMIR Mhealth Uhealth. 2018;6:E10414.
  11. Academy apps. American Academy of Dermatology website. Accessed February 19, 2021. https://www.aad.org/member/publications/apps
References
  1. Wallace S, Clark M, White J. ‘It’s on my iPhone’: attitudes to the use of mobile computing devices in medical education, a mixed-methods study. BMJ Open. 2012;2:e001099.
  2. O’Dea S. Number of smartphone users in the United States from 2018 to 2024 (in millions). Statista website. April 21, 2020. Accessed February 19, 2021. https://www.statista.com/statistics/201182/forecast-of-smartphone-users-in-the-us/
  3. Clement J. Worldwide mobile app revenues in 2014 to 2023. Statista website. Published February 4, 2021. Accessed February 19, 2021.https://www.statista.com/statistics/269025/worldwide-mobile-app-revenue-forecast/
  4. Poushter J, Bishop C, Chwe H. Social media use continues to rise in developing countries but plateaus across developed ones. Pew Research Center Washington DC. Published June 19, 2018. Accessed February 19, 2021. https://www.pewresearch.org/global/2018/06/19/social-media-use-continues-to-rise-in-developing-countries-but-plateaus-across-developed-ones/
  5. Flaten HK, St Claire C, Schlager E, et al. Growth of mobile applications in dermatology—2017 update. Dermatol Online J. 2018 February;24:1-4. Accessed February 19, 2021. https://escholarship.org/uc/item/3hs7n9z6
  6. Tongdee E, Markowitz O. Mobile app rankings in dermatology. Cutis. 2018;102:252-256.
  7. Lipner SR, Hancock J, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatol Treat. doi:10.1080/09546634.2019
  8. Gu L, Lipner SR. Analysis of education on nail conditions at the American Academy of Dermatology annual meetings. Cutis. 2020;105:259-260.
  9. King A, Hoppe RB. “Best practice” for patient-centered communication: a narrative review. J Grad Med Educ. 2013;3:385-393.
  10. Larson RS. A path to better-quality mHealth apps. JMIR Mhealth Uhealth. 2018;6:E10414.
  11. Academy apps. American Academy of Dermatology website. Accessed February 19, 2021. https://www.aad.org/member/publications/apps
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  • There are patient-directed psoriasis and hair loss apps on iOS and Android platforms, but informative apps related to nail disorders are limited.
  • There is a need to develop apps related to nail health for patient education.
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Onychomycosis: New Developments in Diagnosis, Treatment, and Antifungal Medication Safety

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Shari R. Lipner, MD, PhD

Onychomycosis is the most prevalent nail condition worldwide and has a significant impact on quality of life.1 There were 10 million physician visits for nail fungal infections in the National Ambulatory Medical Care Survey from 2007 to 2016, which was more than double the number of all other nail diagnoses combined.2 Therefore, it is important for dermatologists to be familiar with the most current data on diagnosis and treatment of this extremely common nail disease as well as antifungal medication safety.

Onychomycosis Diagnosis

Diagnosis of onychomycosis using clinical examination alone has poor sensitivity and specificity and may lead to progression of disease and unwanted side effects from inappropriate therapy.3,4 Dermoscopy is a useful adjunct but diagnostically is still inferior compared to mycologic testing.5 Classical methods of diagnosis include potassium hydroxide staining with microscopy, fungal culture, and histopathology. Polymerase chain reaction is a newer technique with wide accessibility and excellent sensitivity and specificity.6 Although these techniques have excellent diagnostic accuracy both alone and in combination, the ideal test would have 100% sensitivity and specificity and would not require nail sampling. Artificial intelligence recently has been studied for the diagnosis of onychomycosis. In a prospective study of 90 patients with onychodystrophy who had photographs of the nails taken by nonphysicians, deep neural networks showed comparable sensitivity (70.2% vs 73.0%) and specificity (72.7% vs 49.7%) for diagnosis of onychomycosis vs clinical examination by dermatologists with a mean of 5.6 years of experience.7 Therefore, artificial intelligence may be considered as a supplement to clinical examination for dermatology residents and junior attending dermatologists and may be superior to clinical examination by nondermatologists, but mycologic confirmation is still necessary before initiating onychomycosis treatment.

Treatment of Onychomycosis

There are 3 topical therapies (ciclopirox lacquer 8%, efinaconazole solution 10%, and tavaborole solution 5%) and 3 oral therapies (terbinafine, itraconazole, and griseofulvin) that are approved by the US Food and Drug Administration for onychomycosis therapy. Griseofulvin rarely is used due to the availability of more efficacious treatment options. Fluconazole is an off-label treatment that often is used in the United States.8

There are new data on the efficacy and safety of topical onychomycosis treatments in children. A phase 4 open‐label study of efinaconazole solution 10% applied once daily for 48 weeks was performed in children aged 6 to 16 years with distal lateral subungual onychomycosis (N=62).9,10 The medication was both well tolerated and safe in children. The only treatment-related adverse event was onychocryptosis, which was reported by 2 patients. At week 52, mycologic cure was 65% and complete cure was 40% (N=50). In a pharmacokinetic assessment performed in a subset of 17 patients aged 12 to 16 years, efinaconazole was measured at very low levels in plasma.9

A phase 4 open-label study also was performed to evaluate the safety, pharmacokinetics, and efficacy of tavaborole for treatment of distal lateral subungual onychomycosis in children aged 6 years to under 17 years (N=55).11 Tavaborole solution 5% was applied once daily for 48 weeks; at week 52, mycologic and complete cures were 36.2% and 8.5%, respectively (N=47). Systemic exposure was low (Cmax=5.9 ng/mL [day 29]) in a subset of patients aged 12 years to under 17 years (N=37), and the medication demonstrated good safety and tolerability.11

Fosravuconazole was approved for treatment of onychomycosis in Japan in 2018. In a randomized, double-blind, phase 3 trial of oral fosravuconazole 100 mg once daily (n=101) vs placebo (n=52) for 12 weeks in patients with onychomycosis (mean age, 58.4 years), the complete cure rate at 48 weeks was 59.4%.12 In a small trial of 37 elderly patients (mean age, 78.1 years), complete cure rates were 5.0% in patients with a nail plate thickness of 3 mm or greater and 58.8% in those with a thickness lessthan 3 mm, and there were no severe adverse events.13 In addition to excellent efficacy and proven safety in elderly adults, the main advantage of fosravuconazole is less-potent inhibition of cytochrome P450 3A compared to other triazole antifungals, with no contraindicated drugs listed.

Safety of Antifungals

There are new data describing the safety of oral terbinafine in pregnant women and immunosuppressed patients. In a nationwide cohort study conducted in Denmark (1,650,649 pregnancies [942 oral terbinafine exposed, 9420 unexposed matched cohorts]), there was no association between oral or topical terbinafine exposure during pregnancy and risk of preterm birth, small-for-gestational-age birth weight, low birth weight, or stillbirth.14 In a small study of 13 kidney transplant recipients taking oral tacrolimus, cyclosporine, or everolimus who were treated with oral terbinafine, there were no severe drug interactions and no clinical consequences in renal grafts.15

There also is new information on laboratory abnormalities in adults, children, and patients with comorbidities who are taking oral terbinafine. In a retrospective study of 944 adult patients without pre-existing hepatic or hematologic conditions who were prescribed 3 months of oral terbinafine for onychomycosis, abnormal monitoring liver function tests (LFTs) and complete blood cell counts (CBCs) were uncommon (2.4% and 2.8%, respectively) and mild and resolved after treatment completion. In addition, patients with laboratory abnormalities were an average of 14.8 years older and approximately 3-times more likely to be 65 years or older compared to the overall study population.16 There were similar findings in a retrospective study of 134 children 18 years or younger who were prescribed oral terbinafine for superficial fungal infections. Abnormal monitoring LFTs and CBCs were uncommon (1.7% and 4.4%, respectively) and mild, resolving after after treatment completion.17 Finally, in a study of 255 patients with a pre-existing liver or hematologic condition who were prescribed oral terbinafine for onychomycosis, worsening of LFT or CBC values were rare, and all resolved after treatment completion or medication discontinuation.18

Final Thoughts

Mycologic confirmation is still necessary before treatment despite encouraging data on use of artificial intelligence for diagnosis of onychomycosis. Efinaconazole solution 10% and tavaborole solution 5% have shown good safety, tolerability, and efficacy in children with onychomycosis. Recent data suggest the safety of oral terbinafine in pregnant women and kidney transplant recipients, but these findings must be corroborated before its use in these populations. Fosravuconazole is a promising systemic treatment for onychomycosis with no drug-drug interactions reported to date. While baseline laboratory testing is recommended before prescribing terbinafine, interval laboratory monitoring may not be necessary in healthy adults.19 Prospective studies are necessary to corroborate these findings before formal recommendations can be made for prescribing terbinafine in the special populations discussed above, including children, and for interval laboratory monitoring.

References
  1. Stewart CR, Algu L, Kamran R, et al. Effect of onychomycosis and treatment on patient-reported quality-of-life outcomes: a systematic review [published online June 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.05.143 
  2. Lipner SR, Hancock JE, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatolog Treat. doi:10.1080/09546634.2019.1679337 
  3. Lipner SR, Scher RK. Onychomycosis--a small step for quality of care. Curr Med Res Opin. 2016;32:865-867. 
  4. Lipner SR, Scher RK. Confirmatory testing for onychomycosis. JAMA Dermatol. 2016;152:847. 
  5. Piraccini BM, Balestri R, Starace M, et al. Nail digital dermoscopy (onychoscopy) in the diagnosis of onychomycosis. J Eur Acad Dermatol Venereol. 2013;27:509-513. 
  6. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851. 
  7. Kim YJ, Han SS, Yang HJ, et al. Prospective, comparative evaluation of a deep neural network and dermoscopy in the diagnosis of onychomycosis. PLoS One. 2020;15:e0234334. 
  8. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867. 
  9. Eichenfield LF, Elewski B, Sugarman JL, et al. Efinaconazole 10% topical solution for the treatment of onychomycosis in pediatric patients: open-label phase 4 study [published online July 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.06.1004 
  10. Eichenfield LF, Elewski B, Sugarman JL, et al. Safety, pharmacokinetics, and efficacy of efinaconazole 10% topical solution for onychomycosis treatment in pediatric patients. J Drugs Dermatol. 2020;19:867-872.  
  11. Rich P, Spellman M, Purohit V, et al. Tavaborole 5% topical solution for the treatment of toenail onychomycosis in pediatric patients: results from a phase 4 open-label study. J Drugs Dermatol. 2019;18:190-195. 
  12. Watanabe S, Tsubouchi I, Okubo A. Efficacy and safety of fosravuconazole L-lysine ethanolate, a novel oral triazole antifungal agent, for the treatment of onychomycosis: a multicenter, double-blind, randomized phase III study. J Dermatol. 2018;45:1151-1159. 
  13. Noguchi H, Matsumoto T, Kimura U, et al. Fosravuconazole to treat severe onychomycosis in the elderly [published online October 25, 2020]. J Dermatol. doi:10.1111/1346-8138.15651 
  14. Andersson NW, Thomsen SF, Andersen JT. Exposure to terbinafine in pregnancy and risk of preterm birth, small for gestational age, low birth weight, and stillbirth: a nationwide cohort study [published online October 22, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.10.034  
  15. Moreno-Sabater A, Ouali N, Chasset F, et al. Severe onychomycosis management with oral terbinafine in a kidney transplantation setting: clinical follow-up by image analysis [published online November 27, 2020]. Mycoses. doi:10.1111/myc.13220 
  16. Wang Y, Geizhals S, Lipner SR. Retrospective analysis of laboratory abnormalities in patients prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:497-499. 
  17. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in pediatric patients prescribed terbinafine for superficial fungal infections [published online January 27, 2021]. J Am Acad Dermatol. doi:10.1016/j.jaad.2021.01.073 
  18. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in patients with preexisting liver and hematologic diseases prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:220-221. 
  19. Lamisil. Prescribing information. Novartis Pharmaceuticals Corporation; 2010. https://www.accessdata.fda.gov/drugsatfda_docs/label/2010/022071s003lbl.pdf
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The author reports no conflict of interest.

Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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From the Department of Dermatology, Weill Cornell Medicine, New York, New York.

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Correspondence: Shari R. Lipner MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Onychomycosis is the most prevalent nail condition worldwide and has a significant impact on quality of life.1 There were 10 million physician visits for nail fungal infections in the National Ambulatory Medical Care Survey from 2007 to 2016, which was more than double the number of all other nail diagnoses combined.2 Therefore, it is important for dermatologists to be familiar with the most current data on diagnosis and treatment of this extremely common nail disease as well as antifungal medication safety.

Onychomycosis Diagnosis

Diagnosis of onychomycosis using clinical examination alone has poor sensitivity and specificity and may lead to progression of disease and unwanted side effects from inappropriate therapy.3,4 Dermoscopy is a useful adjunct but diagnostically is still inferior compared to mycologic testing.5 Classical methods of diagnosis include potassium hydroxide staining with microscopy, fungal culture, and histopathology. Polymerase chain reaction is a newer technique with wide accessibility and excellent sensitivity and specificity.6 Although these techniques have excellent diagnostic accuracy both alone and in combination, the ideal test would have 100% sensitivity and specificity and would not require nail sampling. Artificial intelligence recently has been studied for the diagnosis of onychomycosis. In a prospective study of 90 patients with onychodystrophy who had photographs of the nails taken by nonphysicians, deep neural networks showed comparable sensitivity (70.2% vs 73.0%) and specificity (72.7% vs 49.7%) for diagnosis of onychomycosis vs clinical examination by dermatologists with a mean of 5.6 years of experience.7 Therefore, artificial intelligence may be considered as a supplement to clinical examination for dermatology residents and junior attending dermatologists and may be superior to clinical examination by nondermatologists, but mycologic confirmation is still necessary before initiating onychomycosis treatment.

Treatment of Onychomycosis

There are 3 topical therapies (ciclopirox lacquer 8%, efinaconazole solution 10%, and tavaborole solution 5%) and 3 oral therapies (terbinafine, itraconazole, and griseofulvin) that are approved by the US Food and Drug Administration for onychomycosis therapy. Griseofulvin rarely is used due to the availability of more efficacious treatment options. Fluconazole is an off-label treatment that often is used in the United States.8

There are new data on the efficacy and safety of topical onychomycosis treatments in children. A phase 4 open‐label study of efinaconazole solution 10% applied once daily for 48 weeks was performed in children aged 6 to 16 years with distal lateral subungual onychomycosis (N=62).9,10 The medication was both well tolerated and safe in children. The only treatment-related adverse event was onychocryptosis, which was reported by 2 patients. At week 52, mycologic cure was 65% and complete cure was 40% (N=50). In a pharmacokinetic assessment performed in a subset of 17 patients aged 12 to 16 years, efinaconazole was measured at very low levels in plasma.9

A phase 4 open-label study also was performed to evaluate the safety, pharmacokinetics, and efficacy of tavaborole for treatment of distal lateral subungual onychomycosis in children aged 6 years to under 17 years (N=55).11 Tavaborole solution 5% was applied once daily for 48 weeks; at week 52, mycologic and complete cures were 36.2% and 8.5%, respectively (N=47). Systemic exposure was low (Cmax=5.9 ng/mL [day 29]) in a subset of patients aged 12 years to under 17 years (N=37), and the medication demonstrated good safety and tolerability.11

Fosravuconazole was approved for treatment of onychomycosis in Japan in 2018. In a randomized, double-blind, phase 3 trial of oral fosravuconazole 100 mg once daily (n=101) vs placebo (n=52) for 12 weeks in patients with onychomycosis (mean age, 58.4 years), the complete cure rate at 48 weeks was 59.4%.12 In a small trial of 37 elderly patients (mean age, 78.1 years), complete cure rates were 5.0% in patients with a nail plate thickness of 3 mm or greater and 58.8% in those with a thickness lessthan 3 mm, and there were no severe adverse events.13 In addition to excellent efficacy and proven safety in elderly adults, the main advantage of fosravuconazole is less-potent inhibition of cytochrome P450 3A compared to other triazole antifungals, with no contraindicated drugs listed.

Safety of Antifungals

There are new data describing the safety of oral terbinafine in pregnant women and immunosuppressed patients. In a nationwide cohort study conducted in Denmark (1,650,649 pregnancies [942 oral terbinafine exposed, 9420 unexposed matched cohorts]), there was no association between oral or topical terbinafine exposure during pregnancy and risk of preterm birth, small-for-gestational-age birth weight, low birth weight, or stillbirth.14 In a small study of 13 kidney transplant recipients taking oral tacrolimus, cyclosporine, or everolimus who were treated with oral terbinafine, there were no severe drug interactions and no clinical consequences in renal grafts.15

There also is new information on laboratory abnormalities in adults, children, and patients with comorbidities who are taking oral terbinafine. In a retrospective study of 944 adult patients without pre-existing hepatic or hematologic conditions who were prescribed 3 months of oral terbinafine for onychomycosis, abnormal monitoring liver function tests (LFTs) and complete blood cell counts (CBCs) were uncommon (2.4% and 2.8%, respectively) and mild and resolved after treatment completion. In addition, patients with laboratory abnormalities were an average of 14.8 years older and approximately 3-times more likely to be 65 years or older compared to the overall study population.16 There were similar findings in a retrospective study of 134 children 18 years or younger who were prescribed oral terbinafine for superficial fungal infections. Abnormal monitoring LFTs and CBCs were uncommon (1.7% and 4.4%, respectively) and mild, resolving after after treatment completion.17 Finally, in a study of 255 patients with a pre-existing liver or hematologic condition who were prescribed oral terbinafine for onychomycosis, worsening of LFT or CBC values were rare, and all resolved after treatment completion or medication discontinuation.18

Final Thoughts

Mycologic confirmation is still necessary before treatment despite encouraging data on use of artificial intelligence for diagnosis of onychomycosis. Efinaconazole solution 10% and tavaborole solution 5% have shown good safety, tolerability, and efficacy in children with onychomycosis. Recent data suggest the safety of oral terbinafine in pregnant women and kidney transplant recipients, but these findings must be corroborated before its use in these populations. Fosravuconazole is a promising systemic treatment for onychomycosis with no drug-drug interactions reported to date. While baseline laboratory testing is recommended before prescribing terbinafine, interval laboratory monitoring may not be necessary in healthy adults.19 Prospective studies are necessary to corroborate these findings before formal recommendations can be made for prescribing terbinafine in the special populations discussed above, including children, and for interval laboratory monitoring.

Onychomycosis is the most prevalent nail condition worldwide and has a significant impact on quality of life.1 There were 10 million physician visits for nail fungal infections in the National Ambulatory Medical Care Survey from 2007 to 2016, which was more than double the number of all other nail diagnoses combined.2 Therefore, it is important for dermatologists to be familiar with the most current data on diagnosis and treatment of this extremely common nail disease as well as antifungal medication safety.

Onychomycosis Diagnosis

Diagnosis of onychomycosis using clinical examination alone has poor sensitivity and specificity and may lead to progression of disease and unwanted side effects from inappropriate therapy.3,4 Dermoscopy is a useful adjunct but diagnostically is still inferior compared to mycologic testing.5 Classical methods of diagnosis include potassium hydroxide staining with microscopy, fungal culture, and histopathology. Polymerase chain reaction is a newer technique with wide accessibility and excellent sensitivity and specificity.6 Although these techniques have excellent diagnostic accuracy both alone and in combination, the ideal test would have 100% sensitivity and specificity and would not require nail sampling. Artificial intelligence recently has been studied for the diagnosis of onychomycosis. In a prospective study of 90 patients with onychodystrophy who had photographs of the nails taken by nonphysicians, deep neural networks showed comparable sensitivity (70.2% vs 73.0%) and specificity (72.7% vs 49.7%) for diagnosis of onychomycosis vs clinical examination by dermatologists with a mean of 5.6 years of experience.7 Therefore, artificial intelligence may be considered as a supplement to clinical examination for dermatology residents and junior attending dermatologists and may be superior to clinical examination by nondermatologists, but mycologic confirmation is still necessary before initiating onychomycosis treatment.

Treatment of Onychomycosis

There are 3 topical therapies (ciclopirox lacquer 8%, efinaconazole solution 10%, and tavaborole solution 5%) and 3 oral therapies (terbinafine, itraconazole, and griseofulvin) that are approved by the US Food and Drug Administration for onychomycosis therapy. Griseofulvin rarely is used due to the availability of more efficacious treatment options. Fluconazole is an off-label treatment that often is used in the United States.8

There are new data on the efficacy and safety of topical onychomycosis treatments in children. A phase 4 open‐label study of efinaconazole solution 10% applied once daily for 48 weeks was performed in children aged 6 to 16 years with distal lateral subungual onychomycosis (N=62).9,10 The medication was both well tolerated and safe in children. The only treatment-related adverse event was onychocryptosis, which was reported by 2 patients. At week 52, mycologic cure was 65% and complete cure was 40% (N=50). In a pharmacokinetic assessment performed in a subset of 17 patients aged 12 to 16 years, efinaconazole was measured at very low levels in plasma.9

A phase 4 open-label study also was performed to evaluate the safety, pharmacokinetics, and efficacy of tavaborole for treatment of distal lateral subungual onychomycosis in children aged 6 years to under 17 years (N=55).11 Tavaborole solution 5% was applied once daily for 48 weeks; at week 52, mycologic and complete cures were 36.2% and 8.5%, respectively (N=47). Systemic exposure was low (Cmax=5.9 ng/mL [day 29]) in a subset of patients aged 12 years to under 17 years (N=37), and the medication demonstrated good safety and tolerability.11

Fosravuconazole was approved for treatment of onychomycosis in Japan in 2018. In a randomized, double-blind, phase 3 trial of oral fosravuconazole 100 mg once daily (n=101) vs placebo (n=52) for 12 weeks in patients with onychomycosis (mean age, 58.4 years), the complete cure rate at 48 weeks was 59.4%.12 In a small trial of 37 elderly patients (mean age, 78.1 years), complete cure rates were 5.0% in patients with a nail plate thickness of 3 mm or greater and 58.8% in those with a thickness lessthan 3 mm, and there were no severe adverse events.13 In addition to excellent efficacy and proven safety in elderly adults, the main advantage of fosravuconazole is less-potent inhibition of cytochrome P450 3A compared to other triazole antifungals, with no contraindicated drugs listed.

Safety of Antifungals

There are new data describing the safety of oral terbinafine in pregnant women and immunosuppressed patients. In a nationwide cohort study conducted in Denmark (1,650,649 pregnancies [942 oral terbinafine exposed, 9420 unexposed matched cohorts]), there was no association between oral or topical terbinafine exposure during pregnancy and risk of preterm birth, small-for-gestational-age birth weight, low birth weight, or stillbirth.14 In a small study of 13 kidney transplant recipients taking oral tacrolimus, cyclosporine, or everolimus who were treated with oral terbinafine, there were no severe drug interactions and no clinical consequences in renal grafts.15

There also is new information on laboratory abnormalities in adults, children, and patients with comorbidities who are taking oral terbinafine. In a retrospective study of 944 adult patients without pre-existing hepatic or hematologic conditions who were prescribed 3 months of oral terbinafine for onychomycosis, abnormal monitoring liver function tests (LFTs) and complete blood cell counts (CBCs) were uncommon (2.4% and 2.8%, respectively) and mild and resolved after treatment completion. In addition, patients with laboratory abnormalities were an average of 14.8 years older and approximately 3-times more likely to be 65 years or older compared to the overall study population.16 There were similar findings in a retrospective study of 134 children 18 years or younger who were prescribed oral terbinafine for superficial fungal infections. Abnormal monitoring LFTs and CBCs were uncommon (1.7% and 4.4%, respectively) and mild, resolving after after treatment completion.17 Finally, in a study of 255 patients with a pre-existing liver or hematologic condition who were prescribed oral terbinafine for onychomycosis, worsening of LFT or CBC values were rare, and all resolved after treatment completion or medication discontinuation.18

Final Thoughts

Mycologic confirmation is still necessary before treatment despite encouraging data on use of artificial intelligence for diagnosis of onychomycosis. Efinaconazole solution 10% and tavaborole solution 5% have shown good safety, tolerability, and efficacy in children with onychomycosis. Recent data suggest the safety of oral terbinafine in pregnant women and kidney transplant recipients, but these findings must be corroborated before its use in these populations. Fosravuconazole is a promising systemic treatment for onychomycosis with no drug-drug interactions reported to date. While baseline laboratory testing is recommended before prescribing terbinafine, interval laboratory monitoring may not be necessary in healthy adults.19 Prospective studies are necessary to corroborate these findings before formal recommendations can be made for prescribing terbinafine in the special populations discussed above, including children, and for interval laboratory monitoring.

References
  1. Stewart CR, Algu L, Kamran R, et al. Effect of onychomycosis and treatment on patient-reported quality-of-life outcomes: a systematic review [published online June 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.05.143 
  2. Lipner SR, Hancock JE, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatolog Treat. doi:10.1080/09546634.2019.1679337 
  3. Lipner SR, Scher RK. Onychomycosis--a small step for quality of care. Curr Med Res Opin. 2016;32:865-867. 
  4. Lipner SR, Scher RK. Confirmatory testing for onychomycosis. JAMA Dermatol. 2016;152:847. 
  5. Piraccini BM, Balestri R, Starace M, et al. Nail digital dermoscopy (onychoscopy) in the diagnosis of onychomycosis. J Eur Acad Dermatol Venereol. 2013;27:509-513. 
  6. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851. 
  7. Kim YJ, Han SS, Yang HJ, et al. Prospective, comparative evaluation of a deep neural network and dermoscopy in the diagnosis of onychomycosis. PLoS One. 2020;15:e0234334. 
  8. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867. 
  9. Eichenfield LF, Elewski B, Sugarman JL, et al. Efinaconazole 10% topical solution for the treatment of onychomycosis in pediatric patients: open-label phase 4 study [published online July 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.06.1004 
  10. Eichenfield LF, Elewski B, Sugarman JL, et al. Safety, pharmacokinetics, and efficacy of efinaconazole 10% topical solution for onychomycosis treatment in pediatric patients. J Drugs Dermatol. 2020;19:867-872.  
  11. Rich P, Spellman M, Purohit V, et al. Tavaborole 5% topical solution for the treatment of toenail onychomycosis in pediatric patients: results from a phase 4 open-label study. J Drugs Dermatol. 2019;18:190-195. 
  12. Watanabe S, Tsubouchi I, Okubo A. Efficacy and safety of fosravuconazole L-lysine ethanolate, a novel oral triazole antifungal agent, for the treatment of onychomycosis: a multicenter, double-blind, randomized phase III study. J Dermatol. 2018;45:1151-1159. 
  13. Noguchi H, Matsumoto T, Kimura U, et al. Fosravuconazole to treat severe onychomycosis in the elderly [published online October 25, 2020]. J Dermatol. doi:10.1111/1346-8138.15651 
  14. Andersson NW, Thomsen SF, Andersen JT. Exposure to terbinafine in pregnancy and risk of preterm birth, small for gestational age, low birth weight, and stillbirth: a nationwide cohort study [published online October 22, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.10.034  
  15. Moreno-Sabater A, Ouali N, Chasset F, et al. Severe onychomycosis management with oral terbinafine in a kidney transplantation setting: clinical follow-up by image analysis [published online November 27, 2020]. Mycoses. doi:10.1111/myc.13220 
  16. Wang Y, Geizhals S, Lipner SR. Retrospective analysis of laboratory abnormalities in patients prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:497-499. 
  17. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in pediatric patients prescribed terbinafine for superficial fungal infections [published online January 27, 2021]. J Am Acad Dermatol. doi:10.1016/j.jaad.2021.01.073 
  18. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in patients with preexisting liver and hematologic diseases prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:220-221. 
  19. Lamisil. Prescribing information. Novartis Pharmaceuticals Corporation; 2010. https://www.accessdata.fda.gov/drugsatfda_docs/label/2010/022071s003lbl.pdf
References
  1. Stewart CR, Algu L, Kamran R, et al. Effect of onychomycosis and treatment on patient-reported quality-of-life outcomes: a systematic review [published online June 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.05.143 
  2. Lipner SR, Hancock JE, Fleischer AB. The ambulatory care burden of nail conditions in the United States [published online October 21, 2019]. J Dermatolog Treat. doi:10.1080/09546634.2019.1679337 
  3. Lipner SR, Scher RK. Onychomycosis--a small step for quality of care. Curr Med Res Opin. 2016;32:865-867. 
  4. Lipner SR, Scher RK. Confirmatory testing for onychomycosis. JAMA Dermatol. 2016;152:847. 
  5. Piraccini BM, Balestri R, Starace M, et al. Nail digital dermoscopy (onychoscopy) in the diagnosis of onychomycosis. J Eur Acad Dermatol Venereol. 2013;27:509-513. 
  6. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851. 
  7. Kim YJ, Han SS, Yang HJ, et al. Prospective, comparative evaluation of a deep neural network and dermoscopy in the diagnosis of onychomycosis. PLoS One. 2020;15:e0234334. 
  8. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867. 
  9. Eichenfield LF, Elewski B, Sugarman JL, et al. Efinaconazole 10% topical solution for the treatment of onychomycosis in pediatric patients: open-label phase 4 study [published online July 2, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.06.1004 
  10. Eichenfield LF, Elewski B, Sugarman JL, et al. Safety, pharmacokinetics, and efficacy of efinaconazole 10% topical solution for onychomycosis treatment in pediatric patients. J Drugs Dermatol. 2020;19:867-872.  
  11. Rich P, Spellman M, Purohit V, et al. Tavaborole 5% topical solution for the treatment of toenail onychomycosis in pediatric patients: results from a phase 4 open-label study. J Drugs Dermatol. 2019;18:190-195. 
  12. Watanabe S, Tsubouchi I, Okubo A. Efficacy and safety of fosravuconazole L-lysine ethanolate, a novel oral triazole antifungal agent, for the treatment of onychomycosis: a multicenter, double-blind, randomized phase III study. J Dermatol. 2018;45:1151-1159. 
  13. Noguchi H, Matsumoto T, Kimura U, et al. Fosravuconazole to treat severe onychomycosis in the elderly [published online October 25, 2020]. J Dermatol. doi:10.1111/1346-8138.15651 
  14. Andersson NW, Thomsen SF, Andersen JT. Exposure to terbinafine in pregnancy and risk of preterm birth, small for gestational age, low birth weight, and stillbirth: a nationwide cohort study [published online October 22, 2020]. J Am Acad Dermatol. doi:10.1016/j.jaad.2020.10.034  
  15. Moreno-Sabater A, Ouali N, Chasset F, et al. Severe onychomycosis management with oral terbinafine in a kidney transplantation setting: clinical follow-up by image analysis [published online November 27, 2020]. Mycoses. doi:10.1111/myc.13220 
  16. Wang Y, Geizhals S, Lipner SR. Retrospective analysis of laboratory abnormalities in patients prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:497-499. 
  17. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in pediatric patients prescribed terbinafine for superficial fungal infections [published online January 27, 2021]. J Am Acad Dermatol. doi:10.1016/j.jaad.2021.01.073 
  18. Wang Y, Lipner SR. Retrospective analysis of laboratory abnormalities in patients with preexisting liver and hematologic diseases prescribed terbinafine for onychomycosis. J Am Acad Dermatol. 2021;84:220-221. 
  19. Lamisil. Prescribing information. Novartis Pharmaceuticals Corporation; 2010. https://www.accessdata.fda.gov/drugsatfda_docs/label/2010/022071s003lbl.pdf
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Perception of Executive Order on Medicare Pay for Advanced Practice Providers: A Study of Comments From Medical Professionals

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Claire R. Stewart, BA
Shari R. Lipner, MD, PhD

The ability of advanced practice providers (APPs) to practice independently has been a recent topic of discussion among both the medical community and legislatures. Advanced practice provider is an umbrella term that includes physician assistants (PAs) and advanced practice registered nurses, including nurse practitioners (NPs), clinical nurse specialists, certified nurse-midwives, and certified registered nurse anesthetists. Since Congress passed the Balanced Budget Act of 1997, APPs can bill and be paid independently if they are not practicing incident to a physician or in a facility.1 Currently, NPs can practice independently in 27 states and Washington, DC. Physician assistants are required to practice under the supervision of a physician; however, the extent of supervision varies by state.2 Advocates for broadening the scope of practice for APPs argue that NPs and PAs will help to fill the physician deficit, particularly in primary care and rural regions. It has been projected that by 2025, the United States will require an additional 46,000 primary care providers to meet growing medical needs.3

On October 3, 2019, President Donald Trump issued the Executive Order on Protecting and Improving Medicare for Our Nation’s Seniors, in which he proposed an alternative to “Medicare for all.”4 This order instructed the Secretary of Health and Human Services to prepare a regulation that would “eliminate burdensome regulatory billing requirements, conditions of participation, supervision requirements, benefit definitions and all other licensure requirements . . . that are more stringent than applicable Federal or State laws require and that limit professionals from practicing at the top of their field.” Furthermore, President Trump proposed that “services provided by clinicians, including physicians, physician assistants, and nurse practitioners, are appropriately reimbursed in accordance with the work performed rather than the clinician’s occupation.”4

In response to the executive order, members of the medical community utilized Reddit, an online public forum, and Medscape, a medical news website, to vocalize opinions on the executive order.5,6 Our goal was to analyze the characteristics of those who participated in the discussion and their points of view on the plan to broaden the scope of practice and change the Medicare reimbursement plans for APPs.

Methods

All comments on the October 3, 2019, Medscape article, “Trump Executive Order Seeks Proposals on Medicare Pay for NPs, PAs,”5 and the corresponding Reddit discussion on this article6 were reviewed and characterized by the type of commenter—doctor of medicine (MD)/doctor of osteopathic medicine (DO), NP/RN/certified registered nurse anesthetist, PA, medical student, PA student, NP student, pharmacist, dietician, emergency medical technician, scribe, or unknown—as identified in their username, title, or in the text of the comment. Gender of the commenter was recorded when provided. Commenters were further grouped by their support or lack of support for the executive order based on their comments. Patients’ comments underwent further qualitative analysis to identify general themes.

All analyses were conducted with RStudio statistical software. Analyses were reported as proportions. Variables were compared by χ2 and Fisher exact tests. Odds ratios with 95% CIs were calculated. P<.05 was considered statistically significant.

Results

A total of 352 comments (130 on Medscape and 222 on Reddit) posted by 155 unique users (57 on Medscape and 98 on Reddit) were included in the analysis (Table 1). Of the 51 Medscape commenters who identified a gender, 60.7% were male and 39.2% were female. Reddit commenters did not identify a gender. Commenters included MD and DO physicians (43.2%), NPs/RNs/certified registered nurse anesthetists (13.5%), medical students (11.0%), PAs (9.7%), pharmacists (3.2%), NP students (1.9%), PA students (1.3%), emergency medical technicians (1.3%), dieticians (0.6%), and scribes (0.6%). Physicians (54.5% vs 36.73%; P=.032) and NPs (22.8% vs 8.2%; P=.009) made up a larger percentage of all comments on Medscape compared to Reddit, where medical students were more prevalent (16.3% vs 1.8%; P=.005). Nursing students and PA students more commonly posted on Reddit (4.08% of Reddit commenters vs 1.75% of Medscape commenters), though this difference did not achieve statistical significance.

A majority of commenters did not support the executive order, with only 20.6% approving of the plan, 54.8% disapproving, and 24.5% remaining neutral (Figure). Advanced practice providers—NPs, PAs, NP/PA students, and APPs not otherwise specified—were more likely to support the executive order, with 52.3% voicing their support compared to only 4.8% of physicians and medical students expressing support (P<.0001). Similarly, physicians and medical students were more likely to disapprove of the order, with 75.0% voicing concerns compared to only 27.3% of APPs dissenting (P<.0001). A similar percentage of both physicians/medical students and APPs remained neutral (20.2% vs 18.2%). Commenters on Medscape were more likely to voice support for the executive order than those on Reddit (36.8% vs 11.2%; P=.0002), likely due to the higher percentage of NP and PA comments on the former.

Support for executive order by provider type (n=155). APP indicates advanced practice provider.

 

 


Overall, the most commonly discussed topic was provider reimbursement (22.6% of all comments)(Table 2). Physicians and medical students were more likely to discuss physician expertise compared to APPs (32.1% vs 4.5%; P<.001). They also were more likely to raise concerns that the executive order would discourage future generations of physicians from pursuing medicine (15.5% vs 0%; P=.01). Advanced practice providers were more likely than physicians/medical students to comment on the breadth of NP and/or PA training (38.6% vs 19.0%; P=.02). The eTable shows representative comments for each theme encountered.



A subgroup analysis of the comments written by physicians supporting the executive order (n=4) and APPs disapproving of the order (n=12) was performed to identify the dissenting opinions. Physicians who supported the order discussed the need for improved pay for equal work (n=3), the competency of NP and PA training (n=2), the ability of a practice to generate more profit from APPs (n=1), and possible benefits of APPs providing primary care while MDs perform more specialized care (n=1). Of the APPs who did not support the order, there were 4 PAs, 2 registered nurses, 2 NPs, 2 NP students, and 2 PA students. The most common themes discussed were the differences in APP education and training (n=6), lack of desire for further responsibilities (n=4), and the adequacy of the current scope of practice (n=3).

Comment

President Trump’s executive order follows a trend of decreasing required oversight of APPs; however, this study indicates that these policies would face pushback from many physicians. These results are consistent with a prior study that analyzed 309 comments on an article in The New York Times made by physicians, APPs, patients, and laypeople, in which 24.7% had mistrust of APPs and 14.9% had concerns over APP supervision compared to 9% who supported APP independent practice.7 It is clear that there is a serious divide in opinion that threatens to harm the existing collaborations between physicians and APPs.

Primary Care Coverage With APPs
In the comments analyzed in our study, supporters of the executive order argued that an increase in APPs practicing independently would provide much-needed primary care coverage to patients in underserved regions. However, APPs are instead well represented across most specialties, with a majority in dermatology. Of the 4 million procedures billed independently by APPs in 2012, 54.8% were in the field of dermatology.8 The employment of APPs by dermatologists has grown from 28% of practices in 2005 to 46% in 2014, making this issue of particular importance to our field.9,10

Education and Training of APPs
In our analysis, many physicians cited concerns about the education and training of APPs. Dermatologists receive approximately 10,000 hours of training over the course of residency. Per the American Academy of Physician Assistants, PAs spend more than 2000 hours over a 26-month period on various clinical rotations, “with an emphasis on primary care.”11 There are multiple routes to become an advanced practice RN with varying classroom and clinical requirements, with one pathway requiring a bachelor of science in nursing, followed by a master’s degree requiring 500 to 700 hours of supervised clinical work. Although the Dermatology Nurses’ Association and Society of Dermatology Physician Assistants (http://www.dermpa.org) provide online modules, annual conventions with training workshops, and short fellowship programs, neither have formal guidelines on minimum requirements to diagnose and treat dermatologic conditions.2 Despite the lack of formalized dermatologic training, APPs billed for 13.4% of all dermatology procedures submitted to Medicare in 2015.12

Quality of Patient Care
In our study, physicians also voiced concern over reduced quality of patient care. In a review of 33,647 skin cancer screening examinations, PAs biopsied an average of 39.4 skin lesions, while dermatologists biopsied an average of 25.4 skin lesions to diagnose 1 case of melanoma.13 In addition, nonphysician providers accounted for 37.9% of defendants in 174 legal cases related to injury from cutaneous laser surgery.14 Before further laws are enacted regarding the independent practice and billing by NPs and PAs in the field of dermatology, further research is needed to address patient outcomes and safety.

Limitations
This study was subject to several limitations. Because of a lack of other sources offering discussions on the topic, our sample size was limited. Self-identification of users presents a challenge, as an individual can pose as a physician or APP without validation of credentials. Although great care was taken to minimize bias, grouping comments into broad categories may misinterpret a poster’s intentions. Furthermore, the data collected represent only a small proportion of the medical community—readers of Medscape and Reddit who have the motivation to create a user profile and post a comment rather than put their efforts into lobbying or contacting legislators. Those posting may have stronger political opinions or more poignant experiences than the general public. Although selection bias impacts the generalizability of our findings, this analysis allows for deeper insight into the beliefs of a vocal subset of the medical community who may not have the opportunity to present their opinions elsewhere.

Conclusion

Our analysis of the response to President Trump’s executive order reveals that a rollout of these regulations would be met with strong opposition. On October 29, 2019, more than 100 professional organizations, including the American Medical Association and the American Academy of Dermatology, wrote a letter to the Secretary of Health and Human Services that eloquently echoed the sentiments of the physician commenters in this study: “Scope of practice of health care professionals should be based on standardized, adequate training and demonstrated competence in patient care, not politics. While all health care professionals share an important role in providing care to patients, their skillset is not interchangeable with that of a fully trained physician.”15 The executive order would lead to a major shift in the current medical landscape, and as such, it is prudent that these concerns are addressed.

References
  1. Balanced Budget Act of 1997, 42 USC §1395x (1997). Accessed December 15, 2020. https://www.govinfo.gov/content/pkg/PLAW-105publ33/html/PLAW-105publ33.htm
  2. State practice environment. American Association of Nurse Practitioners. Updated October 20, 2020. Accessed December 8, 2020. https://www.aanp.org/advocacy/state/state-practice-environment
  3. Petterson SM, Liaw WR, Phillips RL Jr, et al. Projecting US primary care physician workforce needs: 2010-2015. Ann Fam Med. 2012;10:503-509.
  4. United States, Executive Office of the President [Donald Trump]. Executive Order 13890: Protecting and Improving Medicare for Our Nation’s Seniors. October 3, 2019. Fed Regist. 2019;84:53573-53576.
  5. Young KD. Trump executive order seeks proposals on Medicare pay for NPs, PAs. Medscape. Published October 3, 2019. Accessed December 8, 2020. https://www.medscape.com/viewarticle/919415
  6. Trump seeks proposals on Medicare pay for NPs, PAs. Reddit. Accessed December 8, 2020. https://www.reddit.com/r/medicine/comments/ddy03w/trump_seeks_proposals_on_medicare_pay_for_nps_pas/
  7. Martin E, Huang WW, Strowd LC, et al. Public perception of ethical issues in dermatology: evidenced by New York Times commenters. Dermatol Surg. 2018;44:1571-1577.
  8. Coldiron B, Ratnarathorn M. Scope of physician procedures independently billed by mid-level providers in the office setting. JAMA Dermatol. 2014;150:1153-1159.
  9. Resneck JS Jr. Dermatology practice consolidation fueled by private equity investment: potential consequences for the specialty and patients. JAMA Dermatol. 2018;154:13-14.
  10. Ehrlich A, Kostecki J, Olkaba H. Trends in dermatology practices and the implications for the workforce. J Am Acad Dermatol. 2017;77:746-752.
  11. Become a PA. American Academy of Physician Assistants. Accessed December 8, 2020. https://www.aapa.org/career-central/become-a-pa/.
  12. Zhang M, Zippin J, Kaffenberger B. Trends and scope of dermatology procedures billed by advanced practice professionals from 2012 through 2015. JAMA Dermatol. 2018;154:1040-1044.
  13. Anderson AM, Matsumoto M, Saul MI, et al. Accuracy of skin cancer diagnosis of physician assistants compared with dermatologists in a large health care system. JAMA Dermatol. 2018;154:569-573.
  14. Jalian HR, Jalian CA, Avram MM. Common causes of injury and legal action in laser surgery. JAMA Dermatol. 2013;149:188-193.
  15. American Medical Association. Open letter to the Honorable Alex M. Azar II. Published October 29, 2019. Accessed December 11, 2020. https://searchlf.ama-assn.org/undefined/documentDownload?uri=%2Funstructured%2Fbinary%2Fletter%2FLETTERS%2F2019-10-29-Final-Sign-on-re-10-3-Executive-Order.pdf
Article PDF
CT107001046.PDF
Author and Disclosure Information

From Weill Cornell Medicine, New York, New York. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

The eTable is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, Department of Dermatology, Weill Cornell Medicine, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

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Claire R. Stewart, BA
Shari R. Lipner, MD, PhD
Author and Disclosure Information

From Weill Cornell Medicine, New York, New York. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

The eTable is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, Department of Dermatology, Weill Cornell Medicine, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

Author and Disclosure Information

From Weill Cornell Medicine, New York, New York. Dr. Lipner is from the Department of Dermatology.

The authors report no conflict of interest.

The eTable is available in the Appendix online at www.mdedge.com/dermatology.

Correspondence: Shari R. Lipner, MD, PhD, Department of Dermatology, Weill Cornell Medicine, 1305 York Ave, 9th Floor, New York, NY 10021 ([email protected]).

Article PDF
CT107001046.PDF
Article PDF
CT107001046.PDF

The ability of advanced practice providers (APPs) to practice independently has been a recent topic of discussion among both the medical community and legislatures. Advanced practice provider is an umbrella term that includes physician assistants (PAs) and advanced practice registered nurses, including nurse practitioners (NPs), clinical nurse specialists, certified nurse-midwives, and certified registered nurse anesthetists. Since Congress passed the Balanced Budget Act of 1997, APPs can bill and be paid independently if they are not practicing incident to a physician or in a facility.1 Currently, NPs can practice independently in 27 states and Washington, DC. Physician assistants are required to practice under the supervision of a physician; however, the extent of supervision varies by state.2 Advocates for broadening the scope of practice for APPs argue that NPs and PAs will help to fill the physician deficit, particularly in primary care and rural regions. It has been projected that by 2025, the United States will require an additional 46,000 primary care providers to meet growing medical needs.3

On October 3, 2019, President Donald Trump issued the Executive Order on Protecting and Improving Medicare for Our Nation’s Seniors, in which he proposed an alternative to “Medicare for all.”4 This order instructed the Secretary of Health and Human Services to prepare a regulation that would “eliminate burdensome regulatory billing requirements, conditions of participation, supervision requirements, benefit definitions and all other licensure requirements . . . that are more stringent than applicable Federal or State laws require and that limit professionals from practicing at the top of their field.” Furthermore, President Trump proposed that “services provided by clinicians, including physicians, physician assistants, and nurse practitioners, are appropriately reimbursed in accordance with the work performed rather than the clinician’s occupation.”4

In response to the executive order, members of the medical community utilized Reddit, an online public forum, and Medscape, a medical news website, to vocalize opinions on the executive order.5,6 Our goal was to analyze the characteristics of those who participated in the discussion and their points of view on the plan to broaden the scope of practice and change the Medicare reimbursement plans for APPs.

Methods

All comments on the October 3, 2019, Medscape article, “Trump Executive Order Seeks Proposals on Medicare Pay for NPs, PAs,”5 and the corresponding Reddit discussion on this article6 were reviewed and characterized by the type of commenter—doctor of medicine (MD)/doctor of osteopathic medicine (DO), NP/RN/certified registered nurse anesthetist, PA, medical student, PA student, NP student, pharmacist, dietician, emergency medical technician, scribe, or unknown—as identified in their username, title, or in the text of the comment. Gender of the commenter was recorded when provided. Commenters were further grouped by their support or lack of support for the executive order based on their comments. Patients’ comments underwent further qualitative analysis to identify general themes.

All analyses were conducted with RStudio statistical software. Analyses were reported as proportions. Variables were compared by χ2 and Fisher exact tests. Odds ratios with 95% CIs were calculated. P<.05 was considered statistically significant.

Results

A total of 352 comments (130 on Medscape and 222 on Reddit) posted by 155 unique users (57 on Medscape and 98 on Reddit) were included in the analysis (Table 1). Of the 51 Medscape commenters who identified a gender, 60.7% were male and 39.2% were female. Reddit commenters did not identify a gender. Commenters included MD and DO physicians (43.2%), NPs/RNs/certified registered nurse anesthetists (13.5%), medical students (11.0%), PAs (9.7%), pharmacists (3.2%), NP students (1.9%), PA students (1.3%), emergency medical technicians (1.3%), dieticians (0.6%), and scribes (0.6%). Physicians (54.5% vs 36.73%; P=.032) and NPs (22.8% vs 8.2%; P=.009) made up a larger percentage of all comments on Medscape compared to Reddit, where medical students were more prevalent (16.3% vs 1.8%; P=.005). Nursing students and PA students more commonly posted on Reddit (4.08% of Reddit commenters vs 1.75% of Medscape commenters), though this difference did not achieve statistical significance.

A majority of commenters did not support the executive order, with only 20.6% approving of the plan, 54.8% disapproving, and 24.5% remaining neutral (Figure). Advanced practice providers—NPs, PAs, NP/PA students, and APPs not otherwise specified—were more likely to support the executive order, with 52.3% voicing their support compared to only 4.8% of physicians and medical students expressing support (P<.0001). Similarly, physicians and medical students were more likely to disapprove of the order, with 75.0% voicing concerns compared to only 27.3% of APPs dissenting (P<.0001). A similar percentage of both physicians/medical students and APPs remained neutral (20.2% vs 18.2%). Commenters on Medscape were more likely to voice support for the executive order than those on Reddit (36.8% vs 11.2%; P=.0002), likely due to the higher percentage of NP and PA comments on the former.

Support for executive order by provider type (n=155). APP indicates advanced practice provider.

 

 


Overall, the most commonly discussed topic was provider reimbursement (22.6% of all comments)(Table 2). Physicians and medical students were more likely to discuss physician expertise compared to APPs (32.1% vs 4.5%; P<.001). They also were more likely to raise concerns that the executive order would discourage future generations of physicians from pursuing medicine (15.5% vs 0%; P=.01). Advanced practice providers were more likely than physicians/medical students to comment on the breadth of NP and/or PA training (38.6% vs 19.0%; P=.02). The eTable shows representative comments for each theme encountered.



A subgroup analysis of the comments written by physicians supporting the executive order (n=4) and APPs disapproving of the order (n=12) was performed to identify the dissenting opinions. Physicians who supported the order discussed the need for improved pay for equal work (n=3), the competency of NP and PA training (n=2), the ability of a practice to generate more profit from APPs (n=1), and possible benefits of APPs providing primary care while MDs perform more specialized care (n=1). Of the APPs who did not support the order, there were 4 PAs, 2 registered nurses, 2 NPs, 2 NP students, and 2 PA students. The most common themes discussed were the differences in APP education and training (n=6), lack of desire for further responsibilities (n=4), and the adequacy of the current scope of practice (n=3).

Comment

President Trump’s executive order follows a trend of decreasing required oversight of APPs; however, this study indicates that these policies would face pushback from many physicians. These results are consistent with a prior study that analyzed 309 comments on an article in The New York Times made by physicians, APPs, patients, and laypeople, in which 24.7% had mistrust of APPs and 14.9% had concerns over APP supervision compared to 9% who supported APP independent practice.7 It is clear that there is a serious divide in opinion that threatens to harm the existing collaborations between physicians and APPs.

Primary Care Coverage With APPs
In the comments analyzed in our study, supporters of the executive order argued that an increase in APPs practicing independently would provide much-needed primary care coverage to patients in underserved regions. However, APPs are instead well represented across most specialties, with a majority in dermatology. Of the 4 million procedures billed independently by APPs in 2012, 54.8% were in the field of dermatology.8 The employment of APPs by dermatologists has grown from 28% of practices in 2005 to 46% in 2014, making this issue of particular importance to our field.9,10

Education and Training of APPs
In our analysis, many physicians cited concerns about the education and training of APPs. Dermatologists receive approximately 10,000 hours of training over the course of residency. Per the American Academy of Physician Assistants, PAs spend more than 2000 hours over a 26-month period on various clinical rotations, “with an emphasis on primary care.”11 There are multiple routes to become an advanced practice RN with varying classroom and clinical requirements, with one pathway requiring a bachelor of science in nursing, followed by a master’s degree requiring 500 to 700 hours of supervised clinical work. Although the Dermatology Nurses’ Association and Society of Dermatology Physician Assistants (http://www.dermpa.org) provide online modules, annual conventions with training workshops, and short fellowship programs, neither have formal guidelines on minimum requirements to diagnose and treat dermatologic conditions.2 Despite the lack of formalized dermatologic training, APPs billed for 13.4% of all dermatology procedures submitted to Medicare in 2015.12

Quality of Patient Care
In our study, physicians also voiced concern over reduced quality of patient care. In a review of 33,647 skin cancer screening examinations, PAs biopsied an average of 39.4 skin lesions, while dermatologists biopsied an average of 25.4 skin lesions to diagnose 1 case of melanoma.13 In addition, nonphysician providers accounted for 37.9% of defendants in 174 legal cases related to injury from cutaneous laser surgery.14 Before further laws are enacted regarding the independent practice and billing by NPs and PAs in the field of dermatology, further research is needed to address patient outcomes and safety.

Limitations
This study was subject to several limitations. Because of a lack of other sources offering discussions on the topic, our sample size was limited. Self-identification of users presents a challenge, as an individual can pose as a physician or APP without validation of credentials. Although great care was taken to minimize bias, grouping comments into broad categories may misinterpret a poster’s intentions. Furthermore, the data collected represent only a small proportion of the medical community—readers of Medscape and Reddit who have the motivation to create a user profile and post a comment rather than put their efforts into lobbying or contacting legislators. Those posting may have stronger political opinions or more poignant experiences than the general public. Although selection bias impacts the generalizability of our findings, this analysis allows for deeper insight into the beliefs of a vocal subset of the medical community who may not have the opportunity to present their opinions elsewhere.

Conclusion

Our analysis of the response to President Trump’s executive order reveals that a rollout of these regulations would be met with strong opposition. On October 29, 2019, more than 100 professional organizations, including the American Medical Association and the American Academy of Dermatology, wrote a letter to the Secretary of Health and Human Services that eloquently echoed the sentiments of the physician commenters in this study: “Scope of practice of health care professionals should be based on standardized, adequate training and demonstrated competence in patient care, not politics. While all health care professionals share an important role in providing care to patients, their skillset is not interchangeable with that of a fully trained physician.”15 The executive order would lead to a major shift in the current medical landscape, and as such, it is prudent that these concerns are addressed.

The ability of advanced practice providers (APPs) to practice independently has been a recent topic of discussion among both the medical community and legislatures. Advanced practice provider is an umbrella term that includes physician assistants (PAs) and advanced practice registered nurses, including nurse practitioners (NPs), clinical nurse specialists, certified nurse-midwives, and certified registered nurse anesthetists. Since Congress passed the Balanced Budget Act of 1997, APPs can bill and be paid independently if they are not practicing incident to a physician or in a facility.1 Currently, NPs can practice independently in 27 states and Washington, DC. Physician assistants are required to practice under the supervision of a physician; however, the extent of supervision varies by state.2 Advocates for broadening the scope of practice for APPs argue that NPs and PAs will help to fill the physician deficit, particularly in primary care and rural regions. It has been projected that by 2025, the United States will require an additional 46,000 primary care providers to meet growing medical needs.3

On October 3, 2019, President Donald Trump issued the Executive Order on Protecting and Improving Medicare for Our Nation’s Seniors, in which he proposed an alternative to “Medicare for all.”4 This order instructed the Secretary of Health and Human Services to prepare a regulation that would “eliminate burdensome regulatory billing requirements, conditions of participation, supervision requirements, benefit definitions and all other licensure requirements . . . that are more stringent than applicable Federal or State laws require and that limit professionals from practicing at the top of their field.” Furthermore, President Trump proposed that “services provided by clinicians, including physicians, physician assistants, and nurse practitioners, are appropriately reimbursed in accordance with the work performed rather than the clinician’s occupation.”4

In response to the executive order, members of the medical community utilized Reddit, an online public forum, and Medscape, a medical news website, to vocalize opinions on the executive order.5,6 Our goal was to analyze the characteristics of those who participated in the discussion and their points of view on the plan to broaden the scope of practice and change the Medicare reimbursement plans for APPs.

Methods

All comments on the October 3, 2019, Medscape article, “Trump Executive Order Seeks Proposals on Medicare Pay for NPs, PAs,”5 and the corresponding Reddit discussion on this article6 were reviewed and characterized by the type of commenter—doctor of medicine (MD)/doctor of osteopathic medicine (DO), NP/RN/certified registered nurse anesthetist, PA, medical student, PA student, NP student, pharmacist, dietician, emergency medical technician, scribe, or unknown—as identified in their username, title, or in the text of the comment. Gender of the commenter was recorded when provided. Commenters were further grouped by their support or lack of support for the executive order based on their comments. Patients’ comments underwent further qualitative analysis to identify general themes.

All analyses were conducted with RStudio statistical software. Analyses were reported as proportions. Variables were compared by χ2 and Fisher exact tests. Odds ratios with 95% CIs were calculated. P<.05 was considered statistically significant.

Results

A total of 352 comments (130 on Medscape and 222 on Reddit) posted by 155 unique users (57 on Medscape and 98 on Reddit) were included in the analysis (Table 1). Of the 51 Medscape commenters who identified a gender, 60.7% were male and 39.2% were female. Reddit commenters did not identify a gender. Commenters included MD and DO physicians (43.2%), NPs/RNs/certified registered nurse anesthetists (13.5%), medical students (11.0%), PAs (9.7%), pharmacists (3.2%), NP students (1.9%), PA students (1.3%), emergency medical technicians (1.3%), dieticians (0.6%), and scribes (0.6%). Physicians (54.5% vs 36.73%; P=.032) and NPs (22.8% vs 8.2%; P=.009) made up a larger percentage of all comments on Medscape compared to Reddit, where medical students were more prevalent (16.3% vs 1.8%; P=.005). Nursing students and PA students more commonly posted on Reddit (4.08% of Reddit commenters vs 1.75% of Medscape commenters), though this difference did not achieve statistical significance.

A majority of commenters did not support the executive order, with only 20.6% approving of the plan, 54.8% disapproving, and 24.5% remaining neutral (Figure). Advanced practice providers—NPs, PAs, NP/PA students, and APPs not otherwise specified—were more likely to support the executive order, with 52.3% voicing their support compared to only 4.8% of physicians and medical students expressing support (P<.0001). Similarly, physicians and medical students were more likely to disapprove of the order, with 75.0% voicing concerns compared to only 27.3% of APPs dissenting (P<.0001). A similar percentage of both physicians/medical students and APPs remained neutral (20.2% vs 18.2%). Commenters on Medscape were more likely to voice support for the executive order than those on Reddit (36.8% vs 11.2%; P=.0002), likely due to the higher percentage of NP and PA comments on the former.

Support for executive order by provider type (n=155). APP indicates advanced practice provider.

 

 


Overall, the most commonly discussed topic was provider reimbursement (22.6% of all comments)(Table 2). Physicians and medical students were more likely to discuss physician expertise compared to APPs (32.1% vs 4.5%; P<.001). They also were more likely to raise concerns that the executive order would discourage future generations of physicians from pursuing medicine (15.5% vs 0%; P=.01). Advanced practice providers were more likely than physicians/medical students to comment on the breadth of NP and/or PA training (38.6% vs 19.0%; P=.02). The eTable shows representative comments for each theme encountered.



A subgroup analysis of the comments written by physicians supporting the executive order (n=4) and APPs disapproving of the order (n=12) was performed to identify the dissenting opinions. Physicians who supported the order discussed the need for improved pay for equal work (n=3), the competency of NP and PA training (n=2), the ability of a practice to generate more profit from APPs (n=1), and possible benefits of APPs providing primary care while MDs perform more specialized care (n=1). Of the APPs who did not support the order, there were 4 PAs, 2 registered nurses, 2 NPs, 2 NP students, and 2 PA students. The most common themes discussed were the differences in APP education and training (n=6), lack of desire for further responsibilities (n=4), and the adequacy of the current scope of practice (n=3).

Comment

President Trump’s executive order follows a trend of decreasing required oversight of APPs; however, this study indicates that these policies would face pushback from many physicians. These results are consistent with a prior study that analyzed 309 comments on an article in The New York Times made by physicians, APPs, patients, and laypeople, in which 24.7% had mistrust of APPs and 14.9% had concerns over APP supervision compared to 9% who supported APP independent practice.7 It is clear that there is a serious divide in opinion that threatens to harm the existing collaborations between physicians and APPs.

Primary Care Coverage With APPs
In the comments analyzed in our study, supporters of the executive order argued that an increase in APPs practicing independently would provide much-needed primary care coverage to patients in underserved regions. However, APPs are instead well represented across most specialties, with a majority in dermatology. Of the 4 million procedures billed independently by APPs in 2012, 54.8% were in the field of dermatology.8 The employment of APPs by dermatologists has grown from 28% of practices in 2005 to 46% in 2014, making this issue of particular importance to our field.9,10

Education and Training of APPs
In our analysis, many physicians cited concerns about the education and training of APPs. Dermatologists receive approximately 10,000 hours of training over the course of residency. Per the American Academy of Physician Assistants, PAs spend more than 2000 hours over a 26-month period on various clinical rotations, “with an emphasis on primary care.”11 There are multiple routes to become an advanced practice RN with varying classroom and clinical requirements, with one pathway requiring a bachelor of science in nursing, followed by a master’s degree requiring 500 to 700 hours of supervised clinical work. Although the Dermatology Nurses’ Association and Society of Dermatology Physician Assistants (http://www.dermpa.org) provide online modules, annual conventions with training workshops, and short fellowship programs, neither have formal guidelines on minimum requirements to diagnose and treat dermatologic conditions.2 Despite the lack of formalized dermatologic training, APPs billed for 13.4% of all dermatology procedures submitted to Medicare in 2015.12

Quality of Patient Care
In our study, physicians also voiced concern over reduced quality of patient care. In a review of 33,647 skin cancer screening examinations, PAs biopsied an average of 39.4 skin lesions, while dermatologists biopsied an average of 25.4 skin lesions to diagnose 1 case of melanoma.13 In addition, nonphysician providers accounted for 37.9% of defendants in 174 legal cases related to injury from cutaneous laser surgery.14 Before further laws are enacted regarding the independent practice and billing by NPs and PAs in the field of dermatology, further research is needed to address patient outcomes and safety.

Limitations
This study was subject to several limitations. Because of a lack of other sources offering discussions on the topic, our sample size was limited. Self-identification of users presents a challenge, as an individual can pose as a physician or APP without validation of credentials. Although great care was taken to minimize bias, grouping comments into broad categories may misinterpret a poster’s intentions. Furthermore, the data collected represent only a small proportion of the medical community—readers of Medscape and Reddit who have the motivation to create a user profile and post a comment rather than put their efforts into lobbying or contacting legislators. Those posting may have stronger political opinions or more poignant experiences than the general public. Although selection bias impacts the generalizability of our findings, this analysis allows for deeper insight into the beliefs of a vocal subset of the medical community who may not have the opportunity to present their opinions elsewhere.

Conclusion

Our analysis of the response to President Trump’s executive order reveals that a rollout of these regulations would be met with strong opposition. On October 29, 2019, more than 100 professional organizations, including the American Medical Association and the American Academy of Dermatology, wrote a letter to the Secretary of Health and Human Services that eloquently echoed the sentiments of the physician commenters in this study: “Scope of practice of health care professionals should be based on standardized, adequate training and demonstrated competence in patient care, not politics. While all health care professionals share an important role in providing care to patients, their skillset is not interchangeable with that of a fully trained physician.”15 The executive order would lead to a major shift in the current medical landscape, and as such, it is prudent that these concerns are addressed.

References
  1. Balanced Budget Act of 1997, 42 USC §1395x (1997). Accessed December 15, 2020. https://www.govinfo.gov/content/pkg/PLAW-105publ33/html/PLAW-105publ33.htm
  2. State practice environment. American Association of Nurse Practitioners. Updated October 20, 2020. Accessed December 8, 2020. https://www.aanp.org/advocacy/state/state-practice-environment
  3. Petterson SM, Liaw WR, Phillips RL Jr, et al. Projecting US primary care physician workforce needs: 2010-2015. Ann Fam Med. 2012;10:503-509.
  4. United States, Executive Office of the President [Donald Trump]. Executive Order 13890: Protecting and Improving Medicare for Our Nation’s Seniors. October 3, 2019. Fed Regist. 2019;84:53573-53576.
  5. Young KD. Trump executive order seeks proposals on Medicare pay for NPs, PAs. Medscape. Published October 3, 2019. Accessed December 8, 2020. https://www.medscape.com/viewarticle/919415
  6. Trump seeks proposals on Medicare pay for NPs, PAs. Reddit. Accessed December 8, 2020. https://www.reddit.com/r/medicine/comments/ddy03w/trump_seeks_proposals_on_medicare_pay_for_nps_pas/
  7. Martin E, Huang WW, Strowd LC, et al. Public perception of ethical issues in dermatology: evidenced by New York Times commenters. Dermatol Surg. 2018;44:1571-1577.
  8. Coldiron B, Ratnarathorn M. Scope of physician procedures independently billed by mid-level providers in the office setting. JAMA Dermatol. 2014;150:1153-1159.
  9. Resneck JS Jr. Dermatology practice consolidation fueled by private equity investment: potential consequences for the specialty and patients. JAMA Dermatol. 2018;154:13-14.
  10. Ehrlich A, Kostecki J, Olkaba H. Trends in dermatology practices and the implications for the workforce. J Am Acad Dermatol. 2017;77:746-752.
  11. Become a PA. American Academy of Physician Assistants. Accessed December 8, 2020. https://www.aapa.org/career-central/become-a-pa/.
  12. Zhang M, Zippin J, Kaffenberger B. Trends and scope of dermatology procedures billed by advanced practice professionals from 2012 through 2015. JAMA Dermatol. 2018;154:1040-1044.
  13. Anderson AM, Matsumoto M, Saul MI, et al. Accuracy of skin cancer diagnosis of physician assistants compared with dermatologists in a large health care system. JAMA Dermatol. 2018;154:569-573.
  14. Jalian HR, Jalian CA, Avram MM. Common causes of injury and legal action in laser surgery. JAMA Dermatol. 2013;149:188-193.
  15. American Medical Association. Open letter to the Honorable Alex M. Azar II. Published October 29, 2019. Accessed December 11, 2020. https://searchlf.ama-assn.org/undefined/documentDownload?uri=%2Funstructured%2Fbinary%2Fletter%2FLETTERS%2F2019-10-29-Final-Sign-on-re-10-3-Executive-Order.pdf
References
  1. Balanced Budget Act of 1997, 42 USC §1395x (1997). Accessed December 15, 2020. https://www.govinfo.gov/content/pkg/PLAW-105publ33/html/PLAW-105publ33.htm
  2. State practice environment. American Association of Nurse Practitioners. Updated October 20, 2020. Accessed December 8, 2020. https://www.aanp.org/advocacy/state/state-practice-environment
  3. Petterson SM, Liaw WR, Phillips RL Jr, et al. Projecting US primary care physician workforce needs: 2010-2015. Ann Fam Med. 2012;10:503-509.
  4. United States, Executive Office of the President [Donald Trump]. Executive Order 13890: Protecting and Improving Medicare for Our Nation’s Seniors. October 3, 2019. Fed Regist. 2019;84:53573-53576.
  5. Young KD. Trump executive order seeks proposals on Medicare pay for NPs, PAs. Medscape. Published October 3, 2019. Accessed December 8, 2020. https://www.medscape.com/viewarticle/919415
  6. Trump seeks proposals on Medicare pay for NPs, PAs. Reddit. Accessed December 8, 2020. https://www.reddit.com/r/medicine/comments/ddy03w/trump_seeks_proposals_on_medicare_pay_for_nps_pas/
  7. Martin E, Huang WW, Strowd LC, et al. Public perception of ethical issues in dermatology: evidenced by New York Times commenters. Dermatol Surg. 2018;44:1571-1577.
  8. Coldiron B, Ratnarathorn M. Scope of physician procedures independently billed by mid-level providers in the office setting. JAMA Dermatol. 2014;150:1153-1159.
  9. Resneck JS Jr. Dermatology practice consolidation fueled by private equity investment: potential consequences for the specialty and patients. JAMA Dermatol. 2018;154:13-14.
  10. Ehrlich A, Kostecki J, Olkaba H. Trends in dermatology practices and the implications for the workforce. J Am Acad Dermatol. 2017;77:746-752.
  11. Become a PA. American Academy of Physician Assistants. Accessed December 8, 2020. https://www.aapa.org/career-central/become-a-pa/.
  12. Zhang M, Zippin J, Kaffenberger B. Trends and scope of dermatology procedures billed by advanced practice professionals from 2012 through 2015. JAMA Dermatol. 2018;154:1040-1044.
  13. Anderson AM, Matsumoto M, Saul MI, et al. Accuracy of skin cancer diagnosis of physician assistants compared with dermatologists in a large health care system. JAMA Dermatol. 2018;154:569-573.
  14. Jalian HR, Jalian CA, Avram MM. Common causes of injury and legal action in laser surgery. JAMA Dermatol. 2013;149:188-193.
  15. American Medical Association. Open letter to the Honorable Alex M. Azar II. Published October 29, 2019. Accessed December 11, 2020. https://searchlf.ama-assn.org/undefined/documentDownload?uri=%2Funstructured%2Fbinary%2Fletter%2FLETTERS%2F2019-10-29-Final-Sign-on-re-10-3-Executive-Order.pdf
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  • On October 3, 2019, President Donald Trump issued the Executive Order on Protecting and Improving Medicare for Our Nation’s Seniors, in which he proposed eliminating supervision requirements for advanced practice providers (APPs) and equalizing Medicare reimbursements among APPs and physicians.
  • In a review of comments posted on online forums for medical professionals, a majority of medical professionals disapproved of the executive order.
  • Advanced practice providers were more likely to support the plan, citing the breadth of their experience, whereas physicians were more likely to disapprove based on their extensive training within their specialty.
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Prescribing Patterns of Onychomycosis Therapies in the United States

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Eric J. Yang, MD
Shari R. Lipner, MD, PhD

To the Editor:

Onychomycosis is the most common nail disorder, affecting approximately 5.5% of the world’s population.1 There are a limited number of topical and systemic therapies approved by the US Food and Drug Administration (FDA), but no consensus guidelines exist for the management of onychomycosis. Therefore, we hypothesized that prescribing patterns would vary among different groups.

We examined data from the Centers for Medicare & Medicaid Services’ Part D Prescriber Public Use Files for 2013 to 2016.2 Prescribing patterns were assessed for dermatologists, nurse practitioners, physician assistants, and podiatrists prescribing systemic (ie, terbinafine, itraconazole) or topical (ie, efinaconazole, tavaborole, ciclopirox) therapies. A cut-off of systemic therapy lasting 84 days or more (reflecting FDA-approved treatment regimens for toenail onychomycosis) was used to exclude prescriptions for other fungal conditions that require shorter treatment courses. Statistical analysis with χ2 tests identified differences among specialties’ prescribing patterns.

Overall, onychomycosis medications accounted for $85.4 million in expenditures from 2013 to 2016, with spending increasing at a rate of 21.2% annually (Table 1). The greatest single-year increase was observed from 2014 to 2015, with a 40.6% surge in overall expenditures for onychomycosis medications—increasing from $17.8 million to $25.0 million in spending. Dermatologists’ prescriptions accounted for 14.8% of all claims for onychomycosis medications and 18.3% of total expenditures during the study period, totaling $15.7 million in costs. Dermatologists’ claims increased at a rate of 7.4% annually, while expenditures increased at 15.4% annually. A greater proportion of dermatologists (96.4%) prescribed topicals for onychomycosis relative to nurse practitioners (90.2%) and podiatrists (91.3%)(P<.01)(Table 2). No significant difference was observed in the prescribing patterns of dermatologists and physician assistants (P=.99).



Per-claim spending for treating onychomycosis increased 7.4% annually for dermatologists, second only to podiatrists at 17.2% annually. Each analyzed group reported at least a 7% annual increase in the amount of topicals prescribed for onychomycosis. Following their FDA approvals in 2014, tavaborole and efinaconazole accounted for 0.9% and 2.3% of onychomycosis claims in 2016, respectively, and 15.0% and 25.1% of total Medicare expenditures on onychomycosis treatments that same year, respectively. Itraconazole also disproportionately contributed to expenditures, accounting for 1.3% of onychomycosis claims in 2016 while accounting for 9.5% of total expenditures.

The introduction of efinaconazole and tavaborole in 2014 resulted in large increases in Medicare spending for onychomycosis. Limited manufacturer competition due to patents may contribute to increased spending on these topicals in the future.3 A prior analysis demonstrated that podiatrists prescribe topicals more often than other clinicians,4 but after adjusting for the number of dermatologists managing onychomycosis, we found that a greater proportion of dermatologists (96.4%) are prescribing topicals for onychomycosis than other clinicians. This includes these newly approved, high-cost topicals, thus disproportionately contributing to the cost burden of onychomycosis treatment.



Ciclopirox is the most commonly prescribed therapy for onychomycosis across all groups, prescribed by more than 88% of prescribers in all studied specialties. Although ciclopirox is one of the least expensive treatment options available for onychomycosis, it has the lowest relative cure rate.5 Onychomycosis management requires understanding of drug efficacy and disease severity.6 Inappropriate treatment selection may result in prolonged treatment courses and increased costs. Consensus guidelines for onychomycosis therapies across specialties may yield more cost-effective treatment for this common nail condition.

 



Acknowledgment
The authors thank Paul J. Christos, DrPH, MS (New York, New York), for his advisement regarding statistical analysis for this manuscript.

References
  1. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851.
  2. Medicare provider utilization and payment data: part D prescriber. Centers for Medicare & Medicaid Services website. https://www.cms.gov/Research-Statistics-Data-and-Systems/Statistics-Trends-and-Reports/Medicare-Provider-Charge-Data/Part-D-Prescriber. Updated November 27, 2019. Accessed November 22, 2020.
  3. Yang EJ, Lipner SR. Pharmacy costs of medications for the treatment of onychomycosis in the United States. J Am Acad Dermatol. 2019;81:276-278.
  4. Singh P, Silverberg JI. Trends in utilization and expenditure for onychomycosis treatments in the United States in 2013-2016. Am J Clin Dermatol. 2019;20:311-313.
  5. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867.
  6. Lipner SR. Pharmacotherapy for onychomycosis: new and emerging treatments. Expert Opin Pharmacother. 2019;20:725-735.
Article PDF
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Author and Disclosure Information

Dr. Yang is from Department of Dermatology, Warren Alpert Medical School, Brown University, Providence, Rhode Island. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Eric J. Yang, MD, 593 Eddy St, Providence, RI 02903 ([email protected]). 

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Shari R. Lipner, MD, PhD
Author(s)
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Shari R. Lipner, MD, PhD
Author and Disclosure Information

Dr. Yang is from Department of Dermatology, Warren Alpert Medical School, Brown University, Providence, Rhode Island. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Eric J. Yang, MD, 593 Eddy St, Providence, RI 02903 ([email protected]). 

Author and Disclosure Information

Dr. Yang is from Department of Dermatology, Warren Alpert Medical School, Brown University, Providence, Rhode Island. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Eric J. Yang, MD, 593 Eddy St, Providence, RI 02903 ([email protected]). 

Article PDF
CT106006326.PDF
Article PDF
CT106006326.PDF

To the Editor:

Onychomycosis is the most common nail disorder, affecting approximately 5.5% of the world’s population.1 There are a limited number of topical and systemic therapies approved by the US Food and Drug Administration (FDA), but no consensus guidelines exist for the management of onychomycosis. Therefore, we hypothesized that prescribing patterns would vary among different groups.

We examined data from the Centers for Medicare & Medicaid Services’ Part D Prescriber Public Use Files for 2013 to 2016.2 Prescribing patterns were assessed for dermatologists, nurse practitioners, physician assistants, and podiatrists prescribing systemic (ie, terbinafine, itraconazole) or topical (ie, efinaconazole, tavaborole, ciclopirox) therapies. A cut-off of systemic therapy lasting 84 days or more (reflecting FDA-approved treatment regimens for toenail onychomycosis) was used to exclude prescriptions for other fungal conditions that require shorter treatment courses. Statistical analysis with χ2 tests identified differences among specialties’ prescribing patterns.

Overall, onychomycosis medications accounted for $85.4 million in expenditures from 2013 to 2016, with spending increasing at a rate of 21.2% annually (Table 1). The greatest single-year increase was observed from 2014 to 2015, with a 40.6% surge in overall expenditures for onychomycosis medications—increasing from $17.8 million to $25.0 million in spending. Dermatologists’ prescriptions accounted for 14.8% of all claims for onychomycosis medications and 18.3% of total expenditures during the study period, totaling $15.7 million in costs. Dermatologists’ claims increased at a rate of 7.4% annually, while expenditures increased at 15.4% annually. A greater proportion of dermatologists (96.4%) prescribed topicals for onychomycosis relative to nurse practitioners (90.2%) and podiatrists (91.3%)(P<.01)(Table 2). No significant difference was observed in the prescribing patterns of dermatologists and physician assistants (P=.99).



Per-claim spending for treating onychomycosis increased 7.4% annually for dermatologists, second only to podiatrists at 17.2% annually. Each analyzed group reported at least a 7% annual increase in the amount of topicals prescribed for onychomycosis. Following their FDA approvals in 2014, tavaborole and efinaconazole accounted for 0.9% and 2.3% of onychomycosis claims in 2016, respectively, and 15.0% and 25.1% of total Medicare expenditures on onychomycosis treatments that same year, respectively. Itraconazole also disproportionately contributed to expenditures, accounting for 1.3% of onychomycosis claims in 2016 while accounting for 9.5% of total expenditures.

The introduction of efinaconazole and tavaborole in 2014 resulted in large increases in Medicare spending for onychomycosis. Limited manufacturer competition due to patents may contribute to increased spending on these topicals in the future.3 A prior analysis demonstrated that podiatrists prescribe topicals more often than other clinicians,4 but after adjusting for the number of dermatologists managing onychomycosis, we found that a greater proportion of dermatologists (96.4%) are prescribing topicals for onychomycosis than other clinicians. This includes these newly approved, high-cost topicals, thus disproportionately contributing to the cost burden of onychomycosis treatment.



Ciclopirox is the most commonly prescribed therapy for onychomycosis across all groups, prescribed by more than 88% of prescribers in all studied specialties. Although ciclopirox is one of the least expensive treatment options available for onychomycosis, it has the lowest relative cure rate.5 Onychomycosis management requires understanding of drug efficacy and disease severity.6 Inappropriate treatment selection may result in prolonged treatment courses and increased costs. Consensus guidelines for onychomycosis therapies across specialties may yield more cost-effective treatment for this common nail condition.

 



Acknowledgment
The authors thank Paul J. Christos, DrPH, MS (New York, New York), for his advisement regarding statistical analysis for this manuscript.

To the Editor:

Onychomycosis is the most common nail disorder, affecting approximately 5.5% of the world’s population.1 There are a limited number of topical and systemic therapies approved by the US Food and Drug Administration (FDA), but no consensus guidelines exist for the management of onychomycosis. Therefore, we hypothesized that prescribing patterns would vary among different groups.

We examined data from the Centers for Medicare & Medicaid Services’ Part D Prescriber Public Use Files for 2013 to 2016.2 Prescribing patterns were assessed for dermatologists, nurse practitioners, physician assistants, and podiatrists prescribing systemic (ie, terbinafine, itraconazole) or topical (ie, efinaconazole, tavaborole, ciclopirox) therapies. A cut-off of systemic therapy lasting 84 days or more (reflecting FDA-approved treatment regimens for toenail onychomycosis) was used to exclude prescriptions for other fungal conditions that require shorter treatment courses. Statistical analysis with χ2 tests identified differences among specialties’ prescribing patterns.

Overall, onychomycosis medications accounted for $85.4 million in expenditures from 2013 to 2016, with spending increasing at a rate of 21.2% annually (Table 1). The greatest single-year increase was observed from 2014 to 2015, with a 40.6% surge in overall expenditures for onychomycosis medications—increasing from $17.8 million to $25.0 million in spending. Dermatologists’ prescriptions accounted for 14.8% of all claims for onychomycosis medications and 18.3% of total expenditures during the study period, totaling $15.7 million in costs. Dermatologists’ claims increased at a rate of 7.4% annually, while expenditures increased at 15.4% annually. A greater proportion of dermatologists (96.4%) prescribed topicals for onychomycosis relative to nurse practitioners (90.2%) and podiatrists (91.3%)(P<.01)(Table 2). No significant difference was observed in the prescribing patterns of dermatologists and physician assistants (P=.99).



Per-claim spending for treating onychomycosis increased 7.4% annually for dermatologists, second only to podiatrists at 17.2% annually. Each analyzed group reported at least a 7% annual increase in the amount of topicals prescribed for onychomycosis. Following their FDA approvals in 2014, tavaborole and efinaconazole accounted for 0.9% and 2.3% of onychomycosis claims in 2016, respectively, and 15.0% and 25.1% of total Medicare expenditures on onychomycosis treatments that same year, respectively. Itraconazole also disproportionately contributed to expenditures, accounting for 1.3% of onychomycosis claims in 2016 while accounting for 9.5% of total expenditures.

The introduction of efinaconazole and tavaborole in 2014 resulted in large increases in Medicare spending for onychomycosis. Limited manufacturer competition due to patents may contribute to increased spending on these topicals in the future.3 A prior analysis demonstrated that podiatrists prescribe topicals more often than other clinicians,4 but after adjusting for the number of dermatologists managing onychomycosis, we found that a greater proportion of dermatologists (96.4%) are prescribing topicals for onychomycosis than other clinicians. This includes these newly approved, high-cost topicals, thus disproportionately contributing to the cost burden of onychomycosis treatment.



Ciclopirox is the most commonly prescribed therapy for onychomycosis across all groups, prescribed by more than 88% of prescribers in all studied specialties. Although ciclopirox is one of the least expensive treatment options available for onychomycosis, it has the lowest relative cure rate.5 Onychomycosis management requires understanding of drug efficacy and disease severity.6 Inappropriate treatment selection may result in prolonged treatment courses and increased costs. Consensus guidelines for onychomycosis therapies across specialties may yield more cost-effective treatment for this common nail condition.

 



Acknowledgment
The authors thank Paul J. Christos, DrPH, MS (New York, New York), for his advisement regarding statistical analysis for this manuscript.

References
  1. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851.
  2. Medicare provider utilization and payment data: part D prescriber. Centers for Medicare & Medicaid Services website. https://www.cms.gov/Research-Statistics-Data-and-Systems/Statistics-Trends-and-Reports/Medicare-Provider-Charge-Data/Part-D-Prescriber. Updated November 27, 2019. Accessed November 22, 2020.
  3. Yang EJ, Lipner SR. Pharmacy costs of medications for the treatment of onychomycosis in the United States. J Am Acad Dermatol. 2019;81:276-278.
  4. Singh P, Silverberg JI. Trends in utilization and expenditure for onychomycosis treatments in the United States in 2013-2016. Am J Clin Dermatol. 2019;20:311-313.
  5. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867.
  6. Lipner SR. Pharmacotherapy for onychomycosis: new and emerging treatments. Expert Opin Pharmacother. 2019;20:725-735.
References
  1. Lipner SR, Scher RK. Onychomycosis: clinical overview and diagnosis. J Am Acad Dermatol. 2019;80:835-851.
  2. Medicare provider utilization and payment data: part D prescriber. Centers for Medicare & Medicaid Services website. https://www.cms.gov/Research-Statistics-Data-and-Systems/Statistics-Trends-and-Reports/Medicare-Provider-Charge-Data/Part-D-Prescriber. Updated November 27, 2019. Accessed November 22, 2020.
  3. Yang EJ, Lipner SR. Pharmacy costs of medications for the treatment of onychomycosis in the United States. J Am Acad Dermatol. 2019;81:276-278.
  4. Singh P, Silverberg JI. Trends in utilization and expenditure for onychomycosis treatments in the United States in 2013-2016. Am J Clin Dermatol. 2019;20:311-313.
  5. Lipner SR, Scher RK. Onychomycosis: treatment and prevention of recurrence. J Am Acad Dermatol. 2019;80:853-867.
  6. Lipner SR. Pharmacotherapy for onychomycosis: new and emerging treatments. Expert Opin Pharmacother. 2019;20:725-735.
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  • Dermatologists should consider efficacy and cost of onychomycosis therapies, as inappropriate treatment selection results in longer treatment courses and increased costs.
  • Creation of consensus guidelines for the management of onychomycosis may decrease the costs of treating this difficult-to-manage disease.
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Use of 3D Technology to Support Dermatologists Returning to Practice Amid COVID-19

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Stephanie Ishack, PhD
Shari R. Lipner, MD, PhD

 

Coronavirus disease 2019 (COVID-19) has spread across all 7 continents, including 185 countries, and infected more than 21.9 million individuals worldwide as of August 18, 2020, according to the Johns Hopkins Coronavirus Resource Center. It has strained our health care system and affected all specialties, including dermatology. Dermatologists have taken important safety measures by canceling/deferring elective and nonemergency procedures and diagnosing/treating patients via telemedicine. Many residents and attending dermatologists have volunteered to care for COVID-19 inpatients and donated personal protective equipment (PPE) to hospitals reporting shortages.1 As we prepare to treat increasing numbers of in-office patients, there will be a critical need for PPE. We highlight the use of 3-dimensional (3D) imaging and printing technologies as it applies to the dermatology outpatient setting.

N95 masks are necessary during the COVID-19 pandemic because they effectively filter at least 95% of 0.3-μm airborne particles and provide adequate face seals.1 3-Dimensional imaging integrated with 3D printers can be used to scan precise facial parameters (eg, jawline, nose) and account for facial hair density and length to produce comfortable tailored N95 masks and face seals.1,2 3-Dimensional printing utilizes robotics and computer-aided design systems to layer and deposit biomaterials, thereby creating cost-effective, customizable, mechanically stable, and biocompatible constructs.1,3 An ideal 3D-printed N95 mask would be printed via fused deposition modeling, consisting of a combination of lightweight and fatigue-resistant biomaterials, including electrostatic nonwoven polypropylene and styrene-(ethylene-butylene)-styrene.1,4 The resulting masks, made from industrial-grade raw materials, are practical alternatives for dermatology practices with insufficient supplies.

Face shields offer an additional layer of safety for the face and mucosae and also may provide longevity for N95 masks. Using synthetic polymers such as polycarbonate and polyethylene, 3D printers can be used to construct face shields via fused deposition modeling.1 These face shields may be worn over N95 masks and then can be sanitized and reused.

Mohs surgeons and staff may be at particularly high risk for COVID-19 infection due to their close proximity to the face during surgery, use of cautery, and prolonged time spent with patients while taking layers and suturing. Multispectral optoacoustic tomography is a noninvasive imaging tool that can map skin tumors via optical contrast with accuracy comparable to histologic measurements.5 3-Dimensional facial imaging and printing can be used to calculate tumor surface area for customized masks, leaving sufficient skin for excision and reconstruction. Patient face coverings would cover the nose and mouth, only expose relevant areas near the excision site, and include adjustable/removable ear loops for tumors localized to the ears. A schematic of how 3D technologies can be applied for Mohs micrographic surgery is provided in the Figure.

3-Dimensional (3D) imaging technologies and a 3D-printed face covering prototype that can potentially be used on patients during Mohs micrographic surgery. The biomaterials in this diagram have been well tested in the literature and are the same materials that are used in N95 masks.


As dermatologists reopen and ramp up practice volume, there will be increased PPE requirements. Using 3D technology and imaging to produce N95 masks, face shields, and face coverings, we can offer effective diagnosis and treatment while optimizing safety for dermatologists, staff, and patients.

References
  1. Ishack S, Lipner SR. Applications of 3D printing technology to address COVID-19-related supply shortages [published online April 21, 2020]. Am J Med. 2020;133:771-773.
  2. Cai M, Li H, Shen S, et al. Customized design and 3D printing of face seal for an N95 filtering facepiece respirator. J Occup Environ Hyg. 2018;3:226-234.
  3. Ishack S, Lipner SR. A review of 3-dimensional skin bioprinting techniques: applications, approaches, and trends [published online March 17, 2020]. Dermatol Surg. doi:10.1097/DSS.0000000000002378.
  4. Banerjee SS, Burbine S, Shivaprakash NK, et al. 3D-printable PP/SEBS thermoplastic elastomeric blends: preparation and properties [published online February 17, 2019]. Polymers (Basel). doi:10.3390/polym11020347.
  5. Chuah SY, Attia ABE, Long V. Structural and functional 3D mapping of skin tumours with non-invasive multispectral optoacoustic tomography [published online November 2, 2016]. Skin Res Technol. 2017;23:221-226.
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Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medical College, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Shari R. Lipner, MD, PhD
Author and Disclosure Information

Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medical College, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Author and Disclosure Information

Dr. Ishack is from the New York University School of Medicine, New York. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medical College, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Article PDF
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Utilization of Telehealth Services During the COVID-19 Pandemic
Coronavirus and Dermatology: A Resident’s Perspective

 

Coronavirus disease 2019 (COVID-19) has spread across all 7 continents, including 185 countries, and infected more than 21.9 million individuals worldwide as of August 18, 2020, according to the Johns Hopkins Coronavirus Resource Center. It has strained our health care system and affected all specialties, including dermatology. Dermatologists have taken important safety measures by canceling/deferring elective and nonemergency procedures and diagnosing/treating patients via telemedicine. Many residents and attending dermatologists have volunteered to care for COVID-19 inpatients and donated personal protective equipment (PPE) to hospitals reporting shortages.1 As we prepare to treat increasing numbers of in-office patients, there will be a critical need for PPE. We highlight the use of 3-dimensional (3D) imaging and printing technologies as it applies to the dermatology outpatient setting.

N95 masks are necessary during the COVID-19 pandemic because they effectively filter at least 95% of 0.3-μm airborne particles and provide adequate face seals.1 3-Dimensional imaging integrated with 3D printers can be used to scan precise facial parameters (eg, jawline, nose) and account for facial hair density and length to produce comfortable tailored N95 masks and face seals.1,2 3-Dimensional printing utilizes robotics and computer-aided design systems to layer and deposit biomaterials, thereby creating cost-effective, customizable, mechanically stable, and biocompatible constructs.1,3 An ideal 3D-printed N95 mask would be printed via fused deposition modeling, consisting of a combination of lightweight and fatigue-resistant biomaterials, including electrostatic nonwoven polypropylene and styrene-(ethylene-butylene)-styrene.1,4 The resulting masks, made from industrial-grade raw materials, are practical alternatives for dermatology practices with insufficient supplies.

Face shields offer an additional layer of safety for the face and mucosae and also may provide longevity for N95 masks. Using synthetic polymers such as polycarbonate and polyethylene, 3D printers can be used to construct face shields via fused deposition modeling.1 These face shields may be worn over N95 masks and then can be sanitized and reused.

Mohs surgeons and staff may be at particularly high risk for COVID-19 infection due to their close proximity to the face during surgery, use of cautery, and prolonged time spent with patients while taking layers and suturing. Multispectral optoacoustic tomography is a noninvasive imaging tool that can map skin tumors via optical contrast with accuracy comparable to histologic measurements.5 3-Dimensional facial imaging and printing can be used to calculate tumor surface area for customized masks, leaving sufficient skin for excision and reconstruction. Patient face coverings would cover the nose and mouth, only expose relevant areas near the excision site, and include adjustable/removable ear loops for tumors localized to the ears. A schematic of how 3D technologies can be applied for Mohs micrographic surgery is provided in the Figure.

3-Dimensional (3D) imaging technologies and a 3D-printed face covering prototype that can potentially be used on patients during Mohs micrographic surgery. The biomaterials in this diagram have been well tested in the literature and are the same materials that are used in N95 masks.


As dermatologists reopen and ramp up practice volume, there will be increased PPE requirements. Using 3D technology and imaging to produce N95 masks, face shields, and face coverings, we can offer effective diagnosis and treatment while optimizing safety for dermatologists, staff, and patients.

 

Coronavirus disease 2019 (COVID-19) has spread across all 7 continents, including 185 countries, and infected more than 21.9 million individuals worldwide as of August 18, 2020, according to the Johns Hopkins Coronavirus Resource Center. It has strained our health care system and affected all specialties, including dermatology. Dermatologists have taken important safety measures by canceling/deferring elective and nonemergency procedures and diagnosing/treating patients via telemedicine. Many residents and attending dermatologists have volunteered to care for COVID-19 inpatients and donated personal protective equipment (PPE) to hospitals reporting shortages.1 As we prepare to treat increasing numbers of in-office patients, there will be a critical need for PPE. We highlight the use of 3-dimensional (3D) imaging and printing technologies as it applies to the dermatology outpatient setting.

N95 masks are necessary during the COVID-19 pandemic because they effectively filter at least 95% of 0.3-μm airborne particles and provide adequate face seals.1 3-Dimensional imaging integrated with 3D printers can be used to scan precise facial parameters (eg, jawline, nose) and account for facial hair density and length to produce comfortable tailored N95 masks and face seals.1,2 3-Dimensional printing utilizes robotics and computer-aided design systems to layer and deposit biomaterials, thereby creating cost-effective, customizable, mechanically stable, and biocompatible constructs.1,3 An ideal 3D-printed N95 mask would be printed via fused deposition modeling, consisting of a combination of lightweight and fatigue-resistant biomaterials, including electrostatic nonwoven polypropylene and styrene-(ethylene-butylene)-styrene.1,4 The resulting masks, made from industrial-grade raw materials, are practical alternatives for dermatology practices with insufficient supplies.

Face shields offer an additional layer of safety for the face and mucosae and also may provide longevity for N95 masks. Using synthetic polymers such as polycarbonate and polyethylene, 3D printers can be used to construct face shields via fused deposition modeling.1 These face shields may be worn over N95 masks and then can be sanitized and reused.

Mohs surgeons and staff may be at particularly high risk for COVID-19 infection due to their close proximity to the face during surgery, use of cautery, and prolonged time spent with patients while taking layers and suturing. Multispectral optoacoustic tomography is a noninvasive imaging tool that can map skin tumors via optical contrast with accuracy comparable to histologic measurements.5 3-Dimensional facial imaging and printing can be used to calculate tumor surface area for customized masks, leaving sufficient skin for excision and reconstruction. Patient face coverings would cover the nose and mouth, only expose relevant areas near the excision site, and include adjustable/removable ear loops for tumors localized to the ears. A schematic of how 3D technologies can be applied for Mohs micrographic surgery is provided in the Figure.

3-Dimensional (3D) imaging technologies and a 3D-printed face covering prototype that can potentially be used on patients during Mohs micrographic surgery. The biomaterials in this diagram have been well tested in the literature and are the same materials that are used in N95 masks.


As dermatologists reopen and ramp up practice volume, there will be increased PPE requirements. Using 3D technology and imaging to produce N95 masks, face shields, and face coverings, we can offer effective diagnosis and treatment while optimizing safety for dermatologists, staff, and patients.

References
  1. Ishack S, Lipner SR. Applications of 3D printing technology to address COVID-19-related supply shortages [published online April 21, 2020]. Am J Med. 2020;133:771-773.
  2. Cai M, Li H, Shen S, et al. Customized design and 3D printing of face seal for an N95 filtering facepiece respirator. J Occup Environ Hyg. 2018;3:226-234.
  3. Ishack S, Lipner SR. A review of 3-dimensional skin bioprinting techniques: applications, approaches, and trends [published online March 17, 2020]. Dermatol Surg. doi:10.1097/DSS.0000000000002378.
  4. Banerjee SS, Burbine S, Shivaprakash NK, et al. 3D-printable PP/SEBS thermoplastic elastomeric blends: preparation and properties [published online February 17, 2019]. Polymers (Basel). doi:10.3390/polym11020347.
  5. Chuah SY, Attia ABE, Long V. Structural and functional 3D mapping of skin tumours with non-invasive multispectral optoacoustic tomography [published online November 2, 2016]. Skin Res Technol. 2017;23:221-226.
References
  1. Ishack S, Lipner SR. Applications of 3D printing technology to address COVID-19-related supply shortages [published online April 21, 2020]. Am J Med. 2020;133:771-773.
  2. Cai M, Li H, Shen S, et al. Customized design and 3D printing of face seal for an N95 filtering facepiece respirator. J Occup Environ Hyg. 2018;3:226-234.
  3. Ishack S, Lipner SR. A review of 3-dimensional skin bioprinting techniques: applications, approaches, and trends [published online March 17, 2020]. Dermatol Surg. doi:10.1097/DSS.0000000000002378.
  4. Banerjee SS, Burbine S, Shivaprakash NK, et al. 3D-printable PP/SEBS thermoplastic elastomeric blends: preparation and properties [published online February 17, 2019]. Polymers (Basel). doi:10.3390/polym11020347.
  5. Chuah SY, Attia ABE, Long V. Structural and functional 3D mapping of skin tumours with non-invasive multispectral optoacoustic tomography [published online November 2, 2016]. Skin Res Technol. 2017;23:221-226.
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  • Coronavirus disease 19 has overwhelmed our health care system and affected all specialties, including dermatology.
  • There are concerns about shortages of personal protective equipment to safely care for patients.
  • 3-Dimensional imaging and printing technologies can be harnessed to create face coverings and face shields for the dermatology outpatient setting.
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Approximation of Alcohol-Based Hand Sanitizer Volume Using a Toothpaste Cap

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Wed, 09/16/2020 - 09:24
Author(s)
Mohit Kumar Gupta, BBA
Shari R. Lipner, MD, PhD

 

Practice Gap

The Centers for Disease Control and Prevention recommends handwashing with soap and water or using alcohol-based hand sanitizers to prevent transmission of coronavirus disease 2019. Five steps are delineated for effective handwashing: wetting, lathering, scrubbing, rinsing, and drying. Although alcohol-based sanitizers may be perceived as more damaging to the skin, they are less likely to cause dermatitis than handwashing with soap and water.1 Instructions are precise for handwashing, while there are no recommendations for effective use of alcohol-based hand sanitizers. A common inquiry regarding alcohol-based hand sanitizers is the volume needed for efficacy without causing skin irritation.

The Technique

Approximately 1 mL of alcohol-based hand sanitizer is recommended by some manufacturers. However, abundant evidence refutes this recommendation, including a study that tested the microbial efficacy of alcohol-based sanitizers by volume. A volume of 2 mL was necessary to achieve the 2.0 log reduction of contaminants as required by the US Food and Drug Administration for antimicrobial efficacy.2 The precise measurement of hand sanitizer using a calibrated syringe before each use is impractical. Thus, we recommend using a screw-top toothpaste cap to assist in approximating the necessary volume (Figure). The cap holds approximately 1 mL of liquid as measured using a syringe; therefore, 2 caps filled with sanitizer should be used.

Visual approximation for the appropriate volume (2 mL) of an alcoholbased hand sanitizer needed for disinfection as measured by completely filling the screw-top cap of a toothpaste tube twice.

Practice Implications

The general public may be underutilizing hand sanitizer due to fear of excessive skin irritation or supply shortages, which will reduce efficacy. Patients and physicians can use this simple visual approximation to ensure adequate use of hand sanitizer volume.

References
  1. Stutz N, Becker D, Jappe U, et al. Nurses’ perceptions of the benefits and adverse effects of hand disinfection: alcohol-based hand rubs vs. hygienic handwashing: a multicentre questionnaire study with additional patch testing by the German Contact Dermatitis Research Group. Br J Dermatol. 2009;160:565-572.
  2. Kampf G, Ruselack S, Eggerstedt S, et al. Less and less-influence of volume on hand coverage and bactericidal efficacy in hand disinfection. BMC Infect Dis. 2013;13:472.
Article PDF
CT106003133.pdf
Author and Disclosure Information

Mr. Gupta is from the State University of New York Downstate College of Medicine, Brooklyn. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Mohit Kumar Gupta, BBA
Shari R. Lipner, MD, PhD
Author(s)
Mohit Kumar Gupta, BBA
Shari R. Lipner, MD, PhD
Author and Disclosure Information

Mr. Gupta is from the State University of New York Downstate College of Medicine, Brooklyn. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

Author and Disclosure Information

Mr. Gupta is from the State University of New York Downstate College of Medicine, Brooklyn. Dr. Lipner is from the Department of Dermatology, Weill Cornell Medicine, New York, New York.

The authors report no conflict of interest.

Correspondence: Shari R. Lipner, MD, PhD, 1305 York Ave, New York, NY 10021 ([email protected]).

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Practice Gap

The Centers for Disease Control and Prevention recommends handwashing with soap and water or using alcohol-based hand sanitizers to prevent transmission of coronavirus disease 2019. Five steps are delineated for effective handwashing: wetting, lathering, scrubbing, rinsing, and drying. Although alcohol-based sanitizers may be perceived as more damaging to the skin, they are less likely to cause dermatitis than handwashing with soap and water.1 Instructions are precise for handwashing, while there are no recommendations for effective use of alcohol-based hand sanitizers. A common inquiry regarding alcohol-based hand sanitizers is the volume needed for efficacy without causing skin irritation.

The Technique

Approximately 1 mL of alcohol-based hand sanitizer is recommended by some manufacturers. However, abundant evidence refutes this recommendation, including a study that tested the microbial efficacy of alcohol-based sanitizers by volume. A volume of 2 mL was necessary to achieve the 2.0 log reduction of contaminants as required by the US Food and Drug Administration for antimicrobial efficacy.2 The precise measurement of hand sanitizer using a calibrated syringe before each use is impractical. Thus, we recommend using a screw-top toothpaste cap to assist in approximating the necessary volume (Figure). The cap holds approximately 1 mL of liquid as measured using a syringe; therefore, 2 caps filled with sanitizer should be used.

Visual approximation for the appropriate volume (2 mL) of an alcoholbased hand sanitizer needed for disinfection as measured by completely filling the screw-top cap of a toothpaste tube twice.

Practice Implications

The general public may be underutilizing hand sanitizer due to fear of excessive skin irritation or supply shortages, which will reduce efficacy. Patients and physicians can use this simple visual approximation to ensure adequate use of hand sanitizer volume.

 

Practice Gap

The Centers for Disease Control and Prevention recommends handwashing with soap and water or using alcohol-based hand sanitizers to prevent transmission of coronavirus disease 2019. Five steps are delineated for effective handwashing: wetting, lathering, scrubbing, rinsing, and drying. Although alcohol-based sanitizers may be perceived as more damaging to the skin, they are less likely to cause dermatitis than handwashing with soap and water.1 Instructions are precise for handwashing, while there are no recommendations for effective use of alcohol-based hand sanitizers. A common inquiry regarding alcohol-based hand sanitizers is the volume needed for efficacy without causing skin irritation.

The Technique

Approximately 1 mL of alcohol-based hand sanitizer is recommended by some manufacturers. However, abundant evidence refutes this recommendation, including a study that tested the microbial efficacy of alcohol-based sanitizers by volume. A volume of 2 mL was necessary to achieve the 2.0 log reduction of contaminants as required by the US Food and Drug Administration for antimicrobial efficacy.2 The precise measurement of hand sanitizer using a calibrated syringe before each use is impractical. Thus, we recommend using a screw-top toothpaste cap to assist in approximating the necessary volume (Figure). The cap holds approximately 1 mL of liquid as measured using a syringe; therefore, 2 caps filled with sanitizer should be used.

Visual approximation for the appropriate volume (2 mL) of an alcoholbased hand sanitizer needed for disinfection as measured by completely filling the screw-top cap of a toothpaste tube twice.

Practice Implications

The general public may be underutilizing hand sanitizer due to fear of excessive skin irritation or supply shortages, which will reduce efficacy. Patients and physicians can use this simple visual approximation to ensure adequate use of hand sanitizer volume.

References
  1. Stutz N, Becker D, Jappe U, et al. Nurses’ perceptions of the benefits and adverse effects of hand disinfection: alcohol-based hand rubs vs. hygienic handwashing: a multicentre questionnaire study with additional patch testing by the German Contact Dermatitis Research Group. Br J Dermatol. 2009;160:565-572.
  2. Kampf G, Ruselack S, Eggerstedt S, et al. Less and less-influence of volume on hand coverage and bactericidal efficacy in hand disinfection. BMC Infect Dis. 2013;13:472.
References
  1. Stutz N, Becker D, Jappe U, et al. Nurses’ perceptions of the benefits and adverse effects of hand disinfection: alcohol-based hand rubs vs. hygienic handwashing: a multicentre questionnaire study with additional patch testing by the German Contact Dermatitis Research Group. Br J Dermatol. 2009;160:565-572.
  2. Kampf G, Ruselack S, Eggerstedt S, et al. Less and less-influence of volume on hand coverage and bactericidal efficacy in hand disinfection. BMC Infect Dis. 2013;13:472.
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