Culprits of Medication-Induced Telogen Effluvium, Part 1

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Culprits of Medication-Induced Telogen Effluvium, Part 1
Author(s)
Donglin Zhang, BA
Charlotte Lasenna, MD
Bridget E. Shields, MD

Alopecia is a commonly reported side effect of various medications. Anagen effluvium and telogen effluvium (TE) are considered the most common mechanisms underlying medication-related hair loss. Anagen effluvium is associated with chemotherapeutic agents and radiation therapy, with anagen shedding typically occurring within 2 weeks of medication administration.1,2 Medication-induced TE is a diffuse nonscarring alopecia that is a reversible reactive process.3-5 Telogen effluvium is clinically apparent as a generalized shedding of scalp hair 1 to 6 months after an inciting cause.6 The underlying cause of TE may be multifactorial and difficult to identify given the delay between the trigger and the onset of clinically apparent hair loss. Other known triggers of TE include acute illness,7,8 nutritional deficiencies,4,9 and/or major surgery.10

Each hair follicle independently and sequentially progresses through anagen growth, catagen transition, and telogen resting phases. In the human scalp, the telogen phase typically lasts 3 months, at the end of which the telogen hair is extruded from the scalp. Anagen and telogen follicles typically account for an average of 90% and 10% of follicles on the human scalp, respectively.11 Immediate anagen release is hypothesized to be the mechanism underlying medication-induced TE.12 This theory suggests that an increased percentage of anagen follicles prematurely enter the telogen phase, with a notable increase in hair shedding at the conclusion of the telogen phase approximately 1 to 6 months later.12 First-line management of medication-induced TE is identification and cessation of the causative agent, if possible. Notable regrowth of hair is expected several months after removal of the inciting medication. In part 1 of this 2-part series, we review the existing literature to identify common culprits of medication-induced TE, including retinoids, antifungals, and psychotropic medications.

Retinoids

Retinoids are vitamin A derivatives used in the treatment of a myriad of dermatologic and nondermatologic conditions.13,14 Retinoids modulate sebum production,15 keratinocyte proliferation,16 and epithelial differentiation through signal transduction downstream of the ligand-activated nuclear retinoic acid receptors and retinoid X receptors.13,14,17 The recommended daily dosage of retinol is 900 µg retinol activity equivalent (3000 IU) for men and 700 µg retinol activity equivalent (2333 IU) for women. Retinoids are used in the treatment of acne vulgaris,18 psoriasis,19 and ichthyosis.20 The most commonly reported adverse effects of systemic retinoid therapy include cheilitis, alopecia, and xerosis.21 Retinoid-associated alopecia is dose and duration dependent.19,21-24 A prospective study of acitretin therapy in plaque psoriasis reported that more than 63% (42/66) of patients on 50 mg or more of acitretin daily for 6 months or longer experienced alopecia that reversed with discontinuation.23 A systematic review of isotretinoin use in acne showed alopecia was seen in 3.2% (18/565) of patients on less than 0.5 mg/kg/d of isotretinoin and in 5.7% (192/3375) of patients on 0.5 mg/kg/d or less of isotretinoin.24 In a phase 2 clinical trial of orally administered 9-cis-retinoic acid (alitretinoin) in the treatment of Kaposi sarcoma related to AIDS, 42% (24/57) of adult male patients receiving 60, 100, or 140 mg/m2 alitretinoin daily (median treatment duration, 15.1 weeks) reported alopecia as an adverse effect of treatment.25 In one case report, a patient who ingested 500,000 IU of vitamin A daily for 4 months and then 100,000 IU monthly for 6 months experienced diffusely increased shedding of scalp hair along with muscle soreness, nail dystrophy, diffuse skin rash, and refractory ascites; he was found to have severe liver damage secondary to hypervitaminosis A that required liver transplantation.26 Regarding the pathomechanism of retinoid-induced alopecia, animal and in vitro studies similarly have demonstrated that all-trans-retinoic acid appears to exert its inhibitory effects on hair follicle growth via the influence of the transforming growth factor β2 and SMAD2/3 pathway influence on dermal papillae cells.14,27 Development of hair loss secondary to systemic retinoid therapy may be managed with dose reduction or cessation.

Antifungals

Azole medications have broad-spectrum fungistatic activity against a wide range of yeast and filamentous fungi. Azoles inhibit sterol 14α-demethylase activity, impairing ergosterol synthesis and thereby disrupting plasma membrane synthesis and activity of membrane-bound enzymes.28 Fluconazole is a systemic oral agent in this class that was first approved by the US Food and Drug Administration (FDA) for use in the 1990s.29 A retrospective study by the National Institute of Allergy and Infectious Disease Mycoses Study Group followed the clinical course of 33 patients who developed alopecia while receiving fluconazole therapy for various mycoses.30 The majority (88% [29/33]) of patients received 400 mg or more of fluconazole daily. The median time to hair loss after starting fluconazole was 3 months, and the scalp was involved in all cases. In 97% (32/33) of patients, resolution of alopecia was noted following discontinuation of fluconazole or a dose reduction of 50% or more. In 85% (28/33) of patients, complete resolution of alopecia occurred within 6 months of fluconazole cessation or dose reduction.30 Fluconazole-induced TE was reproducible in an animal model using Wistar rats31; however, further studies are required to clarify the molecular pathways of its effect on hair growth.

Voriconazole is an azole approved for the treatment of invasive aspergillosis, candidemia, and fungal infections caused by Scedosporium apiospermum and Fusarium species. A retrospective survey study of patients who received voriconazole for 1 month or longer found a considerable proportion of patients developed diffuse reversible hair loss.32 Scalp alopecia was noted in 79% (120/152) of patients who completed the survey, with a mean (SD) time to alopecia of 75 (54) days after initiation of voriconazole. Notable regrowth was reported in 69% (79/114) of patients who discontinued voriconazole for at least 3 months. A subgroup of 32 patients were changed to itraconazole or posaconazole, and hair loss stopped in 84% (27/32) with regrowth noted in 69% (22/32) of patients.32 Voriconazole and fluconazole share structural similarity not present with other triazoles.33,34 Because voriconazole-associated alopecia was reversed in the majority of patients who switched to itraconazole or posaconazole, the authors hypothesized that structural similarity of fluconazole and voriconazole may underly the greater risk for TE that is not a class effect of azole medications.31

Psychotropic Medications

Various psychotropic medications have been associated with hair loss. Valproic acid (or sodium valproate) is an anticonvulsant and mood-stabilizing agent used for the treatment of seizures, bipolar disorder (BD), migraines, and neuropathic pain.35,36 Divalproex sodium (or divalproex) is an enteric-coated formulation of sodium valproate and valproic acid with similar indications. Valproate is a notorious culprit of medication-induced hair loss, with alopecia listed among the most common adverse reactions (reported >5%) on its structure product labeling document.37 A systemic review and meta-analysis by Wang et al38 estimated the overall incidence of valproate-related alopecia to be 11% (95% CI, 0.08-0.13). Although this meta-analysis did not find an association between incidence of alopecia and dose or duration of valproate therapy,38 a separate review suggested that valproate-induced alopecia is dose dependent and can be managed with dose reduction.39 A 12-month, randomized, double-blind study of treatment of BD with divalproex (valproate derivative), lithium, or placebo (2:1:1 ratio) showed a significantly higher frequency of alopecia in the divalproex group compared with placebo (16% [30/187] vs 6% [6/94]; P=.03).40 Valproate-related hair loss is characteristically diffuse and nonscarring, often noted 3 to 6 months following initiation of valproate.41,42 The proposed mechanism of valproate-induced alopecia includes chelation of zinc and selenium,43 and a reduction in serum biotinidase activity, thereby decreasing the availability of these essential micronutrients required for hair growth.41 Studies examining the effects of valproate administration and serum biotinidase activity in patients have yielded conflicting results.44-46 In a study of children with seizures including 57 patients treated with valproic acid, 17 treated with carbamazepine, and 75 age- and sex-matched healthy controls, the authors found no significant differences in serum biotinidase enzyme activity across the 3 groups.44 In contrast, a study of 75 children with seizures on valproic acid therapy stratified by dose (mean [SD])—group A: 28.7 [8.5] mg/kg/d; group B: 41.6 [4.9] mg/kg/d; group C: 64.5 [5.8] mg/kg/d—found that patients receiving higher doses (groups B and C) had significantly reduced serum biotinidase activity (1.22 [1.11] and 0.97 [0.07] mmol/min/L, respectively) compared with 50 healthy pediatric controls (5.20 [0.90] mmol/min/L; P<.001). The same study found biotin supplementation at 10 mg/d for 20 days led to resolution of alopecia in 22% (2/9) of patients with alopecia on valproic acid therapy.45 Despite hypothesized effects of valproate on micronutrients, the role of mineral supplementation in treating valproate-associated hair loss remains unclear. There is evidence to suggest that valproic acid–associated alterations in serum biotinidase activity may be transient. In a study of 32 pediatric patients receiving valproic acid for the treatment of epilepsy, serum biotinidase activity was significantly lower after 3 months of valproic acid therapy compared with pretreatment levels (P<.05); at 6 months, the serum biotinidase activity was increased compared with 3 months (P<.05) and not significantly different from pretreatment levels (P>.05).46 Hair regrowth has been observed following discontinuation or dose reduction of valproate therapy in some cases.39,47

Lithium carbonate (lithium) is used in the treatment of BD. Despite its efficacy and low cost, its potential for adverse effects, narrow therapeutic index, and subsequent need for routine monitoring are factors that limit its use.48 Some reported dermatologic adverse reactions on its structure product labeling include xerosis, thinning of hair, alopecia, xerosis cutis, psoriasis onset/exacerbation, and generalized pruritus.49 A systematic review and meta-analysis of 385 studies identified 24 publications reporting adverse effects of lithium on hair with no significantly increased risk of alopecia overall.50 The analysis included 2 randomized controlled trials comparing the effects of lithium and placebo on hair loss in patients with BD. Hair loss was reported in 7% (7/94) of patients taking lithium and 6% (6/94) of the placebo group in the 12-month study40 and in 3% (1/32) of the lithium group and 0% (0/28) of the divalproex group in the 20-month study.51 Despite anecdotal reports of alopecia associated with lithium, there is a lack of high-quality evidence to support this claim. Of note, hypothyroidism is a known complication of lithium use, and serum testing of thyroid function at 6-month intervals is recommended for patients on lithium treatment.52 Because thyroid abnormalities can cause alopecia distinct from TE, new-onset alopecia during lithium use should prompt serum testing of thyroid function. The development of hypothyroidism secondary to lithium is not a direct contraindication to its use53; rather, treatment should be focused on correction with thyroid replacement therapy (eg, supplementation with thyroxine).54

 

 

Commonly prescribed antidepressant medications include selective serotonin reuptake inhibitors (SSRIs) and bupropion. Selective serotonin reuptake inhibitors affect the neuronal serotonin transporter, increasing the concentration of serotonin in the synaptic cleft available for stimulation of postsynaptic serotonin receptors55,56; bupropion is an antidepressant medication that inhibits norepinephrine and dopamine reuptake at the synaptic cleft.57 Alopecia is an infrequent (1 in 100 to 1 in 1000 patients) adverse effect for several SSRIs.58-62 A recent systematic review identified a total of 71 cases of alopecia associated with SSRI use including citalopram (n=11), escitalopram (n=7), fluoxetine (n=27), fluoxvamine (n=5), paroxetine (n=4), and sertraline (n=20), with a median time to onset of hair shedding of 8.6 weeks (range, 3 days to 5 years). Discontinuation of the suspected culprit SSRI led to improvement and/or resolution in 63% (51/81) episodes of alopecia, with a median time to improvement and/or resolution of 4 weeks.63 A comparative retrospective cohort study using a large US health claims database from 2006 to 2014 included more than 1 million new and mutually exclusive patients taking fluoxetine, fluvoxamine, sertraline, citalopram, escitalopram, paroxetine, duloxetine, venlafaxine, desvenlafaxine, and bupropion.64 Overall, 1% (1569/150,404) of patients treated with bupropion received 1 or more physician visits for alopecia. Patients on SSRIs generally had a lower risk for hair loss compared with patients using bupropion (citalopram: hazard ratio [HR], 0.80 [95% CI, 0.74-0.86]; escitalopram: HR, 0.79 [95% CI, 0.74-0.86]; fluoxetine: HR, 0.68 [95% CI, 0.63-0.74]; paroxetine: HR, 0.68 [95% CI, 0.62-0.74]; sertraline: HR, 0.74 [95% CI, 0.69-0.79]), with the exception of fluvoxamine (HR, 0.93 [95% CI, 0.64-1.37]). However, the type of alopecia, time to onset, and time to resolution were not reported, making it difficult to assess whether the reported hair loss was consistent with medication-induced TE. Additionally, the authors acknowledged that bupropion may have been prescribed for smoking cessation, which may carry a different risk profile for the development of alopecia.64 Several other case reports have described alopecia following treatment with SSRIs, including sertraline,65 fluvoxamine,66 paroxetine,67 fluoxetine,68 and escitalopram.69

Overall, it appears that the use of SSRIs portends relatively low risk for alopecia and medication-induced TE. Little is known regarding the molecular effects of SSRIs on hair growth and the pathomechanism of SSRI-induced TE. The potential benefits of discontinuing a suspected culprit medication should be carefully weighed against the risks of medication cessation, and consideration should be given to alternative medications in the same class that also may be associated with TE. In patients requiring antidepressant therapy with suspected medication-induced TE, consider transitioning to a different class of medication with lower risk of medication-induced alopecia; for example, discontinuing bupropion in favor of an SSRI.

Final Thoughts

Medication-induced alopecia is an undesired side effect of many commonly used drugs and drug classes, including retinoids, azole antifungals, and mood stabilizers. Although the precise pathomechanisms of medication-induced TE remain unclear, the recommended management often requires identification of the likely causative agent and its discontinuation, if possible. Suspicion for medication-induced TE should prompt a thorough history of recent changes to medications, risk factors for nutritional deficiencies, underlying illnesses, and recent surgical procedures. Underlying nutritional, electrolyte, and/or metabolic disturbances should be corrected. In part 2 of this series, we will discuss medication-induced alopecia associated with anticoagulant and antihypertensive medications.

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  66. Parameshwar E. Hair loss associated with fluvoxamine use. Am J Psychiatry. 1996;153:581-582. doi:10.1176/ajp.153.4.581
  67. Zalsman G, Sever J, Munitz H. Hair loss associated with paroxetine treatment: a case report. Clin Neuropharmacol. 1999;22:246-247.
  68. Ananth J, Elmishaugh A. Hair loss associated with fluoxetinetreatment. Can J Psychiatry. 1991;36:621. doi:10.1177/070674379103600824
  69. Tirmazi SI, Imran H, Rasheed A, et al. Escitalopram-induced hair loss. Prim Care Companion CNS Disord. 2020;22:19l02496. doi:10.4088/PCC.19l02496
Article PDF
CT112006267.pdf
Author and Disclosure Information

From the Department of Dermatology, University of Wisconsin School of Medicine and Public Health, Madison.

Donglin Zhang and Dr. LaSenna report no conflict of interest. Dr. Shields has received a grant from the Dermatology Foundation.

This article is part 1 of a 2-part series. The second part will appear next month.

Correspondence: Bridget E. Shields, MD, Department of Dermatology, University of Wisconsin, 1 S Park St, Madison, WI 53715([email protected]).

Issue
Cutis - 112(6)
Publications
MDedge Dermatology
Cutis
Topics
Hair & Nails
Page Number
267-271
Sections
Food for Thought
Author(s)
Donglin Zhang, BA
Charlotte Lasenna, MD
Bridget E. Shields, MD
Author(s)
Donglin Zhang, BA
Charlotte Lasenna, MD
Bridget E. Shields, MD
Author and Disclosure Information

From the Department of Dermatology, University of Wisconsin School of Medicine and Public Health, Madison.

Donglin Zhang and Dr. LaSenna report no conflict of interest. Dr. Shields has received a grant from the Dermatology Foundation.

This article is part 1 of a 2-part series. The second part will appear next month.

Correspondence: Bridget E. Shields, MD, Department of Dermatology, University of Wisconsin, 1 S Park St, Madison, WI 53715([email protected]).

Author and Disclosure Information

From the Department of Dermatology, University of Wisconsin School of Medicine and Public Health, Madison.

Donglin Zhang and Dr. LaSenna report no conflict of interest. Dr. Shields has received a grant from the Dermatology Foundation.

This article is part 1 of a 2-part series. The second part will appear next month.

Correspondence: Bridget E. Shields, MD, Department of Dermatology, University of Wisconsin, 1 S Park St, Madison, WI 53715([email protected]).

Article PDF
CT112006267.pdf
Article PDF
CT112006267.pdf

Alopecia is a commonly reported side effect of various medications. Anagen effluvium and telogen effluvium (TE) are considered the most common mechanisms underlying medication-related hair loss. Anagen effluvium is associated with chemotherapeutic agents and radiation therapy, with anagen shedding typically occurring within 2 weeks of medication administration.1,2 Medication-induced TE is a diffuse nonscarring alopecia that is a reversible reactive process.3-5 Telogen effluvium is clinically apparent as a generalized shedding of scalp hair 1 to 6 months after an inciting cause.6 The underlying cause of TE may be multifactorial and difficult to identify given the delay between the trigger and the onset of clinically apparent hair loss. Other known triggers of TE include acute illness,7,8 nutritional deficiencies,4,9 and/or major surgery.10

Each hair follicle independently and sequentially progresses through anagen growth, catagen transition, and telogen resting phases. In the human scalp, the telogen phase typically lasts 3 months, at the end of which the telogen hair is extruded from the scalp. Anagen and telogen follicles typically account for an average of 90% and 10% of follicles on the human scalp, respectively.11 Immediate anagen release is hypothesized to be the mechanism underlying medication-induced TE.12 This theory suggests that an increased percentage of anagen follicles prematurely enter the telogen phase, with a notable increase in hair shedding at the conclusion of the telogen phase approximately 1 to 6 months later.12 First-line management of medication-induced TE is identification and cessation of the causative agent, if possible. Notable regrowth of hair is expected several months after removal of the inciting medication. In part 1 of this 2-part series, we review the existing literature to identify common culprits of medication-induced TE, including retinoids, antifungals, and psychotropic medications.

Retinoids

Retinoids are vitamin A derivatives used in the treatment of a myriad of dermatologic and nondermatologic conditions.13,14 Retinoids modulate sebum production,15 keratinocyte proliferation,16 and epithelial differentiation through signal transduction downstream of the ligand-activated nuclear retinoic acid receptors and retinoid X receptors.13,14,17 The recommended daily dosage of retinol is 900 µg retinol activity equivalent (3000 IU) for men and 700 µg retinol activity equivalent (2333 IU) for women. Retinoids are used in the treatment of acne vulgaris,18 psoriasis,19 and ichthyosis.20 The most commonly reported adverse effects of systemic retinoid therapy include cheilitis, alopecia, and xerosis.21 Retinoid-associated alopecia is dose and duration dependent.19,21-24 A prospective study of acitretin therapy in plaque psoriasis reported that more than 63% (42/66) of patients on 50 mg or more of acitretin daily for 6 months or longer experienced alopecia that reversed with discontinuation.23 A systematic review of isotretinoin use in acne showed alopecia was seen in 3.2% (18/565) of patients on less than 0.5 mg/kg/d of isotretinoin and in 5.7% (192/3375) of patients on 0.5 mg/kg/d or less of isotretinoin.24 In a phase 2 clinical trial of orally administered 9-cis-retinoic acid (alitretinoin) in the treatment of Kaposi sarcoma related to AIDS, 42% (24/57) of adult male patients receiving 60, 100, or 140 mg/m2 alitretinoin daily (median treatment duration, 15.1 weeks) reported alopecia as an adverse effect of treatment.25 In one case report, a patient who ingested 500,000 IU of vitamin A daily for 4 months and then 100,000 IU monthly for 6 months experienced diffusely increased shedding of scalp hair along with muscle soreness, nail dystrophy, diffuse skin rash, and refractory ascites; he was found to have severe liver damage secondary to hypervitaminosis A that required liver transplantation.26 Regarding the pathomechanism of retinoid-induced alopecia, animal and in vitro studies similarly have demonstrated that all-trans-retinoic acid appears to exert its inhibitory effects on hair follicle growth via the influence of the transforming growth factor β2 and SMAD2/3 pathway influence on dermal papillae cells.14,27 Development of hair loss secondary to systemic retinoid therapy may be managed with dose reduction or cessation.

Antifungals

Azole medications have broad-spectrum fungistatic activity against a wide range of yeast and filamentous fungi. Azoles inhibit sterol 14α-demethylase activity, impairing ergosterol synthesis and thereby disrupting plasma membrane synthesis and activity of membrane-bound enzymes.28 Fluconazole is a systemic oral agent in this class that was first approved by the US Food and Drug Administration (FDA) for use in the 1990s.29 A retrospective study by the National Institute of Allergy and Infectious Disease Mycoses Study Group followed the clinical course of 33 patients who developed alopecia while receiving fluconazole therapy for various mycoses.30 The majority (88% [29/33]) of patients received 400 mg or more of fluconazole daily. The median time to hair loss after starting fluconazole was 3 months, and the scalp was involved in all cases. In 97% (32/33) of patients, resolution of alopecia was noted following discontinuation of fluconazole or a dose reduction of 50% or more. In 85% (28/33) of patients, complete resolution of alopecia occurred within 6 months of fluconazole cessation or dose reduction.30 Fluconazole-induced TE was reproducible in an animal model using Wistar rats31; however, further studies are required to clarify the molecular pathways of its effect on hair growth.

Voriconazole is an azole approved for the treatment of invasive aspergillosis, candidemia, and fungal infections caused by Scedosporium apiospermum and Fusarium species. A retrospective survey study of patients who received voriconazole for 1 month or longer found a considerable proportion of patients developed diffuse reversible hair loss.32 Scalp alopecia was noted in 79% (120/152) of patients who completed the survey, with a mean (SD) time to alopecia of 75 (54) days after initiation of voriconazole. Notable regrowth was reported in 69% (79/114) of patients who discontinued voriconazole for at least 3 months. A subgroup of 32 patients were changed to itraconazole or posaconazole, and hair loss stopped in 84% (27/32) with regrowth noted in 69% (22/32) of patients.32 Voriconazole and fluconazole share structural similarity not present with other triazoles.33,34 Because voriconazole-associated alopecia was reversed in the majority of patients who switched to itraconazole or posaconazole, the authors hypothesized that structural similarity of fluconazole and voriconazole may underly the greater risk for TE that is not a class effect of azole medications.31

Psychotropic Medications

Various psychotropic medications have been associated with hair loss. Valproic acid (or sodium valproate) is an anticonvulsant and mood-stabilizing agent used for the treatment of seizures, bipolar disorder (BD), migraines, and neuropathic pain.35,36 Divalproex sodium (or divalproex) is an enteric-coated formulation of sodium valproate and valproic acid with similar indications. Valproate is a notorious culprit of medication-induced hair loss, with alopecia listed among the most common adverse reactions (reported >5%) on its structure product labeling document.37 A systemic review and meta-analysis by Wang et al38 estimated the overall incidence of valproate-related alopecia to be 11% (95% CI, 0.08-0.13). Although this meta-analysis did not find an association between incidence of alopecia and dose or duration of valproate therapy,38 a separate review suggested that valproate-induced alopecia is dose dependent and can be managed with dose reduction.39 A 12-month, randomized, double-blind study of treatment of BD with divalproex (valproate derivative), lithium, or placebo (2:1:1 ratio) showed a significantly higher frequency of alopecia in the divalproex group compared with placebo (16% [30/187] vs 6% [6/94]; P=.03).40 Valproate-related hair loss is characteristically diffuse and nonscarring, often noted 3 to 6 months following initiation of valproate.41,42 The proposed mechanism of valproate-induced alopecia includes chelation of zinc and selenium,43 and a reduction in serum biotinidase activity, thereby decreasing the availability of these essential micronutrients required for hair growth.41 Studies examining the effects of valproate administration and serum biotinidase activity in patients have yielded conflicting results.44-46 In a study of children with seizures including 57 patients treated with valproic acid, 17 treated with carbamazepine, and 75 age- and sex-matched healthy controls, the authors found no significant differences in serum biotinidase enzyme activity across the 3 groups.44 In contrast, a study of 75 children with seizures on valproic acid therapy stratified by dose (mean [SD])—group A: 28.7 [8.5] mg/kg/d; group B: 41.6 [4.9] mg/kg/d; group C: 64.5 [5.8] mg/kg/d—found that patients receiving higher doses (groups B and C) had significantly reduced serum biotinidase activity (1.22 [1.11] and 0.97 [0.07] mmol/min/L, respectively) compared with 50 healthy pediatric controls (5.20 [0.90] mmol/min/L; P<.001). The same study found biotin supplementation at 10 mg/d for 20 days led to resolution of alopecia in 22% (2/9) of patients with alopecia on valproic acid therapy.45 Despite hypothesized effects of valproate on micronutrients, the role of mineral supplementation in treating valproate-associated hair loss remains unclear. There is evidence to suggest that valproic acid–associated alterations in serum biotinidase activity may be transient. In a study of 32 pediatric patients receiving valproic acid for the treatment of epilepsy, serum biotinidase activity was significantly lower after 3 months of valproic acid therapy compared with pretreatment levels (P<.05); at 6 months, the serum biotinidase activity was increased compared with 3 months (P<.05) and not significantly different from pretreatment levels (P>.05).46 Hair regrowth has been observed following discontinuation or dose reduction of valproate therapy in some cases.39,47

Lithium carbonate (lithium) is used in the treatment of BD. Despite its efficacy and low cost, its potential for adverse effects, narrow therapeutic index, and subsequent need for routine monitoring are factors that limit its use.48 Some reported dermatologic adverse reactions on its structure product labeling include xerosis, thinning of hair, alopecia, xerosis cutis, psoriasis onset/exacerbation, and generalized pruritus.49 A systematic review and meta-analysis of 385 studies identified 24 publications reporting adverse effects of lithium on hair with no significantly increased risk of alopecia overall.50 The analysis included 2 randomized controlled trials comparing the effects of lithium and placebo on hair loss in patients with BD. Hair loss was reported in 7% (7/94) of patients taking lithium and 6% (6/94) of the placebo group in the 12-month study40 and in 3% (1/32) of the lithium group and 0% (0/28) of the divalproex group in the 20-month study.51 Despite anecdotal reports of alopecia associated with lithium, there is a lack of high-quality evidence to support this claim. Of note, hypothyroidism is a known complication of lithium use, and serum testing of thyroid function at 6-month intervals is recommended for patients on lithium treatment.52 Because thyroid abnormalities can cause alopecia distinct from TE, new-onset alopecia during lithium use should prompt serum testing of thyroid function. The development of hypothyroidism secondary to lithium is not a direct contraindication to its use53; rather, treatment should be focused on correction with thyroid replacement therapy (eg, supplementation with thyroxine).54

 

 

Commonly prescribed antidepressant medications include selective serotonin reuptake inhibitors (SSRIs) and bupropion. Selective serotonin reuptake inhibitors affect the neuronal serotonin transporter, increasing the concentration of serotonin in the synaptic cleft available for stimulation of postsynaptic serotonin receptors55,56; bupropion is an antidepressant medication that inhibits norepinephrine and dopamine reuptake at the synaptic cleft.57 Alopecia is an infrequent (1 in 100 to 1 in 1000 patients) adverse effect for several SSRIs.58-62 A recent systematic review identified a total of 71 cases of alopecia associated with SSRI use including citalopram (n=11), escitalopram (n=7), fluoxetine (n=27), fluoxvamine (n=5), paroxetine (n=4), and sertraline (n=20), with a median time to onset of hair shedding of 8.6 weeks (range, 3 days to 5 years). Discontinuation of the suspected culprit SSRI led to improvement and/or resolution in 63% (51/81) episodes of alopecia, with a median time to improvement and/or resolution of 4 weeks.63 A comparative retrospective cohort study using a large US health claims database from 2006 to 2014 included more than 1 million new and mutually exclusive patients taking fluoxetine, fluvoxamine, sertraline, citalopram, escitalopram, paroxetine, duloxetine, venlafaxine, desvenlafaxine, and bupropion.64 Overall, 1% (1569/150,404) of patients treated with bupropion received 1 or more physician visits for alopecia. Patients on SSRIs generally had a lower risk for hair loss compared with patients using bupropion (citalopram: hazard ratio [HR], 0.80 [95% CI, 0.74-0.86]; escitalopram: HR, 0.79 [95% CI, 0.74-0.86]; fluoxetine: HR, 0.68 [95% CI, 0.63-0.74]; paroxetine: HR, 0.68 [95% CI, 0.62-0.74]; sertraline: HR, 0.74 [95% CI, 0.69-0.79]), with the exception of fluvoxamine (HR, 0.93 [95% CI, 0.64-1.37]). However, the type of alopecia, time to onset, and time to resolution were not reported, making it difficult to assess whether the reported hair loss was consistent with medication-induced TE. Additionally, the authors acknowledged that bupropion may have been prescribed for smoking cessation, which may carry a different risk profile for the development of alopecia.64 Several other case reports have described alopecia following treatment with SSRIs, including sertraline,65 fluvoxamine,66 paroxetine,67 fluoxetine,68 and escitalopram.69

Overall, it appears that the use of SSRIs portends relatively low risk for alopecia and medication-induced TE. Little is known regarding the molecular effects of SSRIs on hair growth and the pathomechanism of SSRI-induced TE. The potential benefits of discontinuing a suspected culprit medication should be carefully weighed against the risks of medication cessation, and consideration should be given to alternative medications in the same class that also may be associated with TE. In patients requiring antidepressant therapy with suspected medication-induced TE, consider transitioning to a different class of medication with lower risk of medication-induced alopecia; for example, discontinuing bupropion in favor of an SSRI.

Final Thoughts

Medication-induced alopecia is an undesired side effect of many commonly used drugs and drug classes, including retinoids, azole antifungals, and mood stabilizers. Although the precise pathomechanisms of medication-induced TE remain unclear, the recommended management often requires identification of the likely causative agent and its discontinuation, if possible. Suspicion for medication-induced TE should prompt a thorough history of recent changes to medications, risk factors for nutritional deficiencies, underlying illnesses, and recent surgical procedures. Underlying nutritional, electrolyte, and/or metabolic disturbances should be corrected. In part 2 of this series, we will discuss medication-induced alopecia associated with anticoagulant and antihypertensive medications.

Alopecia is a commonly reported side effect of various medications. Anagen effluvium and telogen effluvium (TE) are considered the most common mechanisms underlying medication-related hair loss. Anagen effluvium is associated with chemotherapeutic agents and radiation therapy, with anagen shedding typically occurring within 2 weeks of medication administration.1,2 Medication-induced TE is a diffuse nonscarring alopecia that is a reversible reactive process.3-5 Telogen effluvium is clinically apparent as a generalized shedding of scalp hair 1 to 6 months after an inciting cause.6 The underlying cause of TE may be multifactorial and difficult to identify given the delay between the trigger and the onset of clinically apparent hair loss. Other known triggers of TE include acute illness,7,8 nutritional deficiencies,4,9 and/or major surgery.10

Each hair follicle independently and sequentially progresses through anagen growth, catagen transition, and telogen resting phases. In the human scalp, the telogen phase typically lasts 3 months, at the end of which the telogen hair is extruded from the scalp. Anagen and telogen follicles typically account for an average of 90% and 10% of follicles on the human scalp, respectively.11 Immediate anagen release is hypothesized to be the mechanism underlying medication-induced TE.12 This theory suggests that an increased percentage of anagen follicles prematurely enter the telogen phase, with a notable increase in hair shedding at the conclusion of the telogen phase approximately 1 to 6 months later.12 First-line management of medication-induced TE is identification and cessation of the causative agent, if possible. Notable regrowth of hair is expected several months after removal of the inciting medication. In part 1 of this 2-part series, we review the existing literature to identify common culprits of medication-induced TE, including retinoids, antifungals, and psychotropic medications.

Retinoids

Retinoids are vitamin A derivatives used in the treatment of a myriad of dermatologic and nondermatologic conditions.13,14 Retinoids modulate sebum production,15 keratinocyte proliferation,16 and epithelial differentiation through signal transduction downstream of the ligand-activated nuclear retinoic acid receptors and retinoid X receptors.13,14,17 The recommended daily dosage of retinol is 900 µg retinol activity equivalent (3000 IU) for men and 700 µg retinol activity equivalent (2333 IU) for women. Retinoids are used in the treatment of acne vulgaris,18 psoriasis,19 and ichthyosis.20 The most commonly reported adverse effects of systemic retinoid therapy include cheilitis, alopecia, and xerosis.21 Retinoid-associated alopecia is dose and duration dependent.19,21-24 A prospective study of acitretin therapy in plaque psoriasis reported that more than 63% (42/66) of patients on 50 mg or more of acitretin daily for 6 months or longer experienced alopecia that reversed with discontinuation.23 A systematic review of isotretinoin use in acne showed alopecia was seen in 3.2% (18/565) of patients on less than 0.5 mg/kg/d of isotretinoin and in 5.7% (192/3375) of patients on 0.5 mg/kg/d or less of isotretinoin.24 In a phase 2 clinical trial of orally administered 9-cis-retinoic acid (alitretinoin) in the treatment of Kaposi sarcoma related to AIDS, 42% (24/57) of adult male patients receiving 60, 100, or 140 mg/m2 alitretinoin daily (median treatment duration, 15.1 weeks) reported alopecia as an adverse effect of treatment.25 In one case report, a patient who ingested 500,000 IU of vitamin A daily for 4 months and then 100,000 IU monthly for 6 months experienced diffusely increased shedding of scalp hair along with muscle soreness, nail dystrophy, diffuse skin rash, and refractory ascites; he was found to have severe liver damage secondary to hypervitaminosis A that required liver transplantation.26 Regarding the pathomechanism of retinoid-induced alopecia, animal and in vitro studies similarly have demonstrated that all-trans-retinoic acid appears to exert its inhibitory effects on hair follicle growth via the influence of the transforming growth factor β2 and SMAD2/3 pathway influence on dermal papillae cells.14,27 Development of hair loss secondary to systemic retinoid therapy may be managed with dose reduction or cessation.

Antifungals

Azole medications have broad-spectrum fungistatic activity against a wide range of yeast and filamentous fungi. Azoles inhibit sterol 14α-demethylase activity, impairing ergosterol synthesis and thereby disrupting plasma membrane synthesis and activity of membrane-bound enzymes.28 Fluconazole is a systemic oral agent in this class that was first approved by the US Food and Drug Administration (FDA) for use in the 1990s.29 A retrospective study by the National Institute of Allergy and Infectious Disease Mycoses Study Group followed the clinical course of 33 patients who developed alopecia while receiving fluconazole therapy for various mycoses.30 The majority (88% [29/33]) of patients received 400 mg or more of fluconazole daily. The median time to hair loss after starting fluconazole was 3 months, and the scalp was involved in all cases. In 97% (32/33) of patients, resolution of alopecia was noted following discontinuation of fluconazole or a dose reduction of 50% or more. In 85% (28/33) of patients, complete resolution of alopecia occurred within 6 months of fluconazole cessation or dose reduction.30 Fluconazole-induced TE was reproducible in an animal model using Wistar rats31; however, further studies are required to clarify the molecular pathways of its effect on hair growth.

Voriconazole is an azole approved for the treatment of invasive aspergillosis, candidemia, and fungal infections caused by Scedosporium apiospermum and Fusarium species. A retrospective survey study of patients who received voriconazole for 1 month or longer found a considerable proportion of patients developed diffuse reversible hair loss.32 Scalp alopecia was noted in 79% (120/152) of patients who completed the survey, with a mean (SD) time to alopecia of 75 (54) days after initiation of voriconazole. Notable regrowth was reported in 69% (79/114) of patients who discontinued voriconazole for at least 3 months. A subgroup of 32 patients were changed to itraconazole or posaconazole, and hair loss stopped in 84% (27/32) with regrowth noted in 69% (22/32) of patients.32 Voriconazole and fluconazole share structural similarity not present with other triazoles.33,34 Because voriconazole-associated alopecia was reversed in the majority of patients who switched to itraconazole or posaconazole, the authors hypothesized that structural similarity of fluconazole and voriconazole may underly the greater risk for TE that is not a class effect of azole medications.31

Psychotropic Medications

Various psychotropic medications have been associated with hair loss. Valproic acid (or sodium valproate) is an anticonvulsant and mood-stabilizing agent used for the treatment of seizures, bipolar disorder (BD), migraines, and neuropathic pain.35,36 Divalproex sodium (or divalproex) is an enteric-coated formulation of sodium valproate and valproic acid with similar indications. Valproate is a notorious culprit of medication-induced hair loss, with alopecia listed among the most common adverse reactions (reported >5%) on its structure product labeling document.37 A systemic review and meta-analysis by Wang et al38 estimated the overall incidence of valproate-related alopecia to be 11% (95% CI, 0.08-0.13). Although this meta-analysis did not find an association between incidence of alopecia and dose or duration of valproate therapy,38 a separate review suggested that valproate-induced alopecia is dose dependent and can be managed with dose reduction.39 A 12-month, randomized, double-blind study of treatment of BD with divalproex (valproate derivative), lithium, or placebo (2:1:1 ratio) showed a significantly higher frequency of alopecia in the divalproex group compared with placebo (16% [30/187] vs 6% [6/94]; P=.03).40 Valproate-related hair loss is characteristically diffuse and nonscarring, often noted 3 to 6 months following initiation of valproate.41,42 The proposed mechanism of valproate-induced alopecia includes chelation of zinc and selenium,43 and a reduction in serum biotinidase activity, thereby decreasing the availability of these essential micronutrients required for hair growth.41 Studies examining the effects of valproate administration and serum biotinidase activity in patients have yielded conflicting results.44-46 In a study of children with seizures including 57 patients treated with valproic acid, 17 treated with carbamazepine, and 75 age- and sex-matched healthy controls, the authors found no significant differences in serum biotinidase enzyme activity across the 3 groups.44 In contrast, a study of 75 children with seizures on valproic acid therapy stratified by dose (mean [SD])—group A: 28.7 [8.5] mg/kg/d; group B: 41.6 [4.9] mg/kg/d; group C: 64.5 [5.8] mg/kg/d—found that patients receiving higher doses (groups B and C) had significantly reduced serum biotinidase activity (1.22 [1.11] and 0.97 [0.07] mmol/min/L, respectively) compared with 50 healthy pediatric controls (5.20 [0.90] mmol/min/L; P<.001). The same study found biotin supplementation at 10 mg/d for 20 days led to resolution of alopecia in 22% (2/9) of patients with alopecia on valproic acid therapy.45 Despite hypothesized effects of valproate on micronutrients, the role of mineral supplementation in treating valproate-associated hair loss remains unclear. There is evidence to suggest that valproic acid–associated alterations in serum biotinidase activity may be transient. In a study of 32 pediatric patients receiving valproic acid for the treatment of epilepsy, serum biotinidase activity was significantly lower after 3 months of valproic acid therapy compared with pretreatment levels (P<.05); at 6 months, the serum biotinidase activity was increased compared with 3 months (P<.05) and not significantly different from pretreatment levels (P>.05).46 Hair regrowth has been observed following discontinuation or dose reduction of valproate therapy in some cases.39,47

Lithium carbonate (lithium) is used in the treatment of BD. Despite its efficacy and low cost, its potential for adverse effects, narrow therapeutic index, and subsequent need for routine monitoring are factors that limit its use.48 Some reported dermatologic adverse reactions on its structure product labeling include xerosis, thinning of hair, alopecia, xerosis cutis, psoriasis onset/exacerbation, and generalized pruritus.49 A systematic review and meta-analysis of 385 studies identified 24 publications reporting adverse effects of lithium on hair with no significantly increased risk of alopecia overall.50 The analysis included 2 randomized controlled trials comparing the effects of lithium and placebo on hair loss in patients with BD. Hair loss was reported in 7% (7/94) of patients taking lithium and 6% (6/94) of the placebo group in the 12-month study40 and in 3% (1/32) of the lithium group and 0% (0/28) of the divalproex group in the 20-month study.51 Despite anecdotal reports of alopecia associated with lithium, there is a lack of high-quality evidence to support this claim. Of note, hypothyroidism is a known complication of lithium use, and serum testing of thyroid function at 6-month intervals is recommended for patients on lithium treatment.52 Because thyroid abnormalities can cause alopecia distinct from TE, new-onset alopecia during lithium use should prompt serum testing of thyroid function. The development of hypothyroidism secondary to lithium is not a direct contraindication to its use53; rather, treatment should be focused on correction with thyroid replacement therapy (eg, supplementation with thyroxine).54

 

 

Commonly prescribed antidepressant medications include selective serotonin reuptake inhibitors (SSRIs) and bupropion. Selective serotonin reuptake inhibitors affect the neuronal serotonin transporter, increasing the concentration of serotonin in the synaptic cleft available for stimulation of postsynaptic serotonin receptors55,56; bupropion is an antidepressant medication that inhibits norepinephrine and dopamine reuptake at the synaptic cleft.57 Alopecia is an infrequent (1 in 100 to 1 in 1000 patients) adverse effect for several SSRIs.58-62 A recent systematic review identified a total of 71 cases of alopecia associated with SSRI use including citalopram (n=11), escitalopram (n=7), fluoxetine (n=27), fluoxvamine (n=5), paroxetine (n=4), and sertraline (n=20), with a median time to onset of hair shedding of 8.6 weeks (range, 3 days to 5 years). Discontinuation of the suspected culprit SSRI led to improvement and/or resolution in 63% (51/81) episodes of alopecia, with a median time to improvement and/or resolution of 4 weeks.63 A comparative retrospective cohort study using a large US health claims database from 2006 to 2014 included more than 1 million new and mutually exclusive patients taking fluoxetine, fluvoxamine, sertraline, citalopram, escitalopram, paroxetine, duloxetine, venlafaxine, desvenlafaxine, and bupropion.64 Overall, 1% (1569/150,404) of patients treated with bupropion received 1 or more physician visits for alopecia. Patients on SSRIs generally had a lower risk for hair loss compared with patients using bupropion (citalopram: hazard ratio [HR], 0.80 [95% CI, 0.74-0.86]; escitalopram: HR, 0.79 [95% CI, 0.74-0.86]; fluoxetine: HR, 0.68 [95% CI, 0.63-0.74]; paroxetine: HR, 0.68 [95% CI, 0.62-0.74]; sertraline: HR, 0.74 [95% CI, 0.69-0.79]), with the exception of fluvoxamine (HR, 0.93 [95% CI, 0.64-1.37]). However, the type of alopecia, time to onset, and time to resolution were not reported, making it difficult to assess whether the reported hair loss was consistent with medication-induced TE. Additionally, the authors acknowledged that bupropion may have been prescribed for smoking cessation, which may carry a different risk profile for the development of alopecia.64 Several other case reports have described alopecia following treatment with SSRIs, including sertraline,65 fluvoxamine,66 paroxetine,67 fluoxetine,68 and escitalopram.69

Overall, it appears that the use of SSRIs portends relatively low risk for alopecia and medication-induced TE. Little is known regarding the molecular effects of SSRIs on hair growth and the pathomechanism of SSRI-induced TE. The potential benefits of discontinuing a suspected culprit medication should be carefully weighed against the risks of medication cessation, and consideration should be given to alternative medications in the same class that also may be associated with TE. In patients requiring antidepressant therapy with suspected medication-induced TE, consider transitioning to a different class of medication with lower risk of medication-induced alopecia; for example, discontinuing bupropion in favor of an SSRI.

Final Thoughts

Medication-induced alopecia is an undesired side effect of many commonly used drugs and drug classes, including retinoids, azole antifungals, and mood stabilizers. Although the precise pathomechanisms of medication-induced TE remain unclear, the recommended management often requires identification of the likely causative agent and its discontinuation, if possible. Suspicion for medication-induced TE should prompt a thorough history of recent changes to medications, risk factors for nutritional deficiencies, underlying illnesses, and recent surgical procedures. Underlying nutritional, electrolyte, and/or metabolic disturbances should be corrected. In part 2 of this series, we will discuss medication-induced alopecia associated with anticoagulant and antihypertensive medications.

References
  1. Saleh D, Nassereddin A, Cook C. Anagen effluvium. StatPearls. StatPearls Publishing; 2023. https://www.ncbi.nlm.nih.gov/books/NBK482293/
  2. Guerrero-Putz MD, Flores-Dominguez AC, Castillo-de la Garza RJ, et al. Anagen effluvium after neurointerventional radiation: trichoscopy as a diagnostic ally. Skin Appendage Disord. 2021;8:102-107. doi:10.1159/000518743
  3. Patel M, Harrison S, Sinclair R. Drugs and hair loss. Dermatol Clin. 2013;31:67-73. doi:https://doi.org/10.1016/j.det.2012.08.002
  4. Chen V, Strazzulla L, Asbeck SM, et al. Etiology, management, and outcomes of pediatric telogen effluvium: a single-center study in the United States. Pediatr Dermatol. 2023;40:120-124. doi:10.1111/pde.15154
  5. Watras MM, Patel JP, Arya R. Traditional anticoagulants and hair loss: a role for direct oral anticoagulants? a review of the literature. Drugs Real World Outcomes. 2016;3:1-6. doi:10.1007/s40801-015-0056-z
  6. Hughes EC, Saleh D. Telogen effluvium. StatPearls. StatPearls Publishing; 2023. https://www.ncbi.nlm.nih.gov/books/NBK430848/
  7. Nguyen B, Tosti A. Alopecia in patients with COVID-19: a systematic review and meta-analysis. JAAD Int. 2022;7:67-77. doi:10.1016/j.jdin.2022.02.006
  8. Starace M, Piraccini BM, Evangelista V, et al. Acute telogen effluvium due to dengue fever mimicking androgenetic alopecia. Ital J Dermatol Venerol. 2023;158:66-67. doi:10.23736/s2784-8671.22.07369-8
  9. Patel KV, Farrant P, Sanderson JD, et al. Hair loss in patients with inflammatory bowel disease. Inflamm Bowel Dis. 2013;19:1753-1763. doi:10.1097/MIB.0b013e31828132de
  10. Cohen-Kurzrock RA, Cohen PR. Bariatric surgery–induced telogen effluvium (bar site): case report and a review of hair loss following weight loss surgery. Cureus. 2021;13:E14617. doi:10.7759/cureus.14617
  11. Price VH. Treatment of hair loss. N Engl J Med. 1999;341:964-973. doi:10.1056/nejm199909233411307
  12. Headington JT. Telogen effluvium: new concepts and review. Arch Dermatol. 1993;129:356-363. doi:10.1001/arcderm.1993.01680240096017
  13. Lee DD, Stojadinovic O, Krzyzanowska A, et al. Retinoid-responsive transcriptional changes in epidermal keratinocytes. J Cell Physiol. 2009;220:427-439. doi:10.1002/jcp.21784
  14. Foitzik K, Spexard T, Nakamura M, et al. Towards dissecting the pathogenesis of retinoid-induced hair loss: all-trans retinoic acid induces premature hair follicle regression (catagen) by upregulation of transforming growth factor-beta2 in the dermal papilla. J Invest Dermatol. 2005;124:1119-1126. doi:10.1111/j.0022-202X.2005.23686.x
  15. Karlsson T, Vahlquist A, Kedishvili N, et al. 13-cis-retinoic acid competitively inhibits 3 alpha-hydroxysteroid oxidation by retinol dehydrogenase RoDH-4: a mechanism for its anti-androgenic effects in sebaceous glands? Biochem Biophys Res Commun. 2003;303:273-278. doi:10.1016/s0006-291x(03)00332-2
  16. Chapellier B, Mark M, Messaddeq N, et al. Physiological and retinoid-induced proliferations of epidermis basal keratinocytes are differently controlled. EMBO J. 2002;21:3402-3413. doi:10.1093/emboj/cdf331
  17. Geiger JM. Retinoids and sebaceous gland activity. Dermatology. 1995;191:305-310. doi:10.1159/000246581
  18. Oge LK, Broussard A, Marshall MD. Acne vulgaris: diagnosis and treatment. Am Fam Physician. 2019;100:475-484.
  19. Pilkington T, Brogden RN. Acitretin. Drugs. 1992;43:597-627. doi:10.2165/00003495-199243040-00010
  20. Zaenglein AL, Levy ML, Stefanko NS, et al. Consensus recommendations for the use of retinoids in ichthyosis and other disorders of cornification in children and adolescents. Pediatr Dermatol. 2021;38:164-180. doi:10.1111/pde.14408
  21. Katz HI, Waalen J, Leach EE. Acitretin in psoriasis: an overview of adverse effects. J Am Acad Dermatol. 1999;41(3 suppl):S7-S12. doi:10.1016/s0190-9622(99)70359-2
  22. Tran PT, Evron E, Goh C. Characteristics of patients with hair loss after isotretinoin treatment: a retrospective review study. Int J Trichology. 2022;14:125-127. doi:10.4103/ijt.ijt_80_20
  23. Gupta AK, Goldfarb MT, Ellis CN, et al. Side-effect profile of acitretin therapy in psoriasis. J Am Acad Dermatol. 1989;20:1088-1093. doi:10.1016/s0190-9622(89)70138-9
  24. Lytvyn Y, McDonald K, Mufti A, et al. Comparing the frequency of isotretinoin-induced hair loss at <0.5-mg/kg/d versus ≥0.5-mg/kg/d dosing in acne patients: a systematic review. JAAD Int. 2022;6:125-142. doi:10.1016/j.jdin.2022.01.002
  25. Aboulafia DM, Norris D, Henry D, et al. 9-cis-Retinoic acid capsules in the treatment of AIDS-related Kaposi sarcoma: results of a phase 2 multicenter clinical trial. Arch Dermatol. 2003;139:178-186. doi:10.1001/archderm.139.2.178
  26. Cheruvattath R, Orrego M, Gautam M, et al. Vitamin A toxicity: when one a day doesn’t keep the doctor away. Liver Transpl. 2006;12:1888-1891. doi:10.1002/lt.21007
  27. Nan W, Li G, Si H, et al. All-trans-retinoic acid inhibits mink hair follicle growth via inhibiting proliferation and inducing apoptosis of dermal papilla cells through TGF-β2/Smad2/3 pathway. Acta Histochem. 2020;122:151603. doi:10.1016/j.acthis.2020.151603
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  31. Thompson GR 3rd, Krois CR, Affolter VK, et al. Examination of fluconazole-induced alopecia in an animal model and human cohort. Antimicrob Agents Chemother. 2019;63:e01384-18. doi:10.1128/aac.01384-18
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References
  1. Saleh D, Nassereddin A, Cook C. Anagen effluvium. StatPearls. StatPearls Publishing; 2023. https://www.ncbi.nlm.nih.gov/books/NBK482293/
  2. Guerrero-Putz MD, Flores-Dominguez AC, Castillo-de la Garza RJ, et al. Anagen effluvium after neurointerventional radiation: trichoscopy as a diagnostic ally. Skin Appendage Disord. 2021;8:102-107. doi:10.1159/000518743
  3. Patel M, Harrison S, Sinclair R. Drugs and hair loss. Dermatol Clin. 2013;31:67-73. doi:https://doi.org/10.1016/j.det.2012.08.002
  4. Chen V, Strazzulla L, Asbeck SM, et al. Etiology, management, and outcomes of pediatric telogen effluvium: a single-center study in the United States. Pediatr Dermatol. 2023;40:120-124. doi:10.1111/pde.15154
  5. Watras MM, Patel JP, Arya R. Traditional anticoagulants and hair loss: a role for direct oral anticoagulants? a review of the literature. Drugs Real World Outcomes. 2016;3:1-6. doi:10.1007/s40801-015-0056-z
  6. Hughes EC, Saleh D. Telogen effluvium. StatPearls. StatPearls Publishing; 2023. https://www.ncbi.nlm.nih.gov/books/NBK430848/
  7. Nguyen B, Tosti A. Alopecia in patients with COVID-19: a systematic review and meta-analysis. JAAD Int. 2022;7:67-77. doi:10.1016/j.jdin.2022.02.006
  8. Starace M, Piraccini BM, Evangelista V, et al. Acute telogen effluvium due to dengue fever mimicking androgenetic alopecia. Ital J Dermatol Venerol. 2023;158:66-67. doi:10.23736/s2784-8671.22.07369-8
  9. Patel KV, Farrant P, Sanderson JD, et al. Hair loss in patients with inflammatory bowel disease. Inflamm Bowel Dis. 2013;19:1753-1763. doi:10.1097/MIB.0b013e31828132de
  10. Cohen-Kurzrock RA, Cohen PR. Bariatric surgery–induced telogen effluvium (bar site): case report and a review of hair loss following weight loss surgery. Cureus. 2021;13:E14617. doi:10.7759/cureus.14617
  11. Price VH. Treatment of hair loss. N Engl J Med. 1999;341:964-973. doi:10.1056/nejm199909233411307
  12. Headington JT. Telogen effluvium: new concepts and review. Arch Dermatol. 1993;129:356-363. doi:10.1001/arcderm.1993.01680240096017
  13. Lee DD, Stojadinovic O, Krzyzanowska A, et al. Retinoid-responsive transcriptional changes in epidermal keratinocytes. J Cell Physiol. 2009;220:427-439. doi:10.1002/jcp.21784
  14. Foitzik K, Spexard T, Nakamura M, et al. Towards dissecting the pathogenesis of retinoid-induced hair loss: all-trans retinoic acid induces premature hair follicle regression (catagen) by upregulation of transforming growth factor-beta2 in the dermal papilla. J Invest Dermatol. 2005;124:1119-1126. doi:10.1111/j.0022-202X.2005.23686.x
  15. Karlsson T, Vahlquist A, Kedishvili N, et al. 13-cis-retinoic acid competitively inhibits 3 alpha-hydroxysteroid oxidation by retinol dehydrogenase RoDH-4: a mechanism for its anti-androgenic effects in sebaceous glands? Biochem Biophys Res Commun. 2003;303:273-278. doi:10.1016/s0006-291x(03)00332-2
  16. Chapellier B, Mark M, Messaddeq N, et al. Physiological and retinoid-induced proliferations of epidermis basal keratinocytes are differently controlled. EMBO J. 2002;21:3402-3413. doi:10.1093/emboj/cdf331
  17. Geiger JM. Retinoids and sebaceous gland activity. Dermatology. 1995;191:305-310. doi:10.1159/000246581
  18. Oge LK, Broussard A, Marshall MD. Acne vulgaris: diagnosis and treatment. Am Fam Physician. 2019;100:475-484.
  19. Pilkington T, Brogden RN. Acitretin. Drugs. 1992;43:597-627. doi:10.2165/00003495-199243040-00010
  20. Zaenglein AL, Levy ML, Stefanko NS, et al. Consensus recommendations for the use of retinoids in ichthyosis and other disorders of cornification in children and adolescents. Pediatr Dermatol. 2021;38:164-180. doi:10.1111/pde.14408
  21. Katz HI, Waalen J, Leach EE. Acitretin in psoriasis: an overview of adverse effects. J Am Acad Dermatol. 1999;41(3 suppl):S7-S12. doi:10.1016/s0190-9622(99)70359-2
  22. Tran PT, Evron E, Goh C. Characteristics of patients with hair loss after isotretinoin treatment: a retrospective review study. Int J Trichology. 2022;14:125-127. doi:10.4103/ijt.ijt_80_20
  23. Gupta AK, Goldfarb MT, Ellis CN, et al. Side-effect profile of acitretin therapy in psoriasis. J Am Acad Dermatol. 1989;20:1088-1093. doi:10.1016/s0190-9622(89)70138-9
  24. Lytvyn Y, McDonald K, Mufti A, et al. Comparing the frequency of isotretinoin-induced hair loss at <0.5-mg/kg/d versus ≥0.5-mg/kg/d dosing in acne patients: a systematic review. JAAD Int. 2022;6:125-142. doi:10.1016/j.jdin.2022.01.002
  25. Aboulafia DM, Norris D, Henry D, et al. 9-cis-Retinoic acid capsules in the treatment of AIDS-related Kaposi sarcoma: results of a phase 2 multicenter clinical trial. Arch Dermatol. 2003;139:178-186. doi:10.1001/archderm.139.2.178
  26. Cheruvattath R, Orrego M, Gautam M, et al. Vitamin A toxicity: when one a day doesn’t keep the doctor away. Liver Transpl. 2006;12:1888-1891. doi:10.1002/lt.21007
  27. Nan W, Li G, Si H, et al. All-trans-retinoic acid inhibits mink hair follicle growth via inhibiting proliferation and inducing apoptosis of dermal papilla cells through TGF-β2/Smad2/3 pathway. Acta Histochem. 2020;122:151603. doi:10.1016/j.acthis.2020.151603
  28. Georgopapadakou NH, Walsh TJ. Antifungal agents: chemotherapeutic targets and immunologic strategies. Antimicrob Agents Chemother. 1996;40:279-291. doi:10.1128/aac.40.2.279
  29. Sheehan DJ, Hitchcock CA, Sibley CM. Current and emerging azole antifungal agents. Clin Microbiol Rev. 1999;12:40-79. doi:10.1128/cmr.12.1.40
  30. Pappas PG, Kauffman CA, Perfect J, et al. Alopecia associated with fluconazole therapy. Ann Intern Med. 1995;123:354-357. doi:10.7326/0003-4819-123-5-199509010-00006
  31. Thompson GR 3rd, Krois CR, Affolter VK, et al. Examination of fluconazole-induced alopecia in an animal model and human cohort. Antimicrob Agents Chemother. 2019;63:e01384-18. doi:10.1128/aac.01384-18
  32. Malani AN, Kerr L, Obear J, et al. Alopecia and nail changes associated with voriconazole therapy. Clin Infect Dis. 2014;59:E61-E65. doi:10.1093/cid/ciu275
  33. Greer ND. Voriconazole: the newest triazole antifungal agent. Proc (Bayl Univ Med Cent). 2003;16:241-248. doi:10.1080/08998280.2003.11927910
  34. Drabin´ska B, Dettlaff K, Kossakowski K, et al. Structural and spectroscopic properties of voriconazole and fluconazole—experimental and theoretical studies. Open Chemistry. 2022;20:1575-1590. doi:10.1515/chem-2022-0253
  35. Löscher W. Valproate: a reappraisal of its pharmacodynamic properties and mechanisms of action. Prog Neurobiol. 1999;58:31-59. doi:10.1016/s0301-0082(98)00075-6
  36. Gill D, Derry S, Wiffen PJ, et al. Valproic acid and sodium valproate for neuropathic pain and fibromyalgia in adults. Cochrane Database Syst Rev. 2011;2011:CD009183. doi:10.1002/14651858.CD009183.pub2
  37. Depakote, Prescribing information. Abbott Laboratories; 2011. Accessed November 20, 2023. https://www.accessdata.fda.gov/drugsatfda_docs/label/2011/018723s037lbl.pdf
  38. Wang X, Wang H, Xu D, et al. Risk of valproic acid-related alopecia: a systematic review and meta-analysis. Seizure. 2019;69:61-69. doi:10.1016/j.seizure.2019.04.003
  39. Mercke Y, Sheng H, Khan T, et al. Hair loss in psychopharmacology. Ann Clin Psychiatry. 2000;12:35-42. doi:10.1023/a:1009074926921
  40. Bowden CL, Calabrese JR, McElroy SL, et al. A randomized, placebo-controlled 12-month trial of divalproex and lithium in treatment of outpatients with bipolar I disorder. Divalproex Maintenance Study Group. Arch Gen Psychiatry. 2000;57:481-489. doi:10.1001/archpsyc.57.5.481
  41. Praharaj SK, Munoli RN, Udupa ST, et al. Valproate-associated hair abnormalities: pathophysiology and management strategies. Hum Psychopharmacol. 2022;37:E2814. doi:10.1002/hup.2814
  42. Wilting I, van Laarhoven JH, de Koning-Verest IF, et al. Valproic acid-induced hair-texture changes in a white woman. Epilepsia. 2007;48:400-401. doi:10.1111/j.1528-1167.2006.00933.x
  43. Potter WZ, Ketter TA. Pharmacological issues in the treatment of bipolar disorder: focus on mood-stabilizing compounds. Can J Psychiatry. 1993;38(3 suppl 2):S51-S56.
  44. Castro-Gago M, Gómez-Lado C, Eirís-Pun´al J, et al. Serum biotinidase activity in children treated with valproic acid and carbamazepine. J Child Neurol. 2009;25:32-35. doi:10.1177/0883073809336118
  45. Schulpis KH, Karikas GA, Tjamouranis J, et al. Low serum biotinidase activity in children with valproic acid monotherapy. Epilepsia. 2001;42:1359-1362. doi:10.1046/j.1528-1157.2001.47000.x
  46. Yilmaz Y, Tasdemir HA, Paksu MS. The influence of valproic acid treatment on hair and serum zinc levels and serum biotinidase activity. Eur J Paediatr Neurol. 2009;13:439-443. doi:10.1016/j.ejpn.2008.08.007
  47. Henriksen O, Johannessen SI. Clinical and pharmacokinetic observations on sodium valproate—a 5-year follow-up study in 100 children with epilepsy. Acta Neurol Scand. 1982;65:504-523. doi:10.1111/j.1600-0404.1982.tb03106.x
  48. Fountoulakis KN, Tohen M, Zarate CA Jr. Lithium treatment of bipolar disorder in adults: a systematic review of randomized trials and meta-analyses. Eur Neuropsychopharmacol. 2022;54:100-115. doi:10.1016/j.euroneuro.2021.10.003
  49. Lithium carbonate. Prescribing information. West-Ward Pharmaceuticals; 2018. Accessed November 20, 2023. https://ww.accessdata.fda.gov/drugsatfda_docs/label/2018/017812s033,018421s032,018558s027lbl.pdf
  50. McKnight RF, Adida M, Budge K, et al. Lithium toxicity profile: a systematic review and meta-analysis. Lancet. 2012;379:721-728. doi:10.1016/s0140-6736(11)61516-x
  51. Calabrese JR, Shelton MD, Rapport DJ, et al. A 20-month, double-blind, maintenance trial of lithium versus divalproex in rapid-cycling bipolar disorder. Am J Psychiatry. 2005;162:2152-2161. doi:10.1176/appi.ajp.162.11.2152.
  52. Duce HL, Duff CJ, Zaidi S, et al. Evaluation of thyroid function monitoring in people treated with lithium: advice based on real-world data. Bipolar Disord. 2023;25:402-409. doi:10.1111/bdi.13298
  53. Bocchetta A, Loviselli A. Lithium treatment and thyroid abnormalities. Clin Pract Epidemiol Ment Health. 2006;2:23. doi:10.1186/1745-0179-2-23.
  54. Joffe RT. How should lithium-induced thyroid dysfunction be managed in patients with bipolar disorder? J Psychiatry Neurosci. 2002;27:392.
  55. Preskorn SH. Clinically relevant pharmacology of selective serotonin reuptake inhibitors. an overview with emphasis on pharmacokinetics and effects on oxidative drug metabolism. Clin Pharmacokinet. 1997;32(suppl 1):1-21. doi:10.2165/00003088-199700321-00003
  56. Chu A, Wadhwa R. Selective serotonin reuptake inhibitors. StatPearls. StatPearls Publishing; 2023.
  57. Stahl SM, Pradko JF, Haight BR, et al. A review of the neuropharmacology of bupropion, a dual norepinephrine and dopamine reuptake inhibitor. Prim Care Companion J Clin Psychiatry. 2004;6:159-166. doi:10.4088/pcc.v06n0403
  58. Escitalopram. Prescribing information. Solco Healthcare US, LLC; 2022. Accessed November 20, 2023. https://nctr-crs.fda.gov/fdalabel/services/spl/set-ids/2ffc6ec3-830f-46bc-9b3f-7c42cefa39b2/spl-doc
  59. Fluoxetine. Eli Lilly & Company; 2017. Prescribing information. Accessed November 20, 2023. https://www.accessdata.fda.gov/drugsatfda_docs/label/2017/018936s108lbl.pdf
  60. Paxil. Prescribing information. GlaxoSmithKline; 2012. Accessed November 20, 2023. https://www.accessdata.fda.gov/drugsatfda_docs/label/2012/020031s067,020710s031.pdf
  61. Zoloft. Prescribing information. Pfizer; 2016. Accessed November 20, 2023. https://www.accessdata.fda.gov/drugsatfda_docs/label/2016/019839s74s86s87_20990s35s44s45lbl.pdf
  62. Celexa. Prescribing information. Allergan; 2022. Accessed November 20, 2023. https://www.accessdata.fda.gov/drugsatfda_docs/label/2022/020822s041lbl.pdf
  63. Pejcic AV, Paudel V. Alopecia associated with the use of selective serotonin reuptake inhibitors: systematic review. Psychiatry Res. 2022;313:114620. 10.1016/j.psychres.2022.114620
  64. Etminan M, Sodhi M, Procyshyn RM, et al. Risk of hair loss with different antidepressants: a comparative retrospective cohort study. Int Clin Psychopharmacol. 2018;33:44-48.
  65. Ghanizadeh A. Sertraline-associated hair loss. J Drugs Dermatol. 2008;7:693-694.
  66. Parameshwar E. Hair loss associated with fluvoxamine use. Am J Psychiatry. 1996;153:581-582. doi:10.1176/ajp.153.4.581
  67. Zalsman G, Sever J, Munitz H. Hair loss associated with paroxetine treatment: a case report. Clin Neuropharmacol. 1999;22:246-247.
  68. Ananth J, Elmishaugh A. Hair loss associated with fluoxetinetreatment. Can J Psychiatry. 1991;36:621. doi:10.1177/070674379103600824
  69. Tirmazi SI, Imran H, Rasheed A, et al. Escitalopram-induced hair loss. Prim Care Companion CNS Disord. 2020;22:19l02496. doi:10.4088/PCC.19l02496
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Culprits of Medication-Induced Telogen Effluvium, Part 1
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  • Medications are a common culprit of telogen effluvium (TE), and medication-induced TE should be suspected in patients presenting with diffuse nonscarring alopecia who are taking systemic medication(s).
  • A careful history of new medications and dose adjustments 1 to 6 months prior to notable hair loss may identify the most likely inciting cause.
  • Medication-induced TE often improves with cessation or dose reduction of the culprit medication.
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Prurigo Nodularis: Moving Forward

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Ailish Hanly, MD
Kalman L. Watsky, MD

Prurigo nodularis (PN), a condition that historically has been a challenge to treat, now has a US Food and Drug Administration (FDA)–approved therapy—dupilumab—with other agents in the pipeline. As clinicians, we recognize PN as typically symmetric, keratotic, papular and nodular lesions presenting in older adults with chronic pruritus; patients with atopic dermatitis make up roughly half of patients with PN, but a workup for pruritus is indicated in other settings.1 In the United States, Black patients are 3.4-times more likely than White patients to have PN.2 The differential diagnosis includes conditions such nodular scabies, pemphigoid nodularis, acquired perforating disorders, and hypertrophic lichen planus, which also should be considered, especially in cases that are refractory to first-line therapies. Recent breakthroughs in therapy have come from substantial progress in our understanding of the pathogenesis of PN as driven by disorders of cytokine expression and/or neurocutaneous aberrations. We review progress in the treatment of PN over the last 3 years.

Treatment Guidelines

In 2020, an expert panel published consensus treatment guidelines for PN.1 The panel, which proposed a 4-tiered approach targeting both neural and immunologic mechanisms in the pathogenesis of PN, emphasized the importance of tailoring treatment to the individual patient. Topical therapies remained the mainstay of treatment, with agents such as topical capsaicin, ketamine, lidocaine, and amitriptyline targeting the neural component and topical corticosteroids, calcineurin inhibitors, and calcipotriol and intralesional corticosteroids targeting the immunologic component. Phototherapy, methotrexate, cyclosporine, antidepressants, and gabapentinoids used with varying degrees of success were noted to have acceptable tolerability.1

FDA-Approved Therapy

In September 2022, the FDA approved dupilumab for the treatment of PN. An antagonist of the IL-4 receptor, dupilumab was found to reduce both pruritus and skin lesions over a 24-week period in 2 phase 3 clinical trials.3 Results also demonstrated progressive improvements in measures assessing quality of life and pruritus over the study period, suggesting that continued treatment could lead to even further improvements in these measures. Adverse events were minimal and similar between the dupilumab- and placebo-treated groups.3

The FDA approval of dupilumab is a promising step in decreasing the disease burden of widespread or refractory PN, both for patients and the health care system. The treatment of patients with PN has been more challenging due to comorbidities, including mental health conditions, endocrine disorders, cardiovascular conditions, renal conditions, malignancy, and HIV.4,5 These comorbidities can complicate the use of traditional systemic and immunosuppressive agents. Dupilumab has virtually no contraindications and has demonstrated safety in almost all patient populations.6

Consistent insurance coverage for patients who respond to dupilumab remains to be determined. A review investigating the use of dupilumab in patients with atopic dermatitis at the University of Pittsburgh Medical Center (Pittsburgh, Pennsylvania) found that of 179 patients, 67 (37.4%) did not start dupilumab, mainly due to insurance denial (34/179 [19%]) or copay (20/179 [11%]). Medicare patients were less likely to receive treatment compared to those on private insurance or Medicaid.7 In a recent review of 701 patients with PN, the mean age was 64.8 years,5 highlighting the concern about obtaining insurance coverage for dupilumab in this population given the higher likelihood that these patients will be on Medicare. Prescribers should be aware that coverage denials are likely and should be prepared to advocate for their patients by citing recent studies to hopefully obtain coverage for dupilumab in the treatment of PN. Resources such as the Dupixent MyWay program (https://www.dupixent.com/support-savings/dupixent-my-way) can provide useful recommendations for pursuing insurance approval for this agent.

Investigation of Janus Kinase Inhibitors

Emerging data suggest that Janus kinase (JAK) inhibitors may be beneficial in the treatment of PN. Patients with refractory PN have been treated off label with the JAK inhibitor tofacitinib at a dosage of 5 mg twice daily with improvement in symptoms and minimal side effects.8,9 Similarly, a case report showed that off-label use of the JAK inhibitor baricitinib resulted in marked improvement in pruritus and clearance of lesions at a dosage of 4 mg daily, with reduction in pruritus seen as early as 1 week after treatment initiation.10 Although most patients are able to tolerate JAK inhibitors, known side effects include acne, viral infections, gastrointestinal tract upset, and the potential increased risk for malignancy.11 The use of topical JAK inhibitors such as ruxolitinib has not yet been studied in PN, though cost may limit use to localized disease.

Other New Therapies

Recent case reports and case series have found the vitamin A derivative alitretinoin to be an effective treatment for recalcitrant PN, typically at a dosage of 30 mg daily.12,13 Sustained remission was noted even after discontinuation of the medication.12 Alitretinoin, which has been demonstrated to be effective in treating dermatitis,14 was well tolerated. Similar to JAK inhibitors, there are minimal data investigating the use of topical retinoids in the treatment of localized PN.

 

 

Topical cannabinoids have shown benefit in the treatment of pruritus15 and may be beneficial for the treatment of PN, though there currently are limited data in the literature. With the use of both medical and legal recreational marijuana on the rise, there is an increased interest in cannabinoids, particularly as many patients consider these agents to be more “natural”—and therefore preferable—treatment options. As the use of cannabis derivatives become more commonplace in both traditional and complementary medicine, providers should be prepared to field questions from patients about their potential for PN.

Finally, the IL-31RA inhibitor nemolizumab also has shown promise in the treatment of PN. A recent study suggested that nemolizumab helps modulate inflammatory and neural signaling in PN.16 Nemolizumab has been granted breakthrough therapy designation for the treatment of pruritus in PN based on a phase 2 study that demonstrated improvement in pruritus and skin lesions in a group of 70 patients with moderate to severe PN.17 Nemolizumab, which is used to treat pruritus in atopic dermatitis, has minimal side effects including upper respiratory tract infections and peripheral edema.18

Final Thoughts

Prurigo nodularis historically has been considered difficult to treat, particularly in those with widespread lesions. Dupilumab—the first FDA-approved treatment of PN—is now an exciting option, not just for patients with underlying atopic dermatitis. Not all patients will respond to the medication, and the ease of obtaining insurance approval has yet to be established; therefore, having other treatment options will be imperative. In patients with recalcitrant disease, several other treatment options have shown promise in the treatment of PN; in particular, JAK inhibitors, alitretinoin, and nemolizumab should be considered in patients with widespread refractory PN who are willing to try alternative agents. Ongoing research should be focused on these medications as well as on the development of other novel treatments aimed at relieving affected patients.

References
  1. Elmariah S, Kim B, Berger T, et al. Practical approaches for diagnosis and management of prurigo nodularis: United States expert panel consensus [published online July 15, 2020]. J Am Acad Dermatol. 2021;84:747-760. doi:10.1016/j.jaad.2020.07.025
  2. Boozalis E, Tang O, Patel S, et al. Ethnic differences and comorbidities of 909 prurigo nodularis patients. J Am Acad Dermatol. 2018;79:714.
  3. Yosipovitch G, Mollanazar N, Ständer S, et al. Dupilumab in patients with prurigo nodularis: two randomized, double-blind, placebo-controlled phase 3 trials. Nat Med. 2023;29:1180-1190. doi:10.1038/s41591-023-02320-9
  4. Huang AH, Williams KA, Kwatra SG. Prurigo nodularis: epidemiology and clinical features. J Am Acad Dermatol. 2020;83:1559-1565. doi:10.1016/j.jaad.2020.04.183
  5. Joel MZ, Hydol-Smith J, Kambala A, et al. Prevalence and comorbidity burden of prurigo nodularis in United States adults enrolled in the All of Us research program. J Am Acad Dermatol. 2023;89:1056-1058. doi:10.1016/j.jaad.2023.06.045
  6. Dupixent. Package insert. Regeneron Pharmaceuticals, Inc; 2017.
  7. Khosravi H, Zhang S, Anderson AM, et al. Dupilumab drug survival, treatment failures, and insurance approval at a tertiary care center in the United States. J Am Acad Dermatol. 2020;82:1023-1024. doi:10.1016/j.jaad.2019.12.034
  8. Liu T, Chu Y, Wang Y, et al. Successful treatment of prurigo nodularis with tofacitinib: the experience from a single center. Int J Dermatol. 2023;62:E293-E295. doi:10.1111/ijd.16568
  9. Molloy OE, Kearney N, Byrne N, et al. Successful treatment of recalcitrant nodular prurigo with tofacitinib. Clin Exp Dermatol. 2020;45:918-920. doi:10.1111/ced.14320
  10. Yin M, Wu R, Chen J, et al. Successful treatment of refractory prurigo nodularis with baricitinib. Dermatol Ther. 2022;35:E15642. doi:10.1111/dth.15642
  11. Klein B, Treudler R, Simon JC. JAK-inhibitors in dermatology—small molecules, big impact? overview of the mechanism of action, previous study results and potential adverse effects. J Dtsch Dermatol Ges. 2022;20:19-24. doi:10.1111/ddg.14668
  12. Chung BY, Um JY, Kang SY, et al. Oral alitretinoin for patients with refractory prurigo. Medicina (Kaunas). 2020;56:599. doi:10.3390/medicina56110599
  13. Maqbool T, Kraft JN. Alitretinoin for prurigo nodularis. Clin Exp Dermatol. 2021;46:362-363. doi:10.1111/ced.14385
  14. Grahovac M, Molin S, Prinz JC, et al. Treatment of atopic eczema with oral alitretinoin. Br J Dermatol. 2010;162:217-218. doi:10.1111/j.1365-2133.2009.09522.x
  15. Avila C, Massick S, Kaffenberger BH, et al. Cannabinoids for the treatment of chronic pruritus: a review. J Am Acad Dermatol. 2020;82:1205-1212. doi:10.1016/j.jaad.2020.01.036
  16. Deng J, Liao V, Parthasarathy V, et al. Modulation of neuroimmune and epithelial dysregulation in patients with moderate to severe prurigo nodularis treated with nemolizumab. JAMA Dermatol. 2023;159:977-985. doi:10.1001/jamadermatol.2023.2609
  17. Park B. Nemolizumab gets breakthrough therapy status for prurigo nodularis. Medical Professionals Reference website. Published December 9, 2019. Accessed November 13, 2023. https://www.empr.com/home/news/nemolizumab-gets-breakthrough-therapy-status-for-prurigo-nodularis/
  18. Labib A, Vander Does A, Yosipovitch G. Nemolizumab for atopic dermatitis. Drugs Today (Barc). 2022;58:159-173. doi:10.1358/dot.2022.58.4.3378056
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The authors report no conflict of interest.

Correspondence: Kalman L. Watsky, MD, 46 Prince St, Ste 206, New Haven, CT 06519

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The authors report no conflict of interest.

Correspondence: Kalman L. Watsky, MD, 46 Prince St, Ste 206, New Haven, CT 06519

Author and Disclosure Information

From the Department of Dermatology, Yale School of Medicine, New Haven, Connecticut.

The authors report no conflict of interest.

Correspondence: Kalman L. Watsky, MD, 46 Prince St, Ste 206, New Haven, CT 06519

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CT112006262.pdf

Prurigo nodularis (PN), a condition that historically has been a challenge to treat, now has a US Food and Drug Administration (FDA)–approved therapy—dupilumab—with other agents in the pipeline. As clinicians, we recognize PN as typically symmetric, keratotic, papular and nodular lesions presenting in older adults with chronic pruritus; patients with atopic dermatitis make up roughly half of patients with PN, but a workup for pruritus is indicated in other settings.1 In the United States, Black patients are 3.4-times more likely than White patients to have PN.2 The differential diagnosis includes conditions such nodular scabies, pemphigoid nodularis, acquired perforating disorders, and hypertrophic lichen planus, which also should be considered, especially in cases that are refractory to first-line therapies. Recent breakthroughs in therapy have come from substantial progress in our understanding of the pathogenesis of PN as driven by disorders of cytokine expression and/or neurocutaneous aberrations. We review progress in the treatment of PN over the last 3 years.

Treatment Guidelines

In 2020, an expert panel published consensus treatment guidelines for PN.1 The panel, which proposed a 4-tiered approach targeting both neural and immunologic mechanisms in the pathogenesis of PN, emphasized the importance of tailoring treatment to the individual patient. Topical therapies remained the mainstay of treatment, with agents such as topical capsaicin, ketamine, lidocaine, and amitriptyline targeting the neural component and topical corticosteroids, calcineurin inhibitors, and calcipotriol and intralesional corticosteroids targeting the immunologic component. Phototherapy, methotrexate, cyclosporine, antidepressants, and gabapentinoids used with varying degrees of success were noted to have acceptable tolerability.1

FDA-Approved Therapy

In September 2022, the FDA approved dupilumab for the treatment of PN. An antagonist of the IL-4 receptor, dupilumab was found to reduce both pruritus and skin lesions over a 24-week period in 2 phase 3 clinical trials.3 Results also demonstrated progressive improvements in measures assessing quality of life and pruritus over the study period, suggesting that continued treatment could lead to even further improvements in these measures. Adverse events were minimal and similar between the dupilumab- and placebo-treated groups.3

The FDA approval of dupilumab is a promising step in decreasing the disease burden of widespread or refractory PN, both for patients and the health care system. The treatment of patients with PN has been more challenging due to comorbidities, including mental health conditions, endocrine disorders, cardiovascular conditions, renal conditions, malignancy, and HIV.4,5 These comorbidities can complicate the use of traditional systemic and immunosuppressive agents. Dupilumab has virtually no contraindications and has demonstrated safety in almost all patient populations.6

Consistent insurance coverage for patients who respond to dupilumab remains to be determined. A review investigating the use of dupilumab in patients with atopic dermatitis at the University of Pittsburgh Medical Center (Pittsburgh, Pennsylvania) found that of 179 patients, 67 (37.4%) did not start dupilumab, mainly due to insurance denial (34/179 [19%]) or copay (20/179 [11%]). Medicare patients were less likely to receive treatment compared to those on private insurance or Medicaid.7 In a recent review of 701 patients with PN, the mean age was 64.8 years,5 highlighting the concern about obtaining insurance coverage for dupilumab in this population given the higher likelihood that these patients will be on Medicare. Prescribers should be aware that coverage denials are likely and should be prepared to advocate for their patients by citing recent studies to hopefully obtain coverage for dupilumab in the treatment of PN. Resources such as the Dupixent MyWay program (https://www.dupixent.com/support-savings/dupixent-my-way) can provide useful recommendations for pursuing insurance approval for this agent.

Investigation of Janus Kinase Inhibitors

Emerging data suggest that Janus kinase (JAK) inhibitors may be beneficial in the treatment of PN. Patients with refractory PN have been treated off label with the JAK inhibitor tofacitinib at a dosage of 5 mg twice daily with improvement in symptoms and minimal side effects.8,9 Similarly, a case report showed that off-label use of the JAK inhibitor baricitinib resulted in marked improvement in pruritus and clearance of lesions at a dosage of 4 mg daily, with reduction in pruritus seen as early as 1 week after treatment initiation.10 Although most patients are able to tolerate JAK inhibitors, known side effects include acne, viral infections, gastrointestinal tract upset, and the potential increased risk for malignancy.11 The use of topical JAK inhibitors such as ruxolitinib has not yet been studied in PN, though cost may limit use to localized disease.

Other New Therapies

Recent case reports and case series have found the vitamin A derivative alitretinoin to be an effective treatment for recalcitrant PN, typically at a dosage of 30 mg daily.12,13 Sustained remission was noted even after discontinuation of the medication.12 Alitretinoin, which has been demonstrated to be effective in treating dermatitis,14 was well tolerated. Similar to JAK inhibitors, there are minimal data investigating the use of topical retinoids in the treatment of localized PN.

 

 

Topical cannabinoids have shown benefit in the treatment of pruritus15 and may be beneficial for the treatment of PN, though there currently are limited data in the literature. With the use of both medical and legal recreational marijuana on the rise, there is an increased interest in cannabinoids, particularly as many patients consider these agents to be more “natural”—and therefore preferable—treatment options. As the use of cannabis derivatives become more commonplace in both traditional and complementary medicine, providers should be prepared to field questions from patients about their potential for PN.

Finally, the IL-31RA inhibitor nemolizumab also has shown promise in the treatment of PN. A recent study suggested that nemolizumab helps modulate inflammatory and neural signaling in PN.16 Nemolizumab has been granted breakthrough therapy designation for the treatment of pruritus in PN based on a phase 2 study that demonstrated improvement in pruritus and skin lesions in a group of 70 patients with moderate to severe PN.17 Nemolizumab, which is used to treat pruritus in atopic dermatitis, has minimal side effects including upper respiratory tract infections and peripheral edema.18

Final Thoughts

Prurigo nodularis historically has been considered difficult to treat, particularly in those with widespread lesions. Dupilumab—the first FDA-approved treatment of PN—is now an exciting option, not just for patients with underlying atopic dermatitis. Not all patients will respond to the medication, and the ease of obtaining insurance approval has yet to be established; therefore, having other treatment options will be imperative. In patients with recalcitrant disease, several other treatment options have shown promise in the treatment of PN; in particular, JAK inhibitors, alitretinoin, and nemolizumab should be considered in patients with widespread refractory PN who are willing to try alternative agents. Ongoing research should be focused on these medications as well as on the development of other novel treatments aimed at relieving affected patients.

Prurigo nodularis (PN), a condition that historically has been a challenge to treat, now has a US Food and Drug Administration (FDA)–approved therapy—dupilumab—with other agents in the pipeline. As clinicians, we recognize PN as typically symmetric, keratotic, papular and nodular lesions presenting in older adults with chronic pruritus; patients with atopic dermatitis make up roughly half of patients with PN, but a workup for pruritus is indicated in other settings.1 In the United States, Black patients are 3.4-times more likely than White patients to have PN.2 The differential diagnosis includes conditions such nodular scabies, pemphigoid nodularis, acquired perforating disorders, and hypertrophic lichen planus, which also should be considered, especially in cases that are refractory to first-line therapies. Recent breakthroughs in therapy have come from substantial progress in our understanding of the pathogenesis of PN as driven by disorders of cytokine expression and/or neurocutaneous aberrations. We review progress in the treatment of PN over the last 3 years.

Treatment Guidelines

In 2020, an expert panel published consensus treatment guidelines for PN.1 The panel, which proposed a 4-tiered approach targeting both neural and immunologic mechanisms in the pathogenesis of PN, emphasized the importance of tailoring treatment to the individual patient. Topical therapies remained the mainstay of treatment, with agents such as topical capsaicin, ketamine, lidocaine, and amitriptyline targeting the neural component and topical corticosteroids, calcineurin inhibitors, and calcipotriol and intralesional corticosteroids targeting the immunologic component. Phototherapy, methotrexate, cyclosporine, antidepressants, and gabapentinoids used with varying degrees of success were noted to have acceptable tolerability.1

FDA-Approved Therapy

In September 2022, the FDA approved dupilumab for the treatment of PN. An antagonist of the IL-4 receptor, dupilumab was found to reduce both pruritus and skin lesions over a 24-week period in 2 phase 3 clinical trials.3 Results also demonstrated progressive improvements in measures assessing quality of life and pruritus over the study period, suggesting that continued treatment could lead to even further improvements in these measures. Adverse events were minimal and similar between the dupilumab- and placebo-treated groups.3

The FDA approval of dupilumab is a promising step in decreasing the disease burden of widespread or refractory PN, both for patients and the health care system. The treatment of patients with PN has been more challenging due to comorbidities, including mental health conditions, endocrine disorders, cardiovascular conditions, renal conditions, malignancy, and HIV.4,5 These comorbidities can complicate the use of traditional systemic and immunosuppressive agents. Dupilumab has virtually no contraindications and has demonstrated safety in almost all patient populations.6

Consistent insurance coverage for patients who respond to dupilumab remains to be determined. A review investigating the use of dupilumab in patients with atopic dermatitis at the University of Pittsburgh Medical Center (Pittsburgh, Pennsylvania) found that of 179 patients, 67 (37.4%) did not start dupilumab, mainly due to insurance denial (34/179 [19%]) or copay (20/179 [11%]). Medicare patients were less likely to receive treatment compared to those on private insurance or Medicaid.7 In a recent review of 701 patients with PN, the mean age was 64.8 years,5 highlighting the concern about obtaining insurance coverage for dupilumab in this population given the higher likelihood that these patients will be on Medicare. Prescribers should be aware that coverage denials are likely and should be prepared to advocate for their patients by citing recent studies to hopefully obtain coverage for dupilumab in the treatment of PN. Resources such as the Dupixent MyWay program (https://www.dupixent.com/support-savings/dupixent-my-way) can provide useful recommendations for pursuing insurance approval for this agent.

Investigation of Janus Kinase Inhibitors

Emerging data suggest that Janus kinase (JAK) inhibitors may be beneficial in the treatment of PN. Patients with refractory PN have been treated off label with the JAK inhibitor tofacitinib at a dosage of 5 mg twice daily with improvement in symptoms and minimal side effects.8,9 Similarly, a case report showed that off-label use of the JAK inhibitor baricitinib resulted in marked improvement in pruritus and clearance of lesions at a dosage of 4 mg daily, with reduction in pruritus seen as early as 1 week after treatment initiation.10 Although most patients are able to tolerate JAK inhibitors, known side effects include acne, viral infections, gastrointestinal tract upset, and the potential increased risk for malignancy.11 The use of topical JAK inhibitors such as ruxolitinib has not yet been studied in PN, though cost may limit use to localized disease.

Other New Therapies

Recent case reports and case series have found the vitamin A derivative alitretinoin to be an effective treatment for recalcitrant PN, typically at a dosage of 30 mg daily.12,13 Sustained remission was noted even after discontinuation of the medication.12 Alitretinoin, which has been demonstrated to be effective in treating dermatitis,14 was well tolerated. Similar to JAK inhibitors, there are minimal data investigating the use of topical retinoids in the treatment of localized PN.

 

 

Topical cannabinoids have shown benefit in the treatment of pruritus15 and may be beneficial for the treatment of PN, though there currently are limited data in the literature. With the use of both medical and legal recreational marijuana on the rise, there is an increased interest in cannabinoids, particularly as many patients consider these agents to be more “natural”—and therefore preferable—treatment options. As the use of cannabis derivatives become more commonplace in both traditional and complementary medicine, providers should be prepared to field questions from patients about their potential for PN.

Finally, the IL-31RA inhibitor nemolizumab also has shown promise in the treatment of PN. A recent study suggested that nemolizumab helps modulate inflammatory and neural signaling in PN.16 Nemolizumab has been granted breakthrough therapy designation for the treatment of pruritus in PN based on a phase 2 study that demonstrated improvement in pruritus and skin lesions in a group of 70 patients with moderate to severe PN.17 Nemolizumab, which is used to treat pruritus in atopic dermatitis, has minimal side effects including upper respiratory tract infections and peripheral edema.18

Final Thoughts

Prurigo nodularis historically has been considered difficult to treat, particularly in those with widespread lesions. Dupilumab—the first FDA-approved treatment of PN—is now an exciting option, not just for patients with underlying atopic dermatitis. Not all patients will respond to the medication, and the ease of obtaining insurance approval has yet to be established; therefore, having other treatment options will be imperative. In patients with recalcitrant disease, several other treatment options have shown promise in the treatment of PN; in particular, JAK inhibitors, alitretinoin, and nemolizumab should be considered in patients with widespread refractory PN who are willing to try alternative agents. Ongoing research should be focused on these medications as well as on the development of other novel treatments aimed at relieving affected patients.

References
  1. Elmariah S, Kim B, Berger T, et al. Practical approaches for diagnosis and management of prurigo nodularis: United States expert panel consensus [published online July 15, 2020]. J Am Acad Dermatol. 2021;84:747-760. doi:10.1016/j.jaad.2020.07.025
  2. Boozalis E, Tang O, Patel S, et al. Ethnic differences and comorbidities of 909 prurigo nodularis patients. J Am Acad Dermatol. 2018;79:714.
  3. Yosipovitch G, Mollanazar N, Ständer S, et al. Dupilumab in patients with prurigo nodularis: two randomized, double-blind, placebo-controlled phase 3 trials. Nat Med. 2023;29:1180-1190. doi:10.1038/s41591-023-02320-9
  4. Huang AH, Williams KA, Kwatra SG. Prurigo nodularis: epidemiology and clinical features. J Am Acad Dermatol. 2020;83:1559-1565. doi:10.1016/j.jaad.2020.04.183
  5. Joel MZ, Hydol-Smith J, Kambala A, et al. Prevalence and comorbidity burden of prurigo nodularis in United States adults enrolled in the All of Us research program. J Am Acad Dermatol. 2023;89:1056-1058. doi:10.1016/j.jaad.2023.06.045
  6. Dupixent. Package insert. Regeneron Pharmaceuticals, Inc; 2017.
  7. Khosravi H, Zhang S, Anderson AM, et al. Dupilumab drug survival, treatment failures, and insurance approval at a tertiary care center in the United States. J Am Acad Dermatol. 2020;82:1023-1024. doi:10.1016/j.jaad.2019.12.034
  8. Liu T, Chu Y, Wang Y, et al. Successful treatment of prurigo nodularis with tofacitinib: the experience from a single center. Int J Dermatol. 2023;62:E293-E295. doi:10.1111/ijd.16568
  9. Molloy OE, Kearney N, Byrne N, et al. Successful treatment of recalcitrant nodular prurigo with tofacitinib. Clin Exp Dermatol. 2020;45:918-920. doi:10.1111/ced.14320
  10. Yin M, Wu R, Chen J, et al. Successful treatment of refractory prurigo nodularis with baricitinib. Dermatol Ther. 2022;35:E15642. doi:10.1111/dth.15642
  11. Klein B, Treudler R, Simon JC. JAK-inhibitors in dermatology—small molecules, big impact? overview of the mechanism of action, previous study results and potential adverse effects. J Dtsch Dermatol Ges. 2022;20:19-24. doi:10.1111/ddg.14668
  12. Chung BY, Um JY, Kang SY, et al. Oral alitretinoin for patients with refractory prurigo. Medicina (Kaunas). 2020;56:599. doi:10.3390/medicina56110599
  13. Maqbool T, Kraft JN. Alitretinoin for prurigo nodularis. Clin Exp Dermatol. 2021;46:362-363. doi:10.1111/ced.14385
  14. Grahovac M, Molin S, Prinz JC, et al. Treatment of atopic eczema with oral alitretinoin. Br J Dermatol. 2010;162:217-218. doi:10.1111/j.1365-2133.2009.09522.x
  15. Avila C, Massick S, Kaffenberger BH, et al. Cannabinoids for the treatment of chronic pruritus: a review. J Am Acad Dermatol. 2020;82:1205-1212. doi:10.1016/j.jaad.2020.01.036
  16. Deng J, Liao V, Parthasarathy V, et al. Modulation of neuroimmune and epithelial dysregulation in patients with moderate to severe prurigo nodularis treated with nemolizumab. JAMA Dermatol. 2023;159:977-985. doi:10.1001/jamadermatol.2023.2609
  17. Park B. Nemolizumab gets breakthrough therapy status for prurigo nodularis. Medical Professionals Reference website. Published December 9, 2019. Accessed November 13, 2023. https://www.empr.com/home/news/nemolizumab-gets-breakthrough-therapy-status-for-prurigo-nodularis/
  18. Labib A, Vander Does A, Yosipovitch G. Nemolizumab for atopic dermatitis. Drugs Today (Barc). 2022;58:159-173. doi:10.1358/dot.2022.58.4.3378056
References
  1. Elmariah S, Kim B, Berger T, et al. Practical approaches for diagnosis and management of prurigo nodularis: United States expert panel consensus [published online July 15, 2020]. J Am Acad Dermatol. 2021;84:747-760. doi:10.1016/j.jaad.2020.07.025
  2. Boozalis E, Tang O, Patel S, et al. Ethnic differences and comorbidities of 909 prurigo nodularis patients. J Am Acad Dermatol. 2018;79:714.
  3. Yosipovitch G, Mollanazar N, Ständer S, et al. Dupilumab in patients with prurigo nodularis: two randomized, double-blind, placebo-controlled phase 3 trials. Nat Med. 2023;29:1180-1190. doi:10.1038/s41591-023-02320-9
  4. Huang AH, Williams KA, Kwatra SG. Prurigo nodularis: epidemiology and clinical features. J Am Acad Dermatol. 2020;83:1559-1565. doi:10.1016/j.jaad.2020.04.183
  5. Joel MZ, Hydol-Smith J, Kambala A, et al. Prevalence and comorbidity burden of prurigo nodularis in United States adults enrolled in the All of Us research program. J Am Acad Dermatol. 2023;89:1056-1058. doi:10.1016/j.jaad.2023.06.045
  6. Dupixent. Package insert. Regeneron Pharmaceuticals, Inc; 2017.
  7. Khosravi H, Zhang S, Anderson AM, et al. Dupilumab drug survival, treatment failures, and insurance approval at a tertiary care center in the United States. J Am Acad Dermatol. 2020;82:1023-1024. doi:10.1016/j.jaad.2019.12.034
  8. Liu T, Chu Y, Wang Y, et al. Successful treatment of prurigo nodularis with tofacitinib: the experience from a single center. Int J Dermatol. 2023;62:E293-E295. doi:10.1111/ijd.16568
  9. Molloy OE, Kearney N, Byrne N, et al. Successful treatment of recalcitrant nodular prurigo with tofacitinib. Clin Exp Dermatol. 2020;45:918-920. doi:10.1111/ced.14320
  10. Yin M, Wu R, Chen J, et al. Successful treatment of refractory prurigo nodularis with baricitinib. Dermatol Ther. 2022;35:E15642. doi:10.1111/dth.15642
  11. Klein B, Treudler R, Simon JC. JAK-inhibitors in dermatology—small molecules, big impact? overview of the mechanism of action, previous study results and potential adverse effects. J Dtsch Dermatol Ges. 2022;20:19-24. doi:10.1111/ddg.14668
  12. Chung BY, Um JY, Kang SY, et al. Oral alitretinoin for patients with refractory prurigo. Medicina (Kaunas). 2020;56:599. doi:10.3390/medicina56110599
  13. Maqbool T, Kraft JN. Alitretinoin for prurigo nodularis. Clin Exp Dermatol. 2021;46:362-363. doi:10.1111/ced.14385
  14. Grahovac M, Molin S, Prinz JC, et al. Treatment of atopic eczema with oral alitretinoin. Br J Dermatol. 2010;162:217-218. doi:10.1111/j.1365-2133.2009.09522.x
  15. Avila C, Massick S, Kaffenberger BH, et al. Cannabinoids for the treatment of chronic pruritus: a review. J Am Acad Dermatol. 2020;82:1205-1212. doi:10.1016/j.jaad.2020.01.036
  16. Deng J, Liao V, Parthasarathy V, et al. Modulation of neuroimmune and epithelial dysregulation in patients with moderate to severe prurigo nodularis treated with nemolizumab. JAMA Dermatol. 2023;159:977-985. doi:10.1001/jamadermatol.2023.2609
  17. Park B. Nemolizumab gets breakthrough therapy status for prurigo nodularis. Medical Professionals Reference website. Published December 9, 2019. Accessed November 13, 2023. https://www.empr.com/home/news/nemolizumab-gets-breakthrough-therapy-status-for-prurigo-nodularis/
  18. Labib A, Vander Does A, Yosipovitch G. Nemolizumab for atopic dermatitis. Drugs Today (Barc). 2022;58:159-173. doi:10.1358/dot.2022.58.4.3378056
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Blood Glucose Testing Lancet and Paper Clip as a Milia Extractor

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Blood Glucose Testing Lancet and Paper Clip as a Milia Extractor
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Courtney N. Haller, MD
Nina Lemieux, MD
Dayna G. Diven, MD

Practice Gap

In low-resource settings, dermatologists may not have the preferred tools to evaluate a patient or perform a procedure. Commonplace affordable supplies can be substituted when needed.

Traditionally, tools readily available for comedone extraction in dermatology clinics include sterile disposable hypodermic needles to open the skin and either a comedone extractor or 2 cotton-tip applicators to apply pressure for extraction. However, when these tools are not available, resourceful techniques have been utilized. Ashique and Srinivas1 described a less-painful method for extracting conchae comedones that they called “pen punching,” which involved using the rim of the tip of a ballpoint pen to apply pressure to extract lesions. Mukhtar and Gupta2 used a 3-mL disposable syringe as a comedone extractor; the syringe was cut at the needle hub using a surgical blade, with one half at 30° to 45°. Kaya et al3 used sharp-tipped cautery to puncture closed macrocomedones. Cvancara and Meffert4 described how an autoclaved paper clip could be fashioned into a disposable comedone extractor, highlighting its potential use in humanitarian work or military deployments. A sterilized safety pin has been demonstrated to be an inexpensive tool to extract open and closed comedones without a surgical blade.5 We describe the use of a blood glucose testing lancet and a paper clip for comedone extraction.

Tools and Technique

A patient presented to a satellite clinic requesting extraction of multiple bothersome milia. A comedone extractor was unavailable at that location, and the patient’s access to care elsewhere was limited.

To perform extraction of milia in this case, we used a sterile, twist-top, stainless steel, 30-gauge blood glucose testing lancet and a paper clip sterilized with an isopropyl alcohol wipe (Figure). The beveled edge of the lancet was used to make a superficial opening to the skin, and the end loop of the paper clip was used as a comedone extractor. Applying moderate vertical pressure, 15 milia were expressed from the forearms. The patient tolerated the procedure well and reported minimal pain.

Paper clip and blood glucose testing lancet used for milia extraction.
Paper clip and blood glucose testing lancet used for milia extraction.

Practical Implications

The cost of the paper clip and lancet for our technique was $0.07. These materials are affordable, easy to use, and readily found in a variety of settings, making them a feasible option for performing this procedure. 

References
  1. Ashique KT, Srinivas CR. Pen punching: an innovative technique for comedone extraction from the well of the concha. J Am Acad Dermatol. 2015;73:E177. doi:10.1016/j.jaad.2015.07.033
  2. Mukhtar M, Gupta S. Surgical pearl: disposable syringe as modified customized comedone extractor. J Cutan Aesthet Surg. 2022;15:185-186. doi:10.4103/JCAS.JCAS_112_21
  3. Kaya TI, Tursen U, Kokturk A, et al. An effective extraction technique for the treatment of closed macrocomedones. Dermatol Surg. 2003;29:741-744. doi:10.1046/j.1524-4725.2003.29190.x
  4. Cvancara JL, Meffert JJ. Surgical pearl: versatile paper clip comedo extractor for acne surgery. J Am Acad Dermatol. 1999;40:477-478. doi:10.1016/s0190-9622(99)70501-3
  5. Mukhtar M, Sharma R. Surgical pearl: the safety pin as a better alternative to the versatile paper clip comedo extractor. Int J Dermatol. 2004;43:967-968. doi:10.1111/j.1365-4632.2004.02293.x
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From the Department of Dermatology, University of Texas at Austin Dell Medical School.

The authors report no conflict of interest.

Correspondence: Courtney N. Haller, MD, Health Transformation Building, The University of Texas at Austin, 1601 Trinity St, Building A, Austin, TX 78712 ([email protected]).

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Nina Lemieux, MD
Dayna G. Diven, MD
Author and Disclosure Information

From the Department of Dermatology, University of Texas at Austin Dell Medical School.

The authors report no conflict of interest.

Correspondence: Courtney N. Haller, MD, Health Transformation Building, The University of Texas at Austin, 1601 Trinity St, Building A, Austin, TX 78712 ([email protected]).

Author and Disclosure Information

From the Department of Dermatology, University of Texas at Austin Dell Medical School.

The authors report no conflict of interest.

Correspondence: Courtney N. Haller, MD, Health Transformation Building, The University of Texas at Austin, 1601 Trinity St, Building A, Austin, TX 78712 ([email protected]).

Article PDF
CT112006303.pdf
Article PDF
CT112006303.pdf

Practice Gap

In low-resource settings, dermatologists may not have the preferred tools to evaluate a patient or perform a procedure. Commonplace affordable supplies can be substituted when needed.

Traditionally, tools readily available for comedone extraction in dermatology clinics include sterile disposable hypodermic needles to open the skin and either a comedone extractor or 2 cotton-tip applicators to apply pressure for extraction. However, when these tools are not available, resourceful techniques have been utilized. Ashique and Srinivas1 described a less-painful method for extracting conchae comedones that they called “pen punching,” which involved using the rim of the tip of a ballpoint pen to apply pressure to extract lesions. Mukhtar and Gupta2 used a 3-mL disposable syringe as a comedone extractor; the syringe was cut at the needle hub using a surgical blade, with one half at 30° to 45°. Kaya et al3 used sharp-tipped cautery to puncture closed macrocomedones. Cvancara and Meffert4 described how an autoclaved paper clip could be fashioned into a disposable comedone extractor, highlighting its potential use in humanitarian work or military deployments. A sterilized safety pin has been demonstrated to be an inexpensive tool to extract open and closed comedones without a surgical blade.5 We describe the use of a blood glucose testing lancet and a paper clip for comedone extraction.

Tools and Technique

A patient presented to a satellite clinic requesting extraction of multiple bothersome milia. A comedone extractor was unavailable at that location, and the patient’s access to care elsewhere was limited.

To perform extraction of milia in this case, we used a sterile, twist-top, stainless steel, 30-gauge blood glucose testing lancet and a paper clip sterilized with an isopropyl alcohol wipe (Figure). The beveled edge of the lancet was used to make a superficial opening to the skin, and the end loop of the paper clip was used as a comedone extractor. Applying moderate vertical pressure, 15 milia were expressed from the forearms. The patient tolerated the procedure well and reported minimal pain.

Paper clip and blood glucose testing lancet used for milia extraction.
Paper clip and blood glucose testing lancet used for milia extraction.

Practical Implications

The cost of the paper clip and lancet for our technique was $0.07. These materials are affordable, easy to use, and readily found in a variety of settings, making them a feasible option for performing this procedure. 

Practice Gap

In low-resource settings, dermatologists may not have the preferred tools to evaluate a patient or perform a procedure. Commonplace affordable supplies can be substituted when needed.

Traditionally, tools readily available for comedone extraction in dermatology clinics include sterile disposable hypodermic needles to open the skin and either a comedone extractor or 2 cotton-tip applicators to apply pressure for extraction. However, when these tools are not available, resourceful techniques have been utilized. Ashique and Srinivas1 described a less-painful method for extracting conchae comedones that they called “pen punching,” which involved using the rim of the tip of a ballpoint pen to apply pressure to extract lesions. Mukhtar and Gupta2 used a 3-mL disposable syringe as a comedone extractor; the syringe was cut at the needle hub using a surgical blade, with one half at 30° to 45°. Kaya et al3 used sharp-tipped cautery to puncture closed macrocomedones. Cvancara and Meffert4 described how an autoclaved paper clip could be fashioned into a disposable comedone extractor, highlighting its potential use in humanitarian work or military deployments. A sterilized safety pin has been demonstrated to be an inexpensive tool to extract open and closed comedones without a surgical blade.5 We describe the use of a blood glucose testing lancet and a paper clip for comedone extraction.

Tools and Technique

A patient presented to a satellite clinic requesting extraction of multiple bothersome milia. A comedone extractor was unavailable at that location, and the patient’s access to care elsewhere was limited.

To perform extraction of milia in this case, we used a sterile, twist-top, stainless steel, 30-gauge blood glucose testing lancet and a paper clip sterilized with an isopropyl alcohol wipe (Figure). The beveled edge of the lancet was used to make a superficial opening to the skin, and the end loop of the paper clip was used as a comedone extractor. Applying moderate vertical pressure, 15 milia were expressed from the forearms. The patient tolerated the procedure well and reported minimal pain.

Paper clip and blood glucose testing lancet used for milia extraction.
Paper clip and blood glucose testing lancet used for milia extraction.

Practical Implications

The cost of the paper clip and lancet for our technique was $0.07. These materials are affordable, easy to use, and readily found in a variety of settings, making them a feasible option for performing this procedure. 

References
  1. Ashique KT, Srinivas CR. Pen punching: an innovative technique for comedone extraction from the well of the concha. J Am Acad Dermatol. 2015;73:E177. doi:10.1016/j.jaad.2015.07.033
  2. Mukhtar M, Gupta S. Surgical pearl: disposable syringe as modified customized comedone extractor. J Cutan Aesthet Surg. 2022;15:185-186. doi:10.4103/JCAS.JCAS_112_21
  3. Kaya TI, Tursen U, Kokturk A, et al. An effective extraction technique for the treatment of closed macrocomedones. Dermatol Surg. 2003;29:741-744. doi:10.1046/j.1524-4725.2003.29190.x
  4. Cvancara JL, Meffert JJ. Surgical pearl: versatile paper clip comedo extractor for acne surgery. J Am Acad Dermatol. 1999;40:477-478. doi:10.1016/s0190-9622(99)70501-3
  5. Mukhtar M, Sharma R. Surgical pearl: the safety pin as a better alternative to the versatile paper clip comedo extractor. Int J Dermatol. 2004;43:967-968. doi:10.1111/j.1365-4632.2004.02293.x
References
  1. Ashique KT, Srinivas CR. Pen punching: an innovative technique for comedone extraction from the well of the concha. J Am Acad Dermatol. 2015;73:E177. doi:10.1016/j.jaad.2015.07.033
  2. Mukhtar M, Gupta S. Surgical pearl: disposable syringe as modified customized comedone extractor. J Cutan Aesthet Surg. 2022;15:185-186. doi:10.4103/JCAS.JCAS_112_21
  3. Kaya TI, Tursen U, Kokturk A, et al. An effective extraction technique for the treatment of closed macrocomedones. Dermatol Surg. 2003;29:741-744. doi:10.1046/j.1524-4725.2003.29190.x
  4. Cvancara JL, Meffert JJ. Surgical pearl: versatile paper clip comedo extractor for acne surgery. J Am Acad Dermatol. 1999;40:477-478. doi:10.1016/s0190-9622(99)70501-3
  5. Mukhtar M, Sharma R. Surgical pearl: the safety pin as a better alternative to the versatile paper clip comedo extractor. Int J Dermatol. 2004;43:967-968. doi:10.1111/j.1365-4632.2004.02293.x
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ASH 2023: Equity, Sickle Cell, and Real-Life Outcomes

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Randy Dotinga

 

Health equity, sickle cell disease (SCD), and the thoughtful use of artificial intelligence (AI) and social media are among the key themes to be presented at the Dec. 9-12 annual meeting of the American Society of Hematology (ASH) in San Diego, association leaders told reporters in a media preview session.

Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.

“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”

As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.

In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”

Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”

Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.

Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.

She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”

ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.

AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”

Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel  “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”

Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.

He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”

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Health equity, sickle cell disease (SCD), and the thoughtful use of artificial intelligence (AI) and social media are among the key themes to be presented at the Dec. 9-12 annual meeting of the American Society of Hematology (ASH) in San Diego, association leaders told reporters in a media preview session.

Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.

“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”

As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.

In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”

Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”

Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.

Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.

She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”

ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.

AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”

Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel  “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”

Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.

He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”

 

Health equity, sickle cell disease (SCD), and the thoughtful use of artificial intelligence (AI) and social media are among the key themes to be presented at the Dec. 9-12 annual meeting of the American Society of Hematology (ASH) in San Diego, association leaders told reporters in a media preview session.

Cynthia E. Dunbar, MD, chief of the Translational Stem Cell Biology Branch at the National Heart, Lung, and Blood Institute and secretary of ASH, added that insight into actual patient experiences also will be a major theme at ASH 2023.

“There is a huge growth in research on outcomes and focusing on using real-world data and how important that is,” Dr. Dunbar said. “Academic research and hematology is really focusing on patient-reported outcomes and how care is delivered in a real-world setting – actually looking at what matters to patients. Are they alive in a certain number of years? And how are they feeling?”

As an example, Dr. Dunbar pointed to an abstract that examined clinical databases in Canada and found that real-world outcomes in multiple myeloma treatments were much worse than those in the original clinical trials for the therapies. Patients reached relapse 44% faster and their overall survival was 75% worse.

In the media briefing, ASH chair of communications Mikkael A. Sekeres, MD, MS, of the Sylvester Comprehensive Cancer Center at the University of Miami, noted that patients in these types of clinical trials “are just these pristine specimens of human beings except for the cancer that’s being treated.”

Dr. Dunbar agreed, noting that “patients who are able to enroll in clinical trials are more likely to be able to show up at the treatment center at the right time and for every dose, have transportation, and afford drugs to prevent side effects. They might stay on the drug for longer, or they have nurses who are always encouraging them of how to make it through a toxicity.”

Hematologists and patients should consider randomized controlled trials to be “the best possible outcome, and perhaps adjust their thinking if an individual patient is older, sicker, or less able to follow a regimen exactly,” she said.

Another highlighted study linked worse outcomes in African-Americans with pediatric acute myeloid leukemia to genetic traits that are more common in that population. The traits “likely explain at least in part the worst outcomes in Black patients in prior studies and on some regimens,” Dr. Dunbar said.

She added that the findings emphasize how testing for genetic variants and biomarkers that impact outcomes should be performed “instead of assuming that a certain dose should be given simply based on perceived or reported race or ethnicity.”

ASH President Robert A. Brodsky, MD, of Johns Hopkins University School of Medicine, Baltimore, highlighted an abstract that reported on the use of AI as a clinical decision support tool to differentiate two easily confused conditions — prefibrotic primary myelofibrosis and essential thrombocythemia.

AI “is a tool that’s going to help pathologists make more accurate and faster diagnoses,” he said. He also spotlighted an abstract about the use of “social media listening” to understand the experiences of patients with SCD and their caregivers. “There can be a lot of misuse and waste of time with social media, but they used this in a way to try and gain insight as to what’s really important to the patients and the caregiver.”

Also, in regard to SCD, Dr. Dunbar pointed to a study that reports on outcomes in patients who received lovotibeglogene autotemcel (lovo-cel) gene therapy for up to 60 months. Both this treatment and a CRISPR-based therapy called exa-cel  “appear to result in comparable very impressive efficacy in terms of pain crises and organ dysfunction,” she said. “The hurdle is going to be figuring out how to deliver what will be very expensive and complicated therapies — but likely curative — therapies to patients.”

Another study to be presented at ASH — coauthored by Dr. Brodsky — shows promising results from reduced-intensity haploidentical bone marrow transplantation in adults with severe SCD. Results were similar to those seen with bone marrow from matched siblings, Dr. Sekeres said.

He added that more clarity is needed about new treatment options for SCD, perhaps through a “randomized trial where patients upfront get a haploidentical bone marrow transplant or fully matched bone marrow transplant. Then other patients are randomized to some of these other, newer technology therapies, and we follow them over time. We’re looking not only for overall survival but complications of the therapy itself and how many patients relapse from the treatment.”

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ASTRO Updates Partial Breast Irradiation Guidance in Early Breast Cancer

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The American Society for Radiation Oncology (ASTRO) has issued an updated clinical practice guideline on partial breast irradiation for women with early-stage invasive breast cancer or ductal carcinoma in situ (DCIS). The 2023 guideline, which replaces the 2017 recommendations, factors in new clinical trial data that consistently show no significant differences in overall survival, cancer-free survival, and recurrence in the same breast among patients who receive partial breast irradiation compared with whole breast irradiation. The data also indicate similar or improved side effects with partial vs whole breast irradiation.

To develop the 2023 recommendations, the Agency for Healthcare Research and Quality (AHRQ) conducted a systematic review assessing the latest clinical trial evidence, and ASTRO assembled an expert task force to determine best practices for using partial breast irradiation.

“There have been more than 10,000 women included in these randomized controlled trials, with 10 years of follow-up showing equivalency in tumor control between partial breast and whole breast radiation for appropriately selected patients,” Simona Shaitelman, MD, vice chair of the guideline task force, said in a news release.

“These data should be driving a change in practice, and partial breast radiation should be a larger part of the dialogue when we consult with patients on decisions about how best to treat their early-stage breast cancer,” added Dr. Shaitelman, professor of breast radiation oncology at the University of Texas MD Anderson Cancer Center in Houston.

What’s in the New Guidelines?

For patients with early-stage, node-negative invasive breast cancer, the updated guideline strongly recommends partial breast irradiation instead of whole breast irradiation if the patient has favorable clinical features and tumor characteristics, including grade 1 or 2 disease, estrogen receptor (ER)-positive status, small tumor size, and age 40 or older.

In contrast, the 2017 guideline considered patients aged 50 and older suitable for partial breast irradiation and considered those in their 40s who met certain pathologic criteria “cautionary.”The updated guideline also conditionally recommends partial over whole breast irradiation if the patient has risk factors that indicate a higher likelihood of recurrence, such as grade 3 disease, ER-negative histology, or larger tumor size.

The task force does not recommend partial breast irradiation for patients with positive lymph nodes, positive surgical margins, or germline BRCA1/2 mutations or patients under 40.

Given the lack of robust data in patients with less favorable risk features, such as lymphovascular invasion or lobular histology, partial breast irradiation is conditionally not recommended for these patients.

For DCIS, the updated recommendations mirror those for early-stage breast cancer, with partial breast irradiation strongly recommended as an alternative to whole breast irradiation among patients with favorable clinical and tumor features, such as grade 1 or 2 disease and ER-positive status. Partial breast irradiation is conditionally recommended for higher grade disease or larger tumors, and not recommended for patients with positive surgical margins, BRCA mutations or those younger than 40.

In addition to relevant patient populations, the updated guidelines also address techniques and best practices for delivering partial breast irradiation.

Recommended partial breast irradiation techniques include 3-D conformal radiation therapy, intensity modulated radiation therapy, and multicatheter interstitial brachytherapy, given the evidence showing similar long-term rates of ipsilateral breast recurrence compared with whole breast irradiation.

Single-entry catheter brachytherapy is conditionally recommended, and intraoperative radiation therapy techniques are not recommended unless integrated into a prospective clinical trial or multi-institutional registry.

The guideline also outlines optimal dose, fractionation, target volume, and treatment modality with different partial breast irradiation techniques, taking toxicities and cosmesis into consideration.

“We hope that by laying out the evidence from these major trials and providing guidance on how to administer partial breast radiation, the guideline can help more oncologists feel comfortable offering this option to their patients as an alternative to whole breast radiation,” Janice Lyons, MD, of University Hospitals Seidman Cancer Center, Cleveland, Ohio, and chair of the guideline task force, said in the news release.

The guideline, developed in collaboration with the American Society of Clinical Oncology and the Society of Surgical Oncology, has been endorsed by the Canadian Association of Radiation Oncology, the European Society for Radiotherapy and Oncology, and the Royal Australian and New Zealand College of Radiologists. Guideline development was funded by ASTRO and the systematic evidence review was funded by the Patient-Centered Outcomes Research Institute. Disclosures for the task force are available with the original article.
 

A version of this article was first published on Medscape.com.

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The American Society for Radiation Oncology (ASTRO) has issued an updated clinical practice guideline on partial breast irradiation for women with early-stage invasive breast cancer or ductal carcinoma in situ (DCIS). The 2023 guideline, which replaces the 2017 recommendations, factors in new clinical trial data that consistently show no significant differences in overall survival, cancer-free survival, and recurrence in the same breast among patients who receive partial breast irradiation compared with whole breast irradiation. The data also indicate similar or improved side effects with partial vs whole breast irradiation.

To develop the 2023 recommendations, the Agency for Healthcare Research and Quality (AHRQ) conducted a systematic review assessing the latest clinical trial evidence, and ASTRO assembled an expert task force to determine best practices for using partial breast irradiation.

“There have been more than 10,000 women included in these randomized controlled trials, with 10 years of follow-up showing equivalency in tumor control between partial breast and whole breast radiation for appropriately selected patients,” Simona Shaitelman, MD, vice chair of the guideline task force, said in a news release.

“These data should be driving a change in practice, and partial breast radiation should be a larger part of the dialogue when we consult with patients on decisions about how best to treat their early-stage breast cancer,” added Dr. Shaitelman, professor of breast radiation oncology at the University of Texas MD Anderson Cancer Center in Houston.

What’s in the New Guidelines?

For patients with early-stage, node-negative invasive breast cancer, the updated guideline strongly recommends partial breast irradiation instead of whole breast irradiation if the patient has favorable clinical features and tumor characteristics, including grade 1 or 2 disease, estrogen receptor (ER)-positive status, small tumor size, and age 40 or older.

In contrast, the 2017 guideline considered patients aged 50 and older suitable for partial breast irradiation and considered those in their 40s who met certain pathologic criteria “cautionary.”The updated guideline also conditionally recommends partial over whole breast irradiation if the patient has risk factors that indicate a higher likelihood of recurrence, such as grade 3 disease, ER-negative histology, or larger tumor size.

The task force does not recommend partial breast irradiation for patients with positive lymph nodes, positive surgical margins, or germline BRCA1/2 mutations or patients under 40.

Given the lack of robust data in patients with less favorable risk features, such as lymphovascular invasion or lobular histology, partial breast irradiation is conditionally not recommended for these patients.

For DCIS, the updated recommendations mirror those for early-stage breast cancer, with partial breast irradiation strongly recommended as an alternative to whole breast irradiation among patients with favorable clinical and tumor features, such as grade 1 or 2 disease and ER-positive status. Partial breast irradiation is conditionally recommended for higher grade disease or larger tumors, and not recommended for patients with positive surgical margins, BRCA mutations or those younger than 40.

In addition to relevant patient populations, the updated guidelines also address techniques and best practices for delivering partial breast irradiation.

Recommended partial breast irradiation techniques include 3-D conformal radiation therapy, intensity modulated radiation therapy, and multicatheter interstitial brachytherapy, given the evidence showing similar long-term rates of ipsilateral breast recurrence compared with whole breast irradiation.

Single-entry catheter brachytherapy is conditionally recommended, and intraoperative radiation therapy techniques are not recommended unless integrated into a prospective clinical trial or multi-institutional registry.

The guideline also outlines optimal dose, fractionation, target volume, and treatment modality with different partial breast irradiation techniques, taking toxicities and cosmesis into consideration.

“We hope that by laying out the evidence from these major trials and providing guidance on how to administer partial breast radiation, the guideline can help more oncologists feel comfortable offering this option to their patients as an alternative to whole breast radiation,” Janice Lyons, MD, of University Hospitals Seidman Cancer Center, Cleveland, Ohio, and chair of the guideline task force, said in the news release.

The guideline, developed in collaboration with the American Society of Clinical Oncology and the Society of Surgical Oncology, has been endorsed by the Canadian Association of Radiation Oncology, the European Society for Radiotherapy and Oncology, and the Royal Australian and New Zealand College of Radiologists. Guideline development was funded by ASTRO and the systematic evidence review was funded by the Patient-Centered Outcomes Research Institute. Disclosures for the task force are available with the original article.
 

A version of this article was first published on Medscape.com.

The American Society for Radiation Oncology (ASTRO) has issued an updated clinical practice guideline on partial breast irradiation for women with early-stage invasive breast cancer or ductal carcinoma in situ (DCIS). The 2023 guideline, which replaces the 2017 recommendations, factors in new clinical trial data that consistently show no significant differences in overall survival, cancer-free survival, and recurrence in the same breast among patients who receive partial breast irradiation compared with whole breast irradiation. The data also indicate similar or improved side effects with partial vs whole breast irradiation.

To develop the 2023 recommendations, the Agency for Healthcare Research and Quality (AHRQ) conducted a systematic review assessing the latest clinical trial evidence, and ASTRO assembled an expert task force to determine best practices for using partial breast irradiation.

“There have been more than 10,000 women included in these randomized controlled trials, with 10 years of follow-up showing equivalency in tumor control between partial breast and whole breast radiation for appropriately selected patients,” Simona Shaitelman, MD, vice chair of the guideline task force, said in a news release.

“These data should be driving a change in practice, and partial breast radiation should be a larger part of the dialogue when we consult with patients on decisions about how best to treat their early-stage breast cancer,” added Dr. Shaitelman, professor of breast radiation oncology at the University of Texas MD Anderson Cancer Center in Houston.

What’s in the New Guidelines?

For patients with early-stage, node-negative invasive breast cancer, the updated guideline strongly recommends partial breast irradiation instead of whole breast irradiation if the patient has favorable clinical features and tumor characteristics, including grade 1 or 2 disease, estrogen receptor (ER)-positive status, small tumor size, and age 40 or older.

In contrast, the 2017 guideline considered patients aged 50 and older suitable for partial breast irradiation and considered those in their 40s who met certain pathologic criteria “cautionary.”The updated guideline also conditionally recommends partial over whole breast irradiation if the patient has risk factors that indicate a higher likelihood of recurrence, such as grade 3 disease, ER-negative histology, or larger tumor size.

The task force does not recommend partial breast irradiation for patients with positive lymph nodes, positive surgical margins, or germline BRCA1/2 mutations or patients under 40.

Given the lack of robust data in patients with less favorable risk features, such as lymphovascular invasion or lobular histology, partial breast irradiation is conditionally not recommended for these patients.

For DCIS, the updated recommendations mirror those for early-stage breast cancer, with partial breast irradiation strongly recommended as an alternative to whole breast irradiation among patients with favorable clinical and tumor features, such as grade 1 or 2 disease and ER-positive status. Partial breast irradiation is conditionally recommended for higher grade disease or larger tumors, and not recommended for patients with positive surgical margins, BRCA mutations or those younger than 40.

In addition to relevant patient populations, the updated guidelines also address techniques and best practices for delivering partial breast irradiation.

Recommended partial breast irradiation techniques include 3-D conformal radiation therapy, intensity modulated radiation therapy, and multicatheter interstitial brachytherapy, given the evidence showing similar long-term rates of ipsilateral breast recurrence compared with whole breast irradiation.

Single-entry catheter brachytherapy is conditionally recommended, and intraoperative radiation therapy techniques are not recommended unless integrated into a prospective clinical trial or multi-institutional registry.

The guideline also outlines optimal dose, fractionation, target volume, and treatment modality with different partial breast irradiation techniques, taking toxicities and cosmesis into consideration.

“We hope that by laying out the evidence from these major trials and providing guidance on how to administer partial breast radiation, the guideline can help more oncologists feel comfortable offering this option to their patients as an alternative to whole breast radiation,” Janice Lyons, MD, of University Hospitals Seidman Cancer Center, Cleveland, Ohio, and chair of the guideline task force, said in the news release.

The guideline, developed in collaboration with the American Society of Clinical Oncology and the Society of Surgical Oncology, has been endorsed by the Canadian Association of Radiation Oncology, the European Society for Radiotherapy and Oncology, and the Royal Australian and New Zealand College of Radiologists. Guideline development was funded by ASTRO and the systematic evidence review was funded by the Patient-Centered Outcomes Research Institute. Disclosures for the task force are available with the original article.
 

A version of this article was first published on Medscape.com.

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Fewer than 1 out of 4 patients with HCV-related liver cancer receive antivirals

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Fewer than one out of four patients with hepatitis C virus (HCV)-related hepatocellular carcinoma (HCC) receive oral interferon-free direct-acting antiviral agents (DAAs), and rates aren’t much better for patients seen by specialists, based on a retrospective analysis of private insurance claims.

The study also showed that patients receiving DAAs lived significantly longer, emphasizing the importance of prescribing these medications to all eligible patients, reported principal investigator Mindie H. Nguyen, MD, AGAF,, of Stanford University Medical Center, Palo Alto, California, and colleagues.

“Prior studies have shown evidence of improved survival among HCV-related HCC patients who received DAA treatment, but not much is known about the current DAA utilization among these patients in the general US population,” said lead author Leslie Y. Kam, MD, a postdoctoral scholar in gastroenterology at Stanford Medicine, who presented the findings in November at the annual meeting of the American Association for the Study of Liver Diseases.

To generate real-world data, the investigators analyzed medical records from 3922 patients in Optum’s Clinformatics Data Mart Database. All patients had private medical insurance and received care for HCV-related HCC between 2015 and 2021.

“Instead of using institutional databases which tend to bias toward highly specialized tertiary care center patients, our study uses a large, national sample of HCV-HCC patients that represents real-world DAA treatment rates and survival outcomes,” Dr. Kam said in a written comment.

Within this cohort, fewer than one out of four patients (23.5%) received DAA, a rate that Dr. Kam called “dismally low.”

Patients with either compensated or decompensated cirrhosis had higher treatment rates than those without cirrhosis (24.2% or 24.5%, respectively, vs. 16.2%; P = .001). The investigators noted that more than half of the patients had decompensated cirrhosis, suggesting that HCV-related HCC was diagnosed late in the disease course.

Receiving care from a gastroenterologist or infectious disease physician also was associated with a higher treatment rate. Patients managed by a gastroenterologist alone had a treatment rate of 27.0%, while those who received care from a gastroenterologist or infectious disease doctor alongside an oncologist had a treatment rate of 25.6%, versus just 9.4% for those who received care from an oncologist alone, and 12.4% among those who did not see a specialist of any kind (P = .005).

These findings highlight “the need for a multidisciplinary approach to care in this population,” Dr. Kam suggested.

Echoing previous research, DAAs were associated with extended survival. A significantly greater percentage of patients who received DAA were alive after 5 years, compared with patients who did not receive DAA (47.2% vs. 35.2%; P less than .001). After adjustment for comorbidities, HCC treatment, race/ethnicity, sex, and age, DAAs were associated with a 39% reduction in risk of death (adjusted hazard ratio, 0.61; 0.53-0.69; P less than .001).

“There were also racial ethnic disparities in patient survival whether patients received DAA or not, with Black patients having worse survival,” Dr. Kam said. “As such, our study highlights that awareness of HCV remains low as does the use of DAA treatment. Therefore, culturally appropriate efforts to improve awareness of HCV must continue among the general public and health care workers as well as efforts to provide point of care accurate and rapid screening tests for HCV so that DAA treatment can be initiated in a timely manner for eligible patients. Continual education on the use of DAA treatment is also needed.”

Robert John Fontana, MD, AGAF, professor of medicine and transplant hepatologist at the University of Michigan, Ann Arbor, described the findings as “frustrating,” and “not the kind of stuff I like to hear about.

“Treatment rates are so low,” Dr. Fontana said, noting that even among gastroenterologists and infectious disease doctors, who should be well-versed in DAAs, antivirals were prescribed less than 30% of the time.

In an interview, Dr. Fontana highlighted the benefits of DAAs, including their ease-of-use and effectiveness.

“Hepatitis C was the leading reason that we had to do liver transplants in the United States for years,” he said. “Then once these really amazing drugs called direct-acting antivirals came out, they changed the landscape very quickly. It really was a game changer for my whole practice, and, nationally, the practice of transplant.”

Yet, this study and others suggest that these practice-altering agents are being underutilized, Dr. Fontana said. A variety of reasons could explain suboptimal usage, he suggested, including lack of awareness among medical professionals and the public, the recency of DAA approvals, low HCV testing rates, lack of symptoms in HCV-positive patients, and medication costs.

This latter barrier, at least, is dissolving, Dr. Fontana said. Some payers initially restricted which providers could prescribe DAAs, but now the economic consensus has swung in their favor, since curing patients of HCV brings significant health care savings down the line. This financial advantage—theoretically multiplied across 4-5 million Americans living with HCV—has bolstered a multi-institutional effort toward universal HCV screening, with testing recommended at least once in every person’s lifetime.

“It’s highly cost effective,” Dr. Fontana said. “Even though the drugs are super expensive, you will reduce cost by preventing the people streaming towards liver cancer or streaming towards liver transplant. That’s why all the professional societies—the USPSTF, the CDC—they all say, ‘OK, screen everyone.’ ”

Screening may be getting easier soon, Dr. Fontana predicted, as at-home HCV-testing kits are on the horizon, with development and adoption likely accelerated by the success of at-home viral testing during the COVID-19 pandemic.

Beyond broader screening, Dr. Fontana suggested that greater awareness of DAAs is needed both within and beyond the medical community.

He advised health care providers who don’t yet feel comfortable diagnosing or treating HCV to refer to their local specialist.

“That’s the main message,” Dr. Fontana said. “I’m always eternally hopeful that every little message helps.”

The investigators and Dr. Fontana disclosed no conflicts of interest.

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Fewer than one out of four patients with hepatitis C virus (HCV)-related hepatocellular carcinoma (HCC) receive oral interferon-free direct-acting antiviral agents (DAAs), and rates aren’t much better for patients seen by specialists, based on a retrospective analysis of private insurance claims.

The study also showed that patients receiving DAAs lived significantly longer, emphasizing the importance of prescribing these medications to all eligible patients, reported principal investigator Mindie H. Nguyen, MD, AGAF,, of Stanford University Medical Center, Palo Alto, California, and colleagues.

“Prior studies have shown evidence of improved survival among HCV-related HCC patients who received DAA treatment, but not much is known about the current DAA utilization among these patients in the general US population,” said lead author Leslie Y. Kam, MD, a postdoctoral scholar in gastroenterology at Stanford Medicine, who presented the findings in November at the annual meeting of the American Association for the Study of Liver Diseases.

To generate real-world data, the investigators analyzed medical records from 3922 patients in Optum’s Clinformatics Data Mart Database. All patients had private medical insurance and received care for HCV-related HCC between 2015 and 2021.

“Instead of using institutional databases which tend to bias toward highly specialized tertiary care center patients, our study uses a large, national sample of HCV-HCC patients that represents real-world DAA treatment rates and survival outcomes,” Dr. Kam said in a written comment.

Within this cohort, fewer than one out of four patients (23.5%) received DAA, a rate that Dr. Kam called “dismally low.”

Patients with either compensated or decompensated cirrhosis had higher treatment rates than those without cirrhosis (24.2% or 24.5%, respectively, vs. 16.2%; P = .001). The investigators noted that more than half of the patients had decompensated cirrhosis, suggesting that HCV-related HCC was diagnosed late in the disease course.

Receiving care from a gastroenterologist or infectious disease physician also was associated with a higher treatment rate. Patients managed by a gastroenterologist alone had a treatment rate of 27.0%, while those who received care from a gastroenterologist or infectious disease doctor alongside an oncologist had a treatment rate of 25.6%, versus just 9.4% for those who received care from an oncologist alone, and 12.4% among those who did not see a specialist of any kind (P = .005).

These findings highlight “the need for a multidisciplinary approach to care in this population,” Dr. Kam suggested.

Echoing previous research, DAAs were associated with extended survival. A significantly greater percentage of patients who received DAA were alive after 5 years, compared with patients who did not receive DAA (47.2% vs. 35.2%; P less than .001). After adjustment for comorbidities, HCC treatment, race/ethnicity, sex, and age, DAAs were associated with a 39% reduction in risk of death (adjusted hazard ratio, 0.61; 0.53-0.69; P less than .001).

“There were also racial ethnic disparities in patient survival whether patients received DAA or not, with Black patients having worse survival,” Dr. Kam said. “As such, our study highlights that awareness of HCV remains low as does the use of DAA treatment. Therefore, culturally appropriate efforts to improve awareness of HCV must continue among the general public and health care workers as well as efforts to provide point of care accurate and rapid screening tests for HCV so that DAA treatment can be initiated in a timely manner for eligible patients. Continual education on the use of DAA treatment is also needed.”

Robert John Fontana, MD, AGAF, professor of medicine and transplant hepatologist at the University of Michigan, Ann Arbor, described the findings as “frustrating,” and “not the kind of stuff I like to hear about.

“Treatment rates are so low,” Dr. Fontana said, noting that even among gastroenterologists and infectious disease doctors, who should be well-versed in DAAs, antivirals were prescribed less than 30% of the time.

In an interview, Dr. Fontana highlighted the benefits of DAAs, including their ease-of-use and effectiveness.

“Hepatitis C was the leading reason that we had to do liver transplants in the United States for years,” he said. “Then once these really amazing drugs called direct-acting antivirals came out, they changed the landscape very quickly. It really was a game changer for my whole practice, and, nationally, the practice of transplant.”

Yet, this study and others suggest that these practice-altering agents are being underutilized, Dr. Fontana said. A variety of reasons could explain suboptimal usage, he suggested, including lack of awareness among medical professionals and the public, the recency of DAA approvals, low HCV testing rates, lack of symptoms in HCV-positive patients, and medication costs.

This latter barrier, at least, is dissolving, Dr. Fontana said. Some payers initially restricted which providers could prescribe DAAs, but now the economic consensus has swung in their favor, since curing patients of HCV brings significant health care savings down the line. This financial advantage—theoretically multiplied across 4-5 million Americans living with HCV—has bolstered a multi-institutional effort toward universal HCV screening, with testing recommended at least once in every person’s lifetime.

“It’s highly cost effective,” Dr. Fontana said. “Even though the drugs are super expensive, you will reduce cost by preventing the people streaming towards liver cancer or streaming towards liver transplant. That’s why all the professional societies—the USPSTF, the CDC—they all say, ‘OK, screen everyone.’ ”

Screening may be getting easier soon, Dr. Fontana predicted, as at-home HCV-testing kits are on the horizon, with development and adoption likely accelerated by the success of at-home viral testing during the COVID-19 pandemic.

Beyond broader screening, Dr. Fontana suggested that greater awareness of DAAs is needed both within and beyond the medical community.

He advised health care providers who don’t yet feel comfortable diagnosing or treating HCV to refer to their local specialist.

“That’s the main message,” Dr. Fontana said. “I’m always eternally hopeful that every little message helps.”

The investigators and Dr. Fontana disclosed no conflicts of interest.

Fewer than one out of four patients with hepatitis C virus (HCV)-related hepatocellular carcinoma (HCC) receive oral interferon-free direct-acting antiviral agents (DAAs), and rates aren’t much better for patients seen by specialists, based on a retrospective analysis of private insurance claims.

The study also showed that patients receiving DAAs lived significantly longer, emphasizing the importance of prescribing these medications to all eligible patients, reported principal investigator Mindie H. Nguyen, MD, AGAF,, of Stanford University Medical Center, Palo Alto, California, and colleagues.

“Prior studies have shown evidence of improved survival among HCV-related HCC patients who received DAA treatment, but not much is known about the current DAA utilization among these patients in the general US population,” said lead author Leslie Y. Kam, MD, a postdoctoral scholar in gastroenterology at Stanford Medicine, who presented the findings in November at the annual meeting of the American Association for the Study of Liver Diseases.

To generate real-world data, the investigators analyzed medical records from 3922 patients in Optum’s Clinformatics Data Mart Database. All patients had private medical insurance and received care for HCV-related HCC between 2015 and 2021.

“Instead of using institutional databases which tend to bias toward highly specialized tertiary care center patients, our study uses a large, national sample of HCV-HCC patients that represents real-world DAA treatment rates and survival outcomes,” Dr. Kam said in a written comment.

Within this cohort, fewer than one out of four patients (23.5%) received DAA, a rate that Dr. Kam called “dismally low.”

Patients with either compensated or decompensated cirrhosis had higher treatment rates than those without cirrhosis (24.2% or 24.5%, respectively, vs. 16.2%; P = .001). The investigators noted that more than half of the patients had decompensated cirrhosis, suggesting that HCV-related HCC was diagnosed late in the disease course.

Receiving care from a gastroenterologist or infectious disease physician also was associated with a higher treatment rate. Patients managed by a gastroenterologist alone had a treatment rate of 27.0%, while those who received care from a gastroenterologist or infectious disease doctor alongside an oncologist had a treatment rate of 25.6%, versus just 9.4% for those who received care from an oncologist alone, and 12.4% among those who did not see a specialist of any kind (P = .005).

These findings highlight “the need for a multidisciplinary approach to care in this population,” Dr. Kam suggested.

Echoing previous research, DAAs were associated with extended survival. A significantly greater percentage of patients who received DAA were alive after 5 years, compared with patients who did not receive DAA (47.2% vs. 35.2%; P less than .001). After adjustment for comorbidities, HCC treatment, race/ethnicity, sex, and age, DAAs were associated with a 39% reduction in risk of death (adjusted hazard ratio, 0.61; 0.53-0.69; P less than .001).

“There were also racial ethnic disparities in patient survival whether patients received DAA or not, with Black patients having worse survival,” Dr. Kam said. “As such, our study highlights that awareness of HCV remains low as does the use of DAA treatment. Therefore, culturally appropriate efforts to improve awareness of HCV must continue among the general public and health care workers as well as efforts to provide point of care accurate and rapid screening tests for HCV so that DAA treatment can be initiated in a timely manner for eligible patients. Continual education on the use of DAA treatment is also needed.”

Robert John Fontana, MD, AGAF, professor of medicine and transplant hepatologist at the University of Michigan, Ann Arbor, described the findings as “frustrating,” and “not the kind of stuff I like to hear about.

“Treatment rates are so low,” Dr. Fontana said, noting that even among gastroenterologists and infectious disease doctors, who should be well-versed in DAAs, antivirals were prescribed less than 30% of the time.

In an interview, Dr. Fontana highlighted the benefits of DAAs, including their ease-of-use and effectiveness.

“Hepatitis C was the leading reason that we had to do liver transplants in the United States for years,” he said. “Then once these really amazing drugs called direct-acting antivirals came out, they changed the landscape very quickly. It really was a game changer for my whole practice, and, nationally, the practice of transplant.”

Yet, this study and others suggest that these practice-altering agents are being underutilized, Dr. Fontana said. A variety of reasons could explain suboptimal usage, he suggested, including lack of awareness among medical professionals and the public, the recency of DAA approvals, low HCV testing rates, lack of symptoms in HCV-positive patients, and medication costs.

This latter barrier, at least, is dissolving, Dr. Fontana said. Some payers initially restricted which providers could prescribe DAAs, but now the economic consensus has swung in their favor, since curing patients of HCV brings significant health care savings down the line. This financial advantage—theoretically multiplied across 4-5 million Americans living with HCV—has bolstered a multi-institutional effort toward universal HCV screening, with testing recommended at least once in every person’s lifetime.

“It’s highly cost effective,” Dr. Fontana said. “Even though the drugs are super expensive, you will reduce cost by preventing the people streaming towards liver cancer or streaming towards liver transplant. That’s why all the professional societies—the USPSTF, the CDC—they all say, ‘OK, screen everyone.’ ”

Screening may be getting easier soon, Dr. Fontana predicted, as at-home HCV-testing kits are on the horizon, with development and adoption likely accelerated by the success of at-home viral testing during the COVID-19 pandemic.

Beyond broader screening, Dr. Fontana suggested that greater awareness of DAAs is needed both within and beyond the medical community.

He advised health care providers who don’t yet feel comfortable diagnosing or treating HCV to refer to their local specialist.

“That’s the main message,” Dr. Fontana said. “I’m always eternally hopeful that every little message helps.”

The investigators and Dr. Fontana disclosed no conflicts of interest.

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Taste and smell changes linked with worse QOL and cognition in cirrhosis, renal failure

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Patients with cirrhosis or renal failure who experience changes in taste and smell may have worse quality-of-life (QOL) and may be more likely to exhibit cognitive impairment than those who do not exhibit these sensory changes, according to investigators.

Clinicians should screen for changes in taste and smell among patients at risk of cognitive changes, and offer nutritional interventions to support body weight and QOL, reported principal investigator Jasmohan S. Bajaj, MD, AGAF, of Virginia Commonwealth University, Richmond, and colleagues.

Dr. Jasmohan S. Bajaj

“Cirrhosis is linked with poor nutrition, which could partly be due to anorexia in hepatic encephalopathy (HE) and coexistent renal failure,” the investigators wrote in their abstract, which Dr. Bajaj presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“We wanted to measure how changes in the brain in cirrhosis affect patients’ abilities to smell and taste, and study how that affects their quality of life,” Dr. Bajaj said in a written comment.

To this end, the investigators conducted an observational study involving 59 participants, among whom 22 were healthy, 21 had cirrhosis, and 16 had renal failure requiring dialysis.

“Prior studies individually have shown changes in taste and smell for these two organ failures,” Dr. Bajaj said. “We studied them together as well and linked these to quality of life and individual cognitive tests.”

Of note, individuals with past or current COVID-19, or with current or recent alcohol or tobacco use, were excluded.

Compared with healthy individuals, participants with cirrhosis or renal failure had significantly worse performance on a taste discrimination test, with perceptions of sweet and sour most affected.

Cognitive measurement with Psychometric Hepatic Encephalopathy Score (PHES) and Stroop tests showed that scores were worse for patients with disease than those without. Taste discrimination significantly correlated with both cognitive test scores, regardless of HE or dialysis, whereas smell only correlated with the Stroop test.

Multivariable analysis revealed that better PHES scores and smell discrimination were linked with better taste discrimination. Similarly, better PHES scores and taste discrimination contributed to better smell discrimination. Eating impairment was associated with worse Stroop scores and worse olfactory-related QOL, suggesting that sensory changes, cognitive changes, and eating behaviors were all correlated.

“Health care providers ought to be alert to changes in patients’ eating habits, diet and weight as their liver and kidney disease worsen and as their brain function changes,” Dr. Bajaj said. “Nutritionists and others may be able to assist patients with a healthy diet and suggest ways to improve patients’ reports of their quality of life. Taste and smell are just a few aspects of the complicated assessment of health-related quality of life, brain dysfunction, and nutritional compromise in cirrhosis. We need to be mindful to not just focus on these aspects but to individualize care.”

Adrian M. Di Bisceglie, MD, hepatologist and emeritus professor of internal medicine at Saint Louis University, said the study was “well done,” and called the findings “an interesting little tidbit” that would probably not change his practice as a physician, but could be valuable for designing nutritional interventions.

Saint Louis University
Dr. Adrian M. Di Bisceglie

In an interview, Dr. Di Bisceglie explained that a well-balanced diet with adequate caloric intake can help slow the muscle wasting that occurs with the condition, but creating a tasty menu can be challenging when patients are asked to restrict their sodium intake as a means of reducing fluid retention.

“Salt contributes substantially to the enjoyment of food,” Dr. Di Bisceglie said.

Although the study did not specifically report the salt level in patients’ diets, Dr. Di Bisceglie said the findings highlight the need for low-salt strategies to improve palatability. For example, he suggested increasing umami, or savory flavor, as this can be accomplished without adding a significant amount of salt.

When asked if changes in taste or smell might be used as simple screening tools to detect cognitive impairment in patients with cirrhosis, Dr. Di Bisceglie said that this might be “possible,” but is probably unnecessary.

“There is an easy bedside test that we’ve been using for decades [to predict hepatic encephalopathy], which is reading,” Dr. Di Bisceglie said, noting that patients with cognitive deficits often describe reading paragraphs repeatedly without comprehending what they have read.

The investigators and Dr. Di Bisceglie disclosed no conflicts of interest.

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Patients with cirrhosis or renal failure who experience changes in taste and smell may have worse quality-of-life (QOL) and may be more likely to exhibit cognitive impairment than those who do not exhibit these sensory changes, according to investigators.

Clinicians should screen for changes in taste and smell among patients at risk of cognitive changes, and offer nutritional interventions to support body weight and QOL, reported principal investigator Jasmohan S. Bajaj, MD, AGAF, of Virginia Commonwealth University, Richmond, and colleagues.

Dr. Jasmohan S. Bajaj

“Cirrhosis is linked with poor nutrition, which could partly be due to anorexia in hepatic encephalopathy (HE) and coexistent renal failure,” the investigators wrote in their abstract, which Dr. Bajaj presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“We wanted to measure how changes in the brain in cirrhosis affect patients’ abilities to smell and taste, and study how that affects their quality of life,” Dr. Bajaj said in a written comment.

To this end, the investigators conducted an observational study involving 59 participants, among whom 22 were healthy, 21 had cirrhosis, and 16 had renal failure requiring dialysis.

“Prior studies individually have shown changes in taste and smell for these two organ failures,” Dr. Bajaj said. “We studied them together as well and linked these to quality of life and individual cognitive tests.”

Of note, individuals with past or current COVID-19, or with current or recent alcohol or tobacco use, were excluded.

Compared with healthy individuals, participants with cirrhosis or renal failure had significantly worse performance on a taste discrimination test, with perceptions of sweet and sour most affected.

Cognitive measurement with Psychometric Hepatic Encephalopathy Score (PHES) and Stroop tests showed that scores were worse for patients with disease than those without. Taste discrimination significantly correlated with both cognitive test scores, regardless of HE or dialysis, whereas smell only correlated with the Stroop test.

Multivariable analysis revealed that better PHES scores and smell discrimination were linked with better taste discrimination. Similarly, better PHES scores and taste discrimination contributed to better smell discrimination. Eating impairment was associated with worse Stroop scores and worse olfactory-related QOL, suggesting that sensory changes, cognitive changes, and eating behaviors were all correlated.

“Health care providers ought to be alert to changes in patients’ eating habits, diet and weight as their liver and kidney disease worsen and as their brain function changes,” Dr. Bajaj said. “Nutritionists and others may be able to assist patients with a healthy diet and suggest ways to improve patients’ reports of their quality of life. Taste and smell are just a few aspects of the complicated assessment of health-related quality of life, brain dysfunction, and nutritional compromise in cirrhosis. We need to be mindful to not just focus on these aspects but to individualize care.”

Adrian M. Di Bisceglie, MD, hepatologist and emeritus professor of internal medicine at Saint Louis University, said the study was “well done,” and called the findings “an interesting little tidbit” that would probably not change his practice as a physician, but could be valuable for designing nutritional interventions.

Saint Louis University
Dr. Adrian M. Di Bisceglie

In an interview, Dr. Di Bisceglie explained that a well-balanced diet with adequate caloric intake can help slow the muscle wasting that occurs with the condition, but creating a tasty menu can be challenging when patients are asked to restrict their sodium intake as a means of reducing fluid retention.

“Salt contributes substantially to the enjoyment of food,” Dr. Di Bisceglie said.

Although the study did not specifically report the salt level in patients’ diets, Dr. Di Bisceglie said the findings highlight the need for low-salt strategies to improve palatability. For example, he suggested increasing umami, or savory flavor, as this can be accomplished without adding a significant amount of salt.

When asked if changes in taste or smell might be used as simple screening tools to detect cognitive impairment in patients with cirrhosis, Dr. Di Bisceglie said that this might be “possible,” but is probably unnecessary.

“There is an easy bedside test that we’ve been using for decades [to predict hepatic encephalopathy], which is reading,” Dr. Di Bisceglie said, noting that patients with cognitive deficits often describe reading paragraphs repeatedly without comprehending what they have read.

The investigators and Dr. Di Bisceglie disclosed no conflicts of interest.

Patients with cirrhosis or renal failure who experience changes in taste and smell may have worse quality-of-life (QOL) and may be more likely to exhibit cognitive impairment than those who do not exhibit these sensory changes, according to investigators.

Clinicians should screen for changes in taste and smell among patients at risk of cognitive changes, and offer nutritional interventions to support body weight and QOL, reported principal investigator Jasmohan S. Bajaj, MD, AGAF, of Virginia Commonwealth University, Richmond, and colleagues.

Dr. Jasmohan S. Bajaj

“Cirrhosis is linked with poor nutrition, which could partly be due to anorexia in hepatic encephalopathy (HE) and coexistent renal failure,” the investigators wrote in their abstract, which Dr. Bajaj presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“We wanted to measure how changes in the brain in cirrhosis affect patients’ abilities to smell and taste, and study how that affects their quality of life,” Dr. Bajaj said in a written comment.

To this end, the investigators conducted an observational study involving 59 participants, among whom 22 were healthy, 21 had cirrhosis, and 16 had renal failure requiring dialysis.

“Prior studies individually have shown changes in taste and smell for these two organ failures,” Dr. Bajaj said. “We studied them together as well and linked these to quality of life and individual cognitive tests.”

Of note, individuals with past or current COVID-19, or with current or recent alcohol or tobacco use, were excluded.

Compared with healthy individuals, participants with cirrhosis or renal failure had significantly worse performance on a taste discrimination test, with perceptions of sweet and sour most affected.

Cognitive measurement with Psychometric Hepatic Encephalopathy Score (PHES) and Stroop tests showed that scores were worse for patients with disease than those without. Taste discrimination significantly correlated with both cognitive test scores, regardless of HE or dialysis, whereas smell only correlated with the Stroop test.

Multivariable analysis revealed that better PHES scores and smell discrimination were linked with better taste discrimination. Similarly, better PHES scores and taste discrimination contributed to better smell discrimination. Eating impairment was associated with worse Stroop scores and worse olfactory-related QOL, suggesting that sensory changes, cognitive changes, and eating behaviors were all correlated.

“Health care providers ought to be alert to changes in patients’ eating habits, diet and weight as their liver and kidney disease worsen and as their brain function changes,” Dr. Bajaj said. “Nutritionists and others may be able to assist patients with a healthy diet and suggest ways to improve patients’ reports of their quality of life. Taste and smell are just a few aspects of the complicated assessment of health-related quality of life, brain dysfunction, and nutritional compromise in cirrhosis. We need to be mindful to not just focus on these aspects but to individualize care.”

Adrian M. Di Bisceglie, MD, hepatologist and emeritus professor of internal medicine at Saint Louis University, said the study was “well done,” and called the findings “an interesting little tidbit” that would probably not change his practice as a physician, but could be valuable for designing nutritional interventions.

Saint Louis University
Dr. Adrian M. Di Bisceglie

In an interview, Dr. Di Bisceglie explained that a well-balanced diet with adequate caloric intake can help slow the muscle wasting that occurs with the condition, but creating a tasty menu can be challenging when patients are asked to restrict their sodium intake as a means of reducing fluid retention.

“Salt contributes substantially to the enjoyment of food,” Dr. Di Bisceglie said.

Although the study did not specifically report the salt level in patients’ diets, Dr. Di Bisceglie said the findings highlight the need for low-salt strategies to improve palatability. For example, he suggested increasing umami, or savory flavor, as this can be accomplished without adding a significant amount of salt.

When asked if changes in taste or smell might be used as simple screening tools to detect cognitive impairment in patients with cirrhosis, Dr. Di Bisceglie said that this might be “possible,” but is probably unnecessary.

“There is an easy bedside test that we’ve been using for decades [to predict hepatic encephalopathy], which is reading,” Dr. Di Bisceglie said, noting that patients with cognitive deficits often describe reading paragraphs repeatedly without comprehending what they have read.

The investigators and Dr. Di Bisceglie disclosed no conflicts of interest.

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Is fructose all to blame for obesity?

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Caroline Apovian, MD

recent article hypothesized that fructose causes more metabolic disease than does sucrose when overfed in the human diet. Fructose intake as high-fructose corn syrup (HFCS) has risen since its use in soft drinks in the United States and parallels the increase in the prevalence of obesity.

The newest hypothesis regarding fructose invokes a genetic survival of the fittest rationale for how fructose-enhanced fat deposition exacerbates the increased caloric consumption from the Western diet to promote metabolic disease especially in our adolescent and young adult population. This theory suggests that fructose consumption causes low adenosine triphosphate, which stimulates energy intake causing an imbalance of energy regulation.

Ongoing interest in the association between the increased use of HFCS and the prevalence of obesity in the United States continues. The use of HFCS in sugary sweetened beverages (SSBs) has reduced the cost of these beverages because of technology in preparing HFCS from corn and the substitution of the cheaper HFCS for sugar in SSBs. Although SSBs haven’t been proven to cause obesity, there has been an increase in the risk for type 2 diabetes, cardiovascular disease (CVD), nonalcoholic fatty liver disease (NAFLD), and even cancer. Research in HFCS, weight gain, and metabolic disease continues despite little definitive evidence of causation.

The relationship between SSBs consumption and obesity has been attributed to the increase in overall total caloric intake of the diet. These liquid calories do not suppress the intake of other foods to equalize the total amount of calories ingested. This knowledge has been gleaned from work performed by R. Mattes and B. Rolls in the 1990s through the early 2000s.

This research and the current work on HFCS and metabolic disease is important because there are adolescents and young adults in the United States and globally that ingest a large amount of SSBs and therefore are at risk for metabolic disease, type 2 diabetes, NAFLD, and CVD at an early age.

The concern over fructose stems from the association between the advent of increasing HFCS in SSBs and the increase in prevalence of obesity occurring at similar time periods in the United States, around 1970-1980.

Researchers noted the association and began to focus on potential reasons to pinpoint HFCS or fructose itself so we have a mechanism of action specific to fructose. Therefore, the public could be warned about the risk of drinking SSBs due to the HFCS and fructose ingested and the possibility of metabolic disease. Perhaps, there is a method to remove harmful HFCS from the food supply much like what has happened with industrially produced trans fatty acids. In 2018, the World Health Organization called for a total ban on trans fats due to causation of 500 million early deaths per year globally.

Similar to the process of making HFCS, most trans fats are formed through an industrial process that alters vegetable oil and creates a shelf stable inexpensive partially hydrogenated oil. Trans fats have been shown to increase low-density lipoprotein (LDL) cholesterol and decrease high-density lipoprotein (HDL) increasing the risk for myocardial infarction and stroke.

 

 



What was the pivotal moment for the ban on trans fats? It was tough convincing the scientific community and certainly the industry that trans fats were especially harmful. This is because of the dogma that margarine and Crisco oils were somehow better for you than were lard and butter. The evidence kept coming in from epidemiological studies showing that people who ate more trans fats had increased levels of LDL and decreased levels of HDL, and the dogma that saturated fat was the villain in heart disease was reinforced. Maybe that pivotal moment was when a researcher with experience testing trans fat deposition in cadavers and pigs sued the US Food and Drug Administration (FDA) for not acting on cumulative evidence sooner.

Do we have this kind of evidence to make a claim for the FDA to ban HFCS? What we have is the time course of HFCS entry into the food supply which occurred in 1970. This coincided with the growing prevalence of obesity between 1960 and 2000.

The excess energy in SSBs can provide a hedonic stimulus that overcomes the natural energy balance regulatory mechanism because SSBs excess energy comes in liquid form and may bypass the satiety signal in the hypothalamus.

We still have to prove this.

Blaming fructose in HFCS as the sole cause for the increase obesity will be much tougher than blaming trans fats for an increase in LDL cholesterol and a decrease in HDL cholesterol.

The prevalence of obesity has increased worldwide, even in countries where SSBs do not contain HFCS.

Still, the proof that HFCS can override the satiety pathway and cause excess calorie intake is intriguing and may have teeth if we can pinpoint the increase in prevalence of obesity in children and adolescents on increased ingestion of HFCS in SSBs. There is no reason nutritionally to add sugar or HFCS to liquids. Plus, if HFCS has a metabolic disadvantage then all the more reason to ban it. Then, it becomes like trans fats: a toxin in the food supply.


Dr. Apovian is a Faculty Member, Department of Medicine; Co-Director, Center for Weight Management and Wellness, Section of Endocrinology, Diabetes, and Hypertension, Brigham and Womens Hospital, Harvard Medical School, Boston, Massachusetts. She has disclosed financial relationships with Altimmune, Inc; Cowen and Company, LLC; Currax Pharmaceuticals, LLC; EPG Communication Holdings, Ltd; Gelesis, Srl; L-Nutra, Inc; NeuroBo Pharmaceuticals; and Novo Nordisk, Inc. She has received research grants from the National Institutes of Health; Patient-Centered Outcomes Research Institute; GI Dynamics, Inc.

A version of this article appeared on Medscape.com.

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Caroline Apovian, MD
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Caroline Apovian, MD

recent article hypothesized that fructose causes more metabolic disease than does sucrose when overfed in the human diet. Fructose intake as high-fructose corn syrup (HFCS) has risen since its use in soft drinks in the United States and parallels the increase in the prevalence of obesity.

The newest hypothesis regarding fructose invokes a genetic survival of the fittest rationale for how fructose-enhanced fat deposition exacerbates the increased caloric consumption from the Western diet to promote metabolic disease especially in our adolescent and young adult population. This theory suggests that fructose consumption causes low adenosine triphosphate, which stimulates energy intake causing an imbalance of energy regulation.

Ongoing interest in the association between the increased use of HFCS and the prevalence of obesity in the United States continues. The use of HFCS in sugary sweetened beverages (SSBs) has reduced the cost of these beverages because of technology in preparing HFCS from corn and the substitution of the cheaper HFCS for sugar in SSBs. Although SSBs haven’t been proven to cause obesity, there has been an increase in the risk for type 2 diabetes, cardiovascular disease (CVD), nonalcoholic fatty liver disease (NAFLD), and even cancer. Research in HFCS, weight gain, and metabolic disease continues despite little definitive evidence of causation.

The relationship between SSBs consumption and obesity has been attributed to the increase in overall total caloric intake of the diet. These liquid calories do not suppress the intake of other foods to equalize the total amount of calories ingested. This knowledge has been gleaned from work performed by R. Mattes and B. Rolls in the 1990s through the early 2000s.

This research and the current work on HFCS and metabolic disease is important because there are adolescents and young adults in the United States and globally that ingest a large amount of SSBs and therefore are at risk for metabolic disease, type 2 diabetes, NAFLD, and CVD at an early age.

The concern over fructose stems from the association between the advent of increasing HFCS in SSBs and the increase in prevalence of obesity occurring at similar time periods in the United States, around 1970-1980.

Researchers noted the association and began to focus on potential reasons to pinpoint HFCS or fructose itself so we have a mechanism of action specific to fructose. Therefore, the public could be warned about the risk of drinking SSBs due to the HFCS and fructose ingested and the possibility of metabolic disease. Perhaps, there is a method to remove harmful HFCS from the food supply much like what has happened with industrially produced trans fatty acids. In 2018, the World Health Organization called for a total ban on trans fats due to causation of 500 million early deaths per year globally.

Similar to the process of making HFCS, most trans fats are formed through an industrial process that alters vegetable oil and creates a shelf stable inexpensive partially hydrogenated oil. Trans fats have been shown to increase low-density lipoprotein (LDL) cholesterol and decrease high-density lipoprotein (HDL) increasing the risk for myocardial infarction and stroke.

 

 



What was the pivotal moment for the ban on trans fats? It was tough convincing the scientific community and certainly the industry that trans fats were especially harmful. This is because of the dogma that margarine and Crisco oils were somehow better for you than were lard and butter. The evidence kept coming in from epidemiological studies showing that people who ate more trans fats had increased levels of LDL and decreased levels of HDL, and the dogma that saturated fat was the villain in heart disease was reinforced. Maybe that pivotal moment was when a researcher with experience testing trans fat deposition in cadavers and pigs sued the US Food and Drug Administration (FDA) for not acting on cumulative evidence sooner.

Do we have this kind of evidence to make a claim for the FDA to ban HFCS? What we have is the time course of HFCS entry into the food supply which occurred in 1970. This coincided with the growing prevalence of obesity between 1960 and 2000.

The excess energy in SSBs can provide a hedonic stimulus that overcomes the natural energy balance regulatory mechanism because SSBs excess energy comes in liquid form and may bypass the satiety signal in the hypothalamus.

We still have to prove this.

Blaming fructose in HFCS as the sole cause for the increase obesity will be much tougher than blaming trans fats for an increase in LDL cholesterol and a decrease in HDL cholesterol.

The prevalence of obesity has increased worldwide, even in countries where SSBs do not contain HFCS.

Still, the proof that HFCS can override the satiety pathway and cause excess calorie intake is intriguing and may have teeth if we can pinpoint the increase in prevalence of obesity in children and adolescents on increased ingestion of HFCS in SSBs. There is no reason nutritionally to add sugar or HFCS to liquids. Plus, if HFCS has a metabolic disadvantage then all the more reason to ban it. Then, it becomes like trans fats: a toxin in the food supply.


Dr. Apovian is a Faculty Member, Department of Medicine; Co-Director, Center for Weight Management and Wellness, Section of Endocrinology, Diabetes, and Hypertension, Brigham and Womens Hospital, Harvard Medical School, Boston, Massachusetts. She has disclosed financial relationships with Altimmune, Inc; Cowen and Company, LLC; Currax Pharmaceuticals, LLC; EPG Communication Holdings, Ltd; Gelesis, Srl; L-Nutra, Inc; NeuroBo Pharmaceuticals; and Novo Nordisk, Inc. She has received research grants from the National Institutes of Health; Patient-Centered Outcomes Research Institute; GI Dynamics, Inc.

A version of this article appeared on Medscape.com.

recent article hypothesized that fructose causes more metabolic disease than does sucrose when overfed in the human diet. Fructose intake as high-fructose corn syrup (HFCS) has risen since its use in soft drinks in the United States and parallels the increase in the prevalence of obesity.

The newest hypothesis regarding fructose invokes a genetic survival of the fittest rationale for how fructose-enhanced fat deposition exacerbates the increased caloric consumption from the Western diet to promote metabolic disease especially in our adolescent and young adult population. This theory suggests that fructose consumption causes low adenosine triphosphate, which stimulates energy intake causing an imbalance of energy regulation.

Ongoing interest in the association between the increased use of HFCS and the prevalence of obesity in the United States continues. The use of HFCS in sugary sweetened beverages (SSBs) has reduced the cost of these beverages because of technology in preparing HFCS from corn and the substitution of the cheaper HFCS for sugar in SSBs. Although SSBs haven’t been proven to cause obesity, there has been an increase in the risk for type 2 diabetes, cardiovascular disease (CVD), nonalcoholic fatty liver disease (NAFLD), and even cancer. Research in HFCS, weight gain, and metabolic disease continues despite little definitive evidence of causation.

The relationship between SSBs consumption and obesity has been attributed to the increase in overall total caloric intake of the diet. These liquid calories do not suppress the intake of other foods to equalize the total amount of calories ingested. This knowledge has been gleaned from work performed by R. Mattes and B. Rolls in the 1990s through the early 2000s.

This research and the current work on HFCS and metabolic disease is important because there are adolescents and young adults in the United States and globally that ingest a large amount of SSBs and therefore are at risk for metabolic disease, type 2 diabetes, NAFLD, and CVD at an early age.

The concern over fructose stems from the association between the advent of increasing HFCS in SSBs and the increase in prevalence of obesity occurring at similar time periods in the United States, around 1970-1980.

Researchers noted the association and began to focus on potential reasons to pinpoint HFCS or fructose itself so we have a mechanism of action specific to fructose. Therefore, the public could be warned about the risk of drinking SSBs due to the HFCS and fructose ingested and the possibility of metabolic disease. Perhaps, there is a method to remove harmful HFCS from the food supply much like what has happened with industrially produced trans fatty acids. In 2018, the World Health Organization called for a total ban on trans fats due to causation of 500 million early deaths per year globally.

Similar to the process of making HFCS, most trans fats are formed through an industrial process that alters vegetable oil and creates a shelf stable inexpensive partially hydrogenated oil. Trans fats have been shown to increase low-density lipoprotein (LDL) cholesterol and decrease high-density lipoprotein (HDL) increasing the risk for myocardial infarction and stroke.

 

 



What was the pivotal moment for the ban on trans fats? It was tough convincing the scientific community and certainly the industry that trans fats were especially harmful. This is because of the dogma that margarine and Crisco oils were somehow better for you than were lard and butter. The evidence kept coming in from epidemiological studies showing that people who ate more trans fats had increased levels of LDL and decreased levels of HDL, and the dogma that saturated fat was the villain in heart disease was reinforced. Maybe that pivotal moment was when a researcher with experience testing trans fat deposition in cadavers and pigs sued the US Food and Drug Administration (FDA) for not acting on cumulative evidence sooner.

Do we have this kind of evidence to make a claim for the FDA to ban HFCS? What we have is the time course of HFCS entry into the food supply which occurred in 1970. This coincided with the growing prevalence of obesity between 1960 and 2000.

The excess energy in SSBs can provide a hedonic stimulus that overcomes the natural energy balance regulatory mechanism because SSBs excess energy comes in liquid form and may bypass the satiety signal in the hypothalamus.

We still have to prove this.

Blaming fructose in HFCS as the sole cause for the increase obesity will be much tougher than blaming trans fats for an increase in LDL cholesterol and a decrease in HDL cholesterol.

The prevalence of obesity has increased worldwide, even in countries where SSBs do not contain HFCS.

Still, the proof that HFCS can override the satiety pathway and cause excess calorie intake is intriguing and may have teeth if we can pinpoint the increase in prevalence of obesity in children and adolescents on increased ingestion of HFCS in SSBs. There is no reason nutritionally to add sugar or HFCS to liquids. Plus, if HFCS has a metabolic disadvantage then all the more reason to ban it. Then, it becomes like trans fats: a toxin in the food supply.


Dr. Apovian is a Faculty Member, Department of Medicine; Co-Director, Center for Weight Management and Wellness, Section of Endocrinology, Diabetes, and Hypertension, Brigham and Womens Hospital, Harvard Medical School, Boston, Massachusetts. She has disclosed financial relationships with Altimmune, Inc; Cowen and Company, LLC; Currax Pharmaceuticals, LLC; EPG Communication Holdings, Ltd; Gelesis, Srl; L-Nutra, Inc; NeuroBo Pharmaceuticals; and Novo Nordisk, Inc. She has received research grants from the National Institutes of Health; Patient-Centered Outcomes Research Institute; GI Dynamics, Inc.

A version of this article appeared on Medscape.com.

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COVID livers are safe for transplant

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Transplanting livers from deceased donors who tested positive for SARS-CoV-2 is safe and has no significant impact on short-term outcomes of allografts or recipients, based on a national study with the longest follow-up to date.

Using livers from deceased patients with COVID-19 could be an opportunity expand organ availability, reported principal investigator Nadim Mahmud, MD, of the University of Pennsylvania, Philadelphia, and colleagues.

Findings were presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“During the COVID-19 pandemic, a few centers trialed transplanting solid organs from COVID-19 positive donors with promising initial results,” presenting author Roy X. Wang, MD, of the University of Pennsylvania, said in a written comment. “However, these were smaller experiences with short follow-up that were not exclusively focused on liver transplantation. We wanted to explore the safety of liver transplantation from COVID-19 positive donors using a large national dataset with the longest follow up time to date.”

The dataset included 13,096 COVID-negative donors and 299 COVID-positive donors who died between July 2020 and July 2022, with cases and controls matched via propensity scoring. COVID-positive donors were significantly more likely to be younger and have died of brain death. Beyond this difference in age, no significant demographic differences were detected.

After 1 year of follow-up, no statistically significant differences in patient survival (subhazard ratio, 1.11; log-rank P = .70) or allograft survival (hazard ratio, 1.44; log-rank P = .14) were detected when comparing livers transplanted from positive versus negative donors.

“Our findings support and expand upon the results from earlier studies,” Dr. Wang concluded. “Liver transplant from COVID-19-positive donors has acceptable short-term outcomes and may represent an opportunity to expand organ access.”

Still, more work is needed to assess other clinical metrics and long-term outcomes, he added.

“While we were able to show similar patient and graft survival post-transplant between COVID-19-positive and negative donors, rates of other complications were not investigated such as episodes of rejection, liver injury, and hospitalizations,” Dr. Wang said. “Due to data limitations, we are only able to report on outcomes up to 1 year post transplant. Additional investigation will be needed to continue monitoring future outcomes and identifying any differences between recipients of COVID-19-positive and negative donors.”

Timucin Taner, MD, PhD, division chair of transplant surgery at Mayo Clinic, Rochester, Minnesota, said the study is important because it reaffirms the majority opinion among transplant physicians: These livers are safe.

In an interview, Dr. Taner suggested that Dr. Wang’s call for longer term data is “mostly science speak,” since 1 year of follow-up should be sufficient to determine liver viability.

Mayo Clinic
Dr. Timucin Taner

“If a liver from a COVID-19 donor behaved well for a year, then chances are it’s not going to behave badly [later on] because of the virus at the time of donation,” Dr. Taner said.

He said the reported trends in usage of COVID-positive livers reflect early hesitancy that waned with rising vaccination rates, and recognition that the virus could not be spread via liver donation.

“To date, the only transmission [of SARS-CoV-2] from a transplant has been from a lung transplant,” Dr. Taner said, “and that was back in the days that we didn’t know about this. Other organs don’t transmit the disease, so they are easily usable.”

These new data should further increase confidence among both health care providers and patients, he added.

“[This study is] reassuring to the patients on the waitlist that these organs are very safe to use,” Dr. Taner said. “We as the transplant society are comfortable using them without any hesitation.”

The investigators and Dr. Taner disclosed no conflicts of interest.

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Transplanting livers from deceased donors who tested positive for SARS-CoV-2 is safe and has no significant impact on short-term outcomes of allografts or recipients, based on a national study with the longest follow-up to date.

Using livers from deceased patients with COVID-19 could be an opportunity expand organ availability, reported principal investigator Nadim Mahmud, MD, of the University of Pennsylvania, Philadelphia, and colleagues.

Findings were presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“During the COVID-19 pandemic, a few centers trialed transplanting solid organs from COVID-19 positive donors with promising initial results,” presenting author Roy X. Wang, MD, of the University of Pennsylvania, said in a written comment. “However, these were smaller experiences with short follow-up that were not exclusively focused on liver transplantation. We wanted to explore the safety of liver transplantation from COVID-19 positive donors using a large national dataset with the longest follow up time to date.”

The dataset included 13,096 COVID-negative donors and 299 COVID-positive donors who died between July 2020 and July 2022, with cases and controls matched via propensity scoring. COVID-positive donors were significantly more likely to be younger and have died of brain death. Beyond this difference in age, no significant demographic differences were detected.

After 1 year of follow-up, no statistically significant differences in patient survival (subhazard ratio, 1.11; log-rank P = .70) or allograft survival (hazard ratio, 1.44; log-rank P = .14) were detected when comparing livers transplanted from positive versus negative donors.

“Our findings support and expand upon the results from earlier studies,” Dr. Wang concluded. “Liver transplant from COVID-19-positive donors has acceptable short-term outcomes and may represent an opportunity to expand organ access.”

Still, more work is needed to assess other clinical metrics and long-term outcomes, he added.

“While we were able to show similar patient and graft survival post-transplant between COVID-19-positive and negative donors, rates of other complications were not investigated such as episodes of rejection, liver injury, and hospitalizations,” Dr. Wang said. “Due to data limitations, we are only able to report on outcomes up to 1 year post transplant. Additional investigation will be needed to continue monitoring future outcomes and identifying any differences between recipients of COVID-19-positive and negative donors.”

Timucin Taner, MD, PhD, division chair of transplant surgery at Mayo Clinic, Rochester, Minnesota, said the study is important because it reaffirms the majority opinion among transplant physicians: These livers are safe.

In an interview, Dr. Taner suggested that Dr. Wang’s call for longer term data is “mostly science speak,” since 1 year of follow-up should be sufficient to determine liver viability.

Mayo Clinic
Dr. Timucin Taner

“If a liver from a COVID-19 donor behaved well for a year, then chances are it’s not going to behave badly [later on] because of the virus at the time of donation,” Dr. Taner said.

He said the reported trends in usage of COVID-positive livers reflect early hesitancy that waned with rising vaccination rates, and recognition that the virus could not be spread via liver donation.

“To date, the only transmission [of SARS-CoV-2] from a transplant has been from a lung transplant,” Dr. Taner said, “and that was back in the days that we didn’t know about this. Other organs don’t transmit the disease, so they are easily usable.”

These new data should further increase confidence among both health care providers and patients, he added.

“[This study is] reassuring to the patients on the waitlist that these organs are very safe to use,” Dr. Taner said. “We as the transplant society are comfortable using them without any hesitation.”

The investigators and Dr. Taner disclosed no conflicts of interest.

Transplanting livers from deceased donors who tested positive for SARS-CoV-2 is safe and has no significant impact on short-term outcomes of allografts or recipients, based on a national study with the longest follow-up to date.

Using livers from deceased patients with COVID-19 could be an opportunity expand organ availability, reported principal investigator Nadim Mahmud, MD, of the University of Pennsylvania, Philadelphia, and colleagues.

Findings were presented in November at the annual meeting of the American Association for the Study of Liver Diseases.

“During the COVID-19 pandemic, a few centers trialed transplanting solid organs from COVID-19 positive donors with promising initial results,” presenting author Roy X. Wang, MD, of the University of Pennsylvania, said in a written comment. “However, these were smaller experiences with short follow-up that were not exclusively focused on liver transplantation. We wanted to explore the safety of liver transplantation from COVID-19 positive donors using a large national dataset with the longest follow up time to date.”

The dataset included 13,096 COVID-negative donors and 299 COVID-positive donors who died between July 2020 and July 2022, with cases and controls matched via propensity scoring. COVID-positive donors were significantly more likely to be younger and have died of brain death. Beyond this difference in age, no significant demographic differences were detected.

After 1 year of follow-up, no statistically significant differences in patient survival (subhazard ratio, 1.11; log-rank P = .70) or allograft survival (hazard ratio, 1.44; log-rank P = .14) were detected when comparing livers transplanted from positive versus negative donors.

“Our findings support and expand upon the results from earlier studies,” Dr. Wang concluded. “Liver transplant from COVID-19-positive donors has acceptable short-term outcomes and may represent an opportunity to expand organ access.”

Still, more work is needed to assess other clinical metrics and long-term outcomes, he added.

“While we were able to show similar patient and graft survival post-transplant between COVID-19-positive and negative donors, rates of other complications were not investigated such as episodes of rejection, liver injury, and hospitalizations,” Dr. Wang said. “Due to data limitations, we are only able to report on outcomes up to 1 year post transplant. Additional investigation will be needed to continue monitoring future outcomes and identifying any differences between recipients of COVID-19-positive and negative donors.”

Timucin Taner, MD, PhD, division chair of transplant surgery at Mayo Clinic, Rochester, Minnesota, said the study is important because it reaffirms the majority opinion among transplant physicians: These livers are safe.

In an interview, Dr. Taner suggested that Dr. Wang’s call for longer term data is “mostly science speak,” since 1 year of follow-up should be sufficient to determine liver viability.

Mayo Clinic
Dr. Timucin Taner

“If a liver from a COVID-19 donor behaved well for a year, then chances are it’s not going to behave badly [later on] because of the virus at the time of donation,” Dr. Taner said.

He said the reported trends in usage of COVID-positive livers reflect early hesitancy that waned with rising vaccination rates, and recognition that the virus could not be spread via liver donation.

“To date, the only transmission [of SARS-CoV-2] from a transplant has been from a lung transplant,” Dr. Taner said, “and that was back in the days that we didn’t know about this. Other organs don’t transmit the disease, so they are easily usable.”

These new data should further increase confidence among both health care providers and patients, he added.

“[This study is] reassuring to the patients on the waitlist that these organs are very safe to use,” Dr. Taner said. “We as the transplant society are comfortable using them without any hesitation.”

The investigators and Dr. Taner disclosed no conflicts of interest.

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More than one-third of adults in the US could have NAFLD by 2050

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More than one out of three adults in the United States could have nonalcoholic fatty liver disease (NAFLD) by 2050, substantially increasing the national clinical burden, according to investigators.

These findings suggest that health care systems should prepare for “large increases” in cases of hepatocellular carcinoma (HCC) and need for liver transplants, reported lead author Phuc Le, PhD, MPH, of the Cleveland Clinic, and colleagues.

Cleveland Clinic
Dr. Phuc Le

“Following the alarming rise in prevalence of obesity and diabetes, NAFLD is projected to become the leading indication for liver transplant in the United States in the next decade,” Dr. Le and colleagues wrote in their abstract for the annual meeting of the American Association for the Study of Liver Diseases. “A better understanding of the clinical burden associated with NAFLD will enable health systems to prepare to meet this imminent demand from patients.”

To this end, Dr. Le and colleagues developed an agent-based state transition model to predict future prevalence of NAFLD and associated outcomes.

In the first part of the model, the investigators simulated population growth in the United States using Census Bureau data, including new births and immigration, from the year 2000 onward. The second part of the model simulated natural progression of NAFLD in adults via 14 associated conditions and events, including steatosis, nonalcoholic steatohepatitis (NASH), HCC, liver transplants, liver-related mortality, and others.

By first comparing simulated findings with actual findings between 2000 and 2018, the investigators confirmed that their model could reliably predict the intended epidemiological parameters.

Next, they turned their model toward the future.

It predicted that the prevalence of NAFLD among US adults will rise from 27.8% in 2020 to 34.3% in 2050. Over the same timeframe, prevalence of NASH is predicted to increase from 20.0% to 21.8%, proportion of NAFLD cases developing cirrhosis is expected to increase from 1.9% to 3.1%, and liver-related mortality is estimated to rise from 0.4% to 1% of all deaths.

The model also predicted that the burden of HCC will increase from 10,400 to 19,300 new cases per year, while liver transplant burden will more than double, from 1,700 to 4,200 transplants per year.

“Our model forecasts substantial clinical burden of NAFLD over the next three decades,” Dr. Le said in a virtual press conference. “And in the absence of effective treatments, health systems should plan for large increases in the number of liver cancer cases and the need for liver transplant.”

During the press conference, Norah Terrault, MD, president of the AASLD from the University of Southern California, Los Angeles, noted that all of the reported outcomes, including increasing rates of liver cancer, cirrhosis, and transplants are “potentially preventable.”

Keck School of Medicine
Dr. Norah Terrault

Dr. Terrault went on to suggest ways of combating this increasing burden of NAFLD, which she referred to as metabolic dysfunction–associated steatotic liver disease (MASLD), the name now recommended by the AASLD.

“There’s no way we’re going to be able to transplant our way out of this,” Dr. Terrault said. “We need to be bringing greater awareness both to patients, as well as to providers about how we seek out the diagnosis. And we need to bring greater awareness to the population around the things that contribute to MASLD.”

Rates of obesity and diabetes continue to rise, Dr. Terrault said, explaining why MASLD is more common than ever. To counteract these trends, she called for greater awareness of driving factors, such as dietary choices and sedentary lifestyle.

“These are all really important messages that we want to get out to the population, and are really the cornerstones for how we approach the management of patients who have MASLD,” Dr. Terrault said.

In discussion with Dr. Terrault, Dr. Le agreed that increased education may help stem the rising tide of disease, while treatment advances could also increase the odds of a brighter future.

“If we improve our management of NAFLD, or NAFLD-related comorbidities, and if we can develop an effective treatment for NAFLD, then obviously the future would not be so dark,” Dr. Le said, noting promising phase 3 data that would be presented at the meeting. “We are hopeful that the future of disease burden will not be as bad as our model predicts.”

The study was funded by the Agency for Healthcare Research and Quality. The investigators disclosed no conflicts of interest.

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More than one out of three adults in the United States could have nonalcoholic fatty liver disease (NAFLD) by 2050, substantially increasing the national clinical burden, according to investigators.

These findings suggest that health care systems should prepare for “large increases” in cases of hepatocellular carcinoma (HCC) and need for liver transplants, reported lead author Phuc Le, PhD, MPH, of the Cleveland Clinic, and colleagues.

Cleveland Clinic
Dr. Phuc Le

“Following the alarming rise in prevalence of obesity and diabetes, NAFLD is projected to become the leading indication for liver transplant in the United States in the next decade,” Dr. Le and colleagues wrote in their abstract for the annual meeting of the American Association for the Study of Liver Diseases. “A better understanding of the clinical burden associated with NAFLD will enable health systems to prepare to meet this imminent demand from patients.”

To this end, Dr. Le and colleagues developed an agent-based state transition model to predict future prevalence of NAFLD and associated outcomes.

In the first part of the model, the investigators simulated population growth in the United States using Census Bureau data, including new births and immigration, from the year 2000 onward. The second part of the model simulated natural progression of NAFLD in adults via 14 associated conditions and events, including steatosis, nonalcoholic steatohepatitis (NASH), HCC, liver transplants, liver-related mortality, and others.

By first comparing simulated findings with actual findings between 2000 and 2018, the investigators confirmed that their model could reliably predict the intended epidemiological parameters.

Next, they turned their model toward the future.

It predicted that the prevalence of NAFLD among US adults will rise from 27.8% in 2020 to 34.3% in 2050. Over the same timeframe, prevalence of NASH is predicted to increase from 20.0% to 21.8%, proportion of NAFLD cases developing cirrhosis is expected to increase from 1.9% to 3.1%, and liver-related mortality is estimated to rise from 0.4% to 1% of all deaths.

The model also predicted that the burden of HCC will increase from 10,400 to 19,300 new cases per year, while liver transplant burden will more than double, from 1,700 to 4,200 transplants per year.

“Our model forecasts substantial clinical burden of NAFLD over the next three decades,” Dr. Le said in a virtual press conference. “And in the absence of effective treatments, health systems should plan for large increases in the number of liver cancer cases and the need for liver transplant.”

During the press conference, Norah Terrault, MD, president of the AASLD from the University of Southern California, Los Angeles, noted that all of the reported outcomes, including increasing rates of liver cancer, cirrhosis, and transplants are “potentially preventable.”

Keck School of Medicine
Dr. Norah Terrault

Dr. Terrault went on to suggest ways of combating this increasing burden of NAFLD, which she referred to as metabolic dysfunction–associated steatotic liver disease (MASLD), the name now recommended by the AASLD.

“There’s no way we’re going to be able to transplant our way out of this,” Dr. Terrault said. “We need to be bringing greater awareness both to patients, as well as to providers about how we seek out the diagnosis. And we need to bring greater awareness to the population around the things that contribute to MASLD.”

Rates of obesity and diabetes continue to rise, Dr. Terrault said, explaining why MASLD is more common than ever. To counteract these trends, she called for greater awareness of driving factors, such as dietary choices and sedentary lifestyle.

“These are all really important messages that we want to get out to the population, and are really the cornerstones for how we approach the management of patients who have MASLD,” Dr. Terrault said.

In discussion with Dr. Terrault, Dr. Le agreed that increased education may help stem the rising tide of disease, while treatment advances could also increase the odds of a brighter future.

“If we improve our management of NAFLD, or NAFLD-related comorbidities, and if we can develop an effective treatment for NAFLD, then obviously the future would not be so dark,” Dr. Le said, noting promising phase 3 data that would be presented at the meeting. “We are hopeful that the future of disease burden will not be as bad as our model predicts.”

The study was funded by the Agency for Healthcare Research and Quality. The investigators disclosed no conflicts of interest.

More than one out of three adults in the United States could have nonalcoholic fatty liver disease (NAFLD) by 2050, substantially increasing the national clinical burden, according to investigators.

These findings suggest that health care systems should prepare for “large increases” in cases of hepatocellular carcinoma (HCC) and need for liver transplants, reported lead author Phuc Le, PhD, MPH, of the Cleveland Clinic, and colleagues.

Cleveland Clinic
Dr. Phuc Le

“Following the alarming rise in prevalence of obesity and diabetes, NAFLD is projected to become the leading indication for liver transplant in the United States in the next decade,” Dr. Le and colleagues wrote in their abstract for the annual meeting of the American Association for the Study of Liver Diseases. “A better understanding of the clinical burden associated with NAFLD will enable health systems to prepare to meet this imminent demand from patients.”

To this end, Dr. Le and colleagues developed an agent-based state transition model to predict future prevalence of NAFLD and associated outcomes.

In the first part of the model, the investigators simulated population growth in the United States using Census Bureau data, including new births and immigration, from the year 2000 onward. The second part of the model simulated natural progression of NAFLD in adults via 14 associated conditions and events, including steatosis, nonalcoholic steatohepatitis (NASH), HCC, liver transplants, liver-related mortality, and others.

By first comparing simulated findings with actual findings between 2000 and 2018, the investigators confirmed that their model could reliably predict the intended epidemiological parameters.

Next, they turned their model toward the future.

It predicted that the prevalence of NAFLD among US adults will rise from 27.8% in 2020 to 34.3% in 2050. Over the same timeframe, prevalence of NASH is predicted to increase from 20.0% to 21.8%, proportion of NAFLD cases developing cirrhosis is expected to increase from 1.9% to 3.1%, and liver-related mortality is estimated to rise from 0.4% to 1% of all deaths.

The model also predicted that the burden of HCC will increase from 10,400 to 19,300 new cases per year, while liver transplant burden will more than double, from 1,700 to 4,200 transplants per year.

“Our model forecasts substantial clinical burden of NAFLD over the next three decades,” Dr. Le said in a virtual press conference. “And in the absence of effective treatments, health systems should plan for large increases in the number of liver cancer cases and the need for liver transplant.”

During the press conference, Norah Terrault, MD, president of the AASLD from the University of Southern California, Los Angeles, noted that all of the reported outcomes, including increasing rates of liver cancer, cirrhosis, and transplants are “potentially preventable.”

Keck School of Medicine
Dr. Norah Terrault

Dr. Terrault went on to suggest ways of combating this increasing burden of NAFLD, which she referred to as metabolic dysfunction–associated steatotic liver disease (MASLD), the name now recommended by the AASLD.

“There’s no way we’re going to be able to transplant our way out of this,” Dr. Terrault said. “We need to be bringing greater awareness both to patients, as well as to providers about how we seek out the diagnosis. And we need to bring greater awareness to the population around the things that contribute to MASLD.”

Rates of obesity and diabetes continue to rise, Dr. Terrault said, explaining why MASLD is more common than ever. To counteract these trends, she called for greater awareness of driving factors, such as dietary choices and sedentary lifestyle.

“These are all really important messages that we want to get out to the population, and are really the cornerstones for how we approach the management of patients who have MASLD,” Dr. Terrault said.

In discussion with Dr. Terrault, Dr. Le agreed that increased education may help stem the rising tide of disease, while treatment advances could also increase the odds of a brighter future.

“If we improve our management of NAFLD, or NAFLD-related comorbidities, and if we can develop an effective treatment for NAFLD, then obviously the future would not be so dark,” Dr. Le said, noting promising phase 3 data that would be presented at the meeting. “We are hopeful that the future of disease burden will not be as bad as our model predicts.”

The study was funded by the Agency for Healthcare Research and Quality. The investigators disclosed no conflicts of interest.

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