Infectious Diseases

Infants born to women infected with the hepatitis C virus (HCV) faced twice the risk of stays in the neonatal ICU (NICU) and 2.7 times the risk of low birth weight, a new analysis finds, even when researchers adjusted their data to control for injectable drug use and maternal medical comorbidity.

Clinicians should be “aware that the infants of pregnant people with HCV may have a high rate of need for higher-level pediatric care,” said Brenna L. Hughes, MD, MSc, chief of maternal fetal medicine at Duke University Medical Center, Durham, N.C. She spoke in an interview about the findings, which were presented at the meeting sponsored by the Society for Maternal-Fetal Medicine.

As Dr. Hughes noted, “HCV remains a serious problem in pregnancy because it often goes undiagnosed and/or untreated prior to pregnancy. It can be passed to infants, and this can cause significant health-related outcomes for children as they age.”

For the multicenter U.S. study, researchers identified 249 pregnant mothers with HCV from a 2012-2018 cohort and matched them by gestational age to controls (n = 486). The average age was 28; 71.1% of the cases were non-Hispanic White versus 41.6% of the controls; 8.4% of cases were non-Hispanic Black versus 32.1% of controls (P < .001 for race/ethnicity analysis); and 73% of cases were smokers versus 18% of controls (P < .001). More than 19% of cases reported injectable drug use during pregnancy versus 0.2% of controls (P < .001).

The researchers adjusted their findings for maternal age, body mass index, injectable drug use, and maternal comorbidity.

An earlier analysis of the study data found that 6% of pregnant women with HCV passed it on to their infants, especially those with high levels of virus in their systems. For the new study, researchers focused on various outcomes to test the assumption that “adverse pregnancy outcomes associated with HCV are related to prematurity or to ongoing use of injection drugs,” Dr. Hughes said.

There was no increase in rates of preterm birth or adverse maternal outcomes in the HCV cases. However, infants born to women with HCV were more likely than the controls to require a stay in the NICU (45% vs. 19%; adjusted relative risk, 1.99; 95% confidence interval, 1.54-2.58). They were also more likely to have lower birth weights (small for gestational age < 5th percentile) (10.6% vs. 3.1%; ARR, 2.72; 95% CI, 1.38-5.34).

No difference in outcomes was seen when HCV cases with viremia (33%) were excluded.

“The most surprising finding was that the need for higher-level pediatric care was so high even though there wasn’t an increased risk of prematurity,” Dr. Hughes said.

She added it’s not clear why NICU stays and low birth weights were more common in infants of women with HCV. “It is possible that the higher risk of need for higher-level pediatric care was related to a need for observation or treatment due to use of opioid replacement therapies with opioid agonists.” As for lower birth weight, “there may be other unmeasured risk factors.”

Tatyana Kushner, MD, MSCE, of the division of liver diseases at Icahn School of Medicine at Mount Sinai, New York, said in an interview that the study adds to limited data about HCV in pregnancy. “These findings have been demonstrated in prior studies, and it would be important to tease apart whether [low birth weight] is related to the virus itself or more related to other confounding associated factors such as maternal substance use as well as other associated social determinants of health among women with HCV.”

As for the study’s message, Dr. Kushner said it makes it clear that “hepatitis C adversely impacts outcomes of pregnancy and it is important to identify women of childbearing age for treatment early, ideally prior to pregnancy, in order to improve their pregnancy outcomes. In addition, treatment of hepatitis C during pregnancy should be explored further to determine if treatment during pregnancy can improve outcomes.”

At the moment, she said, “there are ongoing studies to delineate the safety and efficacy of hepatitis C treatment during pregnancy. Given that we are screening for hepatitis C during pregnancy, we need clear recommendations on the use of direct-acting antivirals in people who screen positive.”

The study was funded by the National Institute of Child Health and Human Development. The authors have no disclosures. Dr. Kushner disclosed research support (Gilead) and advisory board service (Gilead, AbbVie, Bausch, GlaxoSmithKline, and Eiger).

Infants born to women infected with the hepatitis C virus (HCV) faced twice the risk of stays in the neonatal ICU (NICU) and 2.7 times the risk of low birth weight, a new analysis finds, even when researchers adjusted their data to control for injectable drug use and maternal medical comorbidity.

Clinicians should be “aware that the infants of pregnant people with HCV may have a high rate of need for higher-level pediatric care,” said Brenna L. Hughes, MD, MSc, chief of maternal fetal medicine at Duke University Medical Center, Durham, N.C. She spoke in an interview about the findings, which were presented at the meeting sponsored by the Society for Maternal-Fetal Medicine.

As Dr. Hughes noted, “HCV remains a serious problem in pregnancy because it often goes undiagnosed and/or untreated prior to pregnancy. It can be passed to infants, and this can cause significant health-related outcomes for children as they age.”

For the multicenter U.S. study, researchers identified 249 pregnant mothers with HCV from a 2012-2018 cohort and matched them by gestational age to controls (n = 486). The average age was 28; 71.1% of the cases were non-Hispanic White versus 41.6% of the controls; 8.4% of cases were non-Hispanic Black versus 32.1% of controls (P < .001 for race/ethnicity analysis); and 73% of cases were smokers versus 18% of controls (P < .001). More than 19% of cases reported injectable drug use during pregnancy versus 0.2% of controls (P < .001).

The researchers adjusted their findings for maternal age, body mass index, injectable drug use, and maternal comorbidity.

An earlier analysis of the study data found that 6% of pregnant women with HCV passed it on to their infants, especially those with high levels of virus in their systems. For the new study, researchers focused on various outcomes to test the assumption that “adverse pregnancy outcomes associated with HCV are related to prematurity or to ongoing use of injection drugs,” Dr. Hughes said.

There was no increase in rates of preterm birth or adverse maternal outcomes in the HCV cases. However, infants born to women with HCV were more likely than the controls to require a stay in the NICU (45% vs. 19%; adjusted relative risk, 1.99; 95% confidence interval, 1.54-2.58). They were also more likely to have lower birth weights (small for gestational age < 5th percentile) (10.6% vs. 3.1%; ARR, 2.72; 95% CI, 1.38-5.34).

No difference in outcomes was seen when HCV cases with viremia (33%) were excluded.

“The most surprising finding was that the need for higher-level pediatric care was so high even though there wasn’t an increased risk of prematurity,” Dr. Hughes said.

She added it’s not clear why NICU stays and low birth weights were more common in infants of women with HCV. “It is possible that the higher risk of need for higher-level pediatric care was related to a need for observation or treatment due to use of opioid replacement therapies with opioid agonists.” As for lower birth weight, “there may be other unmeasured risk factors.”

Tatyana Kushner, MD, MSCE, of the division of liver diseases at Icahn School of Medicine at Mount Sinai, New York, said in an interview that the study adds to limited data about HCV in pregnancy. “These findings have been demonstrated in prior studies, and it would be important to tease apart whether [low birth weight] is related to the virus itself or more related to other confounding associated factors such as maternal substance use as well as other associated social determinants of health among women with HCV.”

As for the study’s message, Dr. Kushner said it makes it clear that “hepatitis C adversely impacts outcomes of pregnancy and it is important to identify women of childbearing age for treatment early, ideally prior to pregnancy, in order to improve their pregnancy outcomes. In addition, treatment of hepatitis C during pregnancy should be explored further to determine if treatment during pregnancy can improve outcomes.”

At the moment, she said, “there are ongoing studies to delineate the safety and efficacy of hepatitis C treatment during pregnancy. Given that we are screening for hepatitis C during pregnancy, we need clear recommendations on the use of direct-acting antivirals in people who screen positive.”

The study was funded by the National Institute of Child Health and Human Development. The authors have no disclosures. Dr. Kushner disclosed research support (Gilead) and advisory board service (Gilead, AbbVie, Bausch, GlaxoSmithKline, and Eiger).

Infants born to women infected with the hepatitis C virus (HCV) faced twice the risk of stays in the neonatal ICU (NICU) and 2.7 times the risk of low birth weight, a new analysis finds, even when researchers adjusted their data to control for injectable drug use and maternal medical comorbidity.

Clinicians should be “aware that the infants of pregnant people with HCV may have a high rate of need for higher-level pediatric care,” said Brenna L. Hughes, MD, MSc, chief of maternal fetal medicine at Duke University Medical Center, Durham, N.C. She spoke in an interview about the findings, which were presented at the meeting sponsored by the Society for Maternal-Fetal Medicine.

As Dr. Hughes noted, “HCV remains a serious problem in pregnancy because it often goes undiagnosed and/or untreated prior to pregnancy. It can be passed to infants, and this can cause significant health-related outcomes for children as they age.”

For the multicenter U.S. study, researchers identified 249 pregnant mothers with HCV from a 2012-2018 cohort and matched them by gestational age to controls (n = 486). The average age was 28; 71.1% of the cases were non-Hispanic White versus 41.6% of the controls; 8.4% of cases were non-Hispanic Black versus 32.1% of controls (P < .001 for race/ethnicity analysis); and 73% of cases were smokers versus 18% of controls (P < .001). More than 19% of cases reported injectable drug use during pregnancy versus 0.2% of controls (P < .001).

The researchers adjusted their findings for maternal age, body mass index, injectable drug use, and maternal comorbidity.

An earlier analysis of the study data found that 6% of pregnant women with HCV passed it on to their infants, especially those with high levels of virus in their systems. For the new study, researchers focused on various outcomes to test the assumption that “adverse pregnancy outcomes associated with HCV are related to prematurity or to ongoing use of injection drugs,” Dr. Hughes said.

There was no increase in rates of preterm birth or adverse maternal outcomes in the HCV cases. However, infants born to women with HCV were more likely than the controls to require a stay in the NICU (45% vs. 19%; adjusted relative risk, 1.99; 95% confidence interval, 1.54-2.58). They were also more likely to have lower birth weights (small for gestational age < 5th percentile) (10.6% vs. 3.1%; ARR, 2.72; 95% CI, 1.38-5.34).

No difference in outcomes was seen when HCV cases with viremia (33%) were excluded.

“The most surprising finding was that the need for higher-level pediatric care was so high even though there wasn’t an increased risk of prematurity,” Dr. Hughes said.

She added it’s not clear why NICU stays and low birth weights were more common in infants of women with HCV. “It is possible that the higher risk of need for higher-level pediatric care was related to a need for observation or treatment due to use of opioid replacement therapies with opioid agonists.” As for lower birth weight, “there may be other unmeasured risk factors.”

Tatyana Kushner, MD, MSCE, of the division of liver diseases at Icahn School of Medicine at Mount Sinai, New York, said in an interview that the study adds to limited data about HCV in pregnancy. “These findings have been demonstrated in prior studies, and it would be important to tease apart whether [low birth weight] is related to the virus itself or more related to other confounding associated factors such as maternal substance use as well as other associated social determinants of health among women with HCV.”

As for the study’s message, Dr. Kushner said it makes it clear that “hepatitis C adversely impacts outcomes of pregnancy and it is important to identify women of childbearing age for treatment early, ideally prior to pregnancy, in order to improve their pregnancy outcomes. In addition, treatment of hepatitis C during pregnancy should be explored further to determine if treatment during pregnancy can improve outcomes.”

At the moment, she said, “there are ongoing studies to delineate the safety and efficacy of hepatitis C treatment during pregnancy. Given that we are screening for hepatitis C during pregnancy, we need clear recommendations on the use of direct-acting antivirals in people who screen positive.”

The study was funded by the National Institute of Child Health and Human Development. The authors have no disclosures. Dr. Kushner disclosed research support (Gilead) and advisory board service (Gilead, AbbVie, Bausch, GlaxoSmithKline, and Eiger).

Among pediatric patients with psoriasis who began treatment with ustekinumab, etanercept, or methotrexate, the rate of serious infections at 6 months was low, with an incidence ranging between 14.9 and 25.6 per 1,000 person-years.

Those are key findings from what is believed to be the largest cohort study of its kind to estimate the 6-month rate of infections among children with psoriasis who started treatment with ustekinumab, etanercept, or methotrexate.

“Clinical trials have demonstrated high efficacy of new immunomodulatory agents in treating children with psoriasis,” lead author Maria C. Schneeweiss, MD, of the division of pharmacoepidemiology in the departments of medicine and dermatology at Brigham and Women’s Hospital and Harvard Medical School, Boston, and colleagues wrote in the article, which was published online in JAMA Dermatology. “However, the risk of infections in clinical practice has not been fully characterized by comparing these medications against each other in pairwise comparisons.”

Drawing from two large U.S. insurance claims databases, the researchers identified 2,338 patients aged 17 years and younger who were receiving treatment with a topical medication for psoriasis and started new treatment with ustekinumab, etanercept, or methotrexate. They stratified their analysis by the time before pediatric labeling (2009-2015) and after pediatric approval (2016-2021), and their follow-up of patients started 1 day after initiating treatment and ended at 6 months.

Of the 2,338 patients, 1,368 (58%) were girls. From 2009 through 2021, 379 patients began treatment with ustekinumab, 779 patients began treatment with etanercept, and 1,180 patients began treatment with methotrexate. The propensity score–adjusted incidence rate of serious infection was 18.4 per 1,000 person-years (3 events) for those who used ustekinumab, 25.6 per 1,000 person-years (9 events) for those who used etanercept, and 14.9 per 1,000 person-years (8 events) for those who used methotrexate. The adjusted rate of outpatient infections was 254.9 per 1,000 person-years (39 events) for those who used ustekinumab, 435.7 per 1,000 person-years (139 events) for those who used etanercept, and 433.6 per 1,000 person-years (209 events) for those who used methotrexate. Meanwhile, the adjusted rate ratio of outpatient infections was 0.58 for ustekinumab vs. etanercept, 0.66 for ustekinumab vs. methotrexate, and 0.95 for etanercept vs. methotrexate. The researchers found that ratios were similar during the off-label use era and after pediatric labeling.

Anna L. Grossberg, MD, director of pediatric dermatology at the Johns Hopkins Children’s Center, Baltimore, who was asked to comment on the work, told this news organization that the data on outpatient infections in ustekinumab users “demonstrated that they may have a decreased risk of infection compared to pediatric psoriasis patients treated with methotrexate or the TNF-alpha inhibitor etanercept. This is previously unreported and reflects my personal experience with this medication in my own pediatric psoriasis patients.” She added the study’s overall findings lend further support to the safety of biologic medications and nonbiologic systemic immunomodulatory treatments for management of psoriasis. “This study will help guide pediatric dermatologists in counseling patients and their families about these risks [of infection], and in general providing reassurance that these risks appear to be quite low,” Dr. Grossberg said. “In particular, ustekinumab, a newer biologic medication that was recently FDA-approved for children 6 years and older for pediatric psoriasis, was not associated with higher infection rates than the other agents analyzed in this study, and in fact appears to carry a reduced risk compared to both etanercept and methotrexate.”

She noted certain limitations of the study, including its reliance on insurance claims data, “which can be limiting because information on possible confounding variables may not be known,” she said. “For example, the authors point out that environmental and behavioral risk factors for serious infection could not be evaluated or adjusted for, nor could the severity of the patients’ psoriasis. Additionally, this study only reported on outpatient infections that resulted in an antibiotic or other medications being prescribed and filled. It therefore may have missed children who presented with certain viral infections (examples could include the common cold and uncomplicated ear infections), which often will not require a prescription medication. Furthermore, it would fail to capture those who may have been seen for an infection but failed to fill the intended prescription.”

Dr. Schneeweiss reported receiving grants from AbbVie and UCB to Brigham and Women’s Hospital unrelated to the topic of this study and outside the submitted work. The study was supported by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Dr. Grossberg reported having no financial disclosures.

Among pediatric patients with psoriasis who began treatment with ustekinumab, etanercept, or methotrexate, the rate of serious infections at 6 months was low, with an incidence ranging between 14.9 and 25.6 per 1,000 person-years.

Those are key findings from what is believed to be the largest cohort study of its kind to estimate the 6-month rate of infections among children with psoriasis who started treatment with ustekinumab, etanercept, or methotrexate.

“Clinical trials have demonstrated high efficacy of new immunomodulatory agents in treating children with psoriasis,” lead author Maria C. Schneeweiss, MD, of the division of pharmacoepidemiology in the departments of medicine and dermatology at Brigham and Women’s Hospital and Harvard Medical School, Boston, and colleagues wrote in the article, which was published online in JAMA Dermatology. “However, the risk of infections in clinical practice has not been fully characterized by comparing these medications against each other in pairwise comparisons.”

Drawing from two large U.S. insurance claims databases, the researchers identified 2,338 patients aged 17 years and younger who were receiving treatment with a topical medication for psoriasis and started new treatment with ustekinumab, etanercept, or methotrexate. They stratified their analysis by the time before pediatric labeling (2009-2015) and after pediatric approval (2016-2021), and their follow-up of patients started 1 day after initiating treatment and ended at 6 months.

Of the 2,338 patients, 1,368 (58%) were girls. From 2009 through 2021, 379 patients began treatment with ustekinumab, 779 patients began treatment with etanercept, and 1,180 patients began treatment with methotrexate. The propensity score–adjusted incidence rate of serious infection was 18.4 per 1,000 person-years (3 events) for those who used ustekinumab, 25.6 per 1,000 person-years (9 events) for those who used etanercept, and 14.9 per 1,000 person-years (8 events) for those who used methotrexate. The adjusted rate of outpatient infections was 254.9 per 1,000 person-years (39 events) for those who used ustekinumab, 435.7 per 1,000 person-years (139 events) for those who used etanercept, and 433.6 per 1,000 person-years (209 events) for those who used methotrexate. Meanwhile, the adjusted rate ratio of outpatient infections was 0.58 for ustekinumab vs. etanercept, 0.66 for ustekinumab vs. methotrexate, and 0.95 for etanercept vs. methotrexate. The researchers found that ratios were similar during the off-label use era and after pediatric labeling.

Anna L. Grossberg, MD, director of pediatric dermatology at the Johns Hopkins Children’s Center, Baltimore, who was asked to comment on the work, told this news organization that the data on outpatient infections in ustekinumab users “demonstrated that they may have a decreased risk of infection compared to pediatric psoriasis patients treated with methotrexate or the TNF-alpha inhibitor etanercept. This is previously unreported and reflects my personal experience with this medication in my own pediatric psoriasis patients.” She added the study’s overall findings lend further support to the safety of biologic medications and nonbiologic systemic immunomodulatory treatments for management of psoriasis. “This study will help guide pediatric dermatologists in counseling patients and their families about these risks [of infection], and in general providing reassurance that these risks appear to be quite low,” Dr. Grossberg said. “In particular, ustekinumab, a newer biologic medication that was recently FDA-approved for children 6 years and older for pediatric psoriasis, was not associated with higher infection rates than the other agents analyzed in this study, and in fact appears to carry a reduced risk compared to both etanercept and methotrexate.”

She noted certain limitations of the study, including its reliance on insurance claims data, “which can be limiting because information on possible confounding variables may not be known,” she said. “For example, the authors point out that environmental and behavioral risk factors for serious infection could not be evaluated or adjusted for, nor could the severity of the patients’ psoriasis. Additionally, this study only reported on outpatient infections that resulted in an antibiotic or other medications being prescribed and filled. It therefore may have missed children who presented with certain viral infections (examples could include the common cold and uncomplicated ear infections), which often will not require a prescription medication. Furthermore, it would fail to capture those who may have been seen for an infection but failed to fill the intended prescription.”

Dr. Schneeweiss reported receiving grants from AbbVie and UCB to Brigham and Women’s Hospital unrelated to the topic of this study and outside the submitted work. The study was supported by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Dr. Grossberg reported having no financial disclosures.

Among pediatric patients with psoriasis who began treatment with ustekinumab, etanercept, or methotrexate, the rate of serious infections at 6 months was low, with an incidence ranging between 14.9 and 25.6 per 1,000 person-years.

Those are key findings from what is believed to be the largest cohort study of its kind to estimate the 6-month rate of infections among children with psoriasis who started treatment with ustekinumab, etanercept, or methotrexate.

“Clinical trials have demonstrated high efficacy of new immunomodulatory agents in treating children with psoriasis,” lead author Maria C. Schneeweiss, MD, of the division of pharmacoepidemiology in the departments of medicine and dermatology at Brigham and Women’s Hospital and Harvard Medical School, Boston, and colleagues wrote in the article, which was published online in JAMA Dermatology. “However, the risk of infections in clinical practice has not been fully characterized by comparing these medications against each other in pairwise comparisons.”

Drawing from two large U.S. insurance claims databases, the researchers identified 2,338 patients aged 17 years and younger who were receiving treatment with a topical medication for psoriasis and started new treatment with ustekinumab, etanercept, or methotrexate. They stratified their analysis by the time before pediatric labeling (2009-2015) and after pediatric approval (2016-2021), and their follow-up of patients started 1 day after initiating treatment and ended at 6 months.

Of the 2,338 patients, 1,368 (58%) were girls. From 2009 through 2021, 379 patients began treatment with ustekinumab, 779 patients began treatment with etanercept, and 1,180 patients began treatment with methotrexate. The propensity score–adjusted incidence rate of serious infection was 18.4 per 1,000 person-years (3 events) for those who used ustekinumab, 25.6 per 1,000 person-years (9 events) for those who used etanercept, and 14.9 per 1,000 person-years (8 events) for those who used methotrexate. The adjusted rate of outpatient infections was 254.9 per 1,000 person-years (39 events) for those who used ustekinumab, 435.7 per 1,000 person-years (139 events) for those who used etanercept, and 433.6 per 1,000 person-years (209 events) for those who used methotrexate. Meanwhile, the adjusted rate ratio of outpatient infections was 0.58 for ustekinumab vs. etanercept, 0.66 for ustekinumab vs. methotrexate, and 0.95 for etanercept vs. methotrexate. The researchers found that ratios were similar during the off-label use era and after pediatric labeling.

Anna L. Grossberg, MD, director of pediatric dermatology at the Johns Hopkins Children’s Center, Baltimore, who was asked to comment on the work, told this news organization that the data on outpatient infections in ustekinumab users “demonstrated that they may have a decreased risk of infection compared to pediatric psoriasis patients treated with methotrexate or the TNF-alpha inhibitor etanercept. This is previously unreported and reflects my personal experience with this medication in my own pediatric psoriasis patients.” She added the study’s overall findings lend further support to the safety of biologic medications and nonbiologic systemic immunomodulatory treatments for management of psoriasis. “This study will help guide pediatric dermatologists in counseling patients and their families about these risks [of infection], and in general providing reassurance that these risks appear to be quite low,” Dr. Grossberg said. “In particular, ustekinumab, a newer biologic medication that was recently FDA-approved for children 6 years and older for pediatric psoriasis, was not associated with higher infection rates than the other agents analyzed in this study, and in fact appears to carry a reduced risk compared to both etanercept and methotrexate.”

She noted certain limitations of the study, including its reliance on insurance claims data, “which can be limiting because information on possible confounding variables may not be known,” she said. “For example, the authors point out that environmental and behavioral risk factors for serious infection could not be evaluated or adjusted for, nor could the severity of the patients’ psoriasis. Additionally, this study only reported on outpatient infections that resulted in an antibiotic or other medications being prescribed and filled. It therefore may have missed children who presented with certain viral infections (examples could include the common cold and uncomplicated ear infections), which often will not require a prescription medication. Furthermore, it would fail to capture those who may have been seen for an infection but failed to fill the intended prescription.”

Dr. Schneeweiss reported receiving grants from AbbVie and UCB to Brigham and Women’s Hospital unrelated to the topic of this study and outside the submitted work. The study was supported by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Dr. Grossberg reported having no financial disclosures.

When 2022 began, we started seeing some light at the end of the COVID-19 tunnel. Vaccines were widely available, and even with new variants of the virus still occasionally emerging, the rates of severe morbidity and mortality appeared to be decreasing.

Expectedly, journals appeared to start moving more toward mainstream topics and publications rather than what seemed like a major focus on COVID-19 publications. The resulting literature was fantastic. This past year brought some outstanding publications related to emergency medicine that are practice changers.

Several of those topics were discussed in a prior Emergency Medicine Viewpoint from this news organization, and many more of the research advances of 2022 will be discussed in the near future. However, in this Viewpoint, I would like to present my annual review of my three “must-read” articles of the past year.

As in past years, I am choosing reviews of the literature rather than original research articles (which, all too often, become outdated or debunked within a few years). I choose these articles in the hopes that readers will not simply settle for my brief reviews of the key points but instead will feel compelled to download and read the entire articles. These publications address common conditions and quandaries we face in the daily practice of emergency medicine and are practice-changing.
 

Myocardial dysfunction after cardiac arrest: Tips and pitfalls

The management of post–cardiac arrest patients remains a hot topic in the resuscitation literature as we continue to understand that the immediate post-arrest period is critical to patient outcome.

Ortuno and colleagues reviewed the current literature on post-arrest care and wrote an outstanding summary of how to optimally care for these patients. More specifically, they focused on post-arrest patients who demonstrate continued shock, or “post–cardiac arrest myocardial dysfunction” (PCAMD).

They propose three mechanisms for the pathogenesis of PCAMD: ischemia reperfusion phenomenon, systemic inflammatory response, and increased catecholamine release

I will skip through the details of the pathophysiology that they describe in the article, but I certainly do recommend that everyone review their descriptions.

Management of these patients begins with a good hemodynamic assessment, which includes clinical markers of perfusion (blood pressure, capillary refill), ECG, and point-of-care ultrasound (POCUS). If the initial assessment reveals an obvious cause of the cardiac arrest (e.g., massive pulmonary embolism, myocardial infarction, pericardial tamponade), then the underlying cause should be treated expeditiously.

In the absence of an obvious treatable cause of the shock, the fluid status and cardiac function should be addressed with POCUS. If the patient is hypovolemic, intravenous fluids should be administered. If the fluid status is adequate, POCUS should be used to estimate the patient’s ventricular function. If the ventricle appears to be hyperdynamic with good contractility, shock should be treated with norepinephrine. On the other hand, if the ventricle is hypodynamic, dobutamine should be substituted for norepinephrine or, more often, added to norepinephrine.

The above represents a simplified summary of the critical points, but the authors do delve into further detail and also discuss some other options for therapies, including steroids, coronary revascularization, extracorporeal membrane oxygenation, and so on. The review is very thoughtful, thorough, and definitely worth a full read.
 

Top myths of diagnosis and management of infectious diseases in hospital medicine

Most, if not all of us in medicine, have heard the saying that 50% of what we learn in medical school (or residency) will turn out to be wrong. I certainly believe in this concept and consequently, like many of you, I enjoy reading about myths and misconceptions that we have been taught. With that in mind, I have to say that I love this article because it seems to have been written specifically to address what I was taught!

This author group, consisting mostly of clinical PharmDs who are experts in antibiotic use, provide us with an evidence-based discussion of myths and pitfalls in how antibiotics are often used in current clinical practice. The authors review their top 10 myths involving the use of antibiotics in treating infections in the hospital setting. A few of these relate more to the inpatient setting, but here are my favorite emergency department (ED)–related myths that they address:

• “Antibiotics do no harm.” The authors address the risk-benefit of antibiotics based on assumed vs. confirmed infections, including a brief discussion of adverse drug effects.
• “Antibiotic durations of 7, 14, or 21 days are typically necessary.” The authors address appropriate duration of antibiotic use and the fact that unnecessarily long durations of use can lead to resistance. They also provide reassurance that some infections can be treated with quite short durations of antibiotics.
• “If one drug is good, two (or more!) is better.” The use of multiple antibiotics, often with overlapping bacterial coverage, is rampant in medicine and further increases the risk for adverse drug effects and resistance.
• “Oral antibiotics are not as good as intravenous antibiotics for hospitalized patients.” This is definitely a myth that I learned. I recall being taught by many senior physicians that anyone sick enough for admission should be treated with intravenous antibiotics. As it turns out, absorption and effectiveness of most oral antibiotics is just as good as intravenous antibiotics, and the oral formulations are often safer.
• “A history of a penicillin allergy means the patient can never receive a beta-lactam antibiotic.” This is a myth that was debunked quite a few years ago, but it seems that many clinicians still need a reminder.

The authors included five more myths that are worth the read. This is an article that needs to be disseminated among all hospital clinicians.
 

Guidelines for low-risk, recurrent abdominal pain in the emergency department

The Society for Academic Emergency Medicine (SAEM) recently initiated a program focused on creating evidence-based approaches to challenging chief complaints and presentations in the emergency department (ED). In 2021, they published an approach to managing patients with recurrent, low-risk chest pain in the ED. This past year, they published their second guideline, focused on the management of patients with low-risk, recurrent abdominal pain in the ED.

Recurrent low-risk abdominal pain is a common and vexing presentation to EDs around the world, and there is little prior published guidance. Do all of these patients need repeat imaging? How do we manage their pain? Are there nonabdominal conditions that should be considered?

Broder and colleagues did a fantastic review of the current literature and, on behalf of SAEM, have provided a rational approach to optimal management of these patients. The four major questions they addressed, with brief summaries of their recommendations, are:

• Should adult ED patients with low-risk, recurrent and previously undifferentiated abdominal pain receive a repeat CT abdomen-pelvis (CTAP) after a negative CTAP within the past 12 months? This is a typical question that we all ponder when managing these patients. Unfortunately, the writing group found insufficient evidence to definitively identify populations in whom CTAP was recommended vs could be safely withheld. It is a bit disappointing that there is no definite answer to the question. On the other hand, it is reassuring to know that the world’s best evidence essentially says that it is perfectly appropriate to use your own good clinical judgment.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain with a negative CTAP receive additional imaging with abdominal ultrasound? In this case, the writing group found enough evidence, though low-level, to suggest against routine ultrasound in the absence of concern specifically for pelvic or hepatobiliary pathology. Like most tests, ultrasound is best used when there are specific concerns rather than being used in an undifferentiated fashion.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive screening for depression/anxiety? The writing group found enough evidence, though low-level again, to suggest that screening for depression and/or anxiety be performed during the ED evaluation. This could lead to successful therapy for the abdominal pain.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive nonopioid and/or nonpharmacologic analgesics? The writing group found little evidence to suggest for or against these analgesics, but they made a consensus recommendation suggesting an opioid-minimizing strategy for pain control.

Although the final recommendations of the writing group were not definitive or based on the strongest level of evidence, I find it helpful to have this guidance, nevertheless, on behalf of a major national organization. I also find it helpful to know that even with the best evidence available, optimal patient care will often boil down to physician experience and gestalt. I should also add that the overall article is chock-full of pearls and helpful information that will further inform the readers’ decisions, and so the full version is definitely worth the read.
 

In summary

There you have it – my three favorite practice-changing articles of 2022. Although I have tried to provide key points here, the full discussions of those key points in the published articles will provide a great deal more education than I can offer in this brief write-up, and so I strongly encourage everyone to read the full versions. Please be sure to include in the comments section your own pick for favorite or must-read articles from the past year.

Amal Mattu, MD, is a professor, vice chair of education, and codirector of the emergency cardiology fellowship in the department of emergency medicine at the University of Maryland, Baltimore. She reported no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

When 2022 began, we started seeing some light at the end of the COVID-19 tunnel. Vaccines were widely available, and even with new variants of the virus still occasionally emerging, the rates of severe morbidity and mortality appeared to be decreasing.

Expectedly, journals appeared to start moving more toward mainstream topics and publications rather than what seemed like a major focus on COVID-19 publications. The resulting literature was fantastic. This past year brought some outstanding publications related to emergency medicine that are practice changers.

Several of those topics were discussed in a prior Emergency Medicine Viewpoint from this news organization, and many more of the research advances of 2022 will be discussed in the near future. However, in this Viewpoint, I would like to present my annual review of my three “must-read” articles of the past year.

As in past years, I am choosing reviews of the literature rather than original research articles (which, all too often, become outdated or debunked within a few years). I choose these articles in the hopes that readers will not simply settle for my brief reviews of the key points but instead will feel compelled to download and read the entire articles. These publications address common conditions and quandaries we face in the daily practice of emergency medicine and are practice-changing.
 

Myocardial dysfunction after cardiac arrest: Tips and pitfalls

The management of post–cardiac arrest patients remains a hot topic in the resuscitation literature as we continue to understand that the immediate post-arrest period is critical to patient outcome.

Ortuno and colleagues reviewed the current literature on post-arrest care and wrote an outstanding summary of how to optimally care for these patients. More specifically, they focused on post-arrest patients who demonstrate continued shock, or “post–cardiac arrest myocardial dysfunction” (PCAMD).

They propose three mechanisms for the pathogenesis of PCAMD: ischemia reperfusion phenomenon, systemic inflammatory response, and increased catecholamine release

I will skip through the details of the pathophysiology that they describe in the article, but I certainly do recommend that everyone review their descriptions.

Management of these patients begins with a good hemodynamic assessment, which includes clinical markers of perfusion (blood pressure, capillary refill), ECG, and point-of-care ultrasound (POCUS). If the initial assessment reveals an obvious cause of the cardiac arrest (e.g., massive pulmonary embolism, myocardial infarction, pericardial tamponade), then the underlying cause should be treated expeditiously.

In the absence of an obvious treatable cause of the shock, the fluid status and cardiac function should be addressed with POCUS. If the patient is hypovolemic, intravenous fluids should be administered. If the fluid status is adequate, POCUS should be used to estimate the patient’s ventricular function. If the ventricle appears to be hyperdynamic with good contractility, shock should be treated with norepinephrine. On the other hand, if the ventricle is hypodynamic, dobutamine should be substituted for norepinephrine or, more often, added to norepinephrine.

The above represents a simplified summary of the critical points, but the authors do delve into further detail and also discuss some other options for therapies, including steroids, coronary revascularization, extracorporeal membrane oxygenation, and so on. The review is very thoughtful, thorough, and definitely worth a full read.
 

Top myths of diagnosis and management of infectious diseases in hospital medicine

Most, if not all of us in medicine, have heard the saying that 50% of what we learn in medical school (or residency) will turn out to be wrong. I certainly believe in this concept and consequently, like many of you, I enjoy reading about myths and misconceptions that we have been taught. With that in mind, I have to say that I love this article because it seems to have been written specifically to address what I was taught!

This author group, consisting mostly of clinical PharmDs who are experts in antibiotic use, provide us with an evidence-based discussion of myths and pitfalls in how antibiotics are often used in current clinical practice. The authors review their top 10 myths involving the use of antibiotics in treating infections in the hospital setting. A few of these relate more to the inpatient setting, but here are my favorite emergency department (ED)–related myths that they address:

• “Antibiotics do no harm.” The authors address the risk-benefit of antibiotics based on assumed vs. confirmed infections, including a brief discussion of adverse drug effects.
• “Antibiotic durations of 7, 14, or 21 days are typically necessary.” The authors address appropriate duration of antibiotic use and the fact that unnecessarily long durations of use can lead to resistance. They also provide reassurance that some infections can be treated with quite short durations of antibiotics.
• “If one drug is good, two (or more!) is better.” The use of multiple antibiotics, often with overlapping bacterial coverage, is rampant in medicine and further increases the risk for adverse drug effects and resistance.
• “Oral antibiotics are not as good as intravenous antibiotics for hospitalized patients.” This is definitely a myth that I learned. I recall being taught by many senior physicians that anyone sick enough for admission should be treated with intravenous antibiotics. As it turns out, absorption and effectiveness of most oral antibiotics is just as good as intravenous antibiotics, and the oral formulations are often safer.
• “A history of a penicillin allergy means the patient can never receive a beta-lactam antibiotic.” This is a myth that was debunked quite a few years ago, but it seems that many clinicians still need a reminder.

The authors included five more myths that are worth the read. This is an article that needs to be disseminated among all hospital clinicians.
 

Guidelines for low-risk, recurrent abdominal pain in the emergency department

The Society for Academic Emergency Medicine (SAEM) recently initiated a program focused on creating evidence-based approaches to challenging chief complaints and presentations in the emergency department (ED). In 2021, they published an approach to managing patients with recurrent, low-risk chest pain in the ED. This past year, they published their second guideline, focused on the management of patients with low-risk, recurrent abdominal pain in the ED.

Recurrent low-risk abdominal pain is a common and vexing presentation to EDs around the world, and there is little prior published guidance. Do all of these patients need repeat imaging? How do we manage their pain? Are there nonabdominal conditions that should be considered?

Broder and colleagues did a fantastic review of the current literature and, on behalf of SAEM, have provided a rational approach to optimal management of these patients. The four major questions they addressed, with brief summaries of their recommendations, are:

• Should adult ED patients with low-risk, recurrent and previously undifferentiated abdominal pain receive a repeat CT abdomen-pelvis (CTAP) after a negative CTAP within the past 12 months? This is a typical question that we all ponder when managing these patients. Unfortunately, the writing group found insufficient evidence to definitively identify populations in whom CTAP was recommended vs could be safely withheld. It is a bit disappointing that there is no definite answer to the question. On the other hand, it is reassuring to know that the world’s best evidence essentially says that it is perfectly appropriate to use your own good clinical judgment.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain with a negative CTAP receive additional imaging with abdominal ultrasound? In this case, the writing group found enough evidence, though low-level, to suggest against routine ultrasound in the absence of concern specifically for pelvic or hepatobiliary pathology. Like most tests, ultrasound is best used when there are specific concerns rather than being used in an undifferentiated fashion.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive screening for depression/anxiety? The writing group found enough evidence, though low-level again, to suggest that screening for depression and/or anxiety be performed during the ED evaluation. This could lead to successful therapy for the abdominal pain.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive nonopioid and/or nonpharmacologic analgesics? The writing group found little evidence to suggest for or against these analgesics, but they made a consensus recommendation suggesting an opioid-minimizing strategy for pain control.

Although the final recommendations of the writing group were not definitive or based on the strongest level of evidence, I find it helpful to have this guidance, nevertheless, on behalf of a major national organization. I also find it helpful to know that even with the best evidence available, optimal patient care will often boil down to physician experience and gestalt. I should also add that the overall article is chock-full of pearls and helpful information that will further inform the readers’ decisions, and so the full version is definitely worth the read.
 

In summary

There you have it – my three favorite practice-changing articles of 2022. Although I have tried to provide key points here, the full discussions of those key points in the published articles will provide a great deal more education than I can offer in this brief write-up, and so I strongly encourage everyone to read the full versions. Please be sure to include in the comments section your own pick for favorite or must-read articles from the past year.

Amal Mattu, MD, is a professor, vice chair of education, and codirector of the emergency cardiology fellowship in the department of emergency medicine at the University of Maryland, Baltimore. She reported no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

When 2022 began, we started seeing some light at the end of the COVID-19 tunnel. Vaccines were widely available, and even with new variants of the virus still occasionally emerging, the rates of severe morbidity and mortality appeared to be decreasing.

Expectedly, journals appeared to start moving more toward mainstream topics and publications rather than what seemed like a major focus on COVID-19 publications. The resulting literature was fantastic. This past year brought some outstanding publications related to emergency medicine that are practice changers.

Several of those topics were discussed in a prior Emergency Medicine Viewpoint from this news organization, and many more of the research advances of 2022 will be discussed in the near future. However, in this Viewpoint, I would like to present my annual review of my three “must-read” articles of the past year.

As in past years, I am choosing reviews of the literature rather than original research articles (which, all too often, become outdated or debunked within a few years). I choose these articles in the hopes that readers will not simply settle for my brief reviews of the key points but instead will feel compelled to download and read the entire articles. These publications address common conditions and quandaries we face in the daily practice of emergency medicine and are practice-changing.
 

Myocardial dysfunction after cardiac arrest: Tips and pitfalls

The management of post–cardiac arrest patients remains a hot topic in the resuscitation literature as we continue to understand that the immediate post-arrest period is critical to patient outcome.

Ortuno and colleagues reviewed the current literature on post-arrest care and wrote an outstanding summary of how to optimally care for these patients. More specifically, they focused on post-arrest patients who demonstrate continued shock, or “post–cardiac arrest myocardial dysfunction” (PCAMD).

They propose three mechanisms for the pathogenesis of PCAMD: ischemia reperfusion phenomenon, systemic inflammatory response, and increased catecholamine release

I will skip through the details of the pathophysiology that they describe in the article, but I certainly do recommend that everyone review their descriptions.

Management of these patients begins with a good hemodynamic assessment, which includes clinical markers of perfusion (blood pressure, capillary refill), ECG, and point-of-care ultrasound (POCUS). If the initial assessment reveals an obvious cause of the cardiac arrest (e.g., massive pulmonary embolism, myocardial infarction, pericardial tamponade), then the underlying cause should be treated expeditiously.

In the absence of an obvious treatable cause of the shock, the fluid status and cardiac function should be addressed with POCUS. If the patient is hypovolemic, intravenous fluids should be administered. If the fluid status is adequate, POCUS should be used to estimate the patient’s ventricular function. If the ventricle appears to be hyperdynamic with good contractility, shock should be treated with norepinephrine. On the other hand, if the ventricle is hypodynamic, dobutamine should be substituted for norepinephrine or, more often, added to norepinephrine.

The above represents a simplified summary of the critical points, but the authors do delve into further detail and also discuss some other options for therapies, including steroids, coronary revascularization, extracorporeal membrane oxygenation, and so on. The review is very thoughtful, thorough, and definitely worth a full read.
 

Top myths of diagnosis and management of infectious diseases in hospital medicine

Most, if not all of us in medicine, have heard the saying that 50% of what we learn in medical school (or residency) will turn out to be wrong. I certainly believe in this concept and consequently, like many of you, I enjoy reading about myths and misconceptions that we have been taught. With that in mind, I have to say that I love this article because it seems to have been written specifically to address what I was taught!

This author group, consisting mostly of clinical PharmDs who are experts in antibiotic use, provide us with an evidence-based discussion of myths and pitfalls in how antibiotics are often used in current clinical practice. The authors review their top 10 myths involving the use of antibiotics in treating infections in the hospital setting. A few of these relate more to the inpatient setting, but here are my favorite emergency department (ED)–related myths that they address:

• “Antibiotics do no harm.” The authors address the risk-benefit of antibiotics based on assumed vs. confirmed infections, including a brief discussion of adverse drug effects.
• “Antibiotic durations of 7, 14, or 21 days are typically necessary.” The authors address appropriate duration of antibiotic use and the fact that unnecessarily long durations of use can lead to resistance. They also provide reassurance that some infections can be treated with quite short durations of antibiotics.
• “If one drug is good, two (or more!) is better.” The use of multiple antibiotics, often with overlapping bacterial coverage, is rampant in medicine and further increases the risk for adverse drug effects and resistance.
• “Oral antibiotics are not as good as intravenous antibiotics for hospitalized patients.” This is definitely a myth that I learned. I recall being taught by many senior physicians that anyone sick enough for admission should be treated with intravenous antibiotics. As it turns out, absorption and effectiveness of most oral antibiotics is just as good as intravenous antibiotics, and the oral formulations are often safer.
• “A history of a penicillin allergy means the patient can never receive a beta-lactam antibiotic.” This is a myth that was debunked quite a few years ago, but it seems that many clinicians still need a reminder.

The authors included five more myths that are worth the read. This is an article that needs to be disseminated among all hospital clinicians.
 

Guidelines for low-risk, recurrent abdominal pain in the emergency department

The Society for Academic Emergency Medicine (SAEM) recently initiated a program focused on creating evidence-based approaches to challenging chief complaints and presentations in the emergency department (ED). In 2021, they published an approach to managing patients with recurrent, low-risk chest pain in the ED. This past year, they published their second guideline, focused on the management of patients with low-risk, recurrent abdominal pain in the ED.

Recurrent low-risk abdominal pain is a common and vexing presentation to EDs around the world, and there is little prior published guidance. Do all of these patients need repeat imaging? How do we manage their pain? Are there nonabdominal conditions that should be considered?

Broder and colleagues did a fantastic review of the current literature and, on behalf of SAEM, have provided a rational approach to optimal management of these patients. The four major questions they addressed, with brief summaries of their recommendations, are:

• Should adult ED patients with low-risk, recurrent and previously undifferentiated abdominal pain receive a repeat CT abdomen-pelvis (CTAP) after a negative CTAP within the past 12 months? This is a typical question that we all ponder when managing these patients. Unfortunately, the writing group found insufficient evidence to definitively identify populations in whom CTAP was recommended vs could be safely withheld. It is a bit disappointing that there is no definite answer to the question. On the other hand, it is reassuring to know that the world’s best evidence essentially says that it is perfectly appropriate to use your own good clinical judgment.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain with a negative CTAP receive additional imaging with abdominal ultrasound? In this case, the writing group found enough evidence, though low-level, to suggest against routine ultrasound in the absence of concern specifically for pelvic or hepatobiliary pathology. Like most tests, ultrasound is best used when there are specific concerns rather than being used in an undifferentiated fashion.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive screening for depression/anxiety? The writing group found enough evidence, though low-level again, to suggest that screening for depression and/or anxiety be performed during the ED evaluation. This could lead to successful therapy for the abdominal pain.
• Should adult ED patients with low-risk, recurrent, and previously undifferentiated abdominal pain receive nonopioid and/or nonpharmacologic analgesics? The writing group found little evidence to suggest for or against these analgesics, but they made a consensus recommendation suggesting an opioid-minimizing strategy for pain control.

Although the final recommendations of the writing group were not definitive or based on the strongest level of evidence, I find it helpful to have this guidance, nevertheless, on behalf of a major national organization. I also find it helpful to know that even with the best evidence available, optimal patient care will often boil down to physician experience and gestalt. I should also add that the overall article is chock-full of pearls and helpful information that will further inform the readers’ decisions, and so the full version is definitely worth the read.
 

In summary

There you have it – my three favorite practice-changing articles of 2022. Although I have tried to provide key points here, the full discussions of those key points in the published articles will provide a great deal more education than I can offer in this brief write-up, and so I strongly encourage everyone to read the full versions. Please be sure to include in the comments section your own pick for favorite or must-read articles from the past year.

Amal Mattu, MD, is a professor, vice chair of education, and codirector of the emergency cardiology fellowship in the department of emergency medicine at the University of Maryland, Baltimore. She reported no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

For years, women’s health advocates have argued that far more research is needed on women’s bodies and health. The world’s first-ever “vagina on a chip,” recently developed at Harvard’s Wyss Institute for Biologically Inspired Engineering in Boston, could go a long way to making that happen. 

“Women’s health has not received the attention it deserves,” says Don Ingber, MD, PhD, who led the team that created the vagina chip. The advance quickly drew media attention after it was reported in the journal Microbiome. But researchers hope for more than headlines. They see the chip as a way to facilitate vaginal health research and open the door to vital new treatments. 

By now, you may have heard of “organs on chips”: tiny devices about the size of a flash drive that are designed to mimic the biological activity of human organs. These glass chips contain living human cells within grooves that allow the passage of fluid, to either maintain or disrupt the cells’ function. So far, Dr. Ingber and his team at the Wyss Institute have developed more than 15 organ chip models, including chips that mimic the lung, intestine, kidney, and bone marrow. 

The idea to develop a vagina chip grew out of research, funded by the Gates Foundation, on a childhood disease called environmental enteric dysfunction, an intestinal disease most commonly found in low-resource nations that is the second leading cause of death in children under 5. That’s when Dr. Ingber discovered just how much the child’s microbiome influences this disease. 

Stemming from that work, the Gates Foundation turned its attention to newborn health – in particular, the impact of bacterial vaginosis, an imbalance in the vagina’s bacterial makeup. Bacterial vaginosis occurs in one out of four women worldwide and has been linked to premature birth as well as HIV, HPV persistence, and cervical cancer. 

Upon establishing the Vaginal Microbiome Research Consortium,  the foundation asked Dr. Ingber to engineer an organ chip that mimicked the vagina’s microbiome. The goal was to test “live biotherapeutic products,” or living microbes like probiotics, that might restore the vagina’s microbiome to health.  

No other preclinical model exists to perform tests like that, says Dr. Ingber. 

“The vagina chip is a way to help make some advances,” he says. 

The Gates Foundation recognized that women’s reproductive health is a major issue, not only in low-income nations, but everywhere around the world. As the project evolved, Dr. Ingber began to hear from female colleagues about how neglected women’s reproductive health is in medical science. 

“It is something I became sensitive to and realized this is just the starting point,” Dr. Ingber says.

Take bacterial vaginosis, for example. Since 1982, treatment has revolved around the same two antibiotics. That’s partly because there is no animal model to study. No other species has the same vaginal bacterial community as humans do.

That makes developing any new therapy “incredibly challenging,” explains Caroline Mitchell, MD, MPH, an ob.gyn. at Massachusetts General Hospital, Boston, and a member of the consortium. 

It turns out, replicating the vagina in a lab dish is, to use the technical term, very hard. 

“That’s where a vagina chip offers an opportunity,” Dr. Mitchell says. “It’s not super-high throughput, but it’s way more high throughput than a [human] clinical trial.” 

As such, the vagina chip could help scientists find new treatments much faster. 

Like Dr. Ingber, Dr. Mitchell also sees the chip as a way to bring more attention to the largely unmet needs in female reproductive medicine.

“Women’s reproductive health has been under-resourced, under-prioritized, and largely disregarded for decades,” she says. And the time may be ripe for change: Dr. Mitchell says she was encouraged by the National Institutes of Health’s Advancing NIH Research on the Health of Women conference, held in 2021 in response to a congressional request to address women’s health research efforts.  

Beyond bacterial vaginosis, Dr. Mitchell imagines the chip could help scientists find new treatments for vaginal yeast infection (candidiasis), chlamydia, and endometriosis. As with bacterial vaginosis, medicines for vaginal yeast infections have not advanced in decades, Dr. Mitchell says.  Efforts to develop a vaccine for chlamydia – which can cause permanent damage to a woman’s reproductive system – have dragged on for many years. And endometriosis, an often painful condition in which the tissue that makes up the uterine lining grows outside the uterus, remains under-researched despite affecting 10% of childbearing-age women.

While some mouse models are used in chlamydia research, it’s hard to say if they’ll translate to humans, given the vaginal and cervical bacterial differences. 

“Our understanding of the basic physiology of the environment of the vagina and cervix is another area where we’re woefully ignorant,” Dr. Mitchell says.

To that end, Dr. Ingber’s team is developing more complex chips mimicking the vagina and the cervix. One of his team members wants to use the chips to study infertility. The researchers have already used the chips to see how bacterial vaginosis and mucous changes impact the way sperm migrates up the reproductive tract. 

The lab is now linking vagina and cervix chips together to study viral infections of the cervix, like HPV, and all types of bacterial diseases of the vaginal tract. By applying cervical mucus to the vagina chip, they hope to learn more about how female reproductive tissues respond to infection and inflammation.

“I always say that organ chips are like synthetic biology at the cell tissue and organ level,” says Dr. Ingber. “You start simple and see if you [can] mimic a clinical situation.” 

As they make the chips more complex – perhaps by adding blood vessel cells and female hormones – Dr. Ingber foresees being able to study the response to hormonal changes during the menstrual cycle.

“We can begin to explore the effects of cycling over time as well as other types of hormonal effects,” he says.

Dr. Ingber also envisions linking the vagina chip to other organ chips – he’s already succeeded in linking eight different organ types together. But for now, the team hopes the vagina chip will enhance our understanding of basic female reproductive biology and speed up the process of developing new treatments for women’s health. 

A version of this article first appeared on WebMD.com.

For years, women’s health advocates have argued that far more research is needed on women’s bodies and health. The world’s first-ever “vagina on a chip,” recently developed at Harvard’s Wyss Institute for Biologically Inspired Engineering in Boston, could go a long way to making that happen. 

“Women’s health has not received the attention it deserves,” says Don Ingber, MD, PhD, who led the team that created the vagina chip. The advance quickly drew media attention after it was reported in the journal Microbiome. But researchers hope for more than headlines. They see the chip as a way to facilitate vaginal health research and open the door to vital new treatments. 

By now, you may have heard of “organs on chips”: tiny devices about the size of a flash drive that are designed to mimic the biological activity of human organs. These glass chips contain living human cells within grooves that allow the passage of fluid, to either maintain or disrupt the cells’ function. So far, Dr. Ingber and his team at the Wyss Institute have developed more than 15 organ chip models, including chips that mimic the lung, intestine, kidney, and bone marrow. 

The idea to develop a vagina chip grew out of research, funded by the Gates Foundation, on a childhood disease called environmental enteric dysfunction, an intestinal disease most commonly found in low-resource nations that is the second leading cause of death in children under 5. That’s when Dr. Ingber discovered just how much the child’s microbiome influences this disease. 

Stemming from that work, the Gates Foundation turned its attention to newborn health – in particular, the impact of bacterial vaginosis, an imbalance in the vagina’s bacterial makeup. Bacterial vaginosis occurs in one out of four women worldwide and has been linked to premature birth as well as HIV, HPV persistence, and cervical cancer. 

Upon establishing the Vaginal Microbiome Research Consortium,  the foundation asked Dr. Ingber to engineer an organ chip that mimicked the vagina’s microbiome. The goal was to test “live biotherapeutic products,” or living microbes like probiotics, that might restore the vagina’s microbiome to health.  

No other preclinical model exists to perform tests like that, says Dr. Ingber. 

“The vagina chip is a way to help make some advances,” he says. 

The Gates Foundation recognized that women’s reproductive health is a major issue, not only in low-income nations, but everywhere around the world. As the project evolved, Dr. Ingber began to hear from female colleagues about how neglected women’s reproductive health is in medical science. 

“It is something I became sensitive to and realized this is just the starting point,” Dr. Ingber says.

Take bacterial vaginosis, for example. Since 1982, treatment has revolved around the same two antibiotics. That’s partly because there is no animal model to study. No other species has the same vaginal bacterial community as humans do.

That makes developing any new therapy “incredibly challenging,” explains Caroline Mitchell, MD, MPH, an ob.gyn. at Massachusetts General Hospital, Boston, and a member of the consortium. 

It turns out, replicating the vagina in a lab dish is, to use the technical term, very hard. 

“That’s where a vagina chip offers an opportunity,” Dr. Mitchell says. “It’s not super-high throughput, but it’s way more high throughput than a [human] clinical trial.” 

As such, the vagina chip could help scientists find new treatments much faster. 

Like Dr. Ingber, Dr. Mitchell also sees the chip as a way to bring more attention to the largely unmet needs in female reproductive medicine.

“Women’s reproductive health has been under-resourced, under-prioritized, and largely disregarded for decades,” she says. And the time may be ripe for change: Dr. Mitchell says she was encouraged by the National Institutes of Health’s Advancing NIH Research on the Health of Women conference, held in 2021 in response to a congressional request to address women’s health research efforts.  

Beyond bacterial vaginosis, Dr. Mitchell imagines the chip could help scientists find new treatments for vaginal yeast infection (candidiasis), chlamydia, and endometriosis. As with bacterial vaginosis, medicines for vaginal yeast infections have not advanced in decades, Dr. Mitchell says.  Efforts to develop a vaccine for chlamydia – which can cause permanent damage to a woman’s reproductive system – have dragged on for many years. And endometriosis, an often painful condition in which the tissue that makes up the uterine lining grows outside the uterus, remains under-researched despite affecting 10% of childbearing-age women.

While some mouse models are used in chlamydia research, it’s hard to say if they’ll translate to humans, given the vaginal and cervical bacterial differences. 

“Our understanding of the basic physiology of the environment of the vagina and cervix is another area where we’re woefully ignorant,” Dr. Mitchell says.

To that end, Dr. Ingber’s team is developing more complex chips mimicking the vagina and the cervix. One of his team members wants to use the chips to study infertility. The researchers have already used the chips to see how bacterial vaginosis and mucous changes impact the way sperm migrates up the reproductive tract. 

The lab is now linking vagina and cervix chips together to study viral infections of the cervix, like HPV, and all types of bacterial diseases of the vaginal tract. By applying cervical mucus to the vagina chip, they hope to learn more about how female reproductive tissues respond to infection and inflammation.

“I always say that organ chips are like synthetic biology at the cell tissue and organ level,” says Dr. Ingber. “You start simple and see if you [can] mimic a clinical situation.” 

As they make the chips more complex – perhaps by adding blood vessel cells and female hormones – Dr. Ingber foresees being able to study the response to hormonal changes during the menstrual cycle.

“We can begin to explore the effects of cycling over time as well as other types of hormonal effects,” he says.

Dr. Ingber also envisions linking the vagina chip to other organ chips – he’s already succeeded in linking eight different organ types together. But for now, the team hopes the vagina chip will enhance our understanding of basic female reproductive biology and speed up the process of developing new treatments for women’s health. 

A version of this article first appeared on WebMD.com.

For years, women’s health advocates have argued that far more research is needed on women’s bodies and health. The world’s first-ever “vagina on a chip,” recently developed at Harvard’s Wyss Institute for Biologically Inspired Engineering in Boston, could go a long way to making that happen. 

“Women’s health has not received the attention it deserves,” says Don Ingber, MD, PhD, who led the team that created the vagina chip. The advance quickly drew media attention after it was reported in the journal Microbiome. But researchers hope for more than headlines. They see the chip as a way to facilitate vaginal health research and open the door to vital new treatments. 

By now, you may have heard of “organs on chips”: tiny devices about the size of a flash drive that are designed to mimic the biological activity of human organs. These glass chips contain living human cells within grooves that allow the passage of fluid, to either maintain or disrupt the cells’ function. So far, Dr. Ingber and his team at the Wyss Institute have developed more than 15 organ chip models, including chips that mimic the lung, intestine, kidney, and bone marrow. 

The idea to develop a vagina chip grew out of research, funded by the Gates Foundation, on a childhood disease called environmental enteric dysfunction, an intestinal disease most commonly found in low-resource nations that is the second leading cause of death in children under 5. That’s when Dr. Ingber discovered just how much the child’s microbiome influences this disease. 

Stemming from that work, the Gates Foundation turned its attention to newborn health – in particular, the impact of bacterial vaginosis, an imbalance in the vagina’s bacterial makeup. Bacterial vaginosis occurs in one out of four women worldwide and has been linked to premature birth as well as HIV, HPV persistence, and cervical cancer. 

Upon establishing the Vaginal Microbiome Research Consortium,  the foundation asked Dr. Ingber to engineer an organ chip that mimicked the vagina’s microbiome. The goal was to test “live biotherapeutic products,” or living microbes like probiotics, that might restore the vagina’s microbiome to health.  

No other preclinical model exists to perform tests like that, says Dr. Ingber. 

“The vagina chip is a way to help make some advances,” he says. 

The Gates Foundation recognized that women’s reproductive health is a major issue, not only in low-income nations, but everywhere around the world. As the project evolved, Dr. Ingber began to hear from female colleagues about how neglected women’s reproductive health is in medical science. 

“It is something I became sensitive to and realized this is just the starting point,” Dr. Ingber says.

Take bacterial vaginosis, for example. Since 1982, treatment has revolved around the same two antibiotics. That’s partly because there is no animal model to study. No other species has the same vaginal bacterial community as humans do.

That makes developing any new therapy “incredibly challenging,” explains Caroline Mitchell, MD, MPH, an ob.gyn. at Massachusetts General Hospital, Boston, and a member of the consortium. 

It turns out, replicating the vagina in a lab dish is, to use the technical term, very hard. 

“That’s where a vagina chip offers an opportunity,” Dr. Mitchell says. “It’s not super-high throughput, but it’s way more high throughput than a [human] clinical trial.” 

As such, the vagina chip could help scientists find new treatments much faster. 

Like Dr. Ingber, Dr. Mitchell also sees the chip as a way to bring more attention to the largely unmet needs in female reproductive medicine.

“Women’s reproductive health has been under-resourced, under-prioritized, and largely disregarded for decades,” she says. And the time may be ripe for change: Dr. Mitchell says she was encouraged by the National Institutes of Health’s Advancing NIH Research on the Health of Women conference, held in 2021 in response to a congressional request to address women’s health research efforts.  

Beyond bacterial vaginosis, Dr. Mitchell imagines the chip could help scientists find new treatments for vaginal yeast infection (candidiasis), chlamydia, and endometriosis. As with bacterial vaginosis, medicines for vaginal yeast infections have not advanced in decades, Dr. Mitchell says.  Efforts to develop a vaccine for chlamydia – which can cause permanent damage to a woman’s reproductive system – have dragged on for many years. And endometriosis, an often painful condition in which the tissue that makes up the uterine lining grows outside the uterus, remains under-researched despite affecting 10% of childbearing-age women.

While some mouse models are used in chlamydia research, it’s hard to say if they’ll translate to humans, given the vaginal and cervical bacterial differences. 

“Our understanding of the basic physiology of the environment of the vagina and cervix is another area where we’re woefully ignorant,” Dr. Mitchell says.

To that end, Dr. Ingber’s team is developing more complex chips mimicking the vagina and the cervix. One of his team members wants to use the chips to study infertility. The researchers have already used the chips to see how bacterial vaginosis and mucous changes impact the way sperm migrates up the reproductive tract. 

The lab is now linking vagina and cervix chips together to study viral infections of the cervix, like HPV, and all types of bacterial diseases of the vaginal tract. By applying cervical mucus to the vagina chip, they hope to learn more about how female reproductive tissues respond to infection and inflammation.

“I always say that organ chips are like synthetic biology at the cell tissue and organ level,” says Dr. Ingber. “You start simple and see if you [can] mimic a clinical situation.” 

As they make the chips more complex – perhaps by adding blood vessel cells and female hormones – Dr. Ingber foresees being able to study the response to hormonal changes during the menstrual cycle.

“We can begin to explore the effects of cycling over time as well as other types of hormonal effects,” he says.

Dr. Ingber also envisions linking the vagina chip to other organ chips – he’s already succeeded in linking eight different organ types together. But for now, the team hopes the vagina chip will enhance our understanding of basic female reproductive biology and speed up the process of developing new treatments for women’s health. 

A version of this article first appeared on WebMD.com.

This transcript has been edited for clarity.

Hello. I’m Dr Sandra Fryhofer. Welcome to Medicine Matters. The topic is highlights from ACIP’s new adult schedule for 2023, published in the Annals of Internal Medicine, and why this new schedule may be a collector’s item.

It’s a new year, which means a new ACIP adult immunization schedule – a valuable resource collating ACIP’s most up-to-date vaccination recommendations.

Here are this year’s five most important changes:

• COVID vaccines now front and center
• New emphasis on polio vaccination
• Inclusion of some nonvaccine products (such as monoclonal antibody products)
• Pharmacists group has approved the schedule for the first time
• New shared clinical decision-making option for pneumococcal vaccines

The schedule’s organization remains the same. It still has four sections:

• Table 1: vaccinations by age
• Table 2: vaccinations by medical condition and other indications
• The Notes section (alphabetically ordered by vaccine type)
• Appendix listing of vaccine-specific contraindications and precautions

But what’s unique this year is that some of the abbreviations have historical implications. The first change is no big surprise in light of what we’ve gone through in the past few years. COVID vaccines are listed first on the cover page by brand name for those authorized and by company name for those still under US emergency use authorization. They’re also listed first on the graphics and in the notes.

COVID and mRNA and protein-based vaccines have now been assigned official abbreviations based on vaccine platform and valency.

• 1vCOV-mRNA: Comirnaty/Pfizer-BioNTech and Spikevax Moderna COVID-19 vaccines
• 2vCOV-mRNA: Pfizer-BioNTech and Moderna bivalent COVID-19 vaccines
• 1vCOV-aPS: Novavax COVID-19 vaccine

Also remarkable is the absence of COVID viral vector vaccines on the list. However, the viral vector COVID vaccine (which has been available but is not preferred) does have a CDC website link in the Notes section.

A sad but necessary inclusion was triggered by recent polio cases in New York. Polio was believed to be eradicated, and we thought adults no longer needed to be vaccinated against polio. In the new schedule, the polio vaccine is listed on the cover page but is not included in the tables. Current polio vaccination recommendations are now in the Notes section.

Also of historical significance and something that may set a precedent is the inclusion of nonvaccine products. The value of COVID preexposure prophylaxis with products including monoclonal antibodies (such as Evusheld) for people who are moderately or severely immunocompromised is mentioned in the Notes section.

For the first time ever, the schedule has been approved by the American Pharmacists Association, which validates pharmacists as established partners in vaccine administration.
 

Color-code key

One aspect of the schedule that has not changed is the color-code key:

• Yellow: Recommended if the patient meets the age requirement
• Purple: Indicated for those with additional risk factors or another indication
• Blue: Recommended based on shared clinical decision-making
• Orange: Precaution
• Red: Contraindicated or not recommended; the vaccine should not be administered. Overlays on the red more precisely clarify whether a vaccine is really contraindicated or just not recommended. An asterisk on red means vaccinate after pregnancy if indicated.
• Gray: No recommendation or not applicable

Vaccinations by age

Table 1 lists recommended vaccinations by age. There is one major change. COVID vaccines are on the first row of the graphic, with the need for both a primary series and boosters emphasized on the overlay. The notes have hyperlinks to the most up-to-date COVID vaccination recommendations.

Pneumococcal vaccination. Pneumococcal vaccination is routinely recommended starting at age 65. Current recommendations for those not previously vaccinated have not changed since last year. But on Table 1, the bottom half of the row for those 65 or older is now blue (and that’s new). This new color blue means shared clinical decision-making and applies to people who were previously considered fully vaccinated with the now extinct combination of PCV13 and PPSV23. These patients now have the option of getting a dose of PCV20 five years after completing their PCV13-PPSV23 combo series. This option is blue because the decision is up to you and your patient.

Check the notes for more pneumococcal vaccination details. For example, for those partially vaccinated using lower valency vaccines, there’s an option of substituting PCV20 for PPSV23 to broaden and increase durability of protection.

The pneumococcal vaccination recommendation options are complicated. A new pneumococcal vaccination app can help.

Hepatitis B. For adults under age 60, the color code for the hepatitis B vaccine is yellow, meaning it’s indicated for all. For older patients, the color code is purple. If a patient who is age 60 or older wants the hepatitis B vaccine, they can have it even in the absence of additional risk indications.
 

Vaccinations by medical condition or other indications

Other than a few minor word changes on the overlay, the only thing that’s new is the COVID vaccine row.

This table is helpful for matching vaccine recommendations with specific medical conditions, including pregnancy, immunocompromise, HIV (with specifics according to CD4 count), asplenia, complement deficiencies, heart disease, lung disease, alcoholism, chronic liver disease, diabetes, health care personnel, and men who have sex with men.

Use this table to dot the i’s and cross the t’s when it comes to vaccination recommendations. For example, take a look at the pregnancy column. Live virus vaccines, including LAIV, MMR, and varicella, are contraindicated and color-coded red. MMR and varicella also have an asterisk, meaning vaccinate after pregnancy if indicated. HPV vaccines are not live virus vaccines, but the overlay says they are not recommended during pregnancy. The asterisk indicates that you can vaccinate after pregnancy.
 

Vaccine notes

The notes are in alphabetical order, and their organization (routine, special situations, and shared clinical decision-making when indicated) has not changed. They are concise and succinct, but sometimes they’re not enough. That’s why vaccine-specific links to more complete recommendations are so convenient.

Notes for hepatitis B contain nuances on specific dosing for vaccinating patients on dialysis, as well as a reminder that newer hepatitis C vaccines such as Heplisav and PreHevbrio are not recommended during pregnancy due to lack of safety data.

For influenza, everyone 6 months or older still needs yearly flu vaccination with an age- and health-appropriate flu vaccine. But for those aged 65 or older, the notes specify the three vaccine versions now preferred: high-dose, recombinant, or adjuvanted versions. However, if these aren’t available, it’s better to get any flu vaccine than to go without.

Under meningococcal vaccines, the notes for MenACWY and MenB are combined. For MenB, trade names Bexsero and Trumenba are specified because the products are not interchangeable. Booster intervals for those still at risk are different for each vaccine type: every 5 years for MenACWY boosters, and every 2-3 years for boosts of MenB.

The recent polio cases in New York have put polio vaccination in the spotlight. ACIP has now reinstated its Polio Vaccine Work Group. The new schedule lists polio vaccines on the cover page. Current recommendations have been added to the notes section. Routine vaccination for adults is not necessary, at least for now. However, those at increased risk for exposure to polio fall in the special-situation category. For those at increased risk who have completed a polio vaccine series, a single lifetime IPV booster can be given. For those at increased risk who have not completed their polio vaccine series, now would be the time to finish the series.
 

Appendix

The final step in using the new schedule is checking the appendix and its list of vaccine-specific contraindications and precautions.

I hope this review of the new ACIP adult immunization schedule has been helpful. For Medicine Matters, I’m Dr. Sandra Fryhofer.

Dr. Fryhofer is clinical associate professor of medicine, Emory University, Atlanta. She reported numerous conflicts of interest.

A version of this article first appeared on Medscape.com.

This transcript has been edited for clarity.

Hello. I’m Dr Sandra Fryhofer. Welcome to Medicine Matters. The topic is highlights from ACIP’s new adult schedule for 2023, published in the Annals of Internal Medicine, and why this new schedule may be a collector’s item.

It’s a new year, which means a new ACIP adult immunization schedule – a valuable resource collating ACIP’s most up-to-date vaccination recommendations.

Here are this year’s five most important changes:

• COVID vaccines now front and center
• New emphasis on polio vaccination
• Inclusion of some nonvaccine products (such as monoclonal antibody products)
• Pharmacists group has approved the schedule for the first time
• New shared clinical decision-making option for pneumococcal vaccines

The schedule’s organization remains the same. It still has four sections:

• Table 1: vaccinations by age
• Table 2: vaccinations by medical condition and other indications
• The Notes section (alphabetically ordered by vaccine type)
• Appendix listing of vaccine-specific contraindications and precautions

But what’s unique this year is that some of the abbreviations have historical implications. The first change is no big surprise in light of what we’ve gone through in the past few years. COVID vaccines are listed first on the cover page by brand name for those authorized and by company name for those still under US emergency use authorization. They’re also listed first on the graphics and in the notes.

COVID and mRNA and protein-based vaccines have now been assigned official abbreviations based on vaccine platform and valency.

• 1vCOV-mRNA: Comirnaty/Pfizer-BioNTech and Spikevax Moderna COVID-19 vaccines
• 2vCOV-mRNA: Pfizer-BioNTech and Moderna bivalent COVID-19 vaccines
• 1vCOV-aPS: Novavax COVID-19 vaccine

Also remarkable is the absence of COVID viral vector vaccines on the list. However, the viral vector COVID vaccine (which has been available but is not preferred) does have a CDC website link in the Notes section.

A sad but necessary inclusion was triggered by recent polio cases in New York. Polio was believed to be eradicated, and we thought adults no longer needed to be vaccinated against polio. In the new schedule, the polio vaccine is listed on the cover page but is not included in the tables. Current polio vaccination recommendations are now in the Notes section.

Also of historical significance and something that may set a precedent is the inclusion of nonvaccine products. The value of COVID preexposure prophylaxis with products including monoclonal antibodies (such as Evusheld) for people who are moderately or severely immunocompromised is mentioned in the Notes section.

For the first time ever, the schedule has been approved by the American Pharmacists Association, which validates pharmacists as established partners in vaccine administration.
 

Color-code key

One aspect of the schedule that has not changed is the color-code key:

• Yellow: Recommended if the patient meets the age requirement
• Purple: Indicated for those with additional risk factors or another indication
• Blue: Recommended based on shared clinical decision-making
• Orange: Precaution
• Red: Contraindicated or not recommended; the vaccine should not be administered. Overlays on the red more precisely clarify whether a vaccine is really contraindicated or just not recommended. An asterisk on red means vaccinate after pregnancy if indicated.
• Gray: No recommendation or not applicable

Vaccinations by age

Table 1 lists recommended vaccinations by age. There is one major change. COVID vaccines are on the first row of the graphic, with the need for both a primary series and boosters emphasized on the overlay. The notes have hyperlinks to the most up-to-date COVID vaccination recommendations.

Pneumococcal vaccination. Pneumococcal vaccination is routinely recommended starting at age 65. Current recommendations for those not previously vaccinated have not changed since last year. But on Table 1, the bottom half of the row for those 65 or older is now blue (and that’s new). This new color blue means shared clinical decision-making and applies to people who were previously considered fully vaccinated with the now extinct combination of PCV13 and PPSV23. These patients now have the option of getting a dose of PCV20 five years after completing their PCV13-PPSV23 combo series. This option is blue because the decision is up to you and your patient.

Check the notes for more pneumococcal vaccination details. For example, for those partially vaccinated using lower valency vaccines, there’s an option of substituting PCV20 for PPSV23 to broaden and increase durability of protection.

The pneumococcal vaccination recommendation options are complicated. A new pneumococcal vaccination app can help.

Hepatitis B. For adults under age 60, the color code for the hepatitis B vaccine is yellow, meaning it’s indicated for all. For older patients, the color code is purple. If a patient who is age 60 or older wants the hepatitis B vaccine, they can have it even in the absence of additional risk indications.
 

Vaccinations by medical condition or other indications

Other than a few minor word changes on the overlay, the only thing that’s new is the COVID vaccine row.

This table is helpful for matching vaccine recommendations with specific medical conditions, including pregnancy, immunocompromise, HIV (with specifics according to CD4 count), asplenia, complement deficiencies, heart disease, lung disease, alcoholism, chronic liver disease, diabetes, health care personnel, and men who have sex with men.

Use this table to dot the i’s and cross the t’s when it comes to vaccination recommendations. For example, take a look at the pregnancy column. Live virus vaccines, including LAIV, MMR, and varicella, are contraindicated and color-coded red. MMR and varicella also have an asterisk, meaning vaccinate after pregnancy if indicated. HPV vaccines are not live virus vaccines, but the overlay says they are not recommended during pregnancy. The asterisk indicates that you can vaccinate after pregnancy.
 

Vaccine notes

The notes are in alphabetical order, and their organization (routine, special situations, and shared clinical decision-making when indicated) has not changed. They are concise and succinct, but sometimes they’re not enough. That’s why vaccine-specific links to more complete recommendations are so convenient.

Notes for hepatitis B contain nuances on specific dosing for vaccinating patients on dialysis, as well as a reminder that newer hepatitis C vaccines such as Heplisav and PreHevbrio are not recommended during pregnancy due to lack of safety data.

For influenza, everyone 6 months or older still needs yearly flu vaccination with an age- and health-appropriate flu vaccine. But for those aged 65 or older, the notes specify the three vaccine versions now preferred: high-dose, recombinant, or adjuvanted versions. However, if these aren’t available, it’s better to get any flu vaccine than to go without.

Under meningococcal vaccines, the notes for MenACWY and MenB are combined. For MenB, trade names Bexsero and Trumenba are specified because the products are not interchangeable. Booster intervals for those still at risk are different for each vaccine type: every 5 years for MenACWY boosters, and every 2-3 years for boosts of MenB.

The recent polio cases in New York have put polio vaccination in the spotlight. ACIP has now reinstated its Polio Vaccine Work Group. The new schedule lists polio vaccines on the cover page. Current recommendations have been added to the notes section. Routine vaccination for adults is not necessary, at least for now. However, those at increased risk for exposure to polio fall in the special-situation category. For those at increased risk who have completed a polio vaccine series, a single lifetime IPV booster can be given. For those at increased risk who have not completed their polio vaccine series, now would be the time to finish the series.
 

Appendix

The final step in using the new schedule is checking the appendix and its list of vaccine-specific contraindications and precautions.

I hope this review of the new ACIP adult immunization schedule has been helpful. For Medicine Matters, I’m Dr. Sandra Fryhofer.

Dr. Fryhofer is clinical associate professor of medicine, Emory University, Atlanta. She reported numerous conflicts of interest.

A version of this article first appeared on Medscape.com.

This transcript has been edited for clarity.

Hello. I’m Dr Sandra Fryhofer. Welcome to Medicine Matters. The topic is highlights from ACIP’s new adult schedule for 2023, published in the Annals of Internal Medicine, and why this new schedule may be a collector’s item.

It’s a new year, which means a new ACIP adult immunization schedule – a valuable resource collating ACIP’s most up-to-date vaccination recommendations.

Here are this year’s five most important changes:

• COVID vaccines now front and center
• New emphasis on polio vaccination
• Inclusion of some nonvaccine products (such as monoclonal antibody products)
• Pharmacists group has approved the schedule for the first time
• New shared clinical decision-making option for pneumococcal vaccines

The schedule’s organization remains the same. It still has four sections:

• Table 1: vaccinations by age
• Table 2: vaccinations by medical condition and other indications
• The Notes section (alphabetically ordered by vaccine type)
• Appendix listing of vaccine-specific contraindications and precautions

But what’s unique this year is that some of the abbreviations have historical implications. The first change is no big surprise in light of what we’ve gone through in the past few years. COVID vaccines are listed first on the cover page by brand name for those authorized and by company name for those still under US emergency use authorization. They’re also listed first on the graphics and in the notes.

COVID and mRNA and protein-based vaccines have now been assigned official abbreviations based on vaccine platform and valency.

• 1vCOV-mRNA: Comirnaty/Pfizer-BioNTech and Spikevax Moderna COVID-19 vaccines
• 2vCOV-mRNA: Pfizer-BioNTech and Moderna bivalent COVID-19 vaccines
• 1vCOV-aPS: Novavax COVID-19 vaccine

Also remarkable is the absence of COVID viral vector vaccines on the list. However, the viral vector COVID vaccine (which has been available but is not preferred) does have a CDC website link in the Notes section.

A sad but necessary inclusion was triggered by recent polio cases in New York. Polio was believed to be eradicated, and we thought adults no longer needed to be vaccinated against polio. In the new schedule, the polio vaccine is listed on the cover page but is not included in the tables. Current polio vaccination recommendations are now in the Notes section.

Also of historical significance and something that may set a precedent is the inclusion of nonvaccine products. The value of COVID preexposure prophylaxis with products including monoclonal antibodies (such as Evusheld) for people who are moderately or severely immunocompromised is mentioned in the Notes section.

For the first time ever, the schedule has been approved by the American Pharmacists Association, which validates pharmacists as established partners in vaccine administration.
 

Color-code key

One aspect of the schedule that has not changed is the color-code key:

• Yellow: Recommended if the patient meets the age requirement
• Purple: Indicated for those with additional risk factors or another indication
• Blue: Recommended based on shared clinical decision-making
• Orange: Precaution
• Red: Contraindicated or not recommended; the vaccine should not be administered. Overlays on the red more precisely clarify whether a vaccine is really contraindicated or just not recommended. An asterisk on red means vaccinate after pregnancy if indicated.
• Gray: No recommendation or not applicable

Vaccinations by age

Table 1 lists recommended vaccinations by age. There is one major change. COVID vaccines are on the first row of the graphic, with the need for both a primary series and boosters emphasized on the overlay. The notes have hyperlinks to the most up-to-date COVID vaccination recommendations.

Pneumococcal vaccination. Pneumococcal vaccination is routinely recommended starting at age 65. Current recommendations for those not previously vaccinated have not changed since last year. But on Table 1, the bottom half of the row for those 65 or older is now blue (and that’s new). This new color blue means shared clinical decision-making and applies to people who were previously considered fully vaccinated with the now extinct combination of PCV13 and PPSV23. These patients now have the option of getting a dose of PCV20 five years after completing their PCV13-PPSV23 combo series. This option is blue because the decision is up to you and your patient.

Check the notes for more pneumococcal vaccination details. For example, for those partially vaccinated using lower valency vaccines, there’s an option of substituting PCV20 for PPSV23 to broaden and increase durability of protection.

The pneumococcal vaccination recommendation options are complicated. A new pneumococcal vaccination app can help.

Hepatitis B. For adults under age 60, the color code for the hepatitis B vaccine is yellow, meaning it’s indicated for all. For older patients, the color code is purple. If a patient who is age 60 or older wants the hepatitis B vaccine, they can have it even in the absence of additional risk indications.
 

Vaccinations by medical condition or other indications

Other than a few minor word changes on the overlay, the only thing that’s new is the COVID vaccine row.

This table is helpful for matching vaccine recommendations with specific medical conditions, including pregnancy, immunocompromise, HIV (with specifics according to CD4 count), asplenia, complement deficiencies, heart disease, lung disease, alcoholism, chronic liver disease, diabetes, health care personnel, and men who have sex with men.

Use this table to dot the i’s and cross the t’s when it comes to vaccination recommendations. For example, take a look at the pregnancy column. Live virus vaccines, including LAIV, MMR, and varicella, are contraindicated and color-coded red. MMR and varicella also have an asterisk, meaning vaccinate after pregnancy if indicated. HPV vaccines are not live virus vaccines, but the overlay says they are not recommended during pregnancy. The asterisk indicates that you can vaccinate after pregnancy.
 

Vaccine notes

The notes are in alphabetical order, and their organization (routine, special situations, and shared clinical decision-making when indicated) has not changed. They are concise and succinct, but sometimes they’re not enough. That’s why vaccine-specific links to more complete recommendations are so convenient.

Notes for hepatitis B contain nuances on specific dosing for vaccinating patients on dialysis, as well as a reminder that newer hepatitis C vaccines such as Heplisav and PreHevbrio are not recommended during pregnancy due to lack of safety data.

For influenza, everyone 6 months or older still needs yearly flu vaccination with an age- and health-appropriate flu vaccine. But for those aged 65 or older, the notes specify the three vaccine versions now preferred: high-dose, recombinant, or adjuvanted versions. However, if these aren’t available, it’s better to get any flu vaccine than to go without.

Under meningococcal vaccines, the notes for MenACWY and MenB are combined. For MenB, trade names Bexsero and Trumenba are specified because the products are not interchangeable. Booster intervals for those still at risk are different for each vaccine type: every 5 years for MenACWY boosters, and every 2-3 years for boosts of MenB.

The recent polio cases in New York have put polio vaccination in the spotlight. ACIP has now reinstated its Polio Vaccine Work Group. The new schedule lists polio vaccines on the cover page. Current recommendations have been added to the notes section. Routine vaccination for adults is not necessary, at least for now. However, those at increased risk for exposure to polio fall in the special-situation category. For those at increased risk who have completed a polio vaccine series, a single lifetime IPV booster can be given. For those at increased risk who have not completed their polio vaccine series, now would be the time to finish the series.
 

Appendix

The final step in using the new schedule is checking the appendix and its list of vaccine-specific contraindications and precautions.

I hope this review of the new ACIP adult immunization schedule has been helpful. For Medicine Matters, I’m Dr. Sandra Fryhofer.

Dr. Fryhofer is clinical associate professor of medicine, Emory University, Atlanta. She reported numerous conflicts of interest.

A version of this article first appeared on Medscape.com.

The American Academy of Pediatrics said it supports the Recommended Childhood and Adolescent Immunization Schedule: United States, 2023.

In a policy statement published online in the journal Pediatrics, the AAP said the updated recommendations do not include major changes from those released in 2022 by the Advisory Committee on Immunization Practices of the Centers for Disease Control and Prevention.

In one small shift, COVID-19 is now addressed in the main text instead of being relegated to the notes section.

“And a new vaccine – Priorix [GlaxoSmithKline] – has been added for MMR [measles, mumps, rubella], so now there are two available,” Sean T. O’Leary, MD, MPH, chair of the AAP’s Committee on Infectious Diseases, told this news organization. “There’s also a second pneumococcal conjugate vaccine listed, PCV15, and this and PCV13 can essentially be used interchangeably.”

Minor updates to the schedule, reflected on the cover page, relate to vaccines for COVID-19, dengue fever, and pneumococcal disease, added Dr. O’Leary, a professor of pediatrics at the University of Colorado Anschutz Medical Campus and Children’s Hospital Colorado, Aurora.

The committee also changed layouts to improve the usability of the schedule. Updated annually, the guidance provides a table on recommended pediatric immunizations from birth to age 18 years, and catch-up recommendations for children aged 4 months to 18 years who start their vaccinations late or are more than 1 month behind the recommended age for vaccine administration.

“We hope this annual update will encourage clinicians to make sure all their patients are up to date on their routine vaccinations,” Dr. O’Leary said. “It’s an opportunity to develop strategies to improve vaccination rates.”

The 2023 schedule follows news from the CDC that kindergarten vaccination rates declined during the 2021-2022 school year. Only 93% of kindergarteners obtained full vaccinations, representing a drop of 1 percentage point from the year before and 2 percentage points from the 2019-2020 school year.

The dip in coverage has been attributed to disruptions caused by the COVID-19 pandemic. AAP advises health care professionals to urge families to make sure their child’s vaccines are current.

Among other additions:
 

In Table 1

• MMR: Second vaccine added (Priorix, GlaxoSmithKline Biologicals)
• Pneumococcal disease: second conjugate vaccine, PCV15, added (Vaxneuvance, Merck Sharp & Dohme).
• COVID-19: New row added.
• Dengue: Text changed from “Seropositive in endemic areas only” to “Seropositive in endemic dengue areas.”
• Inactivated polio vaccine: “See Notes” added to the column for children aged 18 years.

In Table 2

• PCV: Dose 3 to dose 4 interval revised to align with ACIP’s recommendation for dose 4. This dose is necessary only for children ages 12-59 months regardless of risk, or age 60-71 months with any risk who received three doses before age 12 months.

A parent-friendly vaccine schedule for children and adolescents is available on the CDC’s website.

“Vaccines are essential for the health of our whole society, including children and adolescents,” Dr. O’Leary said in a press release from AAP. “These schedules provide a road map [that] parents and pediatricians can follow to help children get the vaccines they need so their immune systems will be ready to recognize and resist diseases.”

As previously, the 2023 schedule was adjusted to ensure consistency between the formats of the childhood/adolescent and adult immunization guidance. A meeting of stakeholder organizations in October 2022 harmonized the two formats.

A version of this article first appeared on Medscape.com.

The American Academy of Pediatrics said it supports the Recommended Childhood and Adolescent Immunization Schedule: United States, 2023.

In a policy statement published online in the journal Pediatrics, the AAP said the updated recommendations do not include major changes from those released in 2022 by the Advisory Committee on Immunization Practices of the Centers for Disease Control and Prevention.

In one small shift, COVID-19 is now addressed in the main text instead of being relegated to the notes section.

“And a new vaccine – Priorix [GlaxoSmithKline] – has been added for MMR [measles, mumps, rubella], so now there are two available,” Sean T. O’Leary, MD, MPH, chair of the AAP’s Committee on Infectious Diseases, told this news organization. “There’s also a second pneumococcal conjugate vaccine listed, PCV15, and this and PCV13 can essentially be used interchangeably.”

Minor updates to the schedule, reflected on the cover page, relate to vaccines for COVID-19, dengue fever, and pneumococcal disease, added Dr. O’Leary, a professor of pediatrics at the University of Colorado Anschutz Medical Campus and Children’s Hospital Colorado, Aurora.

The committee also changed layouts to improve the usability of the schedule. Updated annually, the guidance provides a table on recommended pediatric immunizations from birth to age 18 years, and catch-up recommendations for children aged 4 months to 18 years who start their vaccinations late or are more than 1 month behind the recommended age for vaccine administration.

“We hope this annual update will encourage clinicians to make sure all their patients are up to date on their routine vaccinations,” Dr. O’Leary said. “It’s an opportunity to develop strategies to improve vaccination rates.”

The 2023 schedule follows news from the CDC that kindergarten vaccination rates declined during the 2021-2022 school year. Only 93% of kindergarteners obtained full vaccinations, representing a drop of 1 percentage point from the year before and 2 percentage points from the 2019-2020 school year.

The dip in coverage has been attributed to disruptions caused by the COVID-19 pandemic. AAP advises health care professionals to urge families to make sure their child’s vaccines are current.

Among other additions:
 

In Table 1

• MMR: Second vaccine added (Priorix, GlaxoSmithKline Biologicals)
• Pneumococcal disease: second conjugate vaccine, PCV15, added (Vaxneuvance, Merck Sharp & Dohme).
• COVID-19: New row added.
• Dengue: Text changed from “Seropositive in endemic areas only” to “Seropositive in endemic dengue areas.”
• Inactivated polio vaccine: “See Notes” added to the column for children aged 18 years.

In Table 2

• PCV: Dose 3 to dose 4 interval revised to align with ACIP’s recommendation for dose 4. This dose is necessary only for children ages 12-59 months regardless of risk, or age 60-71 months with any risk who received three doses before age 12 months.

A parent-friendly vaccine schedule for children and adolescents is available on the CDC’s website.

“Vaccines are essential for the health of our whole society, including children and adolescents,” Dr. O’Leary said in a press release from AAP. “These schedules provide a road map [that] parents and pediatricians can follow to help children get the vaccines they need so their immune systems will be ready to recognize and resist diseases.”

As previously, the 2023 schedule was adjusted to ensure consistency between the formats of the childhood/adolescent and adult immunization guidance. A meeting of stakeholder organizations in October 2022 harmonized the two formats.

A version of this article first appeared on Medscape.com.

The American Academy of Pediatrics said it supports the Recommended Childhood and Adolescent Immunization Schedule: United States, 2023.

In a policy statement published online in the journal Pediatrics, the AAP said the updated recommendations do not include major changes from those released in 2022 by the Advisory Committee on Immunization Practices of the Centers for Disease Control and Prevention.

In one small shift, COVID-19 is now addressed in the main text instead of being relegated to the notes section.

“And a new vaccine – Priorix [GlaxoSmithKline] – has been added for MMR [measles, mumps, rubella], so now there are two available,” Sean T. O’Leary, MD, MPH, chair of the AAP’s Committee on Infectious Diseases, told this news organization. “There’s also a second pneumococcal conjugate vaccine listed, PCV15, and this and PCV13 can essentially be used interchangeably.”

Minor updates to the schedule, reflected on the cover page, relate to vaccines for COVID-19, dengue fever, and pneumococcal disease, added Dr. O’Leary, a professor of pediatrics at the University of Colorado Anschutz Medical Campus and Children’s Hospital Colorado, Aurora.

The committee also changed layouts to improve the usability of the schedule. Updated annually, the guidance provides a table on recommended pediatric immunizations from birth to age 18 years, and catch-up recommendations for children aged 4 months to 18 years who start their vaccinations late or are more than 1 month behind the recommended age for vaccine administration.

“We hope this annual update will encourage clinicians to make sure all their patients are up to date on their routine vaccinations,” Dr. O’Leary said. “It’s an opportunity to develop strategies to improve vaccination rates.”

The 2023 schedule follows news from the CDC that kindergarten vaccination rates declined during the 2021-2022 school year. Only 93% of kindergarteners obtained full vaccinations, representing a drop of 1 percentage point from the year before and 2 percentage points from the 2019-2020 school year.

The dip in coverage has been attributed to disruptions caused by the COVID-19 pandemic. AAP advises health care professionals to urge families to make sure their child’s vaccines are current.

Among other additions:
 

In Table 1

• MMR: Second vaccine added (Priorix, GlaxoSmithKline Biologicals)
• Pneumococcal disease: second conjugate vaccine, PCV15, added (Vaxneuvance, Merck Sharp & Dohme).
• COVID-19: New row added.
• Dengue: Text changed from “Seropositive in endemic areas only” to “Seropositive in endemic dengue areas.”
• Inactivated polio vaccine: “See Notes” added to the column for children aged 18 years.

In Table 2

• PCV: Dose 3 to dose 4 interval revised to align with ACIP’s recommendation for dose 4. This dose is necessary only for children ages 12-59 months regardless of risk, or age 60-71 months with any risk who received three doses before age 12 months.

A parent-friendly vaccine schedule for children and adolescents is available on the CDC’s website.

“Vaccines are essential for the health of our whole society, including children and adolescents,” Dr. O’Leary said in a press release from AAP. “These schedules provide a road map [that] parents and pediatricians can follow to help children get the vaccines they need so their immune systems will be ready to recognize and resist diseases.”

As previously, the 2023 schedule was adjusted to ensure consistency between the formats of the childhood/adolescent and adult immunization guidance. A meeting of stakeholder organizations in October 2022 harmonized the two formats.

A version of this article first appeared on Medscape.com.

About half a million children between the ages of 1 and 3 years old have ear tube surgery in the United States every year at an annual cost exceeding $2 billion. It is the most common childhood surgery performed with anesthesia. It is a surgery commonly performed on children in most other high- and middle-income countries.

My group recently published a paper on the timing and necessity of tympanostomy tubes for recurrent otitis media in young children. The primary objective was to quantitatively examine recurrent acute otitis media (AOM) incidence with respect to age of occurrence, the influence of daycare attendance, and other risk factors in individual children. We introduced the concept of a “window of susceptibility” to AOM as new terminology referring to a child who has two or more closely spaced AOM occurrences during a window of time. We sought to know what to expect and how to advise the parent when a child presents with closely spaced AOMs.

A secondary objective was to develop models to predict the risk and timing of AOM recurrences based on the natural history of disease in young children who do not get tympanostomy tubes. Prediction models were developed to assist clinicians in understanding and explaining to parents the benefit of tympanostomy tubes based on the child’s age and number of AOMs.

The children were all from a primary care pediatric practice in Rochester, N.Y., which comprised a typical mixed demographic of largely middle-class, health care–insured families that was broadly representative of the racial/ethnic diversity in the community. The sample included both wealthy families and those living below the poverty line. The diagnosis of AOM was made based on the American Academy of Pediatrics guidance in which a presumed middle ear effusion and a full or bulging tympanic membrane were required. Almost all episodes (> 85%) of clinically diagnosed AOM cases were confirmed by culture of middle ear fluid collected by tympanocentesis to ensure diagnostic accuracy.

286 children who had ear infections were studied. We found that 80% of ear infections occurred during a very narrow window of susceptibility – age 6-21 months. About 72% of children had a window of susceptibility to ear infections that lasted 5 months or less; 97% of children had a window of susceptibility that lasted 10 months or less.

From this result, we observed that about 90% of children have a window of time lasting about 10 months when they get repeated ear infections. By the time a child gets three ear infections in 6 months (a period of time recommended by the AAP and American Academy of Otolaryngology–Head and Neck Surgery when ear tubes might be considered) and then a referral for ear tubes is made and the child gets an appointment with the ear, nose, and throat doctor, and surgery is scheduled, the ear infections were going to stop anyway.

In other words, millions of children worldwide have been getting ear tubes and physicians and parents saw that the ear infections stopped. So they concluded the ear tubes stopped the infections. We found the infections were going to stop anyway even if the child did not receive ear tubes because their susceptibility to ear infections is over by the time the surgery is performed. The child outgrew ear infections.

An exception was children in daycare at an early age. Our study found that children in daycare who are around 6 months old and start getting ear infections at that age are likely destined to have three or more ear infections in the first year of life. If children are going to be in daycare, perhaps those who need them should receive ear tubes early. Analysis of other demographic and risk factor covariates – sex, race/ethnicity, breastfeeding, siblings in the home, smoking in the home, atopy, and family history of otitis media – were not significantly associated with the number of AOMs in the child population we studied.

We developed a prediction model for doctors, so they could input a child’s age, number of ear infections, and daycare attendance and receive back an estimate of the number of likely future ear infections for that child. With that knowledge, physicians and parents can make more informed decisions.

Our message to clinicians and parents is to reconsider the necessity and timing of ear tube surgery for children with recurrent ear infections because the future is not predicted by the past. Children having several ear infections in a short time does not predict that they will have a similar number of ear infections in the future.

The study was supported by the National Institutes of Health awarded to Rochester Regional Health. Dr. Pichichero was principal investigator for the award.

Dr. Pichichero is a specialist in pediatric infectious diseases, Center for Infectious Diseases and Immunology, and director of the Research Institute, at Rochester (N.Y.) General Hospital. He has no conflicts of interest to declare.

About half a million children between the ages of 1 and 3 years old have ear tube surgery in the United States every year at an annual cost exceeding $2 billion. It is the most common childhood surgery performed with anesthesia. It is a surgery commonly performed on children in most other high- and middle-income countries.

My group recently published a paper on the timing and necessity of tympanostomy tubes for recurrent otitis media in young children. The primary objective was to quantitatively examine recurrent acute otitis media (AOM) incidence with respect to age of occurrence, the influence of daycare attendance, and other risk factors in individual children. We introduced the concept of a “window of susceptibility” to AOM as new terminology referring to a child who has two or more closely spaced AOM occurrences during a window of time. We sought to know what to expect and how to advise the parent when a child presents with closely spaced AOMs.

A secondary objective was to develop models to predict the risk and timing of AOM recurrences based on the natural history of disease in young children who do not get tympanostomy tubes. Prediction models were developed to assist clinicians in understanding and explaining to parents the benefit of tympanostomy tubes based on the child’s age and number of AOMs.

The children were all from a primary care pediatric practice in Rochester, N.Y., which comprised a typical mixed demographic of largely middle-class, health care–insured families that was broadly representative of the racial/ethnic diversity in the community. The sample included both wealthy families and those living below the poverty line. The diagnosis of AOM was made based on the American Academy of Pediatrics guidance in which a presumed middle ear effusion and a full or bulging tympanic membrane were required. Almost all episodes (> 85%) of clinically diagnosed AOM cases were confirmed by culture of middle ear fluid collected by tympanocentesis to ensure diagnostic accuracy.

286 children who had ear infections were studied. We found that 80% of ear infections occurred during a very narrow window of susceptibility – age 6-21 months. About 72% of children had a window of susceptibility to ear infections that lasted 5 months or less; 97% of children had a window of susceptibility that lasted 10 months or less.

From this result, we observed that about 90% of children have a window of time lasting about 10 months when they get repeated ear infections. By the time a child gets three ear infections in 6 months (a period of time recommended by the AAP and American Academy of Otolaryngology–Head and Neck Surgery when ear tubes might be considered) and then a referral for ear tubes is made and the child gets an appointment with the ear, nose, and throat doctor, and surgery is scheduled, the ear infections were going to stop anyway.

In other words, millions of children worldwide have been getting ear tubes and physicians and parents saw that the ear infections stopped. So they concluded the ear tubes stopped the infections. We found the infections were going to stop anyway even if the child did not receive ear tubes because their susceptibility to ear infections is over by the time the surgery is performed. The child outgrew ear infections.

An exception was children in daycare at an early age. Our study found that children in daycare who are around 6 months old and start getting ear infections at that age are likely destined to have three or more ear infections in the first year of life. If children are going to be in daycare, perhaps those who need them should receive ear tubes early. Analysis of other demographic and risk factor covariates – sex, race/ethnicity, breastfeeding, siblings in the home, smoking in the home, atopy, and family history of otitis media – were not significantly associated with the number of AOMs in the child population we studied.

We developed a prediction model for doctors, so they could input a child’s age, number of ear infections, and daycare attendance and receive back an estimate of the number of likely future ear infections for that child. With that knowledge, physicians and parents can make more informed decisions.

Our message to clinicians and parents is to reconsider the necessity and timing of ear tube surgery for children with recurrent ear infections because the future is not predicted by the past. Children having several ear infections in a short time does not predict that they will have a similar number of ear infections in the future.

The study was supported by the National Institutes of Health awarded to Rochester Regional Health. Dr. Pichichero was principal investigator for the award.

Dr. Pichichero is a specialist in pediatric infectious diseases, Center for Infectious Diseases and Immunology, and director of the Research Institute, at Rochester (N.Y.) General Hospital. He has no conflicts of interest to declare.

About half a million children between the ages of 1 and 3 years old have ear tube surgery in the United States every year at an annual cost exceeding $2 billion. It is the most common childhood surgery performed with anesthesia. It is a surgery commonly performed on children in most other high- and middle-income countries.

My group recently published a paper on the timing and necessity of tympanostomy tubes for recurrent otitis media in young children. The primary objective was to quantitatively examine recurrent acute otitis media (AOM) incidence with respect to age of occurrence, the influence of daycare attendance, and other risk factors in individual children. We introduced the concept of a “window of susceptibility” to AOM as new terminology referring to a child who has two or more closely spaced AOM occurrences during a window of time. We sought to know what to expect and how to advise the parent when a child presents with closely spaced AOMs.

A secondary objective was to develop models to predict the risk and timing of AOM recurrences based on the natural history of disease in young children who do not get tympanostomy tubes. Prediction models were developed to assist clinicians in understanding and explaining to parents the benefit of tympanostomy tubes based on the child’s age and number of AOMs.

The children were all from a primary care pediatric practice in Rochester, N.Y., which comprised a typical mixed demographic of largely middle-class, health care–insured families that was broadly representative of the racial/ethnic diversity in the community. The sample included both wealthy families and those living below the poverty line. The diagnosis of AOM was made based on the American Academy of Pediatrics guidance in which a presumed middle ear effusion and a full or bulging tympanic membrane were required. Almost all episodes (> 85%) of clinically diagnosed AOM cases were confirmed by culture of middle ear fluid collected by tympanocentesis to ensure diagnostic accuracy.

286 children who had ear infections were studied. We found that 80% of ear infections occurred during a very narrow window of susceptibility – age 6-21 months. About 72% of children had a window of susceptibility to ear infections that lasted 5 months or less; 97% of children had a window of susceptibility that lasted 10 months or less.

From this result, we observed that about 90% of children have a window of time lasting about 10 months when they get repeated ear infections. By the time a child gets three ear infections in 6 months (a period of time recommended by the AAP and American Academy of Otolaryngology–Head and Neck Surgery when ear tubes might be considered) and then a referral for ear tubes is made and the child gets an appointment with the ear, nose, and throat doctor, and surgery is scheduled, the ear infections were going to stop anyway.

In other words, millions of children worldwide have been getting ear tubes and physicians and parents saw that the ear infections stopped. So they concluded the ear tubes stopped the infections. We found the infections were going to stop anyway even if the child did not receive ear tubes because their susceptibility to ear infections is over by the time the surgery is performed. The child outgrew ear infections.

An exception was children in daycare at an early age. Our study found that children in daycare who are around 6 months old and start getting ear infections at that age are likely destined to have three or more ear infections in the first year of life. If children are going to be in daycare, perhaps those who need them should receive ear tubes early. Analysis of other demographic and risk factor covariates – sex, race/ethnicity, breastfeeding, siblings in the home, smoking in the home, atopy, and family history of otitis media – were not significantly associated with the number of AOMs in the child population we studied.

We developed a prediction model for doctors, so they could input a child’s age, number of ear infections, and daycare attendance and receive back an estimate of the number of likely future ear infections for that child. With that knowledge, physicians and parents can make more informed decisions.

Our message to clinicians and parents is to reconsider the necessity and timing of ear tube surgery for children with recurrent ear infections because the future is not predicted by the past. Children having several ear infections in a short time does not predict that they will have a similar number of ear infections in the future.

The study was supported by the National Institutes of Health awarded to Rochester Regional Health. Dr. Pichichero was principal investigator for the award.

Dr. Pichichero is a specialist in pediatric infectious diseases, Center for Infectious Diseases and Immunology, and director of the Research Institute, at Rochester (N.Y.) General Hospital. He has no conflicts of interest to declare.

This transcript has been edited for clarity.

Welcome to Impact Factor, your weekly dose of commentary on a new medical study. I’m Dr F. Perry Wilson of the Yale School of Medicine.

With SARS-CoV-2 sidestepping monoclonal antibodies faster than a Texas square dance, the need for new therapeutic options to treat – not prevent – COVID-19 is becoming more and more dire.

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

Dr. Perry Wilson is associate professor, department of medicine, and director, Clinical and Translational Research Accelerator, at Yale University, New Haven, Conn. He disclosed no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

This transcript has been edited for clarity.

Welcome to Impact Factor, your weekly dose of commentary on a new medical study. I’m Dr F. Perry Wilson of the Yale School of Medicine.

With SARS-CoV-2 sidestepping monoclonal antibodies faster than a Texas square dance, the need for new therapeutic options to treat – not prevent – COVID-19 is becoming more and more dire.

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

Dr. Perry Wilson is associate professor, department of medicine, and director, Clinical and Translational Research Accelerator, at Yale University, New Haven, Conn. He disclosed no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

This transcript has been edited for clarity.

Welcome to Impact Factor, your weekly dose of commentary on a new medical study. I’m Dr F. Perry Wilson of the Yale School of Medicine.

With SARS-CoV-2 sidestepping monoclonal antibodies faster than a Texas square dance, the need for new therapeutic options to treat – not prevent – COVID-19 is becoming more and more dire.

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy Dr. F. Perry Wilson

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

courtesy of the New England Journal of Medicine

Dr. Perry Wilson is associate professor, department of medicine, and director, Clinical and Translational Research Accelerator, at Yale University, New Haven, Conn. He disclosed no relevant conflicts of interest.

A version of this article first appeared on Medscape.com.

Pound of flesh buys less prison time

We should all have more Shakespeare in our lives. Yeah, yeah, Shakespeare is meant to be played, not read, and it can be a struggle to herd teenagers through the Bard’s interesting and bloody tragedies, but even a perfunctory reading of “The Merchant of Venice” would hopefully have prevented the dystopian nightmare Massachusetts has presented us with today.

Ye Jinghan/Unsplash

The United States has a massive shortage of donor organs. This is an unfortunate truth. So, to combat this issue, a pair of Massachusetts congresspeople have proposed HD 3822, which would allow prisoners to donate organs and/or bone marrow (a pound of flesh, so to speak) in exchange for up to a year in reduced prison time. Yes, that’s right. Give up pieces of yourself and the state of Massachusetts will deign to reduce your long prison sentence.

Oh, and before you dismiss this as typical Republican antics, the bill was sponsored by two Democrats, and in a statement one of them hoped to address racial disparities in organ donation, as people of color are much less likely to receive organs. Never mind that Black people are imprisoned at a much higher rate than Whites.

Yeah, this whole thing is what people in the business like to call an ethical disaster.

Fortunately, the bill will likely never be passed and it’s probably illegal anyway. A federal law from 1984 (how’s that for a coincidence) prevents people from donating organs for use in human transplantation in exchange for “valuable consideration.” In other words, you can’t sell your organs for profit, and in this case, reducing prison time would probably count as valuable consideration in the eyes of the courts.

Oh, and in case you’ve never read Merchant of Venice, Shylock, the character looking for the pound of flesh as payment for a debt? He’s the villain. In fact, it’s pretty safe to say that anyone looking to extract payment from human dismemberment is probably the bad guy of the story. Apparently that wasn’t clear.
 

How do you stop a fungi? With a deadly guy

Thanks to the new HBO series “The Last of Us,” there’s been a lot of talk about the upcoming fungi-pocalypse, as the show depicts the real-life “zombie fungus” Cordyceps turning humans into, you know, zombies.

Liane Hentscher/HBO

No need to worry, ladies and gentleman, because science has discovered a way to turn back the fungal horde. A heroic, and environmentally friendly, alternative to chemical pesticides “in the fight against resistant fungi [that] are now resistant to antimycotics – partly because they are used in large quantities in agricultural fields,” investigators at the Leibniz Institute for Natural Product Research and Infection Biology in Jena, Germany, said in a written statement.

We are, of course, talking about Keanu Reeves. Wait a second. He’s not even in “The Last of Us.” Sorry folks, we are being told that it really is Keanu Reeves. Our champion in the inevitable fungal pandemic is movie star Keanu Reeves. Sort of. It’s actually keanumycin, a substance produced by bacteria of the genus Pseudomonas.

Really? Keanumycin? “The lipopeptides kill so efficiently that we named them after Keanu Reeves because he, too, is extremely deadly in his roles,” lead author Sebastian Götze, PhD, explained.

Dr. Götze and his associates had been working with pseudomonads for quite a while before they were able to isolate the toxins responsible for their ability to kill amoebae, which resemble fungi in some characteristics. When then finally tried the keanumycin against gray mold rot on hydrangea leaves, the intensely contemplative star of “The Matrix” and “John Wick” – sorry, wrong Keanu – the bacterial derivative significantly inhibited growth of the fungus, they said.

Additional testing has shown that keanumycin is not highly toxic to human cells and is effective against fungi such as Candida albicans in very low concentrations, which makes it a good candidate for future pharmaceutical development.

To that news there can be only one response from the substance’s namesake.

High fat, bye parasites

Fat. Fat. Fat. Seems like everyone is trying to avoid it these days, but fat may be good thing when it comes to weaseling out a parasite.

The parasite in this case is the whipworm, aka Trichuris trichiura. You can find this guy in the intestines of millions of people, where it causes long-lasting infections. Yikes … Researchers have found that the plan of attack to get rid of this invasive species is to boost the immune system, but instead of vitamin C and zinc it’s fat they’re pumping in. Yes, fat.

John Worthington

The developing countries with poor sewage that are at the highest risk for contracting parasites such as this also are among those where people ingest cheaper diets that are generally higher in fat. The investigators were interested to see how a high-fat diet would affect immune responses to the whipworms.

And, as with almost everything else, the researchers turned to mice, which were introduced to a closely related species, Trichuris muris.

A high-fat diet, rather than obesity itself, increases a molecule on T-helper cells called ST2, and this allows an increased T-helper 2 response, effectively giving eviction notices to the parasites in the intestinal lining.

To say the least, the researchers were surprised since “high-fat diets are mostly associated with increased pathology during disease,” said senior author Richard Grencis, PhD, of the University of Manchester (England), who noted that ST2 is not normally triggered with a standard diet in mice but the high-fat diet gave it a boost and an “alternate pathway” out.

Now before you start ordering extra-large fries at the drive-through to keep the whipworms away, the researchers added that they “have previously published that weight loss can aid the expulsion of a different gut parasite worm.” Figures.

Once again, though, signs are pointing to the gut for improved health.

Pound of flesh buys less prison time

We should all have more Shakespeare in our lives. Yeah, yeah, Shakespeare is meant to be played, not read, and it can be a struggle to herd teenagers through the Bard’s interesting and bloody tragedies, but even a perfunctory reading of “The Merchant of Venice” would hopefully have prevented the dystopian nightmare Massachusetts has presented us with today.

Ye Jinghan/Unsplash

The United States has a massive shortage of donor organs. This is an unfortunate truth. So, to combat this issue, a pair of Massachusetts congresspeople have proposed HD 3822, which would allow prisoners to donate organs and/or bone marrow (a pound of flesh, so to speak) in exchange for up to a year in reduced prison time. Yes, that’s right. Give up pieces of yourself and the state of Massachusetts will deign to reduce your long prison sentence.

Oh, and before you dismiss this as typical Republican antics, the bill was sponsored by two Democrats, and in a statement one of them hoped to address racial disparities in organ donation, as people of color are much less likely to receive organs. Never mind that Black people are imprisoned at a much higher rate than Whites.

Yeah, this whole thing is what people in the business like to call an ethical disaster.

Fortunately, the bill will likely never be passed and it’s probably illegal anyway. A federal law from 1984 (how’s that for a coincidence) prevents people from donating organs for use in human transplantation in exchange for “valuable consideration.” In other words, you can’t sell your organs for profit, and in this case, reducing prison time would probably count as valuable consideration in the eyes of the courts.

Oh, and in case you’ve never read Merchant of Venice, Shylock, the character looking for the pound of flesh as payment for a debt? He’s the villain. In fact, it’s pretty safe to say that anyone looking to extract payment from human dismemberment is probably the bad guy of the story. Apparently that wasn’t clear.
 

How do you stop a fungi? With a deadly guy

Thanks to the new HBO series “The Last of Us,” there’s been a lot of talk about the upcoming fungi-pocalypse, as the show depicts the real-life “zombie fungus” Cordyceps turning humans into, you know, zombies.

Liane Hentscher/HBO

No need to worry, ladies and gentleman, because science has discovered a way to turn back the fungal horde. A heroic, and environmentally friendly, alternative to chemical pesticides “in the fight against resistant fungi [that] are now resistant to antimycotics – partly because they are used in large quantities in agricultural fields,” investigators at the Leibniz Institute for Natural Product Research and Infection Biology in Jena, Germany, said in a written statement.

We are, of course, talking about Keanu Reeves. Wait a second. He’s not even in “The Last of Us.” Sorry folks, we are being told that it really is Keanu Reeves. Our champion in the inevitable fungal pandemic is movie star Keanu Reeves. Sort of. It’s actually keanumycin, a substance produced by bacteria of the genus Pseudomonas.

Really? Keanumycin? “The lipopeptides kill so efficiently that we named them after Keanu Reeves because he, too, is extremely deadly in his roles,” lead author Sebastian Götze, PhD, explained.

Dr. Götze and his associates had been working with pseudomonads for quite a while before they were able to isolate the toxins responsible for their ability to kill amoebae, which resemble fungi in some characteristics. When then finally tried the keanumycin against gray mold rot on hydrangea leaves, the intensely contemplative star of “The Matrix” and “John Wick” – sorry, wrong Keanu – the bacterial derivative significantly inhibited growth of the fungus, they said.

Additional testing has shown that keanumycin is not highly toxic to human cells and is effective against fungi such as Candida albicans in very low concentrations, which makes it a good candidate for future pharmaceutical development.

To that news there can be only one response from the substance’s namesake.

High fat, bye parasites

Fat. Fat. Fat. Seems like everyone is trying to avoid it these days, but fat may be good thing when it comes to weaseling out a parasite.

The parasite in this case is the whipworm, aka Trichuris trichiura. You can find this guy in the intestines of millions of people, where it causes long-lasting infections. Yikes … Researchers have found that the plan of attack to get rid of this invasive species is to boost the immune system, but instead of vitamin C and zinc it’s fat they’re pumping in. Yes, fat.

John Worthington

The developing countries with poor sewage that are at the highest risk for contracting parasites such as this also are among those where people ingest cheaper diets that are generally higher in fat. The investigators were interested to see how a high-fat diet would affect immune responses to the whipworms.

And, as with almost everything else, the researchers turned to mice, which were introduced to a closely related species, Trichuris muris.

A high-fat diet, rather than obesity itself, increases a molecule on T-helper cells called ST2, and this allows an increased T-helper 2 response, effectively giving eviction notices to the parasites in the intestinal lining.

To say the least, the researchers were surprised since “high-fat diets are mostly associated with increased pathology during disease,” said senior author Richard Grencis, PhD, of the University of Manchester (England), who noted that ST2 is not normally triggered with a standard diet in mice but the high-fat diet gave it a boost and an “alternate pathway” out.

Now before you start ordering extra-large fries at the drive-through to keep the whipworms away, the researchers added that they “have previously published that weight loss can aid the expulsion of a different gut parasite worm.” Figures.

Once again, though, signs are pointing to the gut for improved health.

Pound of flesh buys less prison time

We should all have more Shakespeare in our lives. Yeah, yeah, Shakespeare is meant to be played, not read, and it can be a struggle to herd teenagers through the Bard’s interesting and bloody tragedies, but even a perfunctory reading of “The Merchant of Venice” would hopefully have prevented the dystopian nightmare Massachusetts has presented us with today.

Ye Jinghan/Unsplash

The United States has a massive shortage of donor organs. This is an unfortunate truth. So, to combat this issue, a pair of Massachusetts congresspeople have proposed HD 3822, which would allow prisoners to donate organs and/or bone marrow (a pound of flesh, so to speak) in exchange for up to a year in reduced prison time. Yes, that’s right. Give up pieces of yourself and the state of Massachusetts will deign to reduce your long prison sentence.

Oh, and before you dismiss this as typical Republican antics, the bill was sponsored by two Democrats, and in a statement one of them hoped to address racial disparities in organ donation, as people of color are much less likely to receive organs. Never mind that Black people are imprisoned at a much higher rate than Whites.

Yeah, this whole thing is what people in the business like to call an ethical disaster.

Fortunately, the bill will likely never be passed and it’s probably illegal anyway. A federal law from 1984 (how’s that for a coincidence) prevents people from donating organs for use in human transplantation in exchange for “valuable consideration.” In other words, you can’t sell your organs for profit, and in this case, reducing prison time would probably count as valuable consideration in the eyes of the courts.

Oh, and in case you’ve never read Merchant of Venice, Shylock, the character looking for the pound of flesh as payment for a debt? He’s the villain. In fact, it’s pretty safe to say that anyone looking to extract payment from human dismemberment is probably the bad guy of the story. Apparently that wasn’t clear.
 

How do you stop a fungi? With a deadly guy

Thanks to the new HBO series “The Last of Us,” there’s been a lot of talk about the upcoming fungi-pocalypse, as the show depicts the real-life “zombie fungus” Cordyceps turning humans into, you know, zombies.

Liane Hentscher/HBO

No need to worry, ladies and gentleman, because science has discovered a way to turn back the fungal horde. A heroic, and environmentally friendly, alternative to chemical pesticides “in the fight against resistant fungi [that] are now resistant to antimycotics – partly because they are used in large quantities in agricultural fields,” investigators at the Leibniz Institute for Natural Product Research and Infection Biology in Jena, Germany, said in a written statement.

We are, of course, talking about Keanu Reeves. Wait a second. He’s not even in “The Last of Us.” Sorry folks, we are being told that it really is Keanu Reeves. Our champion in the inevitable fungal pandemic is movie star Keanu Reeves. Sort of. It’s actually keanumycin, a substance produced by bacteria of the genus Pseudomonas.

Really? Keanumycin? “The lipopeptides kill so efficiently that we named them after Keanu Reeves because he, too, is extremely deadly in his roles,” lead author Sebastian Götze, PhD, explained.

Dr. Götze and his associates had been working with pseudomonads for quite a while before they were able to isolate the toxins responsible for their ability to kill amoebae, which resemble fungi in some characteristics. When then finally tried the keanumycin against gray mold rot on hydrangea leaves, the intensely contemplative star of “The Matrix” and “John Wick” – sorry, wrong Keanu – the bacterial derivative significantly inhibited growth of the fungus, they said.

Additional testing has shown that keanumycin is not highly toxic to human cells and is effective against fungi such as Candida albicans in very low concentrations, which makes it a good candidate for future pharmaceutical development.

To that news there can be only one response from the substance’s namesake.

High fat, bye parasites

Fat. Fat. Fat. Seems like everyone is trying to avoid it these days, but fat may be good thing when it comes to weaseling out a parasite.

The parasite in this case is the whipworm, aka Trichuris trichiura. You can find this guy in the intestines of millions of people, where it causes long-lasting infections. Yikes … Researchers have found that the plan of attack to get rid of this invasive species is to boost the immune system, but instead of vitamin C and zinc it’s fat they’re pumping in. Yes, fat.

John Worthington

The developing countries with poor sewage that are at the highest risk for contracting parasites such as this also are among those where people ingest cheaper diets that are generally higher in fat. The investigators were interested to see how a high-fat diet would affect immune responses to the whipworms.

And, as with almost everything else, the researchers turned to mice, which were introduced to a closely related species, Trichuris muris.

A high-fat diet, rather than obesity itself, increases a molecule on T-helper cells called ST2, and this allows an increased T-helper 2 response, effectively giving eviction notices to the parasites in the intestinal lining.

To say the least, the researchers were surprised since “high-fat diets are mostly associated with increased pathology during disease,” said senior author Richard Grencis, PhD, of the University of Manchester (England), who noted that ST2 is not normally triggered with a standard diet in mice but the high-fat diet gave it a boost and an “alternate pathway” out.

Now before you start ordering extra-large fries at the drive-through to keep the whipworms away, the researchers added that they “have previously published that weight loss can aid the expulsion of a different gut parasite worm.” Figures.

Once again, though, signs are pointing to the gut for improved health.

Maternal vaccination with two doses of the mRNA COVID-19 vaccine was 95% effective against infant infection from the delta variant, and 45% effective against infant infection from the omicron variant, a new study shows.

Previous research has confirmed that COVID-19 neutralizing antibodies following maternal vaccination or maternal COVID-19 infection are present in umbilical cord blood, breast milk, and infant serum specimens, wrote Sarah C.J. Jorgensen, PharmD, MPH, of the University of Toronto, and colleagues in their article published in The BMJ.

In the study, the researchers identified maternal and newborn pairs using administrative databases from Canada. The study population included 8,809 infants aged younger than 6 months who were born between May 7, 2021, and March 31, 2022, and who underwent testing for COVID-19 between May 7, 2021, and September 5, 2022.

Maternal vaccination with the primary COVID-19 mRNA monovalent vaccine series was defined as two vaccine doses administered up to 14 days before delivery, with at least one of the doses after the conception date.

Maternal vaccination with the primary series plus one booster was defined as three doses administered up to 14 days before delivery, with at least one of these doses after the conception date.

The primary outcome was the presence of delta or omicron COVID-19 infection or hospital admission of the infants.

The study population included 99 COVID-19 cases with the delta variant (with 4,365 controls) and 1,501 cases with the omicron variant (with 4,847 controls).

Overall, the vaccine effectiveness of maternal doses was 95% against delta infection and 45% against omicron.

The effectiveness against hospital admission in cases of delta and omicron variants were 97% and 53%, respectively.

The effectiveness of three doses was 73% against omicron infant infection and 80% against omicron-related infant hospitalization. Data were not available for the effectiveness of three doses against the delta variant.

The effectiveness of two doses of vaccine against infant omicron infection was highest when mothers received the second dose during the third trimester of pregnancy, compared with during the first trimester or second trimester (53% vs. 47% and 53% vs. 37%, respectively).

Vaccine effectiveness with two doses against infant infection from omicron was highest in the first 8 weeks of life (57%), then decreased to 40% among infants after 16 weeks of age.

Although the study was not designed to assess the mechanism of action of the impact of maternal vaccination on infants, the current study results were consistent with other recent studies showing a reduction in infections and hospitalizations among infants whose mothers received COVID-19 vaccines during pregnancy, the researchers wrote in their discussion.

The findings were limited by several factors including the potential unmeasured confounders not available in databases, such as whether infants were breastfed, the researchers noted. Other limitations included a lack of data on home test results and the inability to assess the waning impact of the vaccine effectiveness against the delta variant because of the small number of delta cases, they said. However, the results suggest that the mRNA COVID-19 vaccine during pregnancy was moderately to highly effective for protection against omicron and delta infection and infection-related hospitalization – especially during the first 8 weeks of life.

Effectiveness is encouraging, but updates are needed

The effectiveness of maternal vaccination to prevent COVID-19 infection and related hospitalizations in infants is promising, especially since those younger than 6 months have no other source of vaccine protection against COVID-19 infection, wrote Dana Danino, MD, of Soroka University Medical Center, Israel, and Ilan Youngster, MD, of Shamir Medical Center, Israel, in an accompanying editorial also published in The BMJ.

They also noted that maternal vaccination during pregnancy is an established method of protecting infants from infections such as influenza and pertussis.

Data from previous studies show that most infants whose mothers were vaccinated against COVID-19 during pregnancy retained maternal antibodies at 6 months, “but evidence for protection against neonatal COVID-19 infection has been deficient,” they said.

The current study findings support the value of vaccination during pregnancy, and the findings were strengthened by the large study population, the editorialists wrote. However, whether the same effectiveness holds for other COVID-19 strains such as BQ.1, BQ.1.1, BF.7, XBB, and XBB.1 remains unknown, they said.

Other areas in need of exploration include the optimal timing of vaccination during pregnancy, the protective effects of a bivalent mRNA vaccine (vs. the primary monovalent vaccine in the current study), and the potential benefits of additional boosters, they added.

“Although Jorgenson and colleagues’ study reinforces the value of maternal vaccination against COVID-19 during pregnancy, more studies are needed to better inform vaccination recommendations in an evolving landscape of new SARS-CoV-2 strains and novel vaccines,” the editorialists concluded.

The study was supported by ICES, which is funded by an annual grant from the Ontario Ministry of Health and the Ministry of Long-term Care; the study also received funding from the Canadian Immunization Research Network and the Public Health Agency of Canada. Dr. Jorgensen and the editorialists had no financial conflicts to disclose.

*This article was updated on 3/2/2023.

Maternal vaccination with two doses of the mRNA COVID-19 vaccine was 95% effective against infant infection from the delta variant, and 45% effective against infant infection from the omicron variant, a new study shows.

Previous research has confirmed that COVID-19 neutralizing antibodies following maternal vaccination or maternal COVID-19 infection are present in umbilical cord blood, breast milk, and infant serum specimens, wrote Sarah C.J. Jorgensen, PharmD, MPH, of the University of Toronto, and colleagues in their article published in The BMJ.

In the study, the researchers identified maternal and newborn pairs using administrative databases from Canada. The study population included 8,809 infants aged younger than 6 months who were born between May 7, 2021, and March 31, 2022, and who underwent testing for COVID-19 between May 7, 2021, and September 5, 2022.

Maternal vaccination with the primary COVID-19 mRNA monovalent vaccine series was defined as two vaccine doses administered up to 14 days before delivery, with at least one of the doses after the conception date.

Maternal vaccination with the primary series plus one booster was defined as three doses administered up to 14 days before delivery, with at least one of these doses after the conception date.

The primary outcome was the presence of delta or omicron COVID-19 infection or hospital admission of the infants.

The study population included 99 COVID-19 cases with the delta variant (with 4,365 controls) and 1,501 cases with the omicron variant (with 4,847 controls).

Overall, the vaccine effectiveness of maternal doses was 95% against delta infection and 45% against omicron.

The effectiveness against hospital admission in cases of delta and omicron variants were 97% and 53%, respectively.

The effectiveness of three doses was 73% against omicron infant infection and 80% against omicron-related infant hospitalization. Data were not available for the effectiveness of three doses against the delta variant.

The effectiveness of two doses of vaccine against infant omicron infection was highest when mothers received the second dose during the third trimester of pregnancy, compared with during the first trimester or second trimester (53% vs. 47% and 53% vs. 37%, respectively).

Vaccine effectiveness with two doses against infant infection from omicron was highest in the first 8 weeks of life (57%), then decreased to 40% among infants after 16 weeks of age.

Although the study was not designed to assess the mechanism of action of the impact of maternal vaccination on infants, the current study results were consistent with other recent studies showing a reduction in infections and hospitalizations among infants whose mothers received COVID-19 vaccines during pregnancy, the researchers wrote in their discussion.

The findings were limited by several factors including the potential unmeasured confounders not available in databases, such as whether infants were breastfed, the researchers noted. Other limitations included a lack of data on home test results and the inability to assess the waning impact of the vaccine effectiveness against the delta variant because of the small number of delta cases, they said. However, the results suggest that the mRNA COVID-19 vaccine during pregnancy was moderately to highly effective for protection against omicron and delta infection and infection-related hospitalization – especially during the first 8 weeks of life.

Effectiveness is encouraging, but updates are needed

The effectiveness of maternal vaccination to prevent COVID-19 infection and related hospitalizations in infants is promising, especially since those younger than 6 months have no other source of vaccine protection against COVID-19 infection, wrote Dana Danino, MD, of Soroka University Medical Center, Israel, and Ilan Youngster, MD, of Shamir Medical Center, Israel, in an accompanying editorial also published in The BMJ.

They also noted that maternal vaccination during pregnancy is an established method of protecting infants from infections such as influenza and pertussis.

Data from previous studies show that most infants whose mothers were vaccinated against COVID-19 during pregnancy retained maternal antibodies at 6 months, “but evidence for protection against neonatal COVID-19 infection has been deficient,” they said.

The current study findings support the value of vaccination during pregnancy, and the findings were strengthened by the large study population, the editorialists wrote. However, whether the same effectiveness holds for other COVID-19 strains such as BQ.1, BQ.1.1, BF.7, XBB, and XBB.1 remains unknown, they said.

Other areas in need of exploration include the optimal timing of vaccination during pregnancy, the protective effects of a bivalent mRNA vaccine (vs. the primary monovalent vaccine in the current study), and the potential benefits of additional boosters, they added.

“Although Jorgenson and colleagues’ study reinforces the value of maternal vaccination against COVID-19 during pregnancy, more studies are needed to better inform vaccination recommendations in an evolving landscape of new SARS-CoV-2 strains and novel vaccines,” the editorialists concluded.

The study was supported by ICES, which is funded by an annual grant from the Ontario Ministry of Health and the Ministry of Long-term Care; the study also received funding from the Canadian Immunization Research Network and the Public Health Agency of Canada. Dr. Jorgensen and the editorialists had no financial conflicts to disclose.

*This article was updated on 3/2/2023.

Maternal vaccination with two doses of the mRNA COVID-19 vaccine was 95% effective against infant infection from the delta variant, and 45% effective against infant infection from the omicron variant, a new study shows.

Previous research has confirmed that COVID-19 neutralizing antibodies following maternal vaccination or maternal COVID-19 infection are present in umbilical cord blood, breast milk, and infant serum specimens, wrote Sarah C.J. Jorgensen, PharmD, MPH, of the University of Toronto, and colleagues in their article published in The BMJ.

In the study, the researchers identified maternal and newborn pairs using administrative databases from Canada. The study population included 8,809 infants aged younger than 6 months who were born between May 7, 2021, and March 31, 2022, and who underwent testing for COVID-19 between May 7, 2021, and September 5, 2022.

Maternal vaccination with the primary COVID-19 mRNA monovalent vaccine series was defined as two vaccine doses administered up to 14 days before delivery, with at least one of the doses after the conception date.

Maternal vaccination with the primary series plus one booster was defined as three doses administered up to 14 days before delivery, with at least one of these doses after the conception date.

The primary outcome was the presence of delta or omicron COVID-19 infection or hospital admission of the infants.

The study population included 99 COVID-19 cases with the delta variant (with 4,365 controls) and 1,501 cases with the omicron variant (with 4,847 controls).

Overall, the vaccine effectiveness of maternal doses was 95% against delta infection and 45% against omicron.

The effectiveness against hospital admission in cases of delta and omicron variants were 97% and 53%, respectively.

The effectiveness of three doses was 73% against omicron infant infection and 80% against omicron-related infant hospitalization. Data were not available for the effectiveness of three doses against the delta variant.

The effectiveness of two doses of vaccine against infant omicron infection was highest when mothers received the second dose during the third trimester of pregnancy, compared with during the first trimester or second trimester (53% vs. 47% and 53% vs. 37%, respectively).

Vaccine effectiveness with two doses against infant infection from omicron was highest in the first 8 weeks of life (57%), then decreased to 40% among infants after 16 weeks of age.

Although the study was not designed to assess the mechanism of action of the impact of maternal vaccination on infants, the current study results were consistent with other recent studies showing a reduction in infections and hospitalizations among infants whose mothers received COVID-19 vaccines during pregnancy, the researchers wrote in their discussion.

The findings were limited by several factors including the potential unmeasured confounders not available in databases, such as whether infants were breastfed, the researchers noted. Other limitations included a lack of data on home test results and the inability to assess the waning impact of the vaccine effectiveness against the delta variant because of the small number of delta cases, they said. However, the results suggest that the mRNA COVID-19 vaccine during pregnancy was moderately to highly effective for protection against omicron and delta infection and infection-related hospitalization – especially during the first 8 weeks of life.

Effectiveness is encouraging, but updates are needed

The effectiveness of maternal vaccination to prevent COVID-19 infection and related hospitalizations in infants is promising, especially since those younger than 6 months have no other source of vaccine protection against COVID-19 infection, wrote Dana Danino, MD, of Soroka University Medical Center, Israel, and Ilan Youngster, MD, of Shamir Medical Center, Israel, in an accompanying editorial also published in The BMJ.

They also noted that maternal vaccination during pregnancy is an established method of protecting infants from infections such as influenza and pertussis.

Data from previous studies show that most infants whose mothers were vaccinated against COVID-19 during pregnancy retained maternal antibodies at 6 months, “but evidence for protection against neonatal COVID-19 infection has been deficient,” they said.

The current study findings support the value of vaccination during pregnancy, and the findings were strengthened by the large study population, the editorialists wrote. However, whether the same effectiveness holds for other COVID-19 strains such as BQ.1, BQ.1.1, BF.7, XBB, and XBB.1 remains unknown, they said.

Other areas in need of exploration include the optimal timing of vaccination during pregnancy, the protective effects of a bivalent mRNA vaccine (vs. the primary monovalent vaccine in the current study), and the potential benefits of additional boosters, they added.

“Although Jorgenson and colleagues’ study reinforces the value of maternal vaccination against COVID-19 during pregnancy, more studies are needed to better inform vaccination recommendations in an evolving landscape of new SARS-CoV-2 strains and novel vaccines,” the editorialists concluded.

The study was supported by ICES, which is funded by an annual grant from the Ontario Ministry of Health and the Ministry of Long-term Care; the study also received funding from the Canadian Immunization Research Network and the Public Health Agency of Canada. Dr. Jorgensen and the editorialists had no financial conflicts to disclose.

*This article was updated on 3/2/2023.