User login
Obese children with asthma are resistant to ICS
Obese or overweight children with asthma could be using inhaled corticosteroids (ICS) to no avail, combined results from observational studies suggest.
Using Mendelian randomization, a method for reducing bias in observational studies, investigators from the University of Amsterdam Medical Center performed an analysis of data from four cross-sectional studies and one cohort study on a total of 1,511 children with asthma.
They showed that every 1-unit increase in the body mass index (BMI) z score was associated with a more than twofold higher odds ratio for exacerbation, reported Cristina Longo, PhD, a former postdoctoral fellow at AMC, and assistant professor of medicine at the University of Montreal.
“In this large, multicenter Mendelian randomization study, our findings support current evidence that children with higher BMI status respond inadequately to inhaled corticosteroids, and that this association is likely not explained by measured confounding or reverse causation,” she said in an oral abstract presentation during the European Respiratory Society International Congress.
Unmeasured confounding
The obese-asthma phenotype in children is characterized by reduced lung function, high symptom expression, poor response to ICS, and high health care utilization.
“While most observational studies suggest that weight status is associated with asthma exacerbations, despite using inhaled corticosteroids, it’s unclear whether these associations may be due to unmeasured confounding or reverse causation, which captures the idea that perhaps obesity is a consequence rather than a cause of uncontrolled severe asthma,” she said.
Traditional observational studies of the obesity-asthma link rely on comparing data on asthma in a target population and comparing nonobese patients with obese patients. The problem with this method, Dr. Longo contended, is that the exposure assignment – weight status – is not random, and could lead to bias from potential imbalance of confounders, leading to unintentionally biased results.
In contrast, Mendelian randomization uses genetic data to approximate random assignment of exposures, using a risk score for BMI based on genetic susceptibility. The score is based on the accumulation of genetic variants (single-nucleotide polymorphisms, or SNPs) that predispose individuals to obesity, with higher numbers of variants results in a higher risk score.
The scores are then used to determine the comparison groups for evaluating the obesity-asthma association.
Alphabet soup
Dr. Longo and colleagues analyzed data on a total 1,511 children enrolled in four observational studies (PACMAN, PAGES, HPR, CLARA) and one cohort study (ALSPAC).
They included children with an asthma diagnosis who used ICS and had available information on both BMI and genetics.
The Mendelian randomization analysis was based on a weighted allele score based on 97 SNPs predictive of BMI based on large-scale genomewide association studies. The exposure for the analysis was age- and sex-adjusted BMI z scores based on World Health Organization growth charts for children.
They found that using the Mendelian randomization approach, for each standard deviation increase in BMI, the OR for any parent-reported asthma exacerbations, including urgent care visits or use of oral corticosteroids, was 2.31 (95% confidence interval, 1.26-4.25).
In contrast, if the traditional observational model had been used, the OR would be a nonsignificant 1.10 (95% CI, 0.99-1.22).
“Treatment guidelines recommend steroids for children with asthma who have a higher-than-normal BMI,” Dr. Longo said in a statement. “Our research group felt that the one-size fits-all approach to treating children with asthma with inhaled steroids as their first-line treatment, particularly those with excess weight, warrants revision. At the very least, research identifying potential alternative treatments should be encouraged and prioritized, especially since 30% of children with asthma are also obese. With the childhood obesity epidemic rising, we expect this percentage to increase meaning this problem of poor control will be seen more frequently in routine clinical practice.”
Christopher E. Brightling, PhD, professor of respiratory medicine at the University of Leicester (England), commented that “this is very good and fascinating research with findings that are important and novel.
“It sheds light on the complex interplay between genes, weight, and response to inhaled corticosteroids, underscoring the need to combine drug treatments with lifestyle and diet modifications. Policy makers, health care providers and families need to do much more to tackle the growing obesity epidemic in young people,” he said.
Dr. Brightling was not involved in the study.
The study was supported by the ERS and the European Union’s H2020 research and innovation program. Dr. Longo was a Horizon 2020 Marie-Sklodowska Cure Respire-3 fellow. Dr. Brightling reported no relevant disclosures.
Obese or overweight children with asthma could be using inhaled corticosteroids (ICS) to no avail, combined results from observational studies suggest.
Using Mendelian randomization, a method for reducing bias in observational studies, investigators from the University of Amsterdam Medical Center performed an analysis of data from four cross-sectional studies and one cohort study on a total of 1,511 children with asthma.
They showed that every 1-unit increase in the body mass index (BMI) z score was associated with a more than twofold higher odds ratio for exacerbation, reported Cristina Longo, PhD, a former postdoctoral fellow at AMC, and assistant professor of medicine at the University of Montreal.
“In this large, multicenter Mendelian randomization study, our findings support current evidence that children with higher BMI status respond inadequately to inhaled corticosteroids, and that this association is likely not explained by measured confounding or reverse causation,” she said in an oral abstract presentation during the European Respiratory Society International Congress.
Unmeasured confounding
The obese-asthma phenotype in children is characterized by reduced lung function, high symptom expression, poor response to ICS, and high health care utilization.
“While most observational studies suggest that weight status is associated with asthma exacerbations, despite using inhaled corticosteroids, it’s unclear whether these associations may be due to unmeasured confounding or reverse causation, which captures the idea that perhaps obesity is a consequence rather than a cause of uncontrolled severe asthma,” she said.
Traditional observational studies of the obesity-asthma link rely on comparing data on asthma in a target population and comparing nonobese patients with obese patients. The problem with this method, Dr. Longo contended, is that the exposure assignment – weight status – is not random, and could lead to bias from potential imbalance of confounders, leading to unintentionally biased results.
In contrast, Mendelian randomization uses genetic data to approximate random assignment of exposures, using a risk score for BMI based on genetic susceptibility. The score is based on the accumulation of genetic variants (single-nucleotide polymorphisms, or SNPs) that predispose individuals to obesity, with higher numbers of variants results in a higher risk score.
The scores are then used to determine the comparison groups for evaluating the obesity-asthma association.
Alphabet soup
Dr. Longo and colleagues analyzed data on a total 1,511 children enrolled in four observational studies (PACMAN, PAGES, HPR, CLARA) and one cohort study (ALSPAC).
They included children with an asthma diagnosis who used ICS and had available information on both BMI and genetics.
The Mendelian randomization analysis was based on a weighted allele score based on 97 SNPs predictive of BMI based on large-scale genomewide association studies. The exposure for the analysis was age- and sex-adjusted BMI z scores based on World Health Organization growth charts for children.
They found that using the Mendelian randomization approach, for each standard deviation increase in BMI, the OR for any parent-reported asthma exacerbations, including urgent care visits or use of oral corticosteroids, was 2.31 (95% confidence interval, 1.26-4.25).
In contrast, if the traditional observational model had been used, the OR would be a nonsignificant 1.10 (95% CI, 0.99-1.22).
“Treatment guidelines recommend steroids for children with asthma who have a higher-than-normal BMI,” Dr. Longo said in a statement. “Our research group felt that the one-size fits-all approach to treating children with asthma with inhaled steroids as their first-line treatment, particularly those with excess weight, warrants revision. At the very least, research identifying potential alternative treatments should be encouraged and prioritized, especially since 30% of children with asthma are also obese. With the childhood obesity epidemic rising, we expect this percentage to increase meaning this problem of poor control will be seen more frequently in routine clinical practice.”
Christopher E. Brightling, PhD, professor of respiratory medicine at the University of Leicester (England), commented that “this is very good and fascinating research with findings that are important and novel.
“It sheds light on the complex interplay between genes, weight, and response to inhaled corticosteroids, underscoring the need to combine drug treatments with lifestyle and diet modifications. Policy makers, health care providers and families need to do much more to tackle the growing obesity epidemic in young people,” he said.
Dr. Brightling was not involved in the study.
The study was supported by the ERS and the European Union’s H2020 research and innovation program. Dr. Longo was a Horizon 2020 Marie-Sklodowska Cure Respire-3 fellow. Dr. Brightling reported no relevant disclosures.
Obese or overweight children with asthma could be using inhaled corticosteroids (ICS) to no avail, combined results from observational studies suggest.
Using Mendelian randomization, a method for reducing bias in observational studies, investigators from the University of Amsterdam Medical Center performed an analysis of data from four cross-sectional studies and one cohort study on a total of 1,511 children with asthma.
They showed that every 1-unit increase in the body mass index (BMI) z score was associated with a more than twofold higher odds ratio for exacerbation, reported Cristina Longo, PhD, a former postdoctoral fellow at AMC, and assistant professor of medicine at the University of Montreal.
“In this large, multicenter Mendelian randomization study, our findings support current evidence that children with higher BMI status respond inadequately to inhaled corticosteroids, and that this association is likely not explained by measured confounding or reverse causation,” she said in an oral abstract presentation during the European Respiratory Society International Congress.
Unmeasured confounding
The obese-asthma phenotype in children is characterized by reduced lung function, high symptom expression, poor response to ICS, and high health care utilization.
“While most observational studies suggest that weight status is associated with asthma exacerbations, despite using inhaled corticosteroids, it’s unclear whether these associations may be due to unmeasured confounding or reverse causation, which captures the idea that perhaps obesity is a consequence rather than a cause of uncontrolled severe asthma,” she said.
Traditional observational studies of the obesity-asthma link rely on comparing data on asthma in a target population and comparing nonobese patients with obese patients. The problem with this method, Dr. Longo contended, is that the exposure assignment – weight status – is not random, and could lead to bias from potential imbalance of confounders, leading to unintentionally biased results.
In contrast, Mendelian randomization uses genetic data to approximate random assignment of exposures, using a risk score for BMI based on genetic susceptibility. The score is based on the accumulation of genetic variants (single-nucleotide polymorphisms, or SNPs) that predispose individuals to obesity, with higher numbers of variants results in a higher risk score.
The scores are then used to determine the comparison groups for evaluating the obesity-asthma association.
Alphabet soup
Dr. Longo and colleagues analyzed data on a total 1,511 children enrolled in four observational studies (PACMAN, PAGES, HPR, CLARA) and one cohort study (ALSPAC).
They included children with an asthma diagnosis who used ICS and had available information on both BMI and genetics.
The Mendelian randomization analysis was based on a weighted allele score based on 97 SNPs predictive of BMI based on large-scale genomewide association studies. The exposure for the analysis was age- and sex-adjusted BMI z scores based on World Health Organization growth charts for children.
They found that using the Mendelian randomization approach, for each standard deviation increase in BMI, the OR for any parent-reported asthma exacerbations, including urgent care visits or use of oral corticosteroids, was 2.31 (95% confidence interval, 1.26-4.25).
In contrast, if the traditional observational model had been used, the OR would be a nonsignificant 1.10 (95% CI, 0.99-1.22).
“Treatment guidelines recommend steroids for children with asthma who have a higher-than-normal BMI,” Dr. Longo said in a statement. “Our research group felt that the one-size fits-all approach to treating children with asthma with inhaled steroids as their first-line treatment, particularly those with excess weight, warrants revision. At the very least, research identifying potential alternative treatments should be encouraged and prioritized, especially since 30% of children with asthma are also obese. With the childhood obesity epidemic rising, we expect this percentage to increase meaning this problem of poor control will be seen more frequently in routine clinical practice.”
Christopher E. Brightling, PhD, professor of respiratory medicine at the University of Leicester (England), commented that “this is very good and fascinating research with findings that are important and novel.
“It sheds light on the complex interplay between genes, weight, and response to inhaled corticosteroids, underscoring the need to combine drug treatments with lifestyle and diet modifications. Policy makers, health care providers and families need to do much more to tackle the growing obesity epidemic in young people,” he said.
Dr. Brightling was not involved in the study.
The study was supported by the ERS and the European Union’s H2020 research and innovation program. Dr. Longo was a Horizon 2020 Marie-Sklodowska Cure Respire-3 fellow. Dr. Brightling reported no relevant disclosures.
FROM ERS 2021
Infants breathe better when pregnant moms exercise
Lung function in early infancy may be influenced by the mother’s level of physical activity during pregnancy, results of a study from Sweden suggest.
Low-lung function at 3 months of age, as measured by the ratio of time to peak tidal expiratory flow to expiratory time (tPTEF/tE), was more frequent among children whose mothers were physically inactive during the first half of pregnancy compared with those who exercised either moderately or strenuously, reported Hrefna Katrin Gudmundsdottir, MD, a pediatrician and PhD candidate at the University of Oslo, Norway. The results were based on a prospective observational study of 841 mother-child pairs.
“The potential link between maternal inactivity and low lung function in infancy adds to the importance of advising pregnant women and women of childbearing age on physical activity,” she said in an oral abstract presented during the virtual European Respiratory Society (ERS) International Congress.
Jonathan Grigg, MD, professor of pediatric respiratory and environmental medicine at Queen Mary University of London, who was not involved in the study, commented that it “offers a fascinating hint that increased physical activity of mothers is associated with better lung function in their babies and, therefore, possibly their health in later life. More research is needed to confirm this link, but it is important that women feel supported by their health care providers to be active in a way that is comfortable and accessible to them.”
Impaired lung function in infancy is associated with wheezing and asthma in childhood, and lower lung function later in life, Dr. Gudmundsdottir said. She also noted that impaired lung function begins in utero and is related to fetal and infant size, family history of asthma, and/or maternal smoking.
Physical activity during pregnancy has been demonstrated to reduce the risk of preterm birth and cesarean birth and of children being born either abnormally small or abnormally large for their gestational age, she explained.
To see where physical inactivity in the first half of pregnancy is associated with lower lung function in otherwise healthy 3-month old infants, Dr. Gudmundsdottir and colleagues looked at data on a mother-child cohort from the prospective population-based PreventADALL study, which was designed to study prevention of atopic dermatitis and allergies in children in Norway and Sweden.
A total of 814 infants (49% female) had available measures of tidal flow volume in the awake state at 3 months, as well as mother-reported data on physical activity at 18 weeks of pregnancy.
The investigators categorized the mothers as inactive, with either no or only low-intensity physical activity, “fairly” active, or “very” active based on self reporting.
The average tPTEF/tE value among all infants in the study was 0.391. The average value for 290 infants born to inactive mothers was 0.387, compared with 0.394 for 299 infants born to very active mothers, a difference that was not statistically significant.
Maternal physical activity level was not significantly associated with continuous tPTEF/tE, but the investigators did find that the offspring of inactive mothers were significantly more likely than the children of fairly or very active mothers to have a tPTEF/tE below 0.25 in both univariate analysis (odds ratio, 2.15; P = .011), and in multivariate analysis controlling for maternal age, education, parity, prepregnancy body-mass index, parental atopy, and in-utero exposure to nicotine (OR, 2.18; P = .013).
In univariate but not multivariate analysis, children of inactive mothers were significantly more likely than infants of more active mothers to have tPTEF/tE values below the 50th percentile (OR, 1.35; P = .042).
“We observed a trend that adds to the importance of advising women of childbearing age and pregnant women about physical activity. However, there may be factors that affect both maternal physical activity and lung function in offspring that we have not accounted for and could affect the results, so more research is needed,” Dr. Gudmundsdottir said in a statement.
Dr. Grigg pointed out that “it’s also worth keeping in mind that the single most important thing that mothers can do for their own health and that of their baby is to ensure that they do not smoke or use other tobacco products before, during, and after pregnancy. A smoke-free home has the biggest impact on lung function and health in childhood and later life.”
The study was supported by the University of Oslo. Dr. Gudmundsdottir and Dr. Grigg have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Lung function in early infancy may be influenced by the mother’s level of physical activity during pregnancy, results of a study from Sweden suggest.
Low-lung function at 3 months of age, as measured by the ratio of time to peak tidal expiratory flow to expiratory time (tPTEF/tE), was more frequent among children whose mothers were physically inactive during the first half of pregnancy compared with those who exercised either moderately or strenuously, reported Hrefna Katrin Gudmundsdottir, MD, a pediatrician and PhD candidate at the University of Oslo, Norway. The results were based on a prospective observational study of 841 mother-child pairs.
“The potential link between maternal inactivity and low lung function in infancy adds to the importance of advising pregnant women and women of childbearing age on physical activity,” she said in an oral abstract presented during the virtual European Respiratory Society (ERS) International Congress.
Jonathan Grigg, MD, professor of pediatric respiratory and environmental medicine at Queen Mary University of London, who was not involved in the study, commented that it “offers a fascinating hint that increased physical activity of mothers is associated with better lung function in their babies and, therefore, possibly their health in later life. More research is needed to confirm this link, but it is important that women feel supported by their health care providers to be active in a way that is comfortable and accessible to them.”
Impaired lung function in infancy is associated with wheezing and asthma in childhood, and lower lung function later in life, Dr. Gudmundsdottir said. She also noted that impaired lung function begins in utero and is related to fetal and infant size, family history of asthma, and/or maternal smoking.
Physical activity during pregnancy has been demonstrated to reduce the risk of preterm birth and cesarean birth and of children being born either abnormally small or abnormally large for their gestational age, she explained.
To see where physical inactivity in the first half of pregnancy is associated with lower lung function in otherwise healthy 3-month old infants, Dr. Gudmundsdottir and colleagues looked at data on a mother-child cohort from the prospective population-based PreventADALL study, which was designed to study prevention of atopic dermatitis and allergies in children in Norway and Sweden.
A total of 814 infants (49% female) had available measures of tidal flow volume in the awake state at 3 months, as well as mother-reported data on physical activity at 18 weeks of pregnancy.
The investigators categorized the mothers as inactive, with either no or only low-intensity physical activity, “fairly” active, or “very” active based on self reporting.
The average tPTEF/tE value among all infants in the study was 0.391. The average value for 290 infants born to inactive mothers was 0.387, compared with 0.394 for 299 infants born to very active mothers, a difference that was not statistically significant.
Maternal physical activity level was not significantly associated with continuous tPTEF/tE, but the investigators did find that the offspring of inactive mothers were significantly more likely than the children of fairly or very active mothers to have a tPTEF/tE below 0.25 in both univariate analysis (odds ratio, 2.15; P = .011), and in multivariate analysis controlling for maternal age, education, parity, prepregnancy body-mass index, parental atopy, and in-utero exposure to nicotine (OR, 2.18; P = .013).
In univariate but not multivariate analysis, children of inactive mothers were significantly more likely than infants of more active mothers to have tPTEF/tE values below the 50th percentile (OR, 1.35; P = .042).
“We observed a trend that adds to the importance of advising women of childbearing age and pregnant women about physical activity. However, there may be factors that affect both maternal physical activity and lung function in offspring that we have not accounted for and could affect the results, so more research is needed,” Dr. Gudmundsdottir said in a statement.
Dr. Grigg pointed out that “it’s also worth keeping in mind that the single most important thing that mothers can do for their own health and that of their baby is to ensure that they do not smoke or use other tobacco products before, during, and after pregnancy. A smoke-free home has the biggest impact on lung function and health in childhood and later life.”
The study was supported by the University of Oslo. Dr. Gudmundsdottir and Dr. Grigg have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Lung function in early infancy may be influenced by the mother’s level of physical activity during pregnancy, results of a study from Sweden suggest.
Low-lung function at 3 months of age, as measured by the ratio of time to peak tidal expiratory flow to expiratory time (tPTEF/tE), was more frequent among children whose mothers were physically inactive during the first half of pregnancy compared with those who exercised either moderately or strenuously, reported Hrefna Katrin Gudmundsdottir, MD, a pediatrician and PhD candidate at the University of Oslo, Norway. The results were based on a prospective observational study of 841 mother-child pairs.
“The potential link between maternal inactivity and low lung function in infancy adds to the importance of advising pregnant women and women of childbearing age on physical activity,” she said in an oral abstract presented during the virtual European Respiratory Society (ERS) International Congress.
Jonathan Grigg, MD, professor of pediatric respiratory and environmental medicine at Queen Mary University of London, who was not involved in the study, commented that it “offers a fascinating hint that increased physical activity of mothers is associated with better lung function in their babies and, therefore, possibly their health in later life. More research is needed to confirm this link, but it is important that women feel supported by their health care providers to be active in a way that is comfortable and accessible to them.”
Impaired lung function in infancy is associated with wheezing and asthma in childhood, and lower lung function later in life, Dr. Gudmundsdottir said. She also noted that impaired lung function begins in utero and is related to fetal and infant size, family history of asthma, and/or maternal smoking.
Physical activity during pregnancy has been demonstrated to reduce the risk of preterm birth and cesarean birth and of children being born either abnormally small or abnormally large for their gestational age, she explained.
To see where physical inactivity in the first half of pregnancy is associated with lower lung function in otherwise healthy 3-month old infants, Dr. Gudmundsdottir and colleagues looked at data on a mother-child cohort from the prospective population-based PreventADALL study, which was designed to study prevention of atopic dermatitis and allergies in children in Norway and Sweden.
A total of 814 infants (49% female) had available measures of tidal flow volume in the awake state at 3 months, as well as mother-reported data on physical activity at 18 weeks of pregnancy.
The investigators categorized the mothers as inactive, with either no or only low-intensity physical activity, “fairly” active, or “very” active based on self reporting.
The average tPTEF/tE value among all infants in the study was 0.391. The average value for 290 infants born to inactive mothers was 0.387, compared with 0.394 for 299 infants born to very active mothers, a difference that was not statistically significant.
Maternal physical activity level was not significantly associated with continuous tPTEF/tE, but the investigators did find that the offspring of inactive mothers were significantly more likely than the children of fairly or very active mothers to have a tPTEF/tE below 0.25 in both univariate analysis (odds ratio, 2.15; P = .011), and in multivariate analysis controlling for maternal age, education, parity, prepregnancy body-mass index, parental atopy, and in-utero exposure to nicotine (OR, 2.18; P = .013).
In univariate but not multivariate analysis, children of inactive mothers were significantly more likely than infants of more active mothers to have tPTEF/tE values below the 50th percentile (OR, 1.35; P = .042).
“We observed a trend that adds to the importance of advising women of childbearing age and pregnant women about physical activity. However, there may be factors that affect both maternal physical activity and lung function in offspring that we have not accounted for and could affect the results, so more research is needed,” Dr. Gudmundsdottir said in a statement.
Dr. Grigg pointed out that “it’s also worth keeping in mind that the single most important thing that mothers can do for their own health and that of their baby is to ensure that they do not smoke or use other tobacco products before, during, and after pregnancy. A smoke-free home has the biggest impact on lung function and health in childhood and later life.”
The study was supported by the University of Oslo. Dr. Gudmundsdottir and Dr. Grigg have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Office-based pediatricians unprepared for emergencies
Emergency preparedness in U.S. pediatric offices is variable and less than ideal, especially in smaller independent practices, a 15-month multicenter study has found.
Researchers led by Kamal Abulebda, MD, associate professor of clinical pediatrics in the division of pediatric critical care medicine at Indiana University and Riley Hospital for Children in Indianapolis, report that adherence to the 2007 policy statement of the American Academy of Pediatrics on emergency preparedness in pediatric primary care offices was suboptimal across 42 offices in 9 states. They suggest that academic and community partnerships use in-situ simulation exercises to address preparedness gaps and implement standard procedures for contacting emergency medical services.
The group’s findings were published online in Pediatrics. “These data can be used to guide the development of interventions to improve emergency preparedness and care delivery in pediatric offices, Dr. Abulebda and coauthors wrote, noting that theirs is the first multicenter study to directly measure preparedness and quality of care in pediatric offices.
According to the authors, the incidence of a child’s requiring emergent stabilization in an individual office ranges from weekly to monthly, with seizures and respiratory distress being the most common events.
The study was conducted from 2018 to 2020 by 48 national teams participating in in-situ simulated sessions in the ambulatory setting. Office teams, recruited from practices by members of regional academic medical centers, included two patients – a child with respiratory distress and a child with a seizure. Almost 40% were from Indiana.
The scenarios and checklists for the mock exercises were created by content experts in pediatric emergency medicine and critical care using evidence-based guidelines and best practices.
Previous research has relied on self-reported surveys rather than direct measurement to assess adherence to the AAP guidelines, the authors say. In-person surveys assessed adherence to AAP recommendations for emergency preparedness. In-person surveys were, however, used to gauge adherence to AAP recommendations for emergency preparedness.
Findings
The overall mean emergency preparedness score was 74.7% (standard deviation [SD] 12.9), with an unweighted percentage of adherence to checklists calculated for each case. By emergency type, the median asthma case performance score was 63.6% (interquartile range [IQR] 43.2-81.2), and the median seizure case score was 69.2% (IQR 46.2-80.8).
On the measure of essential equipment and supplies, the mean subscore (relating to availability of such items as oxygen sources, suction devices, and epinephrine, for example) was 82.2% (SD 15.1).
As for recommended policies and protocols (e.g., regular assessment of the office, maintenance of emergency equipment and medications) the mean subscore fell to 57.1% (SD 25.6).
In multivariable analyses, offices with a standardized procedure for contacting EMS had a higher rate of activating that service during the simulations.
Independent practices and smaller total staff size were associated with lower preparedness compared with larger groups: beta = –11.89, 95% confidence interval [CI], 19.33-4.45).
Higher annual patient volume and larger total staff size were slightly associated with higher scores (beta = .001, 95% CI, .00-001, P = .017; and beta = .51, 95% CI, .19-.83, P = .002, respectively).
Affiliation with an academic medical center and the presence of learners were not associated with higher scores. And in multivariable regression, a higher annual patient volume lost its significant association with greater preparedness.
So why the lag in preparedness despite the long-standing AAP recommendations? “It’s most likely due to the rare occurrence of these emergencies in the office setting, in addition to most offices’ dependence on EMS when they encounter pediatric emergencies in their setting,” Dr. Abulebda said in an interview. “A 2018 study published by Yuknis and associates demonstrated that the average time from EMS notification to arrival on scene was just 6 minutes.”
In other study findings, 82% of offices did not have an infant bag valve mask and would therefore need to wait for EMS to administer lifesaving ventilation. “This highlights the need to have this equipment available and maintain the skills necessary to care for patients in respiratory distress, the most common emergency encountered in the office setting,” Dr. Abulebda and associates wrote.
A cardiac arrest board is another example of a potentially lifesaving piece of equipment that was not available in the majority of offices, likely because of the rarity of this event in the office setting, but lack of this item may result in poor cardiopulmonary resuscitation quality before the arrival of EMS.
In an accompanying editorial, Jesse Hackell, MD, a pediatrician at Boston Children’s Health Physicians and New York Medical College in Pomona, N.Y., noted that data from 2 decades ago suggested that many pediatric offices saw multiple children requiring emergency intervention each week. More recent figures, however, indicate the situation has evolved, with fewer than 1% of current pediatric EMS transports originating from the office setting.
Dr. Hackell agrees that implementation of AAP recommendations has been far from universal and cites the cost of equipment and supplies as well as a lack of access to training and evaluation as significant barriers to implementation. “In addition, the infrequent occurrence of these emergencies makes maintenance of resuscitation skills even more difficult without frequent practice,” he wrote.
Further complicating the issue, preparedness needs vary with practice location, the response time of local EMS, and proximity to an emergency department. “Pediatric offices in more rural areas, which are farther from these services, will require more equipment and more skills to provide optimal emergency care to children living in these underresourced areas,” he wrote.
He called for equitable distribution of preparedness training, equipment, and staffing, with guidance designed to meet patient needs and ensure optimal outcomes. “In discussion of recommendations, one should consider the likely conditions requiring this response, availability of resources beyond the pediatric office, and ongoing training and support needed to maintain provider skills at the level needed for a successful response to any pediatric emergency,” Dr. Hackell wrote.
This study was supported by grants from Indiana University Health Values and the RBaby Foundation. One study coauthor is a board observer of a medical device company. No other authors disclosed financial relationships relevant to this work. Dr. Hackell has disclosed having no competing interests.
Emergency preparedness in U.S. pediatric offices is variable and less than ideal, especially in smaller independent practices, a 15-month multicenter study has found.
Researchers led by Kamal Abulebda, MD, associate professor of clinical pediatrics in the division of pediatric critical care medicine at Indiana University and Riley Hospital for Children in Indianapolis, report that adherence to the 2007 policy statement of the American Academy of Pediatrics on emergency preparedness in pediatric primary care offices was suboptimal across 42 offices in 9 states. They suggest that academic and community partnerships use in-situ simulation exercises to address preparedness gaps and implement standard procedures for contacting emergency medical services.
The group’s findings were published online in Pediatrics. “These data can be used to guide the development of interventions to improve emergency preparedness and care delivery in pediatric offices, Dr. Abulebda and coauthors wrote, noting that theirs is the first multicenter study to directly measure preparedness and quality of care in pediatric offices.
According to the authors, the incidence of a child’s requiring emergent stabilization in an individual office ranges from weekly to monthly, with seizures and respiratory distress being the most common events.
The study was conducted from 2018 to 2020 by 48 national teams participating in in-situ simulated sessions in the ambulatory setting. Office teams, recruited from practices by members of regional academic medical centers, included two patients – a child with respiratory distress and a child with a seizure. Almost 40% were from Indiana.
The scenarios and checklists for the mock exercises were created by content experts in pediatric emergency medicine and critical care using evidence-based guidelines and best practices.
Previous research has relied on self-reported surveys rather than direct measurement to assess adherence to the AAP guidelines, the authors say. In-person surveys assessed adherence to AAP recommendations for emergency preparedness. In-person surveys were, however, used to gauge adherence to AAP recommendations for emergency preparedness.
Findings
The overall mean emergency preparedness score was 74.7% (standard deviation [SD] 12.9), with an unweighted percentage of adherence to checklists calculated for each case. By emergency type, the median asthma case performance score was 63.6% (interquartile range [IQR] 43.2-81.2), and the median seizure case score was 69.2% (IQR 46.2-80.8).
On the measure of essential equipment and supplies, the mean subscore (relating to availability of such items as oxygen sources, suction devices, and epinephrine, for example) was 82.2% (SD 15.1).
As for recommended policies and protocols (e.g., regular assessment of the office, maintenance of emergency equipment and medications) the mean subscore fell to 57.1% (SD 25.6).
In multivariable analyses, offices with a standardized procedure for contacting EMS had a higher rate of activating that service during the simulations.
Independent practices and smaller total staff size were associated with lower preparedness compared with larger groups: beta = –11.89, 95% confidence interval [CI], 19.33-4.45).
Higher annual patient volume and larger total staff size were slightly associated with higher scores (beta = .001, 95% CI, .00-001, P = .017; and beta = .51, 95% CI, .19-.83, P = .002, respectively).
Affiliation with an academic medical center and the presence of learners were not associated with higher scores. And in multivariable regression, a higher annual patient volume lost its significant association with greater preparedness.
So why the lag in preparedness despite the long-standing AAP recommendations? “It’s most likely due to the rare occurrence of these emergencies in the office setting, in addition to most offices’ dependence on EMS when they encounter pediatric emergencies in their setting,” Dr. Abulebda said in an interview. “A 2018 study published by Yuknis and associates demonstrated that the average time from EMS notification to arrival on scene was just 6 minutes.”
In other study findings, 82% of offices did not have an infant bag valve mask and would therefore need to wait for EMS to administer lifesaving ventilation. “This highlights the need to have this equipment available and maintain the skills necessary to care for patients in respiratory distress, the most common emergency encountered in the office setting,” Dr. Abulebda and associates wrote.
A cardiac arrest board is another example of a potentially lifesaving piece of equipment that was not available in the majority of offices, likely because of the rarity of this event in the office setting, but lack of this item may result in poor cardiopulmonary resuscitation quality before the arrival of EMS.
In an accompanying editorial, Jesse Hackell, MD, a pediatrician at Boston Children’s Health Physicians and New York Medical College in Pomona, N.Y., noted that data from 2 decades ago suggested that many pediatric offices saw multiple children requiring emergency intervention each week. More recent figures, however, indicate the situation has evolved, with fewer than 1% of current pediatric EMS transports originating from the office setting.
Dr. Hackell agrees that implementation of AAP recommendations has been far from universal and cites the cost of equipment and supplies as well as a lack of access to training and evaluation as significant barriers to implementation. “In addition, the infrequent occurrence of these emergencies makes maintenance of resuscitation skills even more difficult without frequent practice,” he wrote.
Further complicating the issue, preparedness needs vary with practice location, the response time of local EMS, and proximity to an emergency department. “Pediatric offices in more rural areas, which are farther from these services, will require more equipment and more skills to provide optimal emergency care to children living in these underresourced areas,” he wrote.
He called for equitable distribution of preparedness training, equipment, and staffing, with guidance designed to meet patient needs and ensure optimal outcomes. “In discussion of recommendations, one should consider the likely conditions requiring this response, availability of resources beyond the pediatric office, and ongoing training and support needed to maintain provider skills at the level needed for a successful response to any pediatric emergency,” Dr. Hackell wrote.
This study was supported by grants from Indiana University Health Values and the RBaby Foundation. One study coauthor is a board observer of a medical device company. No other authors disclosed financial relationships relevant to this work. Dr. Hackell has disclosed having no competing interests.
Emergency preparedness in U.S. pediatric offices is variable and less than ideal, especially in smaller independent practices, a 15-month multicenter study has found.
Researchers led by Kamal Abulebda, MD, associate professor of clinical pediatrics in the division of pediatric critical care medicine at Indiana University and Riley Hospital for Children in Indianapolis, report that adherence to the 2007 policy statement of the American Academy of Pediatrics on emergency preparedness in pediatric primary care offices was suboptimal across 42 offices in 9 states. They suggest that academic and community partnerships use in-situ simulation exercises to address preparedness gaps and implement standard procedures for contacting emergency medical services.
The group’s findings were published online in Pediatrics. “These data can be used to guide the development of interventions to improve emergency preparedness and care delivery in pediatric offices, Dr. Abulebda and coauthors wrote, noting that theirs is the first multicenter study to directly measure preparedness and quality of care in pediatric offices.
According to the authors, the incidence of a child’s requiring emergent stabilization in an individual office ranges from weekly to monthly, with seizures and respiratory distress being the most common events.
The study was conducted from 2018 to 2020 by 48 national teams participating in in-situ simulated sessions in the ambulatory setting. Office teams, recruited from practices by members of regional academic medical centers, included two patients – a child with respiratory distress and a child with a seizure. Almost 40% were from Indiana.
The scenarios and checklists for the mock exercises were created by content experts in pediatric emergency medicine and critical care using evidence-based guidelines and best practices.
Previous research has relied on self-reported surveys rather than direct measurement to assess adherence to the AAP guidelines, the authors say. In-person surveys assessed adherence to AAP recommendations for emergency preparedness. In-person surveys were, however, used to gauge adherence to AAP recommendations for emergency preparedness.
Findings
The overall mean emergency preparedness score was 74.7% (standard deviation [SD] 12.9), with an unweighted percentage of adherence to checklists calculated for each case. By emergency type, the median asthma case performance score was 63.6% (interquartile range [IQR] 43.2-81.2), and the median seizure case score was 69.2% (IQR 46.2-80.8).
On the measure of essential equipment and supplies, the mean subscore (relating to availability of such items as oxygen sources, suction devices, and epinephrine, for example) was 82.2% (SD 15.1).
As for recommended policies and protocols (e.g., regular assessment of the office, maintenance of emergency equipment and medications) the mean subscore fell to 57.1% (SD 25.6).
In multivariable analyses, offices with a standardized procedure for contacting EMS had a higher rate of activating that service during the simulations.
Independent practices and smaller total staff size were associated with lower preparedness compared with larger groups: beta = –11.89, 95% confidence interval [CI], 19.33-4.45).
Higher annual patient volume and larger total staff size were slightly associated with higher scores (beta = .001, 95% CI, .00-001, P = .017; and beta = .51, 95% CI, .19-.83, P = .002, respectively).
Affiliation with an academic medical center and the presence of learners were not associated with higher scores. And in multivariable regression, a higher annual patient volume lost its significant association with greater preparedness.
So why the lag in preparedness despite the long-standing AAP recommendations? “It’s most likely due to the rare occurrence of these emergencies in the office setting, in addition to most offices’ dependence on EMS when they encounter pediatric emergencies in their setting,” Dr. Abulebda said in an interview. “A 2018 study published by Yuknis and associates demonstrated that the average time from EMS notification to arrival on scene was just 6 minutes.”
In other study findings, 82% of offices did not have an infant bag valve mask and would therefore need to wait for EMS to administer lifesaving ventilation. “This highlights the need to have this equipment available and maintain the skills necessary to care for patients in respiratory distress, the most common emergency encountered in the office setting,” Dr. Abulebda and associates wrote.
A cardiac arrest board is another example of a potentially lifesaving piece of equipment that was not available in the majority of offices, likely because of the rarity of this event in the office setting, but lack of this item may result in poor cardiopulmonary resuscitation quality before the arrival of EMS.
In an accompanying editorial, Jesse Hackell, MD, a pediatrician at Boston Children’s Health Physicians and New York Medical College in Pomona, N.Y., noted that data from 2 decades ago suggested that many pediatric offices saw multiple children requiring emergency intervention each week. More recent figures, however, indicate the situation has evolved, with fewer than 1% of current pediatric EMS transports originating from the office setting.
Dr. Hackell agrees that implementation of AAP recommendations has been far from universal and cites the cost of equipment and supplies as well as a lack of access to training and evaluation as significant barriers to implementation. “In addition, the infrequent occurrence of these emergencies makes maintenance of resuscitation skills even more difficult without frequent practice,” he wrote.
Further complicating the issue, preparedness needs vary with practice location, the response time of local EMS, and proximity to an emergency department. “Pediatric offices in more rural areas, which are farther from these services, will require more equipment and more skills to provide optimal emergency care to children living in these underresourced areas,” he wrote.
He called for equitable distribution of preparedness training, equipment, and staffing, with guidance designed to meet patient needs and ensure optimal outcomes. “In discussion of recommendations, one should consider the likely conditions requiring this response, availability of resources beyond the pediatric office, and ongoing training and support needed to maintain provider skills at the level needed for a successful response to any pediatric emergency,” Dr. Hackell wrote.
This study was supported by grants from Indiana University Health Values and the RBaby Foundation. One study coauthor is a board observer of a medical device company. No other authors disclosed financial relationships relevant to this work. Dr. Hackell has disclosed having no competing interests.
FROM PEDIATRICS
EAACI review urges reduction in antibiotic overuse with allergy
Urgent recommendations from a European Academy of Allergy and Clinical Immunology (EAACI) task force are aimed at reducing antibiotic overuse with allergic disease.
Top recommendations include limiting antibiotic therapy in pregnancy and early childhood to help reduce the allergy epidemic in children, and restricting antibiotic therapy in exacerbations and chronic treatment of allergic diseases, especially asthma and atopic dermatitis.
The review, by lead author Gerdien Tramper-Stranders, MD, PhD, department of pediatrics, Franciscus Gasthuis & Vlietland Hospital, Rotterdam, the Netherlands, and colleagues, was published online Aug. 13 in the journal Allergy.
Several studies have shown that use of antibiotics in childhood and during pregnancy is associated with disturbing the intestinal and respiratory microbiome, which in turn leads to dysbiosis and an increased risk of acquiring allergic diseases, the authors noted.
In addition, patients with allergic diseases such as asthma have a higher risk of being prescribed antibiotics for infections compared with the general population, despite lack of clear clinical benefit.
“In fact, there are no clear data supporting antibiotic prescriptions for acute exacerbations; and clinical and/or laboratory criteria are lacking,” the authors wrote.
Despite that lack of data, antibiotics are often prescribed for exacerbations along with oral corticosteroids, Dr. Tramper-Stranders said in an interview. Some patients may benefit from antibiotics in a flare-up, she said, but more research is needed to determine which ones.
Dr. Tramper-Stranders said Franciscus has begun a large study that includes patients with asthma exacerbations to find biomarkers that might predict the type or origin of exacerbation to personalize treatment.
Recommendations have global relevance
She said although the recommendations are coming from the EAACI group, they apply worldwide.
“Especially in countries outside Northern Europe, antibiotic use is tremendous, leading to high rates of antibiotic resistance; but also increasing the risk for developing allergic diseases when prescribed in infancy,” she said.
She pointed out that in the United States, as many as one in six children receive unnecessary antibiotics for an asthma exacerbation. Overtreatment in adults with flare-ups is also prevalent, at rates from 40%-50%.
Millie Kwan, MD, PhD, an allergy specialist at University of North Carolina in Chapel Hill, said in an interview that in the U.S. there’s been a culture change in the direction of antibiotic restraint – but there are still problems.
“It’s a lot easier for us to whip out our prescription pads and prescribe antibiotics for an asthma patient who’s having a flare-up or a patient who has atopic dermatitis before addressing the underlying mechanism directly,” Dr. Kwan said. She agreed that antibiotic overuse is prevalent in pregnancies in the U.S., and she said that starts with the high prevalence of cesarean births. Nearly one-third of all births in the U.S. are by C-section, twice the rate recommended by the World Health Organization.
“Just bypassing the birth canal actually changes what kind of microflora the infant is being exposed to,” Dr. Kwan said. “That’s the first huge problem.”
The second problem, she said, is the potential for overuse of antibiotics with the surgical procedure.
The researchers wrote that pre-, pro- or postbiotics might alter the course of allergic disease, but clear evidence is lacking.
Until now, Dr. Tramper-Stranders said, pre- or probiotic treatment in infancy, irrespective of previous antibiotic use, has not proved effective in preventing allergies.
Data describing the effect of pre- or probiotics after an antibiotic course are scarce, are limited to older children and adults, and are focused on short-term effects, such as diarrhea prevention, she explained.
Dr. Kwan says she agrees that current data are not strong enough to recommend one over another.
“We don’t even know what the normal amount of bacteria should be to constitute an environment where the immune system develops ‘normally,’ “ she said.
Antibiotics should be prescribed cautiously and by following current recommendations to use the narrowest spectrum available, the authors wrote. Future research in antibiotic stewardship should incorporate biomarker-guided therapy to determine which patients might benefit most from antibiotic therapy.
“Practicing antibiotic stewardship needs recurrent attention and we hope that with this initiative, we specifically reach allergy doctors who will rethink their next [antibiotic] prescription. Within our EAACI task force, we will next work on a guideline for rational antibiotic use in asthma,” Dr. Tramper-Stranders said.
The review’s authors and Dr. Kwan have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Urgent recommendations from a European Academy of Allergy and Clinical Immunology (EAACI) task force are aimed at reducing antibiotic overuse with allergic disease.
Top recommendations include limiting antibiotic therapy in pregnancy and early childhood to help reduce the allergy epidemic in children, and restricting antibiotic therapy in exacerbations and chronic treatment of allergic diseases, especially asthma and atopic dermatitis.
The review, by lead author Gerdien Tramper-Stranders, MD, PhD, department of pediatrics, Franciscus Gasthuis & Vlietland Hospital, Rotterdam, the Netherlands, and colleagues, was published online Aug. 13 in the journal Allergy.
Several studies have shown that use of antibiotics in childhood and during pregnancy is associated with disturbing the intestinal and respiratory microbiome, which in turn leads to dysbiosis and an increased risk of acquiring allergic diseases, the authors noted.
In addition, patients with allergic diseases such as asthma have a higher risk of being prescribed antibiotics for infections compared with the general population, despite lack of clear clinical benefit.
“In fact, there are no clear data supporting antibiotic prescriptions for acute exacerbations; and clinical and/or laboratory criteria are lacking,” the authors wrote.
Despite that lack of data, antibiotics are often prescribed for exacerbations along with oral corticosteroids, Dr. Tramper-Stranders said in an interview. Some patients may benefit from antibiotics in a flare-up, she said, but more research is needed to determine which ones.
Dr. Tramper-Stranders said Franciscus has begun a large study that includes patients with asthma exacerbations to find biomarkers that might predict the type or origin of exacerbation to personalize treatment.
Recommendations have global relevance
She said although the recommendations are coming from the EAACI group, they apply worldwide.
“Especially in countries outside Northern Europe, antibiotic use is tremendous, leading to high rates of antibiotic resistance; but also increasing the risk for developing allergic diseases when prescribed in infancy,” she said.
She pointed out that in the United States, as many as one in six children receive unnecessary antibiotics for an asthma exacerbation. Overtreatment in adults with flare-ups is also prevalent, at rates from 40%-50%.
Millie Kwan, MD, PhD, an allergy specialist at University of North Carolina in Chapel Hill, said in an interview that in the U.S. there’s been a culture change in the direction of antibiotic restraint – but there are still problems.
“It’s a lot easier for us to whip out our prescription pads and prescribe antibiotics for an asthma patient who’s having a flare-up or a patient who has atopic dermatitis before addressing the underlying mechanism directly,” Dr. Kwan said. She agreed that antibiotic overuse is prevalent in pregnancies in the U.S., and she said that starts with the high prevalence of cesarean births. Nearly one-third of all births in the U.S. are by C-section, twice the rate recommended by the World Health Organization.
“Just bypassing the birth canal actually changes what kind of microflora the infant is being exposed to,” Dr. Kwan said. “That’s the first huge problem.”
The second problem, she said, is the potential for overuse of antibiotics with the surgical procedure.
The researchers wrote that pre-, pro- or postbiotics might alter the course of allergic disease, but clear evidence is lacking.
Until now, Dr. Tramper-Stranders said, pre- or probiotic treatment in infancy, irrespective of previous antibiotic use, has not proved effective in preventing allergies.
Data describing the effect of pre- or probiotics after an antibiotic course are scarce, are limited to older children and adults, and are focused on short-term effects, such as diarrhea prevention, she explained.
Dr. Kwan says she agrees that current data are not strong enough to recommend one over another.
“We don’t even know what the normal amount of bacteria should be to constitute an environment where the immune system develops ‘normally,’ “ she said.
Antibiotics should be prescribed cautiously and by following current recommendations to use the narrowest spectrum available, the authors wrote. Future research in antibiotic stewardship should incorporate biomarker-guided therapy to determine which patients might benefit most from antibiotic therapy.
“Practicing antibiotic stewardship needs recurrent attention and we hope that with this initiative, we specifically reach allergy doctors who will rethink their next [antibiotic] prescription. Within our EAACI task force, we will next work on a guideline for rational antibiotic use in asthma,” Dr. Tramper-Stranders said.
The review’s authors and Dr. Kwan have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Urgent recommendations from a European Academy of Allergy and Clinical Immunology (EAACI) task force are aimed at reducing antibiotic overuse with allergic disease.
Top recommendations include limiting antibiotic therapy in pregnancy and early childhood to help reduce the allergy epidemic in children, and restricting antibiotic therapy in exacerbations and chronic treatment of allergic diseases, especially asthma and atopic dermatitis.
The review, by lead author Gerdien Tramper-Stranders, MD, PhD, department of pediatrics, Franciscus Gasthuis & Vlietland Hospital, Rotterdam, the Netherlands, and colleagues, was published online Aug. 13 in the journal Allergy.
Several studies have shown that use of antibiotics in childhood and during pregnancy is associated with disturbing the intestinal and respiratory microbiome, which in turn leads to dysbiosis and an increased risk of acquiring allergic diseases, the authors noted.
In addition, patients with allergic diseases such as asthma have a higher risk of being prescribed antibiotics for infections compared with the general population, despite lack of clear clinical benefit.
“In fact, there are no clear data supporting antibiotic prescriptions for acute exacerbations; and clinical and/or laboratory criteria are lacking,” the authors wrote.
Despite that lack of data, antibiotics are often prescribed for exacerbations along with oral corticosteroids, Dr. Tramper-Stranders said in an interview. Some patients may benefit from antibiotics in a flare-up, she said, but more research is needed to determine which ones.
Dr. Tramper-Stranders said Franciscus has begun a large study that includes patients with asthma exacerbations to find biomarkers that might predict the type or origin of exacerbation to personalize treatment.
Recommendations have global relevance
She said although the recommendations are coming from the EAACI group, they apply worldwide.
“Especially in countries outside Northern Europe, antibiotic use is tremendous, leading to high rates of antibiotic resistance; but also increasing the risk for developing allergic diseases when prescribed in infancy,” she said.
She pointed out that in the United States, as many as one in six children receive unnecessary antibiotics for an asthma exacerbation. Overtreatment in adults with flare-ups is also prevalent, at rates from 40%-50%.
Millie Kwan, MD, PhD, an allergy specialist at University of North Carolina in Chapel Hill, said in an interview that in the U.S. there’s been a culture change in the direction of antibiotic restraint – but there are still problems.
“It’s a lot easier for us to whip out our prescription pads and prescribe antibiotics for an asthma patient who’s having a flare-up or a patient who has atopic dermatitis before addressing the underlying mechanism directly,” Dr. Kwan said. She agreed that antibiotic overuse is prevalent in pregnancies in the U.S., and she said that starts with the high prevalence of cesarean births. Nearly one-third of all births in the U.S. are by C-section, twice the rate recommended by the World Health Organization.
“Just bypassing the birth canal actually changes what kind of microflora the infant is being exposed to,” Dr. Kwan said. “That’s the first huge problem.”
The second problem, she said, is the potential for overuse of antibiotics with the surgical procedure.
The researchers wrote that pre-, pro- or postbiotics might alter the course of allergic disease, but clear evidence is lacking.
Until now, Dr. Tramper-Stranders said, pre- or probiotic treatment in infancy, irrespective of previous antibiotic use, has not proved effective in preventing allergies.
Data describing the effect of pre- or probiotics after an antibiotic course are scarce, are limited to older children and adults, and are focused on short-term effects, such as diarrhea prevention, she explained.
Dr. Kwan says she agrees that current data are not strong enough to recommend one over another.
“We don’t even know what the normal amount of bacteria should be to constitute an environment where the immune system develops ‘normally,’ “ she said.
Antibiotics should be prescribed cautiously and by following current recommendations to use the narrowest spectrum available, the authors wrote. Future research in antibiotic stewardship should incorporate biomarker-guided therapy to determine which patients might benefit most from antibiotic therapy.
“Practicing antibiotic stewardship needs recurrent attention and we hope that with this initiative, we specifically reach allergy doctors who will rethink their next [antibiotic] prescription. Within our EAACI task force, we will next work on a guideline for rational antibiotic use in asthma,” Dr. Tramper-Stranders said.
The review’s authors and Dr. Kwan have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Peanut allergy patients reap continuing benefits past first year, Palforzia study shows
A recent analysis of 142 peanut-allergic children treated for 1.5 to 2 years with a licensed oral immunotherapy (OIT) product confirms what various smaller studies have shown: Maintaining treatment for longer periods improves protection and reduces adverse effects. The findings offer some reassurance regarding the controversial approach, which has become available at a small number of clinics yet faces an uncertain future.
The new study, published July 28 in Allergy, included a subset of patients who chose to complete an extension of the phase 3 PALISADE trial of Palforzia, a proprietary set of premeasured peanut flour capsules developed by Aimmune Therapeutics.
Palforzia was approved last year for children aged 4 to 17 years with peanut allergy – one of the most common food allergies, affecting around 2% of children in the United States and Europe. The treatment is not a cure – patients must still watch what they eat and carry epinephrine for emergency reactions – but it helps build protection through daily ingestion of gradually increasing amounts of the allergen over a period of months.
In the 1-year PALISADE trial, which enrolled 496 peanut-allergic children at 66 sites in North America and Europe, participants received daily doses of study drug or placebo. The dose of the drug was escalated from 3 mg to 300 mg over 6 months; the 300-mg dose was then maintained for another 6 months. By the end of the study, about two-thirds of the children who underwent treatment could safely consume at least 600 mg of peanut protein, about the equivalent of two peanuts.
Could protection be increased with further treatment, and what would be required to sustain it? To address these questions, PALISADE patients who successfully reached the 600-mg threshold, along with those from the placebo group, were invited to participate in Aimmune’s open-label follow-on study. The extension study also explored whether protection could be maintained with less frequent dosing.
Among the 358 eligible participants who opted into the 1-year extension study, 256 came from the PALISADE treatment arm. These children were assigned to five cohorts to continue for 6 months or 12 months with daily or less frequent doses. Within the 6-month group, all started with the 300-mg daily dose. A subset received two doses a week. Within the 12-month group, some patients maintained daily dosing throughout; others received doses every other day, twice weekly, or once every 2 weeks.
The children who continued daily maintenance dosing the longest gained the most protection. Those in less-frequent dosing groups experienced more adverse events than those who received doses every day, the company reported last December in The Journal of Allergy and Clinical Immunology: In Practice.
More than a quarter (97 of 358, or 27.1%) of participants failed to complete the extension. Families could withdraw any time for any reason. Participating in an OIT trial is demanding – it requires office visits for dosing adjustments and blood tests, rest periods, keeping symptom logs in which daily doses are recorded, and possible allergic reactions from the treatment itself. “A common reason for ‘withdrawal of consent’ in clinical studies is the inconvenience of remaining in a long-term study,” Mohamed Yassine, MD, Aimmune’s senior vice present of medical affairs, said via email.
Attrition was concentrated within certain subgroups. Most participants in (88.7%; 102 of 115) PALISADE who received placebo elected to enter the open-label extension; nearly half did not finish. Dropout rates were also high (29.2%) for non-daily dosing participants who had come from the PALISADE treatment arm.
The authors did not report on those high-dropout groups. Instead, they focused their analysis on the 142 treated PALISADE participants who continued daily dosing through the extension – 110 patients for a total of about 1.5 years and 32 patients for about 2 years. In a subgroup analysis, 48.1% of children in the 1.5-year group upped their tolerance to 2,000 mg peanut protein, and even more (80.8%) in the 2-year group reached that threshold – all while taking a 300-mg maintenance dose.
Those who remained on treatment longer also had fewer adverse events. At the exit food challenge, 24% of the 1.5-year participants had reactions that required epinephrine, but among 2-year participants, only 3.8% needed the rescue medication.
Continuing therapy past the first year seemed to have additional benefits, Sandra Hong, MD, director of the Cleveland Clinic Food Allergy Center of Excellence, said in an interview. Dr. Hong was not involved in the new research and has no financial ties with Aimmune or other food allergy companies. “Not only can you ingest more, but your reaction when you do react is going to be less,” she says.
Palforzia is only available through a risk evaluation and mitigation strategy (REMS) program, which educates patients, health care professionals, and pharmacies about immunotherapy risks and precautionary measures. As of last summer, before Aimmune was acquired by Nestlé Health Science, about 100 allergists in the United States had enrolled patients in the REMS program. Families can find allergists who are certified to prescribe Palforzia using the website’s Certified Participant Locator.
Although the field at large remains apprehensive about OIT and other forms of immunotherapy, an estimated 200 or more U.S. clinics are administering home-grown OIT using commercial food products, says Richard Wasserman, an OIT pioneer whose clinic in Dallas has treated allergies to about 20 foods since the practice started offering the therapy in 2008. OIT practitioners have treated more than 15,000 food allergy patients nationwide, Dr. Wasserman said via email, yet they make up just a tiny fraction of the more than 6,000 board-certified allergists in the United States.
Whether using Palforzia or nonproprietary food products, oral immunotherapy requires a lot of time and effort – not just for patients but also practitioners. “You need more space. You need more staffing. Patients doing oral challenges stay in your office for 4 to 5 hours, and we have one-to-one nursing care for them,” said Dr. Hong. “So it’s a lot of resources.”
Her team has treated about 20 children with Palforzia since the Cleveland Clinic began offering the therapy last summer. Dr. Hong and coworkers have administered OIT using commercial peanut flour and peanut butter to some 80 peanut-allergic toddlers younger than 4 years who are too young to receive for the U.S. Food and Drug Administration–approved treatment. Their early data, which were presented at the annual meeting of the American Academy of Allergy, Asthma, and Immunology in February, suggest that toddlers get complete OIT more quickly with fewer side effects than older children, Dr. Hong says. A recent study of preschoolers in Canada also found that nonproprietary OIT is very safe and effective in this younger set and could be cost-saving in the long run.
By comparison, Palforzia, which has a list price of $890 per month, was judged to be less cost-effective in analyses by academic allergists and by the Institute for Clinical and Economic Review. But through a copay savings program, depending on their insurance coverage, some eligible families can pay as little as $20 per month for the FDA-approved treatment.
Because the therapy is time consuming for families and is resource intensive for practices, questions remain as to how long and how frequently patients need to remain on treatment to sustain protection. Do they need to keep taking Palforzia, or “can we switch them to an equivalent amount of food and not bother with the study drug?” said Edwin Kim, director of the UNC Food Allergy Initiative, Chapel Hill, North Carolina, and study investigator for several Palforzia trials, in an interview.
The Food Allergy Support Team, a nonprofit group started by Dr. Wasserman and colleagues, publishes best practices and meets annually to discuss research and protocols. However, the best maintenance dose, the best dosing frequency, and the duration of daily dosing that yields the best outcomes are not known, Dr. Wasserman says.
“We think the best way to answer that question is with a regulated, pharmaceutical-grade form of peanut protein,” Dr. Yassine said.
The field’s experience with Palforzia raises a dilemma: Does its approval legitimize oral immunotherapy in general, or will rigorous, multi-million dollar trials be needed to approve products for each food or combination of foods? About 32 million people in the United States have food allergies – about 1 in 10 adults and 1 in 13 children.
“I think the field has always grappled with that, honestly,” said Stacie Jones, MD, professor of pediatrics and chief of allergy and immunology at the University of Arkansas for Medical Sciences and Arkansas Children’s Hospital, Little Rock, in an interview. Home-grown OIT is “easier to do when you have high control of your small patient volumes or you’re in a clinical trial,” said Dr. Jones, who has served as an investigator on Palforzia trials and last year received more than $30,000 in consulting fees from Aimmune. “It becomes a very different situation when it becomes a national or an international recommended therapy.”
The Canadian Society of Allergy and Clinical Immunology has published clinical practice guidelines and provides practical information on its website on how to implement OIT – including protocols for dozens of foods and diary sheets for patients to log doses and symptoms.
However, U.S. professional societies still consider OIT investigational and suggest that it will not be approved by the FDA. “As a field, are we willing to wait 4 to 5 more years for an egg product? Should we? Are we willing?” said Dr. Kim. “These are tough questions.”
Stacie M. Jones reports advisory board fees, Aimmune Therapeutics, FARE; personal fees, DBV Technologies; clinical trials grants, Aimmune Therapeutics, DBV Technologies, Astellas, Sanofi, Regeneron, FARE, Genentech, and NIH-NIAID. Edwin Kim reports consultancy with Aimmune Therapeutics, Allako, AllerGenis, Belhaven Pharma, DBV Technologies, Duke Clinical Research Institute, and Nutricia; advisory board membership with ALK, DBV Technologies, Kenota Health, and Ukko; grant support from the NIH’s National Institute of Allergy and Infectious Diseases, National Center for Complementary and Integrative Health and Immune Tolerance Network; Food Allergy Research and Education, and the Wallace Research Foundation. Richard Wasserman receives consulting fees from Aimmune Therapeutics and DBV Technologies. Mohamed Yassine is employed by Aimmune Therapeutics. Sandra Hong has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A recent analysis of 142 peanut-allergic children treated for 1.5 to 2 years with a licensed oral immunotherapy (OIT) product confirms what various smaller studies have shown: Maintaining treatment for longer periods improves protection and reduces adverse effects. The findings offer some reassurance regarding the controversial approach, which has become available at a small number of clinics yet faces an uncertain future.
The new study, published July 28 in Allergy, included a subset of patients who chose to complete an extension of the phase 3 PALISADE trial of Palforzia, a proprietary set of premeasured peanut flour capsules developed by Aimmune Therapeutics.
Palforzia was approved last year for children aged 4 to 17 years with peanut allergy – one of the most common food allergies, affecting around 2% of children in the United States and Europe. The treatment is not a cure – patients must still watch what they eat and carry epinephrine for emergency reactions – but it helps build protection through daily ingestion of gradually increasing amounts of the allergen over a period of months.
In the 1-year PALISADE trial, which enrolled 496 peanut-allergic children at 66 sites in North America and Europe, participants received daily doses of study drug or placebo. The dose of the drug was escalated from 3 mg to 300 mg over 6 months; the 300-mg dose was then maintained for another 6 months. By the end of the study, about two-thirds of the children who underwent treatment could safely consume at least 600 mg of peanut protein, about the equivalent of two peanuts.
Could protection be increased with further treatment, and what would be required to sustain it? To address these questions, PALISADE patients who successfully reached the 600-mg threshold, along with those from the placebo group, were invited to participate in Aimmune’s open-label follow-on study. The extension study also explored whether protection could be maintained with less frequent dosing.
Among the 358 eligible participants who opted into the 1-year extension study, 256 came from the PALISADE treatment arm. These children were assigned to five cohorts to continue for 6 months or 12 months with daily or less frequent doses. Within the 6-month group, all started with the 300-mg daily dose. A subset received two doses a week. Within the 12-month group, some patients maintained daily dosing throughout; others received doses every other day, twice weekly, or once every 2 weeks.
The children who continued daily maintenance dosing the longest gained the most protection. Those in less-frequent dosing groups experienced more adverse events than those who received doses every day, the company reported last December in The Journal of Allergy and Clinical Immunology: In Practice.
More than a quarter (97 of 358, or 27.1%) of participants failed to complete the extension. Families could withdraw any time for any reason. Participating in an OIT trial is demanding – it requires office visits for dosing adjustments and blood tests, rest periods, keeping symptom logs in which daily doses are recorded, and possible allergic reactions from the treatment itself. “A common reason for ‘withdrawal of consent’ in clinical studies is the inconvenience of remaining in a long-term study,” Mohamed Yassine, MD, Aimmune’s senior vice present of medical affairs, said via email.
Attrition was concentrated within certain subgroups. Most participants in (88.7%; 102 of 115) PALISADE who received placebo elected to enter the open-label extension; nearly half did not finish. Dropout rates were also high (29.2%) for non-daily dosing participants who had come from the PALISADE treatment arm.
The authors did not report on those high-dropout groups. Instead, they focused their analysis on the 142 treated PALISADE participants who continued daily dosing through the extension – 110 patients for a total of about 1.5 years and 32 patients for about 2 years. In a subgroup analysis, 48.1% of children in the 1.5-year group upped their tolerance to 2,000 mg peanut protein, and even more (80.8%) in the 2-year group reached that threshold – all while taking a 300-mg maintenance dose.
Those who remained on treatment longer also had fewer adverse events. At the exit food challenge, 24% of the 1.5-year participants had reactions that required epinephrine, but among 2-year participants, only 3.8% needed the rescue medication.
Continuing therapy past the first year seemed to have additional benefits, Sandra Hong, MD, director of the Cleveland Clinic Food Allergy Center of Excellence, said in an interview. Dr. Hong was not involved in the new research and has no financial ties with Aimmune or other food allergy companies. “Not only can you ingest more, but your reaction when you do react is going to be less,” she says.
Palforzia is only available through a risk evaluation and mitigation strategy (REMS) program, which educates patients, health care professionals, and pharmacies about immunotherapy risks and precautionary measures. As of last summer, before Aimmune was acquired by Nestlé Health Science, about 100 allergists in the United States had enrolled patients in the REMS program. Families can find allergists who are certified to prescribe Palforzia using the website’s Certified Participant Locator.
Although the field at large remains apprehensive about OIT and other forms of immunotherapy, an estimated 200 or more U.S. clinics are administering home-grown OIT using commercial food products, says Richard Wasserman, an OIT pioneer whose clinic in Dallas has treated allergies to about 20 foods since the practice started offering the therapy in 2008. OIT practitioners have treated more than 15,000 food allergy patients nationwide, Dr. Wasserman said via email, yet they make up just a tiny fraction of the more than 6,000 board-certified allergists in the United States.
Whether using Palforzia or nonproprietary food products, oral immunotherapy requires a lot of time and effort – not just for patients but also practitioners. “You need more space. You need more staffing. Patients doing oral challenges stay in your office for 4 to 5 hours, and we have one-to-one nursing care for them,” said Dr. Hong. “So it’s a lot of resources.”
Her team has treated about 20 children with Palforzia since the Cleveland Clinic began offering the therapy last summer. Dr. Hong and coworkers have administered OIT using commercial peanut flour and peanut butter to some 80 peanut-allergic toddlers younger than 4 years who are too young to receive for the U.S. Food and Drug Administration–approved treatment. Their early data, which were presented at the annual meeting of the American Academy of Allergy, Asthma, and Immunology in February, suggest that toddlers get complete OIT more quickly with fewer side effects than older children, Dr. Hong says. A recent study of preschoolers in Canada also found that nonproprietary OIT is very safe and effective in this younger set and could be cost-saving in the long run.
By comparison, Palforzia, which has a list price of $890 per month, was judged to be less cost-effective in analyses by academic allergists and by the Institute for Clinical and Economic Review. But through a copay savings program, depending on their insurance coverage, some eligible families can pay as little as $20 per month for the FDA-approved treatment.
Because the therapy is time consuming for families and is resource intensive for practices, questions remain as to how long and how frequently patients need to remain on treatment to sustain protection. Do they need to keep taking Palforzia, or “can we switch them to an equivalent amount of food and not bother with the study drug?” said Edwin Kim, director of the UNC Food Allergy Initiative, Chapel Hill, North Carolina, and study investigator for several Palforzia trials, in an interview.
The Food Allergy Support Team, a nonprofit group started by Dr. Wasserman and colleagues, publishes best practices and meets annually to discuss research and protocols. However, the best maintenance dose, the best dosing frequency, and the duration of daily dosing that yields the best outcomes are not known, Dr. Wasserman says.
“We think the best way to answer that question is with a regulated, pharmaceutical-grade form of peanut protein,” Dr. Yassine said.
The field’s experience with Palforzia raises a dilemma: Does its approval legitimize oral immunotherapy in general, or will rigorous, multi-million dollar trials be needed to approve products for each food or combination of foods? About 32 million people in the United States have food allergies – about 1 in 10 adults and 1 in 13 children.
“I think the field has always grappled with that, honestly,” said Stacie Jones, MD, professor of pediatrics and chief of allergy and immunology at the University of Arkansas for Medical Sciences and Arkansas Children’s Hospital, Little Rock, in an interview. Home-grown OIT is “easier to do when you have high control of your small patient volumes or you’re in a clinical trial,” said Dr. Jones, who has served as an investigator on Palforzia trials and last year received more than $30,000 in consulting fees from Aimmune. “It becomes a very different situation when it becomes a national or an international recommended therapy.”
The Canadian Society of Allergy and Clinical Immunology has published clinical practice guidelines and provides practical information on its website on how to implement OIT – including protocols for dozens of foods and diary sheets for patients to log doses and symptoms.
However, U.S. professional societies still consider OIT investigational and suggest that it will not be approved by the FDA. “As a field, are we willing to wait 4 to 5 more years for an egg product? Should we? Are we willing?” said Dr. Kim. “These are tough questions.”
Stacie M. Jones reports advisory board fees, Aimmune Therapeutics, FARE; personal fees, DBV Technologies; clinical trials grants, Aimmune Therapeutics, DBV Technologies, Astellas, Sanofi, Regeneron, FARE, Genentech, and NIH-NIAID. Edwin Kim reports consultancy with Aimmune Therapeutics, Allako, AllerGenis, Belhaven Pharma, DBV Technologies, Duke Clinical Research Institute, and Nutricia; advisory board membership with ALK, DBV Technologies, Kenota Health, and Ukko; grant support from the NIH’s National Institute of Allergy and Infectious Diseases, National Center for Complementary and Integrative Health and Immune Tolerance Network; Food Allergy Research and Education, and the Wallace Research Foundation. Richard Wasserman receives consulting fees from Aimmune Therapeutics and DBV Technologies. Mohamed Yassine is employed by Aimmune Therapeutics. Sandra Hong has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A recent analysis of 142 peanut-allergic children treated for 1.5 to 2 years with a licensed oral immunotherapy (OIT) product confirms what various smaller studies have shown: Maintaining treatment for longer periods improves protection and reduces adverse effects. The findings offer some reassurance regarding the controversial approach, which has become available at a small number of clinics yet faces an uncertain future.
The new study, published July 28 in Allergy, included a subset of patients who chose to complete an extension of the phase 3 PALISADE trial of Palforzia, a proprietary set of premeasured peanut flour capsules developed by Aimmune Therapeutics.
Palforzia was approved last year for children aged 4 to 17 years with peanut allergy – one of the most common food allergies, affecting around 2% of children in the United States and Europe. The treatment is not a cure – patients must still watch what they eat and carry epinephrine for emergency reactions – but it helps build protection through daily ingestion of gradually increasing amounts of the allergen over a period of months.
In the 1-year PALISADE trial, which enrolled 496 peanut-allergic children at 66 sites in North America and Europe, participants received daily doses of study drug or placebo. The dose of the drug was escalated from 3 mg to 300 mg over 6 months; the 300-mg dose was then maintained for another 6 months. By the end of the study, about two-thirds of the children who underwent treatment could safely consume at least 600 mg of peanut protein, about the equivalent of two peanuts.
Could protection be increased with further treatment, and what would be required to sustain it? To address these questions, PALISADE patients who successfully reached the 600-mg threshold, along with those from the placebo group, were invited to participate in Aimmune’s open-label follow-on study. The extension study also explored whether protection could be maintained with less frequent dosing.
Among the 358 eligible participants who opted into the 1-year extension study, 256 came from the PALISADE treatment arm. These children were assigned to five cohorts to continue for 6 months or 12 months with daily or less frequent doses. Within the 6-month group, all started with the 300-mg daily dose. A subset received two doses a week. Within the 12-month group, some patients maintained daily dosing throughout; others received doses every other day, twice weekly, or once every 2 weeks.
The children who continued daily maintenance dosing the longest gained the most protection. Those in less-frequent dosing groups experienced more adverse events than those who received doses every day, the company reported last December in The Journal of Allergy and Clinical Immunology: In Practice.
More than a quarter (97 of 358, or 27.1%) of participants failed to complete the extension. Families could withdraw any time for any reason. Participating in an OIT trial is demanding – it requires office visits for dosing adjustments and blood tests, rest periods, keeping symptom logs in which daily doses are recorded, and possible allergic reactions from the treatment itself. “A common reason for ‘withdrawal of consent’ in clinical studies is the inconvenience of remaining in a long-term study,” Mohamed Yassine, MD, Aimmune’s senior vice present of medical affairs, said via email.
Attrition was concentrated within certain subgroups. Most participants in (88.7%; 102 of 115) PALISADE who received placebo elected to enter the open-label extension; nearly half did not finish. Dropout rates were also high (29.2%) for non-daily dosing participants who had come from the PALISADE treatment arm.
The authors did not report on those high-dropout groups. Instead, they focused their analysis on the 142 treated PALISADE participants who continued daily dosing through the extension – 110 patients for a total of about 1.5 years and 32 patients for about 2 years. In a subgroup analysis, 48.1% of children in the 1.5-year group upped their tolerance to 2,000 mg peanut protein, and even more (80.8%) in the 2-year group reached that threshold – all while taking a 300-mg maintenance dose.
Those who remained on treatment longer also had fewer adverse events. At the exit food challenge, 24% of the 1.5-year participants had reactions that required epinephrine, but among 2-year participants, only 3.8% needed the rescue medication.
Continuing therapy past the first year seemed to have additional benefits, Sandra Hong, MD, director of the Cleveland Clinic Food Allergy Center of Excellence, said in an interview. Dr. Hong was not involved in the new research and has no financial ties with Aimmune or other food allergy companies. “Not only can you ingest more, but your reaction when you do react is going to be less,” she says.
Palforzia is only available through a risk evaluation and mitigation strategy (REMS) program, which educates patients, health care professionals, and pharmacies about immunotherapy risks and precautionary measures. As of last summer, before Aimmune was acquired by Nestlé Health Science, about 100 allergists in the United States had enrolled patients in the REMS program. Families can find allergists who are certified to prescribe Palforzia using the website’s Certified Participant Locator.
Although the field at large remains apprehensive about OIT and other forms of immunotherapy, an estimated 200 or more U.S. clinics are administering home-grown OIT using commercial food products, says Richard Wasserman, an OIT pioneer whose clinic in Dallas has treated allergies to about 20 foods since the practice started offering the therapy in 2008. OIT practitioners have treated more than 15,000 food allergy patients nationwide, Dr. Wasserman said via email, yet they make up just a tiny fraction of the more than 6,000 board-certified allergists in the United States.
Whether using Palforzia or nonproprietary food products, oral immunotherapy requires a lot of time and effort – not just for patients but also practitioners. “You need more space. You need more staffing. Patients doing oral challenges stay in your office for 4 to 5 hours, and we have one-to-one nursing care for them,” said Dr. Hong. “So it’s a lot of resources.”
Her team has treated about 20 children with Palforzia since the Cleveland Clinic began offering the therapy last summer. Dr. Hong and coworkers have administered OIT using commercial peanut flour and peanut butter to some 80 peanut-allergic toddlers younger than 4 years who are too young to receive for the U.S. Food and Drug Administration–approved treatment. Their early data, which were presented at the annual meeting of the American Academy of Allergy, Asthma, and Immunology in February, suggest that toddlers get complete OIT more quickly with fewer side effects than older children, Dr. Hong says. A recent study of preschoolers in Canada also found that nonproprietary OIT is very safe and effective in this younger set and could be cost-saving in the long run.
By comparison, Palforzia, which has a list price of $890 per month, was judged to be less cost-effective in analyses by academic allergists and by the Institute for Clinical and Economic Review. But through a copay savings program, depending on their insurance coverage, some eligible families can pay as little as $20 per month for the FDA-approved treatment.
Because the therapy is time consuming for families and is resource intensive for practices, questions remain as to how long and how frequently patients need to remain on treatment to sustain protection. Do they need to keep taking Palforzia, or “can we switch them to an equivalent amount of food and not bother with the study drug?” said Edwin Kim, director of the UNC Food Allergy Initiative, Chapel Hill, North Carolina, and study investigator for several Palforzia trials, in an interview.
The Food Allergy Support Team, a nonprofit group started by Dr. Wasserman and colleagues, publishes best practices and meets annually to discuss research and protocols. However, the best maintenance dose, the best dosing frequency, and the duration of daily dosing that yields the best outcomes are not known, Dr. Wasserman says.
“We think the best way to answer that question is with a regulated, pharmaceutical-grade form of peanut protein,” Dr. Yassine said.
The field’s experience with Palforzia raises a dilemma: Does its approval legitimize oral immunotherapy in general, or will rigorous, multi-million dollar trials be needed to approve products for each food or combination of foods? About 32 million people in the United States have food allergies – about 1 in 10 adults and 1 in 13 children.
“I think the field has always grappled with that, honestly,” said Stacie Jones, MD, professor of pediatrics and chief of allergy and immunology at the University of Arkansas for Medical Sciences and Arkansas Children’s Hospital, Little Rock, in an interview. Home-grown OIT is “easier to do when you have high control of your small patient volumes or you’re in a clinical trial,” said Dr. Jones, who has served as an investigator on Palforzia trials and last year received more than $30,000 in consulting fees from Aimmune. “It becomes a very different situation when it becomes a national or an international recommended therapy.”
The Canadian Society of Allergy and Clinical Immunology has published clinical practice guidelines and provides practical information on its website on how to implement OIT – including protocols for dozens of foods and diary sheets for patients to log doses and symptoms.
However, U.S. professional societies still consider OIT investigational and suggest that it will not be approved by the FDA. “As a field, are we willing to wait 4 to 5 more years for an egg product? Should we? Are we willing?” said Dr. Kim. “These are tough questions.”
Stacie M. Jones reports advisory board fees, Aimmune Therapeutics, FARE; personal fees, DBV Technologies; clinical trials grants, Aimmune Therapeutics, DBV Technologies, Astellas, Sanofi, Regeneron, FARE, Genentech, and NIH-NIAID. Edwin Kim reports consultancy with Aimmune Therapeutics, Allako, AllerGenis, Belhaven Pharma, DBV Technologies, Duke Clinical Research Institute, and Nutricia; advisory board membership with ALK, DBV Technologies, Kenota Health, and Ukko; grant support from the NIH’s National Institute of Allergy and Infectious Diseases, National Center for Complementary and Integrative Health and Immune Tolerance Network; Food Allergy Research and Education, and the Wallace Research Foundation. Richard Wasserman receives consulting fees from Aimmune Therapeutics and DBV Technologies. Mohamed Yassine is employed by Aimmune Therapeutics. Sandra Hong has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Bronchitis the leader at putting children in the hospital
About 7% (99,000) of the 1.47 million nonmaternal, nonneonatal hospital stays in children aged 0-17 years involved a primary diagnosis of acute bronchitis in 2018, representing the leading cause of admissions in boys (154.7 stays per 100,000 population) and the second-leading diagnosis in girls (113.1 stays per 100,000), Kimberly W. McDermott, PhD, and Marc Roemer, MS, said in a statistical brief.
Depressive disorders were the most common primary diagnosis in girls, with a rate of 176.7 stays per 100,000, and the second-leading diagnosis overall, although the rate was less than half that (74.0 per 100,000) in boys. Two other respiratory conditions, asthma and pneumonia, were among the top five for both girls and boys, as was epilepsy, they reported.
The combined rate for all diagnoses was slightly higher for boys, 2,051 per 100,000, compared with 1,922 for girls, they said based on data from the National Inpatient Sample.
“Identifying the most frequent primary conditions for which patients are admitted to the hospital is important to the implementation and improvement of health care delivery, quality initiatives, and health policy,” said Dr. McDermott of IBM Watson Health and Mr. Roemer of the AHRQ.
About 7% (99,000) of the 1.47 million nonmaternal, nonneonatal hospital stays in children aged 0-17 years involved a primary diagnosis of acute bronchitis in 2018, representing the leading cause of admissions in boys (154.7 stays per 100,000 population) and the second-leading diagnosis in girls (113.1 stays per 100,000), Kimberly W. McDermott, PhD, and Marc Roemer, MS, said in a statistical brief.
Depressive disorders were the most common primary diagnosis in girls, with a rate of 176.7 stays per 100,000, and the second-leading diagnosis overall, although the rate was less than half that (74.0 per 100,000) in boys. Two other respiratory conditions, asthma and pneumonia, were among the top five for both girls and boys, as was epilepsy, they reported.
The combined rate for all diagnoses was slightly higher for boys, 2,051 per 100,000, compared with 1,922 for girls, they said based on data from the National Inpatient Sample.
“Identifying the most frequent primary conditions for which patients are admitted to the hospital is important to the implementation and improvement of health care delivery, quality initiatives, and health policy,” said Dr. McDermott of IBM Watson Health and Mr. Roemer of the AHRQ.
About 7% (99,000) of the 1.47 million nonmaternal, nonneonatal hospital stays in children aged 0-17 years involved a primary diagnosis of acute bronchitis in 2018, representing the leading cause of admissions in boys (154.7 stays per 100,000 population) and the second-leading diagnosis in girls (113.1 stays per 100,000), Kimberly W. McDermott, PhD, and Marc Roemer, MS, said in a statistical brief.
Depressive disorders were the most common primary diagnosis in girls, with a rate of 176.7 stays per 100,000, and the second-leading diagnosis overall, although the rate was less than half that (74.0 per 100,000) in boys. Two other respiratory conditions, asthma and pneumonia, were among the top five for both girls and boys, as was epilepsy, they reported.
The combined rate for all diagnoses was slightly higher for boys, 2,051 per 100,000, compared with 1,922 for girls, they said based on data from the National Inpatient Sample.
“Identifying the most frequent primary conditions for which patients are admitted to the hospital is important to the implementation and improvement of health care delivery, quality initiatives, and health policy,” said Dr. McDermott of IBM Watson Health and Mr. Roemer of the AHRQ.
No link between childhood vaccinations and allergies or asthma
A meta-analysis by Australian researchers found no link between childhood vaccinations and an increase in allergies and asthma. In fact, children who received the BCG vaccine actually had a lesser incidence of eczema than other children, but there was no difference shown in any of the allergies or asthma.
The researchers, in a report published in the journal Allergy, write, “We found no evidence that childhood vaccination with commonly administered vaccines was associated with increased risk of later allergic disease.”
“Allergies have increased worldwide in the last 50 years, and in developed countries, earlier,” said study author Caroline J. Lodge, PhD, principal research fellow at the University of Melbourne, in an interview. “In developing countries, it is still a crisis.” No one knows why, she said. That was the reason for the recent study.
Allergic diseases such as allergic rhinitis (hay fever) and food allergies have a serious influence on quality of life, and the incidence is growing. According to the Global Asthma Network, there are 334 million people living with asthma. Between 2%-10% of adults have atopic eczema, and more than a 250,000 people have food allergies. This coincides temporally with an increase in mass vaccination of children.
Unlike the controversy surrounding vaccinations and autism, which has long been debunked as baseless, a hygiene hypothesis postulates that when children acquire immunity from many diseases, they become vulnerable to allergic reactions. Thanks to vaccinations, children in the developed world now are routinely immune to dozens of diseases.
That immunity leads to suppression of a major antibody response, increasing sensitivity to allergens and allergic disease. Suspicion of a link with childhood vaccinations has been used by opponents of vaccines in lobbying campaigns jeopardizing the sustainability of vaccine programs. In recent days, for example, the state of Tennessee has halted a program to encourage vaccination for COVID-19 as well as all other vaccinations, the result of pressure on the state by anti-vaccination lobbying.
But the Melbourne researchers reported that the meta-analysis of 42 published research studies doesn’t support the vaccine–allergy hypothesis. Using PubMed and EMBASE records between January 1946 and January 2018, researchers selected studies to be included in the analysis, looking for allergic outcomes in children given BCG or vaccines for measles or pertussis. Thirty-five publications reported cohort studies, and seven were based on randomized controlled trials.
The Australian study is not the only one showing the same lack of linkage between vaccination and allergy. The International Study of Asthma and Allergies in Childhood (ISAAC) found no association between mass vaccination and atopic disease. A 1998 Swedish study of 669 children found no differences in the incidence of allergic diseases between those who received pertussis vaccine and those who did not.
“The bottom line is that vaccines prevent infectious diseases,” said Matthew B. Laurens, associate professor of pediatrics at the University of Maryland, Baltimore, in an interview. Dr. Laurens was not part of the Australian study.
“Large-scale epidemiological studies do not support the theory that vaccines are associated with an increased risk of allergy or asthma,” he stressed. “Parents should not be deterred from vaccinating their children because of fears that this would increase risks of allergy and/or asthma.”
Dr. Lodge and Dr. Laurens have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A meta-analysis by Australian researchers found no link between childhood vaccinations and an increase in allergies and asthma. In fact, children who received the BCG vaccine actually had a lesser incidence of eczema than other children, but there was no difference shown in any of the allergies or asthma.
The researchers, in a report published in the journal Allergy, write, “We found no evidence that childhood vaccination with commonly administered vaccines was associated with increased risk of later allergic disease.”
“Allergies have increased worldwide in the last 50 years, and in developed countries, earlier,” said study author Caroline J. Lodge, PhD, principal research fellow at the University of Melbourne, in an interview. “In developing countries, it is still a crisis.” No one knows why, she said. That was the reason for the recent study.
Allergic diseases such as allergic rhinitis (hay fever) and food allergies have a serious influence on quality of life, and the incidence is growing. According to the Global Asthma Network, there are 334 million people living with asthma. Between 2%-10% of adults have atopic eczema, and more than a 250,000 people have food allergies. This coincides temporally with an increase in mass vaccination of children.
Unlike the controversy surrounding vaccinations and autism, which has long been debunked as baseless, a hygiene hypothesis postulates that when children acquire immunity from many diseases, they become vulnerable to allergic reactions. Thanks to vaccinations, children in the developed world now are routinely immune to dozens of diseases.
That immunity leads to suppression of a major antibody response, increasing sensitivity to allergens and allergic disease. Suspicion of a link with childhood vaccinations has been used by opponents of vaccines in lobbying campaigns jeopardizing the sustainability of vaccine programs. In recent days, for example, the state of Tennessee has halted a program to encourage vaccination for COVID-19 as well as all other vaccinations, the result of pressure on the state by anti-vaccination lobbying.
But the Melbourne researchers reported that the meta-analysis of 42 published research studies doesn’t support the vaccine–allergy hypothesis. Using PubMed and EMBASE records between January 1946 and January 2018, researchers selected studies to be included in the analysis, looking for allergic outcomes in children given BCG or vaccines for measles or pertussis. Thirty-five publications reported cohort studies, and seven were based on randomized controlled trials.
The Australian study is not the only one showing the same lack of linkage between vaccination and allergy. The International Study of Asthma and Allergies in Childhood (ISAAC) found no association between mass vaccination and atopic disease. A 1998 Swedish study of 669 children found no differences in the incidence of allergic diseases between those who received pertussis vaccine and those who did not.
“The bottom line is that vaccines prevent infectious diseases,” said Matthew B. Laurens, associate professor of pediatrics at the University of Maryland, Baltimore, in an interview. Dr. Laurens was not part of the Australian study.
“Large-scale epidemiological studies do not support the theory that vaccines are associated with an increased risk of allergy or asthma,” he stressed. “Parents should not be deterred from vaccinating their children because of fears that this would increase risks of allergy and/or asthma.”
Dr. Lodge and Dr. Laurens have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A meta-analysis by Australian researchers found no link between childhood vaccinations and an increase in allergies and asthma. In fact, children who received the BCG vaccine actually had a lesser incidence of eczema than other children, but there was no difference shown in any of the allergies or asthma.
The researchers, in a report published in the journal Allergy, write, “We found no evidence that childhood vaccination with commonly administered vaccines was associated with increased risk of later allergic disease.”
“Allergies have increased worldwide in the last 50 years, and in developed countries, earlier,” said study author Caroline J. Lodge, PhD, principal research fellow at the University of Melbourne, in an interview. “In developing countries, it is still a crisis.” No one knows why, she said. That was the reason for the recent study.
Allergic diseases such as allergic rhinitis (hay fever) and food allergies have a serious influence on quality of life, and the incidence is growing. According to the Global Asthma Network, there are 334 million people living with asthma. Between 2%-10% of adults have atopic eczema, and more than a 250,000 people have food allergies. This coincides temporally with an increase in mass vaccination of children.
Unlike the controversy surrounding vaccinations and autism, which has long been debunked as baseless, a hygiene hypothesis postulates that when children acquire immunity from many diseases, they become vulnerable to allergic reactions. Thanks to vaccinations, children in the developed world now are routinely immune to dozens of diseases.
That immunity leads to suppression of a major antibody response, increasing sensitivity to allergens and allergic disease. Suspicion of a link with childhood vaccinations has been used by opponents of vaccines in lobbying campaigns jeopardizing the sustainability of vaccine programs. In recent days, for example, the state of Tennessee has halted a program to encourage vaccination for COVID-19 as well as all other vaccinations, the result of pressure on the state by anti-vaccination lobbying.
But the Melbourne researchers reported that the meta-analysis of 42 published research studies doesn’t support the vaccine–allergy hypothesis. Using PubMed and EMBASE records between January 1946 and January 2018, researchers selected studies to be included in the analysis, looking for allergic outcomes in children given BCG or vaccines for measles or pertussis. Thirty-five publications reported cohort studies, and seven were based on randomized controlled trials.
The Australian study is not the only one showing the same lack of linkage between vaccination and allergy. The International Study of Asthma and Allergies in Childhood (ISAAC) found no association between mass vaccination and atopic disease. A 1998 Swedish study of 669 children found no differences in the incidence of allergic diseases between those who received pertussis vaccine and those who did not.
“The bottom line is that vaccines prevent infectious diseases,” said Matthew B. Laurens, associate professor of pediatrics at the University of Maryland, Baltimore, in an interview. Dr. Laurens was not part of the Australian study.
“Large-scale epidemiological studies do not support the theory that vaccines are associated with an increased risk of allergy or asthma,” he stressed. “Parents should not be deterred from vaccinating their children because of fears that this would increase risks of allergy and/or asthma.”
Dr. Lodge and Dr. Laurens have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Dupilumab safe, effective in kids 6-11 with moderate-to-severe asthma
Dupilumab (Dupixent, Sanofi and Regeneron) significantly reduced exacerbations compared with placebo in children ages 6-11 years who had moderate-to-severe asthma in a phase 3 trial.
A fully human monoclonal antibody, dupilumab also improved lung function versus placebo by week 12, an improvement that lasted the length of the 52-week trial.
Dupilumab previously had been shown to be safe and effective in adolescents and adults with moderate-to-severe asthma, patients 6 years and older with moderate-to-severe atopic dermatitis, and adults with chronic rhinosinusitis with nasal polyposis, but its safety and effectiveness for moderate-to-severe asthma in the 6-11 years age group was not known.
Results from the randomized, double-blind VOYAGE study conducted across several countries were presented Saturday, July 10, at the European Academy of Allergy and Clinical Immunology (EAACI) Hybrid Congress 2021.
Leonard B. Bacharier, MD, professor of pediatrics, allergy/immunology/pulmonary medicine at Vanderbilt University Medical Center in Nashville, Tennessee, presented the results from the trial, which was funded by Sanofi/Regeneron.
Researchers enrolled 408 children ages 6-11 years with uncontrolled moderate-to-severe asthma. Children on high-dose inhaled corticosteroids (ICS) alone or medium-to-high–dose ICS with a second controller were randomly assigned either to add-on subcutaneous dupilumab 100 mg or 200 mg, based on body weight at study start, or to placebo every 2 weeks for 52 weeks.
Analyses were done in two populations: 350 patients with markers of type 2 inflammation (baseline blood eosinophils ≥150 cells/μl or fractional exhaled nitric oxide [FeNO] ≥20 ppb) and 259 patients with baseline blood eosinophils ≥300 cells/µl.
“The primary endpoint was the annualized rate of severe asthma exacerbations,” Dr. Bacharier said. “The key secondary endpoint was change in percent predicted prebronchodilator FEV1 [forced expiratory volume at 1 second] from baseline to week 12.”
At week 12, the annualized severe asthma exacerbation rate was reduced by 59% (P < .0001) in children with blood eosinophils ≥300 cells/µL and results were similar in those with the type 2 inflammatory phenotype compared with placebo.
Results also indicate a favorable safety profile for dupilumab.
James M. Tracy, DO, an expert with the American College of Allergy, Asthma, and Immunology, told this news organization that adding the dupilumab option for children in the 6-11 age group is “huge.”
Dr. Tracy, who was not involved with the study, said although omalizumab (Xolair, Genentech) is also available for these children, dupilumab stands out because of the range of comorbidities it can treat.
“[Children] don’t have the same rhinosinusitis and polyposis that adults would have, but a lot of them have eczema, and this drug with multiple prongs is incredibly useful and addresses a broad array of allergic conditions,” Dr. Tracy said.
More than 90% of children in the study had at least one concurrent type 2 inflammatory condition, including atopic dermatitis and eosinophilic esophagitis. Dupilumab blocks the shared receptor for interleukin (IL)-4/IL-13, which are key drivers of type 2 inflammation in multiple diseases.
Dr. Tracy said that while dupilumab is not the only drug available to treat children 6-11 years with moderate-to-severe asthma, it is “a significant and unique addition to the armamentarium of the individual practitioner taking care of these very severe asthmatics in the 6-11 age group.”
Dupilumab also led to rapid and sustained improvement in lung function. At 12 weeks, children assigned dupilumab improved their lung function as measured by FEV1 by 5.21% (P = .0009), and that continued through the 52-week study period.
“What we know is the [improved lung function] effect is sustained. What we don’t know is how long you have to keep on the drug for a more permanent effect, which is an issue for all these biologics,” Tracy said.
Dr. Bacharier reported speaker fees and research support from Sanofi/Regeneron. Dr. Tracy has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Dupilumab (Dupixent, Sanofi and Regeneron) significantly reduced exacerbations compared with placebo in children ages 6-11 years who had moderate-to-severe asthma in a phase 3 trial.
A fully human monoclonal antibody, dupilumab also improved lung function versus placebo by week 12, an improvement that lasted the length of the 52-week trial.
Dupilumab previously had been shown to be safe and effective in adolescents and adults with moderate-to-severe asthma, patients 6 years and older with moderate-to-severe atopic dermatitis, and adults with chronic rhinosinusitis with nasal polyposis, but its safety and effectiveness for moderate-to-severe asthma in the 6-11 years age group was not known.
Results from the randomized, double-blind VOYAGE study conducted across several countries were presented Saturday, July 10, at the European Academy of Allergy and Clinical Immunology (EAACI) Hybrid Congress 2021.
Leonard B. Bacharier, MD, professor of pediatrics, allergy/immunology/pulmonary medicine at Vanderbilt University Medical Center in Nashville, Tennessee, presented the results from the trial, which was funded by Sanofi/Regeneron.
Researchers enrolled 408 children ages 6-11 years with uncontrolled moderate-to-severe asthma. Children on high-dose inhaled corticosteroids (ICS) alone or medium-to-high–dose ICS with a second controller were randomly assigned either to add-on subcutaneous dupilumab 100 mg or 200 mg, based on body weight at study start, or to placebo every 2 weeks for 52 weeks.
Analyses were done in two populations: 350 patients with markers of type 2 inflammation (baseline blood eosinophils ≥150 cells/μl or fractional exhaled nitric oxide [FeNO] ≥20 ppb) and 259 patients with baseline blood eosinophils ≥300 cells/µl.
“The primary endpoint was the annualized rate of severe asthma exacerbations,” Dr. Bacharier said. “The key secondary endpoint was change in percent predicted prebronchodilator FEV1 [forced expiratory volume at 1 second] from baseline to week 12.”
At week 12, the annualized severe asthma exacerbation rate was reduced by 59% (P < .0001) in children with blood eosinophils ≥300 cells/µL and results were similar in those with the type 2 inflammatory phenotype compared with placebo.
Results also indicate a favorable safety profile for dupilumab.
James M. Tracy, DO, an expert with the American College of Allergy, Asthma, and Immunology, told this news organization that adding the dupilumab option for children in the 6-11 age group is “huge.”
Dr. Tracy, who was not involved with the study, said although omalizumab (Xolair, Genentech) is also available for these children, dupilumab stands out because of the range of comorbidities it can treat.
“[Children] don’t have the same rhinosinusitis and polyposis that adults would have, but a lot of them have eczema, and this drug with multiple prongs is incredibly useful and addresses a broad array of allergic conditions,” Dr. Tracy said.
More than 90% of children in the study had at least one concurrent type 2 inflammatory condition, including atopic dermatitis and eosinophilic esophagitis. Dupilumab blocks the shared receptor for interleukin (IL)-4/IL-13, which are key drivers of type 2 inflammation in multiple diseases.
Dr. Tracy said that while dupilumab is not the only drug available to treat children 6-11 years with moderate-to-severe asthma, it is “a significant and unique addition to the armamentarium of the individual practitioner taking care of these very severe asthmatics in the 6-11 age group.”
Dupilumab also led to rapid and sustained improvement in lung function. At 12 weeks, children assigned dupilumab improved their lung function as measured by FEV1 by 5.21% (P = .0009), and that continued through the 52-week study period.
“What we know is the [improved lung function] effect is sustained. What we don’t know is how long you have to keep on the drug for a more permanent effect, which is an issue for all these biologics,” Tracy said.
Dr. Bacharier reported speaker fees and research support from Sanofi/Regeneron. Dr. Tracy has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Dupilumab (Dupixent, Sanofi and Regeneron) significantly reduced exacerbations compared with placebo in children ages 6-11 years who had moderate-to-severe asthma in a phase 3 trial.
A fully human monoclonal antibody, dupilumab also improved lung function versus placebo by week 12, an improvement that lasted the length of the 52-week trial.
Dupilumab previously had been shown to be safe and effective in adolescents and adults with moderate-to-severe asthma, patients 6 years and older with moderate-to-severe atopic dermatitis, and adults with chronic rhinosinusitis with nasal polyposis, but its safety and effectiveness for moderate-to-severe asthma in the 6-11 years age group was not known.
Results from the randomized, double-blind VOYAGE study conducted across several countries were presented Saturday, July 10, at the European Academy of Allergy and Clinical Immunology (EAACI) Hybrid Congress 2021.
Leonard B. Bacharier, MD, professor of pediatrics, allergy/immunology/pulmonary medicine at Vanderbilt University Medical Center in Nashville, Tennessee, presented the results from the trial, which was funded by Sanofi/Regeneron.
Researchers enrolled 408 children ages 6-11 years with uncontrolled moderate-to-severe asthma. Children on high-dose inhaled corticosteroids (ICS) alone or medium-to-high–dose ICS with a second controller were randomly assigned either to add-on subcutaneous dupilumab 100 mg or 200 mg, based on body weight at study start, or to placebo every 2 weeks for 52 weeks.
Analyses were done in two populations: 350 patients with markers of type 2 inflammation (baseline blood eosinophils ≥150 cells/μl or fractional exhaled nitric oxide [FeNO] ≥20 ppb) and 259 patients with baseline blood eosinophils ≥300 cells/µl.
“The primary endpoint was the annualized rate of severe asthma exacerbations,” Dr. Bacharier said. “The key secondary endpoint was change in percent predicted prebronchodilator FEV1 [forced expiratory volume at 1 second] from baseline to week 12.”
At week 12, the annualized severe asthma exacerbation rate was reduced by 59% (P < .0001) in children with blood eosinophils ≥300 cells/µL and results were similar in those with the type 2 inflammatory phenotype compared with placebo.
Results also indicate a favorable safety profile for dupilumab.
James M. Tracy, DO, an expert with the American College of Allergy, Asthma, and Immunology, told this news organization that adding the dupilumab option for children in the 6-11 age group is “huge.”
Dr. Tracy, who was not involved with the study, said although omalizumab (Xolair, Genentech) is also available for these children, dupilumab stands out because of the range of comorbidities it can treat.
“[Children] don’t have the same rhinosinusitis and polyposis that adults would have, but a lot of them have eczema, and this drug with multiple prongs is incredibly useful and addresses a broad array of allergic conditions,” Dr. Tracy said.
More than 90% of children in the study had at least one concurrent type 2 inflammatory condition, including atopic dermatitis and eosinophilic esophagitis. Dupilumab blocks the shared receptor for interleukin (IL)-4/IL-13, which are key drivers of type 2 inflammation in multiple diseases.
Dr. Tracy said that while dupilumab is not the only drug available to treat children 6-11 years with moderate-to-severe asthma, it is “a significant and unique addition to the armamentarium of the individual practitioner taking care of these very severe asthmatics in the 6-11 age group.”
Dupilumab also led to rapid and sustained improvement in lung function. At 12 weeks, children assigned dupilumab improved their lung function as measured by FEV1 by 5.21% (P = .0009), and that continued through the 52-week study period.
“What we know is the [improved lung function] effect is sustained. What we don’t know is how long you have to keep on the drug for a more permanent effect, which is an issue for all these biologics,” Tracy said.
Dr. Bacharier reported speaker fees and research support from Sanofi/Regeneron. Dr. Tracy has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Optimizing Severe Asthma Treatment: Challenges and Approaches to Care
Asthma is a complex, heterogeneous disease with unmet treatment needs. Patients with severe asthma generally continue to have severe disease despite being on controller therapies.
Uncontrolled asthma can result in unnecessary suffering and interfere with daily activities. It also increases the risk for exacerbations and places substantial burden on the healthcare system.
In this ReCAP, Drs Sandhya Khurana and Steve N. Georas, from the Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care in Rochester, New York, discuss current challenges in the management of severe asthma, and how advances in the understanding of phenotypes and therapeutic options guide their approaches to asthma management.
They review key indicators of severe asthma, tools to assess asthma control, approaches to phenotyping patients, treatment options for type 2 and non–type 2 asthma, and emerging agents.
--
Sandhya Khurana, MD is a Professor, Department of Medicine, University of Rochester, Director, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Sandhya Khurana, MD, has disclosed the following relevant financial relationships: Received research grant from: GlaxoSmithKline.
Steve N. Georas, MD is a Professor, Department of Medicine, University of Rochester; Walter & Carmina Mary Parkes Family Endowed Professor; Director, Pulmonary Function Labs, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Steve N. Georas, MD, has disclosed no relevant financial relationships.
Asthma is a complex, heterogeneous disease with unmet treatment needs. Patients with severe asthma generally continue to have severe disease despite being on controller therapies.
Uncontrolled asthma can result in unnecessary suffering and interfere with daily activities. It also increases the risk for exacerbations and places substantial burden on the healthcare system.
In this ReCAP, Drs Sandhya Khurana and Steve N. Georas, from the Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care in Rochester, New York, discuss current challenges in the management of severe asthma, and how advances in the understanding of phenotypes and therapeutic options guide their approaches to asthma management.
They review key indicators of severe asthma, tools to assess asthma control, approaches to phenotyping patients, treatment options for type 2 and non–type 2 asthma, and emerging agents.
--
Sandhya Khurana, MD is a Professor, Department of Medicine, University of Rochester, Director, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Sandhya Khurana, MD, has disclosed the following relevant financial relationships: Received research grant from: GlaxoSmithKline.
Steve N. Georas, MD is a Professor, Department of Medicine, University of Rochester; Walter & Carmina Mary Parkes Family Endowed Professor; Director, Pulmonary Function Labs, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Steve N. Georas, MD, has disclosed no relevant financial relationships.
Asthma is a complex, heterogeneous disease with unmet treatment needs. Patients with severe asthma generally continue to have severe disease despite being on controller therapies.
Uncontrolled asthma can result in unnecessary suffering and interfere with daily activities. It also increases the risk for exacerbations and places substantial burden on the healthcare system.
In this ReCAP, Drs Sandhya Khurana and Steve N. Georas, from the Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care in Rochester, New York, discuss current challenges in the management of severe asthma, and how advances in the understanding of phenotypes and therapeutic options guide their approaches to asthma management.
They review key indicators of severe asthma, tools to assess asthma control, approaches to phenotyping patients, treatment options for type 2 and non–type 2 asthma, and emerging agents.
--
Sandhya Khurana, MD is a Professor, Department of Medicine, University of Rochester, Director, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Sandhya Khurana, MD, has disclosed the following relevant financial relationships: Received research grant from: GlaxoSmithKline.
Steve N. Georas, MD is a Professor, Department of Medicine, University of Rochester; Walter & Carmina Mary Parkes Family Endowed Professor; Director, Pulmonary Function Labs, Mary H. Parkes Center for Asthma, Allergy, and Pulmonary Care, Rochester, New York.
Steve N. Georas, MD, has disclosed no relevant financial relationships.
Respiratory infection– and asthma-prone children
Some children are more susceptible to viral and bacterial respiratory infections in the first few years of life than others. However, the factors contributing to this susceptibility are incompletely understood. The pathogenesis, development, severity, and clinical outcomes of respiratory infections are largely dependent on the resident composition of the nasopharyngeal microbiome and immune defense.1
Respiratory infections caused by bacteria and/or viruses are a leading cause of death in children in the United States and worldwide. The well-recognized, predominant causative bacteria are Streptococcus pneumoniae (pneumococcus), nontypeable Haemophilus influenzae (Hflu), and Moraxella catarrhalis (Mcat). Respiratory infections caused by these pathogens result in considerable morbidity, mortality, and account for high health care costs. The clinical and laboratory group that I lead in Rochester, N.Y., has been studying acute otitis media (AOM) etiology, epidemiology, pathogenesis, prevention, and treatment for over 3 decades. Our research findings are likely applicable and generalizable to understanding the pathogenesis and immune response to other infectious diseases induced by pneumococcus, Hflu, and Mcat since they are also key pathogens causing sinusitis and lung infections.
Previous immunologic analysis of children with AOM by our group provided clarity in differences between infection-prone children manifest as otitis prone (OP; often referred to in our publications as stringently defined OP because of the stringent diagnostic requirement of tympanocentesis-proven etiology of infection) and non-OP children. We showed that about 90% of OP children have deficient immune responses following nasopharyngeal colonization and AOM, demonstrated by inadequate innate responses and adaptive immune responses.2 Many of these children also showed an increased propensity to viral upper respiratory infection and 30% fail to produce protective antibody responses after injection of routine pediatric vaccines.3,4
In this column, I want to share new information regarding differences in the nasopharyngeal microbiome of children who are respiratory infection prone versus those who are non–respiratory infection prone and children with asthma versus those who do not exhibit that clinical phenotype. We performed a retrospective analysis of clinical samples collected from 358 children, aged 6 months to 5 years, from our prospectively enrolled cohort in Rochester, N.Y., to determine associations between AOM and other childhood respiratory illnesses and nasopharyngeal microbiota. In order to define subgroups of children within the cohort, we used a statistical method called unsupervised clustering analysis to see if relatively unique groups of children could be discerned. The overall cohort successfully clustered into two groups, showing marked differences in the prevalence of respiratory infections and asthma.5 We termed the two clinical phenotypes infection and asthma prone (n = 99, 28% of the children) and non–infection and asthma prone (n = 259, 72% of the children). Infection- and asthma-prone children were significantly more likely to experience recurrent AOM, influenza, sinusitis, pneumonia, asthma, and allergic rhinitis, compared with non–infection- and asthma-prone children (Figure).
The two groups did not experience significantly different rates of eczema, food allergy, skin infections, urinary tract infections, or acute gastroenteritis, suggesting a common thread involving the respiratory tract that did not cross over to the gastrointestinal, skin, or urinary tract. We found that age at first nasopharyngeal colonization with any of the three bacterial respiratory pathogens (pneumococcus, Hflu, or Mcat) was significantly associated with the respiratory infection– and asthma-prone clinical phenotype. Specifically, respiratory infection– and asthma-prone children experienced colonization at a significantly earlier age than nonprone children did for all three bacteria. In an analysis of individual conditions, early Mcat colonization significantly associated with pneumonia, sinusitis, and asthma susceptibility; Hflu with pneumonia, sinusitis, influenza, and allergic rhinitis; and pneumococcus with sinusitis.
Since early colonization with the three bacterial respiratory pathogens was strongly associated with respiratory illnesses and asthma, nasopharyngeal microbiome analysis was performed on an available subset of samples. Bacterial diversity trended lower in infection- and asthma-prone children, consistent with dysbiosis in the respiratory infection– and asthma-prone clinical phenotype. Nine different bacteria genera were found to be differentially abundant when comparing respiratory infection– and asthma-prone and nonprone children, pointing the way to possible interventions to make the respiratory infection– and asthma-prone child nasopharyngeal microbiome more like the nonprone child.
As I have written previously in this column, recent accumulating data have shed light on the importance of the human microbiome in modulating immune homeostasis and disease susceptibility.6 My group is working toward generating new knowledge for the long-term goal of identifying new therapeutic strategies to facilitate a protective, diverse nasopharyngeal microbiome (with appropriately tuned intranasal probiotics) to prevent respiratory pathogen colonization and/or subsequent progression to respiratory infection and asthma. Also, vaccines directed against colonization-enhancing members of the microbiome may provide a means to indirectly control respiratory pathogen nasopharyngeal colonization.
Dr. Pichichero is a specialist in pediatric infectious diseases and director of the Research Institute at Rochester (N.Y.) General Hospital. He has no conflicts to declare. Contact him at pdnews@mdedge.com
References
1. Man WH et al. Nat Rev Microbiol. 2017;15(5):259-70.
2. Pichichero ME. J Infect. 2020;80(6):614-22.
3. Ren D et al. Clin Infect Dis. 2019;68(9):1566-74.
4. Pichichero ME et al. Pediatr Infect Dis J. 2013;32(11):1163-8.
5. Chapman T et al. PLoS One. 2020 Dec 11;15(12).
6. Blaser MJ. The microbiome revolution. J Clin Invest. 2014;124:4162-5.
Some children are more susceptible to viral and bacterial respiratory infections in the first few years of life than others. However, the factors contributing to this susceptibility are incompletely understood. The pathogenesis, development, severity, and clinical outcomes of respiratory infections are largely dependent on the resident composition of the nasopharyngeal microbiome and immune defense.1
Respiratory infections caused by bacteria and/or viruses are a leading cause of death in children in the United States and worldwide. The well-recognized, predominant causative bacteria are Streptococcus pneumoniae (pneumococcus), nontypeable Haemophilus influenzae (Hflu), and Moraxella catarrhalis (Mcat). Respiratory infections caused by these pathogens result in considerable morbidity, mortality, and account for high health care costs. The clinical and laboratory group that I lead in Rochester, N.Y., has been studying acute otitis media (AOM) etiology, epidemiology, pathogenesis, prevention, and treatment for over 3 decades. Our research findings are likely applicable and generalizable to understanding the pathogenesis and immune response to other infectious diseases induced by pneumococcus, Hflu, and Mcat since they are also key pathogens causing sinusitis and lung infections.
Previous immunologic analysis of children with AOM by our group provided clarity in differences between infection-prone children manifest as otitis prone (OP; often referred to in our publications as stringently defined OP because of the stringent diagnostic requirement of tympanocentesis-proven etiology of infection) and non-OP children. We showed that about 90% of OP children have deficient immune responses following nasopharyngeal colonization and AOM, demonstrated by inadequate innate responses and adaptive immune responses.2 Many of these children also showed an increased propensity to viral upper respiratory infection and 30% fail to produce protective antibody responses after injection of routine pediatric vaccines.3,4
In this column, I want to share new information regarding differences in the nasopharyngeal microbiome of children who are respiratory infection prone versus those who are non–respiratory infection prone and children with asthma versus those who do not exhibit that clinical phenotype. We performed a retrospective analysis of clinical samples collected from 358 children, aged 6 months to 5 years, from our prospectively enrolled cohort in Rochester, N.Y., to determine associations between AOM and other childhood respiratory illnesses and nasopharyngeal microbiota. In order to define subgroups of children within the cohort, we used a statistical method called unsupervised clustering analysis to see if relatively unique groups of children could be discerned. The overall cohort successfully clustered into two groups, showing marked differences in the prevalence of respiratory infections and asthma.5 We termed the two clinical phenotypes infection and asthma prone (n = 99, 28% of the children) and non–infection and asthma prone (n = 259, 72% of the children). Infection- and asthma-prone children were significantly more likely to experience recurrent AOM, influenza, sinusitis, pneumonia, asthma, and allergic rhinitis, compared with non–infection- and asthma-prone children (Figure).
The two groups did not experience significantly different rates of eczema, food allergy, skin infections, urinary tract infections, or acute gastroenteritis, suggesting a common thread involving the respiratory tract that did not cross over to the gastrointestinal, skin, or urinary tract. We found that age at first nasopharyngeal colonization with any of the three bacterial respiratory pathogens (pneumococcus, Hflu, or Mcat) was significantly associated with the respiratory infection– and asthma-prone clinical phenotype. Specifically, respiratory infection– and asthma-prone children experienced colonization at a significantly earlier age than nonprone children did for all three bacteria. In an analysis of individual conditions, early Mcat colonization significantly associated with pneumonia, sinusitis, and asthma susceptibility; Hflu with pneumonia, sinusitis, influenza, and allergic rhinitis; and pneumococcus with sinusitis.
Since early colonization with the three bacterial respiratory pathogens was strongly associated with respiratory illnesses and asthma, nasopharyngeal microbiome analysis was performed on an available subset of samples. Bacterial diversity trended lower in infection- and asthma-prone children, consistent with dysbiosis in the respiratory infection– and asthma-prone clinical phenotype. Nine different bacteria genera were found to be differentially abundant when comparing respiratory infection– and asthma-prone and nonprone children, pointing the way to possible interventions to make the respiratory infection– and asthma-prone child nasopharyngeal microbiome more like the nonprone child.
As I have written previously in this column, recent accumulating data have shed light on the importance of the human microbiome in modulating immune homeostasis and disease susceptibility.6 My group is working toward generating new knowledge for the long-term goal of identifying new therapeutic strategies to facilitate a protective, diverse nasopharyngeal microbiome (with appropriately tuned intranasal probiotics) to prevent respiratory pathogen colonization and/or subsequent progression to respiratory infection and asthma. Also, vaccines directed against colonization-enhancing members of the microbiome may provide a means to indirectly control respiratory pathogen nasopharyngeal colonization.
Dr. Pichichero is a specialist in pediatric infectious diseases and director of the Research Institute at Rochester (N.Y.) General Hospital. He has no conflicts to declare. Contact him at pdnews@mdedge.com
References
1. Man WH et al. Nat Rev Microbiol. 2017;15(5):259-70.
2. Pichichero ME. J Infect. 2020;80(6):614-22.
3. Ren D et al. Clin Infect Dis. 2019;68(9):1566-74.
4. Pichichero ME et al. Pediatr Infect Dis J. 2013;32(11):1163-8.
5. Chapman T et al. PLoS One. 2020 Dec 11;15(12).
6. Blaser MJ. The microbiome revolution. J Clin Invest. 2014;124:4162-5.
Some children are more susceptible to viral and bacterial respiratory infections in the first few years of life than others. However, the factors contributing to this susceptibility are incompletely understood. The pathogenesis, development, severity, and clinical outcomes of respiratory infections are largely dependent on the resident composition of the nasopharyngeal microbiome and immune defense.1
Respiratory infections caused by bacteria and/or viruses are a leading cause of death in children in the United States and worldwide. The well-recognized, predominant causative bacteria are Streptococcus pneumoniae (pneumococcus), nontypeable Haemophilus influenzae (Hflu), and Moraxella catarrhalis (Mcat). Respiratory infections caused by these pathogens result in considerable morbidity, mortality, and account for high health care costs. The clinical and laboratory group that I lead in Rochester, N.Y., has been studying acute otitis media (AOM) etiology, epidemiology, pathogenesis, prevention, and treatment for over 3 decades. Our research findings are likely applicable and generalizable to understanding the pathogenesis and immune response to other infectious diseases induced by pneumococcus, Hflu, and Mcat since they are also key pathogens causing sinusitis and lung infections.
Previous immunologic analysis of children with AOM by our group provided clarity in differences between infection-prone children manifest as otitis prone (OP; often referred to in our publications as stringently defined OP because of the stringent diagnostic requirement of tympanocentesis-proven etiology of infection) and non-OP children. We showed that about 90% of OP children have deficient immune responses following nasopharyngeal colonization and AOM, demonstrated by inadequate innate responses and adaptive immune responses.2 Many of these children also showed an increased propensity to viral upper respiratory infection and 30% fail to produce protective antibody responses after injection of routine pediatric vaccines.3,4
In this column, I want to share new information regarding differences in the nasopharyngeal microbiome of children who are respiratory infection prone versus those who are non–respiratory infection prone and children with asthma versus those who do not exhibit that clinical phenotype. We performed a retrospective analysis of clinical samples collected from 358 children, aged 6 months to 5 years, from our prospectively enrolled cohort in Rochester, N.Y., to determine associations between AOM and other childhood respiratory illnesses and nasopharyngeal microbiota. In order to define subgroups of children within the cohort, we used a statistical method called unsupervised clustering analysis to see if relatively unique groups of children could be discerned. The overall cohort successfully clustered into two groups, showing marked differences in the prevalence of respiratory infections and asthma.5 We termed the two clinical phenotypes infection and asthma prone (n = 99, 28% of the children) and non–infection and asthma prone (n = 259, 72% of the children). Infection- and asthma-prone children were significantly more likely to experience recurrent AOM, influenza, sinusitis, pneumonia, asthma, and allergic rhinitis, compared with non–infection- and asthma-prone children (Figure).
The two groups did not experience significantly different rates of eczema, food allergy, skin infections, urinary tract infections, or acute gastroenteritis, suggesting a common thread involving the respiratory tract that did not cross over to the gastrointestinal, skin, or urinary tract. We found that age at first nasopharyngeal colonization with any of the three bacterial respiratory pathogens (pneumococcus, Hflu, or Mcat) was significantly associated with the respiratory infection– and asthma-prone clinical phenotype. Specifically, respiratory infection– and asthma-prone children experienced colonization at a significantly earlier age than nonprone children did for all three bacteria. In an analysis of individual conditions, early Mcat colonization significantly associated with pneumonia, sinusitis, and asthma susceptibility; Hflu with pneumonia, sinusitis, influenza, and allergic rhinitis; and pneumococcus with sinusitis.
Since early colonization with the three bacterial respiratory pathogens was strongly associated with respiratory illnesses and asthma, nasopharyngeal microbiome analysis was performed on an available subset of samples. Bacterial diversity trended lower in infection- and asthma-prone children, consistent with dysbiosis in the respiratory infection– and asthma-prone clinical phenotype. Nine different bacteria genera were found to be differentially abundant when comparing respiratory infection– and asthma-prone and nonprone children, pointing the way to possible interventions to make the respiratory infection– and asthma-prone child nasopharyngeal microbiome more like the nonprone child.
As I have written previously in this column, recent accumulating data have shed light on the importance of the human microbiome in modulating immune homeostasis and disease susceptibility.6 My group is working toward generating new knowledge for the long-term goal of identifying new therapeutic strategies to facilitate a protective, diverse nasopharyngeal microbiome (with appropriately tuned intranasal probiotics) to prevent respiratory pathogen colonization and/or subsequent progression to respiratory infection and asthma. Also, vaccines directed against colonization-enhancing members of the microbiome may provide a means to indirectly control respiratory pathogen nasopharyngeal colonization.
Dr. Pichichero is a specialist in pediatric infectious diseases and director of the Research Institute at Rochester (N.Y.) General Hospital. He has no conflicts to declare. Contact him at pdnews@mdedge.com
References
1. Man WH et al. Nat Rev Microbiol. 2017;15(5):259-70.
2. Pichichero ME. J Infect. 2020;80(6):614-22.
3. Ren D et al. Clin Infect Dis. 2019;68(9):1566-74.
4. Pichichero ME et al. Pediatr Infect Dis J. 2013;32(11):1163-8.
5. Chapman T et al. PLoS One. 2020 Dec 11;15(12).
6. Blaser MJ. The microbiome revolution. J Clin Invest. 2014;124:4162-5.