Pediatrics

More than a million European children undergo a CT scan each year. Ionizing radiation at moderate (> 100 mGy) to high (> 1 Gy) doses is a recognized risk factor for malignant hematopathies. The risk associated with exposure to low doses (< 100 mGy), typically delivered during a CT scan in children or adolescents, is unknown.

Previous studies assessed the risk for malignant hematopathies related to ionizing radiation from CT scans in young patients. Some showed an increased risk for leukemia with repeated scans, but confounding factors resulted in a lack of statistical power or biases in some cases. The EPI-CT study, coordinated by the International Agency for Research on Cancer, aimed to evaluate the cancer risk among children and adolescents after exposure to low doses of ionizing radiation during CT scans.
 

A European Cohort

A recent article presents an assessment of observed malignant hematopathies following CT scan. The authors followed a multinational European cohort of 948,174 patients who had a CT scan before age 22 years. Ionizing radiation doses to the bone marrow were evaluated based on the scanned body region, patient characteristics, scan year, and the technical parameters of the machine. The analysis involved 876,771 patients who underwent 1,331,896 scans (an average of 1.52 per patient) and were followed for at least 2 years after the first scan.

In total, 790 malignant hematopathies were diagnosed, including 578 lymphoid hematopathies and 203 myeloid hematopathies and acute leukemias. The average follow-up period was 7.8 years. At the time of diagnosis, 51% of patients were under the age of 20 years, and 88.5% were under the age of 30 years. There was an association between cumulative dose and the observed malignant hematopathy, with an observed rate of 1.96 per 100 mGy (790 cases).

This rate corresponds to a 16% increased rate per scan (for a dose observed per scan of 8 mGy). A higher rate for any type of malignant hematopathy was observed for doses > 10 mGy, with an observed rate of 2.66 for doses > 50 mGy, compared with doses < 5 mGy.

The rate of malignant hematopathy increased with older age at the time of radiation exposure, particularly for lymphoid observations. The rate in the 5- to 9-year age group and the > 10-year age group was, respectively, two times and three to four times higher than that in the < 5-year age group. The rate decreased over time, with the highest observed rate between 2 and 5 years after ionizing radiation exposure and the lowest after 10 years.
 

CT Scans Must Be Warranted

This study, which involved nearly a million patients, has higher statistical power than previous studies, despite missing or approximate data (including that related to actually delivered doses). An association was shown between cumulative dose to the bone marrow and the risk of developing malignant hematopathy, both lymphoid and myeloid, with an increased risk even at low doses (10-15 mGy).

The results suggest that for every 10,000 children examined today (with a dose per scan of 8 mGy), 1-2 could develop a radiation-related malignant hematopathy in the next 12 years (1.4 cases). This study confirms the higher risk for cancer at low radiation doses and emphasizes the importance of justifying each pediatric CT scan and optimizing delivered doses. It is important to recall that an MRI or ultrasound can sometimes be an adequate substitute for a CT scan.

This article was translated from   JIM , which is part of the Medscape Professional Network. A version of this article appeared on Medscape.com .

More than a million European children undergo a CT scan each year. Ionizing radiation at moderate (> 100 mGy) to high (> 1 Gy) doses is a recognized risk factor for malignant hematopathies. The risk associated with exposure to low doses (< 100 mGy), typically delivered during a CT scan in children or adolescents, is unknown.

Previous studies assessed the risk for malignant hematopathies related to ionizing radiation from CT scans in young patients. Some showed an increased risk for leukemia with repeated scans, but confounding factors resulted in a lack of statistical power or biases in some cases. The EPI-CT study, coordinated by the International Agency for Research on Cancer, aimed to evaluate the cancer risk among children and adolescents after exposure to low doses of ionizing radiation during CT scans.
 

A European Cohort

A recent article presents an assessment of observed malignant hematopathies following CT scan. The authors followed a multinational European cohort of 948,174 patients who had a CT scan before age 22 years. Ionizing radiation doses to the bone marrow were evaluated based on the scanned body region, patient characteristics, scan year, and the technical parameters of the machine. The analysis involved 876,771 patients who underwent 1,331,896 scans (an average of 1.52 per patient) and were followed for at least 2 years after the first scan.

In total, 790 malignant hematopathies were diagnosed, including 578 lymphoid hematopathies and 203 myeloid hematopathies and acute leukemias. The average follow-up period was 7.8 years. At the time of diagnosis, 51% of patients were under the age of 20 years, and 88.5% were under the age of 30 years. There was an association between cumulative dose and the observed malignant hematopathy, with an observed rate of 1.96 per 100 mGy (790 cases).

This rate corresponds to a 16% increased rate per scan (for a dose observed per scan of 8 mGy). A higher rate for any type of malignant hematopathy was observed for doses > 10 mGy, with an observed rate of 2.66 for doses > 50 mGy, compared with doses < 5 mGy.

The rate of malignant hematopathy increased with older age at the time of radiation exposure, particularly for lymphoid observations. The rate in the 5- to 9-year age group and the > 10-year age group was, respectively, two times and three to four times higher than that in the < 5-year age group. The rate decreased over time, with the highest observed rate between 2 and 5 years after ionizing radiation exposure and the lowest after 10 years.
 

CT Scans Must Be Warranted

This study, which involved nearly a million patients, has higher statistical power than previous studies, despite missing or approximate data (including that related to actually delivered doses). An association was shown between cumulative dose to the bone marrow and the risk of developing malignant hematopathy, both lymphoid and myeloid, with an increased risk even at low doses (10-15 mGy).

The results suggest that for every 10,000 children examined today (with a dose per scan of 8 mGy), 1-2 could develop a radiation-related malignant hematopathy in the next 12 years (1.4 cases). This study confirms the higher risk for cancer at low radiation doses and emphasizes the importance of justifying each pediatric CT scan and optimizing delivered doses. It is important to recall that an MRI or ultrasound can sometimes be an adequate substitute for a CT scan.

This article was translated from   JIM , which is part of the Medscape Professional Network. A version of this article appeared on Medscape.com .

More than a million European children undergo a CT scan each year. Ionizing radiation at moderate (> 100 mGy) to high (> 1 Gy) doses is a recognized risk factor for malignant hematopathies. The risk associated with exposure to low doses (< 100 mGy), typically delivered during a CT scan in children or adolescents, is unknown.

Previous studies assessed the risk for malignant hematopathies related to ionizing radiation from CT scans in young patients. Some showed an increased risk for leukemia with repeated scans, but confounding factors resulted in a lack of statistical power or biases in some cases. The EPI-CT study, coordinated by the International Agency for Research on Cancer, aimed to evaluate the cancer risk among children and adolescents after exposure to low doses of ionizing radiation during CT scans.
 

A European Cohort

A recent article presents an assessment of observed malignant hematopathies following CT scan. The authors followed a multinational European cohort of 948,174 patients who had a CT scan before age 22 years. Ionizing radiation doses to the bone marrow were evaluated based on the scanned body region, patient characteristics, scan year, and the technical parameters of the machine. The analysis involved 876,771 patients who underwent 1,331,896 scans (an average of 1.52 per patient) and were followed for at least 2 years after the first scan.

In total, 790 malignant hematopathies were diagnosed, including 578 lymphoid hematopathies and 203 myeloid hematopathies and acute leukemias. The average follow-up period was 7.8 years. At the time of diagnosis, 51% of patients were under the age of 20 years, and 88.5% were under the age of 30 years. There was an association between cumulative dose and the observed malignant hematopathy, with an observed rate of 1.96 per 100 mGy (790 cases).

This rate corresponds to a 16% increased rate per scan (for a dose observed per scan of 8 mGy). A higher rate for any type of malignant hematopathy was observed for doses > 10 mGy, with an observed rate of 2.66 for doses > 50 mGy, compared with doses < 5 mGy.

The rate of malignant hematopathy increased with older age at the time of radiation exposure, particularly for lymphoid observations. The rate in the 5- to 9-year age group and the > 10-year age group was, respectively, two times and three to four times higher than that in the < 5-year age group. The rate decreased over time, with the highest observed rate between 2 and 5 years after ionizing radiation exposure and the lowest after 10 years.
 

CT Scans Must Be Warranted

This study, which involved nearly a million patients, has higher statistical power than previous studies, despite missing or approximate data (including that related to actually delivered doses). An association was shown between cumulative dose to the bone marrow and the risk of developing malignant hematopathy, both lymphoid and myeloid, with an increased risk even at low doses (10-15 mGy).

The results suggest that for every 10,000 children examined today (with a dose per scan of 8 mGy), 1-2 could develop a radiation-related malignant hematopathy in the next 12 years (1.4 cases). This study confirms the higher risk for cancer at low radiation doses and emphasizes the importance of justifying each pediatric CT scan and optimizing delivered doses. It is important to recall that an MRI or ultrasound can sometimes be an adequate substitute for a CT scan.

This article was translated from   JIM , which is part of the Medscape Professional Network. A version of this article appeared on Medscape.com .

TOPLINE:

Mental health comorbidities are prevalent among youth with overweight or obesity, with the strongest risk factors being male sex, older age, and extreme obesity.

METHODOLOGY:

• Researchers compared clinical characteristics and outcomes among children, adolescents, and young adults with overweight or obesity with or without a comorbid mental disorder who participated in a lifestyle intervention program.
• Overall, data from 114,248 individuals (age, 6-30 years; 53% females) from 226 centers in Germany and Austria participating in the Adiposity Patient Registry were evaluated.
• Individuals were excluded if they had bariatric surgery or used weight-modifying drugs (metformin, orlistat, or glucagon-like peptide-1 analogues).
• Body mass index (BMI) was calculated as a standard deviation score (SDS) from a German youth population reference and was used to define overweight (90th to < 97th percentile), obesity (97th percentile), and severe obesity (≥ 99.5th percentile), which at age 18 correspond to adult cutoffs for overweight and obesity (25 kg/m² and 30 kg/m², respectively).
• Regression analysis identified the factors associated with mental disorders in those with overweight or obesity.

TAKEAWAY:

• A comorbid mental disorder was reported in 3969 individuals, with attention-deficit disorder (ADHD, 42.5%), anxiety (31.3%), depression (24.3%), and eating disorders (12.9%) being the most common.
• The factors most strongly associated with mental health comorbidity were male sex (odds ratio [OR], 1.39; 95% CI, 1.27-1.52), older age (OR, 1.42; 95% CI, 1.25-1.62), and severe obesity (OR, 1.45; 95% CI, 1.30-1.63).
• Mean BMI-SDS was higher in individuals with depression and eating disorders and lower in individuals with ADHD (both P < .001) than in those without mental disorders.
• Individuals with and without mental disorders benefited from similar BMI changes from lifestyle intervention programs.

IN PRACTICE:

The authors wrote, “Healthcare professionals caring for youth with overweight or obesity should be aware of comorbid mental disorders, and regular mental health screening should be considered.”

SOURCE:

This study, led by Angela Galler from the Charité – Universitätsmedizin Berlin, Germany, was published online on January 9, 2024, in the International Journal of Obesity.

LIMITATIONS:

The study’s findings are based on data from a group of children, adolescents, and young adults with overweight or obesity treated in specialized obesity centers and may not be generalizable to all youth with obesity. Moreover, the study could not establish any conclusions regarding the cause or effect between obesity and mental disorders. Individuals were not tested psychologically for mental disorders and might have been underreported.

DISCLOSURES:

The manuscript is part of the Stratification of Obesity Phenotypes to Optimize Future Obesity Therapy project, which was funded by the Innovative Medicines Initiative 2 Joint Undertaking. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

TOPLINE:

Mental health comorbidities are prevalent among youth with overweight or obesity, with the strongest risk factors being male sex, older age, and extreme obesity.

METHODOLOGY:

• Researchers compared clinical characteristics and outcomes among children, adolescents, and young adults with overweight or obesity with or without a comorbid mental disorder who participated in a lifestyle intervention program.
• Overall, data from 114,248 individuals (age, 6-30 years; 53% females) from 226 centers in Germany and Austria participating in the Adiposity Patient Registry were evaluated.
• Individuals were excluded if they had bariatric surgery or used weight-modifying drugs (metformin, orlistat, or glucagon-like peptide-1 analogues).
• Body mass index (BMI) was calculated as a standard deviation score (SDS) from a German youth population reference and was used to define overweight (90th to < 97th percentile), obesity (97th percentile), and severe obesity (≥ 99.5th percentile), which at age 18 correspond to adult cutoffs for overweight and obesity (25 kg/m² and 30 kg/m², respectively).
• Regression analysis identified the factors associated with mental disorders in those with overweight or obesity.

TAKEAWAY:

• A comorbid mental disorder was reported in 3969 individuals, with attention-deficit disorder (ADHD, 42.5%), anxiety (31.3%), depression (24.3%), and eating disorders (12.9%) being the most common.
• The factors most strongly associated with mental health comorbidity were male sex (odds ratio [OR], 1.39; 95% CI, 1.27-1.52), older age (OR, 1.42; 95% CI, 1.25-1.62), and severe obesity (OR, 1.45; 95% CI, 1.30-1.63).
• Mean BMI-SDS was higher in individuals with depression and eating disorders and lower in individuals with ADHD (both P < .001) than in those without mental disorders.
• Individuals with and without mental disorders benefited from similar BMI changes from lifestyle intervention programs.

IN PRACTICE:

The authors wrote, “Healthcare professionals caring for youth with overweight or obesity should be aware of comorbid mental disorders, and regular mental health screening should be considered.”

SOURCE:

This study, led by Angela Galler from the Charité – Universitätsmedizin Berlin, Germany, was published online on January 9, 2024, in the International Journal of Obesity.

LIMITATIONS:

The study’s findings are based on data from a group of children, adolescents, and young adults with overweight or obesity treated in specialized obesity centers and may not be generalizable to all youth with obesity. Moreover, the study could not establish any conclusions regarding the cause or effect between obesity and mental disorders. Individuals were not tested psychologically for mental disorders and might have been underreported.

DISCLOSURES:

The manuscript is part of the Stratification of Obesity Phenotypes to Optimize Future Obesity Therapy project, which was funded by the Innovative Medicines Initiative 2 Joint Undertaking. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

TOPLINE:

Mental health comorbidities are prevalent among youth with overweight or obesity, with the strongest risk factors being male sex, older age, and extreme obesity.

METHODOLOGY:

• Researchers compared clinical characteristics and outcomes among children, adolescents, and young adults with overweight or obesity with or without a comorbid mental disorder who participated in a lifestyle intervention program.
• Overall, data from 114,248 individuals (age, 6-30 years; 53% females) from 226 centers in Germany and Austria participating in the Adiposity Patient Registry were evaluated.
• Individuals were excluded if they had bariatric surgery or used weight-modifying drugs (metformin, orlistat, or glucagon-like peptide-1 analogues).
• Body mass index (BMI) was calculated as a standard deviation score (SDS) from a German youth population reference and was used to define overweight (90th to < 97th percentile), obesity (97th percentile), and severe obesity (≥ 99.5th percentile), which at age 18 correspond to adult cutoffs for overweight and obesity (25 kg/m² and 30 kg/m², respectively).
• Regression analysis identified the factors associated with mental disorders in those with overweight or obesity.

TAKEAWAY:

• A comorbid mental disorder was reported in 3969 individuals, with attention-deficit disorder (ADHD, 42.5%), anxiety (31.3%), depression (24.3%), and eating disorders (12.9%) being the most common.
• The factors most strongly associated with mental health comorbidity were male sex (odds ratio [OR], 1.39; 95% CI, 1.27-1.52), older age (OR, 1.42; 95% CI, 1.25-1.62), and severe obesity (OR, 1.45; 95% CI, 1.30-1.63).
• Mean BMI-SDS was higher in individuals with depression and eating disorders and lower in individuals with ADHD (both P < .001) than in those without mental disorders.
• Individuals with and without mental disorders benefited from similar BMI changes from lifestyle intervention programs.

IN PRACTICE:

The authors wrote, “Healthcare professionals caring for youth with overweight or obesity should be aware of comorbid mental disorders, and regular mental health screening should be considered.”

SOURCE:

This study, led by Angela Galler from the Charité – Universitätsmedizin Berlin, Germany, was published online on January 9, 2024, in the International Journal of Obesity.

LIMITATIONS:

The study’s findings are based on data from a group of children, adolescents, and young adults with overweight or obesity treated in specialized obesity centers and may not be generalizable to all youth with obesity. Moreover, the study could not establish any conclusions regarding the cause or effect between obesity and mental disorders. Individuals were not tested psychologically for mental disorders and might have been underreported.

DISCLOSURES:

The manuscript is part of the Stratification of Obesity Phenotypes to Optimize Future Obesity Therapy project, which was funded by the Innovative Medicines Initiative 2 Joint Undertaking. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

When infants are born, they have nearly a clean slate with regard to their immune systems. Virtually all their immune cells are naive. They have no immunity memory. Vaccines at birth, and in the first 2 years of life, elicit variable antibody levels and cellular immune responses. Sometimes, this leaves fully vaccinated children unprotected against vaccine-preventable infectious diseases.

Newborns are bombarded at birth with microbes and other antigenic stimuli from the environment; food in the form of breast milk, formula, water; and vaccines, such as hepatitis B and, in other countries, with BCG. At birth, to avoid immunologically-induced injury, immune responses favor immunologic tolerance. However, adaptation must be rapid to avoid life-threatening infections. To navigate the gauntlet of microbe and environmental exposures and vaccines, the neonatal immune system moves through a gradual maturation process toward immune responsivity. The maturation occurs at different rates in different children. A major factor affecting immune development is the microbiome of the newborn and the first 100 days of life.
 

Reassessing Vaccine Responsiveness

Vaccine responsiveness is usually assessed by measuring antibody levels in blood. Until recently, it was thought to be “bad luck” when a child failed to develop protective immunity following vaccination. The bad luck was suggested to involve illness at the time of vaccination, especially illness occurring with fever, and especially common viral infections. But studies proved that notion incorrect. About 10 years ago I became more interested in variability in vaccine responses in the first 2 years of life. In 2016, my laboratory described a specific population of children with specific cellular immune deficiencies that we classified as low vaccine responders (LVRs).¹ To preclude the suggestion that low vaccine responses were to be considered normal biological variation, we chose an a priori definition of LVR as those with sub-protective IgG antibody levels to four (≥ 66 %) of six tested vaccines in DTaP-Hib (diphtheria toxoid, tetanus toxoid, pertussis toxoid, pertactin, and filamentous hemagglutinin [DTaP] and Haemophilus influenzae type b polysaccharide capsule [Hib]). Antibody levels were measured at 1 year of age following primary vaccinations at child age 2, 4, and 6 months old. The remaining 89% of children we termed normal vaccine responders (NVRs). We additionally tested antibody responses to viral protein and pneumococcal polysaccharide conjugated antigens (polio serotypes 1, 2, and 3, hepatitis B, and Streptococcus pneumoniae capsular polysaccharides serotypes 6B, 14, and 23F). Responses to these vaccine antigens were similar to the six vaccines (DTaP/Hib) used to define LVR. We and other groups have used alternative definitions of low vaccine responses that rely on statistics.

I recently reviewed the topic of the determinants of vaccine responses in early life, with a focus on the infant microbiome and metabolome: a.) cesarean section versus vaginal delivery, b.) breast versus formula feeding and c.) antibiotic exposure, that impact the immune response² (Figure). In the review I also discussed how microbiome may serve as natural adjuvants for vaccine responses, how microbiota-derived metabolites influence vaccine responses, and how low vaccine responses in early life may be linked to increased infection susceptibility (Figure).

Courtesy Dr. Pichichero

Multiple studies strongly support the notion that breastfeeding has a favorable impact on immune development in early life associated with better vaccine responses, mediated by the microbiome. The mechanism of favorable immune responses to vaccines largely relates to the presence of a specific bacteria species, Bifidobacterium infantis. Breast milk contains human milk oligosaccharides that are not digestible by newborns. B. infantis is a strain of bacteria that utilizes these non-digestible oligosaccharides. Thereby, infants fed breast milk provides B. infantis the essential source of nutrition for its growth and predominance in the newborn gut. Studies have shown that Bifidobacterium spp. abundance in early life is correlated with better immune responses to multiple vaccines. Bifidobacterium spp. abundance has been positively correlated with antibody responses measured after 2 years, linking the microbiome composition to the durability of vaccine-induced immune responses.

Antibiotic exposure in early life may disproportionately damage the newborn and infant microbiome compared with later childhood. The average child receives about three antibiotic courses by the age of 2 years. My lab was among the first to describe the adverse effects of antibiotics on vaccine responses in early life.³ We found that broader spectrum antibiotics had a greater adverse effect on vaccine-induced antibody levels than narrower spectrum antibiotics. Ten-day versus five-day treatment courses had a greater negative effect. Multiple antibiotic courses over time (cumulative antibiotic exposure) was negatively associated with vaccine-induced antibody levels.

Over 11 % of live births worldwide occur preterm. Because bacterial infections are frequent complications of preterm birth, 79 % of very low birthweight and 87 % of extremely low birthweight infants in US NICUs receive antibiotics within 3 days of birth. Recently, my group studied full-term infants at birth and found that exposure to parenteral antibiotics at birth or during the first days of life had an adverse effect on vaccine responses.⁴
 

Microbiome Impacts Immunity

How does the microbiome affect immunity, and specifically vaccine responses? Microbial-derived metabolites affect host immunity. Gut bacteria produce short chain fatty acids (SCFAs: acetate, propionate, butyrate) [115]. SCFAs positively influence immunity cells. Vitamin D metabolites are generated by intestinal bacteria and those metabolites positively influence immunity. Secondary bile acids produced by Clostridium spp. are involved in favorable immune responses. Increased levels of phenylpyruvic acid produced by gut and/or nasopharyngeal microbiota correlate with reduced vaccine responses and upregulated metabolome genes that encode for oxidative phosphorylation correlate with increased vaccine responses.

In summary, immune development commences at birth. Impairment in responses to vaccination in children have been linked to disturbance in the microbiome. Cesarean section and absence of breastfeeding are associated with adverse microbiota composition. Antibiotics perturb healthy microbiota development. The microbiota affect immunity in several ways, among them are effects by metabolites generated by the commensals that inhabit the child host. A child who responds poorly to vaccines and has specific immune cell dysfunction caused by problems with the microbiome also displays increased infection proneness. But that is a story for another column, later.

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

References

1. Pichichero ME et al. J Infect Dis. 2016 Jun 15;213(12):2014-2019. doi: 10.1093/infdis/jiw053.

2. Pichichero ME. Cell Immunol. 2023 Nov-Dec:393-394:104777. doi: 10.1016/j.cellimm.2023.104777.

3. Chapman TJ et al. Pediatrics. 2022 May 1;149(5):e2021052061. doi: 10.1542/peds.2021-052061.

4. Shaffer M et al. mSystems. 2023 Oct 26;8(5):e0066123. doi: 10.1128/msystems.00661-23.

When infants are born, they have nearly a clean slate with regard to their immune systems. Virtually all their immune cells are naive. They have no immunity memory. Vaccines at birth, and in the first 2 years of life, elicit variable antibody levels and cellular immune responses. Sometimes, this leaves fully vaccinated children unprotected against vaccine-preventable infectious diseases.

Newborns are bombarded at birth with microbes and other antigenic stimuli from the environment; food in the form of breast milk, formula, water; and vaccines, such as hepatitis B and, in other countries, with BCG. At birth, to avoid immunologically-induced injury, immune responses favor immunologic tolerance. However, adaptation must be rapid to avoid life-threatening infections. To navigate the gauntlet of microbe and environmental exposures and vaccines, the neonatal immune system moves through a gradual maturation process toward immune responsivity. The maturation occurs at different rates in different children. A major factor affecting immune development is the microbiome of the newborn and the first 100 days of life.
 

Reassessing Vaccine Responsiveness

Vaccine responsiveness is usually assessed by measuring antibody levels in blood. Until recently, it was thought to be “bad luck” when a child failed to develop protective immunity following vaccination. The bad luck was suggested to involve illness at the time of vaccination, especially illness occurring with fever, and especially common viral infections. But studies proved that notion incorrect. About 10 years ago I became more interested in variability in vaccine responses in the first 2 years of life. In 2016, my laboratory described a specific population of children with specific cellular immune deficiencies that we classified as low vaccine responders (LVRs).¹ To preclude the suggestion that low vaccine responses were to be considered normal biological variation, we chose an a priori definition of LVR as those with sub-protective IgG antibody levels to four (≥ 66 %) of six tested vaccines in DTaP-Hib (diphtheria toxoid, tetanus toxoid, pertussis toxoid, pertactin, and filamentous hemagglutinin [DTaP] and Haemophilus influenzae type b polysaccharide capsule [Hib]). Antibody levels were measured at 1 year of age following primary vaccinations at child age 2, 4, and 6 months old. The remaining 89% of children we termed normal vaccine responders (NVRs). We additionally tested antibody responses to viral protein and pneumococcal polysaccharide conjugated antigens (polio serotypes 1, 2, and 3, hepatitis B, and Streptococcus pneumoniae capsular polysaccharides serotypes 6B, 14, and 23F). Responses to these vaccine antigens were similar to the six vaccines (DTaP/Hib) used to define LVR. We and other groups have used alternative definitions of low vaccine responses that rely on statistics.

I recently reviewed the topic of the determinants of vaccine responses in early life, with a focus on the infant microbiome and metabolome: a.) cesarean section versus vaginal delivery, b.) breast versus formula feeding and c.) antibiotic exposure, that impact the immune response² (Figure). In the review I also discussed how microbiome may serve as natural adjuvants for vaccine responses, how microbiota-derived metabolites influence vaccine responses, and how low vaccine responses in early life may be linked to increased infection susceptibility (Figure).

Courtesy Dr. Pichichero

Multiple studies strongly support the notion that breastfeeding has a favorable impact on immune development in early life associated with better vaccine responses, mediated by the microbiome. The mechanism of favorable immune responses to vaccines largely relates to the presence of a specific bacteria species, Bifidobacterium infantis. Breast milk contains human milk oligosaccharides that are not digestible by newborns. B. infantis is a strain of bacteria that utilizes these non-digestible oligosaccharides. Thereby, infants fed breast milk provides B. infantis the essential source of nutrition for its growth and predominance in the newborn gut. Studies have shown that Bifidobacterium spp. abundance in early life is correlated with better immune responses to multiple vaccines. Bifidobacterium spp. abundance has been positively correlated with antibody responses measured after 2 years, linking the microbiome composition to the durability of vaccine-induced immune responses.

Antibiotic exposure in early life may disproportionately damage the newborn and infant microbiome compared with later childhood. The average child receives about three antibiotic courses by the age of 2 years. My lab was among the first to describe the adverse effects of antibiotics on vaccine responses in early life.³ We found that broader spectrum antibiotics had a greater adverse effect on vaccine-induced antibody levels than narrower spectrum antibiotics. Ten-day versus five-day treatment courses had a greater negative effect. Multiple antibiotic courses over time (cumulative antibiotic exposure) was negatively associated with vaccine-induced antibody levels.

Over 11 % of live births worldwide occur preterm. Because bacterial infections are frequent complications of preterm birth, 79 % of very low birthweight and 87 % of extremely low birthweight infants in US NICUs receive antibiotics within 3 days of birth. Recently, my group studied full-term infants at birth and found that exposure to parenteral antibiotics at birth or during the first days of life had an adverse effect on vaccine responses.⁴
 

Microbiome Impacts Immunity

How does the microbiome affect immunity, and specifically vaccine responses? Microbial-derived metabolites affect host immunity. Gut bacteria produce short chain fatty acids (SCFAs: acetate, propionate, butyrate) [115]. SCFAs positively influence immunity cells. Vitamin D metabolites are generated by intestinal bacteria and those metabolites positively influence immunity. Secondary bile acids produced by Clostridium spp. are involved in favorable immune responses. Increased levels of phenylpyruvic acid produced by gut and/or nasopharyngeal microbiota correlate with reduced vaccine responses and upregulated metabolome genes that encode for oxidative phosphorylation correlate with increased vaccine responses.

In summary, immune development commences at birth. Impairment in responses to vaccination in children have been linked to disturbance in the microbiome. Cesarean section and absence of breastfeeding are associated with adverse microbiota composition. Antibiotics perturb healthy microbiota development. The microbiota affect immunity in several ways, among them are effects by metabolites generated by the commensals that inhabit the child host. A child who responds poorly to vaccines and has specific immune cell dysfunction caused by problems with the microbiome also displays increased infection proneness. But that is a story for another column, later.

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

References

1. Pichichero ME et al. J Infect Dis. 2016 Jun 15;213(12):2014-2019. doi: 10.1093/infdis/jiw053.

2. Pichichero ME. Cell Immunol. 2023 Nov-Dec:393-394:104777. doi: 10.1016/j.cellimm.2023.104777.

3. Chapman TJ et al. Pediatrics. 2022 May 1;149(5):e2021052061. doi: 10.1542/peds.2021-052061.

4. Shaffer M et al. mSystems. 2023 Oct 26;8(5):e0066123. doi: 10.1128/msystems.00661-23.

When infants are born, they have nearly a clean slate with regard to their immune systems. Virtually all their immune cells are naive. They have no immunity memory. Vaccines at birth, and in the first 2 years of life, elicit variable antibody levels and cellular immune responses. Sometimes, this leaves fully vaccinated children unprotected against vaccine-preventable infectious diseases.

Newborns are bombarded at birth with microbes and other antigenic stimuli from the environment; food in the form of breast milk, formula, water; and vaccines, such as hepatitis B and, in other countries, with BCG. At birth, to avoid immunologically-induced injury, immune responses favor immunologic tolerance. However, adaptation must be rapid to avoid life-threatening infections. To navigate the gauntlet of microbe and environmental exposures and vaccines, the neonatal immune system moves through a gradual maturation process toward immune responsivity. The maturation occurs at different rates in different children. A major factor affecting immune development is the microbiome of the newborn and the first 100 days of life.
 

Reassessing Vaccine Responsiveness

Vaccine responsiveness is usually assessed by measuring antibody levels in blood. Until recently, it was thought to be “bad luck” when a child failed to develop protective immunity following vaccination. The bad luck was suggested to involve illness at the time of vaccination, especially illness occurring with fever, and especially common viral infections. But studies proved that notion incorrect. About 10 years ago I became more interested in variability in vaccine responses in the first 2 years of life. In 2016, my laboratory described a specific population of children with specific cellular immune deficiencies that we classified as low vaccine responders (LVRs).¹ To preclude the suggestion that low vaccine responses were to be considered normal biological variation, we chose an a priori definition of LVR as those with sub-protective IgG antibody levels to four (≥ 66 %) of six tested vaccines in DTaP-Hib (diphtheria toxoid, tetanus toxoid, pertussis toxoid, pertactin, and filamentous hemagglutinin [DTaP] and Haemophilus influenzae type b polysaccharide capsule [Hib]). Antibody levels were measured at 1 year of age following primary vaccinations at child age 2, 4, and 6 months old. The remaining 89% of children we termed normal vaccine responders (NVRs). We additionally tested antibody responses to viral protein and pneumococcal polysaccharide conjugated antigens (polio serotypes 1, 2, and 3, hepatitis B, and Streptococcus pneumoniae capsular polysaccharides serotypes 6B, 14, and 23F). Responses to these vaccine antigens were similar to the six vaccines (DTaP/Hib) used to define LVR. We and other groups have used alternative definitions of low vaccine responses that rely on statistics.

I recently reviewed the topic of the determinants of vaccine responses in early life, with a focus on the infant microbiome and metabolome: a.) cesarean section versus vaginal delivery, b.) breast versus formula feeding and c.) antibiotic exposure, that impact the immune response² (Figure). In the review I also discussed how microbiome may serve as natural adjuvants for vaccine responses, how microbiota-derived metabolites influence vaccine responses, and how low vaccine responses in early life may be linked to increased infection susceptibility (Figure).

Courtesy Dr. Pichichero

Multiple studies strongly support the notion that breastfeeding has a favorable impact on immune development in early life associated with better vaccine responses, mediated by the microbiome. The mechanism of favorable immune responses to vaccines largely relates to the presence of a specific bacteria species, Bifidobacterium infantis. Breast milk contains human milk oligosaccharides that are not digestible by newborns. B. infantis is a strain of bacteria that utilizes these non-digestible oligosaccharides. Thereby, infants fed breast milk provides B. infantis the essential source of nutrition for its growth and predominance in the newborn gut. Studies have shown that Bifidobacterium spp. abundance in early life is correlated with better immune responses to multiple vaccines. Bifidobacterium spp. abundance has been positively correlated with antibody responses measured after 2 years, linking the microbiome composition to the durability of vaccine-induced immune responses.

Antibiotic exposure in early life may disproportionately damage the newborn and infant microbiome compared with later childhood. The average child receives about three antibiotic courses by the age of 2 years. My lab was among the first to describe the adverse effects of antibiotics on vaccine responses in early life.³ We found that broader spectrum antibiotics had a greater adverse effect on vaccine-induced antibody levels than narrower spectrum antibiotics. Ten-day versus five-day treatment courses had a greater negative effect. Multiple antibiotic courses over time (cumulative antibiotic exposure) was negatively associated with vaccine-induced antibody levels.

Over 11 % of live births worldwide occur preterm. Because bacterial infections are frequent complications of preterm birth, 79 % of very low birthweight and 87 % of extremely low birthweight infants in US NICUs receive antibiotics within 3 days of birth. Recently, my group studied full-term infants at birth and found that exposure to parenteral antibiotics at birth or during the first days of life had an adverse effect on vaccine responses.⁴
 

Microbiome Impacts Immunity

How does the microbiome affect immunity, and specifically vaccine responses? Microbial-derived metabolites affect host immunity. Gut bacteria produce short chain fatty acids (SCFAs: acetate, propionate, butyrate) [115]. SCFAs positively influence immunity cells. Vitamin D metabolites are generated by intestinal bacteria and those metabolites positively influence immunity. Secondary bile acids produced by Clostridium spp. are involved in favorable immune responses. Increased levels of phenylpyruvic acid produced by gut and/or nasopharyngeal microbiota correlate with reduced vaccine responses and upregulated metabolome genes that encode for oxidative phosphorylation correlate with increased vaccine responses.

In summary, immune development commences at birth. Impairment in responses to vaccination in children have been linked to disturbance in the microbiome. Cesarean section and absence of breastfeeding are associated with adverse microbiota composition. Antibiotics perturb healthy microbiota development. The microbiota affect immunity in several ways, among them are effects by metabolites generated by the commensals that inhabit the child host. A child who responds poorly to vaccines and has specific immune cell dysfunction caused by problems with the microbiome also displays increased infection proneness. But that is a story for another column, later.

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

References

1. Pichichero ME et al. J Infect Dis. 2016 Jun 15;213(12):2014-2019. doi: 10.1093/infdis/jiw053.

2. Pichichero ME. Cell Immunol. 2023 Nov-Dec:393-394:104777. doi: 10.1016/j.cellimm.2023.104777.

3. Chapman TJ et al. Pediatrics. 2022 May 1;149(5):e2021052061. doi: 10.1542/peds.2021-052061.

4. Shaffer M et al. mSystems. 2023 Oct 26;8(5):e0066123. doi: 10.1128/msystems.00661-23.

Early treatment with ibuprofen had no significant impact on the risk of death or adverse outcomes in preterm infants with patent ductus arteriosus vs. placebo.

The study population included infants born between 23 weeks 0 days’ and 28 weeks 6 days’ gestation. The researchers randomized 326 extremely preterm infants with patent ductus arteriosus (PDA) at 72 hours or less after birth to ibuprofen at a loading dose of 10 mg/kg followed by two doses of 5 mg/kg at least 24 hours apart, and 327 to placebo.

The PDAs in the infants had a diameter of at least 1.5 mm with pulsatile flow.

Severe dysplasia outcome

The study’s primary outcome was a composite of death or moderate to severe bronchopulmonary dysplasia at 36 weeks’ postmenstrual age. Overall, a primary outcome occurred in 69.2% of infants who received ibuprofen and 63.5% of those who received a placebo.

Risk of death or bronchopulmonary dysplasia at 36 weeks’ postmenstrual age was not reduced by early ibuprofen vs. placebo for preterm infants, the researchers concluded. Moderate or severe bronchopulmonary dysplasia occurred in 64.2% of the infants in the ibuprofen group and 59.3% of the placebo group who survived to 36 weeks’ postmenstrual age.

‘Unforeseeable’ serious adverse events

Forty-four deaths occurred in the ibuprofen group and 33 in the placebo group (adjusted risk ratio 1.09). Two “unforeseeable” serious adverse events occurred during the study that were potentially related to ibuprofen.

The lead author was Samir Gupta, MD, of Sidra Medicine, Doha, Qatar. The study was published online in the New England Journal of Medicine.

Study limitations include incomplete data for some patients.

The study was supported by the National Institute for Health Research Health Technology Assessment Programme. The researchers had no financial conflicts to disclose.

Early treatment with ibuprofen had no significant impact on the risk of death or adverse outcomes in preterm infants with patent ductus arteriosus vs. placebo.

The study population included infants born between 23 weeks 0 days’ and 28 weeks 6 days’ gestation. The researchers randomized 326 extremely preterm infants with patent ductus arteriosus (PDA) at 72 hours or less after birth to ibuprofen at a loading dose of 10 mg/kg followed by two doses of 5 mg/kg at least 24 hours apart, and 327 to placebo.

The PDAs in the infants had a diameter of at least 1.5 mm with pulsatile flow.

Severe dysplasia outcome

The study’s primary outcome was a composite of death or moderate to severe bronchopulmonary dysplasia at 36 weeks’ postmenstrual age. Overall, a primary outcome occurred in 69.2% of infants who received ibuprofen and 63.5% of those who received a placebo.

Risk of death or bronchopulmonary dysplasia at 36 weeks’ postmenstrual age was not reduced by early ibuprofen vs. placebo for preterm infants, the researchers concluded. Moderate or severe bronchopulmonary dysplasia occurred in 64.2% of the infants in the ibuprofen group and 59.3% of the placebo group who survived to 36 weeks’ postmenstrual age.

‘Unforeseeable’ serious adverse events

Forty-four deaths occurred in the ibuprofen group and 33 in the placebo group (adjusted risk ratio 1.09). Two “unforeseeable” serious adverse events occurred during the study that were potentially related to ibuprofen.

The lead author was Samir Gupta, MD, of Sidra Medicine, Doha, Qatar. The study was published online in the New England Journal of Medicine.

Study limitations include incomplete data for some patients.

The study was supported by the National Institute for Health Research Health Technology Assessment Programme. The researchers had no financial conflicts to disclose.

Early treatment with ibuprofen had no significant impact on the risk of death or adverse outcomes in preterm infants with patent ductus arteriosus vs. placebo.

The study population included infants born between 23 weeks 0 days’ and 28 weeks 6 days’ gestation. The researchers randomized 326 extremely preterm infants with patent ductus arteriosus (PDA) at 72 hours or less after birth to ibuprofen at a loading dose of 10 mg/kg followed by two doses of 5 mg/kg at least 24 hours apart, and 327 to placebo.

The PDAs in the infants had a diameter of at least 1.5 mm with pulsatile flow.

Severe dysplasia outcome

The study’s primary outcome was a composite of death or moderate to severe bronchopulmonary dysplasia at 36 weeks’ postmenstrual age. Overall, a primary outcome occurred in 69.2% of infants who received ibuprofen and 63.5% of those who received a placebo.

Risk of death or bronchopulmonary dysplasia at 36 weeks’ postmenstrual age was not reduced by early ibuprofen vs. placebo for preterm infants, the researchers concluded. Moderate or severe bronchopulmonary dysplasia occurred in 64.2% of the infants in the ibuprofen group and 59.3% of the placebo group who survived to 36 weeks’ postmenstrual age.

‘Unforeseeable’ serious adverse events

Forty-four deaths occurred in the ibuprofen group and 33 in the placebo group (adjusted risk ratio 1.09). Two “unforeseeable” serious adverse events occurred during the study that were potentially related to ibuprofen.

The lead author was Samir Gupta, MD, of Sidra Medicine, Doha, Qatar. The study was published online in the New England Journal of Medicine.

Study limitations include incomplete data for some patients.

The study was supported by the National Institute for Health Research Health Technology Assessment Programme. The researchers had no financial conflicts to disclose.

Bone health begins in childhood, particularly during the rapid bone accrual phase of puberty, which is essential for attaining optimal peak bone mass. Peak bone mass is achieved in early adult life and affects both immediate and future fracture risk. Genetic, nutritional, exercise-related, and hormonal factors, and certain diseases and medications, have deleterious effects on bone health.

In addition, emerging data suggest that certain manmade chemicals known as per- and polyfluoroalkyl substances (PFAS) may affect bone accrual during this important period and potentially increase the risk for osteoporosis in adulthood. Osteoporosis refers to increased fracture risk because of low bone density and affects a large proportion of postmenopausal women and older men.

New evidence comes from a recent study conducted by investigators from the Keck School of Medicine, who examined the impact of exposure to PFAS on skeletal outcomes in youth. Of note, participants were primarily Hispanic; this population has a higher risk for osteoporosis in adulthood. PFAS are manmade chemicals with water- and grease-resistant properties. They are used in a variety of products, such as nonstick cookware, food packaging, water-repellent clothing, stain-resistant fabrics, carpets, and in certain industrial processes. They are pervasive in the environment, in wildlife, and in humans.

Use and production of certain PFAS, such as perfluorooctane sulfonic acid (PFOS) and perfluorooctanoic acid (PFOA),  have decreased over the past two decades, with a significant reduction in blood concentrations of these chemicals. However, they can be resistant to degradation and have very long half-lives. As a consequence, these «forever chemicals» continue to linger in the environment. Also, the risk for exposure to other PFAS persists, and almost every individual has detectable levels of PFAS in blood.

Scientists are still learning about the impact of environmental chemicals on bone health. In contrast, other factors that may jeopardize pubertal bone accrual and peak bone mass acquisition have been studied extensively, with guidelines for management of the consequent poor skeletal health.

For PFAS, studies have reported deleterious effects on various body systems, such as the liver, immune system, thyroid, and the developing brain. The limited data related to bone suggest negative associations between certain, but not all, PFAS and bone density — ie, the higher the exposure, the worse the impact on bone health.

PFAS may affect health through alterations in the endocrine system. They have been associated with lower levels of testosterone and downregulation of its receptor (and testosterone is known to modulate bone formation and bone loss). On the other hand, some PFAS are estrogenic, which should be beneficial to bone. A direct impact of PFAS on pathways regulating activity of osteoblasts (bone-forming cells) and osteoclasts (bone-resorbing cells) has also been postulated, with conflicting results.

Previous research on PFAS and human bone health has found mixed results. In adolescents, Xiong and colleagues  reported negative associations of PFOS, PFOA, and perfluorononanoic acid (PFNA), but not perfluorohexane sulfonic acid (PFHxS), levels with bone density at various sites, mostly in females. Carwile and associates  reported similar negative associations of blood concentrations of PFOA and PFOS and urinary concentrations of phthalates with bone density in adolescents, but only in males. Lin and coworkers also reported negative associations of PFOA and bone density in adult premenopausal women, but found no associations of PFOA and PFOS concentrations with self-reported fractures, suggesting questionable biological significance of these findings. These were all cross-sectional studies and did not report on the impact of these chemicals on longitudinal bone accrual.

In the recent study, Beglarian and colleagues examined the impact of PFAS on longitudinal changes in bone density in adolescents, drawn from the Study of Latino Adolescents at Risk of Type 2 Diabetes (SOLAR) cohort and young adults from the Southern California Children’s Health Study (CHS) cohort. They found that in adolescents, higher baseline concentrations of PFOS predicted lower bone accrual over time. In young adults, there was a similar negative association of PFOS concentrations and bone density at baseline, but not with longitudinal bone accrual. In this study, other PFAS were not associated with bone outcomes.

Overall, research appears to suggest that PFOA, PFOS, and PFNA may have deleterious effects on bone density and bone accrual over time. However, data are not consistent across studies and across sexes, and more research is necessary to conclusively define the impact of these chemicals on skeletal health, particularly during the critical pubertal years of maximal bone accrual. In the meantime, continued efforts are necessary to reduce to concentrations of these PFAS in the environment.

Dr. Misra disclosed ties with AbbVie, Sanofi, and Ipsen.
 

A version of this article appeared on Medscape.com.

Bone health begins in childhood, particularly during the rapid bone accrual phase of puberty, which is essential for attaining optimal peak bone mass. Peak bone mass is achieved in early adult life and affects both immediate and future fracture risk. Genetic, nutritional, exercise-related, and hormonal factors, and certain diseases and medications, have deleterious effects on bone health.

In addition, emerging data suggest that certain manmade chemicals known as per- and polyfluoroalkyl substances (PFAS) may affect bone accrual during this important period and potentially increase the risk for osteoporosis in adulthood. Osteoporosis refers to increased fracture risk because of low bone density and affects a large proportion of postmenopausal women and older men.

New evidence comes from a recent study conducted by investigators from the Keck School of Medicine, who examined the impact of exposure to PFAS on skeletal outcomes in youth. Of note, participants were primarily Hispanic; this population has a higher risk for osteoporosis in adulthood. PFAS are manmade chemicals with water- and grease-resistant properties. They are used in a variety of products, such as nonstick cookware, food packaging, water-repellent clothing, stain-resistant fabrics, carpets, and in certain industrial processes. They are pervasive in the environment, in wildlife, and in humans.

Use and production of certain PFAS, such as perfluorooctane sulfonic acid (PFOS) and perfluorooctanoic acid (PFOA),  have decreased over the past two decades, with a significant reduction in blood concentrations of these chemicals. However, they can be resistant to degradation and have very long half-lives. As a consequence, these «forever chemicals» continue to linger in the environment. Also, the risk for exposure to other PFAS persists, and almost every individual has detectable levels of PFAS in blood.

Scientists are still learning about the impact of environmental chemicals on bone health. In contrast, other factors that may jeopardize pubertal bone accrual and peak bone mass acquisition have been studied extensively, with guidelines for management of the consequent poor skeletal health.

For PFAS, studies have reported deleterious effects on various body systems, such as the liver, immune system, thyroid, and the developing brain. The limited data related to bone suggest negative associations between certain, but not all, PFAS and bone density — ie, the higher the exposure, the worse the impact on bone health.

PFAS may affect health through alterations in the endocrine system. They have been associated with lower levels of testosterone and downregulation of its receptor (and testosterone is known to modulate bone formation and bone loss). On the other hand, some PFAS are estrogenic, which should be beneficial to bone. A direct impact of PFAS on pathways regulating activity of osteoblasts (bone-forming cells) and osteoclasts (bone-resorbing cells) has also been postulated, with conflicting results.

Previous research on PFAS and human bone health has found mixed results. In adolescents, Xiong and colleagues  reported negative associations of PFOS, PFOA, and perfluorononanoic acid (PFNA), but not perfluorohexane sulfonic acid (PFHxS), levels with bone density at various sites, mostly in females. Carwile and associates  reported similar negative associations of blood concentrations of PFOA and PFOS and urinary concentrations of phthalates with bone density in adolescents, but only in males. Lin and coworkers also reported negative associations of PFOA and bone density in adult premenopausal women, but found no associations of PFOA and PFOS concentrations with self-reported fractures, suggesting questionable biological significance of these findings. These were all cross-sectional studies and did not report on the impact of these chemicals on longitudinal bone accrual.

In the recent study, Beglarian and colleagues examined the impact of PFAS on longitudinal changes in bone density in adolescents, drawn from the Study of Latino Adolescents at Risk of Type 2 Diabetes (SOLAR) cohort and young adults from the Southern California Children’s Health Study (CHS) cohort. They found that in adolescents, higher baseline concentrations of PFOS predicted lower bone accrual over time. In young adults, there was a similar negative association of PFOS concentrations and bone density at baseline, but not with longitudinal bone accrual. In this study, other PFAS were not associated with bone outcomes.

Overall, research appears to suggest that PFOA, PFOS, and PFNA may have deleterious effects on bone density and bone accrual over time. However, data are not consistent across studies and across sexes, and more research is necessary to conclusively define the impact of these chemicals on skeletal health, particularly during the critical pubertal years of maximal bone accrual. In the meantime, continued efforts are necessary to reduce to concentrations of these PFAS in the environment.

Dr. Misra disclosed ties with AbbVie, Sanofi, and Ipsen.
 

A version of this article appeared on Medscape.com.

Bone health begins in childhood, particularly during the rapid bone accrual phase of puberty, which is essential for attaining optimal peak bone mass. Peak bone mass is achieved in early adult life and affects both immediate and future fracture risk. Genetic, nutritional, exercise-related, and hormonal factors, and certain diseases and medications, have deleterious effects on bone health.

In addition, emerging data suggest that certain manmade chemicals known as per- and polyfluoroalkyl substances (PFAS) may affect bone accrual during this important period and potentially increase the risk for osteoporosis in adulthood. Osteoporosis refers to increased fracture risk because of low bone density and affects a large proportion of postmenopausal women and older men.

New evidence comes from a recent study conducted by investigators from the Keck School of Medicine, who examined the impact of exposure to PFAS on skeletal outcomes in youth. Of note, participants were primarily Hispanic; this population has a higher risk for osteoporosis in adulthood. PFAS are manmade chemicals with water- and grease-resistant properties. They are used in a variety of products, such as nonstick cookware, food packaging, water-repellent clothing, stain-resistant fabrics, carpets, and in certain industrial processes. They are pervasive in the environment, in wildlife, and in humans.

Use and production of certain PFAS, such as perfluorooctane sulfonic acid (PFOS) and perfluorooctanoic acid (PFOA),  have decreased over the past two decades, with a significant reduction in blood concentrations of these chemicals. However, they can be resistant to degradation and have very long half-lives. As a consequence, these «forever chemicals» continue to linger in the environment. Also, the risk for exposure to other PFAS persists, and almost every individual has detectable levels of PFAS in blood.

Scientists are still learning about the impact of environmental chemicals on bone health. In contrast, other factors that may jeopardize pubertal bone accrual and peak bone mass acquisition have been studied extensively, with guidelines for management of the consequent poor skeletal health.

For PFAS, studies have reported deleterious effects on various body systems, such as the liver, immune system, thyroid, and the developing brain. The limited data related to bone suggest negative associations between certain, but not all, PFAS and bone density — ie, the higher the exposure, the worse the impact on bone health.

PFAS may affect health through alterations in the endocrine system. They have been associated with lower levels of testosterone and downregulation of its receptor (and testosterone is known to modulate bone formation and bone loss). On the other hand, some PFAS are estrogenic, which should be beneficial to bone. A direct impact of PFAS on pathways regulating activity of osteoblasts (bone-forming cells) and osteoclasts (bone-resorbing cells) has also been postulated, with conflicting results.

Previous research on PFAS and human bone health has found mixed results. In adolescents, Xiong and colleagues  reported negative associations of PFOS, PFOA, and perfluorononanoic acid (PFNA), but not perfluorohexane sulfonic acid (PFHxS), levels with bone density at various sites, mostly in females. Carwile and associates  reported similar negative associations of blood concentrations of PFOA and PFOS and urinary concentrations of phthalates with bone density in adolescents, but only in males. Lin and coworkers also reported negative associations of PFOA and bone density in adult premenopausal women, but found no associations of PFOA and PFOS concentrations with self-reported fractures, suggesting questionable biological significance of these findings. These were all cross-sectional studies and did not report on the impact of these chemicals on longitudinal bone accrual.

In the recent study, Beglarian and colleagues examined the impact of PFAS on longitudinal changes in bone density in adolescents, drawn from the Study of Latino Adolescents at Risk of Type 2 Diabetes (SOLAR) cohort and young adults from the Southern California Children’s Health Study (CHS) cohort. They found that in adolescents, higher baseline concentrations of PFOS predicted lower bone accrual over time. In young adults, there was a similar negative association of PFOS concentrations and bone density at baseline, but not with longitudinal bone accrual. In this study, other PFAS were not associated with bone outcomes.

Overall, research appears to suggest that PFOA, PFOS, and PFNA may have deleterious effects on bone density and bone accrual over time. However, data are not consistent across studies and across sexes, and more research is necessary to conclusively define the impact of these chemicals on skeletal health, particularly during the critical pubertal years of maximal bone accrual. In the meantime, continued efforts are necessary to reduce to concentrations of these PFAS in the environment.

Dr. Misra disclosed ties with AbbVie, Sanofi, and Ipsen.
 

A version of this article appeared on Medscape.com.

The US Food and Drug Administration (FDA) has approved dupilumab (Dupixent, Regeneron/Sanofi) for the treatment of eosinophilic esophagitis (EoE) in children aged 1-11 years and weighing ≥ 15 kg. It is the first and only medicine approved to treat these patients.

The FDA previously approved the drug for EoE in persons aged 12 years or older and weighing ≥ 40 kg in May 2022, as reported by this news organization.

EoE is a chronic inflammatory disorder driven by type 2 inflammation that damages the esophagus and causes difficulty swallowing and eating. 

Dupilumab is a monoclonal antibody that acts to inhibit part of the inflammatory pathway. 
 

EoE KIDS Trial

The FDA approval of dupilumab for younger children is based on results from the phase 3 randomized, double-blind, placebo-controlled EoE KIDS trial, which had two parts. 

Part A was a 16-week double-blind treatment period that evaluated the safety and efficacy of dupilumab in a tiered weight-based dosing schema.

At 16 weeks, 66% of children who received higher dose dupilumab at tiered dosing regimens based on weight achieved histologic disease remission (six or fewer eosinophils/high power field), which was the primary endpoint, compared with only 3% of children who received placebo.

In addition, a greater decrease in the proportion of days with one or more signs of EoE according to the Pediatric EoE Sign/Symptom Questionnaire caregiver version (PESQ-C) was observed in children treated with dupilumab at 16 weeks compared placebo.

Part B was a 36-week extended active treatment period in which eligible children from Part A in the dupilumab group continued to receive their dose level and those in the placebo group in Part A switched to active treatment. 

Histologic remission was sustained at week 52 in 53% of children treated with dupilumab in Parts A and B. Histologic remission was also achieved at week 52 in 53% of children who switched to dupilumab from placebo in Part B.

The safety profile of dupilumab observed through 16 weeks in these children was generally in line to that seen through 24 weeks in persons aged 12 years or older with EoE. 

The most common adverse events (≥ 2%) more frequently observed with dupilumab than with placebo were injection site reactions, upper respiratory tract infections, arthralgia, and herpes viral infections. In EoE KIDS Part B, one case of helminth infection was reported in the dupilumab arm.

Full prescribing information is available online.

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

The US Food and Drug Administration (FDA) has approved dupilumab (Dupixent, Regeneron/Sanofi) for the treatment of eosinophilic esophagitis (EoE) in children aged 1-11 years and weighing ≥ 15 kg. It is the first and only medicine approved to treat these patients.

The FDA previously approved the drug for EoE in persons aged 12 years or older and weighing ≥ 40 kg in May 2022, as reported by this news organization.

EoE is a chronic inflammatory disorder driven by type 2 inflammation that damages the esophagus and causes difficulty swallowing and eating. 

Dupilumab is a monoclonal antibody that acts to inhibit part of the inflammatory pathway. 
 

EoE KIDS Trial

The FDA approval of dupilumab for younger children is based on results from the phase 3 randomized, double-blind, placebo-controlled EoE KIDS trial, which had two parts. 

Part A was a 16-week double-blind treatment period that evaluated the safety and efficacy of dupilumab in a tiered weight-based dosing schema.

At 16 weeks, 66% of children who received higher dose dupilumab at tiered dosing regimens based on weight achieved histologic disease remission (six or fewer eosinophils/high power field), which was the primary endpoint, compared with only 3% of children who received placebo.

In addition, a greater decrease in the proportion of days with one or more signs of EoE according to the Pediatric EoE Sign/Symptom Questionnaire caregiver version (PESQ-C) was observed in children treated with dupilumab at 16 weeks compared placebo.

Part B was a 36-week extended active treatment period in which eligible children from Part A in the dupilumab group continued to receive their dose level and those in the placebo group in Part A switched to active treatment. 

Histologic remission was sustained at week 52 in 53% of children treated with dupilumab in Parts A and B. Histologic remission was also achieved at week 52 in 53% of children who switched to dupilumab from placebo in Part B.

The safety profile of dupilumab observed through 16 weeks in these children was generally in line to that seen through 24 weeks in persons aged 12 years or older with EoE. 

The most common adverse events (≥ 2%) more frequently observed with dupilumab than with placebo were injection site reactions, upper respiratory tract infections, arthralgia, and herpes viral infections. In EoE KIDS Part B, one case of helminth infection was reported in the dupilumab arm.

Full prescribing information is available online.

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

The US Food and Drug Administration (FDA) has approved dupilumab (Dupixent, Regeneron/Sanofi) for the treatment of eosinophilic esophagitis (EoE) in children aged 1-11 years and weighing ≥ 15 kg. It is the first and only medicine approved to treat these patients.

The FDA previously approved the drug for EoE in persons aged 12 years or older and weighing ≥ 40 kg in May 2022, as reported by this news organization.

EoE is a chronic inflammatory disorder driven by type 2 inflammation that damages the esophagus and causes difficulty swallowing and eating. 

Dupilumab is a monoclonal antibody that acts to inhibit part of the inflammatory pathway. 
 

EoE KIDS Trial

The FDA approval of dupilumab for younger children is based on results from the phase 3 randomized, double-blind, placebo-controlled EoE KIDS trial, which had two parts. 

Part A was a 16-week double-blind treatment period that evaluated the safety and efficacy of dupilumab in a tiered weight-based dosing schema.

At 16 weeks, 66% of children who received higher dose dupilumab at tiered dosing regimens based on weight achieved histologic disease remission (six or fewer eosinophils/high power field), which was the primary endpoint, compared with only 3% of children who received placebo.

In addition, a greater decrease in the proportion of days with one or more signs of EoE according to the Pediatric EoE Sign/Symptom Questionnaire caregiver version (PESQ-C) was observed in children treated with dupilumab at 16 weeks compared placebo.

Part B was a 36-week extended active treatment period in which eligible children from Part A in the dupilumab group continued to receive their dose level and those in the placebo group in Part A switched to active treatment. 

Histologic remission was sustained at week 52 in 53% of children treated with dupilumab in Parts A and B. Histologic remission was also achieved at week 52 in 53% of children who switched to dupilumab from placebo in Part B.

The safety profile of dupilumab observed through 16 weeks in these children was generally in line to that seen through 24 weeks in persons aged 12 years or older with EoE. 

The most common adverse events (≥ 2%) more frequently observed with dupilumab than with placebo were injection site reactions, upper respiratory tract infections, arthralgia, and herpes viral infections. In EoE KIDS Part B, one case of helminth infection was reported in the dupilumab arm.

Full prescribing information is available online.

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

In a recent issue of Pediatric News, the Child Psychiatry Consult column featured an excellent discussion by Dr. David Rettew of some new research into a possible association between excessive crying in infancy and emotional problems later in childhood. This longitudinal study of almost 5,000 children included an assessment at 3 months and an MRI at age 10, which found that the infants who were excessive criers also had smaller amygdala. While the orders of magnitude of the researchers’ observations is small, it is interesting that the mothers of excessive criers were slightly more likely to experience mental health problems.

Dr. Rettew wisely cautions us to take note of this study’s findings but avoid overreacting. If indeed excessive crying in infancy is a marker for future problems, at the moment we may want to increase our efforts in helping parents improve their parenting skills using a nonjudgmental approach.

Using Dr. Rettew’s sage advice as a leaping off point, I will add the reminder that we must continue to meet head on the venerable myth that “colic” is a gastrointestinal problem. We must promise to never code out a parental complaint as “colic.” If we want to label it “excessive crying of infancy,” that’s one thing, but using “colic” only serves to perpetuate the myth and all the old, and sometimes dangerous, remedies that continue to cling to it.

Whether we use the term “colicky behavior” or call it “excessive crying,” we must remember these are merely descriptive terms. We have not made a diagnosis and are obligated to keep our minds open to serious and life-threatening conditions that make infants cry excessively — aberrant coronary arteries and urinary obstructions to name just two.

I can’t leave the phenomenon of colic without adding a nickel to the two cents I have already gifted you. When I was in medical school, I am sure I was told something about the amygdala. But, I suspect that I was only expected to recall where it lived. In the 50+ years since that brief encounter, other folks have learned much more. Prompted by this study, I searched what is known about small amygdala. Turns out that sleep deprivation has been associated with smaller amygdala, as has episodic migraine headaches, both in adults.

Regular readers of Letters from Maine can already smell where this is going. For decades I have believed that both excessive crying in infancy and episodic migraine in children are associated with, and my bias would say “caused” by, sleep deprivation. We learned from this study that mothers of excessively crying infants are more likely to have mental health problems. And, I will add that at least one study has shown that mothers and fathers of excessively crying infants are more likely to suffer from migraines.

Whether you join me in my biased interpretation isn’t important. What this study tells us is that there is likely to be something going on in infancy that may be a marker for future mental health problems. Were these children born with small or vulnerable amygdala? Did poor sleep hygiene contribute to the problem by interfering with the growth of their amygdala? I can envision studies that could provide some clarity. I’m not sure many parents would agree to have their happy and well-slept 3-month-olds slid into an MRI tube to serve as controls. But, I wouldn’t be surprised that we could find a sizable number of sleep deprived and frazzled parents of colicky infants who would agree if we told them it might help find an answer.
 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at [email protected].

In a recent issue of Pediatric News, the Child Psychiatry Consult column featured an excellent discussion by Dr. David Rettew of some new research into a possible association between excessive crying in infancy and emotional problems later in childhood. This longitudinal study of almost 5,000 children included an assessment at 3 months and an MRI at age 10, which found that the infants who were excessive criers also had smaller amygdala. While the orders of magnitude of the researchers’ observations is small, it is interesting that the mothers of excessive criers were slightly more likely to experience mental health problems.

Dr. Rettew wisely cautions us to take note of this study’s findings but avoid overreacting. If indeed excessive crying in infancy is a marker for future problems, at the moment we may want to increase our efforts in helping parents improve their parenting skills using a nonjudgmental approach.

Using Dr. Rettew’s sage advice as a leaping off point, I will add the reminder that we must continue to meet head on the venerable myth that “colic” is a gastrointestinal problem. We must promise to never code out a parental complaint as “colic.” If we want to label it “excessive crying of infancy,” that’s one thing, but using “colic” only serves to perpetuate the myth and all the old, and sometimes dangerous, remedies that continue to cling to it.

Whether we use the term “colicky behavior” or call it “excessive crying,” we must remember these are merely descriptive terms. We have not made a diagnosis and are obligated to keep our minds open to serious and life-threatening conditions that make infants cry excessively — aberrant coronary arteries and urinary obstructions to name just two.

I can’t leave the phenomenon of colic without adding a nickel to the two cents I have already gifted you. When I was in medical school, I am sure I was told something about the amygdala. But, I suspect that I was only expected to recall where it lived. In the 50+ years since that brief encounter, other folks have learned much more. Prompted by this study, I searched what is known about small amygdala. Turns out that sleep deprivation has been associated with smaller amygdala, as has episodic migraine headaches, both in adults.

Regular readers of Letters from Maine can already smell where this is going. For decades I have believed that both excessive crying in infancy and episodic migraine in children are associated with, and my bias would say “caused” by, sleep deprivation. We learned from this study that mothers of excessively crying infants are more likely to have mental health problems. And, I will add that at least one study has shown that mothers and fathers of excessively crying infants are more likely to suffer from migraines.

Whether you join me in my biased interpretation isn’t important. What this study tells us is that there is likely to be something going on in infancy that may be a marker for future mental health problems. Were these children born with small or vulnerable amygdala? Did poor sleep hygiene contribute to the problem by interfering with the growth of their amygdala? I can envision studies that could provide some clarity. I’m not sure many parents would agree to have their happy and well-slept 3-month-olds slid into an MRI tube to serve as controls. But, I wouldn’t be surprised that we could find a sizable number of sleep deprived and frazzled parents of colicky infants who would agree if we told them it might help find an answer.
 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at [email protected].

In a recent issue of Pediatric News, the Child Psychiatry Consult column featured an excellent discussion by Dr. David Rettew of some new research into a possible association between excessive crying in infancy and emotional problems later in childhood. This longitudinal study of almost 5,000 children included an assessment at 3 months and an MRI at age 10, which found that the infants who were excessive criers also had smaller amygdala. While the orders of magnitude of the researchers’ observations is small, it is interesting that the mothers of excessive criers were slightly more likely to experience mental health problems.

Dr. Rettew wisely cautions us to take note of this study’s findings but avoid overreacting. If indeed excessive crying in infancy is a marker for future problems, at the moment we may want to increase our efforts in helping parents improve their parenting skills using a nonjudgmental approach.

Using Dr. Rettew’s sage advice as a leaping off point, I will add the reminder that we must continue to meet head on the venerable myth that “colic” is a gastrointestinal problem. We must promise to never code out a parental complaint as “colic.” If we want to label it “excessive crying of infancy,” that’s one thing, but using “colic” only serves to perpetuate the myth and all the old, and sometimes dangerous, remedies that continue to cling to it.

Whether we use the term “colicky behavior” or call it “excessive crying,” we must remember these are merely descriptive terms. We have not made a diagnosis and are obligated to keep our minds open to serious and life-threatening conditions that make infants cry excessively — aberrant coronary arteries and urinary obstructions to name just two.

I can’t leave the phenomenon of colic without adding a nickel to the two cents I have already gifted you. When I was in medical school, I am sure I was told something about the amygdala. But, I suspect that I was only expected to recall where it lived. In the 50+ years since that brief encounter, other folks have learned much more. Prompted by this study, I searched what is known about small amygdala. Turns out that sleep deprivation has been associated with smaller amygdala, as has episodic migraine headaches, both in adults.

Regular readers of Letters from Maine can already smell where this is going. For decades I have believed that both excessive crying in infancy and episodic migraine in children are associated with, and my bias would say “caused” by, sleep deprivation. We learned from this study that mothers of excessively crying infants are more likely to have mental health problems. And, I will add that at least one study has shown that mothers and fathers of excessively crying infants are more likely to suffer from migraines.

Whether you join me in my biased interpretation isn’t important. What this study tells us is that there is likely to be something going on in infancy that may be a marker for future mental health problems. Were these children born with small or vulnerable amygdala? Did poor sleep hygiene contribute to the problem by interfering with the growth of their amygdala? I can envision studies that could provide some clarity. I’m not sure many parents would agree to have their happy and well-slept 3-month-olds slid into an MRI tube to serve as controls. But, I wouldn’t be surprised that we could find a sizable number of sleep deprived and frazzled parents of colicky infants who would agree if we told them it might help find an answer.
 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at [email protected].

When pediatric patients with epilepsy shift to adult care, inherent challenges are complicated by a near-total lack of efforts to smooth the transition, according to a recent survey. Many respondents received little to no information regarding the process, and many adults were still receiving care from family physicians or pediatric neurologists. The study was published online in Epilepsy & Behavior.

Room for Improvement

“We are not doing as good a job with planning for transition as we should,” said Elaine C. Wirrell, MD, who was not involved with the study. “It is not just a simple issue of sending your patient to an adult neurologist. Transition is a process that happens over time, so we need to do a better job getting our families ready for moving on to an adult provider.” Dr. Wirrell is director of pediatric epilepsy and professor of neurology at the Mayo Clinic in Rochester, Minnesota.

Mayo Clinic

Clumsy Transitions

Investigators distributed a 25-question survey to patients and caregivers who attended the 2019 Epilepsy Awareness Day at Disneyland, and through online support groups in North America. Among 58 responses, 32 came from patients between ages 12 and 17 years or their caregivers.

Despite attempts to recruit a diverse cross-section of respondents, most patients had severe epilepsy and comorbidities: 43% had daily or weekly seizures; 45% were on three or more antiseizure medications; and 74% had intellectual disabilities.

Many children with early-life epilepsies suffer from developmental and epileptic encephalopathy, which has associated non-seizure symptoms including learning challenges, behavioral issues, and other medical concerns, Dr. Wirrell said. Therefore, she said, finding a neurologist who treats adults — and has the expertise and interest to care for such patients — can be difficult.

“We’re seeing many patients not making that transition, or maybe not making it appropriately, so they’re not necessarily getting to the providers who have the most expertise in managing their epilepsy.” Among adults surveyed, 27% were still being followed by pediatric neurologists, and 35% were visiting family doctors for epilepsy-related treatment.

Because the needs of children with complex epilepsy can extend well beyond neurology, Dr. Wirrell added, managing such cases often requires multidisciplinary pediatric teams. “Finding that team on the adult side is more challenging.” As a result, she said, patients may transfer their neurology care without getting additional support for comorbidities such as mood disorders and learning disabilities.

The foregoing challenges are complicated by the fact that pediatric neurologists often lack the time (and in the United States, reimbursement) to adequately address the transition process, said Dr. Wirrell. Providers in freestanding children’s hospitals may face additional challenges coordinating with adult-care providers outside their facilities, she said.

“There’s also potentially a reluctance of both families and physicians to transition the patient on, because there’s concern that maybe there isn’t anybody on the adult side who is able to do as good a job as what they have on the pediatric side.”
 

Well-Coordinated Transitions Should Have No Surprises

Transition should be a planned, independence-promoting process that results in smooth, well-coordinated movement of pediatric patients into adult care — one without surprises or disconnections, the authors wrote. However, 55% of respondents never heard the term “transition” from any provider, even though 69% of patients were being treated in academic specialty centers.

Among 12- to 17-year-olds, 72% had never discussed transition with their healthcare team. That figure includes no 17-year-olds. Approximately 90% of respondents said they received sufficient time during healthcare visits, but 54% reported feeling stressed when moving from pediatric to adult care.

Given resource constraints in many pediatric epilepsy programs, the study authors recommended patient-empowerment tools such as a transition toolkit to help patients and families navigate the transition process even in places without formal transition programs.

“Many of these children are coming over with boatloads of medical records,” Dr. Wirrell said. “It’s not fair to the adult provider, who then has to go through all those records.” Instead, she said, pediatric teams should provide succinct summaries of relevant test results, medication side effects, prior treatments tried, and the like. “Those summaries are critically important so that we can get information to the person who needs it.”

Although successful transition requires significant coordination, she added, much of the process can often be handled by nonphysicians. “There are some very good nurse-led transition programs. Often, we can have a nurse providing education to the family and even potentially having a joint visit with an adult epilepsy nurse for complex patients.”

Pediatric providers also must know when to begin the transition process, Dr. Wirrell said. As soon as patients are 13 or 14 years old, she suggested discussing the process with them and their families every 6 to 12 months, covering specifics ranging from how to order medications to why adult patients may need power of attorney designees.

On a broader scale, said Dr. Wirrell, a smooth handoff requires planning. Fortunately, she said, the topic is becoming a significant priority for a growing number of children’s hospitals specific not only to epilepsy, but also to other chronic illnesses.

Dr. Wirrell is co–editor-in-chief for epilepsy.com. She reports no relevant financial interests.

When pediatric patients with epilepsy shift to adult care, inherent challenges are complicated by a near-total lack of efforts to smooth the transition, according to a recent survey. Many respondents received little to no information regarding the process, and many adults were still receiving care from family physicians or pediatric neurologists. The study was published online in Epilepsy & Behavior.

Room for Improvement

“We are not doing as good a job with planning for transition as we should,” said Elaine C. Wirrell, MD, who was not involved with the study. “It is not just a simple issue of sending your patient to an adult neurologist. Transition is a process that happens over time, so we need to do a better job getting our families ready for moving on to an adult provider.” Dr. Wirrell is director of pediatric epilepsy and professor of neurology at the Mayo Clinic in Rochester, Minnesota.

Mayo Clinic

Clumsy Transitions

Investigators distributed a 25-question survey to patients and caregivers who attended the 2019 Epilepsy Awareness Day at Disneyland, and through online support groups in North America. Among 58 responses, 32 came from patients between ages 12 and 17 years or their caregivers.

Despite attempts to recruit a diverse cross-section of respondents, most patients had severe epilepsy and comorbidities: 43% had daily or weekly seizures; 45% were on three or more antiseizure medications; and 74% had intellectual disabilities.

Many children with early-life epilepsies suffer from developmental and epileptic encephalopathy, which has associated non-seizure symptoms including learning challenges, behavioral issues, and other medical concerns, Dr. Wirrell said. Therefore, she said, finding a neurologist who treats adults — and has the expertise and interest to care for such patients — can be difficult.

“We’re seeing many patients not making that transition, or maybe not making it appropriately, so they’re not necessarily getting to the providers who have the most expertise in managing their epilepsy.” Among adults surveyed, 27% were still being followed by pediatric neurologists, and 35% were visiting family doctors for epilepsy-related treatment.

Because the needs of children with complex epilepsy can extend well beyond neurology, Dr. Wirrell added, managing such cases often requires multidisciplinary pediatric teams. “Finding that team on the adult side is more challenging.” As a result, she said, patients may transfer their neurology care without getting additional support for comorbidities such as mood disorders and learning disabilities.

The foregoing challenges are complicated by the fact that pediatric neurologists often lack the time (and in the United States, reimbursement) to adequately address the transition process, said Dr. Wirrell. Providers in freestanding children’s hospitals may face additional challenges coordinating with adult-care providers outside their facilities, she said.

“There’s also potentially a reluctance of both families and physicians to transition the patient on, because there’s concern that maybe there isn’t anybody on the adult side who is able to do as good a job as what they have on the pediatric side.”
 

Well-Coordinated Transitions Should Have No Surprises

Transition should be a planned, independence-promoting process that results in smooth, well-coordinated movement of pediatric patients into adult care — one without surprises or disconnections, the authors wrote. However, 55% of respondents never heard the term “transition” from any provider, even though 69% of patients were being treated in academic specialty centers.

Among 12- to 17-year-olds, 72% had never discussed transition with their healthcare team. That figure includes no 17-year-olds. Approximately 90% of respondents said they received sufficient time during healthcare visits, but 54% reported feeling stressed when moving from pediatric to adult care.

Given resource constraints in many pediatric epilepsy programs, the study authors recommended patient-empowerment tools such as a transition toolkit to help patients and families navigate the transition process even in places without formal transition programs.

“Many of these children are coming over with boatloads of medical records,” Dr. Wirrell said. “It’s not fair to the adult provider, who then has to go through all those records.” Instead, she said, pediatric teams should provide succinct summaries of relevant test results, medication side effects, prior treatments tried, and the like. “Those summaries are critically important so that we can get information to the person who needs it.”

Although successful transition requires significant coordination, she added, much of the process can often be handled by nonphysicians. “There are some very good nurse-led transition programs. Often, we can have a nurse providing education to the family and even potentially having a joint visit with an adult epilepsy nurse for complex patients.”

Pediatric providers also must know when to begin the transition process, Dr. Wirrell said. As soon as patients are 13 or 14 years old, she suggested discussing the process with them and their families every 6 to 12 months, covering specifics ranging from how to order medications to why adult patients may need power of attorney designees.

On a broader scale, said Dr. Wirrell, a smooth handoff requires planning. Fortunately, she said, the topic is becoming a significant priority for a growing number of children’s hospitals specific not only to epilepsy, but also to other chronic illnesses.

Dr. Wirrell is co–editor-in-chief for epilepsy.com. She reports no relevant financial interests.

When pediatric patients with epilepsy shift to adult care, inherent challenges are complicated by a near-total lack of efforts to smooth the transition, according to a recent survey. Many respondents received little to no information regarding the process, and many adults were still receiving care from family physicians or pediatric neurologists. The study was published online in Epilepsy & Behavior.

Room for Improvement

“We are not doing as good a job with planning for transition as we should,” said Elaine C. Wirrell, MD, who was not involved with the study. “It is not just a simple issue of sending your patient to an adult neurologist. Transition is a process that happens over time, so we need to do a better job getting our families ready for moving on to an adult provider.” Dr. Wirrell is director of pediatric epilepsy and professor of neurology at the Mayo Clinic in Rochester, Minnesota.

Mayo Clinic

Clumsy Transitions

Investigators distributed a 25-question survey to patients and caregivers who attended the 2019 Epilepsy Awareness Day at Disneyland, and through online support groups in North America. Among 58 responses, 32 came from patients between ages 12 and 17 years or their caregivers.

Despite attempts to recruit a diverse cross-section of respondents, most patients had severe epilepsy and comorbidities: 43% had daily or weekly seizures; 45% were on three or more antiseizure medications; and 74% had intellectual disabilities.

Many children with early-life epilepsies suffer from developmental and epileptic encephalopathy, which has associated non-seizure symptoms including learning challenges, behavioral issues, and other medical concerns, Dr. Wirrell said. Therefore, she said, finding a neurologist who treats adults — and has the expertise and interest to care for such patients — can be difficult.

“We’re seeing many patients not making that transition, or maybe not making it appropriately, so they’re not necessarily getting to the providers who have the most expertise in managing their epilepsy.” Among adults surveyed, 27% were still being followed by pediatric neurologists, and 35% were visiting family doctors for epilepsy-related treatment.

Because the needs of children with complex epilepsy can extend well beyond neurology, Dr. Wirrell added, managing such cases often requires multidisciplinary pediatric teams. “Finding that team on the adult side is more challenging.” As a result, she said, patients may transfer their neurology care without getting additional support for comorbidities such as mood disorders and learning disabilities.

The foregoing challenges are complicated by the fact that pediatric neurologists often lack the time (and in the United States, reimbursement) to adequately address the transition process, said Dr. Wirrell. Providers in freestanding children’s hospitals may face additional challenges coordinating with adult-care providers outside their facilities, she said.

“There’s also potentially a reluctance of both families and physicians to transition the patient on, because there’s concern that maybe there isn’t anybody on the adult side who is able to do as good a job as what they have on the pediatric side.”
 

Well-Coordinated Transitions Should Have No Surprises

Transition should be a planned, independence-promoting process that results in smooth, well-coordinated movement of pediatric patients into adult care — one without surprises or disconnections, the authors wrote. However, 55% of respondents never heard the term “transition” from any provider, even though 69% of patients were being treated in academic specialty centers.

Among 12- to 17-year-olds, 72% had never discussed transition with their healthcare team. That figure includes no 17-year-olds. Approximately 90% of respondents said they received sufficient time during healthcare visits, but 54% reported feeling stressed when moving from pediatric to adult care.

Given resource constraints in many pediatric epilepsy programs, the study authors recommended patient-empowerment tools such as a transition toolkit to help patients and families navigate the transition process even in places without formal transition programs.

“Many of these children are coming over with boatloads of medical records,” Dr. Wirrell said. “It’s not fair to the adult provider, who then has to go through all those records.” Instead, she said, pediatric teams should provide succinct summaries of relevant test results, medication side effects, prior treatments tried, and the like. “Those summaries are critically important so that we can get information to the person who needs it.”

Although successful transition requires significant coordination, she added, much of the process can often be handled by nonphysicians. “There are some very good nurse-led transition programs. Often, we can have a nurse providing education to the family and even potentially having a joint visit with an adult epilepsy nurse for complex patients.”

Pediatric providers also must know when to begin the transition process, Dr. Wirrell said. As soon as patients are 13 or 14 years old, she suggested discussing the process with them and their families every 6 to 12 months, covering specifics ranging from how to order medications to why adult patients may need power of attorney designees.

On a broader scale, said Dr. Wirrell, a smooth handoff requires planning. Fortunately, she said, the topic is becoming a significant priority for a growing number of children’s hospitals specific not only to epilepsy, but also to other chronic illnesses.

Dr. Wirrell is co–editor-in-chief for epilepsy.com. She reports no relevant financial interests.

A recently published prospective study in JAMA Network Open identified a significant association between children’s bone health and their proximity to green areas.

The literature emphasized the benefits of childhood exposure to green spaces for neurocognitive, social, behavioral, and mental development, as well as well-being. In addition, such exposure is linked to lower body mass index, increased physical activity, and reduced risks for overweight, obesity, and hypertension. However, specific data on bone mineral density implications are limited.

To address this gap, Hanne Sleurs, PhD, a researcher at the Universiteit Hasselt in Belgium, and colleagues followed the bone health of 327 participants from birth to 4-6 years and examined correlations with individuals’ exposure to green areas. Data collection occurred from October 2014 to July 2021.

Green spaces were categorized as high (vegetation height > 3 m), low (vegetation height ≤ 3 m), and mixed (combination of both). The distances of green spaces from participants’ residences ranged from a radius of 100 m to 3 km. Radial bone mineral density assessment was conducted using quantitative ultrasound during follow-up consultations.

The scientists found that participants frequently exposed to high and mixed vegetation areas within a 500-m radius of their homes had significantly higher bone mineral density than those at other distances or those frequenting spaces with different vegetation. In addition, access to larger green spaces with mixed and high vegetation within a 1-km radius was significantly associated with a lower likelihood of low bone density in children.

“These findings illustrate the positive impact on bone health of early childhood exposure to green areas near their homes during critical growth and development periods, with long-term implications,” wrote the researchers.

The results aligned with those of a prior study in which authors noted factors contributing to families’ frequent park visits, including shorter distances, safety, and park organization, as well as the natural diversity and activities offered.

One hypothesis explaining improved bone density in children visiting green areas was increased physical activity practiced in these locations. The mechanical load from exercise can activate signaling pathways favoring bone development. Literature also gathered data on the influence of green areas on young populations engaging in physical activities, showing positive outcomes.

According to the study authors, the findings are crucial for public health because they emphasize the need for urban investments in accessible green spaces as a strategy for fracture and osteoporosis prevention. In the long term, such initiatives translate to reduced public health expenses, along with physical and emotional gains in communities adopting environmental strategies, they concluded.

This article was translated from the Medscape Portuguese edition. A version of this article appeared on Medscape.com.

A recently published prospective study in JAMA Network Open identified a significant association between children’s bone health and their proximity to green areas.

The literature emphasized the benefits of childhood exposure to green spaces for neurocognitive, social, behavioral, and mental development, as well as well-being. In addition, such exposure is linked to lower body mass index, increased physical activity, and reduced risks for overweight, obesity, and hypertension. However, specific data on bone mineral density implications are limited.

To address this gap, Hanne Sleurs, PhD, a researcher at the Universiteit Hasselt in Belgium, and colleagues followed the bone health of 327 participants from birth to 4-6 years and examined correlations with individuals’ exposure to green areas. Data collection occurred from October 2014 to July 2021.

Green spaces were categorized as high (vegetation height > 3 m), low (vegetation height ≤ 3 m), and mixed (combination of both). The distances of green spaces from participants’ residences ranged from a radius of 100 m to 3 km. Radial bone mineral density assessment was conducted using quantitative ultrasound during follow-up consultations.

The scientists found that participants frequently exposed to high and mixed vegetation areas within a 500-m radius of their homes had significantly higher bone mineral density than those at other distances or those frequenting spaces with different vegetation. In addition, access to larger green spaces with mixed and high vegetation within a 1-km radius was significantly associated with a lower likelihood of low bone density in children.

“These findings illustrate the positive impact on bone health of early childhood exposure to green areas near their homes during critical growth and development periods, with long-term implications,” wrote the researchers.

The results aligned with those of a prior study in which authors noted factors contributing to families’ frequent park visits, including shorter distances, safety, and park organization, as well as the natural diversity and activities offered.

One hypothesis explaining improved bone density in children visiting green areas was increased physical activity practiced in these locations. The mechanical load from exercise can activate signaling pathways favoring bone development. Literature also gathered data on the influence of green areas on young populations engaging in physical activities, showing positive outcomes.

According to the study authors, the findings are crucial for public health because they emphasize the need for urban investments in accessible green spaces as a strategy for fracture and osteoporosis prevention. In the long term, such initiatives translate to reduced public health expenses, along with physical and emotional gains in communities adopting environmental strategies, they concluded.

This article was translated from the Medscape Portuguese edition. A version of this article appeared on Medscape.com.

A recently published prospective study in JAMA Network Open identified a significant association between children’s bone health and their proximity to green areas.

The literature emphasized the benefits of childhood exposure to green spaces for neurocognitive, social, behavioral, and mental development, as well as well-being. In addition, such exposure is linked to lower body mass index, increased physical activity, and reduced risks for overweight, obesity, and hypertension. However, specific data on bone mineral density implications are limited.

To address this gap, Hanne Sleurs, PhD, a researcher at the Universiteit Hasselt in Belgium, and colleagues followed the bone health of 327 participants from birth to 4-6 years and examined correlations with individuals’ exposure to green areas. Data collection occurred from October 2014 to July 2021.

Green spaces were categorized as high (vegetation height > 3 m), low (vegetation height ≤ 3 m), and mixed (combination of both). The distances of green spaces from participants’ residences ranged from a radius of 100 m to 3 km. Radial bone mineral density assessment was conducted using quantitative ultrasound during follow-up consultations.

The scientists found that participants frequently exposed to high and mixed vegetation areas within a 500-m radius of their homes had significantly higher bone mineral density than those at other distances or those frequenting spaces with different vegetation. In addition, access to larger green spaces with mixed and high vegetation within a 1-km radius was significantly associated with a lower likelihood of low bone density in children.

“These findings illustrate the positive impact on bone health of early childhood exposure to green areas near their homes during critical growth and development periods, with long-term implications,” wrote the researchers.

The results aligned with those of a prior study in which authors noted factors contributing to families’ frequent park visits, including shorter distances, safety, and park organization, as well as the natural diversity and activities offered.

One hypothesis explaining improved bone density in children visiting green areas was increased physical activity practiced in these locations. The mechanical load from exercise can activate signaling pathways favoring bone development. Literature also gathered data on the influence of green areas on young populations engaging in physical activities, showing positive outcomes.

According to the study authors, the findings are crucial for public health because they emphasize the need for urban investments in accessible green spaces as a strategy for fracture and osteoporosis prevention. In the long term, such initiatives translate to reduced public health expenses, along with physical and emotional gains in communities adopting environmental strategies, they concluded.

This article was translated from the Medscape Portuguese edition. A version of this article appeared on Medscape.com.

Mothers on vegan diets during pregnancy may give birth to infants with lower mean birth weights than those of omnivorous mothers and may also have a greater risk of preeclampsia, a prospective study of Danish pregnant women suggests.

According to researchers led by Signe Hedegaard, MD, of the department of obstetrics and Gynecology at Rigshospitalet, Juliane Marie Center, University of Copenhagen, low protein intake may lie behind the observed association with birth weight. The report was published in Acta Obstetricia et Gynecologica Scandinavica.

While vegan-identifying mothers were very few in number, the authors conceded, their babies were more likely to weigh less on average than those of omnivorous mothers — 3441 g vs 3601 g — despite a mean gestation 5 days longer.

Prevalence rates of low birth weight (< 2500 g) in the two groups were 11.1% and 2.5%, respectively, and the prevalence of preeclampsia was 11.1% vs 2.6%. The mean birth weight of infants in the maternal vegan group was about 240 g lower than infants born to omnivorous mothers.

“The lower birth weight of around 240 g among vegans compared with omnivorous mothers in our study strengthens our observation that vegans may be at higher risk of giving birth to low-birth-weight infants. The observed effect size on birth weight is comparable to what is observed among daily smokers relative to nonsmokers in this cohort,“ Dr. Hedegaard and colleagues wrote. “Furthermore, the on-average 5-day longer gestation observed among vegans in our study would be indicative of reduced fetal growth rate rather than lower birth weight due to shorter gestation.”

These findings emerged from data on 66,738 pregnancies in the Danish National Birth Cohort, 1996-2002. A food frequency questionnaire characterized pregnant subjects as fish/poultry-vegetarians, lacto/ovo-vegetarians, vegans, or omnivores, based on their self-reporting in gestational week 30.

A total of 98.7% (n = 65,872) of participants were defined as omnivorous, while 1.0% (n = 666), 0.3% (n = 183), and 0.03% (n = 18) identified as fish/poultry vegetarians, lacto/ovo-vegetarians, or vegans, respectively.

Those following plant-based diets of all types were slightly older, more often parous, and less likely to smoke. This plant dietary group also had a somewhat lower prevalence of overweight and obesity (prepregnancy body mass index > 25 [kg/m^2]) and a higher prevalence of underweight (prepregnancy BMI < 18.5).

Total energy intake was modestly lower from plant-based diets, for a mean difference of 0.3-0.7 MJ (72-167 kcal) per day.

As for total protein intake, this was substantially lower for lacto/ovo-vegetarians and vegans: 13.3% and 10.4% of energy, respectively, compared with 15.4% in omnivores.

Dietary intake of micronutrients was also considerably lower among vegans, but after factoring in intake from dietary supplements, no major differences emerged.

Mean birth weight, birth length, length of gestation, and rate of low birth weight (< 2500 g) were similar among omnivorous, fish/poultry-, and lacto/ovo-vegetarians. The prevalence of gestational diabetes, preeclampsia, and cesarean section was similar across groups, but the prevalence of anemia was higher among fish/poultry- and lacto/ovo-vegetarians than omnivorous participants.

As for preeclampsia, previous research in larger numbers of vegans found no indication of hypertensive disorders during pregnancy. Some studies, however, have suggested a link between preeclampsia and low intake of protein, calcium, or vitamin D, but the evidence is inconclusive, and the mechanism is unclear.

The observed associations, however, do not translate to causality, the authors cautioned. “Future studies should put more emphasis on characterizing the diet among those adhering to vegan diets and other forms of plant-based diets during pregnancy,” they wrote. “That would allow for stronger assumptions on possible causality between any association observed with birth or pregnancy outcomes in such studies and strengthen the basis for dietary recommendations.”

This study was funded by the Danish Council for Independent Research. The Danish National Birth Cohort Study is supported by the March of Dimes Birth Defects Foundation, the Danish Heart Association, Danish Medical Research Council, Sygekassernes Helsefond, the Innovation Fund Denmark, and the Danish National Research Foundation. The authors had no conflicts of interest to declare.

Mothers on vegan diets during pregnancy may give birth to infants with lower mean birth weights than those of omnivorous mothers and may also have a greater risk of preeclampsia, a prospective study of Danish pregnant women suggests.

According to researchers led by Signe Hedegaard, MD, of the department of obstetrics and Gynecology at Rigshospitalet, Juliane Marie Center, University of Copenhagen, low protein intake may lie behind the observed association with birth weight. The report was published in Acta Obstetricia et Gynecologica Scandinavica.

While vegan-identifying mothers were very few in number, the authors conceded, their babies were more likely to weigh less on average than those of omnivorous mothers — 3441 g vs 3601 g — despite a mean gestation 5 days longer.

Prevalence rates of low birth weight (< 2500 g) in the two groups were 11.1% and 2.5%, respectively, and the prevalence of preeclampsia was 11.1% vs 2.6%. The mean birth weight of infants in the maternal vegan group was about 240 g lower than infants born to omnivorous mothers.

“The lower birth weight of around 240 g among vegans compared with omnivorous mothers in our study strengthens our observation that vegans may be at higher risk of giving birth to low-birth-weight infants. The observed effect size on birth weight is comparable to what is observed among daily smokers relative to nonsmokers in this cohort,“ Dr. Hedegaard and colleagues wrote. “Furthermore, the on-average 5-day longer gestation observed among vegans in our study would be indicative of reduced fetal growth rate rather than lower birth weight due to shorter gestation.”

These findings emerged from data on 66,738 pregnancies in the Danish National Birth Cohort, 1996-2002. A food frequency questionnaire characterized pregnant subjects as fish/poultry-vegetarians, lacto/ovo-vegetarians, vegans, or omnivores, based on their self-reporting in gestational week 30.

A total of 98.7% (n = 65,872) of participants were defined as omnivorous, while 1.0% (n = 666), 0.3% (n = 183), and 0.03% (n = 18) identified as fish/poultry vegetarians, lacto/ovo-vegetarians, or vegans, respectively.

Those following plant-based diets of all types were slightly older, more often parous, and less likely to smoke. This plant dietary group also had a somewhat lower prevalence of overweight and obesity (prepregnancy body mass index > 25 [kg/m^2]) and a higher prevalence of underweight (prepregnancy BMI < 18.5).

Total energy intake was modestly lower from plant-based diets, for a mean difference of 0.3-0.7 MJ (72-167 kcal) per day.

As for total protein intake, this was substantially lower for lacto/ovo-vegetarians and vegans: 13.3% and 10.4% of energy, respectively, compared with 15.4% in omnivores.

Dietary intake of micronutrients was also considerably lower among vegans, but after factoring in intake from dietary supplements, no major differences emerged.

Mean birth weight, birth length, length of gestation, and rate of low birth weight (< 2500 g) were similar among omnivorous, fish/poultry-, and lacto/ovo-vegetarians. The prevalence of gestational diabetes, preeclampsia, and cesarean section was similar across groups, but the prevalence of anemia was higher among fish/poultry- and lacto/ovo-vegetarians than omnivorous participants.

As for preeclampsia, previous research in larger numbers of vegans found no indication of hypertensive disorders during pregnancy. Some studies, however, have suggested a link between preeclampsia and low intake of protein, calcium, or vitamin D, but the evidence is inconclusive, and the mechanism is unclear.

The observed associations, however, do not translate to causality, the authors cautioned. “Future studies should put more emphasis on characterizing the diet among those adhering to vegan diets and other forms of plant-based diets during pregnancy,” they wrote. “That would allow for stronger assumptions on possible causality between any association observed with birth or pregnancy outcomes in such studies and strengthen the basis for dietary recommendations.”

This study was funded by the Danish Council for Independent Research. The Danish National Birth Cohort Study is supported by the March of Dimes Birth Defects Foundation, the Danish Heart Association, Danish Medical Research Council, Sygekassernes Helsefond, the Innovation Fund Denmark, and the Danish National Research Foundation. The authors had no conflicts of interest to declare.

Mothers on vegan diets during pregnancy may give birth to infants with lower mean birth weights than those of omnivorous mothers and may also have a greater risk of preeclampsia, a prospective study of Danish pregnant women suggests.

According to researchers led by Signe Hedegaard, MD, of the department of obstetrics and Gynecology at Rigshospitalet, Juliane Marie Center, University of Copenhagen, low protein intake may lie behind the observed association with birth weight. The report was published in Acta Obstetricia et Gynecologica Scandinavica.

While vegan-identifying mothers were very few in number, the authors conceded, their babies were more likely to weigh less on average than those of omnivorous mothers — 3441 g vs 3601 g — despite a mean gestation 5 days longer.

Prevalence rates of low birth weight (< 2500 g) in the two groups were 11.1% and 2.5%, respectively, and the prevalence of preeclampsia was 11.1% vs 2.6%. The mean birth weight of infants in the maternal vegan group was about 240 g lower than infants born to omnivorous mothers.

“The lower birth weight of around 240 g among vegans compared with omnivorous mothers in our study strengthens our observation that vegans may be at higher risk of giving birth to low-birth-weight infants. The observed effect size on birth weight is comparable to what is observed among daily smokers relative to nonsmokers in this cohort,“ Dr. Hedegaard and colleagues wrote. “Furthermore, the on-average 5-day longer gestation observed among vegans in our study would be indicative of reduced fetal growth rate rather than lower birth weight due to shorter gestation.”

These findings emerged from data on 66,738 pregnancies in the Danish National Birth Cohort, 1996-2002. A food frequency questionnaire characterized pregnant subjects as fish/poultry-vegetarians, lacto/ovo-vegetarians, vegans, or omnivores, based on their self-reporting in gestational week 30.

A total of 98.7% (n = 65,872) of participants were defined as omnivorous, while 1.0% (n = 666), 0.3% (n = 183), and 0.03% (n = 18) identified as fish/poultry vegetarians, lacto/ovo-vegetarians, or vegans, respectively.

Those following plant-based diets of all types were slightly older, more often parous, and less likely to smoke. This plant dietary group also had a somewhat lower prevalence of overweight and obesity (prepregnancy body mass index > 25 [kg/m^2]) and a higher prevalence of underweight (prepregnancy BMI < 18.5).

Total energy intake was modestly lower from plant-based diets, for a mean difference of 0.3-0.7 MJ (72-167 kcal) per day.

As for total protein intake, this was substantially lower for lacto/ovo-vegetarians and vegans: 13.3% and 10.4% of energy, respectively, compared with 15.4% in omnivores.

Dietary intake of micronutrients was also considerably lower among vegans, but after factoring in intake from dietary supplements, no major differences emerged.

Mean birth weight, birth length, length of gestation, and rate of low birth weight (< 2500 g) were similar among omnivorous, fish/poultry-, and lacto/ovo-vegetarians. The prevalence of gestational diabetes, preeclampsia, and cesarean section was similar across groups, but the prevalence of anemia was higher among fish/poultry- and lacto/ovo-vegetarians than omnivorous participants.

As for preeclampsia, previous research in larger numbers of vegans found no indication of hypertensive disorders during pregnancy. Some studies, however, have suggested a link between preeclampsia and low intake of protein, calcium, or vitamin D, but the evidence is inconclusive, and the mechanism is unclear.

The observed associations, however, do not translate to causality, the authors cautioned. “Future studies should put more emphasis on characterizing the diet among those adhering to vegan diets and other forms of plant-based diets during pregnancy,” they wrote. “That would allow for stronger assumptions on possible causality between any association observed with birth or pregnancy outcomes in such studies and strengthen the basis for dietary recommendations.”

This study was funded by the Danish Council for Independent Research. The Danish National Birth Cohort Study is supported by the March of Dimes Birth Defects Foundation, the Danish Heart Association, Danish Medical Research Council, Sygekassernes Helsefond, the Innovation Fund Denmark, and the Danish National Research Foundation. The authors had no conflicts of interest to declare.