Faculty Bibliography

Evidence is inconsistent regarding which windows of PM_2.5 exposure are critical for adverse perinatal outcomes. We investigated associations between timing of gestational PM_2.5 exposure and perinatal outcomes. Participants included 19,108 mother-infant dyads from 51 sites of the Environmental influences on Child Health Outcomes (ECHO) cohort. Repeated measures of PM_2.5 exposure were included based on high-resolution spatiotemporal models for trimesters 1-3, early first trimester (≤14 days), and late first trimester (70-92 days). We estimated associations of PM_2.5 exposure (per 5 μg/m³ increase) and continuous outcomes (gestational age at birth [GA] and birthweight for gestational age z-scores [BWZs]) using generalized estimating equation (GEE) models for linear regression. Poisson regression via GEE was used to estimate risk ratios (RRs) of PM_2.5 exposure (per 5 μg/m³ increase) with binary outcomes (preterm birth [PTB], <37 completed weeks of gestation), and term small for gestational age [SGA], <10th percentile). We explored effect modification by participants' characteristics. In fully adjusted models, early 1st trimester PM_2.5 exposure was associated with lower BWZ (β = -0.03, 95 % CI -0.06, -0.001); association with term SGA was RR = 1.06, 95 % CI 0.99, 1.13. Results were mostly null for other windows of gestational exposure. When stratified by sex, early pregnancy PM_2.5 exposure and lower BWZ associations were observed among females, but not males. Suggestive evidence indicates that associations of PM_2.5 exposure with GA, PTB risk, and term SGA risk may vary by maternal race and ethnicity. Our results suggest that policies and practices that reduce the risks of PM_2.5 exposure, particularly in pre-conception and early pregnancy, may improve perinatal outcomes.

BACKGROUND:There is growing interest in understanding the link between early life exposures to ambient air pollution and childhood blood pressure; however, existing findings, largely from single site/cohort studies, are inconclusive. METHODS:(per 10-ppb) exposures with blood pressure outcomes were estimated using linear and Poisson regressions adjusted for sociodemographic, lifestyle, temporal, and spatial confounders. RESULTS:with both SBP (β: -2.42, 95 %CI: -4.70, -0.14) and DBP (β: -1.94, 95 %CI: -3.81, -0.08) percentiles were suggested. CONCLUSION/CONCLUSIONS:and blood pressure was counterintuitive and warrants further investigation.

Pediatric hypertension is increasing in prevalence and is associated with cardiovascular and kidney outcomes in adulthood. Beyond traditional contributors such as obesity and kidney disease, a growing body of evidence implicates environmental exposures in the early disruption of blood pressure regulation. This review aims to evaluate and synthesize current evidence on key exposure routes, including airborne pollutants, heavy metals, and endocrine-disrupting chemicals, and their impact on pediatric blood pressure regulation through biological pathways involving vascular integrity, kidney sodium handling, neurohormonal signaling, and epigenetic programming. Mechanistic studies support roles for oxidative stress, endothelial dysfunction, hormonal dysregulation, and persistent transcriptional changes in mediating exposure-related blood pressure elevations. Although pediatric data remain limited and often are derived from observational studies, the plausibility of these pathways and the developmental sensitivity of the cardiovascular system underscore the urgency for longitudinal research. Clinical and public health strategies should incorporate environmental risk assessment to better identify modifiable exposures contributing to hypertension in children.

OBJECTIVE:Early-life exposure to phthalates, widely used in consumer products, may induce developmental lung adaptations and predispose to respiratory morbidity throughout childhood. We assessed the associations of fetal phthalate exposure with wheezing, asthma, and lung function from birth to adolescence. METHODS:We performed 1-stage individual participant data meta-analyses with data from six European birth cohorts (3,745 mother-child pairs) to assess associations of pregnancy-averaged maternal urinary concentrations of 7 phthalate metabolites and 3 phthalate groups (high- and low-molecular-weight phthalate metabolites and sum of di-2-ethylhexyl phthalate metabolites) with wheezing in infancy (0-1 years) and at preschool age (1-5 years), and asthma and lung function at school age (5-12 years). RESULTS:z-scores after multiple testing correction. CONCLUSION/CONCLUSIONS:Fetal exposure to higher phthalate concentrations is associated with lung function adaptations, while overall no consistent associations were observed with childhood wheezing or asthma. Future studies are needed to assess the causality of the observed associations, to identify the underlying mechanisms, and to assess potential respiratory consequences in adult life.

Hypertensive disorders of pregnancy (HDP) are a leading cause of maternal and infant mortality and morbidity worldwide. This prospective cohort study investigated the association of racial and ethnic disparities in HDP and explored the potential mediation effect of environmental chemical exposures on excess HDP risk among non-Hispanic Black pregnant people. A total of 3,279 pregnant people were included from 11 cohorts across the United States in the Environmental influences on Child Health Outcomes (ECHO) Program. We analyzed 20 environmental chemicals detected in over 70 % of biospecimens collected during pregnancy. Among Hispanic, non-Hispanic White, and non-Hispanic Black participants, 11.8 %, 10.8 %, and 16.6 % were diagnosed with HDP, respectively. Compared with non-Hispanic White participants, non-Hispanic Black participants had a higher risk of HDP (aRR = 1.48; 95 % CI 1.13-1.94) and higher levels of traditional phthalate metabolites, but lower levels of phthalate alternative metabolites and perfluorooctanoic acid. Hispanic participants had a lower risk of gestational hypertension (aRR = 0.62; 95 % CI 0.40-0.98) and lower levels of perfluoroalkyl substances than non-Hispanic White participants. Critically, despite these race/ethnicity-specific exposure patterns, individual chemical exposures did not mediate the association between racial/ethnic group and HDP. These findings highlight the need to investigate cumulative chemical mixtures and non-chemical environmental and social determinants as potential drivers of HDP disparities.

The exponential rise in plastic production has driven widespread contamination by micro- and nanoplastics (MNPs) in the environment. These plastic particles and their chemical additives have been detected in water sources, human bodily fluids, and reproductive tissues. With global fertility rates declining, their role as potential contributors is under investigation. This scoping review compares findings from in vitro experiments, in vivo studies across animal models, and epidemiological data to assess potential reproductive hazards associated with MNP exposure. Forty original studies published within the last decade were identified. MNPs have been detected in human breast milk, placenta, endometrium, ovaries, testis, semen, follicular fluid, blood, and urine samples. Humans are estimated to absorb 74,000-121,000 particles annually through inhalation, ingestion, skin contact, and use of plastic materials, including medical devices. Experimental evidence demonstrates that MNPs can cross biological barriers, interact with cells, and disrupt cellular pathways, including steroidogenesis, energy metabolism, inflammatory pathways, and oxidative stress. Thirty in vivo animal studies have associated MNPs with altered reproductive endpoints in both males (i.e., altered semen quality and spermatogenesis) and females (i.e., altered folliculogenesis, depleted ovarian reserve, and reduced litter sizes), with possible transgenerational effects. In conclusion, current evidence suggests MNPs may represent a reproductive health hazard to humans and animals. The relative contributions of particle toxicity and their chemical additives remain difficult to disentangle. Overall, plastics and their associated chemicals represent a serious health and environmental concern, which continues to grow in the absence of restrictions and international agreements.

OBJECTIVE:To examine associations between oxidative stress and fetal weight across pregnancy. STUDY DESIGN/METHODS:Cohort study of pregnant participants from 2016-2021 in New York City with urinary lipid, protein, and DNA oxidative stress biomarkers (<18, 18-25, >25 weeks) and estimated fetal weight from ultrasound fetal biometry with the HadlockIII formula (20, 30, 36 weeks). RESULT/RESULTS:percentile. Oxidative stress biomarkers of protein damage were associated with larger estimated fetal weight at 20 (3.4 [95% CI: 1.2, 5.7]) and 36 weeks (16.5 [95% CI: 5.2, 27.8]). CONCLUSION/CONCLUSIONS:These findings advance our understanding of different oxidative stress pathways and their potential role in fetal growth.

Children face an urgent threat in the form of hazards posed by plastics in the environment. Despite robust and rapidly accumulating evidence on the effects of plastic on children's health, plastic presents a paradox for child health providers: while plastic is a vehicle for so many interventions, robust evidence from laboratory and human studies show that chemicals used to produce plastics contribute to chronic conditions in multiple organ systems and disrupt hormone function, and exposure to plastic-derived toxins is associated with adverse birth outcomes, metabolic conditions, neurodevelopmental disease and disability, and reproductive conditions. Evidence-based, safe, simple, and low-cost steps exist for child health providers in primary care to help families limit children's exposure to plastic-derived toxins. Health-care providers also have a crucial opportunity to protect the health and wellbeing of future generations of children by supporting local and global campaigns for governments, industries, and the general public to reduce the accumulation of plastics in the environment and minimise the use of plastics within health-care systems.

Phenolic compounds may be harmful to the developing fetus, but many have not been studied in-depth for adverse childhood allergic and respiratory health effects. We hypothesized that higher levels of phenolic compounds in prenatal spot urine would be associated with greater odds of childhood atopic dermatitis, allergic rhinitis, and asthma, and that child sex may modify these associations. 3198 mother-child paired cases were enrolled from 16 cohorts in the U.S. ECHO consortium. Fifteen phenols (e.g. benzophenones, parabens, bisphenols, triclosans) were measured from mother's urine during pregnancy using a multi-class chemical panel. Childhood outcomes included parent-reported atopic dermatitis (1466 mother-child pairs) between ages 0-3 years, and allergic rhinitis (901 mother-child pairs) and asthma (1662 mother-child pairs) between ages 5-9 years. Prenatal parabens were associated with increased odds of atopic dermatitis (odds ratio (OR) 1.13, 95 % confidence intervals (CI) 1.02, 1.26). Benzophenones were associated with lower odds of asthma (OR 0.77, CI 0.66, 0.90). Compared to boys, girls demonstrated higher odds of parabens (1.21, CI 1.04, 1.42), benzophenones (1.18, CI 1.00, 1.38) and bisphenol S (1.21, CI 1.03, 1.43) being associated with atopic dermatitis, and of the benzophenones (1.46, CI 1.11, 1.93) being associated with allergic rhinitis. An association of benzophenones (0.66, CI 0.53, 0.83) with lower odds of asthma was stronger among boys. These findings suggest that prenatal paraben and other phenol exposures may adversely affect early-life allergic and respiratory outcomes, with sex-specific vulnerability. Novel, multi-modality approaches to reduce maternal phenol exposure during pregnancy are urgently needed to protect children's health.

Prior research links prenatal exposure to organophosphate (OP) pesticides to adverse health outcomes via molecular mechanisms, such as oxidative stress, neurotransmitter disruption, and mitochondrial dysfunction. This study investigates such mechanisms by assessing the relationships between prenatal OP pesticide exposure and targeted urinary maternal metabolomic profiles using data from the New York University Children's Health and Environment Study (NYU CHES) cohort (n = 890). Urine samples were collected at three time points during pregnancy (T