Rising global temperatures pose a new threat to brain development in children, according to a groundbreaking study led by researchers at the Barcelona Institute for Global Health (ISGlobal). Published in Environment International, the research reveals that exposure to elevated ambient temperatures during pregnancy and early infancy correlates with slower growth of the thalamus later in childhood, signaling possible long-term neurological consequences linked to climate change.
The study harnessed data from 3,251 children enrolled in the Generation R Study, a comprehensive birth cohort based in the Netherlands. By integrating a sophisticated high-resolution climate model with longitudinal brain MRI scans taken at approximately 10 and 14 years of age, the researchers could map how temperature exposures from conception through 8.5 years influenced neurodevelopment. This novel methodology enabled detailed tracking of 11 distinct brain regions to uncover the specific impacts of thermal environments during sensitive developmental periods.
Remarkably, among all examined brain structures, only the thalamus demonstrated a consistent association with early life heat exposure. This central brain hub is essential for relaying sensory and motor information to the cerebral cortex and develops exceptionally early in fetal life along a tightly choreographed timeline. The thalamus’ dense vascularization during gestation may explain its heightened vulnerability, where heat-induced placental dysfunction or altered blood flow potentially disrupts its normal maturation.
The researchers pinpointed a critical exposure window extending from conception to the fifth month postpartum, where sustained monthly mean temperatures around 20.5°C—significantly above the 12.5°C reference—were linked to diminished thalamic growth between ages 9 and 15. In contrast, exposure to colder temperatures showed no significant relationship with brain structure alterations, underscoring the unique risks posed by heat.
While the precise biological mechanisms remain speculative, existing evidence suggests several plausible pathways. Heat stress during pregnancy may trigger maternal hormonal imbalances, impair placental protective functions, or interfere with serotonin signaling critical for thalamocortical connectivity. Additionally, heat-related oxidative stress and inflammatory responses may exacerbate prenatal neural vulnerabilities, though further investigation is essential.
Functionally, slower thalamic growth correlated with increased externalizing behavioral symptoms in adolescence, such as aggression and rule-breaking, yet no direct effects on cognitive performance were detected. These findings raise concerns about potential links between early thermal insults and neurodevelopmental disorders, highlighting the need for future longitudinal studies to explore these associations and underlying mechanisms thoroughly.
Lead author Laura Granés and her team emphasize the urgent public health implications amidst escalating global temperatures due to climate change. “Protecting pregnant women and infants from excessive heat exposure could become a crucial intervention to safeguard healthy brain development,” the researchers conclude. Their work calls for heightened awareness and targeted strategies to mitigate thermal risks during these formative stages of human development.
Subject of Research: People
Article Title: Early life ambient temperature and brain volumes change throughout childhood
News Publication Date: Not specified
Web References: http://dx.doi.org/10.1016/j.envint.2026.110385
References: Granés, L., Essers, E., Kusters, M. S. W., Petricola, S., Tiemeier, P. H., Soriano-Mas, P. C., Schwartz, P. J., & Guxens, P. M. (2026). Early life ambient temperature and brain volumes change throughout childhood. Environment International, 214(110385), 110385.
Keywords: Developmental neuroscience, Heat, Children, Pregnancy, Thalamus
Tags: ambient temperature and child neurodevelopmentChild brain development and heat exposureclimate change impact on neurodevelopmentclimate-related risks to childhood brain healthdevelopmental neurobiology and environmental factorsearly infancy environmental stressors and brain structureearly life temperature effects on brain growthhigh-resolution climate modeling in neurodevelopment researchlong-term neurological consequences of climate changelongitudinal MRI studies in childrenprenatal heat exposure neurological effectsthalamus development and vulnerability



