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Gestational inhalation of nanoparticles disrupts placental zone structure and induces vascular placentation in rats

Seymore, T.; McWilliams, D.; Ozkuyumcu, K.; Louro, P.; Cary, C.; Goedken, M.; Joseph, L.; Stapleton, P.

2026-06-11 pharmacology and toxicology
10.64898/2026.06.08.730946 bioRxiv
Show abstract

Airborne contaminants represent a significant environmental health concern for vulnerable populations, including pregnant individuals. In particular, maternal inhalation of particulate matter (PM) during pregnancy has been linked to adverse outcomes such as fetal growth restriction (FGR). Increasing evidence identifies placental dysfunction as a mechanism for this condition. Placental efficiency, defined as the ratio of fetal mass to placental mass, is frequently altered in FGR. Many aspects contribute to placental efficiency including surface area available for nutrient and waste exchange and placental vascularization. In this study, we hypothesized that maternal inhalation of ultrafine PM during pregnancy would reduce the size and/or number of placental structures that are necessary for nutrient transport. Engineered titanium dioxide nanoparticles (nano-TiO2) were used as a proxy for ultrafine PM and pregnant Sprague Dawley rats were exposed via whole-body inhalation to nano-TiO2 aerosols (9.23 {+/-} 0.39 mg/m3) from gestational day (GD) 5 to 19. On GD 20, placentas were collected and processed for histological evaluation. While gestational inhalation of nano-TiO2 did not affect placental weight or efficiency, it reduced decidua and labyrinth zone size. Exposed placentas exhibited compensatory adaptations characterized by increased blood space number and maternal blood space expansion. Together, these findings indicate that inhalation of nanoparticles disrupts placental structure while simultaneously eliciting adaptive vascular responses that may preserve nutrient exchange capacity. By characterizing the effects of PM exposure on placental morphology and structure, this study highlights the placenta as a vulnerable target of inhaled pollutants and provides mechanistic insight into pathways contributing to PM-induced FGR.

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