Does Arsenic Increase the Risk of Neural Tube Defects Among a Highly Exposed Population? A New Case-control Study in Bangladesh

Overview

Journal Birth Defects Res

Specialties Reproductive Medicine
Toxicology

Date 2016 Nov 2

PMID 27801974

Citations 12

Authors

Maitreyi Mazumdar

Affiliations

Soon will be listed here.

Abstract

Background: Neural tube defects are debilitating birth defects that occur when the developing neural plate fails to close in early gestation. Arsenic induces neural tube defects in animal models, but whether environmental arsenic exposure increases risk of neural tube defects in humans is unknown.

Methods: We describe a new case-control study in Bangladesh, a country currently experiencing an epidemic of arsenic poisoning through contaminated drinking water. We plan to understand how arsenic influences risk of neural tube defects in humans through mechanisms that include disruption of maternal glucose and folate metabolism, as well as epigenetic effects. We also investigate whether sweat chloride concentration, a potential new biomarker for arsenic toxicity, can be used to identify women at higher risk for having a child affected by neural tube defect. We will collect dural tissue from cases, obtained at the time of surgical closure of the defect, and believe investigation of these samples will provide insight into the epigenetic mechanisms by which prenatal arsenic exposure affects the developing nervous system.

Conclusion: These studies explore mechanisms by which arsenic may increase risk of neural tube defects in humans and use a unique population with high arsenic exposure to test hypotheses. If successful, these studies may assist countries with high arsenic exposure such as Bangladesh to identify populations at high risk of neural tube defects, as well as direct development of novel screening strategies for maternal risk.Birth Defects Research 109:92-98, 2017.© 2016 The Authors Birth Defects Research Published by Wiley Periodicals, Inc.

Citing Articles

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Parental arsenic exposure and tissue-specific DNA methylation in Bangladeshi infants with spina bifida.

Tindula G, Mukherjee S, Ekramullah S, Arman D, Islam J, Biswas S Epigenetics. 2024; 19(1):2416345.

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Arsenic modifies the effect of folic acid in spina bifida prevention, a large hospital-based case-control study in Bangladesh.

Wei C, Mukherjee S, Ekramullah S, Arman D, Islam M, Azim M Environ Health. 2024; 23(1):51.

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The Importance of Neurosurgical Intervention and Surgical Timing for Management of Pediatric Patients with Myelomeningoceles in Bangladesh.

Mukherjee S, Papadakis J, Arman D, Islam J, Azim M, Rahman A World Neurosurg. 2024; 187:e673-e682.

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A quest for genetic causes underlying signaling pathways associated with neural tube defects.

Rai S, Leydier L, Sharma S, Katwala J, Sahu A Front Pediatr. 2023; 11:1126209.

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