Prenatal exposure to environmental factors and congenital limb defects.

Q Medicine

Birth Defects Research Part C-Embryo Today-Reviews Pub Date : 2016-09-01 DOI:10.1002/bdrc.21140

P. Alexander, K. L. Clark, R. Tuan

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引用次数: 25

Abstract

Limb congenital defects afflict approximately 0.6:1000 live births. In addition to genetic factors, prenatal exposure to drugs and environmental toxicants, represents a major contributing factor to limb defects. Examples of well-recognized limb teratogenic agents include thalidomide, warfarin, valproic acid, misoprostol, and phenytoin. While the mechanism by which these agents cause dymorphogenesis is increasingly clear, prediction of the limb teratogenicity of many thousands of as yet uncharacterized environmental factors (pollutants) remains inexact. This is limited by the insufficiencies of currently available models. Specifically, in vivo approaches using guideline animal models have inherently deficient predictive power due to genomic and anatomic differences that complicate mechanistic comparisons. On the other hand, in vitro two-dimensional (2D) cell cultures, while accessible for cellular and molecular experimentation, do not reflect the three-dimensional (3D) morphogenetic events in vivo nor systemic influences. More robust and accessible models based on human cells that accurately replicate specific processes of embryonic limb development are needed to enhance limb teratogenesis prediction and to permit mechanistic analysis of the adverse outcome pathways. Recent advances in elucidating mechanisms of normal development will aid in the development of process-specific 3D cell cultures within specialized bioreactors to support multicellular microtissues or organoid constructs that will lead to increased understanding of cell functions, cell-to-cell signaling, pathway networks, and mechanisms of toxicity. The promise is prompting researchers to look to such 3D microphysiological systems to help sort out complex and often subtle interactions relevant to developmental malformations that would not be evident by standard 2D cell culture testing. Birth Defects Research (Part C) 108:243-273, 2016. © 2016 Wiley Periodicals, Inc.

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产前环境因素暴露与先天性肢体缺陷。

肢体先天性缺陷约占活产婴儿的0.6:1000。除了遗传因素外，产前接触药物和环境毒物是造成肢体缺陷的一个主要因素。众所周知的肢体致畸剂包括沙利度胺、华法林、丙戊酸、米索前列醇和苯妥英。虽然这些药物引起畸形发生的机制越来越清楚，但对数千种尚未表征的环境因素(污染物)的肢体致畸性的预测仍然不准确。这受到当前可用模型不足的限制。具体来说，由于基因组和解剖结构的差异使机制比较复杂化，使用指导动物模型的体内方法固有地缺乏预测能力。另一方面，体外二维(2D)细胞培养虽然可用于细胞和分子实验，但不能反映体内三维(3D)形态发生事件或系统性影响。需要基于人类细胞的更强大和可访问的模型来准确复制胚胎肢体发育的特定过程，以增强肢体致畸的预测，并允许对不良后果途径的机制分析。在阐明正常发育机制方面的最新进展将有助于在专门的生物反应器中开发过程特异性3D细胞培养，以支持多细胞微组织或类器官结构，从而增加对细胞功能、细胞间信号传导、通路网络和毒性机制的理解。这一前景促使研究人员将目光投向这种3D微生理系统，以帮助理清与发育畸形相关的复杂而微妙的相互作用，这些相互作用在标准的2D细胞培养测试中是不明显的。出生缺陷研究(C辑)(8):444 - 444,2016。©2016 Wiley期刊公司

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来源期刊

Birth Defects Research Part C-Embryo Today-Reviews DEVELOPMENTAL BIOLOGY-

CiteScore

3.65

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： John Wiley & Sons and the Teratology Society are please to announce a new journal, Birth Defects Research . This new journal is a comprehensive resource of original research and reviews in fields related to embryo-fetal development and reproduction. Birth Defects Research draws from the expertise and reputation of two current Wiley journals, and introduces a new forum for reviews in developmental biology and embryology. Part C: Embryo Today: Reviews