Mouse Imaging Centre, The Hospital for Sick Children, Toronto, Ontario, Canada.
Department of Medical Biophysics, University of Toronto, Toronto, Ontario, Canada.
J Physiol. 2018 Aug;596(15):3285-3297. doi: 10.1113/JP274845. Epub 2017 Sep 24.
Chronic fetal hypoxia is one of the most common complications of pregnancy and is known to cause fetal growth restriction. The structural adaptations of the placental vasculature responsible for growth restriction with chronic hypoxia are not well elucidated. Using a mouse model of chronic maternal hypoxia in combination with micro-computed tomography and scanning electron microscopy, we found several placental adaptations that were beneficial to fetal growth including capillary expansion, thinning of the interhaemal membrane and increased radial artery diameters, resulting in a large drop in total utero-placental vascular resistance. One of the mechanisms used to achieve the rapid increase in capillaries was intussusceptive angiogenesis, a strategy used in human placental development to form terminal gas-exchanging villi. These results contribute to our understanding of the structural mechanisms of the placental vasculature responsible for fetal growth restriction and provide a baseline for understanding adaptive physiological responses of the placenta to chronic hypoxia.
The fetus and the placenta in eutherian mammals have a unique set of compensatory mechanisms to respond to several pregnancy complications including chronic maternal hypoxia. This study examined the structural adaptations of the feto- and utero-placental vasculature in an experimental mouse model of chronic maternal hypoxia (11% O from embryonic day (E) 14.5-E17.5). While placental weights were unaffected by exposure to chronic hypoxia, using micro-computed tomography, we found a 44% decrease in the absolute feto-placental arterial vascular volume and a 30% decrease in total vessel segments in the chronic hypoxia group compared to control group. Scanning electron microscopy imaging showed significant expansion of the capillary network; consequently, the interhaemal membrane was 11% thinner to facilitate maternal-fetal exchange in the chronic hypoxia placentas. One of the mechanisms for the rapid capillary expansion was intussusceptive angiogenesis. Analysis of the utero-placental arterial tree showed significant increases (24%) in the diameter of the radial arteries, resulting in a decrease in the total utero-placental resistance by 2.6-fold in the mice exposed to chronic maternal hypoxia. Together these adaptations acted to preserve placental weight whereas fetal weight was decreased.
慢性胎儿缺氧是妊娠中最常见的并发症之一,已知会导致胎儿生长受限。导致慢性缺氧时胎盘血管结构适应生长受限的机制尚未完全阐明。本研究使用慢性母体缺氧的小鼠模型结合微计算机断层扫描和扫描电子显微镜,发现了几种有利于胎儿生长的胎盘适应机制,包括毛细血管扩张、血腔膜变薄和放射状动脉直径增加,从而使总的子宫胎盘血管阻力大幅下降。实现毛细血管快速增加的机制之一是出芽型血管生成,这是人类胎盘发育中形成终末气体交换绒毛的策略。这些结果有助于我们理解导致胎儿生长受限的胎盘血管结构机制,并为理解胎盘对慢性缺氧的适应性生理反应提供基线。
真兽类哺乳动物的胎儿和胎盘具有一套独特的补偿机制,以应对包括慢性母体缺氧在内的几种妊娠并发症。本研究在慢性母体缺氧(从胚胎第 14.5 天到第 17.5 天,氧浓度 11%)的实验小鼠模型中检查了胎-胎盘血管的结构适应。尽管胎盘重量不受慢性缺氧暴露的影响,但通过微计算机断层扫描,我们发现与对照组相比,慢性缺氧组的绝对胎-胎盘动脉血管体积减少了 44%,总血管段减少了 30%。扫描电子显微镜成像显示毛细血管网络显著扩张;因此,在慢性缺氧的胎盘中,血腔膜变薄了 11%,以促进母体-胎儿交换。快速毛细血管扩张的机制之一是出芽型血管生成。对子宫胎盘动脉树的分析表明,放射状动脉的直径显著增加(24%),导致在慢性母体缺氧暴露的小鼠中,子宫胎盘总阻力降低了 2.6 倍。这些适应共同作用以维持胎盘重量,而胎儿体重则下降。