Maureen Peers de Nieuwburgh, Mallory Hunt, Prashant Chandrasekaran, Tiffaney L Vincent, Kevin B Hayes, Isabel R Randazzo, Meredith Gunder, Felix R De Bie, Arthur Colson, Minqi Lu, Hongbo Wen, Sylvia N Michki, Jack Rychik, Fréderic Debiève, Jeremy Katzen, Lisa R Young, Marcus G Davey, Alan W Flake, J William Gaynor, David B Frank
{"title":"Chronic Hypoxia in an EXTrauterine Environment for Neonatal Development Impairs Lung Development.","authors":"Maureen Peers de Nieuwburgh, Mallory Hunt, Prashant Chandrasekaran, Tiffaney L Vincent, Kevin B Hayes, Isabel R Randazzo, Meredith Gunder, Felix R De Bie, Arthur Colson, Minqi Lu, Hongbo Wen, Sylvia N Michki, Jack Rychik, Fréderic Debiève, Jeremy Katzen, Lisa R Young, Marcus G Davey, Alan W Flake, J William Gaynor, David B Frank","doi":"10.1165/rcmb.2024-0012OC","DOIUrl":null,"url":null,"abstract":"<p><p>Severe fetal hypoxia poses a significant risk to lung development resulting in severe postnatal complications. Existing chronic hypoxia animal models lack the ability to achieve pathologically reduced fetal oxygen without compromising animal development, placental blood flow, or maternal health. Using an established model of isolated chronic hypoxia involving the Extrauterine Environment for Neonatal Development (EXTEND), we are able to investigate the direct impact of fetal hypoxia on lung development. Oxygen delivery to preterm fetal lambs (105-110 days GA) delivered by cesarean section was reduced, and animals were supported on EXTEND through the canalicular or saccular stage of lung development. Fetal lambs in hypoxic conditions showed significant growth restriction compared to their normoxic counterparts. We also observed modest aberrant vascular remodeling in the saccular group after hypoxic conditions with decreased macrovessel numbers, microvascular endothelial cell numbers, and increased peripheral vessel muscularization. In addition, fetal hypoxia resulted in enlarged distal airspaces and decreased septal wall volume. Moreover, there was a reduction in mature SFTPB and processed SFTPC protein expression concomitant with a decrease in AT2 cell number. These findings demonstrate that maternally-independent fetal hypoxia predominantly impacts distal airway development, AT2 cell number, and surfactant production with mild effects on the vasculature.</p>","PeriodicalId":7655,"journal":{"name":"American Journal of Respiratory Cell and Molecular Biology","volume":" ","pages":""},"PeriodicalIF":5.9000,"publicationDate":"2024-10-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"American Journal of Respiratory Cell and Molecular Biology","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1165/rcmb.2024-0012OC","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"BIOCHEMISTRY & MOLECULAR BIOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Severe fetal hypoxia poses a significant risk to lung development resulting in severe postnatal complications. Existing chronic hypoxia animal models lack the ability to achieve pathologically reduced fetal oxygen without compromising animal development, placental blood flow, or maternal health. Using an established model of isolated chronic hypoxia involving the Extrauterine Environment for Neonatal Development (EXTEND), we are able to investigate the direct impact of fetal hypoxia on lung development. Oxygen delivery to preterm fetal lambs (105-110 days GA) delivered by cesarean section was reduced, and animals were supported on EXTEND through the canalicular or saccular stage of lung development. Fetal lambs in hypoxic conditions showed significant growth restriction compared to their normoxic counterparts. We also observed modest aberrant vascular remodeling in the saccular group after hypoxic conditions with decreased macrovessel numbers, microvascular endothelial cell numbers, and increased peripheral vessel muscularization. In addition, fetal hypoxia resulted in enlarged distal airspaces and decreased septal wall volume. Moreover, there was a reduction in mature SFTPB and processed SFTPC protein expression concomitant with a decrease in AT2 cell number. These findings demonstrate that maternally-independent fetal hypoxia predominantly impacts distal airway development, AT2 cell number, and surfactant production with mild effects on the vasculature.
胎儿严重缺氧会对肺部发育造成极大风险,导致严重的产后并发症。现有的慢性缺氧动物模型无法在不影响动物发育、胎盘血流或母体健康的情况下使胎儿血氧达到病理性降低。利用宫外新生儿发育环境(Extrauterine Environment for Neonatal Development,EXTEND)建立的隔离慢性缺氧模型,我们能够研究胎儿缺氧对肺部发育的直接影响。我们减少了剖腹产早产羔羊(体重105-110天)的供氧量,并通过EXTEND支持动物完成肺发育的管状或囊状阶段。与正常缺氧条件下的胎羔相比,缺氧条件下的胎羔生长明显受限。我们还观察到,缺氧条件下的囊状组血管重塑出现适度异常,大血管数量减少,微血管内皮细胞数量减少,外周血管肌肉化增加。此外,胎儿缺氧导致远端气腔扩大和室间隔壁体积缩小。此外,随着AT2细胞数量的减少,成熟的SFTPB和经过处理的SFTPC蛋白表达也随之减少。这些研究结果表明,胎儿缺氧主要影响远端气道发育、AT2细胞数量和表面活性物质的产生,对血管的影响轻微。
期刊介绍:
The American Journal of Respiratory Cell and Molecular Biology publishes papers that report significant and original observations in the area of pulmonary biology. The focus of the Journal includes, but is not limited to, cellular, biochemical, molecular, developmental, genetic, and immunologic studies of lung cells and molecules.