Stainsby Andrew V, DeKoninck Philip L J, Crossley Kelly J, Thiel Alison, Wallace Megan J, Pearson James T, Kashyap Aidan J, Croughan Michelle K, Allison Beth A, Hodges Ryan, Thio Marta, Flemmer Andreas W, McGillick Erin V, Te Pas Arjan B, Hooper Stuart B, Kitchen Marcus J
Ritchie Centre, Hudson Institute of Medical Research, Melbourne, Australia.
Department of Obstetrics and Gynaecology, Monash University, Melbourne, Australia.
Anat Rec (Hoboken). 2025 Apr;308(4):1082-1093. doi: 10.1002/ar.25159. Epub 2023 Jan 23.
Congenital diaphragmatic hernia (CDH) is a major cause of severe lung hypoplasia and pulmonary hypertension in the newborn. While the pulmonary hypertension is thought to result from abnormal vascular development and arterial vasoreactivity, the anatomical changes in vascular development are unclear. We have examined the 3D structure of the pulmonary arterial tree in rabbits with a surgically induced diaphragmatic hernia (DH). Fetal rabbits (n = 6) had a left-sided DH created at gestational day 23 (GD23), delivered at GD30, and briefly ventilated; sham-operated litter mates (n = 5) acted as controls. At postmortem the pulmonary arteries were filled with a radio-opaque resin before the lungs were scanned using computed tomography (CT). The 3D reconstructed images were analyzed based on vascular branching hierarchy using the software Avizo 2020.2. DH significantly reduced median number of arteries (2,579 (8440) versus 576 (442), p = .017), artery numbers per arterial generation, mean total arterial volume (43.5 ± 8.4 vs. 19.9 ± 3.1 μl, p = .020) and mean total arterial cross-sectional area (82.5 ± 2.3 vs. 28.2 ± 6.2 mm, p =.036). Mean arterial radius was increased in DH kittens between the eighth and sixth branching generation and mean arterial length between the sixth and 28th branching generation. A DH in kittens resulted in threefold reduction in pulmonary arterial cross-sectional area, primarily due to reduced arterial branching. Thus, the reduction in arterial cross-sectional area could be a major contributor to pulmonary hypertension infants with CDH.
先天性膈疝(CDH)是新生儿严重肺发育不全和肺动脉高压的主要原因。虽然肺动脉高压被认为是由异常的血管发育和动脉血管反应性引起的,但血管发育中的解剖学变化尚不清楚。我们研究了手术诱导膈疝(DH)兔的肺动脉树的三维结构。将胎兔(n = 6)在妊娠第23天(GD23)造成左侧DH,在GD30分娩并进行短暂通气;假手术的同窝仔兔(n = 5)作为对照。死后,在使用计算机断层扫描(CT)扫描肺部之前,用不透射线的树脂填充肺动脉。使用Avizo 2020.2软件根据血管分支层次对三维重建图像进行分析。DH显著减少了动脉的中位数(2579(8440)对576(442),p = 0.017)、每代动脉的数量、平均总动脉体积(43.5±8.4对19.9±3.1μl,p = 0.020)和平均总动脉横截面积(82.5±2.3对28.2±6.2mm,p = 0.036)。DH幼崽在第八代至第六代分支之间平均动脉半径增加,在第六代至第28代分支之间平均动脉长度增加。幼崽中的DH导致肺动脉横截面积减少了三倍,主要是由于动脉分支减少。因此,动脉横截面积的减少可能是CDH婴儿肺动脉高压的主要原因。
