肺动静脉共干和左肺动脉中断；发育过程中神经嵴和第二心脏场的病理学和作用。

Pulmonary ductal coarctation and left pulmonary artery interruption; pathology and role of neural crest and second heart field during development.

机构信息

Department of Cardiology, Leiden University Medical Center, Leiden, The Netherlands.

Department of Anatomy & Embryology, Leiden University Medical Center, Leiden, The Netherlands.

出版信息

PLoS One. 2020 May 15;15(5):e0228478. doi: 10.1371/journal.pone.0228478. eCollection 2020.

DOI:10.1371/journal.pone.0228478

PMID:32413023

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7228067/

Abstract

OBJECTIVES

In congenital heart malformations with pulmonary stenosis to atresia an abnormal lateral ductus arteriosus to left pulmonary artery connection can lead to a localised narrowing (pulmonary ductal coarctation) or even interruption We investigated embryonic remodelling and pathogenesis of this area.

MATERIAL AND METHODS

Normal development was studied in WntCre reporter mice (E10.0-12.5) for neural crest cells and Nkx2.5 immunostaining for second heart field cells. Data were compared to stage matched human embryos and a VEGF120/120 mutant mouse strain developing pulmonary atresia.

RESULTS

Normal mouse and human embryos showed that the mid-pharyngeal endothelial plexus, connected side-ways to the 6th pharyngeal arch artery. The ventral segment formed the proximal pulmonary artery. The dorsal segment (future DA) was solely surrounded by neural crest cells. The ventral segment had a dual outer lining with neural crest and second heart field cells, while the distal pulmonary artery was covered by none of these cells. The asymmetric contribution of second heart field to the future pulmonary trunk on the left side of the aortic sac (so-called pulmonary push) was evident. The ventral segment became incorporated into the pulmonary trunk leading to a separate connection of the left and right pulmonary arteries. The VEGF120/120 embryos showed a stunted pulmonary push and a variety of vascular anomalies.

SUMMARY

Side-way connection of the DA to the left pulmonary artery is a congenital anomaly. The primary problem is a stunted development of the pulmonary push leading to pulmonary stenosis/atresia and a subsequent lack of proper incorporation of the ventral segment into the aortic sac. Clinically, the aberrant smooth muscle tissue of the ductus arteriosus should be addressed to prohibit development of severe pulmonary ductal coarctation or even interruption of the left pulmonary artery.

摘要

目的

在肺动脉瓣闭锁合并肺动脉瓣狭窄的先天性心脏病中，异常的动脉导管左肺动脉连接可导致局部狭窄（肺动脉导管狭窄），甚至中断。我们研究了该区域的胚胎重塑和发病机制。

材料和方法

我们使用 WntCre 报告基因小鼠（E10.0-12.5）研究神经嵴细胞的正常发育，并进行第二心脏场细胞的 Nkx2.5 免疫染色。将数据与发育肺动脉闭锁的阶段匹配的人类胚胎和 VEGF120/120 突变小鼠进行比较。

结果

正常的小鼠和人类胚胎显示，咽中动脉丛连接到第六咽弓动脉的侧面。腹侧节段形成近端肺动脉。背侧节段（未来的 DA）仅被神经嵴细胞包围。腹侧段有双重的外衬，由神经嵴细胞和第二心脏场细胞组成，而远端肺动脉则没有这些细胞。第二心脏场在主动脉囊左侧未来肺动脉干的不对称贡献（所谓的肺动脉推动）是明显的。腹侧段被纳入肺动脉干，导致左右肺动脉的独立连接。VEGF120/120 胚胎显示肺动脉推动发育迟缓，并有多种血管异常。

总结

DA 与左肺动脉的侧方连接是一种先天性异常。主要问题是肺动脉推动发育迟缓，导致肺动脉狭窄/闭锁，随后腹侧段不能正常纳入主动脉囊。临床上，应处理异常的动脉导管平滑肌组织，以防止严重的肺动脉导管狭窄甚至左肺动脉中断的发展。

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肺动静脉共干和左肺动脉中断；发育过程中神经嵴和第二心脏场的病理学和作用。

Pulmonary ductal coarctation and left pulmonary artery interruption; pathology and role of neural crest and second heart field during development.

机构信息

出版信息

OBJECTIVES

MATERIAL AND METHODS

RESULTS

SUMMARY

目的

材料和方法

结果

总结

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