钙化
心包
医学
心脏瓣膜
戊二醛
心脏病学
病理
内科学
作者
Fei Kong,Jingjing Zhang,Yang Yang,Yunyang Zhang,Jian Ge,Jingwu Song,Changyu Shao,Haoran Li,Yujie Ren,Xianghui Kong,Xianghui Kong,Chengyao Ni,Xiangdong Kong,Xiangdong Kong,Ruibo Zhao
标识
DOI:10.1002/adhm.202500856
摘要
Calcific aortic valve disease is an inexorably degenerative pathology and a common cause of morbidity and mortality in heart disease. Clinically, it has no effective medical therapy but can be managed with artificial heart valve replacement, particularly using bioprosthetic heart valves (BHV), entailing high biocompatibility. Current BHV mainly derives from glutaraldehyde (GA) cross-linked pericardium, however, residual aldehyde groups may inevitably remain during cross-link, potentially binding with calcium and inducing in situ calcification after implantation, thus leading to valve re-failure and posing a significant clinical challenge. Inspired by the high reducibility and clinical potential of sodium thiosulfate (STS), herein, STS as a novel modification post GA cross-linking to eliminate residual aldehyde in pericardium is presented. Notably, in vitro and in vivo studies demonstrated high ability against calcification in STS-modified porcine pericardium (SPP) with over 75% decrease of calcific density compared to GA alone cross-linked pericardium (GPP). More importantly, SPP can reduce macrophages and T cell inflation, as well as their associated proinflammation cytokines, building an immune-privileged microenvironment with a suppressed inflammation response. More generally, given the great potential of STS in treating vascular calcification clinically, these achievements further offer a new generation of BHV materials with boosted anti-calcification.
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