Department of Bioengineering, Rice University, Houston, TX 77251-1892, USA.
Cardiovasc Pathol. 2011 Sep-Oct;20(5):e157-67. doi: 10.1016/j.carpath.2010.07.004. Epub 2010 Sep 2.
Congenital cardiac valve disease is common, affecting ∼1% of the population, with substantial morbidity and mortality, but suboptimal treatment options. Characterization of the specific matrix and valve cell phenotypic abnormalities in these valves could lend insight into disease pathogenesis and potentially pave the way for novel therapies.
Thirty-five human aortic and pulmonic valves were categorized based on gross and microscopic assessment into control valves (n=21); dysplastic valves, all except one also displaying hemodynamic changes (HEMO/DYSP, n=6); and hemodynamically altered valves (HEMO, n=8). Immunohistochemistry was performed on valve sections and flow cytometry on valvular interstitial cells.
While both hemodynamically altered aortic and pulmonic valves demonstrated increased collagen turnover and cell activation, prolyl 4-hydroxylase and hyaluronan increased in hemodynamically altered aortic valves but decreased in hemodynamically altered pulmonic valves relative to control valves (P<.001). HEMO/DYSP aortic valves demonstrated decreased collagen and elastic fiber synthesis and turnover compared to both hemodynamically altered aortic valves and control aortic valves (each P<.006). Valvular interstitial cells from both hemodynamically altered and HEMO/DYSP pulmonic valves showed altered cell phenotype compared to control valves (each P<.032), especially increased non-muscle myosin. Furthermore, valvular interstitial cells from hemodynamically altered pulmonic valves and HEMO/DYSP aortic and pulmonic valves each demonstrated greater size and complexity compared to control valves (each P<.05).
Dysplastic semilunar valves displayed alterations in collagen and elastic fiber turnover that were distinct from valves similarly exposed to altered hemodynamics as well as to control valves. These results demonstrate that dysplastic valves are not simply valves with gross changes or loss of leaflet layers, but contain complex matrix and cell phenotype changes that, with future study, could potentially be targets for novel nonsurgical treatments.
先天性心脏瓣膜疾病很常见,影响了约 1%的人群,发病率和死亡率都很高,但治疗选择并不理想。对这些瓣膜中特定基质和瓣膜细胞表型异常的特征进行描述,可能有助于深入了解疾病的发病机制,并为新的治疗方法铺平道路。
根据大体和显微镜评估,将 35 个人主动脉瓣和肺动脉瓣分为对照组(n=21);发育不良瓣膜(除了一个之外,其余均有血流动力学改变)(HEMO/DYSP,n=6);血流动力学改变的瓣膜(HEMO,n=8)。对瓣膜切片进行免疫组织化学染色,对瓣膜间质细胞进行流式细胞术分析。
虽然血流动力学改变的主动脉瓣和肺动脉瓣都表现出胶原代谢和细胞激活增加,但脯氨酰 4-羟化酶和透明质酸在血流动力学改变的主动脉瓣中增加,而在血流动力学改变的肺动脉瓣中减少,与对照组相比(P<.001)。HEMO/DYSP 主动脉瓣与血流动力学改变的主动脉瓣和对照组主动脉瓣相比,胶原和弹性纤维合成及代谢均减少(P<.006)。与对照组瓣膜相比,血流动力学改变和 HEMO/DYSP 肺动脉瓣的瓣膜间质细胞均表现出表型改变(P<.032),尤其是非肌球蛋白增加。此外,与对照组瓣膜相比,血流动力学改变的肺动脉瓣和 HEMO/DYSP 主动脉瓣和肺动脉瓣的瓣膜间质细胞的大小和复杂性均增加(P<.05)。
发育不良的半月瓣表现出胶原和弹性纤维代谢改变,与同样受到血流动力学改变影响的瓣膜以及对照组瓣膜不同。这些结果表明,发育不良的瓣膜不仅仅是有明显结构改变或瓣叶缺失的瓣膜,还包含复杂的基质和细胞表型改变,进一步研究,这些改变可能成为新的非手术治疗的靶点。
