Mechanical Stretch Regimen Enhances the Formation of Bioengineered Autologous Cardiac Muscle Grafts

P. Akhyari, P. Fedak, R. Weisel, T. J. Lee, S. Verma, Donald A. G. Mickle, Ren-Ke Li
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引用次数: 250

Abstract

BackgroundSurgical repair of congenital and acquired cardiac defects may be enhanced by the use of autologous bioengineered muscle grafts. These tissue-engineered constructs are not optimal in their formation and function. We hypothesized that a mechanical stretch regimen applied to human heart cells that were seeded on a three-dimensional gelatin scaffold (Gelfoam) would improve tissue formation and enhance graft strength. Methods and ResultsHeart cells from children undergoing repair of Tetralogy of Fallot were isolated and cultured. Heart cells were seeded on gelatin-matrix scaffolds (Gelfoam) and subjected to cyclical mechanical stress (n=7) using the Bio-Stretch Apparatus (80 cycles/minute for 14 days). Control scaffolds (n=7) were maintained under identical conditions but without cyclical stretch. Cell counting, histology, and computerized image analysis determined cell proliferation and their spatial distribution within the tissue-engineered grafts. Collagen matrix formation and organization was determined with polarized light and laser confocal microscopy. Uniaxial tensile testing assessed tissue-engineered graft function. Human heart cells proliferated within the gelatin scaffold. Remarkably, grafts that were subjected to cyclical stretch demonstrated increased cell proliferation and a marked improvement of cell distribution. Collagen matrix formation and organization was enhanced by mechanical stretch. Both maximal tensile strength and resistance to stretch were improved by cyclical mechanical stretch. ConclusionThe cyclical mechanical stretch regimen enhanced the formation of a three-dimensional tissue-engineered cardiac graft by improving the proliferation and distribution of seeded human heart cells and by stimulating organized matrix formation resulting in an order of magnitude increase in the mechanical strength of the graft.
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机械拉伸方案促进生物工程自体心肌移植物的形成
背景:自体生物工程肌肉移植可以提高先天性和后天性心脏缺损的外科修复效果。这些组织工程结构在其形成和功能上不是最佳的。我们假设,将人类心脏细胞植入三维明胶支架(明胶泡沫)上的机械拉伸方案可以改善组织形成并增强移植物强度。方法与结果分离培养法洛四联症患儿心脏细胞。将心脏细胞植入明胶基质支架(Gelfoam)上,使用Bio-Stretch Apparatus(80循环/分钟,持续14天)进行循环机械应力(n=7)。对照支架(n=7)在相同条件下维持,但不进行周期性拉伸。细胞计数、组织学和计算机图像分析决定了细胞增殖及其在组织工程移植物中的空间分布。用偏振光和激光共聚焦显微镜观察胶原基质的形成和组织。单轴拉伸试验评估组织工程移植物的功能。人类心脏细胞在明胶支架内增殖。值得注意的是,周期性拉伸的移植物细胞增殖增加,细胞分布明显改善。机械拉伸增强了胶原基质的形成和组织。循环机械拉伸提高了材料的最大拉伸强度和抗拉伸性能。结论循环机械拉伸方案通过促进人心脏种子细胞的增殖和分布,促进有组织基质的形成,使移植物的机械强度提高一个数量级,从而促进了三维组织工程心脏移植物的形成。
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