Abstract
Cardiac tissue engineering using biomaterials with or without combination of stem cell therapy offers a new option for repairing infarcted heart. However, the bioactivity of biomaterials remains to be optimized because currently available biomaterials do not mimic the biochemical components as well as the structural properties of native myocardial extracellular matrix. Here we hypothesized that human heart valve-derived scaffold (hHVS), as a clinically relevant novel biomaterial, may provide the proper microenvironment of native myocardial extracellular matrix for cardiac repair. In this study, human heart valve tissue was sliced into 100 μm tissue sheet by frozen-sectioning and then decellularized to form the hHVS. Upon anchoring onto the hHVS, post-infarct murine BM c-kit+ cells exhibited an increased capacity for proliferation and cardiomyogenic differentiation in vitro. When used to patch infarcted heart in a murine model of myocardial infarction, either implantation of the hHVS alone or c-kit+ cell-seeded hHVS significantly improved cardiac function and reduced infarct size; while c-kit+ cell-seeded hHVS was even superior to the hHVS alone. Thus, we have successfully developed a hHVS for cardiac repair. Our in vitro and in vivo observations provide the first clinically relevant evidence for translating the hHVS-based biomaterials into clinical strategies to treat myocardial infarction.
Highlights
Cardiac tissue engineering using biomaterials with or without combination of stem cell therapy offers a new option for repairing infarcted heart
We show that the human heart valve-derived scaffold (hHVS) was able to promote proliferation and cardiomyogenic differentiation of bone marrow (BM) c-kit+cells in vitro
We have developed a human heart valve-derived scaffold for cardiac repair
Summary
Cardiac tissue engineering using biomaterials with or without combination of stem cell therapy offers a new option for repairing infarcted heart. We hypothesized that human heart valve-derived scaffold (hHVS), as a clinically relevant novel biomaterial, may provide the proper microenvironment of native myocardial extracellular matrix for cardiac repair. Cardiac tissue scaffold is designed mainly based on natural and synthetic biomaterials[12,13,14,15,16,17,18,19], which do not mimic the biochemical components and structural properties of native myocardial extracellular matrix. Recent experimental studies reveal that the native extracellular matrix (as a 3D structural scaffold) contains optimal biochemical constituents, facilitating the integration of implanted cells into the host organ/tissue. We reasoned that the human native myocardial tissue-derived matrix might provide a clinically relevant novel scaffold as well as support BM stem cell transplantation for cardiac repair. This study presents a novel native myocardial tissue-derived scaffold which is featured with superior cardiac repair function and potential therapeutic benefits
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