Three-dimensional functional human myocardial tissues fabricated from induced pluripotent stem cells
Citations Over TimeTop 10% of 2015 papers
Abstract
The most radical treatment currently available for severe heart failure is heart transplantation; however, the number of donor hearts is limited. A better approach is to make human cardiac tissues. We developed an original cell sheet-based tissue-engineering technology to fabricate human cardiac tissue by layering myocardial cell sheets. Human induced pluripotent stem (iPS) cells were differentiated into cardiomyocytes to fabricate cardiomyocyte sheets. Initially, three-layer human iPS cardiomyocyte (hiPSCM) sheets were transplanted on subcutaneous tissues of nude rats. Next, to fabricate thicker tissue, three-layer sheets were transplanted on one day, then additional three-layer sheets were transplanted onto them the following day, after the first sheets were vascularized. On day 3, the final three-layer sheets were again transplanted, creating a nine-layer graft (multi-step transplantation procedure). In the last step, six-layer sheets were transplanted on fat tissues of the inguinal portion, which were subsequently resected together with the femoral arteries and veins to make transplantable grafts with connectable vessels. They were then transplanted ectopically to the neck portion of other rats by anastomosing vessels with the host's jugular arteries and veins. Transplanted three-layer hiPSCMs were beating and, histologically, showed a cardiac muscle-like structure with vascular systems. Moreover, transplanted hiPSCMs proliferated and matured in vivo. Significantly thicker tissues were fabricated by a multi-step transplantation procedure. The ectopically transplanted graft survived and continued to beat. We succeeded in fabricating functional human cardiac tissue with cell sheet technology. Transplanting this cardiac tissue may become a new treatment option for severe heart failure. Copyright © 2015 John Wiley & Sons, Ltd.
Related Papers
- → Combining Chondrocytes and Smooth Muscle Cells to Engineer Hybrid Soft Tissue Constructs(2000)87 cited
- → Human heart disease: lessons from human pluripotent stem cell-derived cardiomyocytes(2017)61 cited
- → Investigation of a small-diameter decellularised artery as a potential scaffold for vascular tissue engineering; biomechanical evaluation and preliminary cell seeding(2012)42 cited
- → Preparation of small intestinal submucosa as a scaffold for cardiac tissue engineering(2011)3 cited
- → A Nondestructive Fiber-Based Imaging System to Assess Tissue-Engineered Vascular Grafts(2012)