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Topic 1: Cardiac ECM Biomechanics in Heart Regeneration
Myocardial infarction (MI) affects more than 8 million Americans, causing massive heart cell death and heart function decrease. As a promising strategy, stem cell therapy delivers cells to damaged areas (scar tissues) to revitalize infracted heart. Unfortunately, the success rate for stem cells differentiating into cardiac muscle cells is extremely low, limiting the great potential of stem cell for cardiac repair and regeneration. In this project, we are investigating the underlying mechanisms that hinder the regenerative potential of stem cell in scar tissue of the damaged hearts. (Collaborators: Dr. Jianjun Guan/Ohio State University, Dr. Ryan Butler, Dr. Andrew Claude/MSU)
Topic 2: Cardiac Tissue Engineering via Acellular Myocardial Scaffolds
In this project, we assess whether the decellularized myocardial scaffold, along with coordinated multifaceted stimulations, promotes the differentiation of stem cells towards cardiomyocyte phenotype. The knowledge gained from the proposed research will help us better understand fundamental bioengineering in the development of a thick cardiac patch and benefit future exploration of whole-
Topic 3: 3D Heart Muscle Fiber Disruption Reconstructed via Diffusion Tensor-
Our study is the first attempt to characterize the disruption of the 3D myocardial fiber structure in an area of myocardial infarction and correlate this disruption with the structural and biomechanical changes of the infarcted myocardium. We have successfully created myocardial infarction in a pig model with a balloon catheterization technique, and developed a diffusion tensor magnetic resonance imaging (DT-
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Topic 1: The Fundamentals of Heart Valve Tissue Biomechanics
We are currently investigating the ultrastructural mechanism, which minimizes creep and allows valve leaflets behaving as quasi-
Topic 2: Tissue Engineered Heart Valves
The long-
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In this research direction, we are developing a high fidelity human body mesh with anatomic details of important organs/tissues using 3D reconstruction software and physically based constitutive models that capture the formation of tissue defects and their dependence on strain level and strain rate. The human body mesh has been integrated into finite element (FE) models that are subsequently subjected to blast and crash impact events. The knowledge based on the integrated simulations will be applied to facilitate the development of safety countermeasures for combat vehicular systems and solider protective equipment. (Collaborators: Dr. Lakiesha Williams, Dr. Raj Prabhu, Dr. Mark F. Horstemeyer/MSU)
Other Directions – Tissue Biomechanics and Regeneration
Our other contributions include: (1) Demonstrating the important biomechanical role of small proteoglycans as the collagen interfibrillar bridges in tendinous tissues; (2) revealing the collagen molecular behavior in collagenous tissues under biaxial stretch; (3) demonstrating that collagen fibrils in patellar tendon undergo significantly greater recruitment at higher strain rates; (4) carrying out cross-