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<h3>Overview</h3> | <h3>Overview</h3> | ||
<font size=3>Our research spans the disciplinary boundaries between nanotechnology, biomaterials, and | <font size=3> | ||
Our research spans the disciplinary boundaries between nanotechnology, biomaterials, and mechanobiology with an emphasis on their applications to tissue engineering and regenerative medicine. Through the use of multi-scale (nano/micro/meso) fabrication and integration tools, we focus on the development and application of bio-inspired materials/devices/systems and functional tissue engineering models for elucidating cell biology, drug screening, disease modeling, and stem cell-based therapies. Using engineered microenvironments in combination with quantitative live cell imaging approaches, we are also studying the intricate interactions between mechanical and biochemical signaling in the regulation of cell/tissue function and fate decisions that are essential for tumor progression and metastasis, tissue repair and regeneration following injury, and various developmental events. The ultimate goal of our research is to better understand complex cellular behavior in response to microenvironmental cues in normal, aging and disease states, to gain new mechanistic insights into the control of cell-tissue structure and function, and to develop multi-scale regenerative technologies for improving human health. | |||
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Revision as of 20:37, 11 December 2014
OverviewOur research spans the disciplinary boundaries between nanotechnology, biomaterials, and mechanobiology with an emphasis on their applications to tissue engineering and regenerative medicine. Through the use of multi-scale (nano/micro/meso) fabrication and integration tools, we focus on the development and application of bio-inspired materials/devices/systems and functional tissue engineering models for elucidating cell biology, drug screening, disease modeling, and stem cell-based therapies. Using engineered microenvironments in combination with quantitative live cell imaging approaches, we are also studying the intricate interactions between mechanical and biochemical signaling in the regulation of cell/tissue function and fate decisions that are essential for tumor progression and metastasis, tissue repair and regeneration following injury, and various developmental events. The ultimate goal of our research is to better understand complex cellular behavior in response to microenvironmental cues in normal, aging and disease states, to gain new mechanistic insights into the control of cell-tissue structure and function, and to develop multi-scale regenerative technologies for improving human health. |
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