Biomimetic Scaffolds for Tissue Repair and Regeneration

Xia, Younan

Title:

Biomimetic Scaffolds for Tissue Repair and Regeneration

dc.contributor.author	Xia, Younan	en_US
dc.contributor.corporatename	Georgia Institute of Technology. Institute for Electronics and Nanotechnology	en_US
dc.contributor.corporatename	Georgia Institute of Technology. School of Biomedical Engineering	en_US
dc.contributor.corporatename	Emory University	en_US
dc.date.accessioned	2022-10-25T04:14:20Z
dc.date.available	2022-10-25T04:14:20Z
dc.date.issued	2022-09-27
dc.description	Presented on September 27, 2022 from 12:00 p.m.-1:00 p.m. in the Marcus Nanotechnology Building, Rooms 1116-1118, Georgia Tech, Atlanta, GA.	en_US
dc.description	Younan Xia is the Brock Family Chair and Georgia Research Alliance Eminent Scholar in Nanomedicine at the Georgia Institute of Technology. He received a B.S. degree in chemical physics from the University of Science and Technology of China, a M.S. degree in inorganic chemistry from University of Pennsylvania, and a Ph.D. degree in physical chemistry from Harvard University. He started as an Assistant Professor of Chemistry at the University of Washington in 1997 and was promoted to Associate Professor and Full Professor in 2002 and 2004, respectively. He joined the Department of Biomedical Engineering at Washington University in St. Louis in 2007 as the James M. McKelvey Professor and then moved to Georgia Tech in 2012, holding joint appointments in the Wallace H. Coulter Department of Biomedical Engineering and School of Chemistry and Biochemistry. His group has invented a myriad of nanomaterials with controlled properties for widespread use in applications related to plasmonics, electronics, photonics, photovoltaics, display, catalysis, energy conversion, nanomedicine, and regenerative medicine. Xia has co-authored more than 830 publications in peer-reviewed journals, with a total citations of over 176,000 and an h-index of 208. He has been named a Top 10 Chemist and Materials Scientist based on the number of citations per publication. He has received a number of prestigious awards, including Materials Research Society Medal (2017), American Chemical Society National Award in the Chemistry of Materials (2013), NIH Director's Pioneer Award (2006), David and Lucile Packard Fellow in Science and Engineering (2000), and NSF CAREER Award (2000).	en_US
dc.description	Runtime: 55:29 minutes	en_US
dc.description.abstract	We are seeking to augment rotator cuff repair and peripheral nerve regeneration by developing biomimetic scaffolds capable of recapitulating the compositional, structural, mechanical, and cellular features of the native tissues. Rotator cuff tears are prevalent in the elderly population. Unfortunately, successful repair remains a major clinical challenge, with high post-operative failure rates. At the root of these failures is the poor healing at the repaired tendon-to-bone insertion, and the lack of regeneration of the native attachment structure. We are developing biomimetic scaffolds to augment the surgical repair and healing of the tendon-to-bone attachment. The research is built around the premise that scaffolds can be designed with hierarchical, functionally-graded structures to match the native enthesis for the regeneration of a robust interface between the reattached tendon and bone. When combined with mesenchymal stem cells, the translational potential of the scaffolds in enhancing the formation of a mechanically functional tendon-to-bone insertion are tested in a clinically relevant rotator cuff injury-and-repair model. Peripheral nerve injury is a large-scale problem that annually affects more than one million people in the US. We are developing nerve guidance conduits based on electrospun fibers for the surgical repair of large defects in thick nerves. The conduit facilitates nerve regeneration across a gap by providing a protective environment, limiting the possible directions of axonal sprouting, concentrating neurotrophic factors, and offering physical guidance to neurite extension. Specifically, we are working with conduits featuring a multi-tubular design to recapitulate the fascicles typical of a peripheral nerve while providing good mechanical strength to resist kinking and distortion during surgery. We augment nerve regeneration by leveraging the physical cue arising from the uniaxial alignment of electrospun fibers and nanoscale grooves engraved in the surface of the fibers, in addition to the biological cues provided by Schwann cells and/or encapsulated neurotrophic factors. A combination of in vitro and in vivo models are used to optimize the design and parameters of the conduits for peripheral nerve repair and functional recovery.	en_US
dc.format.extent	55:29 minutes
dc.identifier.uri	http://hdl.handle.net/1853/67535
dc.language.iso	en_US	en_US
dc.publisher	Georgia Institute of Technology	en_US
dc.relation.ispartofseries	Nano@Tech Lecture Series
dc.subject	Biomaterials	en_US
dc.subject	Regenerative medicine	en_US
dc.subject	Tissue engineering	en_US
dc.title	Biomimetic Scaffolds for Tissue Repair and Regeneration	en_US
dc.type	Moving Image
dc.type.genre	Lecture
dspace.entity.type	Publication
local.contributor.author	Xia, Younan
local.contributor.corporatename	Institute for Electronics and Nanotechnology (IEN)
local.relation.ispartofseries	Nano@Tech Lecture Series
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