Kim: Difference between revisions
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[[Kim:Links | <font face="trebuchet ms" size=3 style="color:#ffffff"> '''LINKS''' </font>]] | [[Kim:Links | <font face="trebuchet ms" size=3 style="color:#ffffff"> '''LINKS''' </font>]] | ||
[[Kim:Contact | <font face="trebuchet ms" size=3 style="color:#ffffff"> '''CONTACT''' </font>]] | [[Kim:Contact | <font face="trebuchet ms" size=3 style="color:#ffffff"> '''CONTACT''' </font>]] | ||
[[Kim:Outreach | <font face="trebuchet ms" size=3 style="color:#ffffff"> '''OUTREACH''' </font>]] | |||
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<h3>Overview</h3> | <h3>Overview</h3> | ||
Our research spans the disciplinary boundaries between biomaterials, nanotechnology, and cell mechanobiology with an emphasis on their applications to tissue engineering and regenerative medicine. Through the use of multiscale fabrication and integration tools, we focus on the development and applications of biomimetic cell culture models and functional tissue engineering constructs for high-throughput drug screening, stem cell-based therapies, disease diagnostics, and medical device development. Using engineered microenvironments in combination with live cell imaging approaches, we are also studying the interplay between mechanical and biochemical signaling in the regulation of cell function and fate decisions that are essential for 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 multiscale regenerative technologies for improving human health. | <font size=3>Our research spans the disciplinary boundaries between biomaterials, nanotechnology, and cell mechanobiology with an emphasis on their applications to tissue engineering and regenerative medicine. Through the use of multiscale (nano/micro/meso) fabrication and integration tools, we focus on the development and applications of biomimetic cell culture models and functional tissue engineering constructs for high-throughput drug screening, stem cell-based therapies, disease diagnostics, and medical device development. Using engineered microenvironments in combination with quantitative live cell imaging approaches, we are also studying the interplay between mechanical and biochemical signaling in the regulation of cell function and fate decisions that are essential for 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 multiscale regenerative technologies for improving human health. </font> | ||
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<h3>News</h3> | <h3>News</h3> | ||
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* | * Cameron Nemeth received The SLUG Symposium Undergraduate Student Award (2012) | ||
* Derek Britain, Sam Frankel, Cameron Nemeth, and Nicole Trosper have been awarded for Mary Gates Undergraduate Research Scholarship (2012) | |||
* | * D. Kim appointed as program committee member of [http://www.ieee-nanomed.org/2012/ '''IEEE International Conference on Nano/Molecular Medicine and Engineering'''] (2012) | ||
* | * D. Kim co-organized the first USACM Thematic Conference on Multiscale Methods and Validation in Medicine and Biology: Biomechanics and Mechanobiology (Jan, 2012) | ||
* D. Kim gave an invited talk at the 5th International Conference on Cell Therapy, Seoul, Korea (Nov. 2011) | |||
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<h3> | <h3>Featured Publications</h3> | ||
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* | * Nanopatterned cardiac cell patches promote stem cell niche formation and myocardial regeneration, Integrative Biology, Vol. 4, Issue 9,pp. 1019-1033, 2012 [http://pubs.rsc.org/en/journals/journalissues/ib#!issueid=ib004009&type=current&issnprint=1757-9694 '''(Featured Cover Article)'''] [http://pubs.rsc.org/en/content/articlelanding/2012/ib/c2ib20067h Article]<br> | ||
* Matrix rigidity controls endothelial differentiation and morphogenesis of cardiac precursors, Science Signaling, vol. 5, issue 227, p. ra41, 2012. [http://stke.sciencemag.org/content/vol5/issue227/cover.dtl '''(Featured as a Cover Article)'''] [http://stke.sciencemag.org/cgi/content/abstract/sigtrans;5/227/ra41 Article] | |||
* Engineering neuronal growth cone to promote axon regeneration over inhibitory molecules, Proceedings of the National Academy of Sciences USA, vol. 108, pp. 5057-5062, 2011. [http://www.pnas.org/content/early/2011/03/03/1011258108.full.pdf+html Article]<BR> | |||
* Biomimetic nanopatterns as enabling tools for analysis and control of live cells, Advanced Materials, 2010. [http://www.ncbi.nlm.nih.gov/pubmed/20803528 Pubmed], [http://www.hubmed.org/display.cgi?uids=20803528 Hubmed] <BR> | |||
* Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs, Proceedings of National Academy of Sciences USA, vol.107, pp. 565-570, 2010. [http://www.ncbi.nlm.nih.gov/pubmed/20018748 Pubmed], [http://www.hubmed.org/display.cgi?uids=20018748 Hubmed] <BR> | |||
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Revision as of 21:24, 18 December 2012
OverviewOur research spans the disciplinary boundaries between biomaterials, nanotechnology, and cell mechanobiology with an emphasis on their applications to tissue engineering and regenerative medicine. Through the use of multiscale (nano/micro/meso) fabrication and integration tools, we focus on the development and applications of biomimetic cell culture models and functional tissue engineering constructs for high-throughput drug screening, stem cell-based therapies, disease diagnostics, and medical device development. Using engineered microenvironments in combination with quantitative live cell imaging approaches, we are also studying the interplay between mechanical and biochemical signaling in the regulation of cell function and fate decisions that are essential for 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 multiscale regenerative technologies for improving human health. |
News
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Featured Publications
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