000			04157cam a2200469Ki 4500
001			9780367814809
003			FlBoTFG
005			20220509192913.0
006			m o d
007			cr |n|||||||||
008			200129s2020 flu o 000 0 eng d
040			_aOCoLC-P _beng _cOCoLC-P
020			_a9781000725803 _q(electronic bk.)
020			_a1000725804 _q(electronic bk.)
020			_a9780367814809 _q(electronic bk.)
020			_a0367814803 _q(electronic bk.)
020			_a9781000725667 _q(electronic bk. : PDF)
020			_a1000725669 _q(electronic bk. : PDF)
020			_z1138039136
020			_z9781138039131
035			_a(OCoLC)1137745442
035			_a(OCoLC-P)1137745442
050		4	_aQP517.B56
072		7	_aMED _x009000 _2bisacsh
072		7	_aTEC _x021000 _2bisacsh
072		7	_aSCI _x010000 _2bisacsh
072		7	_aMQW _2bicssc
082	0	4	_a610.28 _223
245	0	0	_aBiomimetic microengineering _h[electronic resource] / _cedited by Hyun Jung Kim.
260			_aBoca Raton, FL : _bCRC PRESS, _c2020.
300			_a1 online resource.
520			_aThis book will examine the relevant biological subjects involved in biomimetic microengineering as well as the design and implementation methods of such engineered microdevices. Physiological topics covered include regeneration of complex responses of our body on a cellular, tissue, organ, and inter-organ level. Technological concepts in cell and tissue engineering, stem cell biology, microbiology, biomechanics, materials science, micro- and nanotechnology, and synthetic biology are highlighted to increase understanding of the transdisciplinary methods used to create the more complex, robust biomimetic engineered models. The effectiveness of the new bioinspired microphysiological systems as replacements for existing in vitro or in vivo models is explained through sections that include the protocols to reconstitute three-dimensional (3D) structures, recapitulate physiological functions, and emulate the pathophysiology of human diseases. This book will also discuss how researchers can discover bridge technologies for disease modeling and personalized precision medicine. Features Focuses on cutting edge technologies that enable manipulation of living systems in a spatiotemporal manner. Incorporates research on reverse engineering of comples microenvironmental factors in human diseases. Highlights technologies related to patient-specific personalized medicine and their potential uses. Written by chapter authors who are highly respected researchers in science and engineering. Includes extensive references at the end of each chapter to enhance further study. Hyun Jung Kim is an Assistant Professor in the Department of Biomedical Engineering at The University of Texas at Austin. After receiving hois Ph.D. degree at Yonsei University in the Republic of Korea, he did extensive postdctoral research at both the University of Chicago and the Wyss Institute at Harvard University. These efforts resulted in cutting-edge breakthroughs in synthetic microbial community research and organomimetic human Gut-on-a-Chip microsystem. His research on Gut-on-a-Chip technology leads to the creation of a microfluidic device that mimics the physiology and pathology of the living human intestine. Since 2015, he has explored novel human host-microbiome ecosystems to discover the disease mechanism and new therapeutics in inflammatory bowel disease and colorectal cancers at UT Austin. In collaboration with clinicians, his lab is currently developing disease-oriented, patient-specific models for the advancement in pharmaceutical and clinical fields.
588			_aOCLC-licensed vendor bibliographic record.
650		0	_aBiomimetics.
650		0	_aMicrobiology.
650		0	_aTissue engineering.
650		7	_aMEDICAL / Biotechnology _2bisacsh
650		7	_aTECHNOLOGY / Material Science _2bisacsh
650		7	_aSCIENCE / Biotechnology _2bisacsh
700	1		_aKim, Hyun Jung.
856	4	0	_3Taylor & Francis _uhttps://www.taylorfrancis.com/books/9780367814809
856	4	2	_3OCLC metadata license agreement _uhttp://www.oclc.org/content/dam/oclc/forms/terms/vbrl-201703.pdf
999			_c126184 _d126184