Biomimetic Microengineering
Herausgeber: Kim, Hyun Jung
Biomimetic Microengineering
Herausgeber: Kim, Hyun Jung
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This book will examine the methods to reconstitute three-dimensional (3D) structure, recapitulate the human physiology as well as pathology during health and disease. A focus is on the regeneration of complex responses of our body in cells, tissues, organs, and inter-organ level interactions.
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This book will examine the methods to reconstitute three-dimensional (3D) structure, recapitulate the human physiology as well as pathology during health and disease. A focus is on the regeneration of complex responses of our body in cells, tissues, organs, and inter-organ level interactions.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 396
- Erscheinungstermin: 25. Juni 2024
- Englisch
- Abmessung: 234mm x 156mm
- Gewicht: 730g
- ISBN-13: 9781032652528
- ISBN-10: 1032652527
- Artikelnr.: 70116285
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 396
- Erscheinungstermin: 25. Juni 2024
- Englisch
- Abmessung: 234mm x 156mm
- Gewicht: 730g
- ISBN-13: 9781032652528
- ISBN-10: 1032652527
- Artikelnr.: 70116285
Hyun Jung Kim is an Assistant Professor in the Department of Biomedical Engineering at The University of Texas at Austin. After receiving his Ph.D. at Yonsei University in the Republic of Korea, he did extensive postdoctoral research at both the University of Chicago and the Wyss Institute at Harvard University (under Professor Donald Ingber). These efforts resulted in cutting edge breakthroughs in synthetic microbial community research and organomimetic human Gut-on-a-Chip microphysiological system. His research on Gut-on-a-Chip technology leads to the creation of a microfluidic device that 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 cancer. In collaboration with clinicians, his lab is currently developing disease-oriented, patient-specific models for the advancement of Precision Medicine.
PART I Emulating the Microenvironment of a Living System. Emulating
Biomechanical Environments in Microengineered Systems. Biomimetic
Microsystems for Blood and Lymphatic Vascular Research. Multispecies
Microbial Communities and Synthetic Microbial Ecosystems. PART II Enabling
Technologies for Building a Biomimetic Model. Stem Cell Engineering.
Organoid Technology for Basic Science and Biomedical Research. Design,
Fabrication, and Microflow Control Techniques for Organ-on-a-Chip Devices.
Microfluidic Techniques for High-Throughput Cell Analysis. 3D Printing and
Bioprinting Technologies. PART III Pathomimetic Disease Modeling.
Microengineered Models of Human Gastrointestinal Diseases. Respiratory
Pathophysiology - Microphysiological Models of Human Lung. In Vitro
Alzheimer's Disease Modeling Using Stem Cells. PART IV Towards
Translational Application and Precision Medicine. Manufacturing and
Assembly of Micro- and Nano-scale Devices and Interfaces Using Silk
Proteins. Microarray 3D Bioprinting for Creating Miniature Human Tissue
Replicas for Predictive Compound Screening. Integration of the Immune
System into Complex In Vitro Models for Preclinical Drug Development.
Biomechanical Environments in Microengineered Systems. Biomimetic
Microsystems for Blood and Lymphatic Vascular Research. Multispecies
Microbial Communities and Synthetic Microbial Ecosystems. PART II Enabling
Technologies for Building a Biomimetic Model. Stem Cell Engineering.
Organoid Technology for Basic Science and Biomedical Research. Design,
Fabrication, and Microflow Control Techniques for Organ-on-a-Chip Devices.
Microfluidic Techniques for High-Throughput Cell Analysis. 3D Printing and
Bioprinting Technologies. PART III Pathomimetic Disease Modeling.
Microengineered Models of Human Gastrointestinal Diseases. Respiratory
Pathophysiology - Microphysiological Models of Human Lung. In Vitro
Alzheimer's Disease Modeling Using Stem Cells. PART IV Towards
Translational Application and Precision Medicine. Manufacturing and
Assembly of Micro- and Nano-scale Devices and Interfaces Using Silk
Proteins. Microarray 3D Bioprinting for Creating Miniature Human Tissue
Replicas for Predictive Compound Screening. Integration of the Immune
System into Complex In Vitro Models for Preclinical Drug Development.
PART I Emulating the Microenvironment of a Living System. Emulating
Biomechanical Environments in Microengineered Systems. Biomimetic
Microsystems for Blood and Lymphatic Vascular Research. Multispecies
Microbial Communities and Synthetic Microbial Ecosystems. PART II Enabling
Technologies for Building a Biomimetic Model. Stem Cell Engineering.
Organoid Technology for Basic Science and Biomedical Research. Design,
Fabrication, and Microflow Control Techniques for Organ-on-a-Chip Devices.
Microfluidic Techniques for High-Throughput Cell Analysis. 3D Printing and
Bioprinting Technologies. PART III Pathomimetic Disease Modeling.
Microengineered Models of Human Gastrointestinal Diseases. Respiratory
Pathophysiology - Microphysiological Models of Human Lung. In Vitro
Alzheimer's Disease Modeling Using Stem Cells. PART IV Towards
Translational Application and Precision Medicine. Manufacturing and
Assembly of Micro- and Nano-scale Devices and Interfaces Using Silk
Proteins. Microarray 3D Bioprinting for Creating Miniature Human Tissue
Replicas for Predictive Compound Screening. Integration of the Immune
System into Complex In Vitro Models for Preclinical Drug Development.
Biomechanical Environments in Microengineered Systems. Biomimetic
Microsystems for Blood and Lymphatic Vascular Research. Multispecies
Microbial Communities and Synthetic Microbial Ecosystems. PART II Enabling
Technologies for Building a Biomimetic Model. Stem Cell Engineering.
Organoid Technology for Basic Science and Biomedical Research. Design,
Fabrication, and Microflow Control Techniques for Organ-on-a-Chip Devices.
Microfluidic Techniques for High-Throughput Cell Analysis. 3D Printing and
Bioprinting Technologies. PART III Pathomimetic Disease Modeling.
Microengineered Models of Human Gastrointestinal Diseases. Respiratory
Pathophysiology - Microphysiological Models of Human Lung. In Vitro
Alzheimer's Disease Modeling Using Stem Cells. PART IV Towards
Translational Application and Precision Medicine. Manufacturing and
Assembly of Micro- and Nano-scale Devices and Interfaces Using Silk
Proteins. Microarray 3D Bioprinting for Creating Miniature Human Tissue
Replicas for Predictive Compound Screening. Integration of the Immune
System into Complex In Vitro Models for Preclinical Drug Development.