Cellular In Vitro Testing (eBook, PDF)
Methods and Protocols
Redaktion: Haycock, John; Wilkinson, J. Malcolm; Ahluwalia, Arti
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Cellular In Vitro Testing (eBook, PDF)
Methods and Protocols
Redaktion: Haycock, John; Wilkinson, J. Malcolm; Ahluwalia, Arti
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Growing cells in 2D under static conditions has long been the gold standard of cell culture, despite this method not being representative of the complex in vivo environment. The use of animal models also has clear ethical and scientific limitations, and increasingly the 3Rs (replacement, refinement, reduction) in relation to animal models are being
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Growing cells in 2D under static conditions has long been the gold standard of cell culture, despite this method not being representative of the complex in vivo environment. The use of animal models also has clear ethical and scientific limitations, and increasingly the 3Rs (replacement, refinement, reduction) in relation to animal models are being
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Produktdetails
- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 192
- Erscheinungstermin: 27. August 2014
- Englisch
- ISBN-13: 9789814364980
- Artikelnr.: 43976908
- Verlag: Taylor & Francis
- Seitenzahl: 192
- Erscheinungstermin: 27. August 2014
- Englisch
- ISBN-13: 9789814364980
- Artikelnr.: 43976908
- Herstellerkennzeichnung Die Herstellerinformationen sind derzeit nicht verfügbar.
John W. Haycock is director of the Centre for Biomaterials and Tissue Engineering and associate director of the Kroto Research Institute, University of Sheffield, UK. He has a PhD in neuroscience from Newcastle University, UK. His key areas of work include scaffolds for nerve injury repair, 3D nerve models as alternatives for animal testing, and 3D imaging. Prof. Haycock is a member of the EPSRC Peer Review College, UK, and internationally has served on grant-awarding panels and examination bodies in Canada (CFI), Finland, and Sweden. Arti Ahluwalia is associate professor of bioengineering at the Department of Information Engineering, Faculty of Engineering; vice director of Interdepartmental Research Center "E. Piaggio"; and head of the MCB Group, University of Pisa, Italy. She is currently affiliated with National Council of Research Institute of Clinical Physiology (CNR-IFC), Italy, and is director of its NanoBioScopy Lab. Dr. Ahluwalia has a PhD in bioengineering from the Polytechnic of Milan, Italy. Her research is mainly centered on the interactions between biological systems and man-made materials devices or structures for the creation of organ and system models in vitro, tissue engineering, biosensing, robots for autism, bioreactors, and in vitro models. John M. Wilkinson is the founder and managing director of Kirkstall Ltd., UK. Prior to founding Kirkstall, he had been managing a high-technology consulting company in Cambridge, UK, following a career in high-technology product development in both large corporations and startups. Dr. Wilkinson earned his PhD from Middlesex University, UK. He is a fellow of the Institute of Nanotechnology, UK, and has been a visiting lecturer for FSRM, Neuchatel, Switzerland, on the subject of micro- and nanotechnology in biomedical engineering for over ten years.
Preface, Chapter 1: Methods for Conducting Connected Culture Experiments
Using the Quasi-Vivo® Chambers, Chapter 2: The Use of in vitro 3D Cell
Models of Human Airway Epithelia (MucilAir(TM)) in Inhalation Toxicity,
Chapter 3: Cultivation of Human Hepatocytes in the Quasi-Vivo® System: From
Isolation and Seeding to Quantification of Xenobiotic-Metabolizing Enzyme
Expression and Activity, Chapter 4: Generation of Patient-Specific Cardiac
Patches by Human Cardiac Progenitor Cells and 3D Scaffolds, Chapter 5: In
vitro Risk Assessment of Nanoparticles, Chapter 6: Utilizing
Nanosensor-Incorporated Scaffolds in the Development of a 3D Lung Model,
Chapter 7: Development of a Paracrine-Signaling Model for Detecting
Irritancy Using Human Keratinocytes and Fibroblasts, Chapter 8: Advanced in
vitro Models of the Intestinal Mucosa for Drug Delivery Studies, Chapter 9:
An in vitro NHBE Model of the Human Bronchial Epithelium, Chapter 10:
Method for Simple and Routine Three-Dimensional Cell Culture
Using the Quasi-Vivo® Chambers, Chapter 2: The Use of in vitro 3D Cell
Models of Human Airway Epithelia (MucilAir(TM)) in Inhalation Toxicity,
Chapter 3: Cultivation of Human Hepatocytes in the Quasi-Vivo® System: From
Isolation and Seeding to Quantification of Xenobiotic-Metabolizing Enzyme
Expression and Activity, Chapter 4: Generation of Patient-Specific Cardiac
Patches by Human Cardiac Progenitor Cells and 3D Scaffolds, Chapter 5: In
vitro Risk Assessment of Nanoparticles, Chapter 6: Utilizing
Nanosensor-Incorporated Scaffolds in the Development of a 3D Lung Model,
Chapter 7: Development of a Paracrine-Signaling Model for Detecting
Irritancy Using Human Keratinocytes and Fibroblasts, Chapter 8: Advanced in
vitro Models of the Intestinal Mucosa for Drug Delivery Studies, Chapter 9:
An in vitro NHBE Model of the Human Bronchial Epithelium, Chapter 10:
Method for Simple and Routine Three-Dimensional Cell Culture
Preface, Chapter 1: Methods for Conducting Connected Culture Experiments
Using the Quasi-Vivo® Chambers, Chapter 2: The Use of in vitro 3D Cell
Models of Human Airway Epithelia (MucilAir(TM)) in Inhalation Toxicity,
Chapter 3: Cultivation of Human Hepatocytes in the Quasi-Vivo® System: From
Isolation and Seeding to Quantification of Xenobiotic-Metabolizing Enzyme
Expression and Activity, Chapter 4: Generation of Patient-Specific Cardiac
Patches by Human Cardiac Progenitor Cells and 3D Scaffolds, Chapter 5: In
vitro Risk Assessment of Nanoparticles, Chapter 6: Utilizing
Nanosensor-Incorporated Scaffolds in the Development of a 3D Lung Model,
Chapter 7: Development of a Paracrine-Signaling Model for Detecting
Irritancy Using Human Keratinocytes and Fibroblasts, Chapter 8: Advanced in
vitro Models of the Intestinal Mucosa for Drug Delivery Studies, Chapter 9:
An in vitro NHBE Model of the Human Bronchial Epithelium, Chapter 10:
Method for Simple and Routine Three-Dimensional Cell Culture
Using the Quasi-Vivo® Chambers, Chapter 2: The Use of in vitro 3D Cell
Models of Human Airway Epithelia (MucilAir(TM)) in Inhalation Toxicity,
Chapter 3: Cultivation of Human Hepatocytes in the Quasi-Vivo® System: From
Isolation and Seeding to Quantification of Xenobiotic-Metabolizing Enzyme
Expression and Activity, Chapter 4: Generation of Patient-Specific Cardiac
Patches by Human Cardiac Progenitor Cells and 3D Scaffolds, Chapter 5: In
vitro Risk Assessment of Nanoparticles, Chapter 6: Utilizing
Nanosensor-Incorporated Scaffolds in the Development of a 3D Lung Model,
Chapter 7: Development of a Paracrine-Signaling Model for Detecting
Irritancy Using Human Keratinocytes and Fibroblasts, Chapter 8: Advanced in
vitro Models of the Intestinal Mucosa for Drug Delivery Studies, Chapter 9:
An in vitro NHBE Model of the Human Bronchial Epithelium, Chapter 10:
Method for Simple and Routine Three-Dimensional Cell Culture