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Conductive Polymers: Electrical Interactions in Cell Biology and Medicine [Kõva köide]

Edited by (Universite Laval, Quebec, Canada), Edited by (Université Laval, Quebec, Canada), Edited by (University of Wollongong, Australia)
  • Formaat: Hardback, 420 pages, kõrgus x laius: 234x156 mm, kaal: 1102 g, 118 Illustrations, black and white
  • Sari: Series in Materials Science and Engineering
  • Ilmumisaeg: 14-Apr-2017
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1482259281
  • ISBN-13: 9781482259285
Teised raamatud teemal:
Conductive Polymers: Electrical Interactions in Cell Biology and MedicineSuurem pilt
  • Formaat: Hardback, 420 pages, kõrgus x laius: 234x156 mm, kaal: 1102 g, 118 Illustrations, black and white
  • Sari: Series in Materials Science and Engineering
  • Ilmumisaeg: 14-Apr-2017
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1482259281
  • ISBN-13: 9781482259285
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781482259285.html
Märksõnad:

This book is dedicated to the field of conductive polymers, focusing on electrical interactions with biological systems. It addresses the use of conductive polymers as the conducting interface for electrical communications with the biological system, both in vitro and in vivo. It provides an overview on the chemistry and physics of conductive polymers, their useful characteristics as well as limitations, and technologies that apply conductive polymers for medical purposes. This groundbreaking resource addresses cytotoxicity and tissue compatibility of conductive polymers, the basics on electromagnetic fields, and commonly used experimental methods. Readers will also learn how cells are cultured in vitro with conductive polymers, and how conductive polymers and living tissues interact electrically. Throughout the contents, chapter authors emphasize the importance of conductive polymers in biomedical engineering and their potential applications in medicine.

Arvustused

"Profs. Zhang, Rouabhia, and Moulton have assembled a group of investigators that are working on issues ranging from materials synthesis, device characterization, and analytical measurements of performance. Of particular interest and value are several reports from clinically-inclined investigators that describe recent studies of electrically-mediated cell response. These areas represent opportunities for future developments and collaborations between chemists, materials scientists, biomedical engineers, and physicians. Taken together, these chapters provide a comprehensive overview of issues related to the interface between active devices and biological systems" David C. Martin, Karl W. and Renate Böer Professor of Materials Science & Engineering, University of Delaware (from the Foreword)

Series Preface ix
Foreword xi
Preface xiii
Editors xvii
Contributors xix
1 Early history of conductive organic polymers
1(22)
Seth C. Rasmussen
2 Synthesis of biomedically relevant conducting polymers
23(18)
Simon E. Moulton
Darren Svirskis
3 Properties and characterization of conductive polymers
41(36)
David L. Officer
Klaudia Wagner
Pawel Wagner
4 Mechanism in charge transfer and electrical stability
77(30)
Wen Zheng
Jun Chen
Peter C. Innis
5 Industry-viable metal anticorrosion application of polyaniline
107(22)
Yizhong Luo
Xianhong Wang
6 Medical device implants for neuromodulation
129(20)
Trenton A. Jerde
7 The electromagnetic nature of protein--protein interactions
149(22)
Anna Katharina Hildebrandt
Thomas Kemmer
Andreas Hildebrandt
8 The impact of electric fields on cell processes, membrane proteins, and intracellular signaling cascades
171(26)
Trisha M. Pfluger
Siwei Zhao
9 Lipid-protein electrostatic interactions in the regulation of membrane--protein activities
197(20)
Natalia Wilke
Maria B. Decca
Guillermo G. Montich
10 Experimental methods to manipulate cultured cells with electrical and electromagnetic fields
217(14)
Ze Zhang
Shiyun Meng
Mahmoud Rouabhia
11 The neurotrophic factor rationale for using brief electrical stimulation to promote peripheral nerve regeneration in animal models and human patients
231(20)
Tessa Gordon
12 In vitro modulatory effects of electrical field on fibroblasts
251(14)
Mahmoud Rouabhia
Ze Zhang
13 The role of electrical field on neurons: In vitro studies
265(18)
A. Lee Miller
Huan Wang
Michael J. Yaszemski
Lichun Lu
14 Modulation of bone cell activities in vitro by electrical and electromagnetic stimulations
283(14)
Ze Zhang
Mahmoud Rouabhia
15 Electrical stimulation of cells derived from muscle
297(26)
Anita F. Quigley
Justin L. Bourke
Robert M. I. Kapsa
16 The response of endothelial cells to endogenous bioelectric fields
323(24)
Peter R. Bergethon
17 The role of electrical field on stem cells in vitro
347(26)
Miina Bjorninen
Suvi Haimi
Michael J. Higgins
Jeremy M. Crook
18 Effects of electrical stimulation on cutaneous wound healing: Evidence from in vitro studies and clinical trials
373(14)
Sara Ud-Din
Ardeshir Bayat
19 Effect of electrical stimulation on bone healing
387(16)
Michelle Griffin
Ardeshir Bayat
Index 403
Dr. Ze Zhang is a full professor of the Department of Surgery at Laval University and a senior researcher in the Division of Regenerative Medicine of CHU in Quebec City. He received bachelors and masters degrees in engineering from Chengdu University of Science & Technology (now Sichuan University) in 1982 and 1984, and then a PhD degree in experimental medicine from Laval University in 1993. After a postdoctoral training in Japan he returned to Laval University in 1995. Dr. Ze Zhangs main research focuses are cardiovascular implants and tissue repair using synthetic polymers and electrical stimulation. He has published more than 100 peer-reviewed papers and 4 book chapters.



Dr. Mahmoud Rouabhia is a full professor at the Faculty of Dentistry of Laval University. He is a senior scientist in the field of Immunologyimmunology, cell biology, and tissue engineering. He got his PhD in France, followed by a postdoctoral training for four years in Canada. Dr. Rouabhia research interest includes studying the interaction between human cells biomaterials and electrical stimulation for better wound healing. Dr. Rouabhia has more than 130 peer-reviewed scientific publications. He also published over 15 book chapters/review articles, and two patents. He is the editor/coeditor of two books in the field of tissue engineering and wound healing.



Dr. Simon E. Moulton is a full professor of Biomedical Electromaterials Science in the Faculty of Science, Engineering and Technology at Swinburne University of Technology. He completed his PhD at the University of Wollongong in 2002 and has developed a substantial research track record in the synthesis and fabrication of organic conducting materials for use in a variety of biomedical applications. He has a strong focus in materials chemistry research with an emphasis in developing composite biomaterials through the integration of electroactive materials with conventional biomaterials. He has published 1 book, 4 book chapters and 95 journal papers with an h-index of 27.