Molecular Motors in Bionanotechnology
Autor Keith Firman, James Youellen Limba Engleză Hardback – 18 mar 2013
Molecular Motors in Bionanotechnology describes a wide range of molecular motors, ranging from chemical motors to biological motors, in a manner that updates, or reviews, both classification of the type of motor and the grouping into families. Many techniques have evolved to study and characterise molecular motors at the single-molecule level (e.g. use of molecular tweezer devices for single-molecule studies). The text introduces the reader to the concepts and benefits of these techniques. In addition, it looks at the structural information and how this helps understand function and, finally, how some of these motors are being used or may be used in the future as part of a synthetic biology approach to building devices and sensors.
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Specificații
ISBN-13: 9789814267021
ISBN-10: 9814267023
Pagini: 216
Ilustrații: 44 black & white illustrations, 8 colour illustrations
Dimensiuni: 152 x 229 x 15 mm
Greutate: 0.5 kg
Ediția:1
Editura: Jenny Stanford Publishing
Colecția Jenny Stanford Publishing
ISBN-10: 9814267023
Pagini: 216
Ilustrații: 44 black & white illustrations, 8 colour illustrations
Dimensiuni: 152 x 229 x 15 mm
Greutate: 0.5 kg
Ediția:1
Editura: Jenny Stanford Publishing
Colecția Jenny Stanford Publishing
Public țintă
Academic and PostgraduateNotă biografică
James Youell has been working as a research fellow since 2004 at the University of Portsmouth on the design of a high-throughput single-molecule drug development tool utilising molecular motors. Through the development of this system, he has worked alongside a pan European research team, incorporating cutting-edge experimental tools, to build the various biological and synthetic components required. Dr Youell has published a number of papers on the development of such synthetic biology devices and given invited seminars on the subject.
Keith Firman is now retired from the University of Portsmouth, where he was reader in Molecular Biotechnology. He investigated the properties of type I restriction-modification systems. This led to the coordination of three consecutive European grants worth, in total, in excess of €4,500,000 to develop an electronic device for biosensing using single-molecule molecular motors. Dr Firman has published more than 50 papers and was also invited to participate in a number of international road-mapping exercises in nanotechnology.
Keith Firman is now retired from the University of Portsmouth, where he was reader in Molecular Biotechnology. He investigated the properties of type I restriction-modification systems. This led to the coordination of three consecutive European grants worth, in total, in excess of €4,500,000 to develop an electronic device for biosensing using single-molecule molecular motors. Dr Firman has published more than 50 papers and was also invited to participate in a number of international road-mapping exercises in nanotechnology.
Cuprins
Preface, Acknowledgement, Chapter 1: Mode of Activity of Molecular Motors, Chapter 2: Chemical Motors, Chapter 3: Biological Motors That Produce Rotary Motion, Chapter 4: Biological Motors That Produce Linear Motion, Chapter 5: Towards Bionanotechnology, Bibliography
Descriere
Many techniques have evolved to study and characterize molecular motors at the single-molecule level, such as the use of molecular tweezer devices for single-molecule studies. This book describes a wide range of molecular motors, from chemical to biological. It introduces readers to the concepts and benefits of each technique and looks at structural information and how this helps understand function. The book also examines how some of these motors are being used or may be used in the future as part of a synthetic biology approach to building devices and sensors.