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Adaptive Optics for Biological Imaging [Kõva köide]

Edited by (University of California-Santa Cruz, USA)
  • Formaat: Hardback, 388 pages, kõrgus x laius: 254x178 mm, kaal: 861 g, 14 Tables, black and white; 242 Illustrations, black and white
  • Ilmumisaeg: 26-Apr-2013
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1439850186
  • ISBN-13: 9781439850183
Teised raamatud teemal:
Adaptive Optics for Biological ImagingSuurem pilt
  • Formaat: Hardback, 388 pages, kõrgus x laius: 254x178 mm, kaal: 861 g, 14 Tables, black and white; 242 Illustrations, black and white
  • Ilmumisaeg: 26-Apr-2013
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1439850186
  • ISBN-13: 9781439850183
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781439850183.html
Märksõnad:
"Written by an international team of leaders in the field, this comprehensive reference presents a complete overview of the core principles, state-of-the-art methods, and emerging applications of adaptive optics in biological imaging. It emphasizes the use of adaptive optics to correct wavefront aberrations caused by light propagation in biological samples. Accessible to readers without a background in optics, the book describes the fundamentals, components, and systems used in adaptive optics. It also covers optics systems as well as newer applications in this rapidly expanding field"--

Adaptive Optics for Biological Imaging brings together groundbreaking research on the use of adaptive optics for biological imaging. The book builds on prior work in astronomy and vision science. Featuring contributions by leaders in this emerging field, it takes an interdisciplinary approach that makes the subject accessible to nonspecialists who want to use adaptive optics techniques in their own work in biology and bioengineering.

Organized into three parts, the book covers principles, methods, and applications of adaptive optics for biological imaging, providing the reader with the following benefits:

  • Gives a general overview of applied optics, including definitions and vocabulary, to lay a foundation for clearer communication across disciplines
  • Explains what kinds of optical aberrations arise in imaging through various biological tissues, and what technology can be used to correct for these aberrations
  • Explores research done with a variety of biological samples and imaging instruments, including wide-field, confocal, and two-photon microscopes
  • Discusses both indirect wavefront sensing, which uses an iterative approach, and direct wavefront sensing, which uses a parallel approach

Since the sample is an integral part of the optical system in biological imaging, the field will benefit from participation by biologists and biomedical researchers with expertise in applied optics. This book helps lower the barriers to entry for these researchers. It also guides readers in selecting the approach that works best for their own applications.

Arvustused

"Overall, this is an excellent book, which achieves its stated primary goal. Without reservations, this is a book I would recommend to anyone who wishes to start learning about the principles and potential of AO in this field." Biomedical Engineering OnLine

"The strength of the book is the delicate balance of theory and instrumentation and applications. Another example of the comprehensive nature of the chapters is a critical discussion of the adaptive optical elements. Adaptive Optics for Biological Imaging is a good place to start to understand the problem (aberrations induced by the instrument, the objective, and the specimen and its preparation and mounting in the microscope), and the various instrumental and computational approaches to approach a solution (minimize the significant aberrations)." Barry R. Masters, Journal of Biomedical Optics, Volume 18, July 2013

"This book is a broad and comprehensive introduction to the use of adaptive optics (AO) in biological microscopy. It provides a much-needed entrée to the field and includes not only the basics and general principles but also discussion of practical implementations and key application areas." From the Foreword by Professor Austin Roorda, University of California at Berkeley, and Professor Claire Max, University of California at Santa Cruz

Foreword ix
Preface xi
Editor xiii
Contributors xv
SECTION I Principles
1 Principles of Wave Optics
3(26)
Donald T. Gavel
2 Principles of Geometric Optics
29(14)
Joel A. Kubby
3 Theory of Image Formation
43(8)
Michael Schwertner
SECTION II Methods
4 Aberrations and the Benefit of Their Correction in Confocal Microscopy
51(24)
Michael Schwertner
5 Specimen-Induced Geometrical Distortions
75(8)
Michael Schwertner
6 Simulation of Aberrations
83(12)
Michael Schwertner
7 Overview of Adaptive Optics in Biological Imaging
95(14)
Elijah Y. S. Yew
Peter T. C. So
8 Wavefront Correctors
109(42)
Joel A. Kubby
9 Adaptive Optics System Alignment and Assembly
151(26)
Diana C. Chen
SECTION III Applications
Part 1 Indirect Wavefront Sensing
10 Sensorless Adaptive Optics for Microscopy
177(14)
Martin J. Booth
Alexander Jesacher
11 Implementation of Adaptive Optics in Nonlinear Microscopy for Biological Samples Using Optimization Algorithms
191(18)
John M. Girkin
12 AO Two-Photon Fluorescence Microscopy Using Stochastic Parallel Descent Algorithm with Zernike Polynomial Basis
209(22)
Yaopeng Zhou
13 Pupil-Segmentation-Based Adaptive Optics for Microscopy
231(22)
Na Ji
Eric Betzig
Part 2 Direct Wavefront Sensing
14 Coherence-Gated Wavefront Sensing
253(18)
Jonas Binding
Markus Ruckel
15 Adaptive Optics in Wide-Field Microscopy
271(28)
Peter Kner
Zvi Kam
David A. Agard
John Sedat
16 Biological Imaging and Adaptive Optics in Microscopy
299(16)
Elijah Y. S. Yew
Jae Won Cha
Jerome Ballesta
Peter T. C. So
17 Adaptive Optical Microscopy Using Direct Wavefront Measurements
315(30)
Oscar Azucena
Xiaodong Tao
Joel A. Kubby
Index 345
Joel Kubby is the Department Chair of Electrical Engineering in the Baskin School of Engineering at the University of California at Santa Cruz. His research is in the area of microelectromechanical systems (MEMS) with applications in optics, fluidics, and BioMEMS. Before joining the University of California at Santa Cruz in 2005, he was an area manager with the Wilson Center for Research and Technology and a member of technical staff in the Xerox Research Center Webster in Rochester, New York (19872005). Prior to Xerox, he was at the Bell Telephone Laboratories in Murray Hill, New Jersey, working in the area of scanning tunneling microscopy.