Handbook of Biomedical Nonlinear Optical Microscopy.
Title:
Handbook of Biomedical Nonlinear Optical Microscopy.
Author:
Masters, Barry R.
ISBN:
9780198036821
Personal Author:
Physical Description:
1 online resource (895 pages)
Contents:
Contents -- Foreword -- Contributors -- PART I. HISTORICAL DEVELOPMENT OF NONLINEAR OPTICAL MICROSCOPY AND SPECTROSCOPY -- INTRODUCTION TO PART I: HISTORICAL DEVELOPMENT OF NONLINEAR OPTICAL MICROSCOPY AND SPECTROSCOPY -- 1 THE GENESIS OF NONLINEAR MICROSCOPIES AND THEIR IMPACT ON MODERN DEVELOPMENTS -- 1.1 Introduction -- 1.2 Maria Göppert-Mayer's Scientific Life -- 1.3 Maria Göppert-Mayer's 1931 Doctoral Dissertation -- 1.4 Nonlinear Optical Processes and Microscopy -- 1.5 The Scanning Harmonic Optical Microscope at Oxford University -- 1.6 The Role of Lasers in the Development of Nonlinear Microscopy -- 1.7 The Denk, Strickler, and Webb Science Report (1990) and Their Patent (1991) -- 1.8 Comparison of Multiphoton Excitation Microscopy and Confocal Microscopy -- 1.9 Modern Developments in Nonlinear Microscopy and Their Impact -- 1.10 Major Biomedical Applications of Nonlinear Microscopy -- 1.11 Conclusion -- References -- Appendix: Key Developments of Lasers and Laser Technology -- 2 THE SCIENTIFIC LIFE OF MARIA GÖPPERT-MAYER -- 2.1 Professional Life -- 2.2 Experimental Verification of Göppert-Mayer's Theory Predicting Two-Photon Absorption Processes -- 2.3 Microscopic Implementation of Nonlinear Spectroscopy -- References -- 3 THE HISTORY OF PERTURBATION THEORY FROM ASTRONOMY TO QUANTUM MECHANICS -- 3.1 Introduction -- 3.2 The Genesis of Perturbation Theory -- 3.3 Perturbation Theory in Quantum Mechanics -- 3.4 Conclusion -- References -- 4 ENGLISH TRANSLATIONS OF AND TRANSLATOR'S NOTES ON MARIA GÖPPERT-MAYER'S THEORY OF TWO-QUANTUM PROCESSES[sup(*)] -- 4.1 English Translation of: Göppert, M. (1929). Über die Wahrscheinlichkeit des Zusamenwirkens zweier Lichtquanten in einem Elementarakt. Die Naturwissenschaften, 17, 932, (1929)[sup(*)].
4.2 English Translation of: Göppert-Mayer, M. (1931). Über Elementarakte mit zwei Quantensprüngen. Ann. Phys (Leipzig), 9, 273-294, (1931) -- 4.3 Notes on Maria Göppert-Mayer's Theory of Two-Quantum Processes -- References -- PART II. NONLINEAR OPTICAL SPECTROSCOPY -- INTRODUCTION TO PART II: NONLINEAR OPTICAL SPECTROSCOPY -- II.1 Two-Photon Excitation Fluorescence Spectroscopy -- II.2 Second-Harmonic and Third-Harmonic Generation -- II.3 Coherent Anti-Stokes Raman Scattering -- II.4 Comparison of the Three Nonlinear Optical Techniques -- II.5 Conclusions -- References -- 5 CLASSICAL AND QUANTUM THEORY OF ONE-PHOTON AND MULTIPHOTON FLUORESCENCE SPECTROSCOPY -- 5.1 Introduction -- 5.2 Principles of Fluorescence and Phosphorescence -- 5.3 Atom-Radiation Interactions: Transition from Classical to Quantum Approaches -- 5.4 Quantum Mechanics Primer -- 5.5 Quantum Mechanical Transition Probabilities for One-Photon and Two-Photon Processes -- 5.6 Selection Rules and Parity -- 5.7 Summary of Important Concepts and Defenitions Relating to Electronic Transitions -- References -- 6 SECOND- AND HIGHER-ORDER HARMONIC GENERATION -- 6.1 Introduction -- 6.2 Theory of the Nonlinear Optical Susceptibility -- 6.3 Simple Model of the Nonlinear Susceptibility -- 6.4 Quantum Mechanical Treatment of the Nonlinear Susceptibility[sup(*)] -- 6.5 Wave Equation Description of Harmonic Generation[sup(*)] -- 6.6 N-th Harmonic Generation[sup(*)] -- 6.7 Harmonic Generation with Focused Laser Beams[sup(*)] -- 6.8 Surface Nonlinear Optics -- 6.9 Nonlinear Optical Microscopy -- 6.10 Harmonic Generation as a Probe of Membrane Potentials -- References -- 7 THEORY OF SPONTANEOUS AND COHERENT RAMAN SCATTERING -- 7.1 Introduction -- 7.2 The Origin of the CARS Signal -- 7.3 CARS Spectral Properties[sup(*)] -- 7.4 CARS under Tight Focusing[sup(*)] -- 7.5 Conclusion -- References.
PART III. NONLINEAR OPTICAL INSTRUMENTS FOR MICROSCOPIC IMAGING AND ANALYSIS -- INTRODUCTION TO PART III: NONLINEAR OPTICAL INSTRUMENTS FOR MICROSCOPIC IMAGING AND ANALYSIS: REVIEW AND FORECAST -- 8 LASER SOURCES FOR NONLINEAR MICROSCOPY -- 8.1 Overview -- 8.2 Mode-Locking -- 8.3 Methods of Mode-Locking -- 8.4 Practical Mode-Locked Lasers -- 8.5 Pulse Shapes from Mode-Locked Lasers -- 8.6 Currently Available Commercial Laser Systems -- 8.7 Future Sources -- 8.8 Practical Advice for Use of Femtosecond Lasers -- References -- 9 ULTRASHORT OPTICAL PULSE DELIVERY FOR NONLINEAR OPTICAL MICROSCOPY -- 9.1 Introduction -- 9.2 Experimental Design Considerations for Ultrashort Optical Pulse Delivery -- 9.3 Characteristics of Fiber Conduction of Ultrashort Optical Pulses -- 9.4 Summary -- References -- 10 AN OPTICAL DESIGN PRIMER FOR NONLINEAR OPTICAL MICROSCOPES -- 10.1 Introduction -- 10.2 Excitation Light Conditioning -- 10.3 Elements of Microscope Design -- 10.4 Conclusion -- References -- 11 IMAGE FORMATION IN MULTIPHOTON FLUORESCENCE MICROSCOPY[sup(*)] -- 11.1 Introduction -- 11.2 Three-Dimensional Image Formation -- 11.3 Three-Dimensional Intensity Point Spread Function -- 11.4 Three-Dimensional Optical Transfer Function -- 11.5 Image Resolution -- 11.6 Effect of Fluorescence Wavelength -- References -- 12 SIGNAL DETECTION AND PROCESSING IN NONLINEAR OPTICAL MICROSCOPES -- 12.1 Introduction -- 12.2 Physical Principles for High-Sensitivity Optical Detection -- 12.3 Criteria for Detector Selection in Nonlinear Microscopy -- 12.4 Characterization of Detector Noise Characteristics and Signal Processing[sup(*)] -- 12.5 A Survey of Detector Types and Their Characteristics -- 12.6 Conclusion -- References -- 13 MULTIPHOTON EXCITATION OF FLUORESCENT PROBES -- 13.1 Introduction and Overview -- 13.2 Estimation of Multiphoton Excitation.
13.3 Measurement Methods of Multiphoton Excitation Cross-Section -- 13.4 Cross-Section Data -- References -- 14 MULTIPHOTON-INDUCED CELL DAMAGE -- 14.1 Introduction -- 14.2 Multiphoton Microscopes and Imaging Devices -- 14.3 Photodamage Phenomena -- 14.4 Photothermal Damage -- 14.5 Photochemical Damage -- 14.6 Damage by Multiphoton Ionization -- 14.7 Conclusion -- References -- 15 APPLICATIONS OF SECOND-HARMONIC GENERATION MICROSCOPY -- 15.1 Introduction -- 15.2 Basic Principles -- 15.3 Instrumentation -- 15.4 Applications -- 15.5 Conclusion -- References -- 16 SECOND-HARMONIC GENERATION IMAGING MICROSCOPY OF STRUCTURAL PROTEIN IN ARRAYS IN TISSUE -- 16.1 Introduction and History of Second-Harmonic Generation Imaging -- 16.2 Theoretical and Physical Considerations -- 16.3 Experimental Considerations -- 16.4 Second-Harmonic Generation of Structural Protein Arrays -- 16.5 Second-Harmonic Generation Directionality of Collagen Fibers: Structural Considerations -- 16.6 Comparison with Other Optical Imaging Methods -- 16.7 Limitations of Second-Harmonic Generation Imaging -- 16.8 Prospects -- References -- 17 COHERENT ANTI-STOKES RAMAN SCATTERING (CARS) MICROSCOPY: INSTRUMENTATION AND APPLICATIONS -- 17.1 Imaging Properties of CARS Microscopy[sup(*)] -- 17.2 The CARS Light Source -- 17.3 The CARS Laser Scanning Microscope -- 17.4 CARS Microscopy Techniques for Nonresonant Background Suppression -- 17.5 CARS Microspectroscopy -- 17.6 CARS Imaging of Biological Samples -- 17.7 Other Applications of CARS Microscopy -- 17.8 Prospects and Conclusions -- References -- 18 HIGH-SPEED IMAGING USING MULTIPHOTON EXCITATION MICROSCOPY -- 18.1 Introduction -- 18.2 Fundamental Limits of High-Speed Multiphoton Microscopy -- 18.3 Implementations of High-Speed Multiphoton Microscopes -- 18.4 Conclusion -- References.
19 NONLINEAR MULTISPECTRAL OPTICAL IMAGING MICROSCOPY: CONCEPTS, INSTRUMENTATION, AND APPLICATIONS -- 19.1 Introduction -- 19.2 Light-Matter Interactions -- 19.3 Multispectral Imaging -- 19.4 Spatial Scanning Techniques (Spectral Multiplexing) -- 19.5 Wavelength Scanning Techniques (Spatial Multiplexing) -- 19.6 Nonscanning Techniques -- 19.7 Spectral Image Analysis -- 19.8 Applications of Multiphoton Multispectral Imaging in Biology and Medicine -- 19.9 Prospects and Conclusions -- References -- 20 MULTIPHOTON POLARIZATION MICROSCOPY -- 20.1 Introduction -- 20.2 Setting up a Multiphoton Polarization Microscope -- 20.3 Multiphoton Polarization Imaging of Skin Stratum Corneum and Dermal Fibers -- 20.4 Conclusion -- References -- 21 LIFETIME-RESOLVED IMAGING IN NONLINEAR MICROSCOPY -- 21.1 Introduction -- 21.2 The Laser Scanning Microscope -- 21.3 Physical Background of Fluorescence Lifetime Imaging -- 21.4 Requirements for Fluorescence Lifetime Imaging in Scanning Microscopes -- 21.5 Frequency-Domain Techniques -- 21.6 Analog Time-Domain Systems -- 21.7 Photon Counting Techniques -- 21.8 Applications of FLIM in Biology -- 21.9 Concluding Remarks -- References -- 22 FÖRSTER RESONANCE ENERGY TRANSFER (FRET) -- 22.1 Introduction -- 22.2 FRET Theory and Experimental Studies -- 22.3 Physics Background for Understanding FRET -- 22.4 Theories and Experiments of Resonance Energy Transfer up to and Including the Work of Förster -- 22.5 Classical and Quantum Mechanical Description of Energy Transfer after Förster -- 22.6 Summary and Comments on Förster's Theory of Resonance Energy Transfer -- References -- 23 TWO-PHOTON FÖRSTER RESONANCE ENERGY TRANSFER (FRET) MICROSCOPY -- 23.1 Introduction -- 23.2 FRET Theory -- 23.3 FRET Microscopy -- 23.4 Different Microscopic Techniques of Measuring FRET Signals -- 23.5 Conclusion -- References.
24 DIFFRACTION UNLIMITED FAR-FIELD FLUORESCENCE MICROSCOPY.
Abstract:
List of Contributors. Foreword, Watt Webb. Part I. Historical Development of Nonlinear Optical Spectroscopy and Microscopy. Introduction to Part I: Historical Development of Nonlinear Optical Microscopy and Spectroscopy, Barry R. Masters. Chapter 1. The Genesis of Nonlinear Optical Microscopies and Their Impact on Modern Developments, Barry R. Masters and Peter T. C. So. Chapter 2. The Scientific Life of Maria Goppert-Mayer, Barry R. Masters. Chapter 3. The History of Perturbation Theory from Astronomy to Quantum Mechanics, Barry R. Masters. Chapter 4. English Translations of and Translator's Notes on Maria Goppert-Mayer's Theory of Two-Quantum Processes, Barry R. Masters. Part II. Nonlinear Optical Spectroscopy. Introduction to Part II: Nonlinear Optical Spectroscopy, Robert W. Boyd and Barry R. Masters. Chapter 5. Classical and Quantum Theory of One-Photon and Multiphoton Fluorescence Spectroscopy, Barry R. Masters and Peter T. C. So. Chapter 6. Second- and Higher-Order Harmonic Generation, Robert W. Boyd. Chapter 7. Theory of Spontaneous and Coherent Raman Scattering, Eric O. Potma and X. Sunney Xie. Part III. Nonlinear Optical Instruments for Microscopic Imaging and Analysis. Introduction to Part III: Nonlinear Optical Instruments for Microscopic Imaging and Analysis: Review and Forecast, Peter T. C. So and Daekeun Kim. Chapter 8. Laser Sources for Non-Linear Microscopy, John Girkin. Chapter 9. Ultrashort Optical Pulse Delivery for Nonlinear Optical Microscopy, Peter T.C. So and Daekeun Kim. Chapter 10. An Optical Design Primer for Nonlinear Optical Microscopy, Peter T. C. So and Daekeun Kim. Chapter 11. Image Formation in Multiphoton Fluorescence Microscopy, Min Gu. Chapter 12. Signal Detection and Processing in Nonlinear Optical Microscopes, Siavash Yazdanfar and Peter T. C. So. Chapter 13. Multiphoton Excitation of Fluorescent Probes,
Chris Xu and Warren R. Zipfel. Chapter 14. Multiphoton-Induced Cell Damage, Karsten Konig. Chapter 15. Applications of Second-Harmonic Generation Microscopy, Jerome Mertz. Chapter 16. Second-Harmonic Generation Imaging Microscopy of Structural Protein, Paul J. Campagnola. Chapter 17. Coherent Anti-Stokes Raman Scattering (CARS) Microscopy: Instrumentation and Applications, Eric O. Potma and X. Sunney Xie. Chapter 18. High-speed Imaging Using Multiphoton Excitation, Ki H. Kim, Karsten Bahlmann, Timothy Ragan, Daekeun Kim, and Peter T. C. So. Chapter 19. Nonlinear Multi-Spectral Optical Imaging Microscopy: Concepts, Instrumentation, and Applications, Sebastian Wachsmann-Hogiu and Daniel L. Farkas. Chapter 20. Multiphoton Polarization Microscopy, Yen Sun, Wen Lo, Jiunn Wen Su, Sung-Jan Lin, Shiou-Hwa Jee, and Chen-Yuan Dong. Chapter 21. Lifetime-Resolved Imaging in Nonlinear Microscopy, Wolfgang Becker and Axel Bergmann. Chapter 22. Forster Resonance Energy Transfer (FRET), Barry R. Masters and Peter T. C. So. Chapter 23. Two-Photon Forster Resonance Energy Transfer (FRET) Microscopy, Ye Chen, Horst Wallrabe and Ammasi Periasamy. Chapter 24. Diffraction Unlimited Far-Field Fluorescence Microscopy, Andreas Schonle, Jan Keller, Benjamin Harke, and Stefan W. Hell. Chapter 25. Two-Photon Fluorescence Correlation Spectroscopy, Suzette Pabit and Keith Berland. Chapter 26. Photobleaching and Recovery with Nonlinear Microscopy, Edward Brown, Ania Majewska, and Rakesh K. Jain. Chapter 27. Femtosecond Laser Nanoprocessing, Karsten Konig. Part IV. Biomedical Applications of Nonlinear Optical Microscopy. Introduction to Part IV: Biomedical Applications of Nonlinear Optical Microscopy, Bruce J. Tromberg. Chapter 28. Pioneering Applications Of Two-Photon Microscopy To Mammalian Neurophysiology: Seven Case Studies, Q.-T. Nguyen, G. O. Clay, N. Nishimura, C. B.
Schaffer, L. F. Schroeder, P. S. Tsai, and D. Kleinfeld. Chapter 29. Applications of Non-Linear Intravital Microscopy in Tumor Biology, Rakesh K. Jain, Michael F. Booth, Timothy P. Padera, Lance L. Munn, Dai Fukumura, and Edward Brown. Chapter 30. Immunology Based on Nonlinear Optical Microscopy, Ian Parker and Michael D. Cahalan. Chapter 31. Multiphoton Imaging in Animal Development, Irina V. Larina and Mary E. Dickinson. Chapter 32. Nonlinear Microscopy Applied to Dermatology, Barry R. Masters and Peter T. C. So. Chapter 33. Cellular Metabolism Monitored by NAD(P)H Imaging with Two-Photon Excitation Microscopy, Barry R. Masters. Index.
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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2017. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
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