Fundamentals of Light Microscopy and Electronic Imaging

Fundamentals of Light Microscopy and Electronic Imaging, Second Edition provides a coherent introduction to the principles and applications of the integrated optical microscope system, covering both theoretical and practical considerations. It expands and updates discussions of multi-spectral imaging, intensified digital cameras, signal colocalization, and uses of objectives, and offers guidance in the selection of microscopes and electronic cameras, as well as appropriate auxiliary optical systems and fluorescent tags. The book is divided into three sections covering optical principles in diffraction and image formation, basic modes of light microscopy, and components of modern electronic imaging systems and image processing operations. Each chapter introduces relevant theory, followed by descriptions of instrument alignment and image interpretation. This revision includes new chapters on live cell imaging, measurement of protein dynamics, deconvolution microscopy, and interference microscopy. PowerPoint slides of the figures as well as other supplementary materials for instructors are available at a companion website: www.wiley.com/go/murphy/lightmicroscopy

Autorentext

DOUGLAS B. MURPHY supervises core facilities in
microscopy and histology at the new HHMI Janelia Farm Research
Campus in Ashburn, Virginia. An Adjunct Professor of Cell Biology
at Johns Hopkins School of Medicine in Baltimore, Maryland, Dr.
Murphy helped establish the School of Medicine Microscope Facility
there, which he supervised until 2006.

MICHAEL W. DAVIDSON is an assistant scholar/scientist
affiliated with the National High Magnetic Field Laboratory and the
Department of Biological Science at Florida State University where
he is involved in developing educational websites. His digital
images and photomicrographs have graced the covers of over 2,000
publications.

Klappentext

"This book will provide individuals without background knowledge in optical physics, electronics, or image processing with many of the basic facts they need to know to understand both the power and limitations of their images."
—Cell Biology Education on the First Edition

Fundamentals of Light Microscopy and Electronic Imaging, Second Edition provides a coherent introduction to the principles and applications of the integrated optical microscope system, covering both theoretical and practical considerations. It expands and updates discussions of multi-spectral imaging, intensified digital cameras, signal colocalization, and uses of objectives, and offers guidance in the selection of microscopes and electronic cameras, as well as appropriate auxiliary optical systems and fluorescent tags.

Written in simple, clear language, the book is divided into three sections covering optical principles in diffraction and image formation, basic modes of light microscopy, and components of modern electronic imaging systems and image processing operations. Each chapter introduces relevant theory, followed by descriptions of instrument alignment and image interpretation. Including new sections on live cell imaging, measurement of protein dynamics, deconvolution, multiphoton microscopy, and superresolution microscopy, Fundamentals of Light Microscopy and Electronic Imaging, Second Edition features the following chapters:

• Fundamentals of Light Microscopy
• Light and Color
• Illuminators, Filters, and the Isolation of Specific Wavelengths
• Lenses and Geometrical Optics
• Diffraction and Interference in Image Formation
• Diffraction and Spatial Resolution
• Phase Contrast Microscopy and Darkfield Microscopy
• Properties of Polarized Light
• Polarization Microscopy
• Differential Interference Contrast (DIC) Microscopy and Modulation Contrast Microscopy
• Fluorescence Microscopy
• Fluorescence Imaging of Dynamic Molecular Processes
• Confocal Laser Scanning Microscopy
• Two-Photon Excitation Fluorescence Microscopy
• Superresolution Imaging
• Imaging Living Cells with the Microscope
• Fundamentals of Digital Imaging
• Digital Imaging Processing

Zusammenfassung

Fundamentals of Light Microscopy and Electronic Imaging, Second Edition provides a coherent introduction to the principles and applications of the integrated optical microscope system, covering both theoretical and practical considerations. It expands and updates discussions of multi-spectral imaging, intensified digital cameras, signal colocalization, and uses of objectives, and offers guidance in the selection of microscopes and electronic cameras, as well as appropriate auxiliary optical systems and fluorescent tags.

The book is divided into three sections covering optical principles in diffraction and image formation, basic modes of light microscopy, and components of modern electronic imaging systems and image processing operations. Each chapter introduces relevant theory, followed by descriptions of instrument alignment and image interpretation. This revision includes new chapters on live cell imaging, measurement of protein dynamics, deconvolution microscopy, and interference microscopy.

PowerPoint slides of the figures as well as other supplementary materials for instructors are available at a companion website:

www.wiley.com/go/murphy/lightmicroscopy

Inhalt

Preface xi

Acknowledgments xii

1. Fundamentals of Light Microscopy 1

Overview 1

Optical Components of the Light Microscope 1

Aperture and Image Planes in a Focused, Adjusted Microscope 5

Note: Objectives, Eyepieces, and Eyepiece Telescopes 6

Koehler Illumination 9

Adjusting the Microscope for Koehler Illumination 9

Note: Summary of Steps for Koehler Illumination 11

Note: Focusing Oil Immersion Objectives 14

Fixed Tube Length versus Infinity Optical Systems 15

Precautions for Handling Optical Equipment 16

Care and Maintenance of the Microscope 17

Exercise: Calibration of Magnification 17

2. Light and Color 21

Overview 21

Light as a Probe of Matter 21

The Dual Particle- and Wave-Like Nature of Light 25

The Quality of Light 26

Properties of Light Perceived by the Eye 27

Physical Basis for Visual Perception and Color 28

Addition and Subtraction Colors 30

Exercise: Complementary Colors 32

3. Illuminators, Filters, and the Isolation of Specific Wavelengths 35

Overview 35

Illuminators and Their Spectra 35

Illuminator Alignment and Bulb Replacement 41

Demonstration: Spectra of Common Light Sources 41

Demonstration: Aligning a 100-W Mercury Arc Lamp in an Epi-Illuminator 43

Filters for Adjusting the Intensity and Wavelength of Illumination 45

Effects of Light on Living Cells 50

4. Lenses and Geometrical Optics 53

Overview 53

Reflection and Refraction of Light 53

Image Formation by a Simple Lens 56

Note: Real and Virtual Images 57

Rules of Ray Tracing for a Simple Lens 58

ObjectImage Math 58

The Principal Aberrations of Lenses 62

Designs and Specifications of Objectives 65

Condensers 71

Oculars 72

Microscope Slides and Coverslips 73

The Care and Cleaning of Optics 73

Exercise: Constructing and Testing an Optical Bench Microscope 76

5. Diffraction and Interference in Image Formation 79

Overview 79

Diffraction and Interference 80

The Diffraction Image of a Point Source of Light 83

The Constancy of Optical Path Length between Object and Image 85

Demonstration: Viewing the Airy Disk with a Pinhole Aperture 85

Effect of Aperture Angle on Diffraction Spot Size 87

Diffraction by a Grating and Calculation of Its Line Spacing, D 89

Demonstration: The Diffraction Grating 93

Abbé's Theory for Image Formation in the Microscope 94

A Diffraction Pattern Is Formed in the Rear Aperture of the Objective 97 …