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Intro; Preface; Contents; Contributors; 1 Quantitative Phase Imaging: Principles and Applications; 1.1 Introduction; 1.2 Physical Interpretation of Phase Imaging in Transmission Versus Reflection Measurements; 1.3 Principles of Full-Field QPI; 1.3.1 Off-axis Methods; 1.3.2 Phase-Shifting Methods; 1.4 Applications; 1.4.1 Medical Applications; 1.4.2 Cellular Dynamics; 1.4.3 Tomography; 1.5 Important Concepts in QPI; 1.5.1 Effects of Spatial Coherence; 1.5.2 Defining Resolution; 1.6 Summary and Outlook; References; 2 Interferometric Scattering (iSCAT) Microscopy and Related Techniques
2.1 Introduction2.2 Historical Perspective; 2.3 Interferometric Scattering Microscopy (iSCAT); 2.3.1 Foundations; 2.3.2 Detection Sensitivity and Signal-to-Noise Ratio (SNR); 2.3.3 Background Removal; 2.3.4 Long Measurements: Indefinite Photostability; 2.3.5 Fast Measurements: No Saturation; 2.3.6 Exquisite Lateral and Axial Resolution; 2.3.7 Illumination and Detection Schemes; 2.4 iSCAT Showcase; 2.4.1 Detection and Sensing of Nanoparticles; 2.4.2 Dynamics in Nanobiology; 2.5 Summary and Outlook; References
3 Label-Free, Ultrahigh-Speed, Direct Imaging and Tracking of Bionanoparticles in Live Cells by Using Coherent Brightfield Microscopy3.1 Introduction to Label-Free Imaging in Live Cells Through Linear Scattering; 3.2 COBRI Microscopy; 3.3 Scattering Background Estimation and Correction; 3.4 Label-Free, Ultrahigh-Speed Imaging and Tracking of a Single Bionanoparticle in Live Cells; 3.4.1 Single Virus Dynamics on Cell Membrane; 3.4.2 Nanoscopic Dynamics of a Cell Vesicle During Active Transportation; 3.5 Conclusions and Future Perspectives; References
4 Tomographic Diffractive Microscopy: Principles, Implementations, and Applications in Biology4.1 Introduction; 4.2 Digital Holographic Microscopy; 4.3 TDM with Illumination Rotation; 4.4 Multiwavelength TDM; 4.5 TDM with Sample Rotation; 4.6 Combined Approaches; 4.7 Conclusion and Perspectives; References; 5 Near-Field Scanning Optical Microscope Combined with Digital Holography for Three-Dimensional Electromagnetic Field Reconstruction; 5.1 Introduction to Near-Field Scanning Optical Microscopy (NSOM); 5.2 Principles of Digital Holography
5.3 Near-Field Scanning Optical Microscopy Combined with Digital Holography5.3.1 Experimental Setup; 5.3.2 3D Reconstructed EM Field Through Different Media; 5.3.3 Characterization of the Angular Scattering; 5.4 Possible Applications; 5.4.1 Coupled Nanoantennas; 5.4.2 Brownian Nanoparticles as Stochastic Optical Probes; 5.4.3 Scattering Through Disordered Media; 5.5 Conclusion; References; 6 Absorption-Based Far-Field Label-Free Super-Resolution Microscopy; 6.1 Introduction to Absorption-Based Far-Field Label-Free Super-Resolution Microscopy
2.1 Introduction2.2 Historical Perspective; 2.3 Interferometric Scattering Microscopy (iSCAT); 2.3.1 Foundations; 2.3.2 Detection Sensitivity and Signal-to-Noise Ratio (SNR); 2.3.3 Background Removal; 2.3.4 Long Measurements: Indefinite Photostability; 2.3.5 Fast Measurements: No Saturation; 2.3.6 Exquisite Lateral and Axial Resolution; 2.3.7 Illumination and Detection Schemes; 2.4 iSCAT Showcase; 2.4.1 Detection and Sensing of Nanoparticles; 2.4.2 Dynamics in Nanobiology; 2.5 Summary and Outlook; References
3 Label-Free, Ultrahigh-Speed, Direct Imaging and Tracking of Bionanoparticles in Live Cells by Using Coherent Brightfield Microscopy3.1 Introduction to Label-Free Imaging in Live Cells Through Linear Scattering; 3.2 COBRI Microscopy; 3.3 Scattering Background Estimation and Correction; 3.4 Label-Free, Ultrahigh-Speed Imaging and Tracking of a Single Bionanoparticle in Live Cells; 3.4.1 Single Virus Dynamics on Cell Membrane; 3.4.2 Nanoscopic Dynamics of a Cell Vesicle During Active Transportation; 3.5 Conclusions and Future Perspectives; References
4 Tomographic Diffractive Microscopy: Principles, Implementations, and Applications in Biology4.1 Introduction; 4.2 Digital Holographic Microscopy; 4.3 TDM with Illumination Rotation; 4.4 Multiwavelength TDM; 4.5 TDM with Sample Rotation; 4.6 Combined Approaches; 4.7 Conclusion and Perspectives; References; 5 Near-Field Scanning Optical Microscope Combined with Digital Holography for Three-Dimensional Electromagnetic Field Reconstruction; 5.1 Introduction to Near-Field Scanning Optical Microscopy (NSOM); 5.2 Principles of Digital Holography
5.3 Near-Field Scanning Optical Microscopy Combined with Digital Holography5.3.1 Experimental Setup; 5.3.2 3D Reconstructed EM Field Through Different Media; 5.3.3 Characterization of the Angular Scattering; 5.4 Possible Applications; 5.4.1 Coupled Nanoantennas; 5.4.2 Brownian Nanoparticles as Stochastic Optical Probes; 5.4.3 Scattering Through Disordered Media; 5.5 Conclusion; References; 6 Absorption-Based Far-Field Label-Free Super-Resolution Microscopy; 6.1 Introduction to Absorption-Based Far-Field Label-Free Super-Resolution Microscopy