Fluorescence Spectroscopy and Microscopy in Biology

Part I - Fluorescence Spectroscopy: Basics and Advanced Approaches.- Chapter 1 Choosing the right fluorescent probe.- Chapter 2 Fluorescence kinetics and time-resolved measurement.- Chapter 3 Quantitative Approach to Applications of Electronic Energy Transfer (EET).- Chapter 4 Single-molecule FRET: principles and analysis.- Chapter 5 Principles of fluorescence correlation and dual-color cross-correlation spectroscopy.- Part II - Fluorescence Microscopy: Basics and Advanced Approaches.- Chapter 6 Introduction to Fluorescence Microscopy.- Chapter 7 Wohland STED and RESOLFT fluorescent nanoscopy.- Chapter 8 Fluorescence Correlation Spectroscopy in Space and Time.- Part C - Applications of Fluorescence Spectroscopy and Microscopy to biological membranes.- Chapter 9 Determination of Biomolecular Oligomerization in the Live Cell Plasma Membrane via Single-molecule Brightness and Co-localization Analysis.- Chapter 10 Quantitative photoactivated localization microscopy of membrane receptoroligomers.- Chapter 11 Diffusion measurements at the nanoscale with STED-FCS.- Chapter 12 Single molecule microscopy methods to study mitochondrial processes.- Chapter 13 Transient state (TRAST) spectroscopy and imaging - exploiting the rich information source of fluorophore dark state transitions in biomolecular and cellular studies.- Chapter 14 The analysis of in-membrane nanoscopic aggregation of lipids and proteins by MC-FRET.- Part D - Applications of Fluorescence Spectroscopy to protein studies.- Chapter 15 Single-molecule fluorescence spectroscopy of intrinsically disordered proteins.- Chapter 16 Insights into the conformational dynamics of potassium channels using homo-FRET approaches.- Chapter 17 Intrinsic fluorescence kinetics in proteins.- Chapter 18 Dynamics and hydration of proteins viewed by fluorescence methods: investigations famor protein engineering and synthetic biology.