Cell Mechanics

I. Basics Concept and Preparation of Culture Substrates for Cell Mechanical Studies.<br>Basic Rheology for Biologists.<br>Polyacrylamide Hydrogels for Cell Mechanics: Steps towards Optimization and Alternative Uses.<br>Microscopic Methods for Measuring the Elasticity of Gel Substrates for Cell Culture: Microspheres, Microindenters, and Atomic Force Microscopy. <br>Surface Patterning.<br>Molecular Engineering of Cellular Environments: Cell Adhesion to Nano-Digital Surfaces.<br><br>II. Subcellular Mechanical Properties and Activities.<br>Probing Cellular Mechanical Responses to Stimuli Using Ballistic Intracellular Nanorheology.<br>Multiple Particle Tracking and Two-Point Microrheology in Cells.<br>Imaging Stress Propagation in the Cytoplasm of a Living Cell.<br>Probing Intracellular Force Distributions by High-Resolution Live Cell Imaging and Inverse Dynamics.<br>Analysis of Microtubule Curvature.<br>Nuclear Mechanics and Methods. <br><br>III. Cellular and Embryonic Mechanical Properties and Activities.<br><br>The Use of Gelatin Substrates for Traction Force Microscopy in Rapidly Moving Cells.<br>Microfabricated Silicone Elastomeric Post Arrays for Measuring Traction Forces of Adherent Cells.<br>Cell Adhesion Strengthening: Measurement and Analysis.<br>Studying the Mechanics of Cellular Processes by Atomic Force Microscopy.<br>Using Force to Probe Single-Molecule Receptor-Cytoskeletal Anchoring beneath the Surface of a Living Cell.<br>High Throughput Rheological Measurements with an Optical Stretcher.<br>Measuring Mechanical Properties of Embryos and Embryonic Tissues. <br><br>IV. Mechanical Stimuli to Cells.<br>Tools to Study Cell Mechanics and Mechanotransduction.<br>Magnetic Tweezers in Cell Biology.<br>Optical Neuronal Guidance.<br>Microtissue Elasticity: Measurements by Atomic Force Microscopy and Its Influence on Cell Differentiation. <br>Demystifying the effects of a three-dimensional microenvironment in tissue morphogenesis.