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  • Book
    Liang Huang and Wenhui Wang.
    Intro -- Acknowledgments -- Introduction -- 1.1 Overview of Microfluidics -- 1.1.1 Background and Brief Development History -- 1.1.2 Microfluidic Chip Material and Processing Method -- 1.2 Sample Manipulation Methods in Microfluidic Chips -- 1.2.1 Fluidic Methods -- 1.2.2 Optical Methods -- 1.2.3 Magnetic Methods -- 1.2.4 Acoustic Methods -- 1.2.5 DEP Methods -- 1.3 DEP Microfluidic Chips -- 1.3.1 Theory of DEP -- 1.3.2 DEP Parameter Analysis -- 1.3.3 Advances in DEP-Based Single-Cell Manipulation -- 1.3.4 Electrode Fabrication of DEP Chips -- 1.4 Research Purposes and Significances 1.5 Main Content of the Book -- Thick-Electrode DEP for Single-Cell 3D Rotation -- 2.1 Introduction -- 2.2 Progress in Cell Rotation Manipulation -- 2.3 Thick-Electrode Multi-Electrode Chip Design -- 2.3.1 Principle and Design of Thick-Electrode Multi-Electrode Construction -- 2.3.2 Design and Simulation of 3D Rotational Structure of "Armillary Sphere" -- 2.4 Chip Fabrication -- 2.5 Experimental Setup -- 2.5.1 Experimental Equipment -- 2.5.2 Signal Configuration -- 2.5.3 Experimental Methods -- 2.5.4 3D Rotation Speed Measurement Method -- 2.6 Single-Cell 3D Rotation Experiment 2.6.1 Cell Sample Preparation -- 2.6.2 Cell Capture Validation -- 2.6.3 3D Rotation Experiment -- 2.6.4 Relationship Between Speed and Electrical Signal Parameters -- 2.7 Cellular Electrical Property Analysis -- 2.7.1 Principles of Cellular Electrical Parameter Measurement -- 2.7.2 Key Factors in Electrical Property Analysis -- 2.7.3 Experimental Analysis -- 2.8 Cell 3D Morphology Reconstruction -- 2.8.1 Principle of Reconstruction -- 2.8.2 Analysis of Reconstruction Results -- 2.9 Summary -- Opto-electronic Integration of Thick-Electrode DEP Microfluidic Chip -- 3.1 Introduction 3.2 Progress in Single-Cell Mechanical Property Measurement -- 3.3 Electro-Rotation Chip Function Expansion -- 3.3.1 Electro-Rotation Chip Function Expansion Requirements -- 3.3.2 Principle of Optical Stretcher -- 3.3.3 Step-Stress Analysis of Cell Mechanical Properties -- 3.4 Chip Design and Fabrication -- 3.5 Experimental Setup -- 3.5.1 Experimental Instruments -- 3.5.2 Experimental Steps -- 3.6 Single-Cell Manipulation and Multi-Parameter Analysis Experiments -- 3.6.1 Experimental Demonstration of Filter Mirror -- 3.6.2 Cell Motions when the Fibers Are Misaligned 3.6.3 Single-Cell Dual-Fiber Capture Experiment -- 3.6.4 Single-Cell Optical Stretch Experiment -- 3.6.5 Single-Cell Mechanical Property Measurement -- 3.6.6 Single-Cell Electro-Rotation -- 3.7 Summary -- Summary and Outlook -- 4.1 Main Work -- 4.2 Major Innovations -- 4.3 Future Prospects -- References -- Authors' Biographies -- Blank Page
    Digital Access  Atypon 2020