Abstract 1. Introduction 1.1 Motivation 1.2 Magnetic Techniques in Biology 1.2.1 In vivo Magnetic Techniques 1.2.2 In vitro Magnetic Techniques 1.

3 Single-Cell Analysis Tools 1.3.1 Flow-Based Systems 1.3.2 Array-Based Systems 1.4 Circuit Theory 1.5 Magnetophoretic Circuits 2. Theory 2.

1 Magnetic Materials 2.2 Magnetic Forces 2.3 Computational Methods 2.3.1 Analytical Solution 2.3.2 Finite-Element-Method-Based Analytical Solution 2.4 Particle Trajectory Analysis 3.

Experimental Methods 3.1 Chip Microfabrication 3.2 Chip Surface Functionalization 3.3 Packing Methods 3.3.1 Chamber 3.3.2 Electrical Connections 3.

4 Magnetic Field Apparatus 3.5 Control/Monitor System 3.6 Data and Image Analysis Methods 3.7 Cell Labeling 3.8 Magnetic Nanoparticle Fabrication 4. Particle Transport and Storage with Magnetophoretic Circuits 4.1 Magnetophoretic Circuits in Applied 2D Magnetic Field 4.1.

1 Conductors 4.1.2 Diodes 4.1.3 Capacitors 4.2 Magnetophoretic Circuits in Applied 3D Magnetic Field 4.2.1 Conductors 4.

2.2 Diodes 4.3 Magnetometamaterials 5. Particle Switching with Magnetic Transistors 5.1 Magnetophoretic Transistors in Applied 2D Magnetic Field 5.2 Magnetophoretic Transistors in Applied 3D Magnetic Field 6. Integrated Magnetomicrofluidics Circuits 6.1 Random Access Memory for Organizing Single Beads and Cells 6.

2 Magnetomicrofluidics 6.2.1 Magnetomicrofluidics Circuit Theory 6.2.2 Magnetic Transfer in Magnetomicrofluidics Circuits 6.3 Improving the Microfluidics Fabrication Strategy 6.3.1 Surface Passivation inside Microfluidics Channels 6.

3.2 Fabrication of Magnetomicrofluidics Chips based on Silicon and Glass Anodic Bonding 6.3.3 Interfacing the Microfluidics Chips to the World 6.3.4 Operation of the Magnetomicrofluidics Circuits 7. Biological Applications 7.1 Biocompatibility Tests 7.

1.1 Nonadherent Cells 7.1.2 Adherent Cells 7.2 RNA-Seq Tests 7.3 Drug Screening Tests 8. Final Words and Future Directions.