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Table of contents
Chapter 1 Biological fundamental concepts and electromagnetic hyperthermia
1.1 Biological fundamental concepts
1.1.1 Biological cells
1.1.2 Biological tissues
1.1.3 Neoplasm, tumor and cancer
1.2 Electromagnetic hyperthermia
1.2.1 Electromagnetic therapy
1.2.2 Effect of heat injury on biological tissues
1.2.3 Hyperthermia
1.2.4 Hyperthermia techniques
1.2.5 Thermal ablation
1.2.6 Physical characteristics of microwave hyperthermia
1.2.7 Current development of microwave hyperthermia
Chapter 2 Dielectric characterizations of biological tissues in microwave frequencies
2.1 Introduction
2.2 Permittivity
2.3 Dielectric mechanisms
2.4 Relaxation time
2.5 Debye relation
2.6 Cole–Cole diagram
2.7 Measurement techniques of dielectric characterizations
2.8 Models of the Open–Ended Coaxial Probe
2.9 Dielectric characterization measurement system
2.10 Dielectric characterization measurement by 1st method: coaxial probe
2.10.1 Electromagnetic therapy
2.10.2 Electromagnetic therapy
2.11 Dielectric characterization measurement by 2nd method: coaxial cable
2.11.1 Electromagnetic therapy
2.11.2 Electromagnetic therapy
2.12 Comparisons
2.13 Experimental tolerance
2.14 Conclusion
Chapter 3 Microwave hyperthermia instrumentation and ex vivo experiments on the biological tissues
3.1 Introduction
3.2 Microwave hyperthermia instrumentation system
3.3 Microwave hyperthermia experiment procedure
3.4 Experimental results 1st method: coaxial cable RG393
3.5 Experimental results 2nd method: Warrior cable
3.6 Comparisons
3.7 Conclusion
Chapter 4 COMSOL Multiphysics simulation of ex vivo microwave hyperthermia instrumentation on the biological tissues
4.1 Introduction
4.2 Introduction of COMSOL Multiphysics
4.3 Heating model for ex vivo microwave hyperthermia simulation
4.4 Design of microwave hyperthermia system
4.5 Microwave hyperthermia simulation protocol
4.6 Ex vivo microwave hyperthermia simulation results
4.7 Parameters’ Influences on the simulation
4.8 Discussions
4.9 Comparisons between experimental results and simulations
4.10 Conclusion
