Electrical Properties of Tissues Quantitative Magnetic Resonance Mapping

This book covers the latest developments in tissue electrical conductivity and current density imaging, increasingly popular as well as challenging applications of MRI. These applications are enabled by the acquisition of high-quality MR phase images. This book provides a practical description of the MRI physics needed to understand and acquire phase images in MRI and the key details required to reconstruct them into conductivity, current density or electric field distributions. Comprehensive details are provided about the electrical properties of biological tissues, computational modeling considerations, experimental methods, construction of non-biological and biological phantoms and MRI pulse sequences. An inclusive review of image reconstruction algorithms, and their potential applications is provided for applications directed at determining current density or electric fields, such as in transcranial DC or AC stimulation techniques; as well as electrical conductivity reconstructions that may be of use in quantitative MRI applications used to detect cancer or other pathologies. This is an excellent book for undergraduate and graduate students beginning to explore phase, current density, and conductivity imaging in MRI, and will also be of great use to researchers interested in the area of MR-based electrical property imaging.

1.       Electromagnetic Properties and the Basis for CDI, MREIT and EPT

2.       Modeling for Electromagnetic Characterization, Prediction and Reconstruction

3.       Magnetic Resonance Imaging Basics

4.       Phantom Construction and Equipment Configurations for Characterizing Electrical Properties using MRI

5.       MR Current Density and MREIT Data Acquisition

6.       Magnetic Resonance Current Density Imaging (MR-CDI)

7.       Magnetic Resonance Electrical Impedance Tomography

8.       Magnetic Resonance Electrical Properties Tomography - MREPT

Rosalind Sadleir is an Associate Professor in the School of Biological Health Systems Engineering at Arizona State University. Her areas of interest range over theoretical electromagnetic analysis and modeling, experimental and clinical measurements and commercial device development. She has been involved in and  made contributions to MREIT in pulse sequence development, finite element modeling, high field imaging, algorithm development and functional imaging.

Dr Atul Singh Minhas is an academic in the School of Engineering at Macquarie University in Sydney (Australia). Dr Minhas has extensive industry experience in the design and development of multiple 3T MRI systems from concept to fully functional imaging devices. He has contributed to the theory and applications of MR-based electrical conductivity imaging techniques at magnetic fields of 3T, 9.4T and 18.8T.