TY - JOUR
T1 - Clinical Applications of Electrical Conductivity Imaging Using MRI
AU - Mandija, Stefano
AU - Tha, Khin Khin
AU - Katoch, Nitish
AU - Göksu, Cihan
AU - Katscher, Ulrich
AU - Sadleir, Rosalind
AU - Jung, Kyu-Jin
AU - Luo, Jierong
AU - Giannakopoulos, Ilias I
AU - Kim, Dong-Hyun
AU - Shmueli, Karin
AU - Lattanzi, Riccardo
AU - Ider, Yusuf Ziya
AU - Thielscher, Axel
AU - van den Berg, Cornelis
N1 - © 2026 The Author(s). Journal of Magnetic Resonance Imaging published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.
PY - 2026/3/7
Y1 - 2026/3/7
N2 - Magnetic resonance imaging (MRI) has emerged as a noninvasive technique for probing the electrical properties of biological tissues: electrical conductivity and relative permittivity. This review focuses on the electrical conductivity and provides a comprehensive overview of applications across both low- and high-frequency regimes. At low frequencies (below 1 MHz), conductivity mapping primarily reflects tissue microstructure and ionic composition. In contrast, at high frequencies (around 100 MHz), tissue conductivity primarily reflects ionic composition. First, we summarize the theoretical foundations, technical developments, and reconstruction algorithms that underpin conductivity imaging, highlighting advances in magnetic resonance electrical impedance tomography, current density imaging, and electrical properties tomography. The main part of the article discusses preclinical and clinical applications, demonstrating the potential and possible roles of conductivity imaging in clinical settings, along with current challenges and emerging applications. Finally, we outline future directions toward integrating conductivity imaging into routine MRI protocols, with the potential to enhance diagnostic precision and therapeutic monitoring. EVIDENCE LEVEL: 1. TECHNICAL EFFICACY: Stage 3.
AB - Magnetic resonance imaging (MRI) has emerged as a noninvasive technique for probing the electrical properties of biological tissues: electrical conductivity and relative permittivity. This review focuses on the electrical conductivity and provides a comprehensive overview of applications across both low- and high-frequency regimes. At low frequencies (below 1 MHz), conductivity mapping primarily reflects tissue microstructure and ionic composition. In contrast, at high frequencies (around 100 MHz), tissue conductivity primarily reflects ionic composition. First, we summarize the theoretical foundations, technical developments, and reconstruction algorithms that underpin conductivity imaging, highlighting advances in magnetic resonance electrical impedance tomography, current density imaging, and electrical properties tomography. The main part of the article discusses preclinical and clinical applications, demonstrating the potential and possible roles of conductivity imaging in clinical settings, along with current challenges and emerging applications. Finally, we outline future directions toward integrating conductivity imaging into routine MRI protocols, with the potential to enhance diagnostic precision and therapeutic monitoring. EVIDENCE LEVEL: 1. TECHNICAL EFFICACY: Stage 3.
KW - conductivity MRI
KW - current density imaging
KW - electrical impedance tomography
KW - electrical properties tomography
KW - MR-EPT
UR - https://www.scopus.com/pages/publications/105032134681
U2 - 10.1002/jmri.70279
DO - 10.1002/jmri.70279
M3 - Review
C2 - 41795132
SN - 1053-1807
SP - 1224
EP - 1245
JO - Journal of magnetic resonance imaging : JMRI
JF - Journal of magnetic resonance imaging : JMRI
ER -