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Functional magnetic resonance electrical impedance tomography (f MREIT ) sensitivity analysis using an active bidomain finite‐element model of neural tissue
Author(s) -
Sadleir Rosalind J.,
Fu Fanrui,
Chauhan Munish
Publication year - 2019
Publication title -
magnetic resonance in medicine
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.696
H-Index - 225
eISSN - 1522-2594
pISSN - 0740-3194
DOI - 10.1002/mrm.27351
Subject(s) - electrical impedance tomography , bidomain model , tomography , electrical impedance , nuclear magnetic resonance , neuromodulation , magnetic resonance imaging , materials science , signal (programming language) , noise (video) , electrical resistivity tomography , physics , electrical resistivity and conductivity , biomedical engineering , computer science , stimulation , optics , neuroscience , medicine , radiology , quantum mechanics , artificial intelligence , image (mathematics) , programming language , biology
Purpose A direct method of imaging neural activity was simulated to determine typical signal sizes. Methods An active bidomain finite‐element model was used to estimate approximate perturbations in MR phase data as a result of neural tissue activity, and when an external MR electrical impedance tomography imaging current was added to the region containing neural current sources. Results Modeling‐predicted, activity‐related conductivity changes should produce measurable differential phase signals in practical MR electrical impedance tomography experiments conducted at moderate resolution at noise levels typical of high field systems. The primary dependence of MR electrical impedance tomography phase contrast on membrane conductivity changes, and not source strength, was demonstrated. Conclusion Because the injected imaging current may also affect the level of activity in the tissue of interest, this technique can be used synergistically with neuromodulation techniques such as deep brain stimulation, to examine mechanisms of action.