4.6 Article

Novel inductively coupled ear-bars (ICEs) to enhance restored fMRI signal from susceptibility compensation in rats

Journal

CEREBRAL CORTEX
Volume -, Issue -, Pages -

Publisher

OXFORD UNIV PRESS INC
DOI: 10.1093/cercor/bhad479

Keywords

susceptibility artifact; resting-state fMRI; inductive coils; entorhinal cortex; Alzheimer's disease

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This study presents an optimized technique for imaging deep-brain areas in rodents. By introducing baby cream into the middle ear, susceptibility-induced signal losses near the ear cavities and reduced sensitivity from the surface array coil are alleviated. The implementation of inductively coupled ear-bars enhances the detection sensitivity of deep brain regions without modifications to the scanner interface. Using this technique, large-scale networks originating from the entorhinal cortex can be observed, facilitating improved functional magnetic resonance imaging outcomes.
Functional magnetic resonance imaging faces inherent challenges when applied to deep-brain areas in rodents, e.g. entorhinal cortex, due to the signal loss near the ear cavities induced by susceptibility artifacts and reduced sensitivity induced by the long distance from the surface array coil. Given the pivotal roles of deep brain regions in various diseases, optimized imaging techniques are needed. To mitigate susceptibility-induced signal losses, we introduced baby cream into the middle ear. To enhance the detection sensitivity of deep brain regions, we implemented inductively coupled ear-bars, resulting in approximately a 2-fold increase in sensitivity in entorhinal cortex. Notably, the inductively coupled ear-bar can be seamlessly integrated as an add-on device, without necessitating modifications to the scanner interface. To underscore the versatility of inductively coupled ear-bars, we conducted echo-planner imaging-based task functional magnetic resonance imaging in rats modeling Alzheimer's disease. As a proof of concept, we also demonstrated resting-state-functional magnetic resonance imaging connectivity maps originating from the left entorhinal cortex-a central hub for memory and navigation networks-to amygdala hippocampal area, Insular Cortex, Prelimbic Systems, Cingulate Cortex, Secondary Visual Cortex, and Motor Cortex. This work demonstrates an optimized procedure for acquiring large-scale networks emanating from a previously challenging seed region by conventional magnetic resonance imaging detectors, thereby facilitating improved observation of functional magnetic resonance imaging outcomes.

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