Stimulus-induced Rotary Saturation Imaging of Visually Evoked Response: A Pilot Study

Overview

Journal NMR Biomed

Publisher Wiley

Date 2024 Nov 5

PMID 39497348

Authors

Milena Capiglioni

Roland Beisteiner

Pedro Lima Cardoso

Federico Turco

Baudouin Jin

Claus Kiefer

Simon Daniel Robinson

Andrea Federspiel

Siegfried Trattnig

Roland Wiest

Affiliations

Soon will be listed here.

Abstract

Spin-lock (SL) pulses have been proposed to directly detect neuronal activity otherwise inaccessible through standard functional magnetic resonance imaging. However, the practical limits of this technique remain unexplored. Key challenges in SL-based detection include ultra-weak signal variations, sensitivity to magnetic field inhomogeneities, and potential contamination from blood oxygen level-dependent effects, all of which hinder the reliable isolation of neuronal signals. This pilot study evaluates the performance of the stimulus-induced rotary saturation (SIRS) technique to map visual stimulation response in the human cortex. A rotary echo spin-lock (RESL) preparation followed by a 2D echo planar imaging readout was used to investigate 12 healthy subjects at rest and during continuous exposure to 8 Hz flickering light. The SL amplitude was fixed to the target neuroelectric oscillations at that frequency. The signal variance was used as contrast metric, and two alternative post-processing pipelines (regression-filtering-rectification and normalized subtraction) were statistically evaluated. Higher variance in the SL signal was detected in four of the 12 subjects. Although group-level analysis indicated activation in the occipital pole, analysis of variance revealed that this difference was not statistically significant, highlighting the need for comparable control measures and more robust preparations. Further optimization in sensitivity and robustness is required to noninvasively detect physiological neuroelectric activity in the human brain.

Citing Articles

Stimulus-induced rotary saturation imaging of visually evoked response: A pilot study.

Capiglioni M, Beisteiner R, Cardoso P, Turco F, Jin B, Kiefer C NMR Biomed. 2024; 38(1):e5280.

PMID: 39497348 PMC: 11602267. DOI: 10.1002/nbm.5280.

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