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- Title
Improving sensitivity, specificity, and reproducibility of individual brainstem activation.
- Authors
Matt, Eva; Fischmeister, Florian Ph. S.; Amini, Ahmad; Robinson, Simon D.; Weber, Alexandra; Foki, Thomas; Gizewski, Elke R.; Beisteiner, Roland
- Abstract
Functional imaging of the brainstem may open new avenues for clinical diagnostics. However, for reliable assessments of brainstem activation, further efforts improving signal quality are needed. Six healthy subjects performed four repeated functional magnetic resonance imaging (fMRI) sessions on different days with jaw clenching as a motor task to elicit activation in the trigeminal motor nucleus. Functional images were acquired with a 7 T MR scanner using an optimized multiband EPI sequence. Activation measures in the trigeminal nucleus and a control region were assessed using different physiological noise correction methods (aCompCor and RETROICOR-based approaches with variable numbers of regressors) combined with cerebrospinal fluid or brainstem masking. Receiver-operating characteristic analyses accounting for sensitivity and specificity, activation overlap analyses to estimate the reproducibility between sessions, and intraclass correlation analyses (ICC) for testing reliability between subjects and sessions were used to systematically compare the physiological noise correction approaches. Masking the brainstem led to increased activation in the target ROI and resulted in higher values for the area under the curve (AUC) as a combined measure for sensitivity and specificity. With the highest values for AUC, activation overlap, and ICC, the most favorable physiological noise correction method was to control for the cerebrospinal fluid time series (aCompCor with one regressor). Brainstem motor nuclei activation can be reliably identified using high-field fMRI with optimized acquisition and processing strategies—even on single-subject level. Applying specific physiological noise correction methods improves reproducibility and reliability of brainstem activation encouraging future clinical applications.
- Subjects
FUNCTIONAL magnetic resonance imaging; INTRACLASS correlation; CEREBROSPINAL fluid
- Publication
Brain Structure & Function, 2019, Vol 224, Issue 8, p2823
- ISSN
1863-2653
- Publication type
Article
- DOI
10.1007/s00429-019-01936-3