Ayushe A. Sharma scite author profile

Background: Magnetic resonance spectroscopic imaging (MRSI) is a neuroimaging technique that may be useful for non-invasive mapping of brain temperature (i.e., thermometry) over a large brain volume. To date, intra-subject reproducibility of MRSI-based brain temperature (MRSI-t) has not been investigated. The objective of this repeated measures MRSI-t study was to establish intra-subject reproducibility and repeatability of brain temperature, as well as typical brain temperature range.Methods: Healthy participants aged 23–46 years (N = 18; 7 females) were scanned at two time points ~12-weeks apart. Volumetric MRSI data were processed by reconstructing metabolite and water images using parametric spectral analysis. Brain temperature was derived using the frequency difference between water and creatine (TCRE) for 47 regions of interest (ROIs) delineated by the modified Automated Anatomical Labeling (AAL) atlas. Reproducibility was measured using the coefficient of variation for repeated measures (COVrep), and repeatability was determined using the standard error of measurement (SEM). For each region, the upper and lower bounds of Minimal Detectable Change (MDC) were established to characterize the typical range of TCRE values.Results: The mean global brain temperature over all subjects was 37.2°C with spatial variations across ROIs. There was a significant main effect for time [F(1, 1,591) = 37.0, p < 0.0001] and for brain region [F(46, 1,591) = 2.66, p < 0.0001]. The time*brain region interaction was not significant [F(46, 1,591) = 0.80, p = 0.83]. Participants' TCRE was stable for each ROI across both time points, with ROIs' COVrep ranging from 0.81 to 3.08% (mean COVrep = 1.92%); majority of ROIs had a COVrep <2.0%.Conclusions: Brain temperature measurements were highly consistent between both time points, indicating high reproducibility and repeatability of MRSI-t. MRSI-t may be a promising diagnostic, prognostic, and therapeutic tool for non-invasively monitoring brain temperature changes in health and disease. However, further studies of healthy participants with larger sample size(s) and numerous repeated acquisitions are imperative for establishing a reference range of typical brain TCRE, as well as the threshold above which TCRE is likely pathological.

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In Vivo Imaging of Neuroinflammatory Targets in Treatment-Resistant Epilepsy

Sharma

Szaflarski

2020

Curr Neurol Neurosci Rep

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Neuroinflammation as a pathophysiological factor in the development and maintenance of functional seizures: A hypothesis

Sharma

Szaflarski

2021

Epilepsy & Behavior Reports

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Highlights Early-life stress may be a priming neuroinflammatory factor for later development of FS. Secondary trauma has emerged as an important predisposing factor for FS initiation. We propose an explanatory, two-hit hypothesis for FS development. The proposed hypothesis is based on findings from neuroimaging and biomarker studies.

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Regional brain atrophy and aberrant cortical folding relate to anxiety and depression in patients with traumatic brain injury and psychogenic nonepileptic seizures

et al. 2021

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Objective: Psychogenic nonepileptic seizures (PNES) are characterized by multifocal and global abnormalities in brain function and connectivity. Only a few studies have examined neuroanatomic correlates of PNES. Traumatic brain injury (TBI) is reported in 83% of patients with PNES and may be a key component of PNES pathophysiology. In this study, we included patients with TBI preceding the onset of PNES (TBI-PNES) and TBI without PNES (TBI-only) to identify neuromorphometric abnormalities associated with PNES. Methods: Adults diagnosed with TBI-PNES (n = 62) or TBI-only (n = 59) completed psychological questionnaires and underwent 3-T magnetic resonance imaging. Imaging data were analyzed by voxel-and surface-based morphometry. Voxelwise general linear models computed group differences in gray matter volume, cortical thickness, sulcal depth, fractal dimension (FDf), and gyrification. Statistical models were assessed with permutation-based testing at 5000 iterations with the Threshold-Free Cluster Enhancement toolbox. Logarithmically scaled p-values corrected for multiple comparisons using familywise error were considered significant at p < .05. Post hoc analyses determined the association between structural and psychological measures (p < .05). Results: TBI-PNES participants demonstrated atrophy of the left inferior frontal gyrus and the right cerebellum VIII. Relative to TBI-only, TBI-PNES participants had decreased FDf in the right superior parietal gyrus and decreased sulcal depth in the left insular cortex. Significant clusters were positively correlated with global assessment of functioning scores, and demonstrated varying negative associations with measures of anxiety, depression, somatization, and global severity of symptoms. Significance: The diagnosis of PNES was associated with brain atrophy and reduced cortical folding in regions implicated in emotion processing, regulation, and response inhibition. Cortical folds primarily develop during the third trimester of pregnancy and remain relatively constant throughout the remainder of

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Concordance between focal brain temperature elevations and focal edema in temporal lobe epilepsy

et al. 2023

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Objective: Neuroinflammation (NI) is a pathophysiological factor in many neurological disorders, including epilepsy. Because NI causes microstructural tissue damage that worsens with increasing brain temperature, abnormally elevated brain temperatures may be a surrogate measure of the biochemical consequences of NI. This study investigated whether patients with temporal lobe epilepsy (TLE) have abnormal brain temperature elevations (T CRE ) in seizure-producing regions that show evidence of edema and/or microstructural damage. Methods: Twenty adults with TLE and 20 healthy controls (HCs) were scanned at 3-Tesla. T CRE in each voxel was calculated (T CRE = −102.61(Δ H20−CRE) + 206.1°C) by non-invasive volumetric magnetic resonance spectroscopic imaging and thermometry (MRSI-t). Multi-shell diffusion images were processed by neurite orientation and density imaging (NODDI). Voxel wise two-sample t tests computed group differences in imaging data. Multimodal data fusion (joint independent component analysis [ICA]) determined the spatial coupling of T CRE with NODDI.Results: T CRE analyses showed that, compared to HCs, TLEs had higher T CRE (p < .001). NODDI analyses showed increased extracellular free water (p FWE < 0.05) in the medial temporal lobes, with the most pronounced increases ipsilateral to seizure onset. TLEs also had increased angular dispersion of neurites (p < .001) and decreased neurite density (p FWE <0.05) in the ictal-onset medial temporal lobe, as well as more widespread, bilateral patterns of abnormalities.Focal increases in T CRE were spatially concordant with increased free water in the left inferior and middle temporal gyri and the associated cortex. In TLE, ICA loadings extracted from this region of overlap were associated with greater mood disturbance (r = .34, p = .02) and higher depression scores (r = .37, p = .009). Significance:The spatial concordance between focal T CRE elevations and edema in TLE supports the notion that brain thermometry visualizes the correlates of focal NI. MRSI-t-based T CRE elevations may, therefore, be a useful biomarker for identifying seizure-producing tissue in patients with focal epilepsy caused by brain damage.

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Ayushe A. Sharma

Repeatability and Reproducibility of in-vivo Brain Temperature Measurements

In Vivo Imaging of Neuroinflammatory Targets in Treatment-Resistant Epilepsy

Neuroinflammation as a pathophysiological factor in the development and maintenance of functional seizures: A hypothesis

Regional brain atrophy and aberrant cortical folding relate to anxiety and depression in patients with traumatic brain injury and psychogenic nonepileptic seizures

Concordance between focal brain temperature elevations and focal edema in temporal lobe epilepsy

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