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Your search keyword '"Jäger, Anna-Thekla P."' showing total 7 results
Start Over Author "Jäger, Anna-Thekla P."
7 results on '"Jäger, Anna-Thekla P."'

1. Modeling venous bias in resting state functional MRI metrics

Author

Huck, Julia, Jäger, Anna‐Thekla, Schneider, Uta, Grahl, Sophia, Fan, Audrey P, Tardif, Christine, Villringer, Arno, Bazin, Pierre‐Louis, Steele, Christopher J, and Gauthier, Claudine J

Subjects
Bioengineering, Biomedical Imaging, bias, rsfMRI, ultra-high field MRI, vasculature, Neurosciences, Cognitive Sciences, Experimental Psychology
Abstract

Resting-state (rs) functional magnetic resonance imaging (fMRI) is used to detect low-frequency fluctuations in the blood oxygen-level dependent (BOLD) signal across brain regions. Correlations between temporal BOLD signal fluctuations are commonly used to infer functional connectivity. However, because BOLD is based on the dilution of deoxyhemoglobin, it is sensitive to veins of all sizes, and its amplitude is biased by draining veins. These biases affect local BOLD signal location and amplitude, and may also influence BOLD-derived connectivity measures, but the magnitude of this venous bias and its relation to vein size and proximity is unknown. Here, veins were identified using high-resolution quantitative susceptibility maps and utilized in a biophysical model to investigate systematic venous biases on common local rsfMRI-derived measures. Specifically, we studied the impact of vein diameter and distance to veins on the amplitude of low-frequency fluctuations (ALFF), fractional ALFF (fALFF), Hurst exponent (HE), regional homogeneity (ReHo), and eigenvector centrality values in the grey matter. Values were higher across all distances in smaller veins, and decreased with increasing vein diameter. Additionally, rsfMRI values associated with larger veins decrease with increasing distance from the veins. ALFF and ReHo were the most biased by veins, while HE and fALFF exhibited the smallest bias. Across all metrics, the amplitude of the bias was limited in voxel-wise data, confirming that venous structure is not the dominant source of contrast in these rsfMRI metrics. Finally, the models presented can be used to correct this venous bias in rsfMRI metrics.

Published
2023

4. Decreased long‐range temporal correlations in the resting‐state functional magentic resonance imaging blood‐oxygen‐level‐dependent signal reflect motor sequence learning up to 2 weeks following training

Author

Jäger, Anna‐Thekla P., primary, Bailey, Alexander, additional, Huntenburg, Julia M., additional, Tardif, Christine L., additional, Villringer, Arno, additional, Gauthier, Claudine J., additional, Nikulin, Vadim, additional, Bazin, Pierre‐Louis, additional, and Steele, Christopher J., additional

Published
2023
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6. Decreased long‐range temporal correlations in the resting‐state functional magnetic resonance imaging blood‐oxygen‐level‐dependent signal reflect motor sequence learning up to 2 weeks following training.

Author

Jäger, Anna‐Thekla P., Bailey, Alexander, Huntenburg, Julia M., Tardif, Christine L., Villringer, Arno, Gauthier, Claudine J., Nikulin, Vadim, Bazin, Pierre‐Louis, and Steele, Christopher J.

Subjects
*FUNCTIONAL magnetic resonance imaging, *MOTOR learning, *MOTOR cortex, *PREMOTOR cortex, *HEBBIAN memory, *IMPLICIT learning, *OXYGEN consumption
Abstract

Decreased long‐range temporal correlations (LRTC) in brain signals can be used to measure cognitive effort during task execution. Here, we examined how learning a motor sequence affects long‐range temporal memory within resting‐state functional magnetic resonance imaging signal. Using the Hurst exponent (HE), we estimated voxel‐wise LRTC and assessed changes over 5 consecutive days of training, followed by a retention scan 12 days later. The experimental group learned a complex visuomotor sequence while a complementary control group performed tightly matched movements. An interaction analysis revealed that HE decreases were specific to the complex sequence and occurred in well‐known motor sequence learning associated regions including left supplementary motor area, left premotor cortex, left M1, left pars opercularis, bilateral thalamus, and right striatum. Five regions exhibited moderate to strong negative correlations with overall behavioral performance improvements. Following learning, HE values returned to pretraining levels in some regions, whereas in others, they remained decreased even 2 weeks after training. Our study presents new evidence of HE's possible relevance for functional plasticity during the resting‐state and suggests that a cortical subset of sequence‐specific regions may continue to represent a functional signature of learning reflected in decreased long‐range temporal dependence after a period of inactivity. [ABSTRACT FROM AUTHOR]

Published
2024
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