Your search keyword '"Visuomotor network"' showing total 5 results

1. Visual feedback alters force control and functional activity in the visuomotor network after stroke

Author

Archer, Derek B, Kang, Nyeonju, Misra, Gaurav, Marble, Shannon, Patten, Carolynn, and Coombes, Stephen A

Subjects

Rehabilitation, Neurosciences, Stroke, Brain Disorders, Physical Rehabilitation, Eye Disease and Disorders of Vision, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Adult, Aged, Brain, Feedback, Sensory, Female, Hand Strength, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Recovery of Function, Stroke Rehabilitation, Force control, Visual feedback, fMRI, Visuomotor network, Ipsilateral M1

Abstract

Modulating visual feedback may be a viable option to improve motor function after stroke, but the neurophysiological basis for this improvement is not clear. Visual gain can be manipulated by increasing or decreasing the spatial amplitude of an error signal. Here, we combined a unilateral visually guided grip force task with functional MRI to understand how changes in the gain of visual feedback alter brain activity in the chronic phase after stroke. Analyses focused on brain activation when force was produced by the most impaired hand of the stroke group as compared to the non-dominant hand of the control group. Our experiment produced three novel results. First, gain-related improvements in force control were associated with an increase in activity in many regions within the visuomotor network in both the stroke and control groups. These regions include the extrastriate visual cortex, inferior parietal lobule, ventral premotor cortex, cerebellum, and supplementary motor area. Second, the stroke group showed gain-related increases in activity in additional regions of lobules VI and VIIb of the ipsilateral cerebellum. Third, relative to the control group, the stroke group showed increased activity in the ipsilateral primary motor cortex, and activity in this region did not vary as a function of visual feedback gain. The visuomotor network, cerebellum, and ipsilateral primary motor cortex have each been targeted in rehabilitation interventions after stroke. Our observations provide new insight into the role these regions play in processing visual gain during a precisely controlled visuomotor task in the chronic phase after stroke.

Published

2018

2. Whole-brain estimates of directed connectivity for human connectomics

Author

Stefan Frässle, Zina M. Manjaly, Cao T. Do, Lars Kasper, Klaas P. Pruessmann, and Klaas E. Stephan

Subjects

Regression dynamic causal modeling, rDCM, Generative model, Effective connectivity, Connectomics, Visuomotor network, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Connectomics is essential for understanding large-scale brain networks but requires that individual connection estimates are neurobiologically interpretable. In particular, a principle of brain organization is that reciprocal connections between cortical areas are functionally asymmetric. This is a challenge for fMRI-based connectomics in humans where only undirected functional connectivity estimates are routinely available. By contrast, whole-brain estimates of effective (directed) connectivity are computationally challenging, and emerging methods require empirical validation.Here, using a motor task at 7T, we demonstrate that a novel generative model can infer known connectivity features in a whole-brain network (>200 regions, >40,000 connections) highly efficiently. Furthermore, graph-theoretical analyses of directed connectivity estimates identify functional roles of motor areas more accurately than undirected functional connectivity estimates. These results, which can be achieved in an entirely unsupervised manner, demonstrate the feasibility of inferring directed connections in whole-brain networks and open new avenues for human connectomics.

Published

2021

3. Visual feedback alters force control and functional activity in the visuomotor network after stroke

Author

Gaurav Misra, Derek B. Archer, Carolynn Patten, Nyeonju Kang, Stephen A. Coombes, and Shannon Marble

Subjects

Male, genetic structures, Brain activity and meditation, lcsh:RC346-429, 0302 clinical medicine, Feedback, Sensory, Visuomotor network, Stroke, Supplementary motor area, Hand Strength, Ipsilateral M1, 05 social sciences, Rehabilitation, fMRI, Stroke Rehabilitation, Brain, Regular Article, Middle Aged, Magnetic Resonance Imaging, medicine.anatomical_structure, Neurology, Neurological, lcsh:R858-859.7, Female, Primary motor cortex, Psychology, Adult, Cognitive Neuroscience, 1.1 Normal biological development and functioning, lcsh:Computer applications to medicine. Medical informatics, 050105 experimental psychology, Feedback, Premotor cortex, 03 medical and health sciences, Underpinning research, medicine, Humans, 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, Eye Disease and Disorders of Vision, lcsh:Neurology. Diseases of the nervous system, Aged, Sensory, Neurosciences, Inferior parietal lobule, Recovery of Function, Neurophysiology, Force control, medicine.disease, Visual feedback, Brain Disorders, Visual cortex, Physical Rehabilitation, Neurology (clinical), Neuroscience, 030217 neurology & neurosurgery

Abstract

Modulating visual feedback may be a viable option to improve motor function after stroke, but the neurophysiological basis for this improvement is not clear. Visual gain can be manipulated by increasing or decreasing the spatial amplitude of an error signal. Here, we combined a unilateral visually guided grip force task with functional MRI to understand how changes in the gain of visual feedback alter brain activity in the chronic phase after stroke. Analyses focused on brain activation when force was produced by the most impaired hand of the stroke group as compared to the non-dominant hand of the control group. Our experiment produced three novel results. First, gain-related improvements in force control were associated with an increase in activity in many regions within the visuomotor network in both the stroke and control groups. These regions include the extrastriate visual cortex, inferior parietal lobule, ventral premotor cortex, cerebellum, and supplementary motor area. Second, the stroke group showed gain-related increases in activity in additional regions of lobules VI and VIIb of the ipsilateral cerebellum. Third, relative to the control group, the stroke group showed increased activity in the ipsilateral primary motor cortex, and activity in this region did not vary as a function of visual feedback gain. The visuomotor network, cerebellum, and ipsilateral primary motor cortex have each been targeted in rehabilitation interventions after stroke. Our observations provide new insight into the role these regions play in processing visual gain during a precisely controlled visuomotor task in the chronic phase after stroke., Highlights • Increased visual gain engaged visuomotor network in stroke and control groups. • Stroke group also showed visual gain effect in cerebellar lobule VI/VIIb. • Stroke group showed increased contralesional M1 activity for all visual gain levels.

Published

2018

4. Whole-brain estimates of directed connectivity for human connectomics.

Author

Frässle, Stefan, Manjaly, Zina M., Do, Cao T., Kasper, Lars, Pruessmann, Klaas P., and Stephan, Klaas E.

Subjects

*FUNCTIONAL connectivity, *ESTIMATES, *HUMAN beings

Abstract

Connectomics is essential for understanding large-scale brain networks but requires that individual connection estimates are neurobiologically interpretable. In particular, a principle of brain organization is that reciprocal connections between cortical areas are functionally asymmetric. This is a challenge for fMRI-based connectomics in humans where only undirected functional connectivity estimates are routinely available. By contrast, whole-brain estimates of effective (directed) connectivity are computationally challenging, and emerging methods require empirical validation. Here, using a motor task at 7T, we demonstrate that a novel generative model can infer known connectivity features in a whole-brain network (>200 regions, >40,000 connections) highly efficiently. Furthermore, graph-theoretical analyses of directed connectivity estimates identify functional roles of motor areas more accurately than undirected functional connectivity estimates. These results, which can be achieved in an entirely unsupervised manner, demonstrate the feasibility of inferring directed connections in whole-brain networks and open new avenues for human connectomics. [ABSTRACT FROM AUTHOR]

Published

2021

5. Visual feedback alters force control and functional activity in the visuomotor network after stroke.

Author

Archer DB, Kang N, Misra G, Marble S, Patten C, and Coombes SA

Subjects

Adult, Aged, Female, Hand Strength physiology, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Brain physiopathology, Feedback, Sensory physiology, Recovery of Function, Stroke physiopathology, Stroke Rehabilitation methods

Abstract

Modulating visual feedback may be a viable option to improve motor function after stroke, but the neurophysiological basis for this improvement is not clear. Visual gain can be manipulated by increasing or decreasing the spatial amplitude of an error signal. Here, we combined a unilateral visually guided grip force task with functional MRI to understand how changes in the gain of visual feedback alter brain activity in the chronic phase after stroke. Analyses focused on brain activation when force was produced by the most impaired hand of the stroke group as compared to the non-dominant hand of the control group. Our experiment produced three novel results. First, gain-related improvements in force control were associated with an increase in activity in many regions within the visuomotor network in both the stroke and control groups. These regions include the extrastriate visual cortex, inferior parietal lobule, ventral premotor cortex, cerebellum, and supplementary motor area. Second, the stroke group showed gain-related increases in activity in additional regions of lobules VI and VIIb of the ipsilateral cerebellum. Third, relative to the control group, the stroke group showed increased activity in the ipsilateral primary motor cortex, and activity in this region did not vary as a function of visual feedback gain. The visuomotor network, cerebellum, and ipsilateral primary motor cortex have each been targeted in rehabilitation interventions after stroke. Our observations provide new insight into the role these regions play in processing visual gain during a precisely controlled visuomotor task in the chronic phase after stroke.

Published

2017