Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.

Although the spinal cord is the output station of the central motor system, little is known about the relationships between its functional activity and willed movement parameters in humans. We investigated here blood oxygenation level-dependent functional magnetic resonance imaging (fMRI) signal cha...

Full description

Bibliographic Details
Main Authors: Maieron, M, Iannetti, G, Bodurka, J, Tracey, I, Bandettini, P, Porro, C
Format: Journal article
Language:English
Published: 2007
_version_ 1797059846645743616
author Maieron, M
Iannetti, G
Bodurka, J
Tracey, I
Bandettini, P
Porro, C
author_facet Maieron, M
Iannetti, G
Bodurka, J
Tracey, I
Bandettini, P
Porro, C
author_sort Maieron, M
collection OXFORD
description Although the spinal cord is the output station of the central motor system, little is known about the relationships between its functional activity and willed movement parameters in humans. We investigated here blood oxygenation level-dependent functional magnetic resonance imaging (fMRI) signal changes in the cervical spinal cord during a simple finger-to-thumb opposition task in 13 right-handed volunteers, using a dedicated array of 16 receive-only surface coils on a 3 Tesla MRI system. In a first experiment, we found significant fMRI signal increases on both sides of the lower cervical spinal cord while subjects performed the motor task at a comfortable pace (approximately 0.5 Hz) using either hand. Both the spatial extent of movement-related clusters and peak signal increases were significantly higher on the side of the cord ipsilateral to the moving hand than on the contralateral side. Movement-related activity was consistently larger than signal fluctuations during rest. In a second experiment, we recorded spinal cord responses while the same motor sequence was performed using the dominant hand at two different rates (approximately 0.5 or 1 Hz). The intensity but not the spatial extent of the response was larger during higher rates, and it was higher on the ipsilateral side of the cord. Notwithstanding the limited spatial resolving power of the adopted technique, the present results clearly indicate that the finger movement-related fMRI signals recorded from the spinal cord have a neural origin and that as a result of recent technological advances, fMRI can be used to obtain novel and quantitative physiological information on the activity of spinal circuits.
first_indexed 2024-03-06T20:09:57Z
format Journal article
id oxford-uuid:2a376dac-6002-46a2-aad5-23845cc3f391
institution University of Oxford
language English
last_indexed 2024-03-06T20:09:57Z
publishDate 2007
record_format dspace
spelling oxford-uuid:2a376dac-6002-46a2-aad5-23845cc3f3912022-03-26T12:23:47ZFunctional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.Journal articlehttp://purl.org/coar/resource_type/c_dcae04bcuuid:2a376dac-6002-46a2-aad5-23845cc3f391EnglishSymplectic Elements at Oxford2007Maieron, MIannetti, GBodurka, JTracey, IBandettini, PPorro, CAlthough the spinal cord is the output station of the central motor system, little is known about the relationships between its functional activity and willed movement parameters in humans. We investigated here blood oxygenation level-dependent functional magnetic resonance imaging (fMRI) signal changes in the cervical spinal cord during a simple finger-to-thumb opposition task in 13 right-handed volunteers, using a dedicated array of 16 receive-only surface coils on a 3 Tesla MRI system. In a first experiment, we found significant fMRI signal increases on both sides of the lower cervical spinal cord while subjects performed the motor task at a comfortable pace (approximately 0.5 Hz) using either hand. Both the spatial extent of movement-related clusters and peak signal increases were significantly higher on the side of the cord ipsilateral to the moving hand than on the contralateral side. Movement-related activity was consistently larger than signal fluctuations during rest. In a second experiment, we recorded spinal cord responses while the same motor sequence was performed using the dominant hand at two different rates (approximately 0.5 or 1 Hz). The intensity but not the spatial extent of the response was larger during higher rates, and it was higher on the ipsilateral side of the cord. Notwithstanding the limited spatial resolving power of the adopted technique, the present results clearly indicate that the finger movement-related fMRI signals recorded from the spinal cord have a neural origin and that as a result of recent technological advances, fMRI can be used to obtain novel and quantitative physiological information on the activity of spinal circuits.
spellingShingle Maieron, M
Iannetti, G
Bodurka, J
Tracey, I
Bandettini, P
Porro, C
Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title_full Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title_fullStr Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title_full_unstemmed Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title_short Functional responses in the human spinal cord during willed motor actions: evidence for side- and rate-dependent activity.
title_sort functional responses in the human spinal cord during willed motor actions evidence for side and rate dependent activity
work_keys_str_mv AT maieronm functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity
AT iannettig functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity
AT bodurkaj functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity
AT traceyi functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity
AT bandettinip functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity
AT porroc functionalresponsesinthehumanspinalcordduringwilledmotoractionsevidenceforsideandratedependentactivity