Disentangling motor planning and motor execution in unmedicated de novo Parkinson's disease patients: An fMRI study

Disentangling motor planning and motor execution in unmedicated de novo Parkinson's disease patients: An fMRI study

Many studies have used functional magnetic resonance imaging to unravel the neuronal underpinnings of motor system abnormalities in Parkinson's disease, indicating functional inhibition at the level of basal ganglia-thalamo-cortical motor networks. The study aim was to extend the characterizati...

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Bibliographic Details
Published in:NeuroImage clinical Vol. 22; p. 101784
Main Authors: Martin, Jason A, Zimmermann, Nadine, Scheef, Lukas, Jankowski, Jakob, Paus, Sebastian, Schild, Hans H, Klockgether, Thomas, Boecker, Henning
Format: Journal Article
Language:English
Published: Netherlands Elsevier 01-01-2019
Subjects:
Adult
Cerebellum - diagnostic imaging
Cerebellum - physiopathology
Female
Fingers - physiology
Functional Neuroimaging
Humans
Magnetic Resonance Imaging
Male
Middle Aged
Motor Activity - physiology
Motor Cortex - diagnostic imaging
Motor Cortex - physiopathology
Nerve Net - diagnostic imaging
Nerve Net - physiopathology
Parkinson Disease - diagnostic imaging
Parkinson Disease - physiopathology
Prefrontal Cortex - diagnostic imaging
Prefrontal Cortex - physiopathology
Putamen - diagnostic imaging
Putamen - physiopathology
Regular
Serial Learning - physiology
Basal ganglia
Self-initiated movement
Functional MRI
Motor networks
Parkinson's disease
Compensation
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Summary:Many studies have used functional magnetic resonance imaging to unravel the neuronal underpinnings of motor system abnormalities in Parkinson's disease, indicating functional inhibition at the level of basal ganglia-thalamo-cortical motor networks. The study aim was to extend the characterization of functional motor changes in Parkinson's Disease by dissociating between two phases of action (i.e. motor planning and motor execution) during an automated unilateral finger movement sequence with the left and right hand, separately. In essence, we wished to identify neuronal dysfunction and potential neuronal compensation before (planning) and during (execution) automated sequential motor behavior in unmedicated early stage Parkinson's Disease patients. Twenty-two Parkinson's Disease patients (14 males; 53 ± 11 years; Hoehn and Yahr score 1.4 ± 0.6; UPDRS (part 3) motor score 16 ± 6) and 22 healthy controls (14 males; 49 ± 12 years) performed a pre-learnt four finger sequence (index, ring, middle and little finger, in order), either self-initiated (FREE) or externally triggered (REACT), within an 8-second time window. Findings were most pronounced during FREE with the clinically most affected side, where motor execution revealed significant underactivity of contralateral primary motor cortex, contralateral posterior putamen (sensorimotor territory), ipsilateral anterior cerebellum / cerebellar vermis, along with underactivity in supplementary motor area (based on ROI analyses only), corroborating previous findings in Parkinson's Disease. During motor planning, Parkinson's Disease patients showed a significant relative overactivity in dorsolateral prefrontal cortex (DLPFC), suggesting a compensatory overactivity. To a variable extent this relative overactivity in the DLPFC went along with a relative overactivity in the precuneus and the ipsilateral anterior cerebellum/cerebellar vermis Our study illustrates that a refined view of disturbances in motor function and compensatory processes can be gained from experimental designs that try to dissociate motor planning from motor execution, emphasizing that compensatory mechanisms are triggered in Parkinson's Disease when voluntary movements are conceptualized for action.
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ISSN:2213-1582
2213-1582
DOI:10.1016/j.nicl.2019.101784