Atrophy of Cerebellar Lobule VI and Primary Motor Cortex in Cervical Dystonia - a Region of Interest-based Study

Overview

Journal J Neural Transm (Vienna)

Specialties Neurology
Physiology

Date 2024 Oct 6

PMID 39370479

Authors

Kai Grimm

Fatemeh Sadeghi

Gerhard Schon

Abdullah Okar

Mathias Gelderblom

Robert Schulz

Simone Zittel

Affiliations

Soon will be listed here.

Abstract

Background: Recently, a network model of cervical dystonia (CD) has been adopted that implicates nodes and pathways involving cerebellar, basal-ganglia and cortico-cortical connections. Although functional changes in the cerebello-thalamo-cortical network in dystonia have been reported in several studies, structural information of this network remain sparse.

Objective: To characterize the structural properties of the cerebellar motor network in isolated CD patients. This includes cerebellar lobules involved in motor processing, the dentate nucleus (DN), the thalamus, and the primary motor cortex (M1).

Methods: Magnetic resonance imaging data of 18 CD patients and 18 healthy control subjects were acquired. In CD patients, the motor part of the Toronto Western Spasmodic Torticollis Rating Scale was assessed to evaluate motor symptom severity. The volume of cerebellar lobules I-VI and VIII, the DN and thalamus, and the cortical thickness (CT) of M1 were determined for a region of interest (ROI)-based quantitative analysis. Volumes/CT of these ROIs were compared between groups and associated with motor symptom severity in patients.

Results: The volume of lobule VI and the CT of M1 were reduced in CD patients. The volumes of the other ROIs were not different between groups. No association was identified between the structural properties of lobule VI or M1 and the severity of CD motor symptoms.

Conclusion: Atrophy within the cerebellum and M1 contributes to CD's complex motor network pathology. Further investigations are needed to ascertain the mechanisms underlying the local volume loss.

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