Implications of the Putamen in Pain and Motor Deficits in Complex Regional Pain Syndrome

Overview

Journal Pain

Specialties Neurology
Psychiatry

Date 2019 Nov 7

PMID 31693538

Citations 27

Authors

Monica Azqueta-Gavaldon

Andrew M Youssef

Claudia Storz

Jordan Lemme

Heike Schulte-Gocking

Lino Becerra

Shahnaz C Azad

Anselm Reiners

Birgit Ertl-Wagner

David Borsook

Jaymin Upadhyay

Eduard Kraft

Affiliations

Soon will be listed here.

Abstract

Complex regional pain syndrome (CRPS) develops after-limb injury, with persistent pain and deficits in movement frequently co-occurring. The striatum is critical for mediating multiple mechanisms that are often aberrant in CRPS, which includes sensory and pain processing, motor function, and goal-directed behaviors associated with movement. Yet, much remains unknown with regards to the morphological and functional properties of the striatum and its subregions in this disease. Thus, we investigated 20 patients (15 female, age 58 ± 9 years, right-handed) diagnosed with chronic (6+ months of pain duration) CRPS in the right hand and 20 matched, healthy controls with anatomical and resting-state, functional magnetic resonance imaging. In addition, a comprehensive clinical and behavioral evaluation was performed, where each participant's pain, motor function, and medical history were assessed. Complex regional pain syndrome patients harbored significant abnormalities in hand coordination, dexterity, and strength. These clinical pain- and movement-related findings in CRPS patients were concomitant with bilateral decreases in gray matter density in the putamen as well as functional connectivity increases and decreases among the putamen and pre-/postcentral gyri and cerebellum, respectively. Importantly, higher levels of clinical pain and motor impairment were associated with increased putamen-pre-/postcentral gyri functional connectivity strengths. Collectively, these findings suggest that putaminal alterations, specifically the functional interactions with sensorimotor structures, may underpin clinical pain and motor impairment in chronic CRPS patients.

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