Levodopa Is a Double-Edged Sword for Balance and Gait in People With Parkinson's Disease

Overview

Journal Mov Disord

Date 2015 Jun 23

PMID 26095928

Citations 181

Authors

Carolin Curtze

John G Nutt

Patricia Carlson-Kuhta

Martina Mancini

Fay B Horak

Affiliations

Soon will be listed here.

Abstract

Background: The effects of levodopa on balance and gait function in people with Parkinson's disease (PD) is controversial. This study compared the relative responsiveness to l-dopa on six domains of balance and gait: postural sway in stance; gait pace; dynamic stability; gait initiation; arm swing; and turning in people with mild and severe PD, with and without dyskinesia.

Methods: We studied 104 subjects with idiopathic PD (H & Y II [n = 52] and III-IV [n = 52]) and 64 age-matched controls. Subjects performed a mobility task in the practical off state and on l-dopa: standing quietly for 30 seconds, initiating gait, walking 7 meters, and turning 180 degrees. Thirty-four measures of mobility were computed from inertial sensors. Standardized response means were used to determine relative responsiveness to l-dopa.

Results: The largest improvements with l-dopa were found for arm swing and pace-related gait measures. Gait dynamic stability was unaffected by PD and not responsive to l-dopa. l-dopa reduced turning duration, but only in subjects with severe PD. In contrast to gait, postural sway in quiet standing increased with l-dopa, especially in the more severely affected subjects. The increase in postural sway, as well as decrease in turning duration and exaggerated arm swing with l-dopa was observed only for subjects with dyskinesia at the time of testing.

Conclusions: The observed spectrum of l-dopa responsiveness in balance and gait measures suggests that multiple neural circuits control balance and gait. Many of the negative effects of l-dopa may be directly or indirectly caused by dyskinesia.

Citing Articles

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Sway frequencies may predict postural instability in Parkinson's disease: a novel convolutional neural network approach.

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Cani I, DAscanio I, Baldelli L, Lopane G, Ranciati S, Mantovani P Eur J Neurol. 2024; 32(1):e16580.

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