Training in Ataxia - Individuals With Degenerative Cerebellar Diseases

Columbia University64 enrolled

Overview

Balance and aerobic training show promise as treatments for degenerative cerebellar diseases, but the neural effects of both training methods are unknown. The goal of this project is to evaluate how each training method impacts the brain, and particularly, the degenerating cerebellum. Various neuroimaging techniques will be used to accomplish this goal and test the hypothesis that balance training impacts brain structures outside the cerebellum whereas aerobic training causes more neuroplastic changes within the cerebellum.

Degenerative cerebellar diseases are a group of disorders that cause severe disability and can be fatal. There are currently no known disease-modifying treatments available for use, and there is a critical need to find treatments that slow disease progression and allow affected individuals to live more functional lives. Balance and aerobic training show promise as treatments for degenerative cerebellar diseases, but the neural effects of both training methods have not been thoroughly investigated. It is crucial to understand how the training impacts the brain, and particularly the cerebellum, in order to determine if one training method is better at slowing disease progression than the other. The goal of this proposal is to compare the neural effects of balance versus aerobic training in individuals with degenerative cerebellar diseases. The investigator hypothesizes that aerobic training causes neuroplastic changes within the cerebellum whereas balance training causes improvements for people with cerebellar degeneration by impacting brain structures outside the cerebellum. If this hypothesis is true, aerobic training may have more influence on disease progression than balance training as it directly impacts the cerebellum. To investigate the hypothesis, various neuroimaging techniques will be used. In AIM 1, the investigator will compare cerebellar volume before and after the participants perform either 6-months of balance or aerobic training. In AIM 2, the investigator will investigate whether neural changes have clinical significance by correlating cerebellar volume changes with clinical measures of ataxia. Finally, for AIM 3, the investigator will use diffusion tensor imaging and resting state fMRI scans to examine how both training methods impact cerebellar microstructure and functional cerebellar connections. The investigator hopes that a detailed understanding of how each training method impacts the cerebellum will lead to more targeted training regimens with the goal of slowing disease progression of these devastating diseases.

Study Type

INTERVENTIONAL

Allocation

RANDOMIZED

Purpose

TREATMENT

Masking

DOUBLE

Enrollment

Conditions

Cerebellar Ataxia

Interventions

Aerobic TrainingBEHAVIORAL

Aerobic training on stationary bike 5x a week for 30 minutes a day.

Balance TrainingBEHAVIORAL

Balance training 5x a week for 30 minutes as instructed by a therapist. Standard of care.

Eligibility

Sex: ALLMin age: 18 Years

Medical Language ↔ Plain English

Inclusion Criteria: * Diagnosed with spinocerebellar ataxia * Cerebellar atrophy on MRI * Prevalence of ataxia on clinical exam * Ability to safely ride a stationary exercise bike Exclusion Criteria: * Other neurologic conditions * Heart disease * Cognitive impairment * Medical instability

Locations (1)

Columbia University Irving Medical Center

New York, New York, United States

Outcomes

Primary Outcomes

Change in Assessment and Rating of Ataxia (SARA) Score

This is to measure ataxia severity. The Scale for the Assessment and Rating of Ataxia (SARA) will be administered before and after training. SARA is an 8-item performance based scale, yielding a total score of 0 (no ataxia) to 40 (most severe ataxia) - with higher scores indicating more severe ataxia. The scores are based on patient performance of gait, stance, sitting, speech disturbance, finger chase, nose-finger test, fast alternating hand movements and heel-shin slide. The change in score from baseline to 6 months, 9 months, and 12 months will be reported.

Time frame: Baseline, 6 months, 9 months, 12 months

Secondary Outcomes

Average Gait Speed

This is to measure average time to complete 8-meter walk test. Participants will walk 8 meters as fast as possible three different times. Gait will be reported as meters per second (m/s).

Time frame: Baseline, 6 months, 9 months, 12 months

Dynamic Gait Index Score

The dynamic gait index (DGI) will be performed to assess balance. Patients will be asked to walk 20 feet and conditions such as speed and head position will be varied as previously described. The examiner will then grade the subject's movement on a four-point ordinal scale, ranging from 0 (lowest level of function) to 3 (highest level of function). The total score range is 0 to 24, with higher scores indicating better dynamic balance and functional mobility.

Time frame: Baseline, 6 months, 9 months, 12 months

Timed Up and Go (TUG)

The Timed Up and Go will be performed to assess balance. Once the tester says "Go", participants will stand from seated and walk around a cone that is 3 meters away, then walk back to the chair and sit back down. Participants will be timed from the moment the tester says "Go" until seated again.

Time frame: Baseline, 6 months, 9 months, 12 months

Data from ClinicalTrials.gov

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