Ukulele Playing to Improve Cognition in People with Multiple Sclerosis: a Feasibility Study

Not Applicable

Completed

• Conditions: Multiple Sclerosis; Nervous System Diseases; Pathologic Processes; Autoimmune Diseases of the Nervous System; Autoimmune Diseases; Demyelinating Autoimmune Diseases, CNS; Demyelinating Diseases; Immune System Diseases

• Registration Number: NCT05792176
• Lead Sponsor: University of Texas at Austin

Brief Summary

Over the past 10 years, the rates of multiple sclerosis (MS) have nearly doubled in the United States. This chronic, neuroinflammatory, and neurodegenerative disease is most often diagnosed between the ages of 20-40. Cognitive impairment effects up to 70% of people with MS (PwMS) and has a detrimental impact on mental health, social connections, and employment. Further, up to 50% of PwMS also struggle with depression. Numerous cognitive rehabilitation programs are available to address cognitive impairment, but few interventions have simultaneous effects on cognition and emotional well-being. Music interventions have potential to fill this gap. Brain imaging studies on music and emotion show that music can modulate activity in the brains structures that are known to be crucially involved in emotion. Further, music engages areas of the brain that are involved with paying attention, making predictions, and updating events in our memory.

The purpose of this study is to determine the feasibility of an online musical training intervention (MTI) for PwMS and explore the potential effect on cognition, psychosocial, and functional well-being compared to an active control group (music listening (ML)). The specific aims are to: 1) determine the feasibility and acceptability of delivering the MTI virtually over three months to PwMS; 2) evaluate the effect of the MTI on cognitive functioning (processing speed, working memory, cognitive flexibility, response inhibition), psychosocial (anxiety, depression, stress, quality of life, self-efficacy) and functional (insomnia) well-being compared to ML; and 3) (exploratory aim) to utilize non-invasive neuroimaging to determine if pre-intervention brain activity predicts post-intervention cognitive functioning.

Detailed Description

Multiple sclerosis (MS) affects more than 2.8 million people worldwide. The prevalence has increased in every region worldwide since 2013, and in the United States, rates have nearly doubled. It is the main cause of nontraumatic disability in young adults in many countries. MS is a chronic neuroinflammatory and neurodegenerative disease with an unpredictable course. Varying visible and invisible symptoms occur in MS. The invisible symptoms, such as fatigue, depression, psychological distress, insomnia, and cognitive dysfunction pose a significant burden on quality of life (QoL) and workforce participation, rendering PwMS more vulnerable to mental health challenges compared to those affected by physical disability alone. Cognitive impairment occurs in 40-70%, depression in up to 50%, and fatigue can be present in up to 85-95% of PwMS. The interplay of cognitive impairment, mood, impaired sleep quality, and fatigue contributes significantly to worsened QoL. Cognitive impairment can occur in early and late phases of the disease and may include alterations in information processing, attention, executive functions and working memory. Multiple interventions have been created to address cognitive impairments such as conventional cognitive rehabilitation, computer-based programs, non-invasive brain stimulation, and neurologic music therapy. Many of these interventions have shown improvements in various domains of cognitive impairment. However, the effect of cognitive rehabilitation on psychosocial well-being in addition to cognitive symptoms is rare.

This research aims to fill a gap in cognitive rehabilitation with an innovative music training intervention for PwMS. Active music engagement interventions (i.e., instrument playing) have shown improvements in cognitive, motor, and psychosocial outcomes in other neurological conditions. However, few studies have examined the impact for PwMS. Most music intervention studies in PwMS evaluate the impact of music on fatigue, pain, mood disorders, walking, and balance. The impact of music on cognition is much less studied. Our team is currently conducting a systematic review examining the differences between active and passive music engagement in PwMS. Sixteen studies were included in the review. Only two studies examined active music making (singing or musical instrument playing), only one of those evaluated the impact on cognition (no improvement), and neither evaluated the effect on psychosocial (anxiety, depression, quality of life) outcomes. Twelve of the studies evaluated passive music engagement (music listening with or without movement); however, the primary outcome in most of these studies was neurological motor skills versus non-motor or psychosocial outcomes. One study, that used both active and passive musical engagement, examined the effect of cognitive rehabilitation plus neurological music therapy on cognitive abilities, mood, emotional components, and MS quality of life. They found significant improvements in cognitive function, motivation, emotional awareness, depression, and quality of life in the intervention that entailed cognitive rehabilitation plus neurological music therapy. However, no significant differences were found between the experimental group (cognitive rehabilitation plus neurological music therapy) and active control (cognitive rehabilitation alone).

Music listening and making is processed throughout spinal, subcortical, and cortical regions, and thus has meaningful and broad impacts on complex cognitive, affective, and sensorimotor processes. The impact of instrumental music playing on executive functioning has been demonstrated in many studies with children; however, this has not been studied in PwMS. Specific to executive function, neuroimaging studies with functional magnetic resonance imaging (fMRI) and functional near-infrared spectroscopy (fNIRS) show an increase in neural activations the right frontal and prefrontal regions in PwMS on cognitive tests requiring lower cognitive load (e.g., 1-back) working memory tasks when compared to healthy controls and lower activation on higher cognitive load tasks (2- and 3-back). Theoretically, it is hypothesized that the neuronal damage caused by MS causes processing resources to be diminished, thus different brain areas are recruited to cope with task demands as difficulty increases. The rehabilitative effects of music in relation to other neurological disorders is linked to changes in brain neuroplasticity, which describes the adaption and cortical reorganization after training or learning a new task. This study will examine the feasibility of an online musical training intervention (MTI) for PwMS, explore the potential effect on cognitive functioning, psychosocial, and functional well-being, and explore a neuroimaging via fNIRS, a non-invasive technique, to determine if pre-intervention brain activity predicts post-intervention cognitive functioning.

The purpose of this study is to determine the feasibility of an online musical training intervention (MTI) for PwMS and explore the potential effect on cognition, psychosocial, and functional well-being compared to an active control group (music listening (ML)). The specific aims are to: 1) determine the feasibility and acceptability of delivering the MTI virtually over three months to PwMS; 2) evaluate the effect of the MTI on cognitive functioning (processing speed, working memory, cognitive flexibility, response inhibition), psychosocial (anxiety, depression, stress, quality of life, self-efficacy) and functional (insomnia) well-being compared to ML; and 3) (exploratory aim) to utilize non-invasive neuroimaging to determine if pre-intervention brain activity predicts post-intervention cognitive functioning.

Study Timeline

• Study First Submitted: 2023-02-16
• Study Start: 2023-03-27
• Study First Submitted QC: 2023-03-28
• Study First Posted: 2023-03-31
• Primary Completion: 2024-10-01
• Study Completion: 2024-10-01
• Status Verified: 2024-11
• Last Update Submitted: 2025-03-10
• Last Update Posted: 2025-03-13

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 29

Inclusion Criteria

• Diagnosed with multiple sclerosis (relapsing remitting, secondary progression, primary progressive)
• Diagnosed more than 6 months prior to starting study
• Self-reported cognitive impairment as assessed by having at least 5 problems "sometimes" or more often on the Perceived Deficits Questionnaire
• Read, write, and understand English
• Access to computer and zoom

Exclusion Criteria

• Diagnosed with another neurological condition that causes cognitive impairment
• MS exacerbation within the last 30 days
• Unable to travel to The University of Texas at Austin for fNIRS data collection
• Professional musician (primary source of income)

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Primary Outcome Measures

Name	Time	Method
Intervention Feasibility	Immediately post-intervention	Protocol adherence will be evaluated by recording the average number of modules completed by participants.
Intervention Acceptability	Immediately post-intervention	Acceptability will be evaluated with semi-structured interview questions to understand the participant's perception of MTI delivery and content and the perceived impact.

Secondary Outcome Measures

Name	Time	Method
Mean Change from Baseline in Stress Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Perceived Stress Scale will be used. The minimum score is 0, and the maximum score is 40. Higher scores indicate more perceived stress.
Mean Change from Baseline in Self-Efficacy Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Chronic Disease Self-Efficacy Scale will be used. The minimum score is 6, and the maximum score is 60. Higher scores indicate more self-efficacy.
Mean Change from Baseline in Executive Functioning Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Stroop Color and Word Test evaluates impulse control and inhibition to evaluate executive functioning. When the name of a color (e.g., "blue," "green," or "red") is displayed in an incongruent color, name (for example, the word "blue" printed in red), naming the color of the word takes longer and is more prone to errors than when the word and color are congruent or neutral. The scoring uses median duration of incongruent trials.
Mean Change from Baseline in Anxiety Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Patient-Reported Outcomes Measurement Information System (PROMIS) Emotional Distress-Anxiety Short-Form 8a will be used. The minimum score is 8, and the maximum score is 40. Higher scores indicate more anxiety.
Mean Change from Baseline in Attention Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Trail Making A\&B will be used to measure attention. Trails A and B are two separate timed tests. Faster time means greater attention.
Mean Change from Baseline in Memory Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	Immediate and delayed recognition tests will be used. Participant are shown 10 words to memorize. In the immediate recognition test, they are immediately asked to identify the 10 words they memorized out of a list of 20. Later in the testing series, participants will again be asked to recall the 10 words. The number of correct responses will be scored. Higher scores means better memory.
Mean Change from Baseline in Quality of Life Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Multiple Sclerosis Quality of Life Questionnaire will be used. The minimum score is 27, and the maximum score is 135. Higher scores indicate worse quality of life.
Mean Change from Baseline in Depression Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Patient-Reported Outcomes Measurement Information System (PROMIS) Depression Short-Form 8a will be used. The minimum score is 8, and the maximum score is 40. Higher scores indicate higher levels of depressive symptoms.
Mean Change from Baseline in Sleep Disturbance Scores at 12 weeks and 16 weeks	Immediately post-intervention and 1-month post-intervention	The Patient-Reported Outcomes Measurement Information System (PROMIS) Sleep disturbance Short-Form 6a will be used. The minimum score is 6, and the maximum score is 30. Higher scores indicate more sleep disturbance.

Trial Locations

Locations (1)

University of Texas at Austin; 🇺🇸 Austin, Texas, United States