Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT04581564 |
| Other study ID # |
818479 |
| Secondary ID |
R21DC018699 |
| Status |
Recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
February 1, 2024 |
| Est. completion date |
December 31, 2024 |
Study information
| Verified date |
January 2024 |
| Source |
The University of Texas at Dallas |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Every year, approximately 100,000 people are diagnosed with aphasia-a language disorder
leading to substantial difficulties in their daily communication. Based on the observation
that many people with aphasia can sing words that they otherwise cannot speak, melodic
intonation therapy (MIT) was developed in the 1970s. Although recognized as a standard
aphasia treatment, the neural mechanisms of MIT have been largely unexplored.
Our first goal is to identify the active ingredient of the music intervention. Although
rhythm has long been considered secondary to melody, recent evidence has challenged this
notion by demonstrating that rhythm alone is sufficient enough to facilitate improvements in
speech fluency for people with aphasia. To corroborate the positive role of rhythm, we will
train aphasic patients to leverage "rhythmic groove" for sets of sentences/phrases delivered
through a fun and engaging video gaming platform. This intervention emerges from the
theoretical framework, built from neuroimaging data, that language processes heavily rely on
neural resources within the sensorimotor and fronto-striatal circuits that subserve
rhythm/timing processes.
Our second goal is to characterize the neural plasticity associated with language recovery
promoted by the novel rhythm-based therapy. We hypothesize that neuroplasticity will manifest
itself as increased white matter tracts, presumably due to changes in myelination in either
ipsilateral or contralateral (homologues) language areas. To effectively measure myelin white
matter fraction (MWF) in candidate tracts, we will mainly use a patented Laplace-transformed
relaxation MRI technique. Additionally, we will measure resting-state functional connectivity
using BOLD (Blood Oxygen-Level Dependent) fMRI. Lastly, we will attempt to record cortical
activity using fNIRS (functional Near-Infrared Spectroscopy) during the pre-post behavioral
assessments.
Taken together, the proposed interdisciplinary research has theoretical, methodological, and
clinical innovations and significance. This exploratory work will serve as a critical
stepping stone toward unraveling the therapeutic component of music in neurological disorders
and will provide evidence-based guidance to the clinicians and therapists.
Description:
Every year, approximately 800,000 people have a stroke in the United States alone. Among
these individuals, roughly 100,000 are diagnosed with aphasia-a disorder characterized by
profound challenges in daily communication with their families and peers. Notably, many
individuals with aphasia can sing despite their speech difficulties, an observation which led
to the development of melodic-intonation therapy (MIT) in the 1970s. Although MIT has since
been accepted as a viable aphasia therapy by the American Academy of Neurology, the
underlying neurological mechanisms that enable speech recovery remain poorly understood.
Here, we propose a highly interdisciplinary approach to study the neural mechanisms of
language recovery in aphasia through a novel rhythm-based language intervention.
Our ultimate goal is to help clinicians and therapists optimize aphasia treatment by
elucidating the neural basis underlying music-induced language recovery through multimodal
neuroimaging and novel statistical analysis. In particular, we will test a hypothesis that
rhythm alone is sufficient to facilitate language recovery, without melody To explore this
hypothesis, we recently devised a novel framework for music-based language therapy that
solely leverages rhythm to facilitate language production at the phrase or sentence level.
Our therapy was used in a case study with a patient with chronic aphasia who had severely
impaired speech fluency due to a large unilateral stroke in the left hemisphere. Following
eight weeks of rhythm therapy, she exhibited remarkable improvement in speech production
(i.e., from 1-2 spontaneous words to 16 sentences made from 42 words), and increased
functional and structural connectivity within key regions of interest associated with the
right sensorimotor network. While compelling, these preliminary data warrant further
validation using proper active controls and a larger sample size, a goal to be achieved
through the proposed research. We have since translated the rhythm therapy into a fun and
engaging game termed "TheraBeat" that can be installed on a tablet PC or smartphone. In the
proposed research, we will use TheraBeat as a home-based aphasia therapeutic intervention to
minimize the burden of patient travel and increase accessibility to therapy. The proposed
study will be accomplished by pursuing the following specific aims:. This prediction is based
upon the theoretical and neuroscientific framework that demonstrates how language heavily
relies on rhythm processes mediated by the bilateral sensorimotor network.
Aim 1. Determine the therapeutic role of rhythm in speech recovery for people with aphasia.
Based on recent evidence garnered by our group as well as others, we expect that rhythm-based
rehabilitation will enhance speech fluency in people with chronic aphasia, i.e., our target
patients who are beyond six months after the onset of stroke. This hypothesis will be tested
by directly comparing post-therapy outcomes of the treatment group, who will practice speech
production daily through rhythmic activity, to an active control group who will receive
conventional speech production therapy without the use of rhythmic activities.
Aim 2. Characterize the neural plasticity promoted by rhythm-based intervention. We
hypothesize that daily participation in our new therapy program will promote neuroplasticity
along the sensorimotor network, especially within the intact perilesional left or right
fronto-striatal circuits that are known to play a key role in speech production and fluency.
To determine structural neuroplasticity following the intervention, we will utilize patented
myelin-based MRI in combination with diffusion tensor imaging (DTI). To explore functional
neuroplasticity, we will use both resting-state fMRI and functional near-infrared
spectroscopy (fNIRS). These structural and functional data will be analyzed via a novel
statistical shape analysis that captures morphological changes, which cannot be detected by
simple statistical approaches.
By using an innovative rhythm-based therapeutic intervention and cutting-edge neuroimaging
techniques, we will address hitherto unknown questions regarding how and why music works as a
therapeutic regimen for aphasia rehabilitation. With expertise in aphasia rehabilitation,
neuroimaging, computer science, and data analytics, our interdisciplinary research team is
well poised to undertake this investigation. The proposed research will serve as a critical
stepping stone toward understanding the therapeutic role of music in neurological disorders.
Our results will lay the foundations for future studies on music-induced language recovery.
