Motor Disorders

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41 Motor Disorders Trials Near You

Power is an online platform that helps thousands of Motor Disorders patients discover FDA-reviewed trials every day. Every trial we feature meets safety and ethical standards, giving patients an easy way to discover promising new treatments in the research stage.

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No Placebo
Highly Paid
Stay on Current Meds
Pivotal Trials (Near Approval)
Breakthrough Medication

Parent-Child Yoga for Congenital Heart Disease

Montréal, Quebec
This trial is testing if parent-child yoga sessions can help improve attention in young children with congenital heart disease. The study involves children aged 4 to 6 and their parents. Yoga is believed to help these children focus better and reduce symptoms of ADHD. Yoga has been explored as a beneficial intervention for various health conditions, including heart disorders and pain management in children with sickle cell disease.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:4 - 6

24 Participants Needed

Neurobehavioral Therapy for Conversion Disorder

Providence, Rhode Island
The goal of this pilot randomized clinical trial is to learn if Neurobehavioral Therapy (NBT) works to treat motor functional neurological disorder (mFND) (also referred to as functional motor disorder). The main questions it aims to answer are: * Does NBT lower mFND symptoms? * Does NBT lower common co-occurring symptoms and improve functioning? Researchers will compare NBT to standard medical care (SMC). Participants will be randomized to receive either: * 12 weekly sessions of NBT, along with their SMC, * or continue receiving their SMC as provided by their treating clinicians. * all participants. regardless of group assignment, will complete a total of five in-clinic visits at the following time points: Baseline, 6 weeks, 12 weeks, 8 Months and 12 Months for self-report surveys to assess functional status, quality of life and mFND symptoms.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased

40 Participants Needed

Mobile App Rehabilitation for Speech Disorders

Tallahassee, Florida
This study evaluates the efficacy of smartphone-based speech therapy administered at home compared with usual care. Participants will be randomized into the treatment and waitlist control groups with an allocation ratio of 1:1.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased

36 Participants Needed

Virtual Reality Rehabilitation for Stroke

Kentville, Nova Scotia
The goal of this clinical trial is to test whether a low-cost virtual reality (VR) motor rehabilitation platform can improve motor recovery in people recovering from a first-time ischemic stroke both in the hospital and at home. The study focuses on adults aged 18 and older who have experienced moderate to severe upper limb motor deficits. The main questions it aims to answer are: * Can VR-based motor therapy improve upper limb motor function compared to standard care? * Is VR-based motor therapy a feasible and acceptable treatment option for stroke patients? Researchers will compare patients receiving VR therapy to those receiving standard care to see if the VR therapy leads to greater improvements in motor recovery and more positive patient experiences. Participants will: * Complete standardized assessments of motor function and quality of life at multiple time points. * Participate in VR therapy sessions (if in the treatment group), using gamified activities designed to improve upper limb movement. * Provide feedback on their experience with the VR system, including ease of use, motion sickness, and engagement. This study will help determine whether VR-based rehabilitation can be a practical, effective way to improve access to therapy and recovery outcomes for stroke patients, especially in rural settings with limited rehabilitation resources.
No Placebo Group

Trial Details

Trial Status:Not Yet Recruiting
Trial Phase:Unphased

40 Participants Needed

Speech-Language Therapy for Primary Progressive Aphasia

Austin, Texas
Difficulties with speech and language are the first and most notable symptoms of primary progressive aphasia (PPA). While there is evidence that demonstrates positive effects of speech-language treatment for individuals with PPA who only speak one language (monolinguals), there is a significant need for investigating the effects of treatment that is optimized for bilingual speakers with PPA. This stage 2 efficacy clinical trial seeks to establish the effects of culturally and linguistically tailored speech-language interventions administered to bilingual individuals with PPA. The overall aim of the intervention component of this study is to establish the relationships between the bilingual experience (e.g., how often each language is used, how "strong" each language is) and treatment response of bilinguals with PPA. Specifically, the investigators will evaluate the benefits of tailored speech-language intervention administered in both languages to bilingual individuals with PPA (60 individuals will be recruited). The investigators will conduct an assessment before treatment, after treatment and at two follow-ups (6 and 12-months post-treatment) in both languages. When possible, a structural scan of the brain (magnetic resonance image) will be collected before treatment in order to identify if brain regions implicated in bilingualism are associated with response to treatment. In addition to the intervention described herein, 30 bilingual individuals with PPA will be recruited to complete behavioral cognitive-linguistic testing and will not receive intervention. Results will provide important knowledge about the neural mechanisms of language re-learning and will address how specific characteristics of bilingualism influence cognitive reserve and linguistic resilience in PPA.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:40+

60 Participants Needed

BCI-Controlled Devices for Motor Disorders

Austin, Texas
Injuries affecting the central nervous system may disrupt the cortical pathways to muscles causing loss of motor control. Nevertheless, the brain still exhibits sensorimotor rhythms (SMRs) during movement intents or motor imagery (MI), which is the mental rehearsal of the kinesthetics of a movement without actually performing it. Brain-computer interfaces (BCIs) can decode SMRs to control assistive devices and promote functional recovery. Despite rapid advancements in non-invasive BCI systems based on EEG, two persistent challenges remain: First, the instability of SMR patterns due to the non-stationarity of neural signals, which may significantly degrade BCI performance over days and hamper the effectiveness of BCI-based rehabilitation. Second, differentiating MI patterns corresponding to fine hand movements of the same limb is still difficult due to the low spatial resolution of EEG. To address the first challenge, subjects usually learn to elicit reliable SMR and improve BCI control through longitudinal training, so a fundamental question is how to accelerate subject training building upon the SMR neurophysiology. In this study, the investigators hypothesize that conditioning the brain with transcutaneous electrical spinal stimulation, which reportedly induces cortical inhibition, would constrain the neural dynamics and promote focal and strong SMR modulations in subsequent MI-based BCI training sessions - leading to accelerated BCI training. To address the second challenge, the investigators hypothesize that neuromuscular electrical stimulation (NMES) applied contingent to the voluntary activation of the primary motor cortex through MI can help differentiate patterns of activity associated with different hand movements of the same limb by consistently recruiting the separate neural pathways associated with each of the movements within a closed-loop BCI setup. The investigators study the neuroplastic changes associated with training with the two stimulation modalities.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased

100 Participants Needed

Hippotherapy for Neuromotor Impairment

Missoula, Montana
The goal of this pilot clinical trial is to determine if physical therapy incorporating horses can improve the motor skills of the arms in children 6-17 years old with neuromotor disorders (such as cerebral palsy, spinal muscular atrophy, or spina bifida) compared to standard play-based physical therapy. The main questions it aims to answer are: 1. Is the study protocol feasible and acceptable for participants, that investigators could apply them to a larger trial? 2. Do participants make improvements toward their goals for motor function, arm use, and participation in life situations following treatment, and is it different between the experimental and comparative intervention groups? 3. What are the physiological, behavioral, and emotional responses of children receiving physical therapy incorporating horses, versus those receiving standard physical therapy? Researchers will compare the experimental group who receive physical therapy incorporating horses to the comparative intervention group who receive standard play-based physical therapy to see if there is a difference in outcomes. Participants will complete a pre- and post-intervention assessment of their motor function and participation in life situations. Participants will receive physical therapy twice a week for 8 weeks for the intervention. In both groups, physiological, behavioral, and emotional responses to the interventions will be measured in 4 total sessions, 1 each at weeks 2, 4, 6, and 8.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:6 - 17

24 Participants Needed

Terazosin for Early Parkinson's Disease

Los Angeles, California
Parkinson's disease (PD) is characterized by many non-motor symptoms that occur several years before the diagnosis, in particular idiopathic REM behavior disorder (iRBD), which is associated with autonomic impairment. The purpose of this study is to investigate the effect of treatment with the selective post-synaptic a1-adrenergic blocker terazosin on 123I-MIBG myocardial uptake in a population of subjects with defined pre-motor PD risks (i.e. hyposmia and RBD) and abnormal baseline 123I-MIBG uptake, with or without 123I-Ioflupane uptake abnormality or PD motor symptoms. Scintigraphic changes will be correlated to motor and non-motor severity of PD, measured by validated clinical scales and cardiac autonomic function tests.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Phase 2
Age:50 - 85

15 Participants Needed

Terazosin Therapy for Parkinson's Disease

Los Angeles, California
This trial is testing terazosin, a medication that helps relax muscles and improve blood flow, on people with early signs of Parkinson's disease risks. The goal is to see if it can slow down or prevent the progression of the disease. Terazosin and similar drugs were recently found to enhance energy production and reduce Parkinson's disease progression in animal studies and human data.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Phase 2
Age:50 - 85

15 Participants Needed

BCI-FIT for ALS

Portland, Oregon
This project adds to non-invasive BCIs for communication for adults with severe speech and physical impairments due to neurodegenerative diseases. Researchers will optimize \& adapt BCI signal acquisition, signal processing, natural language processing, \& clinical implementation. BCI-FIT relies on active inference and transfer learning to customize a completely adaptive intent estimation classifier to each user's multi-modality signals simultaneously. 3 specific aims are: 1. develop \& evaluate methods for on-line \& robust adaptation of multi-modal signal models to infer user intent; 2. develop \& evaluate methods for efficient user intent inference through active querying, and 3. integrate partner \& environment-supported language interaction \& letter/word supplementation as input modality. The same 4 dependent variables are measured in each SA: typing speed, typing accuracy, information transfer rate (ITR), \& user experience (UX) feedback. Four alternating-treatments single case experimental research designs will test hypotheses about optimizing user performance and technology performance for each aim.Tasks include copy-spelling with BCI-FIT to explore the effects of multi-modal access method configurations (SA1.3a), adaptive signal modeling (SA1.3b), \& active querying (SA2.2), and story retell to examine the effects of language model enhancements. Five people with SSPI will be recruited for each study. Control participants will be recruited for experiments in SA2.2 and SA3.4. Study hypotheses are: (SA1.3a) A customized BCI-FIT configuration based on multi-modal input will improve typing accuracy on a copy-spelling task compared to the standard P300 matrix speller. (SA1.3b) Adaptive signal modeling will allow people with SSPI to typing accurately during a copy-spelling task with BCI-FIT without training a new model before each use. (SA2.2) Either of two methods of adaptive querying will improve BCI-FIT typing accuracy for users with mediocre AUC scores. (SA3.4) Language model enhancements, including a combination of partner and environmental input and word completion during typing, will improve typing performance with BCI-FIT, as measured by ITR during a story-retell task. Optimized recommendations for a multi-modal BCI for each end user will be established, based on an innovative combination of clinical expertise, user feedback, customized multi-modal sensor fusion, and reinforcement learning.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased

60 Participants Needed

Hand Rehabilitation for Stroke

San Francisco, California
The purpose of this study is to find out what are the best settings for applying electrical nerve stimulation over the skin for the short-term improvement of hand dysfunction after a stroke. The ultimate goal is to some day design an effective long-term training program to help someone recovery their ability to use their hands and function independently at home and in society. In order to know how to apply electrical nerve stimulation to produce a good long-term effect on hand dysfunction, the investigators first need to know how to make it work best in the short-term, and improve our understanding of for whom it works and how it works. The investigators will use a commercially available transcutaneous electrical nerve stimulation (TENS) unit to gently apply electrical nerve stimulation over the skin of the affected arm. This is a portable, safe and easy to use device designed for patients to operate in their homes.
No Placebo Group

Trial Details

Trial Status:Active Not Recruiting
Trial Phase:Unphased

25 Participants Needed

Why Other Patients Applied

"My orthopedist recommended a half replacement of my right knee. I have had both hips replaced. Currently have arthritis in knee, shoulder, and thumb. I want to avoid surgery, and I'm open-minded about trying a trial before using surgery as a last resort."

HZ
Arthritis PatientAge: 78

"I was diagnosed with stage 4 pancreatic cancer three months ago, metastatic to my liver, and I have been receiving and responding well to chemotherapy. My blood work revealed that my tumor markers have gone from 2600 in the beginning to 173 as of now, even with the delay in treatment, they are not going up. CT Scans reveal they have been shrinking as well. However, chemo is seriously deteriorating my body. I have 4 more treatments to go in this 12 treatment cycle. I am just interested in learning about my other options, if any are available to me."

ID
Pancreatic Cancer PatientAge: 40

"I've tried several different SSRIs over the past 23 years with no luck. Some of these new treatments seem interesting... haven't tried anything like them before. I really hope that one could work."

ZS
Depression PatientAge: 51

"As a healthy volunteer, I like to participate in as many trials as I'm able to. It's a good way to help research and earn money."

IZ
Healthy Volunteer PatientAge: 38

"I changed my diet in 2020 and I’ve lost 95 pounds from my highest weight (283). I am 5’3”, female, and now 188. I still have a 33 BMI. I've been doing research on alternative approaches to continue my progress, which brought me here to consider clinical trials."

WR
Obesity PatientAge: 58
12

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Why We Started Power

We started Power when my dad was diagnosed with multiple myeloma, and I struggled to help him access the latest immunotherapy. Hopefully Power makes it simpler for you to explore promising new treatments, during what is probably a difficult time.

Bask
Bask GillCEO at Power
Learn More About Trials
How Do Clinical Trials Work?Are Clinical Trials Safe?What Can I Expect During a Clinical Trial?

Frequently Asked Questions

How much do Motor Disorders clinical trials pay?

Each trial will compensate patients a different amount, but $50-100 for each visit is a fairly common range for Phase 2–4 trials (Phase 1 trials often pay substantially more). Further, most trials will cover the costs of a travel to-and-from the clinic.

How do Motor Disorders clinical trials work?

After a researcher reviews your profile, they may choose to invite you in to a screening appointment, where they'll determine if you meet 100% of the eligibility requirements. If you do, you'll be sorted into one of the treatment groups, and receive your study drug. For some trials, there is a chance you'll receive a placebo. Across Motor Disorders trials 30% of clinical trials have a placebo. Typically, you'll be required to check-in with the clinic every month or so. The average trial length for Motor Disorders is 12 months.

How do I participate in a study as a "healthy volunteer"?

Not all studies recruit healthy volunteers: usually, Phase 1 studies do. Participating as a healthy volunteer means you will go to a research facility several times over a few days or weeks to receive a dose of either the test treatment or a "placebo," which is a harmless substance that helps researchers compare results. You will have routine tests during these visits, and you'll be compensated for your time and travel, with the number of appointments and details varying by study.

What does the "phase" of a clinical trial mean?

The phase of a trial reveals what stage the drug is in to get approval for a specific condition. Phase 1 trials are the trials to collect safety data in humans. Phase 2 trials are those where the drug has some data showing safety in humans, but where further human data is needed on drug effectiveness. Phase 3 trials are in the final step before approval. The drug already has data showing both safety and effectiveness. As a general rule, Phase 3 trials are more promising than Phase 2, and Phase 2 trials are more promising than phase 1.

Do I need to be insured to participate in a Motor Disorders medical study?

Clinical trials are almost always free to participants, and so do not require insurance. The only exception here are trials focused on cancer, because only a small part of the typical treatment plan is actually experimental. For these cancer trials, participants typically need insurance to cover all the non-experimental components.

What are the newest Motor Disorders clinical trials?

Most recently, we added SMART for Post-Traumatic Stress Disorder, Virtual Reality Rehabilitation for Stroke and Hippotherapy for Neuromotor Impairment to the Power online platform.

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