394 Clinical Trials for Stroke
The purpose of this research is to evaluate a new investigational device for the diagnosis of stroke, the EMVision emu™ Brain Scanner. Stroke is the result of a blood clot stopping the normal flow of blood in the brain (ischaemic stroke) or a breakage in a blood vessel causing bleeding in the brain (haemorrhagic stroke). Stroke is a medical emergency and must be quickly diagnosed and treated. Computed tomography (CT) or magnetic resonance imaging (MRI) scans are commonly used to diagnose stroke, but they are not always readily available. EMVision has developed the emu™ Brain Scanner, a helmet-like device which scans the head using ultra-high frequency radio signals. It is portable and easy to use, making it more accessible than CT or MRI machines. Easier access to the EMVision emu™ Brain Scanner may reduce the time taken to diagnose stroke, leading to faster treatment and better health outcomes. It is the purpose of this study in the first instance to determine the accuracy of the EMVision emu™ Brain Scanner in the detection of haemorrhagic stroke.
This study aims to evaluate the feasibility and impact of transcutaneous electrical stimulation of the spinal cord (TESS) on the recovery of post-stroke individuals who have upper limb hemiparesis. It will compare outcomes measures between individuals who receive upper limb task specific training with TESS and individuals who receive task specific training of the upper limb with Sham, or fake, TESS.
The purpose of this research study is to explore whether genetic testing can offer a personalized and timely approach to assist physicians in making more informed medication decisions for stroke or high-risk transient ischemic attack (TIA) patients during their hospital stay.
To determine changes in power symmetry, gait symmetry, and functional outcomes for participants' poststroke (Inpatient Rehabilitation Facility) after participating in an intervention using a recumbent cycle with power biofeedback (BFB). To determine how this intervention can impact gait asymmetry, a common disorder poststroke secondary to hemiparesis. Gait asymmetry is a difficult impairment to treat because it is difficult for both therapists and patients to perceive. Training with BFB allows for quantitative data about the power production or lack of that directly impacts safety in walking, increased energy expenditure, and decreased gait speed.
The purpose of this study is to evaluate whether adding an emotional wellness component to occupational therapy (OT) and/or speech therapy (ST) telerehabilitation improves overall emotional well-being and activity participation for people with stroke.
To evaluate feasibility and effectiveness of non-invasive VNS to enhance stroke recovery
Shoulder pain is extremely common after stroke and occurs in 30-70% of patients. The pain may begin as early as one week after stroke, although peak onset and severity occurs around four months, and persists into the chronic stage. Chronic post stroke shoulder pain (PSSP) interferes with motor recovery, decreases quality of life, and contributes to depression. PSSP is thought to be caused mainly by damage to the myofascial tissues around the shoulder joint. Interestingly, an MRI study in patients with PSSP showed that the degree of structural damage to the muscles did not correlate with the degree of pain. Thus, the pathophysiology of myofascial dysfunction and pain in PSSP has not been elucidated leading to missed opportunities for early diagnosis and variable success with pain management. The accumulation of hyaluronic acid (HA) in muscle and its fascia can cause myofascial dysfunction. HA is a glycosaminoglycan (GAG) consisting of long-chain polymers of disaccharide units of glucuronic acid and N-acetylglucosamine and is a chief constituent of the extracellular matrix of muscle. In physiologic quantities, HA functions as a lubricant and a viscoelastic shock absorber, enabling force transmission during contraction and stretch. Reduced joint mobility and spasticity result in focal accumulation and alteration of HA in muscle. This can lead to the development of stiff areas and taut bands, dysfunctional gliding of deep fascia and muscle layers, reduced range of motion (ROM), and pain. However, the association of muscle HA accumulation with PSSP has not been established. The investigators have quantified the concentration of HA in muscle using T1rho (T1ρ) MRI and found that T1ρ relaxation time is increased in post stroke shoulder pain and stiffness. Furthermore, dynamic US imaging using shear strain mapping can quantify dysfunctional gliding of muscle that may generate pain during ROM. Myofascial dysfunction can result in non-painful reduction in ROM (latent PSSP), which may become painful due to episodic overuse injury producing greater shear dysfunction (active PSSP). Hence, shear strain mapping may differentiate between latent versus active PSSP. Thus, quantitative Motor Recovery (MR) and US imaging may serve as useful biomarkers to elucidate the pathophysiology of myofascial dysfunction.
Loss of reading ability due to stroke, called alexia, likely affects over a million Americans at any given time and causes difficulty performing many daily life functions, such as paying bills, using email/text, reading for pleasure, and reading signs in the community. Understanding the brain and cognitive basis of alexia could improve diagnosis and treatment of this important problem. In this study, the investigators will perform a large-scale behavioral and brain imaging study of stroke survivors and typical older adults to improve our understanding of the brain and cognitive basis of reading in both of these groups. Participants will complete a battery of tests of reading, speech, language, and thinking abilities. In addition, some participants will complete an MRI. Sessions will be completed across approximately 2-6 weeks, but may be extended depending on participants' schedules and availability. Some participants will be invited to repeat these procedures once or twice in approximately 3-12 months to monitor for changes in reading abilities and MRI measurements over time.
The investigators are investigating ways to incorporate new technologies that can enhance functional outcome after neurological insult into the patient recovery space. In order to accelerate the translation of these technologies to patient care spaces, the investigators need to identify the locations that are feasible for its use. Currently the investigators are using video game technologies that are used to maximize motor recovery of impaired upper extremities after neurological insult in the outpatient (clinic) setting. These technologies interface with robotics and other hardware to create a therapy experience that is fun, engaging, dynamic, challenging, and promotes repetitions that are otherwise difficult to achieve during conventional post-stroke rehabilitation. The investigators think early use of these technologies could enhance recovery of the arm, but It is not known if use of these technologies in the early post-stroke recovery period is safe and feasible.
This study aims to assess the feasibility and acceptability of "MAYA", a mobile cognitive behavioral therapy app for anxiety and mood disorders, in adults who have had a stroke.
This research study aims to understand the relationship between brain stimulation and leg skill learning in both healthy adults and persons with chronic stroke.
This study investigates the effects of Tizanidine on the voluntary movement controls of the arms of participants who have had a stroke and have not had a stroke by measuring medication-induced changes in upper extremity kinematics, pupillometry, and brain activity. Tizanidine is approved by the U.S. Food and Drug Administration. Understanding how different areas of the brain are involved in movement impairments may help rehabilitation efforts and assist in restoring healthy movement in individuals who have had a stroke.
The aim of this study is to evaluate how vibration of the tendons enhances arm and hand training in survivors of chronic stroke. The investigators hypothesize that wrist/elbow robotic training, combined with body awareness training will improve arm and hand function in individuals with chronic stroke.
The purpose of this study is to evaluate the safety, feasibility, and efficacy of an exoskeletal network of passive, multi-joint springs for forearm supination. Also known as the forearm ExoNET, the device is a passive, robotic device that will properly assist forearm supination in the post-stroke adult population.
Stroke is a leading cause of long-term disability. Research has placed little emphasis on integrating care partners (CP) (family members) into the rehabilitation process without increasing negative care partner outcomes. The research team has developed and implemented a novel, web-based care partner-focused intervention (CARE-CITE) designed to foster problem-solving and skill building while facilitating care partner engagement during stroke survivor (SS) upper extremity practice of daily activities in the home setting. By providing a family-focused approach to rehabilitation interventions, this project will help develop more effective treatments that improve CP and outcomes after stroke.
Physical therapists use dry static cupping for the treatment of many conditions, including spasticity for patients post-stroke. While research better describes the effects of dry static cupping for patients with orthopedic conditions, information is lacking on central conditions, such as stroke and resulting spasticity.
Dysphagia, or difficulty swallowing, is a common symptom of many neurological diseases but its treatment is not well established or easily accessible. To start addressing this gap, the researchers developed and validated a cost-effective wearable surface electromyography (sEMG) biofeedback sensor technology (i-Phagia), optimized to record muscle activity from the head/neck and provide biofeedback to patients and adherence data to clinicians during swallow therapy. This system has been developed with commercially available and widely used materials and the Purdue University IRB has determined that the device is non-significant risk device. The goal of this clinical trial is to learn if this biofeedback (using this new technology/i-Phagia) when used as an adjunct to a standard swallow therapy protocol works to improve swallowing function in patients post chronic stroke or diagnosed with Parkinson's disease. It will also help the investigators learn whether this therapy protocol is equally effective when provided in-person versus via telehealth. Finally, it will determine which patient factors may influence how well the treatment works. The main questions it aims to answer are: * Does biofeedback (using this new technology/i-Phagia) when used as an adjunct to a standard swallow therapy protocol works better than a standard of care treatment to improve swallowing function in patients post chronic stroke or diagnosed with Parkinson's disease? * Is completing the swallow therapy protocol at home (via telehealth) as effective as completing it in-person (in the clinic)? * What factors related to the patients (e.g., age, diagnosis, etc.) may influence how well the treatment works? Participants will: * Complete a 12-week swallow treatment protocol (12 treatment visits) either in-person or at home (via telehealth) * Complete 3 in-person evaluations (pre-treatment; post-treatment; and at a 12-week post treatment follow-up time point) * Exercise at home several days per week and keep a diary/log of their home exercise The hypothesis is that upon study completion, the efficacy of sEMG biofeedback-facilitated swallow therapy for both in-person and telehealth service delivery in two neurogenic dysphagia populations will have been established, and variables determining response to treatment will begin to be identified.
Early evidence suggests the benefits of post-stroke motor rehabilitation may be enhanced by applying electrical stimulation to the ear. This study aims to test the new approach of pairing ear stimulation with motor rehabilitation in the home setting in stroke survivors with upper limb motor function deficits.
Background: Stroke is the fifth leading cause of death in the United States. It is also a leading cause of disability. More than 70% of people who survive strokes have mental impairment or dementia. Medical factors, such as the severity of the stroke, affect whether a person will have mental impairment afterward. But social factors, such as education and ethnicity, seem to play a role as well. Researchers want to learn more about how social and lifestyle factors affect a person s chances of maintaining mental functions after a stroke. Objective: To better understand how social and lifestyle factors affect the risk of mental impairment after a stroke. Eligibility: People aged 18 years and older who had a stroke and a brain scan while they were enrolled in NIH Study 01N0007 (Natural History of Stroke Study). Design: Participants will have 1 study visit, by telephone. The call will last about 45 minutes. Participants will talk about their health since their stroke. They will answer questions about themselves. Topics will include: * Their race * Education * Ethnicity * Employment * Marital status * Residence address * Recent health history * Medical insurance They will have tests of their memory, attention, and language skills. They will repeat numbers and words forward and backward. Researchers will look at the data and imaging scans collected during participant s enrollment in NIH Study 01N0007. This data will include: * The hospital that first saw the participant at the time of their stroke. * The type of imaging that was first used then. * The primary diagnosis at admission. * Other medical details.
This study uses functional magnetic resonance imaging to map neural activity throughout the central nervous system during a shoulder abduction task to characterize what motor pathways are being used post-stroke.
The overall goal of this proposed study is to evaluate the efficacy of a small-group, stroke-specific, self-management program delivered via telehealth to improve self-efficacy, activity performance, and quality of life in individuals with sub-acute stroke.
Traditional rehabilitation approaches are time and personnel intensive and costly, and leave \~75% of stroke survivors with residual disability. We propose a clinical trial to determine effects of forced aerobic exercise (FE; i.e., mechanically supplemented) in facilitating upper and lower extremity motor recovery post-stroke in an outpatient rehabilitation setting, to elucidate neural and biochemical substrates of FE-induced motor recovery, and to evaluate cost effectiveness of a FE-centered intervention compared to traditional stroke rehabilitation. The global effect of FE has the potential to enhance recovery in a growing population of stroke survivors in a cost-effective manner, thus accelerating its clinical acceptance.
The purpose of this study is to investigate the feasibility of a mobile telerehabilitation software for post-acute stroke care for Rio Grande Valley (RGV) stroke survivors with community health worker (CHW) at-home support and to estimate the functional health, mental health (depression), and caregiver burden outcomes of this new CHW-supported, at-home rehabilitation service delivery model and to identify salient barriers to and facilitators of adopting and delivering the new rehabilitation delivery model to further disseminate the model in real-world communities.
Investigators will conduct a randomized controlled trial (RCT) to assess intervention efficacy of telehealth delivery of the GLB-CVA (tGLB-CVA) compared to a 6-month wait-list control (WLC) in partnership with a diverse group of patient partners and peer mentors.
Transcranial magnetic stimulation (TMS) interventions could feasibly strengthen residual corticospinal tract (CST) connections and enhance recovery of paretic hand function after stroke. This project will test whether personalized brain state-dependent TMS can activate the residual corticospinal tract better than standard TMS, and evaluate the relationship between this activation and hand motor impairment.
This interventional trial will compare a novel prehospital stroke transport algorithm (OPUS-i) to a traditional prehospital stroke transport algorithm to improve outcomes in rural stroke patients by determining the effect of implementing a data-driven prehospital stroke algorithm on time to and endovascular therapy. The study consists of a multicenter cohort and will last 24 months but individual subject study duration is 90 days.
The purposes of this study include: 1. - To identify whether features of aberrant intermuscular coordination patterns can be used to predict motor impairment after stroke. 2. - To test whether muscle synergies are malleable to a non-invasive EMG-guided exercise that induces changes in intermuscular coordination of upper extremity muscles after stroke.
This study will evaluate the effects of a form of non-invasive brain stimulation on brain functioning and memory in participants with post-stroke cognitive impairment (PSCI).
The goal of this research study is to learn how the brain areas that plan and control movement interact with the areas responsible for hearing and perceiving speech in healthy adults and people who have had cerebellar strokes. The main questions it aims to answer are: 1. What regions of the brain's sensory systems show changes in their activity related to speech? 2. To what extent do these regions help listeners detect and correct speech errors? 3. What is the role of the cerebellum (a part of the brain in the back of the head) in these activities? Participants will be asked to complete several experimental sessions involving behavioral speech and related tests and non-invasive brain imaging using electroencephalography (EEG) and functional magnetic resonance imaging (fMRI).
The ERA Stroke project will compare the effects of robotic gait training (RGT) and usual care (UC) gait training in patients in the subacute phase of stroke recovery undergoing inpatient rehabilitation at the Baylor Scott \& White Institute for Rehabilitation (BSWIR).