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Apathy is a common set of symptoms seen in many people following a stroke. Apathy occurs when a person has lost motivation, becomes withdrawn, and stops doing things that used to be important to them. Apathy has a large negative impact on a person's quality of life, and can also have a large impact the people who take care of them. There are currently no FDA-approved treatments to help with apathy, and other services like therapy may be difficult to access for people who have had a stroke. To address this problem, investigators are conducting a study to find out if a form of treatment called repetitive transcranial magnetic stimulation (rTMS) can be safe and helpful for people struggling with apathy after a stroke. This study will apply a new form of rTMS which can be delivered quickly to a part of the brain called the medial prefrontal cortex (mPFC). This study will help establish whether this treatment is safe, comfortable, and effective for people with apathy after a stroke, and will help researchers develop new forms of treatment.
This trial tests a promising new intervention to promote post-stroke neural reorganization and functional recovery. The Q Therapeutic (BQ 3.0) is a wearable medical system that produces and delivers non-invasive, extremely-low-intensity and low-frequency, frequency-tuned electromagnetic fields in order to stimulate neuronal networks with the aim of reducing disability and promoting neurorecovery. This trial is a prospective, single-arm, open-label, single center clinical trial designed to evaluate the safety, feasibility, and efficacy of the Q Therapeutic (BQ 3.0) System in the rehabilitation of people with chronic stroke.
Evaluate the effectiveness of the Q Therapeutic (BQ 3.0) System for individuals with chronic stroke in improving upper extremity function as determined by change in functional outcome measures after 3-month treatment, including in-clinic and at-home sessions.
This study examines the effectiveness of the cardiac rehabilitation program for stroke patients. The study will examine if patients with stroke, who receive cardiac rehabilitation in addition to their standard of care treatments, demonstrate improved recovery of function. It will also examine if these patients have reduced hospital readmission, reduced rate of recurrent stroke, and mortality.
Constraint-Induced Movement Therapy or CI Therapy is a form of treatment that systematically employs the application of selected behavioral techniques delivered in intensive treatment over consecutive day with the following strategies utilized: behavioral strategies are implemented to improve the use of the more- affected limb in life situation called a Transfer Package (TP), motor training using a technique called shaping to make progress in successive approximations, repetitive, task oriented training, and strategies to encourage or constrain participants to use the more-affected extremity including restraint of the less-affected arm in the upper extremity (UE) protocol. Numerous studies examining the application of CI therapy with UE rehabilitation after stroke have demonstrated strong evidence for improving the amount of use and the quality of the more-affected UE functional use in the participant's daily life situation. CI Therapy studies with adults, to date, have explored intensive treatment for participants with a range from mild-to-severe motor impairment following stroke with noted motor deficits and limited use of the more-affected arm and hand in everyday activities. Each CI Therapy protocol was designed for the level of impairment demonstrated by participants recruited for the study. However, often following stroke, patients not only have motor deficits but somatosensory impairments as well. The somatosensory issues have not, as yet, been systematically measured and trained in CI Therapy protocols with adults and represent an understudied area of stroke recovery. We hypothesize that participants with mild-to-severe motor impairment and UE functional use deficits can benefit from CI therapy protocols that include somatosensory measurement and training components substituted for portions of motor training without loss in outcome measure gains. Further, we hypothesize that adults can improve somatosensory outcomes as a result of a combined CI therapy plus somatosensory component protocol.
Constraint-Induced Therapy (CI Therapy) is a behavioral approach to neurorehabilitation and consists of multi-components that have been applied in a systematic method to improve the use of the limb or function addressed in the intensive treatment. CI Therapy for the more-affected upper extremity (UE) post-stroke is administered in daily treatment sessions over consecutive weekdays. Sessions include motor training with repeated, timed trials using a technique called shaping, a set of behavioral strategies known as the Transfer Package (TP) to improve the use of the more-affected hand in the life situation, and strategies to remind participants to use the more-affected UE including restraint. Robust improvements in the amount and qualify of use have been realized with stroke participants from mild-to-severe UE impairment.
The Ekso (Ekso Bionics) is a wearable exoskeleton that provides robotic support and walking assistance for patients with lower extremity paralysis. Research suggests that exoskeleton-assisted gait training is as effective as conventional gait training at improving walking outcomes and balance during both the chronic and subacute period following stroke (Goffredo et al., 2019; Molteni et al., 2017; Molteni et al., 2021; Nam et al., 2019; Rojek, 2019). Exoskeleton-assisted gait training during acute inpatient rehabilitation provides a means for patients to actively participate in gait training during the early and most severe stages of stroke recovery. Most acute inpatient rehabilitation facilities (IRFs) report a feasibility of 5-8 Ekso sessions during inpatient stays and demonstrate significant improvement from baseline (Nolan et al., 2020; Swank, 2020). Nolan et al. (2020) demonstrated that stroke patients receiving Ekso ambulated 1640 feet more than patients undergoing more conventional gait training techniques during inpatient rehabilitation, suggesting that the exoskeleton may offer additional benefit during this phase of recovery. Despite promising evidence, there have been no randomized controlled trials within the IRF setting. Because Ekso-gait training increases the number of steps patients can take, during acute inpatient physical therapy (PT), the investigators hypothesize that patients who participate in Ekso-gait training will demonstrate quicker improvements in balance, gait speed, endurance and independence in functional ambulation during their stay in the IRF. In this study, eligible patients admitted to Sunnyview Rehabilitation Hospital (SRH) for rehabilitation following stroke will be randomized to receive conventional or Ekso-gait training therapy. Meaningful clinical benchmarks for balance and walking will be assessed using the Berg Balance Scale (BBS) (Alghadir, 2018; Moore, 2018), the 10 Meter Walk Test (10MWT) (Bowden, 2008; Moore, 2018), the Six Minute Walk Test (6MWT) (Kubo et al., 2020; Moore, 2018), and Functional Ambulation Category (FAC) (Mehrholz, 2007). Achieving these benchmark scores are associated with several positive outcomes, including increased ability to ambulate in the community and reduced risk of falling (Alghadir, 2018; Bowden, 2008; Kubo et al., 2020). The investigators also hypothesize that patients in the Ekso cohort will report greater value/usefulness when compared to patients receiving standard care.
This project seeks to determine how post-stroke cognitive impairment moderates motor learning during walking in older adults with chronic stroke and identify brain structural markers that mediate this relationship. The chosen experimental design integrates biomechanical analyses, neuropsychological assessments, and brain imaging techniques to determine the impact of post-stroke cognitive impairment severity on two forms of motor learning (explicit and implicit) and examine the role of the dorsolateral prefrontal cortex in the relationship between cognition and explicit motor learning. Ultimately, this work may lead to the development of a more comprehensive, effective treatment approach to improve walking dysfunction in older adults post-stroke.
Participants are being asked to participate in a research study conducted by Shih-Chiao Tseng, PT, Ph.D. at Texas Woman's University. This research study is to determine whether low-intensive brain stimulation can enhance learning of a leg movement task. The investigators also want to know if brain stimulation can improve the nerve function and walking performance. Our goal is to understand any relationship between brain stimulation and overall movement control improvement. Participants have been invited to join this research if they have had a stroke before or they are healthy adults aged 21 years or older. Research evidence shows stroke can induce permanent brain damage and therefore may cause a person to have trouble learning a new task. This in turn may significantly impact the recovery of motor function in stroke survivors. In addition, the investigators also want to know how a healthy person learns this new leg task and see if her/his learning pattern differs from a stroke survivor. This study comprises two phases: Phase I study investigates short-term effects of brain stimulation on leg skill learning and only requires two visits to TWU. The total time commitment for Phase I study will be about 6.5 hours, 3.5 hours on the first visit and three hours on the second visit; Phase II study is an expanded version of Phase I study to investigate long-term effects of brain stimulation on leg skill learning and requires to complete 12 visits of exercise training paired with brain stimulation over a four-week period and additional one visit for follow-up test. The total time commitment for Phase II study will be about 20 hours, a total of 18 hours for 12 exercise training sessions and two hours for a follow-up test. The investigators hypothesize that people with chronic stroke will show a slower rate of acquiring this leg skill as compared to healthy adults. The investigators also hypothesize that co-applying brain stimulation with 12 sessions of exercise training will enhance skill learning of this leg task for people with chronic stroke and this 12-session exercise program may exert beneficial influences on the nerve function and leg muscle activation, and consequentially improve motor control for walking.
The goal of this project is to determine the feasibility and optimal parameters of a novel, comprehensive approach to gait training in individuals with chronic stroke. The comprehensive approach includes biofeedback-based gait training and aerobic exercise intensity-based gait training.