582 Clinical Trials for Various Conditions
This study will critically examine the feasibility, safety and efficacy of HBOT during inpatient rehabilitation (IPR) after acute ischemic stroke measured by non-disruption of 3 hours of daily therapy, frequency of neurological deterioration or complications (seizure, hemorrhage, brain edema), and functional communication, activities of daily living (ADLs) and mobility.
The goal of this clinical trial is to evaluate whether our transitional care program helps stroke survivors better manage their risk factors for stroke to lower the risk of a repeat stroke. The main question it aims to answer is: - Does the program help participants meet the targets set by the American Heart Association clinical guidelines for control of risk factors associated with stroke? Researchers will compare participants enrolled right after being discharged from the hospital to participants enrolled around 3-5 months after being discharged to examine whether timing differences in enrollment affect the efficacy of the program. Participants will: * Keep track of their medications, their exercise, and their health information using smart devices provided by the study * Answer questions about their health and lifestyle * Meet with our team of healthcare providers
This project aims to develop a novel visual training paradigm for use in visually-intact participants and those sufferings from stroke-induced visual impairments. Our task design is built upon theories of statistical learning to reduce the overall training burden while still producing profound improvements to visual abilities. Efficacy will be first established in visually-intact controls before testing in stroke survivors to assess the feasibility of this form of learning in the damaged visual system.
Using the CorTec Brain Interchange (BIC) System, we will examine the effect of a plasticity-inducing therapy regime on the rehabilitation of upper limb impairment post-stroke. This study's main objective is to implement and evaluate neuroplasticity-inducing stimulation. The stimulation methods for inducing neuroplasticity have been selected based on prior preclinical and intraoperative work that has shown promise in providing rehabilitative benefits for stroke patients. We will be structuring this study as an open prospective feasibility study.
People living with the cognitive effects of stroke are at risk for recurrent stroke and further cognitive decline. Also problematic is that stroke risk clusters in families and biological family members of people who have ischemic stroke may also be at increased risk of stroke and/or cognitive decline. The primary goal of this study is to test the feasibility of a virtually delivered cognitive strategy training and health coaching program to reduce vascular risk and promote brain health in persons with stroke and their biological family members.
Early identification of intracranial atherosclerotic disease (ICAD) may impact the management of patients undergoing mechanical thrombectomy (MT). The aim of the study is to develop and validate a scoring system for pre-thrombectomy diagnosis of ICAD in posterior circulation large vessel/distal medium vessel occlusion strokes (LVOs/DMVOs).
This is a single-center, pilot study of up to 25 subjects with residual upper extremity deficits at least six months after an ischemic stroke. The purpose of the study is to evaluate the initial clinical safety, device functionality, and treatment effect of non-invasive electrical stimulation of the trigeminal and/or vagus nerves (nTVNS) using the NeuraStasis Stimulator System adjunctive to rehabilitation. Subjects will either receive the intervention or control-sham stimulation. The study will inform the design and implementation of a pivotal study.
Individuals surviving Chronic Ischemic Stroke have lingering walking deficits long after their infarct. The main goal of this study is to compare two high intensity treadmill walking programs to see which improves walking more. The main question we aim to answer is: How does blood flow restricted high-intensity treadmill training impact walking function? Participants will be randomly separated into two groups. One group will perform the high intensity treadmill training with blood flow restriction on their Stroke affected leg, while the second group performs high intensity treadmill training only. Every week participants will be asked to walk on the treadmill for a total of 75 minutes during 2x 1-hour sessions. On visit 1, participants will undergo strength, balance, and walking testing. They will then be treated 2x weekly for 4 weeks (visit 2-9) and be re-tested to track progress on visit 10. Participants will again be treated 2x weekly for 4 more weeks (visit 11-18) and be tested to see the end results on visit 19. Researchers will then compare both groups to see if blood flow restriction training changes walking function, strength, and balance.
The APPEND-CT registry is an investigator-driven multicenter retrospective observational database intended to compile cardiac CT follow-up data after Watchman FLX device implantation and function as a platform for answering clinical and research questions within LAAC follow-up. The derived studies should support therapeutic decision-making, improve risk-stratification in LAAC and help generate hypotheses for potential future clinical intervention trials.
The aim of this study is to compare the effectiveness of 6-weeks of reactive balance training (REACT) with and without neuromuscular electrical stimulation (NMES) to paretic lower limb muscles on biomechanical, clinical, neuromuscular and neuroplastic outcomes of reactive balance control. This project is a Phase-I study and incorporates a double-blinded, randomized controlled trial design. Methods: Forty-six individuals with chronic stroke will be recruited and screened for determining their eligibility for the study. Once enrolled, they will be randomized into either of the two groups: intervention group (23 participants) and control group (23 participants). Both groups will undergo series of pre-training assessments which includes a postural disturbance in the form of a slip- or trip-like perturbations and walking tests in laboratory environment. After the pre-training assessment, individuals will undergo 6-weeks of training (2 hour per session, 2 sessions per week). The intervention group will receive NMES with the REACT training and the control group will receive ShamNMES. NMES will be applied to the different muscle groups of the paretic lower limb using an advanced software which is able to synchronize muscle activation with the time of perturbation onset and according to the phases of gait. After training, both groups will again be tested on all the assessments performed pre training. This study will help us understand the immediate therapeutic and mechanistic effects of REACT+NMES and inform stroke rehabilitation research and clinical practice. Our study will provide foundational evidence for future use of NMES to implement clinically applicable neuromodulation adjuvants to reactive balance training, which could be leveraged for designing more effective future interventions for fall-risk reduction.
The purpose of this research is to better understand the impact of cortically-induced blindness (CB) and the compensatory strategies subjects with this condition may develop on naturalistic behaviors, specifically, driving. Using a novel Virtual Reality (VR) program, the researchers will gather data on steering behavior in a variety of simulated naturalistic environments. Through the combined use of computer vision, deep learning, and gaze-contingent manipulations of the visual field, this work will test the central hypothesis that changes to visually guided steering behaviors in CB are a consequence of changes to the visual sampling and processing of task-related motion information (i.e., optic flow).
The objective of this study is to evaluate the efficacy of the COOLSTAT® Transnasal Thermal Regulating Device in reducing temperature in a population of febrile subjects who meet the inclusion/exclusion criteria.
The purpose of this study is to evaluate the limb functional improvement after contralateral C7 root transfer in stroke patients.
The purpose of this study is to investigate the accessibility of beauty products for individuals with upper extremity disabilities. By examining various factors such as packaging design, product applicators, and ease of use, this research aims to identify barriers faced by individuals with upper extremity disabilities or visual deficits when using beauty products. The study seeks to provide insights and recommendations for improving the accessibility of beauty products, ultimately promoting inclusivity and enhancing the overall beauty experience for individuals with disabilities.
Atrial Fibrillation (AF) is an abnormal heart rhythm. Because AF is often asymptomatic, it often remains undiagnosed in the early stages. Anticoagulant therapy greatly reduces the risks of stroke in patients diagnosed with AF. However, diagnosis of AF requires long-term ambulatory monitoring procedures that are burdensome and/or expensive. Smart devices (such as Apple or Fitbit) use light sensors (called "photoplethysmography" or PPG) and motion sensors (called "accelerometers") to continuously record biometric data, including heart rhythm. Smart devices are already widely adopted. This study seeks to validate an investigational machine-learning software (also called "algorithms") for the long-term monitoring and detection of abnormal cardiac rhythms using biometric data collected from consumer smart devices. The research team aims to enroll 500 subjects who are being followed after a stroke event of uncertain cause at the Emory Stroke Center. Subjects will undergo standard long-term cardiac monitoring (ECG), using FDA-approved wearable devices fitted with skin electrodes or implantable continuous recorders, and backed by FDA-approved software for abnormal rhythm detection. Patients will wear a study-provided consumer wrist device at home, for the 30 days of ECG monitoring, 23 hours a day. At the end of the 30 days, the device data will be uploaded to a secure cloud server and will be analyzed offline using proprietary software (called "algorithms") and artificial intelligence strategies. Detection of AF events using the investigational algorithms will be compared to the results from the standard monitoring to assess their reliability. Attention will be paid to recorded motion artifacts that can affect the quality and reliability of recorded signals. The ultimate aim is to establish that smart devices can potentially be used for monitoring purposes when used with specialized algorithms. Smart devices could offer an affordable alternative to standard-of-care cardiac monitoring.
Acute ischemic stroke (AIS) is a treatable disease if patients can be transported and treated at stroke centers. MindRhythm, Inc (sponsor) has developed an investigational medical device that is designed for prehospital field use to differentiate the two major forms of acute ischemic stroke, namely Large Vessel Occlusion (LVO) stroke and non-large vessel occlusion stroke. The intended use is for paramedics to decide which destination hospital is best for the patient based on the device result. Large vessel occlusion stroke patients should be brought directly to comprehensive stroke centers which can perform thrombectomy, and non-large vessel occlusion stroke should be brought to primary stroke centers. Use of the device will save time getting the patient to thrombectomy and all others to intravenous thrombolytics or blood thinners that clear clots improves outcomes for all patients. The Harmony 5000 device manufactured by MindRhythm has been tested in the pre-hospital environment, but because large vessel occlusion stroke is less common than non-large vessel occlusion stroke, the sponsor wants to obtain additional recordings from patients with large vessel occlusion to better refine their algorithms. Investigators will perform acute recordings on patients who arrive at the medical center who have computed tomography angiography studies showing the presence of large vessel occlusion stroke stroke, and on patients transferred to the angiography suite for thrombectomy. Recordings are performed in parallel to standard workflow of large vessel occlusion stroke patients so the research will not delay treatments.
The purpose of this study is to evaluate whether milvexian compared to placebo reduce the risk of recurrent ischemic stroke.
The recovery from a stroke is often incomplete. It is the leading cause of acquired permanent disability in the adult population. Persistent functional loss of the hand and arm contributes significantly to disability. However, the current standard of care to treat hand and arm movements are inadequate. There is an urgent need for innovative and effective therapies for recovery of the upper limb after stroke. Growing evidence shows that electrical spinal cord stimulation, combined with activity-dependent rehabilitation, enables voluntary movement of paralyzed muscles in some neurologic disorders, such as spinal cord injury. The investigators hypothesize that spinal networks that lost control after stroke can be activated by non-invasive electrical stimulation of the spinal cord to improve functional recovery. The aims of the study are: 1. to determine the improvements in hand and arm function that result from the combined application of non-invasive spinal stimulation and activity-based rehabilitation. Surface electrodes placed over the skin of the neck will be used for non-invasive electrical stimulation of the spinal cord. Functional task practice will be used for activity-dependent rehabilitation, 2. to evaluate long-lasting benefits to hand and arm function that persist beyond the period of spinal stimulation.
This study aims to develop a neurophysiological marker for post-stroke participants that predicts upper extremity motor recovery in response to a standard upper extremity rehabilitation protocol of task-specific training (TST). For this aim, the researchers will utilize transcranial magnetic stimulation (TMS) combined with electromyography (EMG) and electroencephalography (EEG) to observe inpatients with stroke-related hemiplegia and follow their recovery through outpatient for up to 3 months. Motor-evoked potentials (MEPs), transcranial-evoked potentials (TEPs), action research arm test (ARAT) scores, and clinical outcome measures will be recorded at different time points of the inpatient rehabilitation period. The researchers hypothesize that changes in motor recovery will be reflected in changes in the MEPs and TEPs.
The investigators aim to examine whether amantadine can help patients recover from stroke. This will be a blinded randomized clinical trial (RCT). Patients will be randomized post-ischemic or hemorrhagic stroke either to the placebo arm or amantadine arm. Patients will be on study drug or placebo for 1 month but will be enrolled for 3 months total. At various time points patients will be examined and fill out questionnaires to determine level of stroke recovery.
Dysphagia is a serious cause of morbidity and mortality in stroke survivors. Electrical stimulation is often included as part of the treatment plan for dysphagia, and can be applied at a sensory or motor level intensity. However, evidence to support these different modes of stimulation is lacking. This study compared the effectiveness of sensory and motor level stimulation on post-stroke dysphagia.
Ischemic stroke is the leading cause of long-term disability in the United States. Endovascular intervention with mechanical thrombectomy has become the standard of care for acute large vessel occlusion (LVO) stroke since multiple clinical trials demonstrated improved long-term clinical outcomes with treatment. However, despite high rates of successful vessel recanalization and thus reperfusion of ischemic brain tissue in current practice, many patients continue to suffer debilitating strokes and poor long-term functional outcome. Pharmacologic neuroprotection could potentially present a means of addressing this mismatch in radiologic vs. clinical outcomes by protecting and salvaging damaged brain tissue. Intra-arterial delivery of a cocktail of neuroprotective therapy at the time of endovascular reperfusion would provide immediate, targeted therapy directly to the damaged brain territory. Hypothermia, minocycline and magnesium can target multiple facets of the complex ischemic injury cascade, and have each demonstrated neuroprotection in multiple preclinical models. This is a phase I trial that aims to demonstrate safety and feasibility of administering cold saline, minocycline, and magnesium sulfate intra-arterially immediately after thrombectomy in stroke interventions.
The investigators would like to investigate the effectiveness of somatosensory training for robot-assisted hand motor rehabilitation after stroke.
This research aims to examine changes in plastic potential of the visual system with time from stroke affecting primary visual cortex. We will measure structural and mechanistic aspects of progressive degeneration along the early visual pathways, correlating them with changes in visual performance, and in responsiveness to visual restoration training. This project will advance both scientific knowledge, as well as technical capability and clinical practices for restoring vision and quality of life for people suffering from cortical blindness.
A Phase II, randomized, blinded, placebo-controlled, parallel group study with patients experiencing a large vessel occlusion acute ischemic stroke who are selected for endovascular revascularization. Participants will be given a 48 h infusion of either 0.5 mL/kg/h RNS60 (up to a maximum of 60 mL/h), 1 mL/kg/h RNS60 (up to a maximum of 120 mL/h), or 1 mL/kg/h (up to a maximum of 120 mL/h) placebo (normal saline) starting within 30 minutes of consent after confirmation of candidacy for endovascular thrombectomy.
The objective of this study is to evaluate the impact of Viz LVO in hospital systems with non-interventional and interventional (spoke and hub) stroke centers on the timing and outcomes of patients with suspected acute ischemic stroke indicated for mechanical thrombectomy.
Stroke is the third leading cause of death and the first cause of physical disability and dementia worldwide. Ischemic stroke caused by large vessel occlusion (LVO) is responsible for the vast majority of deaths and disabilities. A very effective and safe treatment, called mechanical thrombectomy (MT) is available for LVO patients. Nevertheless, no blood biomarkers able to identify LVO patients rapidly and to direct them to CT angiography and thrombectomy currently exist. The TIME study is an observational prospective cohort study. All Patients referred to the emergency department or stroke unit with a suspected stroke as identified by paramedics, nurses or clinicians will be enrolled in the study. A panel of blood biomarkers will be analysed retrospectively via standard laboratory assays. The main outcome of the TIME study will be the evaluation of the clinical diagnostic performance of a panel of blood biomarkers, in conjunction with clinical data, for the identification of large vessel occlusion ischemic stroke subtype. This study will allow the identification and evaluation of a final panel of biomarkers and will prompt the development of a test for LVO stroke diagnosis.
The brain is able to change throughout life in response to learning, or injury, or to adapt to changes in the environment, which is known as neuroplasticity. Stroke survivors suffer disabling chronic motor impairments that have proven challenging to improve. Increasing neuroplasticity using selective serotonin reuptake inhibitors (SSRIs) is a promising approach to promote motor recovery in patients with stroke.
The primary objective of this study is to demonstrate safety and effectiveness of the Penumbra System in a population with acute ischemic stroke (AIS) secondary to intracranial large vessel occlusion (LVO).
This multiple ascending dose study assesses the safety, tolerability and pharmacokinetics of NP10679 when delivered intravenously in escalating dose levels in comparison to placebo.