View clinical trials related to Stroke.
Filter by: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.
Thrombus shedding in patients with atrial fibrillation (AF) can lead to cerebral artery embolism. Stroke caused by AF is very dangerous, which not only threatens the life of patients, but also seriously affects the quality of life. This study aims to explore the biomarkers of stroke in patients with AF by integrating proteomics and metabolomics data, and establish the network relationship of stroke in patients with AF, so as to reveal the molecular mechanism of stroke in patients with AF.
In the current project, primary health care patients with mental illness such as anxiety, depression, fatigue or sleep disorders will be followed. The study includes both health conversations with the health curve as a systematic work with lifestyle habits, and the biochemical risk marker copeptin with a focus on improved lifestyle habits and the development of cardiovascular complications. Participants will be followed up at 12 and 24 months with renewed health interview including the health curve and blood sampling. National registries will be used for a, up to 20 year long follow-up regarding cardiovascular complications and mortality.
This study is being done to see how errors lead to improvement. Specifically, we are evaluating the errors stroke participants make during an upper extremity exercise program when reaching for a target using their affected arm. Once we understand the participant's reaching errors, we plan to create a customized reaching exercise according to the individual's specific error tendencies which will lead to better performance on movement ability after training.
Spasticity, or greater muscle resistance, is a major disabling condition following stroke. Recovery of lost motor function in patients with stroke may be affected by spasticity, which most commonly develops in elbow and ankle muscles. However, despite its clinical relevance, the natural development of spasticity over the first 3 months after stroke is not clearly understood. Indeed, common clinical measures of spasticity such as the Modified Ashworth Scale (MAS) do not take into account the neurophysiological origin of spasticity and lack reliability and objectivity. The objective of this study is to examine the natural history of the development of spasticity among patients with stroke over the first 3 months using a new neurophysiological measure (TSRT, the tonic stretch reflex threshold angle) and its velocity sensitivity (mu) in comparison to MAS and other common clinical tests. In addition, detailed brain imaging will be used to understand the relationship between damage to brain regions relevant to the development of spasticity and TSRT/mu values. It is hypothesized that 1) TSRT/mu will indicate the presence of spasticity earlier than MAS/clinical tests; 2) TSRT/mu measures will be more closely related to motor impairments and activity limitations than MAS; 3) the lesion severity (identified by imaging) will be related to the change in TSRT/mu values. Outcomes will be measured in a pilot cohort of 12 patients hospitalized for first-ever stroke. Measurements will be taken at the bedside within the 1st week of the patient's admission and will be done once per week for 12 weeks with a follow-up at week 16. Brain Imaging will be done around the 6th week post-stroke.
The purpose of the study is to test the technical functionality, safety, and feasibility of a bimanual robotic exoskeletal platform and associated serious games in order to offer information on technological and functional advances that will be included in the device's finalization. In addition, a secondary goal will be to assess the therapeutic effects of a rehabilitation therapy based on the bimanual configuration, comparing it to a unimanual treatment delivered on the same platform (using the specific configuration).
The CLEVER Study is a prospective, 2-arm, randomized, single-center pilot study to assess the safety and efficacy of intensive blood pressure control using Clevidipine (on-label use) in AIS patients undergoing standard of care mechanical thrombectomy (MT) within 24-hours of symptoms onset.
Stroke is the leading cause of serious, long-term disability. The emergence of abnormal muscle synergies following a stroke presents a major limitation to the recovery of independent function. Despite the development of many interventions for movement recovery post-stroke, rehabilitation treatments are minimally effective to the muscle synergy impairment. Previous studies have found that muscle synergy impairment is associated with the damage to the corticospinal tract and the maladaptive recruitment of the contralesional cortico-reticulospinal tract. The investigators hypothesize that facilitating the damaged cortico-spinal tract (via primary motor cortex) and/or inhibiting the contralesional cortico-reticulospinal tract (via dorsal premotor cortex) will reduce muscle synergy impairment. In this pilot project, the investigators propose to run a proof-of-concept pilot trial to evaluate the effect of the targeted high-definition transcranial direct current stimulation (HD-tDCS) on mitigating muscle synergy impairment.
Background: Stroke is a common cause of morbidity, including paresis, and stroke survivors often have reduced function in their paretic arm. Many do not regain full recovery of their arm function, which negatively impacts their quality of life. Recent studies have indicated that robotic training may improve upper limb function abilities among stroke survivors, by enabling repetitive, adaptive, and intensive training and more accurate control of task complexity. Robotic training in addition to standard rehabilitative care has shown promise for improving functional skills among stroke survivors. One type of robotic training is error enhancement, whereby an error made by the patient is exaggerated, increasing the signal to noise ratio which causes errors to be more noticeable. This, in turn, enhances movement correction. Previous studies have found that error enhancement has promise as a clinical treatment for patients with motor deficits. Objectives: This study aims to evaluate the effect of a robotic device (DeXtreme) on the functional capabilities of the paretic arm of stroke survivors. This device aims to improve arm function by utilizing error enhancement techniques. Methods: A double-blind randomized placebo-controlled study comparing treatment outcomes between two groups to assess the effect of error enhancement robotic training on functional use of the arm and hand in patients after stroke. Forty stroke patients will undergo 6 sessions of 25 minutes each with the Dextreme device. One group will receive training with error enhancement forces applied, while the control group will receive similar training without error enhancement. Outcomes (motor function, speed, tone, and spasticity) will be assessed twice prior to and following the treatment sessions,
This study has two interventional components, the first is a cross-over design and the second is a randomized control trial. Both will evaluate the effectiveness of transcutaneous (non-invasive) spinal cord stimulation on gait and balance function for individuals with hemiplegia due to stroke.