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Stroke clinical trials

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NCT ID: NCT02405143 Not yet recruiting - Stroke Clinical Trials

Restoration of Vision After Stroke

REVIS
Start date: April 2015
Phase: N/A
Study type: Interventional

Occipital stroke is associated with homonymous visual field defects (occurring on one side of the visual field). Despite spontaneous recovery, some degree of defect is often permanent. Currently, no treatment exists for such visual field defects.The purpose of this study is to test the efficacy of a type of electrical brain stimulation method, transcranial alternating current stimulation, in reducing these type of visual field defects in their chronic stage.

NCT ID: NCT02404857 Completed - Clinical trials for Poststroke/CVA Hemiparesis

BCI Post-stroke Neurorehabilitation

BCI-stroke
Start date: January 2015
Phase: N/A
Study type: Interventional

The goal is to evaluate the potential of a EEG based BCI (Brain-Computer-Interface) connected to a non-invasive pneumatic glove for rehabilitation of hand-movements post-stroke.

NCT ID: NCT02403349 Active, not recruiting - Ischemic Stroke Clinical Trials

Comparison of Peripheral and Cerebral Arterial Flow in Acute Ischemic Stroke: Fimasartan vs. Valsartan vs. Atenolol

FAVOR
Start date: May 2012
Phase: Phase 4
Study type: Interventional

Confirm central blood pressure reduction effect of Fimasartan, Valsartan and Atenolol and compare correlation with the measured peripheral (central blood pressure, pulse wave velocity, and flow-mediated dilation) and cerebral blood flow factors (transcranial doppler findings, cerebral blood flow volume) in acute ischemic stroke patients with hypertension.

NCT ID: NCT02401724 Not yet recruiting - Stroke Clinical Trials

NonInvasive Brain Stimulation in Stroke Patients

RTNIBS
Start date: March 2015
Phase: N/A
Study type: Interventional

After a stroke affecting the right side of the brain, many patients are affected by "spatial neglect": the damage to the brain causes them to ignore the left side of their surroundings. At its most extreme they may be unaware that they have a left side, or believe that it is moving normally when it is in fact paralysed. In milder cases, people may be unable to recognise touch on the left side if their right side is also being touched, or objects in their left visual field if something is visible to their right. Neglect alters peoples' quality of life profoundly, often renders them more dependent on others to undertake basic activities of daily living, and makes effective rehabilitation much more difficult. The limited success of current treatment approaches indicates gaps in understanding of the underlying mechanisms of neglect and its recovery. Recent data suggest that the problems in responding to the left side are a result of an imbalance of activity in those parts of the brain responsible for deciding which side to pay attention to. It might therefore be possible to help people with neglect by "rebalancing" the brain either by increasing activity in the damaged side, or alternatively by reducing activity in the undamaged side. In this pilot study, the investigators will test whether they can help by doing the second of these things. The investigators propose to conduct a pilot clinical trial to explore whether using electric currents to temporarily modify the activity of specific areas of the intact side of the brain, influences recovery from neglect, when used either alone, or in combination with a training method that has previously appeared promising as a treatment. Brain activity will be modified using a technique called "transcranial direct current stimulation (tDCS)", in which small electric currents are applied to the scalp with a wire covered in damp cotton pads. This will be done over the specific parts of the brain that are responsible for focusing attention to one side. The investigators will compare the clinical outcomes of four interventions (1: behavioural, 2: tDCS, 3: a combination of both and 4: control). The investigators hope that these studies will advance their understanding of what treatments may help people with neglect, and how they might work.

NCT ID: NCT02401698 Suspended - Stroke Clinical Trials

Exploring Cerebellar Inhibition of the Motor Cortex in Stroke Patients

Start date: December 2014
Phase: N/A
Study type: Observational

The past 10 years of research in post stroke patients have shown certain types of rehabilitation can help neuronal plasticity of the brain. Transcranial magnetic stimulation (TMS) can be used to monitor this plasticity by mapping the brain's function (measuring brain activity). Recent research suggests that TMS can be used for both prognosis (determining future function) and to determine what type of rehabilitation therapy will work best after stroke. The purposes of this research study are to: 1) determine changes in cerebellar activity after motor cortical stroke 2) compare changes in recovery of motor function with changes in cerebellar - motor cortex connections; 3) determine the ability of TMS to "predict" functional outcome after stroke. The primary hypotheses are: 1) functional recovery will be correlated with TMS changes (as measure of motor threshold (MT), intracortical inhibition, cerebellar cerebral inhibition (CBI), motor evoked potentials (MEPs) and recruitment curves; 2) baseline TMS will predict future functional outcomes.

NCT ID: NCT02400138 Completed - Stroke Clinical Trials

Home-based Respiratory Training After Stroke

Start date: February 2016
Phase: N/A
Study type: Interventional

Weakness of the respiratory muscles demonstrated by individuals with stroke, may generate important symptoms, such as fatigue and dyspnea. Since adequate strength of the inspiratory and expiratory muscles is required, mainly when performing physical activities, rehabilitation interventions for stroke subjects should include respiratory training. This study will test the hypothesis that home-based combined training of the inspiratory and expiratory muscles is effective in improving strength of the inspiratory and expiratory muscles, endurance of the inspiratory muscles, dyspnea, walking capacity, and ocurrence of respiratory complications after stroke. For this clinical trial, people after stroke will be randomly allocated into either experimental or control/sham groups. The experimental group will undertake training of the inspiratory plus expiratory muscles with the Orygen Dual Valve device, regulated at 50% of the subjects' maximal inspiratory and expíratory pressure values, seven times/week over eight weeks during 40 minutes/day. The control group will undertake the same protocol, but the participants will receive the devices without resistance. At baseline, post intervention, and four weeks after the cessation of the intervention, researchers blinded to group allocations will collect the following outcome measures: maximal inspiratory and expiratory pressures, inspiratory endurance, dyspnea, walking capacity, and ocurrence of respiratory complications.

NCT ID: NCT02399904 Completed - Clinical trials for Post Stroke Shoulder Subluxation

Effect of California Tri-pull Taping Method on Shoulder Subluxation, Pain, Active Range of Motion and Upper Limb Functional Recovery After Stroke - A Pre Test Post Test Design

CTPT
Start date: November 2012
Phase: Phase 1
Study type: Interventional

This study was conducted to check the effect of California tri-pull taping method on post stroke shoulder subluxation, prior to conduct a large randomized clinical trial this study was conducted, and the result of the study was promising for the treatment of shoulder subluxation.

NCT ID: NCT02399540 Completed - Stroke Clinical Trials

Late LTP-like Plasticity Effects of tDCS in Chronic Stroke Patients

Start date: March 2015
Phase: N/A
Study type: Interventional

Rationale: About 80% of stroke patients suffer motor impairments, but current therapies have limited effects on motor recovery. Therefore, investigating new potential therapeutic approaches is crucial. Transcranial Direct Current Stimulation (tDCS) is a form of non-invasive electrical stimulation where a weak current is applied through electrodes over the scalp. This stimulation is known to (1) induce changes in neuronal excitability -which can last up to one day with late LTP-like plasticity protocols- in a polarity and site-specific manner, and (2) facilitate motor learning and stroke recovery. However, it is unknown how the motor cortex excitability changes that follow tDCS relate to the increase in motor learning and recovery potential. The currently upheld hypothesis is that motor learning needs to be synchronized in time with electrical stimulation (paired stimulation), but recent results from our lab suggest that tDCS also increases skill learning after stimulation has ended (unpaired stimulation). If this is true, tDCS has a much larger therapeutic window and is a more valuable clinical tool than currently believed. Therefore, the investigators want to investigate how late LTP-like plasticity tDCS affects the increase in skill learning normally seen with tDCS when applied 24 hours before training. The outcome of this study can provide important guidelines on effective motor therapy during stroke rehabilitation. Objective: Identify the effect of late LTP-like plasticity tDCS in chronic stroke patients on skill learning 24 hours later. Study design: Double-blinded, randomized between-subjects trials. Study population: Chronic stroke patients. Main study parameters/endpoints: The main objective of the study is to determine the effect of late LTP-like plasticity tDCS on skill learning 24 hours later. As a motor learning paradigm, the investigators will use a circuit tracking task which chronic stroke patients perform better if tDCS is applied concurrently. During this task, patients have to trace a cursor over a circuit as fast and accurately as possible by moving a computer mouse. Skill will be quantified by calculating a combined speed/ accuracy score and skill improvement compared to baseline (LI; the learning index) will be compared between the sham, conventional unpaired tDCS, conventional paired tDCS groups and the late LTP-like plasticity tDCS groups.

NCT ID: NCT02398656 Active, not recruiting - Stroke, Acute Clinical Trials

A Randomized Controlled Trial of TNK-tPA Versus Standard of Care for Minor Ischemic Stroke With Proven Occlusion

TEMPO-2
Start date: April 2015
Phase: Phase 3
Study type: Interventional

This trial will enroll patients that have been diagnosed with a transient ischemic attack (TIA) or minor stroke that has occurred within the past 12 hours. Anyone diagnosed with a minor stroke faces the possibility of long-term disability and even death, regardless of treatment. Stroke symptoms such as weakness, difficulty speaking and paralysis may improve or worsen over the hours or days immediately following a stroke. TEMPO-2 is a minor stroke trial for patients presenting within 12 hours of their symptom onset. Patients will be randomized to TNK-tPA or standard of care. In the intervention group TNK-tPA is given as a single, intravenous bolus (0.25mg/Kg) immediately upon randomization. Maximum dose 50mg. The control group will receive antiplatelet agent(s) as decided by the treating physician. Antiplatelet agent(s) choice will be at the treating physician's discretion. TEMPO-2 Coordinating Centre is located in Calgary, AB, Canada. There will be approximately 50 sites participating worldwide. Dr. Shelagh Coutts is the Principal Investigator.

NCT ID: NCT02398409 Completed - Stroke Clinical Trials

Informal Caregivers ANSWERS-VA

Start date: November 3, 2014
Phase: N/A
Study type: Interventional

The purpose of this study is to determine the effectiveness of the ANSWERS- VA intervention (Acquiring New Skills While Enhancing Remaining Strengths for Veterans) while also determining it's cost effectiveness in the stroke and traumatic brain injury (TBI) populations.