View clinical trials related to Stroke.
Filter by:The aim of this work is to elaborate a statistical model to predict the effectiveness of robotic treatment in subjects with neurological diseases. The model will be used to understand which subjects are most responsive to this type of treatment
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.
Stroke has been considered one of the main causes of long-term disability in the adult population. Technological advances in the neurological area have been observed in the last decades, which accentuates the interest in promoting non-invasive stimulation techniques, capable of modulating brain polarity, where among these techniques is the transcranial direct current stimulation - tDCS. Previous studies analyzed by systematic reviews suggest that the effects of tDCS may vary between individuals, where some stroke patients may not receive any additional benefit from the therapy. Thus, it is necessary to use a biomarker that can choose those that will possibly benefit from the electric current. Therefore, the aim of this study is to identify the dynamics of EEG microstates after tDCS and dual-task training in subjects after chronic stroke, as well as to assess how microstate parameters in stroke patients are altered by tDCS and dual-task training. at three different moments (Stimulation in M1 + dual-task training; Stimulation in M1 and DLPF + dual-task training; Sham stimulation) and to observe whether the microstates encode information that reflects the motor and/or cognitive capacity of these patients.
This research program aims at investigating the effects of upper-limb robotic therapy primed with interactive exergaming as an innovative hybrid regimen in stroke rehabilitation.
The Bio-Repository of DNA in Stroke (BRAINS) recruits all subtypes of stroke as well as controls from two different continents, Europe and Asia. Subjects recruited from the United Kingdom (UK) will include stroke patients of European ancestry as well as British South Asians. Stroke subjects from South Asia will be recruited from India and Sri Lanka. Subjects are also recruited in Qatar. South Asian cases will also have control subjects recruited.
Stroke is closely associated with high mortality among patients in hospitals and immobility leading development of deep vein thrombosis (DVT) leading to pulmonary embolism (PE) and Venous thromboembolism (VTE) and/or ankle joint contracture, which impairs mobility resulting in bedridden. Worldwide, the incidences of DVTs is 0.75-2.69 per 1000 individuals and 2-7 per 1000 for individuals aged > 70 years and accounts for 600,000-800,000 deaths yearly. Pharmacological treatment for DVTs include anti-coagulants to prevent blood clot development and VTE but may cause haemorrhagic stroke leading to death. Non-invasive treatment such as intermittent pneumatic compression (IPC) and anti-embolism stockings may prevent DVT but not ankle joint contractures, which affects 50% of all stroke patients. Joint contractures exacerbate pedal edema and fluid retention, hamper proper joint movement and decreases ADLs and quality of life. Regular physiotherapy is vital for preventing ankle joint contracture and DVT but is labour intensive hence posing an increased workload on physiotherapists resulting in decreased physiotherapy duration. This study will investigate the use of an automated robot-assisted ankle exercise solution (Venous Assistance and Contracture Management System, VACOM) to mimic therapist-assisted on bed passive ankle exercises to preclude the development of ankle joint contracture and facilitate venous flow in lower extremities to reduce DVT risk. The investigators hypothesize that the Venous Assistance and Contracture Management (VACOM) system can prevent ankle contracture, improve ankle range of motion (ROM) and flexibility while reducing the risk of DVT incidence among stroke patients more than using IPC alone. Additionally, through early ankle mobilization, rehabilitation can be optimized to achieve better neurological recovery.
Minocycline is the second generation of tetracycline. Because of its lipophilicity, it has high penetrance of blood-brain barrier. Animal model studies have shown that minocycline can reduce cerebral damage after ischemic stroke, and its mechanism involves multiple molecular pathways, such as antioxidant, anti-inflammatory, anti apoptotic pathways, and protection of blood-brain barrier. Clinical studies have also shown that minocycline can significantly improve 3-month National Institute of Health Stroke Scale (NIHSS) and modified Rankin Scale (mRS) of patients with ischemic stroke, indicating that minocycline is a potential neuroprotective drug. Minocycline is believed to protect the blood-brain barrier, thereby reducing the ischemia-reperfusion injury caused by mechanical thrombectomy. However, whether minocycline can become a synergistic treatment method of mechanical thrombectomy, there is no clinical research in this area at present. Therefore, investigators carry out the study on the effect of minocycline in patients with acute anterior circulation ischemic stroke after mechanical thrombectomy, and plan to enroll 180 patients. To explore the safety and effectiveness of minocycline in patients with acute ischemic stroke after thrombectomy.
This is a two phase prospective observational study that aims to validate the use of a motion capture software (Leap Motion) to measure and quantify functional deficits of the hand in stroke patients using a standard battery of exercises. The objectives of this study are: 1. To compare the differences between results of hand kinematic computational analysis in patients with ischemic stroke and healthy subjects. 2. To analyze the relation between hand kinematic computational analysis and clinical scales usually performed to evalutate neurologic deficits in stroke patients. 3. To analyze the relation between hand kinematic computational analysis and stroke lesion on brain MRI. 4. To analyze changes between results of hand kinematic computational analysis in the acute phase of stroke and at three months, and its relation with evolution of neurological evaluation clinical scales, functional clinical scales and quality of life.
This is an observational, prospective, multicenter, cohort study in patients with cardioembolic stroke and previous oral or parenteral anticoagulant therapy. Patients in which anticoagulante therapy is mantained will be compared to those in which it is interrupted, in terms of stroke or systemic embolism and haemorrhagic transformation.
The ARIES study is an observational study in which patients with a recent acute ischemic stroke of cryptogenic aetiology are consecutively enrolled in order to perform a extensive cardiologic work-up. The main objective is to study parameters that could predict arrythmias on prolonged monitoring and also echocardiographic parameters of left atrial disfunction that could predict the presence of a hidden atrial fibrilation and recurrent ischemic events in patients with cryptogenic stroke.