View clinical trials related to Ischemic Stroke.
Filter by:Patients who have suffered a stroke are having an increased risk of having recurrent stroke in the future. This risk of stroke is increased by atrial fibrillation, which often "comes and goes" (called paroxysmal) and hence escapes routine diagnostics. The hypothesis of Find-AF 2 is that enhanced (evaluation in a ECG core lab), prolonged (at least 7 days of rhythm monitoring annually) and intensified (continuous rhythm monitoring in high risk patients) not only finds atrial fibrillation more often, but that changes in therapeutic management (e. g. start of anticoagulation after detection of atrial fibrillation) results in a decrease of cardioembolism (which can be either recurrent stroke or systemic embolism). To prove this hypothesis, patients will be randomised into two groups: the first group will receive the currently available standard care for patients with stroke. In the second group, cardiac rhythm monitoring adapted to the risk of the occurrence of atrial fibrillation is performed - either with a 7-day long-term ECG (at baseline, after 3 and 12 months and every 12 months thereafter) or with continuous monitoring using an implantable cardiac monitor. If atrial fibrillation is detected, this information will be given to the treating study physician. Any therapeutic decision is at the discretion of the treating physician, but should follow current guidelines.
DETERMINE is a multicenter, prospective, randomised, open, blinded end-point assessed (PROBE) trial, to evaluate two approaches of blood pressure (BP) management during mechanical thrombectomy for acute ischemic stroke due to an anterior large vessel occlusion.
The purpose of this research study is to discover the functions of circulating white blood cells, called monocytes, and associated circulating substances in heart attack and ischemic stroke patients. Ischemic Strokes (clots) occur as a result of an obstruction within a blood vessel supplying blood to the brain. A type of monocyte carrying a surface marker called "P2X4" helps the immune system sense and respond to danger signals from the body such as heart muscle and brain tissue injuries. The researchers expect to learn more about how these monocyte cells react to heart and brain tissue injury, and how the cells may then produce proteins or other chemical substances which promote the healing of heart muscle after heart attack and brain tissue after an ischemic stroke.
Preclinical research has established a convincing connection between changes in the gut microbiota composition and stroke outcome. However clinical data on the gut-brain axis, and its chronic characteristics, is sparse. Additional investigations in the context of ischemic stroke regarding the relationship between dysbiosis and functional changes of the microbiome, as characterized by the metabolome, are still required. The StrokeMicroBiomics study will offer insight into these mechanisms and offer new potential targets for therapeutic interventions. The primary objective is the characterisation of gut dysbiosis in ischemic stroke patients in the acute phase after stroke and during a 3 month follow-up period. The secondary objectives include the identification of dysregulated gut microbiome metabolites and key immune cell populations in addition to the clinical progression of the study participants during the 3 month follow-up period after disease onset.
Hemodialysis is a therapeutic strategy used in subjects with chronic renal failure. Our working hypothesis is based on results published in experimental animal models of stroke where the investigators have demonstrated that peritoneal dialysis is an effective technique to reduce blood glutamate levels and reduce infarct volume. The objective of this clinical trial is to evaluate the viability, safety and efficacy of hemodialysis in patients with acute ischemic stroke, proposing that it may have a) a potential neuroprotective effect by reducing the excitotoxic levels of glutamate and proinflammatory cytokines in blood and b) fewer technical problems than peritoneal dialysis to apply in usual clinical practice.
CEST in Stroke is an observational magnetic resonance imaging (MRI) study in acute ischaemic stroke patients. Ischaemic stokes are the most common type of stroke and occur when a blood clot blocks the flow of blood and oxygen your brain needs. This can lead to cellular death (infarction) so the quicker a stroke is diagnosed and treated, the better a patient's recovery is likely to be. The purpose of this study is to determine the technical feasibility of a new MRI technique known as Chemical Exchange Saturation Transfer (CEST) imaging for assessing the extent of potentially salvageable brain tissue (penumbra) around an area of infarction. CEST imaging works by looking at the chemicals in the brain cells. The chemicals may change when cells are affected by stroke. Stroke patients are not normally treated with with clotbusting drugs or clot-retrieving devices if they arrive at hospital many hours after the stroke because treatment may not help and in some cases it may cause more harm than good. However, the new MRI technique could detect those stroke patients who arrive at hospital many hours after the stroke but still have salvageable brain - in these cases it would be helpful to treat these patients and therefore stop those cells from dying. However, there are several technical issues that need to be addressed before CEST can be adopted as a routine clinical assessment. CEST in Stroke hopes to address these issues by using an alternate MRI sequence capable of acquiring CEST data over a large portion of the brain in approximately in 10 minutes. The overall aim of study is to determine the feasibility of CEST imaging for assessing the extent of penumbra, in order to determine which patients may benefit from re-perfusion interventions who would otherwise not be eligible. If the study is successful, further research will be implemented to help clinical decision making in stroke patients who present outside of conventional time windows.
This is a multicenter, doble blind, placebo controlled clinical trial to asses de safety and efficacy of intravenous administration of alogenic adipose tissue-derived mesenchymal stem cells in the first four days from acute ischemic stroke.
There are over 7 million stroke survivors in the US alone, with approximately 795,000 new cases annually. Despite the best available physiotherapy, 30-60% of stroke survivors remain affected by difficulty walking, with foot weakness often being the main cause. Given that post-stroke gait impairments remain poorly addressed, new methods that can provide lasting improvements are necessary. Brain-computer interface (BCI) technology may be one such novel approach. BCI technology enables "direct brain control" of external devices such as assistive devices and prostheses by translating brain waves into control signals. When BCI systems are integrated with functional electrical stimulation (FES) systems, they can be used to deliver a novel physical therapy to improve movement after stroke. BCI-FES systems are hypothesized to stimulate recovery after stroke beyond that of conventional physical therapy.
EVTRNA is to analyze the differentiated expression pattern of circular RNA (circRNA), long non-coding RNA (lncRNA) and micro-RNA (miRNA) by next-generation sequencing in acute ischemic stroke patients before and/or after endovascular treatment. The candidate circRNA/lncRNA/miRNA will be verified as the biomarker and regulator for progression and prognosis of acute ischemic stroke with endovascular treatment. Further, the candidate non-coding RNA will be used to evaluate the effect of endovascular treatment on both peripheral and central immune after stroke.
The purpose of this pilot study is to assess the feasibility of implementing a home blood pressure self-management program in a population of recent stroke survivors in the Washington, D.C. area. The investigators hypothesize that hypertensive stroke survivors in the Washington, DC area who participate in the Home Blood Pressure Monitoring program will have a greater reduction in mean systolic blood pressure (SBP) from baseline to 3 months, as measured by automated office blood pressure (AOBP), as compared to usual care.