View clinical trials related to Cerebrovascular Disorders.
Filter by:This study is a prospective, single arm, single-center study to evaluate the safety and feasibility of the Remedy Robot for on premise and remote robotic Neurointervention.
Enhanced recovery after surgery (ERAS) is a strategy of perioperative management aimed to accelerate the rehabilitation of patients through various optimized perioperative managements as well as ongoing adherence to a patient-focused, multidisciplinary, and multimodal approach. Alleviating the injury and stress caused by surgery or disease is the core principle of ERAS, which has been shown to reduce complication rates after surgery, promote patient recovery, decrease hospital length of stay and reduce costs. ERAS has been widely applied in many surgical perioperative fields, and it has achieved remarkable effects. However, there are few applications of ERAS in neurosurgery, especially in clinical trials of neurocritical care patients. Therefore, the investigators attempt to conduct the study of ERAS in neurosurgical intensive patients using a series of optimized perioperative managements that have been verified to be effective by evidence-based medicine, and to evaluate the safety and effectiveness of ERAS in neurocritical care. The aim of this study is to explore the most suitable ERAS protocols to accelerate the postoperative rehabilitation process of neurocritical care patients, and to provide more evidence-based medicine for the effectiveness and safety of ERAS in neurosurgery.
The proposed study will generate a national mapping of healthcare utilization patterns in people post-stroke in the chronic phase living in the community; examine the associations between individual-level characteristics, health outcomes and healthcare utilization; and will describe patients' perspectives on their needs for health services and their experiences of using them. The study will use mixed-methods methodology (quantitative and qualitative) and will proceed in three parts. In part 1, data will be extracted retrospectively from electronic medical records of of Clalit Health Services, covering all patients with a stroke diagnosis. In part 2, a sub-sample of 240 patients will be asked to answer standardized questionnaires. In part 3, a sub-sample of 20 participants will participate in in-depth, semi-structured interviews.
The etiology and specific pathogenesis of many cardiovascular diseases such as coronary atherosclerosis, cardiomyopathy, atrial fibrillation, and stroke are still unclear. Improving diagnosis and treatment, clarifying the pathogenesis, and providing scientific basis for the prevention and treatment are hot research topics in the study of cardiovascular and cerebrovascular diseases. This study intends to collect clinical data and biological specimen data of patients with cardiovascular and cerebrovascular diseases who meet the inclusion and exclusion criteria, and use multi-omics technology to deeply understand the pathogenic mechanisms of cardiovascular and cerebrovascular diseases and provide new ideas for specific and individualized treatment of patients with cardiovascular and cerebrovascular diseases, to construct early predictive prognostic models and provide a basis for effective treatment of clinical practice in patients with cardiovascular and cerebrovascular diseases.
The primary aim of the study is to develop a national registry of cerebrovascular diseases in order to define the subtypes of these diseases associated with a worse prognosis. Secondly, the study aims to find clinical, radiological, and biological markers capable tof predicting the outcome of cerebrovascular diseases and the onset of complications related to therapeutic procedures, and to calculate predictive prognostic scores composed of multiple variables. Each participating center will collect clinical, radiological, and biological data from the medical records of the study participants. Patients included in the study will not undergo any additional medical procedures to those of normal clinical practice.
The management of small unruptured intracranial aneurysms (UIA) with ischemic cerebrovascular disease (ICVD) has been a very controversial topic in neurosurgery. Thus, we initiated a multicenter, prospective, randomized controlled trial (PROBE) design to elucidate in UIA patients with ICVD who do not qualify for preventive endovascular or neurosurgical intervention whether aspirin treatment decreases the risk of aneurysm growth and rupture.
The specific study aims will be: 1. To design and develop the hardware and software of the VR+MT and MR+MT systems. 2. To test the feasibility of the VR+MT and MR+MT systems from the patients and to collect the feedback of users with respect to their experiences. 3. To examine the treatment effects of VR+MT and MR+MT compared to the traditional MT (i.e., control group) in patients with stroke by conducting a randomized controlled trial. 4. To identify who will be the possible good responders to VR+MT and MR+MT based on their baseline motor functions and mental imagery abilities.
Multicentre, prospective, Multi-arm Multi-stage (MAMS) seamless phase 2b/3 interventional randomized placebo-controlled double-blinded parallel-assignment (2 arms with 1:1 randomization) efficacy and safety trial to test intra-arterial tenecteplase at the completion of thrombectomy versus best practice in participants with anterior circulation LVO receiving mechanical thrombectomy within 24 hours of symptoms onset.
The purpose of this study is to determine the safety and feasibility of using inhaled nitric oxide (iNO) in patients undergoing intra-arterial mechanical thrombectomy (blood clot extraction or IAMT) for treatment of acute ischemic (non-bleeding) stroke (AIS).
To explore the pathogenesis of cardiovascular and cerebrovascular diseases through study on cardio-cerebral integration based on multimodal imaging technology, and clinical evaluation of its secondary diseases and intervention treatment. Cardiovascular and cerebrovascular diseases are leading causes of death and disability worldwide. Atherosclerosis of the large arteries of the brain and the heart has received extensive attention and in-depth research. By contrast, the epidemiology of small-vessel disease (SVD) of the brain and heart is less well established. The vascular anatomy of the heart and brain is similar in that conduit arteries are distributed on the surface of these organs with tissue perfusion achieved through deep penetrating arteries. In the heart, SVD involves the deep penetrating coronary arterioles and the subendocardial plexus of microvessels. The clinical sequelae of SVD in the heart include stable and acute coronary syndromes and heart failure in the longer term. SVD in the brain mainly involves small subcortical arterioles. If a vascular occlusion occurs, small lacunar lesions can occur, while long-term chronic ischemia caused by SVD may manifest as vascular cognitive impairment. There is a close relationship between cardiovascular and cerebrovascular diseases, and cardiovascular risk factors are related to the etiology of cerebral SVD. However, whether this relationship has a causal remains unclear. Thus, the study of cardiovascular and cerebrovascular integration based on multimodal imaging technology has important value for the diagnosis, efficacy evaluation, and prognosis judgment of cardiovascular and cerebrovascular diseases.