View clinical trials related to Intracerebral Haemorrhage.
Filter by:Spontaneous intracerebral haemorrhage (ICH) accounts for approximately 10-15% of all strokes but stands for 50% of stroke-related morbidity and mortality. Approximately half of all patients with ICH have a decreased level of consciousness at hospital admission. Despite this, intensive care and neurosurgical interventions are uncommon. A study conducted in low- and middle-income countries has demonstrated a beneficial effect of a treatment package consisting of early intensive blood pressure lowering, as well as the treatment of pyrexia and elevated blood glucose levels. The I-CATCHER team is now planning to conduct a similar study in Sweden and Australia, as well as in other high-income countries. The study has a clear focus on implementation, aiming to improve treatment and prognosis for patients with ICH within a few years. The purpose of I-CATCHER is to investigate whether a structured treatment package (Care Bundle) improves 3-month prognosis in patients with spontaneous ICH compared to standard care.
The aim of this observational study is to determine how and why inadequate brain blood flow occurs after bleeding in patients with intracerebral haemorrhage (ICH). Treatment for strokes caused by burst blood vessels involves reducing blood pressure (BP) to stop the bleeding. However, this reduction in BP may affect blood flow, causing blockages in blood vessels within the brain. Fast breathing also affects brain blood flow. Therefore, participants will be asked to undergo a simple brain blood flow assessment using transcranial Doppler (TCD) within 48 hours upon admission to hospital. Patients will then have a follow-up TCD assessment at 4-7 days post-ICH onset, in addition to an MRI scan at >7 days. This research will help to confirm if blockages after bleeding are caused by reduced blood flow within the brain.
A study in the use of the Narcotrend depth of anaesthesia monitor to record a) seizures, and b) monitor a level of sedation referred to as 'burst suppression', in sedated patients in the adult and paediatric intensive care. Studies have shown that patients in coma on the intensive care unit may have subclinical in addition to clinical seizures. Subclinical seizures are seizures that do not show any outward signs and may go undetected. The current gold standard of recording seizures in the intensive care unit is by non-invasive, continuous monitoring of the electrical activity of the brain by electroencephalography (cEEG) using cerebral function analysing monitor (CFAM). This is recorded with simultaneous video recording and is performed by Clinical Neurophysiology departments. There has been a steady increase in demand for this service over recent years. Additionally, CFAM / cEEG is labour intensive and expensive. If trends continue, the proportion of hospitals offering CFAM / cEEG will continue to rise, creating increased demand for specialist staff, of which there are a finite number. Depth of anaesthesia monitors are used by anaesthetists to assess the level of anaesthesia in sedated patients using specialised, automated EEG analysis and are now recommended by NICE (DG6) to tailor anaesthetic dose to individual patients. This study aims to investigate the utility of the Narcotrend depth of anaesthesia monitor to monitor for seizures and burst suppression on the adult and paediatric intensive care unit. These monitors are cheaper and more widely available with the scope to be used at every bed space requiring neuro observation on the intensive care unit. The study aims to recruit all patients who are referred for CFAM / cEEG monitoring at Nottingham University Hospitals (NUH) Trust over a 12 month period. These patients will undergo simultaneous recording using CFAM / cEEG and depth of anaesthesia monitoring.
This is an open-labelled, single centre randomised controlled trial evaluating the efficacy of early minimally invasive image-guided hematoma evacuation in combination with the current best medical treatment compared to best medical treatment alone in improving functional outcome rates at 6 months after initial treatment in patients with spontaneous supratentorial intracerebral haemorrhage.
Intracerebral hemorrhage (ICH) accounts for 10-15% of all strokes without effective pharmacological treatment. Inflammation following ICH contributes to barrier disruption and peri-hematoma edema, leading to deterioration of neurological function. Preclinical evidence suggests that bone marrow hematopoietic stem and progenitor cells (HSPCs) are swiftly activated after ICH. Thereafter, these HSPCs produce an increased output of anti-inflammatory monocytes as an endogenous protective mechanism. Stimulation of β3 adrenergic receptor using selective agonists promotes the production of anti-inflammatory monocytes in bone marrow, and thereby reduces neuroinflammation, brain edema and neurological deficits. This study is to assess the safety and efficacy of a β3 adrenergic receptor agonist Mirabegron as a potential treatment option in ICH patients.
This trial will help inform the development of a new treatment for intracerebral haemorrhage (ICH; also known as haemorrhagic stroke). ICH is a type of stroke caused by spontaneous bleeding into the brain. In the hours to days after bleeding occurs, inflammation develops in the brain around the haematoma (collection of blood in the brain). Inflammation is the body's natural response to injury, however when it continues unchecked there is a risk that the brain tissue around the haematoma will become swollen. This type of swelling can worsen existing stroke symptoms or cause new deficits such as speech disturbance and limb weakness, which can lead to long term disability. The level of inflammation in the blood is high after ICH. The investigators want to investigate whether blocking this inflammation can improve overall recovery. The investigators research group has extensively investigated the use of a well-established anti-inflammatory drug, Kineret® in trials with patients who have suffered a stroke or brain haemorrhage. Kineret® is similar to a naturally-produced protein called interleukin-1 receptor antagonist (IL-1Ra) and is already licensed to treat patients with rheumatoid arthritis. The investigators have evidence from these previous studies that Kineret® reduced levels of inflammation in the blood after ischaemic stroke (caused by a blockage in an artery). However, in order to develop Kineret® as a treatment for ICH, the investigators need to know if it reduces levels of inflammation present in the blood following ICH and if it reduces swelling in the brain.
The study is a prospective phase II randomised, double-blind, placebo-controlled investigator-driven trial in acute intracerebral haemorrhage patients. The study has 2 arms with 1:1 randomisation to either intravenous tranexamic acid or placebo and will test the hypothesis that in patients with spontaneous ICH, treatment with tranexamic acid within 2 hours of onset will reduce haematoma expansion compared to placebo.
This study aims to explore the effectiveness of tranexamic acid (also known as trans amine or TXA) in reducing hematoma expansion in patients with hemorrhagic stroke when given in the acute phase. METHODOLOGY This will be a Phase III, parallel-group double-blind randomised placebo control trial. Patients allocated to the control group will receive standard care for hemorrhagic stroke according to the 2015 American Heart Association guidelines. Patients allocated to the intervention group will receive, in addition to standard care, a loading dose of intravenous TXA 1gm within 3 hours of symptom onset followed by a 1gm maintenance dose over 8 hours. Timing and dosing are in accordance to previous established study protocols. Patients in the intervention group will only receive a single treatment course of TXA. Study subjects will be identified by either the on-duty clinicians from the Department of Neurosurgery of this institution or by the study investigators. Should the patient meet study eligibility criteria consent will be obtained either from the patient or from his/her next of kin. 1:1 block randomization will be performed by a remote internet randomization service by accessing a website. Patients allocated to the intervention arm will have 1gm of TXA added to 100ml of normal saline (0.9%) infused over 10 minutes as a loading dose. This is then followed by a maintenance dose of 1gm of TXA in 500ml of intravenous isotonic solution infused at 120mg/hour (60ml/hour) for 8 hours. Patient's allocated to the control arm will have an equal volume of normal saline (0.9%) infused as a placebo. The patient and the outcome assessor will be blinded to study group allocation. The primary endpoint of this study will be to assess the percentage change in brain blood clot volume by computed tomography brain scans on admission, 6 hours later, at 24 hours and at 1 week.
This is a multicenter, randomized, adaptive clinical trial comparing standard medical management to early (<24 hours) surgical hematoma evacuation using minimally invasive parafascicular surgery (MIPS) in the treatment of acute spontaneous supratentorial intracerebral hemorrhage.
Specific cardiovascular diseases, such as stroke and heart attack, have been shown to vary by ethnic group. However, less is known about differences between ethnic groups and a wider range of cardiovascular diseases. This study will examine differences between ethnic groups (White, Black, South Asian and Mixed/Other) and first lifetime presentation of twelve different cardiovascular diseases. This information may help to predict the onset of cardiovascular diseases and inform disease prevention strategies. The hypothesis is that different ethnic groups have differing associations with the range of cardiovascular diseases studied.