Active clinical trials for "Subarachnoid Hemorrhage"

HS-1000 device, a proprietary new non-invasive brain monitor, is expected to safely and accurately monitor physiological signs of the brain with minimal discomfort to patients, providing information about normal or abnormal brain-related conditions and providing decision-making support for physicians. Investigators hypothesis that the HS-1000 is capable of detecting and monitoring various neuropathologies, using the acoustic raw data derived from the noninvasive procedure.

Pupose: Takotsubo cardiomyopathy is a rare and not well-known complication of the subarachnoid hemorrhage. This form of heart failure, called as "broke heart" or "apical ballooning syndrome", was first described by Japanese authors at the beginning of 1990's. 1.5-2.2% of acute coronary syndrome is Takotsubo cardiomyopathy. Its predisposing factors, hypothetical parthenogenesis, diagnostic criteria and therapeutic methods are already known from the literature. The study intends to include all patients over 18 years of age who were admitted to our clinic within 48 hours after the bleeding regardless of gender, neurological status or age. Data to be registered within 24 hours after admittance: Instruments: Intracranial blood flow characteristics:TCCD - using Transcranial Color Doppler; systolic, diastolic and mean blood flow velocity, Systolic / Diastolic ratio, pulsatility index ECG abnormalities: Corrected QT Interval (QTc), T wave, ST segment, arrhythmia Echocardiography (Ejection fraction%, exact location and degree of cardiac wall motion abnormalities) - documented with video recording Hypothesis: The risk of Takotsubo cardiomyopathy (TS) is increased if SAH is associated with more severe state, a greater degree of bleeding, intraventricular and/ or intracerebral hemorrhage. The definitive care of patients is postponed due to the appearance of TS, which could affect the final outcome.

The risk of delayed cerebral ischemia (DCI) after subarachnoid hemorrhage (SAH) is associated with large cerebral artery vasospasm, but vasospasm is not a strong predictor for DCI. Assessment of cerebral autoregulation with transcranial Doppler (TCD) may improve the prediction of DCI. The aim of this prospective study was to assess the value of TCD-derived variables to be used alone or in combination for prediction of DCI

Endothelin-1 (ET-1) seems to be involved in the pathogenesis of cerebral vasospasm after subarachnoid hemorrhage. However measurements of cerebrospinal fluid concentrations (CSF) of ET-1 are not sensitive enough to predict the development of vasospasm representing the average value throughout the entire cerebral circulation. Cerebral microdialysis (MD) is a technique able to detect molecule concentrations in a small perivascular area. The investigators performed a prospective observational clinical study to test the hypothesis that MD ET-1 concentrations should be a sensitive predictor for vasospasm. Patients with subarachnoid hemorrhage at high risk for vasospasm according to Fisher scale admitted to the ICU were consecutively studied. All patients received surgery within 48 hours from the bleeding; MD probe was placed in the area at risk for vasospasm after surgery and samples were hourly collected and analysed to measure lactate, piruvate and glutamate levels; ET-1 levels in CSF and MD fluids were measured from admission until day 7. At admission and after 7 days two angiographies were performed to detect the degree and extent of vasospasm, Transcranial Doppler and neurological evaluation were daily performed. Patients were then classified according to the presence of vasospasm in 3 groups: absence of vasospasm (NV), presence of vasospasm (CV), acute neurological deterioration (AND).

The aim of the study is to evaluate the cortical excitability in the severe brain injured patients. We hypothesize that: There is a continuous decrease in intracortical inhibition from healthy subjects to awake patients with severe brain injury, and to patients with impaired consciousness. Decreased intracortical inhibition correlate with the degree of impairment assessed with the clinical scores in patients with severe brain injury.

The goal of this observational study is to develop and validate a predictive score of 1-year outcomes in subarachnoid hemorrhage (SAH) patients receiving aneurism coiling. Using our database filled up prospectively, the investigators plan to collect clinical, biological and radiological admission characteristics of coiled SAH cases and their 1-year Rankin outcome score during 5 years (2003-2007). The investigators plan to confirm our score in a validation cohort (from 2008 to 2009).

The purpose of this retrospective study is to test the hypothesis that uncontrolled tachycardia serves as a risk factor for adverse cardiovascular events and poor outcome after Subarachnoid Hemorrhage (SAH).

This study will evaluate the hypothesis that the administration of intraventricular tPA reduces the rates of cerebral vasospasm and ventriculoperitoneal shunt-dependent hydrocephalus in patients with aneurysmal subarachnoid hemorrhage.

Aneurysmal subarachnoid hemorrhage (aSAH) is bleeding into the space between the brain and the tissues that surround the brain as a result of a ruptured aneurysm and is a type of stroke associated with high morbidity and mortality. Those that survive the initial bleed are critically ill and require prolonged intensive care unit stays since they are at risk for a multitude of secondary insults that can further worsen functional outcomes. An especially feared secondary insult is delayed cerebral ischemia (DCI), which is a lack of blood flow to a particular portion of the brain that can result in an ischemic stroke and produce profound neurologic deficits. How DCI develops in some people after aSAH and not others is unknown, but many have hypothesized various mechanisms such as 1) cerebral vasospasm, a focal anatomic narrowing of the blood vessels in the brain that could decrease downstream blood flow, 2) abnormal electrical activity, and 3) microthrombi, or the formation of small blood clots. It is vitally important to identify a therapy that could protect the brain from these secondary insults that happen days after the initial brain bleed. Ketamine is a drug used in the majority of hospitals around the world for various indications, including general anesthesia, sedation, and for pain. Ketamine blocks a specific receptor that is present within the brain and in doing so could play a critical protective role against these secondary insults after aSAH by blocking the flow of dangerous chemicals. Ketamine may provide the following beneficial properties after aSAH: 1) pain control, 2) seizure prevention, 3) blood pressure support, 4) dilation of the brain blood vessels, 5) sedation, 6) anti-depressant, and 7) anti-inflammatory. This project is designed to test whether ketamine sedation in the intensive care unit after aneurysm repair provides better outcomes than the currently used sedation regimen.

Test single nucleotide polymorphisms (SNP's) in ruptured and unruptured aneurysm tissue to identify a genetic difference between the two types of aneurysms; and to test SNP's in arteriovenous malformation tissue to identify a genetic link.