Active clinical trials for "Vasospasm, Intracranial"

Nimodipine reduces the risk of poor outcome and delayed cerebral ischemia in patients suffering aneurysmal subarachnoid haemorrhage (SAH), but its mode of action is unknown. Its beneficial effect is assumed to be due its neuroprotective effects by reducing intracellular calcium and thereby cellular apoptosis, but higher concentrations might induce marked systemic hypotension, thereby inducing cerebral ischemia. Since several dosing regimes and routes of administration with inconclusive superiority exist and since the target site concentration of nimodipine - the unbound drug concentrations beyond the blood-brain barrier - is still not known, it is reasonable to measure nimodipine concentrations within the blood, cerebrospinal fluid (CSF) and interstitial brain tissue following oral, intra-venous and intra-arterial administration and correlate intra-arterial nimodipine administration to measures of cerebral metabolism and oxygenation. Therefore, the investigators propose to investigate in 30 patients suffering severe aneurysmal SAH and requiring cerebral microdialysis for cerebral neurochemical monitoring: the ability of nimodipine to penetrate into the brain of neurointensive care patients by comparing exposure in brain, CSF and plasma, dependent on the route of administration (i.e. oral, intra-venous, and intra-arterial) and dosing intra-venously (0.5 - 2mg/h) the impact of orally, intra-venously, and intra-arterially delivered nimodipine on cerebral metabolism, i.e. lactate/pyruvate ratio, pbtO2 and transcranial doppler flow velocities the effect of oral and intra-venous nimodipine on systemic hemodynamic and cardiac parameters, using continuous Pulse Contour Cardiac Output (PiCCO) monitoring the penetration properties of ethanol - as an excipient of nimodipine infusion - into the brain by comparing exposure in brain, CSF and plasma and quantifying the neuronal exposure to alcohol dependent on blood levels

The primary objective of the study is to determine the optimal intra-arterial drug treatment regimen for arterial lumen restoration post cerebral vasospasm following aneurysmal subarachnoid hemorrhage. The secondary objective is to evaluate clinical outcome at 90 days post discharge following optimal intra-arterial drug treatment for cerebral vasospasm. We hypothesize that Intra-arterial (IA) infusion of a combination of multiple vasodilators is more efficacious than single agent treatment cerebral vasospasm therapy. All procedures done as a part of this study are standard hospital care procedures done to treat cerebral vasospasm and all drugs to be used are FDA approved.

The goal of this observational study is to learn about the possibility to predict clinical course of subarachnoid hemorrhage (SAH) patients by performing the retrospective analysis of clinical data available in early pre-vasospasm phase. The main questions it aims to answer are: What biomarkers retrieved from Computed Tomography (CT) and Computed Tomography Angiography (SAH location, leaked blood volume, cerebrospinal fluid volume, etc.) can be used to predict development of cerebral vasospasms, delayed cerebral ischemia and patients' outcome. What biomarkers retrieved from transcranial Doppler examinations in early pre vasospasm can be used to predict development of cerebral vasospasms, delayed cerebral ischemia and patients' outcome. What biomarkers retrieved from multimodal physiological monitoring in early pre vasospasm can be used to predict development of cerebral vasospasms, delayed cerebral ischemia and patients' outcome. What is impact of other clinical data (blood test results, age, gender, etc.) on development of cerebral vasospasms and delayed cerebral ischemia.

A Blind-adjudication Multi-center Phase II Randomized Clinical Trial of Continuous Low-dose Intravenous Heparin Therapy in Coiled Low-grade Aneurysmal Subarachnoid Hemorrhage Patients with Significant Hemorrhage Burden. - STUDY IS TEMPORARILY SUSPENDED WITH PLAN TO RESUME SOON. NO SAFETY CONCERNS

Patients with brain hemorrhage resulting from a ruptured aneurysm (SAH) are at risk of developing a condition called vasospasm, one or two weeks after their hemorrhage. This is a major cause of stroke and death following SAH. A special type of CT scan, called CT perfusion, analyzes regional blood flow in the brain. We hypothesize that CT perfusion scans performed on admission and day 6 post-hemorrhage will enable us to predict which patients will go on to develop vasospasm.

The purpose of this study is to determine if intrathecal nicardipine is safe for the treatment of cerebral vasospasm.

The purpose of this study is to evaluate the usefulness of adding Milrinone to the current standard treatment for cerebral vasospasm.

The hypothesis is that intravenous infusion of sodium nitrite is safe and effective for the reversal of cerebral vasospasm after subarachnoid hemorrhage in patients with a cerebral aneurysm.

Aneurysmal subarachnoid hemorrhage (bleeding on the brain due to a ruptured aneurysm) is a serious condition with a high morbidity (incidence of having ill health) and mortality (death). There are approximately 11 cases per 100,000 in the population per year, and approximately 40% of these cases are fatal. (Ingall) Among the fortunate subjects who survive the initial bleed, vasospasm and subsequent stroke are a major cause of morbidity. Vasospasm is defined as a prolonged severe, although reversible cause of arterial narrowing that occurs after bleeding into the subarachnoid space, most commonly after aneurysmal rupture. (Youman) The reduced arterial diameter inhibits blood flow and deprives the brain of oxygen, which often results in a stroke. Vasospasm is a major problem when treating subjects with aneurysmal subarachnoid hemorrhage. For these reasons, it is essential to diagnose cerebral vasospasm early, before permanent deficits develop. There may be another option to solve this dilemma. The field of neuro-monitoring (neurological monitoring) has the technology available to continuously monitor brain activity of these sedated ICU subjects. This may allow for early diagnosis and possibly identify changes in neurologic function before they become symptomatic. In the past, neuro-monitoring was primarily used in the operating room to monitor neurologic function during surgery in and around the spinal cord. Surgery to the spine or spinal cord also carries its own form of risk, either from mechanical trauma to the spinal cord or its nerve roots, or from interruption of the blood supply to these structures. Should damage to nerve fibers occur, the end result could be paralysis, loss of sensation, and onset of severe burning (i.e. neuropathic) pain. The field of intraoperative neuro-monitoring (IOM) was developed to address these risks during spine surgery, whereby nerves rostral (toward the head) or caudal (toward the feet) to the site of surgery are stimulated (usually via electrical pulses) and signals are recorded from the side opposite to the site of stimulation. Thus, the signals carried by nerve fibers are forced to pass through the region at risk from the surgery. In the event that changes in nerve responses are seen, the surgical team is notified, and they can change what they're doing to try and restore signals, thereby preserving function in the nerve fibers. This same technology has been used in the neurosurgical ICU to monitor subjects with severe brain injury from trauma, stroke, intracranial hemorrhage and subarachnoid hemorrhage. Using continuous electroencephalogram (EEG) monitoring combined with somatosensory evoked potentials (SSEPs) (a type of neuro monitoring) has been used to determine prognosis, identify subjects in subclinical status epilepticus (state of brain being in a constant seizure), predict elevations in the intracranial pressure Increased pressure within the skull), and diagnose cerebral hypoxia (not enough oxygen in the brain) (Amantini)

A randomized clinical trial investigating magnesium sulphate ability to reduce risk of cerebral vasospasm after acute subarachnoid hemorrhage hence improving outcome particularly in haptoglobin 2-2 patients who are highly susceptible for severe complications after subarachnoid hemorrhage.