View clinical trials related to Brain Lesion.
Filter by:The progression of brain lesions after severe head trauma or subarachnoid hemorrhage results from extra cranial aggression which is well controlled in intensive care and intracranial aggression which is less well known and therefore less well managed. The detection of events that can generate new lesions from intracranial monitoring is limited and late once the lesions are irreversible. Invasive cortical depolarizations (SD) can be observed using cortical electrodes and an acquisition system having access to the usually filtered DC signal (0 to 1 Hz). SD are observed at the onset of a new attack of the cortex and spread widely away from the site of aggression. During their propagation, SD generate a significant metabolic demand, and can cause ischemic injury, particularly after meningeal or post-traumatic hemorrhage. SDs are therefore both a marker of new lesion and a mechanism of progression of primary lesions. Yet this type of monitoring is only performed in some expert centers around the world. The analysis of the feasibility and safety of the placement of cortical electrodes in this indication is therefore an essential step to study the clinical benefit of individualized management on the basis of this monitoring.
The primary objective of this study was to evaluate the safety (clinical and biological) and pharmacokinetics (plasma and urine) profile of P03277 following single administration at ascending dose levels in healthy subjects.
In this randomized double-blind controlled study we would like to test the benefit of neurofeedback for the recovery of patients with frontal brain injury during an early stage of neurorehabilitation.
A wide spectrum of methods is used to image brain activation in vivo. It can be directly detected by neurons electrical activity imaging (cortical simulation mapping, calcium imaging, voltage sensitive dyes) or indirectly by imaging hemodynamic changes induced by the neurovascular coupling in the vessels surrounding the activated neurons (intrinsic optical imaging, photoacoustic imaging, positron emission tomography (PET), functional magnetic resonance imaging (fMRI)). Ultrasound as the potential to complement these functional imaging techniques at low cost. Ultrasound imaging can do real-time in-depth imaging of brain. However, its use to imaging of major vessels has been limited until now due to its poor sensitivity. To overcome this limitation functional ultrasound (fUS) was developed in Institut Langevin since 2011. This technique enables high spatio-temporal resolution imaging of whole-brain microvasculature dynamics in response to brain activation without the need of contrast agent. This fUS method relies on a new power Doppler imaging sequence sensitive enough to detect blood flow in most of cerebral vessels (arterioles, big venules and larger vessels). Repeating the acquisition of such ultrasensitive Doppler images over time enables to follow flow dynamics in such vessels modulated by local neuronal activity. Applied to the rat brain, fUS was proved able to map brain activation at high spatiotemporal resolution and high signal to noise ratio. The aim of this study is now to apply fUS on human brain in intraoperative condition. The main objective of this study is to find activation maps through intraoperative ultrasensitive Doppler compared to gold standard cortical simulation mapping and functional MRI. Secondly the investigators want to test sensitivity of this new Doppler mode. fUS method will be used for different types of stimuli and intensity and the investigators will do some control acquisitions. Blood vessel density observed with a conventional Doppler will be compared to the one measured with the ultrasensitive Doppler to prove that this new Doppler mode enhance micro vessel visualization.
The position of the head of the patient influences the cerebral venous return and cerebral perfusion pressure (CPP). In our daily practice, it is almost routine to prescribe a Trendelenburg position 30 ° in all brain-damaged patients. However, this is based only on precarious bibliographic databases. It has been shown to decrease the Intracranial Pressure (ICP) in Trendelenburg position relative to the horizontal, with varying effects on PPC. Effects on sylvian objectified by Doppler velocities and cerebral oxygenation seem unaffected by changes of position of the head of the patient. But the whole of the literature on this subject has significant bias.
This prospective observational study will investigate the frequency of new onset atrial fibrillation (AF) and of further cardiac arrhythmias as well as of (clinically silent) cerebral lesions in endurance runners before, during and after the BMW-Berlin Marathon 2011.