View clinical trials related to Intracranial Pressure.
Filter by:The goal of this prospective, multicenter, observational, cohort trail is to explore the pattern of brain temperature-brain pressure association in acute brain injury and to clarify its predictive value for prognosis and neurological function 30 days after acute brain injury.
50 patients with verified new-onset Idiopathic Intracranial Hypertension are randomly allocated to standard weight management (dietician counselling) or trial intervention consisting of subcutaneous injections with Semaglutide for 10 months combined, in the initial 8 weeks following diagnosis, with a Very Low Calorie-Diet (max 800 kcal/day)
Aim: To compare the effect of procedural anesthesia management with ketofol and propofol on the sonographic optic nerve sheath diameter in the endoscopic retrograde cholangiopancreatography (ERCP) procedures.
The use of non-invasive intracranial pressure monitoring, including intracranial pressure pulse morphology in patients with COVID-19, could calculate possible components associated with the presence of neurological symptoms in these patients, in addition to being a tool with the potential to monitor the repercussion of MV at cerebral compliance patient patients. In addition, it is likely that patients with COVID-19 also have cerebral embolization more frequently than healthy patients, which is justified by transcranial doppler ultrasound assessment. The aim of the study is to monitor this brain pressure using a non-invasive method of monitoring, with a helmet-like system in place, for 1 hour for 7 consecutive days. There will be no associated invasive procedure of any kind. Monitoring will be done by the criteria themselves, no place where the patient and the mandatory volunteer. Another objective is to capture signs of microembolisms (small strokes that have not yet manifested) by performing a doppler ultrasound on the head with a helmet also for 1 hour, in a single evaluation. The study population will include inpatients with COVID-19 infection. The control group will be in patients who do not have Covid-19. The control group will consist of people with similar characteristics and who have not recovered. Patients who meet the inclusion criteria incorporated into the monitoring with a non-invasive intracranial pressure device for 1 hour during hospitalization (Brain4Care® device approved by ANVISA), being monitored for up to seven days, in addition to monitoring for 1 hour with a transcranial doppler ultrasound helmet DWL® in a single assessment. There will be no invasive procedures or other equipment used without due knowledge by Organs competent bodies. It does not collect collection or retention of any biological material.
External ventricular drain (EVD) placement is performed very often in neurosurgical practices. EVD's are most commonly placed at the bedside using external anatomical landmarks to guide the catheter into the frontal horn of the ipsilateral lateral ventricle. EVDs are often placed due to acute neurological compromise and require timely insertion. Accurate catheter placement is essential to achieving effective external CSF drainage without complications or occlusion/failure of the catheter. Catheter placement is most commonly performed via a freehand approach using external anatomical landmarks to help identify the location of the lateral ventricle within the brain without the aid of imaging. Proper identification of the ventricles on pre-procedure imaging, surgeon skill, and estimation of pathologic perturbations to the normal location of the ventricles all factor into the success of catheter placement. Multiple passes are often required. The accuracy rate from the freehand technique has been reported to range from 40 to 98 percent. Current methods for EVD placement do not compensate for superficial brain vessels or pathology that may alter the intracranial anatomy such as trauma, hemorrhage, or mass lesions. Some studies have attempted to use CTA imaging to identify intracranial vessels in an attempt to avoid them during placement. Image guidance is a tool used very commonly for placement of EVD's and shunts in the operating room. AxiEM Stealth is a noninvasive image localization modality that registers a CT or MRI to the individual patients facial and scalp anatomy. This study will compare the current standard of care of freehand placement of bedside external ventricular catheters to the placement of EVD catheters with AxiEM Stealth image guidance.
The purpose of this pilot study is to assess whether the intracranial pressure (ICP) can be detected by using a non-invasive retinal fundus scanner, recording the vessels of the eye entering from the optic disc. The artery's diameter (A) is measured and compared to the vein's diameter (V) thereby a ratio A/V can be calculated. This ratio is compared to the values obtained from conventional fiberoptic intraparenchymal, intraventricular ICP monitoring using external ventricular drain (EVD) or lumbar pressure monitoring. Valid non-invasive techniques for objective measurements of the intracranial pressure do not exist at the given time now and this study could prove to help the development of monitoring patients ICP without surgical intervention.
Background: It has already been established that there is a weak positive relationship between increased intracranial pressure (ICP), as measured by lumbar puncture manometry, and increased Body Mass Index (BMI). This is also observed clinically in some patients with idiopathic intracranial hypertension, who typically have raised BMI. The relationship between BMI and percentage body fat is non-linear, especially at BMI > 40. The Bod Pod device enables non-invasive body composition profiling, including accurate calculation of percentage body fat, without the use of radiation. Aim: To examine the relationship between intracranial pressure as measured by lumbar puncture manometry and percentage body fat as measured by air-displacement plethysmography (Bod Pod) Methods: 100 patients undergoing routine diagnostic and therapeutic lumbar punctures for a variety of non-emergency neurological conditions will be recruited. Cerebrospinal fluid opening pressure will be measured using standard manometry techniques. Blood pressure, height, weight, collar size, waist size and hip size will be measured. Body composition profiling will be carried out using the Bod Pod.
The PANDA trial is a multicenter prospective observational study designed to analyze various ICP derived parameters and clinical status in neurosurgical critical patients through a new big data acquisition system.
Mannitol 20% has long been used to treat elevated intracranial hypertension in trauma and intensive care settings. More recent data indicate that hypertonic saline may be as effective or more effective than mannitol for this purpose, with possible fewer side effects. This study compares both agents in favoring cerebral relaxation during elective supratentorial procedures for tumor resection. Study hypothesis: 3% hypertonic saline will provide better cerebral relaxation with fewer side effects than 20% mannitol.