View clinical trials related to Intracranial Pressure Increase.
Filter by:Laparoscopic surgery is a widely used alternative to open surgery; Advantages include reduced bleeding and pain intensity, shorter hospital stay, and improved cosmetic results. Laparoscopic surgery involves the creation of a carbon dioxide (CO2) pneumoperitoneum to facilitate a clear surgical view, which can result in increased intracranial pressure (ICP). Ultrasonographic measurement of optic nerve sheath diameter (ONSD) is a simple, non-invasive, yet reliable technique for ICP assessment.Ultrasonographic assessment of optic nerve sheath diameter (ONSD) has been proposed as a non-invasive measurement of intracranial pressure.
The placement of external ventricular drainage (EVD) is a life-saving procedure used to relieve high pressures in the brain. Often performed at the bedside, a small tube (catheter) is inserted into one ventricle of the brain to drain cerebrospinal fluid and release the pressure build up. In standard practice, EVDs are placed freehand and initial catheter malpositioning occurs in up to ~60% of procedures. Currently, there are no adequate means to verify the position of the catheter before insertion which is a significant impediment to ensure accurate positioning. This non-interventional study aims to validate a novel technology, Bullseye EVD, for verifying the position of the EVD catheter during these emergency procedures.
The study aims to show the effects of interscalene brachial plexus (ISBP) block on intracranial pressure by measuring optic nerve sheath diameter (ONSD) and internal vein collapsibility index (IJV-CI).
Invasive neuromonitoring of intracranial pressure (ICP) is an important element of neurosurgical critical care that is used primarily as an indicator of adequate cerebral perfusion in patients, when clinical observation is not an option. Due to the constraint in size and the critical structures within the posterior fossa, detection of intracranial pressure particularly in the postoperative phase has been deemed desirable in patients with surgery in this region, particularly in those subjected to prolonged procedures and critical care. The posterior fossa is an anatomically constricted compartment with narrow spaces and intracranial hypertension quickly leads to brainstem damage and neurological dysfunction. ICP in the supratentorial space not necessarily correlates with ICP in the infratentorial space. Some authors claim that it would be beneficial to measure ICP in infratentorial space after posterior fossa surgery in some cases. The relationship between the intracranial pressure profiles in the supratentorial and infratentorial compartments remain unclear. After a neurosurgical operation in the posterior fossa there are most likely pressure differences between supra- and infratentorial spaces. It is well known that the pressure within the skull is unevenly distributed, with appreciable ICP gradients. Thus, the investigators intend to apply the intracranial multimodal monitoring in both infratentorial and supratentorial compartments simultaneously. Such coincident measurements most likely will be the most sensitive way to assess focal swelling, ischemia and tissue perfusion, or other relevant complications in the posterior fossa structures. The goal of this study is to test whether direct infratentorial monitoring is a more efficacious method for detecting dynamic changes in the operative compartment and whether it is safe, in view of the critical structures within the region.
1. Observe the changes of TCD/TCCD spectrum shape before and after lumbar puncture in patients with severe neurological disease. 2. Discuss the TCD/TCCD spectrum shape and parameters of cerebral arteries and neurocritical patients Correlation of intracranial pressure.
In modern medicine, doctors attempt to monitor all physiological variables to assess their evolution and to decide, based on their changes, the therapeutic attitudes to adopt. Furthermore, this helps to establish a forecast of the evolution to be expected. The measurement of Intracranial Pressure (ICP) has become indispensable for managing brain pathology at the anterior and middle fossa level. Doctors generally carry out this measurement at the frontal level. However, experimental and clinical studies have shown that supra-tentorial ICP measurement does not precisely predict the ICP situation in the posterior fossa. The increased ICP in the posterior fossa is directly responsible for the clinical deterioration and eventual death in patients with tumour, hemorrhagic, or ischemic pathology of the posterior fossa structures. Some of these lesions are treatable, and their effects reversible if the increase in ICP in the posterior fossa is controlled by pharmacological or even surgical means, preventing it from reaching high levels. This need for on-time ICP control is genuine in the cerebellar hemispheres' lesions, not so much in lesions involving the brainstem. Therefore, the increase in ICP in the posterior fossa needs to be known and documented to facilitate decision-making regarding the therapy to be adopted, be it medical or surgical. It is known what the abnormal ICP levels are at the supratentorial level, but what is not known whether these same levels apply to the posterior fossa. In other words, what it is not know with certainty is whether the same levels of ICP in the posterior fossa and its elevation during the same time are going to have equally pernicious effects or these effects are greater or lesser. Doctors need to have tables of ICP values in the posterior fossa to help them decide when these values are in the physiological range. When posterior fossa intracranial pressure lye in the pathological range, and patients need pharmacological treatment or surgical decompression, knowing for sure the posterior fossa ICP is essential. Finally, when doctors also need to know when any therapeutic attempt is useless. Currently, doctors only monitor the ICP at the supra-tentorial level and deduce the changes in the posterior fossa from the CT and MRI images, that is, the size of the lesions, the occlusion of the cisterns, the internal cerebral hernias (cerebellar tonsils, trans-tentorial hernia from bottom to top). However, doctors do not have a tool that can objectify the pathophysiological situation of the posterior fossa's structures in real-time. Monitoring the posterior fossa ICP will help doctors in decision-making in patients with traumatic, hemorrhagic, ischemic, or tumour pathologies (in the latter case, in the postoperative period of posterior fossa tumours). This posterior fossa ICP measurement will lead to improvements in morbidity/mortality in this subgroup of patients.
This study will test the use of video ophthalmoscope to provide information about intracranial pressure without the use of invasive methods, anesthesia or contact with the eye.
Severe Trauma Brain Injury (TBIs) is a public health problem and monitoring of Intracranial Pressure (ICP) is a determinant key of it prognosis. Within the noninvasive methods to estimate the ICP, the measurement of intraocular pressure has been proposed because of its biological plausibility (proximity of the eye to the encephalic contend). Objective. Correlate intraocular pressure with ICP in children with TBIs and obtain their utility values.