16 Clinical Trials for Various Conditions
The purpose of this study is to assess the ability of the Fluids Monitor to detect hemispheric bioimpedance asymmetry associated with acute brain pathology in patients presenting with suspected Acute Ischemic Stroke (AIS).
A prospective cohort minimal risk study to determine the impact of the COVID-19 crisis on outcomes of neurologically injured ICU patients.
The purpose of this study is to test the safety and effectiveness of a single dose of fingolimod in patients with primary spontaneous intracerebral hemorrhage (ICH).
Severe acute brain injury (SABI), including large artery acute ischemic stroke, intracerebral hemorrhage, and severe traumatic brain injury continue to be the leading cause of death and disability in adults in the U.S. Due to concerns for a poor long-term quality of life, withdrawal of mechanical ventilation and supportive medical care with transition to comfort care is the most common cause of death in SABI, but occurs at a highly variable rate (for example in Traumatic Brain Injury (TBI) 45-89%). Decision aids (DAs) are shared decision-making tools which have been successfully implemented and validated for many other diseases to assist difficult decision making. The investigators have developed a pilot DA for goals-of-care decisions for surrogates of SABI patients. This was developed through qualitative research using semi-structured interviews in surrogate decision makers of TBI patients and physicians. The investigators now propose to pilot-test a DA for surrogates of SABI patients in a feasibility trial.
The purpose of this study is to evaluate the antipyretic effect of bromocriptine in critically-ill patients with acute neurologic injury and fever from infectious and non-infectious etiologies.
Cognitive skills are essential to live independently, manage finances, maintain employment, and function in society. Loss of these cognitive skills puts a tremendous burden on society as seen with dementias, Alzheimer's disease, and traumatic brain injury. The INSIGHT-ICU Study (Illuminating Neuropsychological dysfunction and Systemic Inflammatory mechanisms Gleaned after Hospitalization in Trauma-ICU Study) is the first comprehensive and longitudinal long-term cognitive impairment study after traumatic injury. The societal impact of long-term cognitive impairment after trauma is immense given that these patients are young and constitute a large proportion of employable adults.
The goal of this observational study is to explore the relationship of heart function with the course and outcomes after traumatic brain injuries and nontraumatic intracerebral hemorrhage. The goal is to explore association between routinely collected hemodynamic and brain monitoring data. Participants already taking intervention A as part of their regular medical care and the investigators will follow up with participants 6 months after discharging the hospital.
This prospective, randomized study aims to comprehensively evaluate the impact of cranioplasty timing on postoperative complications and long-term functional outcomes following decompressive hemicraniectomy (DHC). The primary endpoint focuses on comparing the rates of various postoperative complications, including infection, seizures, return to the operating room, and the need for ventriculoperitoneal shunting, between patients undergoing standard of care cranioplasty (\>3 months after DHC) and those receiving early cranioplasty (within 8 weeks).
The goal is to pilot test a highly accessible, web-based, pragmatic, scalable intervention to overcome ongoing problems with high stakes decision-making by surrogate decision-makers of patients in ICUs with severe acute brain injury (SABI), including those with moderate-severe traumatic brain injury, large hemispheric acute ischemic stroke and intracerebral hemorrhage.
The purpose of this research study to find out if clinically unconscious acute brain injury patients that show brain activation to music and language on electroencephalogram (EEG) (bedside test) have better outcomes and wake up in the future.
This is an observational study in neurocritical care units at University of California San Francisco Medical Center (UCSFMC), Zuckerberg San Francisco General Hospital (ZSFGH), and Duke University Medical Center. In this study, the investigators will primarily use the monitor mode of the Transcranial Doppler (TCD, non-invasive FDA approved device) to record cerebral blood flow velocity (CBFV) signals from the Middle Cerebral Artery and Internal Carotid Artery. TCD data and intracranial pressure (ICP) data will be collected in the following four scenarios. Each recording is up to 60 minutes in length. Multimodality high-resolution physiological signals will be collected from brain injured patients: traumatic brain injury, subarachnoid and intracerebral hemorrhage, liver failure, and ischemic stroke. This is not a hypothesis-driven study but rather a signal database development project with a goal to collect multimodality brain monitoring data to support development and validation of algorithms that will be useful for future brain monitoring devices. In particular, the collected data will be used to support: Development and validation of noninvasive intracranial pressure (nICP) algorithms. Development and validation of continuous monitoring of neurovascular coupling state for brain injury patients Development and validation of noninvasive approaches of detecting elevated ICP state. Development and validation of approaches to determine most likely causes of ICP elevation. Development and validation of approaches to detect acute cerebral hemodynamic response to various neurovascular procedures.
Patients who experience lung injury are often placed on a ventilator to help them heal; however, if the ventilator volume settings are too high, it can cause additional lung injury. It is proven that using lower ventilator volume settings improves outcomes. In patients with acute brain injury, it is proven that maintaining a normal partial pressure of carbon dioxide in the arterial blood improves outcomes. Mechanical ventilator settings with higher volumes and higher breathing rates are sometimes required to maintain a normal partial pressure of carbon dioxide. These 2 goals of mechanical ventilation, using lower volumes to prevent additional lung injury but maintaining a normal partial pressure of carbon dioxide, are both important for patients with acute brain injury. The investigators have designed a computerized ventilator protocol in iCentra that matches the current standard of care for mechanical ventilation of patients with acute brain injury by targeting a normal partial pressure of carbon dioxide with the lowest ventilator volume required. This is a quality improvement study with the purpose of observing and measuring the effects of implementation of a standard of care mechanical ventilation protocol for patients with acute brain injury in the iCentra electronic medical record system at Intermountain Medical Center. We hypothesize that implementation of a standardized neuro lung protective ventilation protocol will be feasible, will achieve a target normal partial pressure of carbon dioxide, will decrease tidal volumes toward the target 6 mL/kg predicted body weight, and will improve outcomes.
The goals of the project are to evaluate a noninvasive monitor of brain metabolism and blood flow in critically ill humans. If validated, such a reliable noninvasive brain blood flow and metabolism monitor, by allowing physiologic and pharmacologic decisions based on real-time brain physiology, potentially will become an important tool for clinicians in their efforts to prevent additional brain tissue death in patients admitted with stroke, brain hemorrhage and traumatic brain injury.
Surges in the sympathetic nervous system occur at the ictus of a variety of neurological critical illnesses including intracranial hemorrhage and ischemic stroke. It is hypothesized that these exaggerated increases in sympathetic nervous activity produce maladaptations that promote secondary brain injury. One of these possible mechanisms include diffuse vasospasm that cause cerebral ischemia. Hence, methods to abrogate the sympathetic nervous system in this context are under active investigation. One possible method is the regional anesthesia technique of the stellate ganglion nerve block, which is ordinarily used for complex regional pain syndrome, but has been shown to reduce cerebral sympathetic activity and reduces vasospasm in patients with subarachnoid hemorrhage. However, its effect on the microcirculation is not clear. Hence, we propose to study patients receiving the stellate ganglion nerve block as part of their standard medical care and to image their retinal microcirculation before and after the procedure using Optical Coherence Tomography Angiography (OCTA).
The purpose of this research, which has been determined as non-significant risk by the central IRB overseeing the study, is to obtain information to help further develop a machine (a medical device) to measure the pressure around the brain from the outside (this pressure is called intracranial pressure or ICP). Monitoring and managing ICP is an important part of care for patients with conditions such as Traumatic Brain Injury (TBI). However, the current way of measuring ICP requires surgery to drill a hole into the skull, and therefore can introduce additional risks such as infections and pain. Recent research has shown it may be possible to measure ICP without needing surgery. This technology is in development, but large amounts of data is required to build these new devices. Through collecting a large database of information from patients who have both the routine surgical device and the research device applied to their head, the research team will work to develop and test an effective and potentially safer way of monitoring patient ICP.
The purpose of this study is to create a state-wide biorepository and resource center for cerebrovascular diseases in Florida, which will include collecting medical history information and blood from subjects affected by cerebrovascular disease. The information and blood samples collected may be used in future research for the study of cerebrovascular disease and to learn about, prevent or treat other health problems.