173 Clinical Trials for Various Conditions
The main purpose of this study is to compare patients with a deep bleed in the brain undergoing surgery to patients receiving routine medical care. The standard treatment involves admission to the Intensive Care Unit (ICU) with close monitoring and blood pressure control. It also includes other medical (non-surgical) treatments to prevent more bleeding or another stroke. Sometimes, doctors will recommend surgery to remove the blood if medical treatment alone is not successful. There is evidence that doing minimally invasive surgery early-using a small opening in the skull to remove blood-may help some patients. Researchers aim to understand whether this surgery is better than current medical treatment, which may include surgeries to relieve pressure on the brain in some cases. This study, called REACH, is comparing usual medical care to early minimally invasive surgery so doctors can know which is better for patients.
Background: While the intensive care of patients with life-threatening brain illnesses has advanced tremendously, a large number of therapies are still without proper scientific support. This can be partly explained by the fact that mechanisms of initial brain injury are still not well understood. Why additional neurological injury occurs during a patient's stay in the NeuroCritical Care Unit (NCCU) despite current best, evidence-based clinical practices, is also not well understood. However, over the past decade, better tools have become available to measure and monitor the impact of our clinical care on the rapidly changing physiology and chemistry of the injured brain. Some of these tools are CT, MRI, ultrasound, and catheter-based technology measuring blood flow and metabolism. These tools have enabled earlier detection of injury and complications and newer therapeutic strategies. Purpose: Examine disease pathways common to all brain injuries seen in the University of Maryland's 22-bed NCCU. Life-threatening neurological illnesses cared for in the NCCU include massive stroke, bleeding in and around the brain (subarachnoid hemorrhage, intracerebral hemorrhage, subdural hemorrhage, intraventricular hemorrhage), brain tumors, difficult to control seizures, neurologic infections, nerve and muscle diseases (such as myasthenia gravis or Guillain-Barre Syndrome), and spinal cord disorders among others. Many NCCU patients are comatose or paralyzed and may suffer injuries in other parts of the body as well. This effort will require the creation of a robust clinical database for the capture of data including patient characteristics (age, sex), clinical characteristics, medical treatments, surgical interventions, physiological data (such as vital signs, cerebral blood flow, intracranial pressure, cerebral oximetry, etc), laboratory data, and standard-of-care diagnostic studies such as electroencephalography (EEG), ultrasound, CT, MRI, and angiograms. Similar databases exist at other major centers for neurocritical care and have been instrumental to the identification of characteristics both predictive of and associated with outcomes of patients long after their stay in the NCCU. In addition, the samples collected will be included in the University of Maryland Medicine (UMM) Biorepository which is a shared resource to enable biomedical research by University of Maryland faculty.
Objective: The primary objective of this multicenter prospective registry is to provide additional safety, technical outcomes and clinical outcomes data for minimally invasive endoscopic surgery (MIES) with Apollo or Artemis for the evacuation of supratentorial brain hemorrhage in adult patients who do not qualify for the concurrent INVEST Feasibility randomized controlled trial at active INVEST centers.
The primary objective of this multicenter single arm feasibility study is to provide an assessment of enrollment and follow up feasibility for this patient population being treated with the Apollo Minimally Invasive Surgical Treatment (MIES). Patients who do not qualify for the INVEST Feasibility Study will be referred to the INVEST Registry study.
Fever, defined as temperature higher than 38.3C (100.9 F), is common in patients with head injuries and is associated with poor recovery after injury. The current standard of care is to use oral acetaminophen (Tylenol) followed by a body cooling device. This method can effectively reduce fever but results in a high rate of shivering. Shivering is stressful to the heart and can further worsen brain injury. Methods to combat shivering have been developed and are successful in limiting the stress in the majority of patients that use a body cooling device. However, the drugs used to control shivering are sedating and may also interfere with brain recovery. The purpose of this study is to assess whether ibuprofen given intravenously is more effective in combating fever than the current standard of care. Should results from this study demonstrate that ibuprofen infusion is effective, a larger study will be conducted to determine whether this aggressive fever control regimen leads to improved recovery after brain injury.
The specific aims of this study are to: 1. Definitively determine the therapeutic benefit of the intensive treatment relative to the standard treatment in the proportion of patients with death and disability (mRS 4-6) at 3 months among subjects with ICH who are treated within 4.5 hours of symptom onset. 2. Evaluate the therapeutic benefit of the intensive treatment relative to the standard treatment in the subjects' quality of life as measured by EuroQol at 3 months. 3. Evaluate the therapeutic benefit of the intensive treatment relative to the standard treatment in the proportion of hematoma expansion (defined as increase from baseline hematoma volume of at least 33%) and in the change from baseline peri-hematoma volume at 24 hours on the serial computed tomographic (CT) scans. 4. Assess the safety of the intensive treatment relative to the standard treatment in the proportion of subjects with treatment-related serious adverse events (SAEs) within 72 hours.
This study is one of the three projects of an NIH Rare Disease Clinical Research Consortium. A "consortium" is a group of centres sharing information and resources to perform research. The consortium research focuses on brain blood vessel malformations in three different rare diseases. The focus of this specific study is on Hemorrhagic Telangiectasia (HHT). HHT is a condition characterized by blood vessel malformations, called telangiectasia and arteriovenous malformations (AVMs), occurring in the brain, nose, lungs, stomach, bowels and liver. Brain AVMs (BAVMs) in HHT are difficult to study because they are rare, affecting approximately 10% of people with HHT. While other types of BAVMs have been studied in depth, studies in the HHT population have been very small. Here, we propose the first large-scale collaboration by joining with 12 HHT Centers of Excellence in North America to perform a large study of risk factors for bleeding from BAVMs, called intracranial hemorrhage (ICH) in HHT patients. The current standard of clinical practice across North America, is to screen all HHT patients for BAVMs with magnetic resonance imaging (MRI). If BAVMs are detected, patients are referred to a multidisciplinary neurovascular team for consideration for treatment. Treatment decisions are made on a case by case basis, balancing risks of complications from the BAVM with risks of therapy, but are limited by the few studies available in HHT. We hope that the knowledge we obtain about the risk factors for intracranial bleeding in these patients from this larger study will help us to improve the care of HHT patients. We plan to study risk factors for rupture of BAVMs, including primarily genetics and imaging characteristics of the BAVMs. Knowledge about risk factors will help in the care and management of HHT patients. This will be achieved through the collection of health information to construct a HHT database, blood sampling and banking (through the National Institute of Neurological Disorders and Stroke \[NINDS\]), and through genetic analysis at the University of California San Francisco.
The investigators intend to show that DDAVP improves platelet activity from baseline to 60 minutes after treatment start.
The purpose of this academic lead study is to determine if a treatment strategy of early intensive blood pressure (BP) lowering compared to conservative BP lowering policy in patients with elevated blood pressure within 6 hours of acute intracerebral haemorrhage (ICH) improves the outcome of death and disability at 3 months after onset.
Animal studies show that the breakdown of blood results in iron accumulation in the brain after brain hemorrhage (ICH); and that iron plays a role in brain injury in ICH patients. Deferoxamine (DFO) has been extensively used in clinical practice for more than 30 years to remove excessive iron from the body, and has been shown to provide some benefit in animal studies of ICH. Therefore, we plan to undertake this study to evaluate the safety and tolerability of treatment with DFO in patients with ICH, and to determine the maximal tolerated dose to be used in future studies to determine if treatment with DFO can improve the outcome of patients with ICH. Our main objectives are: 1) to evaluate the safety and tolerability of varying doses of DFO, by determining the treatment related adverse events, in patients with ICH; and 2) to determine the maximal tolerated dose to be adopted in subsequent studies to test the efficacy of DFO in improving outcome after ICH. We hypothesize that DFO is well-tolerated and has minimal serious adverse effects in patients with ICH; and that treatment with DFO will improve patients' outcome. The results can potentially bring into account new means to improve the outcome of patients with ICH. ICH is a frequent cause of disability and death. A successful study demonstrating the efficacy of iron-modifying therapy would be of considerable public health significance.
The purpose of this trial is to evaluate the safety and effectiveness of lowering blood pressure using nicardipine in persons with acute hypertension associated with intracerebral hemorrhage.
The primary objective of this study is to assess the safety of the 3D Transcranial Ultrasound Brain Imaging (3D TRUBI) device in Traumatic Brain Injury (TBI) patients with intracranial hemorrhage (ICH). The secondary objective is to assess the diagnostic potential of 3D TRUBI. The latter will be achieved by comparison of 3D TRUBI scans with admission head computed tomography (CT), the standard of care diagnostic modality. Demonstrating the feasibility and safety of the 3D TRUBI system is the first step toward expanding access of an alternative to CT for diagnostic imaging and triage of mass casualties of war or natural disasters in the field and in rapidly deployed medical centers or other austere environments.
The investigators propose to perform serial detailed cognitive, motor, behavioral, and blood collection follow-up using longitudinal structured telephone interviews of an anticipated 350 ICH survivors enrolled in Minimally Invasive Surgery Plus Alteplase for Intracerebral Hemorrhage Evacuation (MISTIE) III and ENRICH trials to identify specific cognitive and motor impairment and to perform RNA sequencing to evaluate for evidence of chronic inflammation. The investigators' expected sample size in 2022 accounts for mortality attrition of 10%/year.
The objectives of the RECONFIG clinical study are to : 1. To identify the time to the first diagnosis of cognitive motor dissociation (CMD) in intracerebral hemorrhage (ICH) patients and to investigate whether these patients will clinically follow commands earlier after the hemorrhage. 2. To determine whether CMD independently predicts long term functional outcomes (6-month mRS scores) in ICH patients, and is associated with long term cognitive and quality of life outcomes. 3. To determine the EEG response to verbal commands of the motor imagery paradigm between patients with and without sensory aphasia. The overall goal is to determine predictors and the trajectory of neurological recovery.
The primary objective of this multicenter randomized controlled study is to compare the safety and efficacy of minimally invasive hematoma evacuation with the Artemis Neuro Evacuation Device to best medical management for the treatment of intracerebral hemorrhage (ICH).
The goal of this study is to preliminarily determine/estimate feasibility and whether frequent and early conivaptan use, at a dose currently determined to be safe (i.e., 40mg/day), is safe and well-tolerated in patients with cerebral edema from intracerebral hemorrhage (ICH) and pressure (ICP). A further goal is to preliminarily estimate whether conivaptan at this same dose can reduce cerebral edema (CE) in these same patients. This study is also an essential first step in understanding the role of conivaptan in CE management. Hypothesis: The frequent and early use of conivaptan at 40mg/day will be safe and well-tolerated, and also reduce cerebral edema, in patients with intracerebral hemorrhage and pressure.
Intracerebral hemorrhage (ICH) is the most severe form of stroke: early mortality is 40%, and 80%-of survivors are physically disabled with high rates of cognitive impairment and depression. In an effort to address the issues with conventional treatments, a new integrated systematic approach has been developed. This approach utilizes an educational process where specific core competencies (pillars) of mapping, navigation, access, optics and automated resection have been integrated into a single standardized system to deliver targeted therapy for an individual patient based on location and patient factors. This system has demonstrated safety and efficacy in oncology patients and is also FDA approved for use in the ICH patient population as well. This registry will collect data form multiple site that preform the MiSPACE procedure as part of clinical care. The intent of this registry is to collect data on the economic impact as well as clinical outcomes using the MiSPACE approach with the integrated technology in the early treatment of ICH.
Dense array EEG and EIT (electrical impedence tomography) are new technologies that can add to information needed to diagnose neurological problems in infants - both preterm and term. The investigators propose a method to test these technologies in the preterm population to determine its safety and ease of use. The investigators will test on preterm infants of 30-34 weeks gestation, starting first with the older infants (32-34 weeks) then moving down to the smaller population (30-32 weeks). In both groups the investigators will start with a short time period and gradually extend the time as safety is established. All studies will be conducted at Shands Teaching Hospital at the University of Florida.
Early hematoma growth (HG) after spontaneous intra-cerebral/intra-parenchymal hemorrhage (IPH) is common and associated with neurological deterioration and poor clinical outcome. Temperature modulation to hypothermia (Temperature, 32-34°C) has been associated with reduction or improvement of physiopathologic processes associated with inflammatory activation and degradation of blood-brain barrier after all types of brain injury. In this sense, we believe that the initiation of an ultra-early protocol of active temperature modulation or Targeted Temperature Management (TTM) to mild induced hypothermia (MIH, 32-34°C) may be associated with good safety and tolerability profile, less HG and cerebral edema after IPH by modulation of systemic and local inflammatory responses, so we hypothesize that TTM to MIH will be a safe/tolerable and effective therapy to limit HG and cerebral edema after IPH.
The overall aim of this project is to prospectively determine whether MRI can improve the conventional neuroradiological evaluation (CT with or without cerebral angiography) of patients with a spontaneous ICH or IVH. The study design will also allow us to identify the added benefit of specific MR sequences and repeat MRI in the chronic stage, thereby allowing us to prospectively determine their value in a consecutive series of patients. This information should have a major impact on the management of these patients by providing data on the diagnostic yield of routine MRI in patients presenting with a wide variety of causes for ICH or IVH. These data will help guide the diagnostic evaluation and the management of brain hemorrhage patients in the future.
This is a study to evaluate how recombinant tissue plasminogen activator (rt-PA) is utilized in patients with intraventricular hemorrhage (IVH). rt-PA is a drug that has been shown to dissolve blood, and may allow intraventricular catheters to be more effective for a longer period of time.
A problem with breathing during sleep, called obstructive sleep apnea (OSA), likely increases the risk of stroke and is common in people who have had a stroke, present in about 2/3 of stroke survivors. There is also evidence that OSA predicts worse outcome after stroke. The question being addressed in the Stroke and CPAP Outcome Study 3 (SCOUTS3) is how to improve use of continuous positive airway pressure (CPAP) therapy to treat OSA when started during intensive stroke rehabilitation.
This study has two main goals: 1) to refine and enhance the R2R-TBI intervention; and 2) to examine the efficacy of the R2R-TBI intervention in a randomized control trial. To achieve the second goal, we will employ a between-groups randomized treatment design with repeated measures at baseline, one-month post-randomization, and at a six-month follow-up. The two conditions will be: a) usual medical care plus access to internet resources regarding pediatric brain injury (Internet Resources Comparison group, IRC), and b) usual medical care plus the R2R-TBI intervention (Road-to-Recovery group, R2R-TBI).
The purpose of this prospective, single center, single arm registry is to assess technical feasibility, peri-procedural complications, post-procedure imaging outcomes, and 30-day safety outcomes in subjects with intraventricular hemorrhages utilizing the Artemis Neuro Evacuation Device in the hyper-acute phase.
In this study, investigators look at a different type of technology that might help to avoid having to perform CT scans in certain patients suspected of having a head injury. Near-infrared spectroscopy (NIRS) uses a specific light wavelength to determine if there is bleeding into the head as a result of trauma. Investigators will study NIRS, using a device called the Infrascanner model 2000, to determine if it is as good at detecting bleeding in the head as CT scan, which is the current gold standard. Investigators will try to determine if NIRS can rule in or rule out bleeding into the head, and perhaps this can help to avoid subjecting these youth to the potentially harmful effects of radiation. Investigators will also study how easy it is to use NIRS so that it might become a standard part of the workup for children with suspected head injury.
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).
This is a multicenter, randomized, adaptive clinical trial comparing standard medical management to early (\<24 hours) surgical hematoma evacuation using minimally invasive parafascicular surgery (MIPS) in the treatment of acute spontaneous supratentorial intracerebral hemorrhage.
This is a human clinical study involving the isolation of autologous bone marrow derived stem cells (BMSC) and transfer to the vascular system and inferior 1/3 of the nasal passages in order to determine if such a treatment will provide improvement in neurologic function for patients with certain neurologic conditions. http://mdstemcells.com/nest/
The overall purpose of this study is to evaluate how effective Thromboelastography (TEG) is on identifying ischemic and hemorrhagic stroke patients at increased risk for bleeding after receiving tissue plasminogen activator (tPA), as well as on differentiating between patients in whom optimal thrombolysis has been achieved, and those whom it has not.
Traumatic brain injury (TBI) is the most common cause of acquired disability in youth and a source of significant morbidity and family burden. Novel behavior problems are among the most common and problematic consequences, yet many youth fail to receive needed psychological services due to lack of identification and access. Linking youth with TBI to effective treatments could improve functional outcomes, reduce family burden, and increase treatment satisfaction. The investigators overarching aim is to compare the effectiveness, feasibility, and acceptability of three formats of family problem solving therapy (F-PST) for improving functional outcomes of complicated mild to severe adolescent TBI: therapist-guided, face-to-face; therapist-guided online; and self-guided, online F-PST.