996 Clinical Trials for Various Conditions
Traumatic brain injury (TBI) accounts for approximately 2.5 million visits to emergency departments in the United States each year. After decades of research, management strategies for severe TBI (sTBI) patients are still evolving. Optimizing intracranial pressure (ICP) and cerebral perfusion pressure (CPP) are paramount in the management of these patients and placement of these monitors is the current standard-of-care. However, monitoring brain oxygenation (PbtO2) with invasive intraparenchymal monitors is currently under investigation in the management of severe TBI and placement of these monitors is gaining widespread use. This has opened the door for the use of tiered therapy to optimize ICP and PbtO2 simultaneously. Current evidence indicates that correction of ICP, CPP and PbtO2 in sTBI requires optimized analgesia and sedation. Ketamine is one of the few drugs available that has both sedative and analgesic properties and does not commonly compromise respiratory drive like opioids and sedative-hypnotics. However, traditionally, ketamine has been viewed as contraindicated in the setting of TBI due to concerns for elevation in ICP. Yet, new data has cast this long-held assumption into significant doubt. Hence the present pilot study will characterize the neurophysiological response to a single dose of ketamine in critically-ill TBI patient with ICP and PbtO2 monitoring.
This is a research study that aims to examine whether Veterans with mild Traumatic Brain Injuries are at risk for dementia by studying their memory, brain wave activity, brain structure and proteins that can be elevated after brain injury and in dementia.
This study aims to determine the safety of HB-adMSC infusion and treatment effects of HB-adMSC infusion on brain structure, neurocognitive/functional outcomes, and neuroinflammation after subacute and chronic neurological injury in adults.
Concussion is the most common type of brain injury throughout life. Study is seeking improvement of long-term residua following adolescent and adult post-traumatic injuries often associated with contact sports and accidental causes. Typically defined as reversible head injury with temporary loss of brain function. Symptoms range from physical, cognitive, pain (headache) and emotional signs consistent with TBI and Post-Traumatic Stress Syndrome. Use of AD-cSVF parenteral delivery to encourage repair of damage and decreased function following concussion, particularly in contact, repetitive sports injuries. Range of damage is measured in Grade I-III according to graduated severity. Unfortunately, less information is available about repetitive concussions and the long-term health issues.
The potential long-term effects of Traumatic Brain Injury (TBI) are poorly understood. Repeated concussions have been associated with an elevated incidence of Alzheimer's disease (AD) along with a reduced age of onset. As repetitive TBI has been studied, a syndrome has now been identified: chronic traumatic encephalopathy (CTE). There are growing concerns about the long-term neurologic consequences of head impact exposure from routine participation in contact sports (e.g., boxing, football). Brain autopsies of athletes with confirmed CTE have demonstrated tau-immunoreactive neurofibrillary tangles and neuropil threads (known as tauopathy). The relationship between exposure to repetitive head impact and the subsequent development of chronic neurodegenerative disease has not been established. Further, as the diagnosis of CTE (defined by the presence of tauopathy) is presently made after death at autopsy, clinical tools and biomarkers for detecting it remain to be defined. With the advent of FDA-approved PET amyloid imaging, clinicians and researchers are now able to estimate plaque density in the brains of living patients. However, there are critical limitations to amyloid imaging. Current evidence suggests that markers of the presence and severity of tauopathy may be able to address these limitations. The study will utilize both \[18F\] Florbetapir and \[18F\]-T807 PET imaging to investigate amyloid and tau accumulation in subjects with a history of concussions. In order to determine whether problems with cognition and memory are seen within the populations defined for the study, the researchers will administer a core battery of neurocognitive testing. This battery will assess cognitive abilities commonly affected by TBI, including processing speed, reaction time, new problem-solving, executive functions, attention and concentration, and learning and memory. These tests, in conjunction with the imaging, will be able to determine whether regional brain activity is associated with specific cognitive problems. The researchers will obtain PET and neurocognitive data in 3 cohorts: subjects with a history of TBIs, subjects with mild cognitive impairment (MCI) and no TBI history, and healthy controls. The investigators aim to determine whether individuals with TBI are on the same trajectory of neurodegenerative disease seen in AD or in CTE. Because of the overlap in clinical/cognitive and some behavioral symptoms in AD and CTE, an additional biomarker tool is needed to prevent misdiagnosis. Accurate diagnosis is crucial in order to provide patients with appropriate treatment.
Background: - Chronic traumatic encephalopathy (CTE) is a brain disease caused in part by head injury. The brain changes from CTE can only be seen at autopsy. Researchers want to test a new brain scan to help diagnose CTE in living patients. Objective: - To determine if a new type of brain scan can detect changes that occur in chronic traumatic encephalopathy. Eligibility: - Adults age 18 60 with previous head injury or participation in certain sports. Design: * Participants will be screened with: * Physical exam * Blood and urine tests * Tests of thinking, mood, and memory * 30-minute magnetic resonance imaging (MRI) brain scan. A magnetic field and radio waves take pictures of the brain. Participants will lie on a table that slides into a metal cylinder. They will get earplugs for the loud knocking sounds. * Visit 1: Participants will have a 70-minute PET scan of the brain with a small amount of a radioactive chemical. That will be injected through an intravenous tube (catheter) in each arm. A catheter will also be put into an artery at the wrist or elbow. * Participants will lie on a bed that slides in and out of a donut-shaped scanner. A plastic mask may be molded to their face and head. Vital signs and heart activity will be checked before and during the scan. * Blood and urine will be taken before and after the scan. * Participants will be checked on by phone the next day. * Visit 2: Participants will repeat Visit 1 with a different chemical and no artery catheter. * Visit 3: Participants may have a spinal tap. Some fluid will be removed by needle between the bones in the back.
Chronic traumatic encephalopathy (CTE) is a progressive degenerative brain disease with symptoms that include memory loss, problems with impulse control, and depression that can lead to suicide. As the disease progresses, it can lead to dementia. Currently CTE can only be diagnosed postmortem where an over-accumulation of a protein called tau is observed. There is now a new experimental measure that makes it possible, for the first time, to measure tau protein in the living human brain using a novel positron emission tomography (PET) ligand, \[F-18\] AV-1451 (aka, \[18F\]-T807). The main objective of this study is to use a novel PET approach to measure tau accumulation in the brain. The presence of CTE at autopsy in deceased National Football League (NFL) players has been well documented. Accordingly, we will conduct this study in a group of retired NFL players who have clinical symptoms of CTE and are suspected of having CTE based on high levels of tau in their spinal fluid and abnormalities seen on research brain scans. We will compare them with a control group of former elite level athletes who have not experienced any brain trauma, deny any clinical symptoms, and who have completely normal spinal fluid tau and amyloid levels, and brain scans. We will also include a group of subjects with AD. All participants will be recruited from ongoing studies, headed by the Partnering PI of this proposal, Dr. Robert Stern, at the Boston University Center for the Study of Traumatic Encephalopathy and the Alzheimer's Disease Center. We will use both a beta amyloid PET scan (\[18F\]-florbetapir) and a tau PET scan (\[18F\]-T807) on consecutive days. With the beta amyloid scan we expect little or no evidence of amyloid in the NFL players with presumed CTE, and no evidence of amyloid in the control group of athletes with no history of repetitive brain trauma. In contrast we expect to see beta amyloid accumulation in the AD patient brains. With the new tau ligand, we expect that the NFL players with presumed CTE will show elevated levels of tau protein in the brain, which will not be observed in athletes without a history of brain trauma, but which will be seen in the AD patients' brains. Another goal is to use the latest MRI technologies to develop specific tau imaging biomarkers that correlate with the PET and spinal fluid tau measures but without the radiation of PET or invasiveness of spinal taps. The development of these surrogate imaging markers of tau, is critically important to diagnosing CTE. This in turn will lead to studies relevant to treatment and prevention of this devastating disease. Finally, as an exploratory method of examining possible genetic risk for CTE, we will also use cutting edge genetic analysis of blood samples from subjects in this proposal and compare tau load, measured by PET tau ligand uptake and cerebrospinal fluid (CSF) p-tau level, with a measure of genetic susceptibility to tau load, referred to as the genetic risk score for tau.
This study will explore the use of flortaucipir as a biomarker for chronic traumatic encephalopathy (CTE) and examine the relationship between clinical presentation and tau deposition.
This project was designed to determine brain imaging patterns using 2-(1-{6-\[(2-fluorine 18-labeled fluoroethyl)methylamino\]-2-naphthyl}ethylidene)malononitrile (\[F-18\]FDDNP) with positron emission tomography (PET) in participants with suspected Chronic Traumatic Encephalopathy (CTE), a progressive degenerative disease of the brain found in people with a history of repetitive traumatic brain injuries (TBIs), characterized by personality, behavioral, and mood disturbances, cognitive impairment, and sometimes motor symptoms. Currently, CTE can only be definitely diagnosed from neuropathological examination of the brain after autopsy. Developing tools to assist in the detection of this condition in living individuals at risk would facilitate research focusing on discovering potential prevention and treatment strategies.
The objective of this study is to measure the frequency and clinical types of mild cognitive impairment (MCI) or dementia that occur among up to 150 military retirees with and without a history of traumatic brain injury (TBI) among residents of the Armed Forces Retirement Home, Washington D.C. and the Veterans Home of California-Yountville. Investigators will compare the characteristics of dementia in those who have had a prior TBI to the characteristics in those without a history of TBI. It is our hypothesis that the dementia or MCI among those with prior TBI has distinct neuropsychological features that distinguishes it from those with dementia or MCI without a history of TBI.
Severe traumatic brain injury (TBI) is associated with a 20-30% mortality rate and significant disability among most survivors. The Centers for Disease Control and Prevention (CDC) estimate that 2% of the U.S. population lives with disabilities directly attributable to TBI, with annual costs exceeding $76.5 billion. Current treatments are largely ineffective because they are instituted after irreversible damage has already occurred. By the time intracranial pressure (ICP) increases or brain tissue oxygen tension (PbtO2) decreases to harmful levels, it is often too late to reverse or repair the damage. A computerized method has been developed that can predict these injurious events ahead of time, allowing clinicians to intervene before further damage occurs. The goal of this proposal is to test these predictions in real time. The first phase of the project (Year 1) involves setting up the informatics infrastructure, with no patient interaction. In the second phase (Year 2), subjects, through surrogate decision-makers, will be enrolled in an observational study where data on intracranial pressure and brain tissue oxygen tension will be collected, and the prediction algorithm will be tested for accuracy. Clinical management will follow standard care protocols, and no additional interventions will be performed. Approximately 120 individuals will participate in this study at the University of Chicago and Ben Taub General Hospital in Houston. Data collected will include both the electronic medical record and data from bedside intensive care unit monitors. The electronic medical record includes demographic information, injury characteristics, laboratory values, and imaging data, while the intensive care unit monitor provides real-time vital signs such as intracranial pressure, brain tissue oxygen tension, and mean arterial pressure. These data will be securely stored in a research computer database. Efforts will be made to contact subjects or their caretakers at 6 months to follow up on recovery. This research aims to improve patient outcomes by providing predictions of further brain injury, with the potential for future interventions to prevent permanent brain damage.
Patients evaluated at Penn Presbyterian Medical Center for traumatic brain injury (TBI), who sign the informed consent, will undergo assessment of electrophysiologic potentials evoked by transcranial magnetic stimulation (TMS), using the Delphi-MD device (QuantalX Neuroscience Ltd., Saba Israel).
The purpose of this study is to evaluate the effect of transcranial photobiomodulation (tPBM) in older patients with chronic traumatic brain injury (TBI). The study aims to examine the effect of tPBM on prefrontal cerebral blood flow (CBF) and executive function (EF)
The goal of this clinical trial is to determine which crystalloid (saline or balanced) should be used in the critical management of Traumatic Brain Injury (TBI) in moderate or severe TBI patients. This trial will determine whether the use of saline or balanced crystalloids is associated with improved outcomes in TBI patients. Participants will 1. be given fluids through the veins, either saline or balanced fluid will be given. 2. From the first day to the day 14 of the hospitalization (or discharge, whichever comes first), vital signs, laboratory values, treatments given, and other medical data will be collected from the medical record. 3. Six months later, your final disability, if any, will be assessed during your follow-up with a doctor. It involves answering a short survey that will take about 5 minutes or less.
The primary objective of this study is to establish if Glial Fibrillary Acidic Protein (GFAP) and Ubiquitin C-terminal Hydrolase L1 (UCH-L1) are predictive of computed tomography (CT) findings in pediatric traumatic brain injuries (TBI). The participant population is pediatric patients, ages 0 to less than 18 years old with a possible TBI or trauma-related injury who have blood drawn per standard of care in the emergency department. Blood samples will be analyzed using the i-STAT TBI cartridge (Abbott Laboratories, Abbott Park, IL, USA) by the Emergency Department charge nurse within one hour of collection of the blood sample. Clinical outcomes will be assessed via telephone interview with a parent at 3 and 6 months for all surviving TBI patients.
The use of Hyberbaric Oxygen Therapy (HBOT) would be a new treatment plan rather than conventional rest. If effective, this new use technology would add to the clinical treatment among mild traumatic brain injury (mTBI) patients. The use of a point of care Glial Fibrillary Acidic Protein (GFAP) biomarker would aid in clinical decision making to create a new care plan of return to sport among unarmed combat athletes who suffer from mTBI. The innovation would be a new treatment and diagnosis strategy that will protect these athletes from serious long-term sequelae. There are no published randomized controlled studies using HBOT to treat concussed athletes within one week of injury. There are no published studies using GFAP levels to predict post concussive symptoms (PCS).
The two goals of the proposed study are: (1) To determine how brain activity changes with cognitive recovery over time from acute to chronic phases of traumatic brain injury (TBI). (2) To determine how the time of anodal transcranial electrical stimulation (A-tES) administration affects cognitive performance and brain activity in TBI. To achieve these study goals, the investigators will conduct a pilot clinical trial over three years in which the investigators aim to recruit 60 patients with moderate to severe TBI at the University of Cincinnati Medical Center (UCMC). During the acute phase of TBI, all participants will complete clinical questionnaires and perform 2 cognitive computer tasks while their brain activity is recorded. Half of the participants will be randomly selected to receive A-tES for 15 minutes while performing cognitive tasks and the other half will receive sham stimulation. All participants will be followed for 6 months. During their 3-month follow-up, the investigators will perform another session where all participants complete the questionnaires and receive A-tES while performing cognitive tasks during brain recording. In their last visit at 6 months post-injury, all participants will complete the questionnaires and cognitive tasks with brain recording but no stimulation treatment. From the collected data, the investigators will determine if time from brain injury correlates with brain activity during performance of cognitive tasks. The investigators will also assess the efficacy of early A-tES treatment for improving cognitive task performance and clinical test ratings at 6 months post-injury in comparison to A-tES delivered during the 3-month follow-up visit.
The objective of the study is to conduct a randomized controlled trial of Cognitive Behavioral Therapy for Insomnia (CBT-I) in a sample of active-duty sailors with a history of traumatic brain injury (TBI). The investigators will test the impact of CBT-I on insomnia symptoms as well as post-concussive symptoms, psychological symptoms, and neurocognitive functioning in comparison to treatment as usual. The investigators will also compare the effectiveness of traditional in-person CBT-I and CBT-I delivered via a clinician-supervised digital health platform, Clinician Operated Assistive Sleep Technology (COAST) in comparison to treatment as usual on symptoms of insomnia, post-concussive symptoms, neurocognitive functioning, and psychological health. Participants will be assessed at baseline, post-treatment, and 3 months later.
The purpose of this study is to assess the incidence of early post-traumatic seizures. The study will also assess the benefit of lacosamide compared to levetiracetam in regards to agitation and behavioral adverse effects in patients with moderate to severe traumatic brain injury requiring seizure prophylaxis.
The purpose of this study is to learn more about how brain stimulation affects word finding problems in people who have a traumatic brain injury (TBI). The type of brain stimulation used is called transcranial direct current stimulation (tDCS). tDCS delivers low levels of electric current to the brain and high definition tDCS (HD-tDCS) delivers the current with multiple electrodes on the scalp. This current is delivered with HD-tDCS to parts of the brain that may help with remembering things. The investigators hope that this can help to improve word finding and memory problems in people with TBI.
The purpose of the study is to test whether low level electric stimulation, called transcranial Direct Current Stimulation (tDCS), on the part of the brain (i.e., pre-supplementary motor area) thought to aid in memory will improve verbal retrieval in civilian (non-military, non-veteran) participants with histories of traumatic brain injuries. The primary outcome measures are neuropsychological assessments of verbal retrieval, and the secondary measures are neuropsychological assessments of other cognitive abilities and electroencephalography (EEG) measures. Additionally, the study will examine the degree to which baseline assessments of cognition, concussion history, structural brain imaging, and EEG predict responses to treatment over time, both on assessments administered within the intervention period and at follow-up.
Researchers at Massachusetts General Hospital are looking to see if a program created to help improve thinking and memory can work for refugees and asylum seekers with traumatic brain injury (TBI). They're checking if this program is practical and if people find it helpful. The study will have two groups, and people will be assigned to a group by chance. One group will participate in the program and answer questionnaires before starting the program and then one month and three months after the end of the program. The other group will answer a questionnaire after they enroll, then one month and three months after enrollment. People in this second group will have the option to participate in the program after three months.
The goal of this study is to learn if a enhanced environment (Metro Café) with multi model approach (an approach that combines several therapies) in chronic traumatic brain injury improves outcomes of recovery better than traditional therapy. The main questions it aims to answer are: * Determine the amount of therapy dosage (speech, cognition, arm and leg movements) obtained during the Metro Café therapy session. * Evaluate the connection between environmental enrichment dosage (the Metro Café) and clinical outcome scores. Researchers will compare Metro Café Treatment to those who do not receive this treatment to see if better improvements in function after a traumatic brain injury are seen in the Metro Café Treatment Participants will train in the Metro Cafe during the 2-month gap between assessments, for a total of 18 training sessions, each up to 2 hours, 3 times per week. Participants will greet and serve customers drinks and snacks, maintain food supplies at the counters and performs housekeeping tasks with advice and assistance from a supervising researcher as needed,
Mild traumatic brain (mTBI) injury affects 400,000 U.S. Veterans resulting in physical, cognitive and mental health symptoms. The Department of Defense (DoD) reported 26 suicides a day from mTBI despite ongoing care for the Veterans. The purpose of this pilot research study is to evaluate the effect of treating Veterans suffering from mTBI or persistent post-concussion syndrome with hyperbaric oxygen therapy (HBOT).
The purpose of this study is to develop and validate ways to provide better patient education and clinical management for individuals who go to the emergency department (ED) with concussion or mild traumatic brain injury (mTBI).
Our proposed study, \"NEUROBALANCE,\" aims to evaluate the effectiveness of a combined intervention involving robotic balance training and noninvasive brain stimulation in improving balance functions in individuals with chronic traumatic brain injury (TBI). The study will recruit 45 participants who have had a TBI for over six months and experience persistent balance deficits. Participants will be randomized into three groups: (1) robotic balance training with active brain stimulation, (2) robotic balance training with sham brain stimulation, and (3) standard-of-care rehabilitation. The study will involve 12 training sessions over four weeks, with assessments conducted at baseline, post-training, and two months post-training to evaluate balance recovery and retention. The primary focus is understanding how this intervention affects brain and muscle activity during balance tasks and how these changes translate into functional improvements in clinical outcome measures of balance function. Additionally, participant feedback on brain stimulation and exercise engagement will be collected to inform future studies. This research is particularly relevant to military service members, as TBI and balance impairments are common among this population. The findings may guide the development of personalized training protocols and contribute to broader rehabilitation strategies.
The goal of this blinded, adaptive, randomized, placebo-controlled clinical trial is to investigate the use of hyperbaric oxygen as a therapy to treat mild to moderate traumatic brain injury in Veterans and active military. The main questions it aims to answer are: * Does Hyperbaric Oxygen Therapy (HBOT) reduce neurobehavioral symptoms? (Aim 1) * How many HBOT sessions are needed to achieve a significant reduction in neurobehavioral symptoms? (Aim 2) * Does HBOT reduce posttraumatic stress disorder (PTSD) symptoms? (Aim 3) Exploratory objectives will explore if there are changes in: 1.) cognitive functioning using neuropsychological tests and the National Institutes of Health (NIH) toolbox, 2.) inflammation biomarkers in blood, 3.) microbiome in stool samples, 4.) electroencephalogram (EEG), 5.) sleep characteristics, and 6.) fMRI. Research will compare HBOT therapy to a placebo condition to see if HBOT works to treat neurobehavioral symptoms. The placebo condition is a chamber that remains unpressurized and has 21% oxygen. Participants will: 1. Complete baseline assessments to determine eligibility. 2. Attend 40 sessions of HBOT or placebo (normal air) within 12 weeks. 3. Complete questionnaires and interviews throughout the course of the study. 4. Complete a 2-week post treatment visit
Acute intermittent hypoxia (AIH) involves 1-2min of breathing low oxygen air to stimulate neuroplasticity. Animal and human studies show that AIH improves motor function after neural injury, particularly when paired with task-specific training. Using a double blind cross-over study we will test whether AIH and task-specific airway protection training improves airway protection more than training alone in individuals with chronic mild-moderate traumatic brain injury (TBI).
Cognitive impairment after moderate to severe traumatic brain injury (msTBI) not only significantly affects the quality of life in individuals with msTBI, but also increases the possibility of late-life dementia. The goal of this study is to determine whether acute (\< 1 week) cerebrovascular injury and its recovery within the first year postinjury measured by cerebral autoregulation and brain perfusion are associated with cognitive outcome at 12 months after msTBI. The results from this study will improve our understanding of cerebrovascular contributions to cognitive decline related to TBI and provide critical data to inform the development of strategies based on vascular mechanisms to improve cognition and prevent neurodegeneration after msTBI.
The overarching goal of this pilot study is to assess the feasibility and safety of transcutaneous auricular neurostimulation (tan) in ICU patients with TBi and to determine the effect of tan on serum markers of inflammation. exploratory analyses will examine effects on such physiological parameters as blood pressure, heart rate, and intracranial pressure (iCP), as well as measures of neurological function.