38 Clinical Trials for Cerebral Ischemia
The investigators propose to infuse healthy autologous mitochondria into cerebral vessels supplying brain tissue experiencing ischemia in patients who undergo standard-of- care endovascular reperfusion therapy.
In this prospective, single-arm, open-label, imaging and treatment study, the investigator will test the hypothesis that crizanlizumab will prevent the progression of silent cerebral infarcts in patients with sickle cell disease. Study participants will undergo brain MRI before initiation of crizanlizumab and at 6 and 30 months after starting crizanlizumab infusions. The crizanlizumab cohort will be compared to a matched, observational cohort of patients not receiving crizanlizumab.
The purpose of this study is to test feasibility of a comparative effectiveness framework for acute stroke imaging using prospective electronic health data. This is a prospective, cohort feasibility study of patients presenting to the Emergency Department with suspected acute ischemic stroke. The clinical stroke team will not be blinded to the imaging modality given the nature and purpose of the interventions/imaging. Knowledge of the imaging modality used and the knowledge gained from the resulting data will need to be considered for treatment decisions. Blinding will be maintained for data abstraction and analyses. Analysis will be on an "intent-to-scan" basis and all qualifying patients will be included in their assigned cohort.
RESTORE is a randomized clinical trial investigating the safety and feasibility of using EEG treatment targets (burst suppression vs. seizure suppression) for post-cardiac arrest refractory status epilepticus treatment.
The Stroke Recovery Initiative is a nation-wide participant recruitment registry that connects people who have had a stroke with researchers who are working to develop new approaches to improve recovery after stroke.
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 goal of this clinical trial is to determine if Transcranial Magnetic Stimulation (TMS) combined with modified Constraint Induced Language Therapy (mCILT) is an effective treatment for aphasia when delivered in the subacute stage after stroke. The main questions this study aims to answer are: 1. Can TMS combined with mCILT improve overall speech? 2. Can we identify specific behavioral and biological characteristics that would benefit most from the TMS and mCILT treatment? Researchers will compare real TMS to sham (fake) TMS to see whether TMS can treat subacute aphasia. Importantly, this trial will use electric field guided TMS to identify optimal and individualized stimulation intensity and site targeting. Participants will: * Complete a screening and medical intake to determine eligibility * Undergo MRI scans * Participate in 10 consecutive sessions (Monday-Friday) of TMS and mCILT treatment * Complete follow-up assessments immediately and 4 months after treatment
The goal of this clinical trial is to determine if Transcranial Magnetic Stimulation (TMS) combined with Speech-Language Therapy (SLT) is an effective treatment for mild aphasia in persons with chronic stroke. The main questions this study aims to answer are: 1. Can TMS combined with SLT improve conversational speech and comprehension? 2. Can we identify specific behavioral and biological characteristics that would benefit most from the TMS and SLT treatment? Researchers will compare real TMS to sham (fake) TMS to see whether TMS can treat post-stroke mild aphasia. Participants will: * Complete a screening and medical intake to determine eligibility * Undergo a MRI * Participate in 10 consecutive sessions (Monday-Friday) of TMS and SLT treatment * Complete follow-up assessments 2 and 4 months after treatment
To determine effectiveness of therapy to improve neurodevelopmental outcomes in infants with mild HIE. To determine the adverse effects of Therapeutic Hypothermia (TH) in mild HIE on the neonate and his/her family. Determine heterogeneity of the treatment effect across key subgroups obtained in the first 6 hours after birth prior to the decision to initiate therapy.
The purpose of this study is to improve the ability of the investigators to monitor brain health in newborn babies at risk of brain injuries. The researchers will be using an investigational system of devices to non-invasively (that, is, without penetrating the skin), measure the amount of oxygen going to and being used by the brain. They will be taking some bedside research measurements during the babies' stay at the hospital. With these measurements, the intention is to study the role of oxygen in brain injury and test the efficacy of the research device and its potential as a permanent bedside diagnostic device.
The primary objective is to characterize the prevalence and type of ABI following cannulation for pediatric patients who require ECMO support. The secondary objective is to describe the time course and rates of ABI using ultralow-field bedside MRI relative to both duration of ECMO support and clinical imaging obtained in routine care of pediatric ECMO patients.
This is a multicenter trial to establish the efficacy of cooling and the optimal duration of induced hypothermia for neuroprotection in pediatric comatose survivors of cardiac arrest. The study team hypothesizes that longer durations of cooling may improve either the proportion of children that attain a good neurobehavioral recovery or may result in better recovery among the proportion already categorized as having a good outcome.
Life-threatening mass effect (LTME) arises when brain swelling displaces or compresses crucial midline structures subsequent to acute brain injuries (ABIs) like traumatic brain injury (TBI), ischemic stroke (IS), and intraparenchymal hemorrhage (IPH), which can manifest rapidly within hours or more gradually over days. Despite advancements in surgical management, significant gaps in understanding persist regarding optimal monitoring and therapeutic approaches. The current standard for identifying LTME involves neurologic decline in conjunction with radiographic evidence or increased intracranial pressure (ICP) indicating space-occupying mass effect. However, in critically ill patients, reliance on subjective physical exam findings, such as decreased arousal, often leads to delayed recognition, occurring only after catastrophic shifts have already occurred. The goal of this study is to determine the association of non-invasive biomarkers with neurologic deterioration, and to determine whether non-invasive biomarker inclusion improves detection of outcome and decline. The investigators propose to use various non-invasive methods to monitor ICP as adjuncts in detecting deteriorating mass effect. These methods include quantitative pupillometry, radiographic data, laboratory data, and other bedside diagnostic tests available including electroencephalography (EEG), skull vibrations detected via brain4care device, optic nerve sheath diameter assessment (ONSD), and ultrasound-guided eyeball compression. Some of these methods will be measured \*only\* for the purposes of the research study (such as skull vibrations via brain4care). Other measurements, such as quantitative pupillometry, will represent additional measurements beyond those already being collected for clinical care. This research study is necessary to understand the association of these non-invasive biomarkers with neurological decline and outcomes while considering potential confounding factors.
People living with the cognitive effects of stroke are at risk for recurrent stroke and further cognitive decline. Also problematic is that stroke risk clusters in families and biological family members of people who have ischemic stroke may also be at increased risk of stroke and/or cognitive decline. The primary goal of this study is to test the feasibility of a virtually delivered cognitive strategy training and health coaching program to reduce vascular risk and promote brain health in persons with stroke and their biological family members.
This is an observational study in patients who require clinical anesthesia. The main purpose of this study is to understand whether there are differences in the cerebral blood flow, and oxygen metabolism affected by different types of anesthesia. Subjects who require clinical anesthesia for a clinical MRI and for whom the use of anesthetics for the exam are in clinical equipoise are asked to join the study. All eligible subjects will be asked to provide informed consent before participating in the study.
To evaluate the dose-response of relevant blood biomarkers to remote ischemic conditioning in patients with age-related cerebral white matter hyperintensities on MRI, in preparation for a subsequent larger efficacy trial.
Prospective, multi-center, single-arm early feasibility study enrolling a minimum of 15 subjects at up to a minimum of 3 active investigational sites in the United States. The subjects must be diagnosed with acute ischemic stroke (AIS), must be post-mechanical thrombectomy, will have had intravenous thrombolytics, and have a visible MCA, ACA or PCA occlusive clot on initial angiographic imaging. Each subject will receive the Pulse NanoMED procedure after attempted neurovascular therapy to achieve better reperfusion.
A human subjects research study, the primary purpose of which is to assess the EFFECTS OF SEMAGLUTIDE ON INTRACRANIAL BLOOD FLOW AND BLOOD-BRAIN BARRIER PERMEABILITY IN TYPE-2 DIABETES (T2D) through testing of the intervention on patients in a clinical setting. The study will randomize subjects with diabetes to either semaglutide or matching placebo. Magnetic resonance images will be primary endpoint measured at baseline and at one year to assess effect of this FDA approved medication. Given the available evidence supporting the neuroprotective effect of this drug class and stroke reduction with semaglutide, and the investigators preliminary data showing that T2D had significantly reduced total number of distal arterial branches in the brain than non-T2D, the investigators expect treatment with semaglutide will be associated with improved intracranial blood flow condition.
Hypoxic-ischemic encephalopathy (HIE) affects approximately 4,000 to 12,000 persons annually in the United States. Mortality from HIE has been reported up to 60%, with at least 25% of survivors left with significant neurocognitive disability. Despite this vital unmet medical need, no pharmacological adjunct or alternative therapy has proven beneficial in improving outcomes in neonatal HIE. RLS-0071 is a novel peptide being developed for the treatment of neonatal HIE. This study is designed to evaluate the safety and tolerability of RLS-0071 in the treatment of newborns with moderate or severe HIE.
Unilateral cerebral palsy (UCP) is a leading cause of childhood disability. An early brain injury impairs the upper extremity function, bimanual coordination, and impacts the child's independence. The existing therapeutic interventions have higher training doses and modest effect sizes. Thus, there is a critical need to find an effective priming agent to enhance bimanual skill learning in children with UCP. This study aims to determine the effects of a novel priming agent, remote ischemic conditioning (RIC), when paired with bimanual skill training to enhance bimanual skill learning and to augment skill dependent plasticity in children with UCP.
Cerebral small vessel disease (CSVD) can lead to vascular cognitive impairment and dementia (VCID). The hallmark of CSVD is the appearance and progression of white matter hyperintensities (WMH) on MRI. The goal of this study it to recruit and follow individuals at risk for WMH progression and use serial MRI scanning to gain insights into the pathogenesis of CSVD.
The goal of this study is to gain a better understanding of why some individuals who have suffered a stroke experience post-stroke cognitive decline. Specifically this study is testing whether global disruption of the blood-brain barrier detected at the time of the stroke is informative about the risk of post-stroke cognitive decline over the next 3 years.
Unilateral cerebral palsy (UCP) is a leading cause of childhood disability. An early brain injury impairs the upper extremity function, bimanual coordination, and impacts the child's independence. The existing therapeutic interventions have higher training doses and modest effect sizes. Thus, there is a critical need to find an effective priming agent to enhance bimanual skill learning in children with UCP. This study aims to determine the effects of a novel priming agent, remote ischemic conditioning (RIC), when paired with intensive bimanual skill training to enhance bimanual skill learning and to augment skill dependent plasticity in children with UCP.
This is a randomized, pilot interventional study in participants with visual field deficit (VFD) caused by cortical lesion. Damage to the primary visual cortex (V1) causes a contra-lesional, homonymous loss of conscious vision termed hemianopsia, the loss of one half of the visual field. The goal of this project is to elaborate and refine a rehabilitation protocol for VFD participants. It is hypothesized that visual restoration training using moving stimuli coupled with noninvasive current stimulation on the visual cortex will promote and speed up recovery of visual abilities within the blind field in VFD participants. Moreover, it is expected that visual recovery positively correlates with reduction of the blind field, as measured with traditional visual perimetry: the Humphrey visual field test or an eye-tracker based visual perimetry implemented in a virtual reality (VR) headset. Finally, although results will vary among participants depending on the extent and severity of the cortical lesion, it is expected that a bigger increase in neural response to moving stimuli in the blind visual field in cortical motion area, for those participants who will show the largest behavioral improvement after training. The overarching goals for the study are as follows: Group 1a will test the basic effects of transcranial random noise stimulation (tRNS) coupled with visual training in stroke cohorts, including (i) both chronic/subacute ischemic and chronic hemorrhagic VFD stroke participants, and (ii) longitudinal testing up to 6 months post-treatment. Group 1b will test the effects of transcranial tRNS coupled with visual training on a Virtual Reality (VR) device in stroke cohorts, including both chronic/subacute ischemic and chronic hemorrhagic VFD stroke participants. Group 2 will examine the effects of tRNS alone, without visual training, also including chronic and subacute VFD stroke participants and longitudinal testing.
This study will be a longitudinal multiple-visit observational study, done to identify possible bioindicators of recovery and repair of motor corticospinal pathways which may be targeted by future interventions in infants with perinatal stroke. 65 participants will be recruited and complete 1 visit at time point 1 (0-2 months), and 2 visits at each timepoints 2-5 with windows of +- 4 weeks (3-6 months, 12 months, 18 months and 24 months). Visits will consist of Magnetic Resonance Imaging (MRI) assessment during the child's natural sleep, Transcranial Magnetic Stimulation (TMS), and Motor Behavioral Assessments.
Demonstrating the pathophysiological link between Left Atrial (LA) and Left Atrial Appendage (LAA) pathology and embolic strokes in non-Atrial Fibrillation (AF) individuals represents a major advance in stroke prevention strategies. Instead of relying on non-specific criteria for stroke risk assessment, the investigators propose to identify individuals with high-risk of embolic stroke using imaging criteria that reflect the underlying pathophysiology of embolic stroke of cardiac origin. the investigators can therefore lay the groundwork for future anticoagulation strategies for stroke prevention beyond AF.
Ammonia is a waste product of protein and amino acid catabolism and is also a potent neurotoxin. High blood ammonia levels on the brain can manifest as cytotoxic brain edema and vascular compromise leading to intellectual and developmental disabilities. The following aims are proposed: Aim 1 of this study will be to determine the chronology of biomarkers of brain injury in response to a hyperammonemic (HA) brain insult in patients with an inherited hyperammonemic disorder. Aim 2 will be to determine if S100B, NSE, and UCHL1 are altered in patients with two other inborn errors of metabolism, Maple Syrup Urine Disease (MSUD) and Glutaric Acidemia (GA1).
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.
This is a prospective open enrollment biorepository to collect and evaluate blood and tissue collected during cerebrovascular procedures, which will then be used for the purposes of identifying biological markers, inflammatory cell infiltrates, and biological states in stroke and other cerebrovascular diseases in the human condition. The study population will include up to 1000 subjects with cerebrovascular disease or suspected cerebrovascular disease. Male and female participants 18 years of age and older will be enrolled. This protocol covers the procurement of biological samples from patients undergoing any cerebrovascular surgery and/or neurointerventional clinical procedure at University of Kentucky. Control participants will include patients undergoing non-emergent, elective diagnostic cerebral angiography as well as patients undergoing emergent angiogram cases. This study represents the first time that tissue, clot and blood will be evaluated for the markers, proteins, and cytokines in human subjects undergoing cerebrovascular procedures. By starting with the human condition, the investigators aim to minimize this loss in translation. Overall, this study will have a great impact on our knowledge of stroke pathology. In essence, this could fundamentally change not only how the investigators develop treatment strategies for the stroke patient population but allow us to individualize the treatment dependent on time after stroke, age, sex, and co-morbidities. Molecular techniques that are impractical when delivered systemically could be delivered locally to impede the early inflammation. This research aims to advance understanding of cerebrovascular disease and to support the development of improved therapies.
The risk of stroke and vascular dementia is high in individuals who have had a prior stroke or TIA, and in those who have vascular disease risk factors, such as high blood pressure, abnormal cholesterol, diabetes or pre-diabetes. These vascular risk factors can improve with exercise. This study will examine the impact of a 6 month, low intensity group exercise class on fitness, walking, balance, and brain health. This study will also collect fitness, walking, balance, and brain health outcome measures at baseline and post all other MERCE exercise and robotics interventions.