309 Clinical Trials for Various Conditions
A study to assess pharmacokinetics, safety and tolerability of brexpiprazole in children ages 6 to \<13 years with CNS disorders.
This study will examine how HIV affects the brain and nervous system, learning, and behavior in children on highly active antiretroviral therapy (HAART). Although HAART has resulted in fewer HIV-infected children getting sick and even fewer dying from AIDS, many children on this treatment regimen develop significant brain or nervous system problems, such as learning difficulties, attention problems, hyperactivity, and depression. People who acquired HIV disease in the first decade of life and who have evidence of central nervous system (CNS) disease (e.g., encephalopathy, CNS compromise, ADHD, bipolar disease, major depression or psychosis) may be eligible for this study. Candidates are screened with a medical history, physical examination, neuropsychological testing and a CT scan of the head, if one has not been done within 12 months of entering the study. Participants undergo the following tests and procedures: * MRI and MRS scan of the head: These tests use a magnetic field and radio waves to obtain images of the brain and detect changes in certain brain chemicals that may be affected by HIV infection. Both procedures are done at the same time. The patient lies on a table that is moved into the scanner (a narrow cylinder), wearing earplugs to muffle loud knocking and thumping sounds that occur during the scanning process. The procedure lasts about 50 to 60 minutes, during which time the patient can communicate with the staff. * Neuropsychological testing: Patients' thinking and behavior are evaluated with tests to measure their memory, attention, language, problem-solving, academic, and motor skills and questionnaires to assess behavioral and emotional functioning, quality of life, and adherence to HIV medication. Parents are also asked to complete questionnaires assessing their child's behavioral and emotional functioning, quality of life, important life events, and adherence to HIV medication. * Lumbar puncture (spinal tap): Cerebrospinal fluid (CSF) is collected for analysis. For this procedure, a local anesthetic is given and a needle is inserted in the space between the bones in the lower back where the CSF circulates below the spinal cord. Some fluid is collected through the needle. Blood tests and a physical examination are done before the procedure to make sure it can be done as safely as possible. Patients may also be sedated to prevent any discomfort. * Follow-up: The blood tests, MRI and MRS scans and spinal tap are repeated 1 and 2 years after the initial evaluation. Some blood and spinal fluid samples from participants are stored for possible future studies related to HIV research
This Phase II open-label, uncontrolled, multicenter trial is designed to investigate the pharmacokinetic (PK) profile of gadopiclenol in plasma, in pediatric patients aged up to 23 months inclusive (term neonates or preterm infants after the neonatal period), using a population PK approach. Primary objective is to evaluate the PK profile of gadopiclenol in plasma following single intravenous injection of 0.05 mmol/kg body weight (BW) in pediatric population aged up to 23 months (inclusive) scheduled for a contrast-enhanced MRI examination of any body region including central nervous system (CNS).
Safety and Efficacy Study in pediatric subjects \<2 years of age who have undergone Brain or Spine MRI pre and post 0.1 mmol/kg ProHance administration. Imaging conditions will represent those in routine clinical practice. Retrospective enrolment with a prospective blinded read.
This is a retrospective study to collect already existing data and images from patients ≥ 2 years of age who had MRI for CNS diseases with MultiHance administration at a standard 0.10 mmol/kg dose or the half dose of 0.05 mmol/kg. The MRI images of all included patients will be prospectively reviewed in a blinded read to compare the efficacy of the two doses.
Inflammatory or degenerative diseases of the brain and spinal cord, such as multiple sclerosis, may be related to problems with an individual s immune system. However, more information is needed on the ways in which the cells of the immune system interact with the central nervous system (CNS). This study will compare tests performed on both healthy volunteers and individuals who have signs or symptoms of immune-related damage to their CNS. This study will include two groups of subjects at least 12 years old. Subjects will either have symptoms of immune-related CNS damage, or will be healthy volunteers selected for comparison purposes. Study participants will visit the NIH Clinical Center on an outpatient basis for an initial evaluation visit. During the visit, patients will provide a comprehensive medical history and undergo a neurological examination, and will provide blood samples for research purposes. The healthy volunteers will be asked to schedule a return visit for a magnetic resonance imaging (MRI) procedure, and may be asked to undergo other tests requested by the study researchers on an as-needed basis. The group of patients with symptoms of immune-related CNS damage will be asked to undergo a series of tests, including the following: * MRI procedures, with a minimum of three brain MRIs and one spinal cord MRI taken approximately 4 weeks apart * A diagnostic lumbar puncture, performed on an outpatient basis * Tests of brain and vision activity * Additional blood and tissue samples Patients with symptoms of immune-related CNS damage may be offered the opportunity to participate in additional followup tests with NIH researchers.
This is a study involving the use of Magnetic Resonance Imaging (MRI) contrast agents called Gadavist. The purpose of this study is to look at the safety (what are the side effects) and efficacy (how well does it work) of Gadavist when used for taking images of the brain and spine. The results of the MRI will be compared to the results of images taken without Gadavist.
The collection of data from the myriad of services described is significantly impacted by NIH guidelines defining medical research involving humans as well as the recent implementation of HIPAA constraints which further complicate the conduct of retrospective clinical outcomes research. Simple case reports or case series analysis now involve IRB participation as well as voluminous documentation. The solution to this dilemma lies in developing and promoting secure, confidential prospective clinical databases for storing clinical data for subsequent retrospective de-identified inquiry. These databases function in a way analogous to "tissue banks" for subsequent basic science research. Patients consent to prospective entry of their clinical information into the database so long as they continue to be a patient with the Department of Neurological Surgery or the Departments or Divisions in association with the affiliated programs briefly described above. The consent is obtained during the patient's first inpatient or outpatient encounter in parallel with the HIPAA consent. It can be withdrawn by request of the patient at any time, but it does not expire unless the patient withdraws it, or the patient severs their patient care relationship with UCI Neurosurgery or the affiliated programs. The database is stored on a separate secure server maintained and backed up by the UCIMC Information Technology Department. Access to the database is restricted at multiple levels, with the majority of personnel allowed only limited access for data entry purposes. Only the database programmer/coordinator, the Department Administrator and the Chairman of the Department will have unrestricted access to the database. Authority for permission for levels of security clearance and access to the database, for other individuals, will be vested in the Chairman of the Department of Neurological Surgery. A separate IRB proposal will be formulated for individual study related to the acquisition of data from the de-identified database. Since these future studies will be performed on data sets derived from the previously consented subjects of this IRB-approved project, the requirement for additional consent forms are not anticipated. As a result IRB research proposals utilizing the database can be expedited. Once the specific study is approved, the investigator(s) are provided with the clinical information from the database in the form of a de-identified data set.
This study will examine how the brain rewires itself to make up for the lack of movement many people with stroke experience. It will try to determine if the rewiring differs depending on the location of the stroke and the amount of time since the stroke occurred. For some stoke patients, weakness may persist, while others recover completely after time. It is not known which parts of the brain are involved in the recovery of different types of stroke and if the type of stroke affects recovery. People 18 years of age and older who have had subacute thromboembolic or hemorrhagic stroke more than 3 months before enrolling may participate in this study. Participants come to the NIH Clinical Center three times every 2 years for up to 10 years. At the first visit, patients have a neurological examination and perform tests of motor abilities such as lifting small objects, turning cards, using a spoon, stacking checkers and lifting cans during a short period of time as rapidly as possible. At the second visit, subjects have structural magnetic resonance imaging (MRI) scans of the brain. MRI uses a strong magnetic field and radio waves to obtain images of body organs and tissues. The MRI scanner is a metal cylinder surrounded by a strong magnetic field. During the scan, the subject lies on a table that can slide in and out of the cylinder, wearing earplugs to muffle loud knocking noises associated with the scanning process. Total scan time is about 30 minutes At the third visit, subjects perform some simple movement tasks during functional MRI (fMRI) scans. The procedure is the same as with structural MRI, except that subjects are asked to perform simple movement tasks in the scanner. Before the fMRI scans, electrodes are attached to the subject's arms and legs to monitor muscle activity (surface electromyography). Total scan time is about 1.5 hours. Movement tasks might include pinching a force-measuring instrument with the fingers, pressing different keys on a keyboard as fast as possible, inserting pegs into small holes on a board, lifting weights, flipping cards or similar activities.
The purpose of this study was to assess the safety and enhancing properties of the magnetic resonance imaging (MRI) contrast agent MultiHance in children aged 2 to 17 years having central nervous system (CNS) disorders.
This study will examine the underlying mental processes that determine how people understand social behavior, remember information, and think. Language, planning, problem solving, reasoning, social behavior, and memory are the critical parts of cognition that make up daily life. This study will explore the association between performance on various experimental tasks and day-to-day functioning. Healthy normal volunteers and patients with certain kinds of brain damage (primarily focal or degenerative lesions of the human prefrontal cortex) or psychiatric disorders may be eligible for this study. Candidates with central nervous system trauma, disease or dysfunction will be screened with a routine neurological examination and history. Participants may be asked to complete written tests, sit in front of a computer monitor and press a key to indicate a decision about what appears on the screen (for example, whether a statement is accurate) and answer questions from a test examiner. A skin conductance response (SCR) test may be done along with some of the cognitive tests. SCR uses electrodes (pieces of metal attached to wires) placed on the fingers to measure the subject's emotional reaction to a test. Participants may also do an evoked response test, in which the subject watches words or scenes on a TV screen while his or her responses are recorded from electrodes placed on the scalp (similar to an electroencephalogram). The tests will be scheduled for an average of one session a week, with each session lasting from 30 minutes to 3 hours. Generally, 15 sessions will be scheduled over a 1-year period. Special arrangements will be made to accommodate participants from out-of-town. Participants may have a magnetic resonance imaging (MRI) scan of the brain. This test uses radio waves and a strong magnetic field to picture structural and chemical changes in tissue. For the procedure, the subject lies on a table in a space enclosed by a metal cylinder (the scanner) for about 1 hour. In addition, some study subjects will be invited to participate in a training study designed to improve their planning or social behavior. Participation requires coming to NIH daily over a 1- to 2-month period for 1 to 2 hours each visit.
This research trial will study discourse processing-that is, how the brain processes the meaning of language. It will examine, for example, how words and sentences are interpreted in cases where more than one meaning is possible. The study will include two parts: 1. An investigation of the role of the prefrontal cortex of the brain in discourse processing will compare test performance of patients with prefrontal cortex damage with that of healthy age-matched normal volunteers. 2. An investigation of the role of aging in discourse processing will compare test performance of young healthy subjects (18 to 40 years old) with older healthy subjects (41 to 80 years old). All study candidates-both normal volunteers and patients with brain damage-must be at least 18 years old, speak English as their native language, have a high school degree or equivalent (GED), read on a minimum fourth grade level and be right-handed. Study candidates who have central nervous system disease, dysfunction or trauma will have a routine history and neurological examination. They will also undergo neuropsychological testing if they have not already done so. Patients with neurological damage who have not had a magnetic resonance imaging (MRI) scan within six months or a year will be asked to undergo this procedure. Study participants will take verbal or written tests; sit in front of a computer screen and press computer keys in response to what they are shown; answer questions from an examiner, which may be tape-recorded; and fill out questionnaires. There will be rest breaks between tasks. The studies will be spread over three to four days, with sessions lasting from 30 minutes to three hours.
The goal of this clinical trial is two-fold. First to investigate the feasibility of whether a remotely administered smartphone app can increase the volume and intensity of physical activity in daily life in individuals with a LRRK2 G2019S or GBA1 N370S genetic mutation over a long period of time (24 months). Second, to explore the preliminary efficacy of exercise on markers for prodromal Parkinson's disease progression in individuals with a LRRK2 G2019S or GBA1 N370S genetic mutation. Participants will be tasked to achieve an incremental increase of daily steps (volume) and amount of minutes exercised at a certain heart rate (intensity) with respect to their own baseline level. Motivation with regards to physical activity will entirely be communicated through the study specific Slow Speed smartphone app. A joint primary objective consists of two components. First to determine the longitudinal effect of an exercise intervention in LRRK2 G2019S or GBA1 N370S variant carriers on a prodromal load score, comprised of digital biomarkers of prodromal symptoms. The secondary component of the primary outcome is to determine the feasibility of a remote intervention study. The secondary objective is the effect of a physical activity intervention on digital markers of physical fitness. Exploratory outcomes entail retention rate, completeness of remote digital biomarker assessments, digital prodromal motor and non-motor features of PD. Using these biomarkers, the investigators aim to develop a composite score (prodromal load score) to estimate the total prodromal load. An international exercise study with fellow researchers in the United Kingdom are currently in preparation (Slow-SPEED-UK) and active in the Netherlands (Slow-SPEED-NL). Our intention is to analyse overlapping outcomes combined where possible through a meta-analysis plan, to obtain insight on (determinants of) heterogeneity in compliance and possible efficacy across subgroups
The goal of this study is to verify whether the use of deep brain stimulation can improve motor function of the hand and arm and speech abilities for people following a stroke. Participants will undergo a surgical procedure to implant deep brain stimulation electrode leads. The electrodes will be connected to external stimulators and a series of experiments will be performed to identify the types of movements that the hand and arm can make and how speech abilities are affected by the stimulation. The implant will be removed after less than 30 days. Results of this study will provide the foundation for future studies evaluating the efficacy of a minimally-invasive neuro-technology that can be used in clinical neuro-rehabilitation programs to restore speech and upper limb motor functions in people with subcortical strokes, thereby increasing independence and quality of life.
This study will investigate different donanemab dosing regimens and their effect on the frequency and severity of ARIA-E in adults with early symptomatic Alzheimer's disease (AD) and explore participant characteristics that might predict risk of ARIA. Approximately 300 additional participants will be enrolled per addendum. The study will last approximately 91 weeks and include up to 26 visits in the main study.
The goal of this clinical trial is to evaluate the effect of transcutaneous spinal cord stimulation on blood pressure in individuals with an acute spinal cord injury (within 30 days of injury). Blood pressure instability, specifically orthostatic hypotension (a drop in blood pressure when moving lying flat on your back to an upright position), appears early after the injury and often significantly interferes with participation in the critical rehabilitation time period. The main questions it aims to answer are: 1. Can optimal spinal stimulation increase blood pressure and resolve orthostatic symptoms (such as dizziness and nausea) when individuals undergo an orthostatic provocation (a sit-up test)? Optimal stimulation and sham stimulation (which is similar to a placebo treatment) will be compared. 2. What are the various spinal sites and stimulation parameters that can be used to increase and stabilize blood pressure to the normal range of 110-120 mmHg? Participants will undergo orthostatic tests (lying on a bed that starts out flat and then moved into an upright seated position by raising the head of bed by 90° and dropping the base of the bed by 90° from the knee) with optimal and sham stimulation, and their blood pressure measurements will be evaluated and compared.
This project will investigate the effect of spinal cord transcutaneous stimulation on blood pressure in individuals with a chronic spinal cord injury who experience blood pressure instability, specifically, orthostatic hypotension (a drop in blood pressure when moving from lying flat on your back to an upright position). The main questions it aims to answer are: 1. What are the various spinal sites and stimulation parameters that normalize and stabilize blood pressure during an orthostatic provocation (70 degrees tilt)? 2. Does training, i.e., exposure to repeated stimulation sessions, have an effect on blood pressure stability? Participants will undergo orthostatic tests (lying on a table that starts out flat, then tilts upward up to 70 degrees), with and without stimulation, and changes in their blood pressure will be evaluated.
This is a multi-site, global, open-label study that includes a phase 1b evaluation of elacestrant in combination with abemaciclib in women and men with brain metastases from estrogen receptor (ER)-positive, human epidermal growth factor receptor-2 (HER-2) negative breast cancer. Phase 1b was designed to select the recommended phase 2 dose and is followed by an ongoing phase 2 evaluation of elacestrant in combination with abemaciclib in patients with active brain metastases from ER-positive, HER-2 negative breast cancer.
There is a need for caregiver-initiated and -implemented non-pharmacological interventions directly to and for the person with dementia, including environmental assessment and modification, as first-line treatments for behavioral and psychological symptoms of dementia (BPSD) in persons living with dementia (PLWD). Delivered via telehealth, Harmony at HOME (H@H) aims to train caregivers of persons with moderate to severe ADRD in the skills of assessing and modifying the home environment to promote "person-environment fit," a concept that posits that the ability to access features within a built environment (e.g. bathroom, stairs,) or that factors within the environment itself (lighting, noise level, temperature), especially when linked with individualized social support, contribute to or even shape behavior. In addition to the intervention, the first 10 caregiver participants to enroll will also be invited to participate in two focus groups that will be facilitated during and after the intervention. The first focus group focuses on experiences as a dementia caregiver in rural areas. The second focus group focuses on providing feedback regarding caregivers' perceptions, acceptability, and usefulness of the H@H intervention. These focus groups will be conducted as structured interviews with open-ended questions that encourage participants to share their experiences.
This cluster randomized pragmatic clinical trial will test the effectiveness and feasibility of embedding the Tele-Savvy intervention, a psychoeducational program for family and other informal caregivers of older adults living in the community with Alzheimer's disease and related dementia (ADRD), in two health care systems/clinical sites: UConn Health in Farmington, Connecticut, and Emory Healthcare in Atlanta, Georgia.
To assess the long-term safety and tolerability of XEN496 in pediatric subjects with KCNQ2 developmental and epileptic encephalopathy (KCNQ2-DEE) who had participated in the primary study (XPF-009-301).
A Multi-Center, Phase II, Randomized, Double-Blind, Prospective, Active Placebo-Controlled Trial of Sub-Anesthetic Intravenous Infusion of Ketamine to Treat Levodopa-Induced Dyskinesia in Subjects with Parkinson's Disease.
The main goals of this study are to further determine whether the study drug donanemab is safe and effective in participants with Alzheimer's disease and to validate video scale assessments.
To investigate the potential antiseizure effects of adjunctive XEN496 (ezogabine) compared with placebo in children with KCNQ2 Developmental and Epileptic Encephalopathy (KCNQ2-DEE).
The goal of this study is to verify whether electrical stimulation of the cervical spinal cord can activate muscles of the arm and hand in people with hemiplegia following stroke. Participants will undergo a surgical procedure to implant a system which provides epidural electrical stimulation (EES) of the cervical spinal cord. Researchers will quantify the ability of EES to recruit arm and hand muscles and produce distinct kinematic movements. The implant will be removed after less than 30 days. Results of this study will provide the foundation for future studies evaluating the efficacy of a minimally-invasive neuro-technology that can be used in clinical neurorehabilitation programs to restore upper limb motor function in people with subcortical strokes, thereby increasing independence and quality of life.
This pilot study will determine the feasibility of implementing a combinatory rehabilitation strategy involving testosterone replacement therapy (TRT) with locomotor training (LT; walking on a treadmill with assistance and overground walking) in men with testosterone deficiency and walking dysfunction after incomplete or complete spinal cord injury. The investigators hypothesize that LT+TRT treatment will improve muscle size and bone mineral density in men with low T and ambulatory dysfunction after incomplete or complete SCI, along with muscle fundtion and walking recovery in men with T low and ambulatory dysfunction ater incomplete SCI.
The purpose of this study is to use Transcranial Magnetic Stimulation (TMS) while subjects are making reaching movements in a robotic arm device in order to discover how different brain areas control movement before and after stroke and when these brain areas are most sensitive to TMS.
This study will validate a predictive model that uses demographics, functional status, neurophysiology, neuroanatomy, and other potential biomarkers to predict the likelihood of a clinically significant change in impairment at the end of a robot assisted therapy intervention.The study will include magnetic resonance imaging (MRI), transcranial magnetic stimulation (TMS), and an arm exercise program consisting of robot-assisted exercise combined with functional arm exercise called transition to task training (TTT).
Incomplete spinal cord injuries (SCI) are the most frequent neurologic category, comprising 66.7% of all SCI cases. People with incomplete SCI may retain some ability to move the legs and therefore the capacity to regain walking. Studies that show functional improvement in locomotion via electrical stimulation of lumbosacral circuits suggest that the underlying mechanisms are neuromodulation of lumbosacral spinal cord automaticity and sensory feedback. Both epidural and transcutaneous spinal stimulation are demonstrating exciting potential to improve limb function for people after chronic SCI. Available treatment options for SCI are less than satisfactory and most often do not achieve full restoration of function. Recent experimental results suggest an exciting new approach of using electrical spinal stimulation to enable users to regain control of their weak or paralyzed muscles. Using surgically-implanted electrodes, epidural stimulation results in remarkable improvements of lower extremity function as well as autonomic functions such as bladder function and sexual function. In addition to epidural stimulation, over only the last few years a novel strategy of skin surface electrical spinal stimulation has also demonstrated exciting potential for improving walking function. Using a high-frequency stimulation pulse, current can pass through the skin without discomfort and activate the spinal cord; this results in patterned stepping movements for people without SCI and improved lower extremity function following SCI. This study will directly compare skin-surface transcutaneous stimulation with implanted epidural stimulation for improving lower extremity function.
Compare the safety and effectiveness of pRESET to Solitaire in the treatment of stroke related to large vessel occlusion