90 Clinical Trials for Various Conditions
This study will explore how the brain works during memory testing in an effort to understand why some patients with schizophrenia have memory difficulties. Patients with schizophrenia and their unaffected family members are eligible for this study. Studying family members may help identify the genes related to the memory deficit in schizophrenia. Normal volunteers will also be studied. Normal volunteers, patients with schizophrenia, and their family members interested in participating in this study will be screened with a complete medical examination and psychiatric assessment, and performance of simple tasks. Study participants will be shown numbers on a screen and asked to recall them after a brief period. This will be done during electroencephalographic (EEG) recording, in which electrodes attached to the scalp measure the brain s electrical activity. The same test will be repeated while the patient has magnetic resonance imaging of the brain. The combined MRI and EEG testing will permit better localization of the brain s electrical activity. ...
Background: Chronic heavy drinking can cause alcohol use disorder (AUD). AUD changes how the brain works. People with AUD may drink compulsively or feel like they cannot control their alcohol use. Acamprosate is an FDA-approved drug that reduces anxiety and craving in some, but not all, people with AUD. Objective: To learn more about how acamprosate affects brain function in people with AUD. Eligibility: People aged 21 to 65 years with moderate to severe AUD. Design: Participants will stay in the clinic for 21 days after a detoxification period of approximately 7 days. Acamprosate is a capsule taken by mouth. Half of participants will take this drug 3 times a day with meals. The other half will take a placebo. The placebo looks like the study drug but does not contain any medicine. Participants will not know which capsules they are taking. Participants will have a procedure called electroencephalography (EEG): A gel will be applied to certain locations on their scalp, and a snug cap will be placed on their head. The cap has sensors with wires. The sensors detect electrical activity in the brain. Participants will lie still and perform 2 tasks: they will look at different shapes and press a button when they see a specific one; and they will listen to tones and press dedicated buttons when they hear the corresponding tones. Participants will have 2 EEGs: 1 on day 2 and 1 on day 23 of their study participation. They may opt to have up to 4 more EEG studies (one on day 13 and one on each of the three follow-up visits) and 2 sleep studies, in which they would have sensors attached to their scalp while they sleep. Participants may have up to three follow-up visits for 6 months.
Patients with Parkinson's Disease will be studied before, during, and after a deep brain stimulation implantation procedure to see if the stimulation location and the size of the electrical field produced by subthalamic nucleus (STN) DBS determine the degree to which DBS engages circuits that involve prefrontal cortex executive functions, and therefore have a direct impact on the patient's ability to inhibit actions.
The purpose of the study is to test the effects of brief, low-intensity transcranial focused ultrasound (TUS) on electrophysiological, behavioral, and cognitive markers related to anxiety disorders.
Transcranial magnetic stimulation (TMS) is an effective treatment for depression, but clinical outcome is suboptimal, partially because investigators are missing biologically-grounded brain markers which show that TMS is modifying activity at the intended target in the brain. The goal of this proposal is to characterize the key markers of the brain's response to repeated doses of TMS with high resolution using invasive brain recordings in humans, and relate these brain markers to noninvasive recordings. These markers will improve the understanding of TMS and can be used to optimize and enhance clinical efficacy for depression and other psychiatric disorders.
The purpose of this study is to understand how ketamine brings about dissociative symptoms.
This study will enroll patients with epilepsy who are being evaluated for epilepsy surgery and have electrodes implanted in the brain and/or have electrodes on the scalp. Additionally, this study will recruit normal and online controls (participants who do not have epilepsy). Participants will be asked to participate in 1 to 2 (30-90 minutes) daily sessions designed to test aspects of human cognition such as memory, speech, language, feeling, movement, attention, sound perception, and emotions. Generally, this will involve working on a computer, looking at pictures or watching videos, and answering questions. Additionally, participants may be asked to be hooked up to additional equipment such as eye tracker, electrical stimulator, heart rate monitor, sweat monitor or other non-invasive equipment. The overall aim of this study is to use human intracranial electrophysiology (the recording of the electrical activity of the human brain) to study localization and function of the human brain.
This research study will use computerized tasks, electroencephalography (EEG), and magnetic resonance imaging (MRI) to look at how the drug psilocybin, a naturally occurring compound contained in hundreds of species of psychoactive mushrooms, changes thoughts and brain activity.
The study intervention is to perform standard somatosensory evoked responses limited to the face during rhizotomy procedures of the gasserian ganglion (trigeminal ganglion) for the treatment of trigeminal neuralgia. The evoked responses will be measured at two locations before and after the clinical rhizotomy including: the standard contralateral scalp (EEG) and at the gasserian ganglion through an FDA-approved recording electrode.
Depression is a leading cause of morbidity and mortality, conferring substantial healthcare and societal costs. By studying methods to non-invasively target neural circuitry involved in reward responsivity, information generated by this project will improve understanding of the circuit alterations that underlie motivation and pleasure deficits in depression, and could also lead to the development of biologically-based markers of neurostimulation-based treatment response.
The primary purpose of this study is to determine functional target engagement of SAGE-904 using electrophysiological paradigms before and after ketamine administration.
The purpose of this study is to evaluate the use of virtual reality (VR) technology as adjunct to routine anesthesia care for patients undergoing electrophysiology (EP) procedures.
Subjects will be consented to wear the AleriTM sensor prior to, during, and after an Electrophysiology Procedure. During this time, the system will measure the following parameters from subjects: HR, temperature, saline volume/rate, urine production volume, USG, BPO. Data will be retrospectively analyzed to determine if the system effectively operates under these conditions, and can effectively monitor hydration levels of subjects compared to currently available methods.
This study is a Phase 1, randomized, double-blind, placebo-controlled study of multiple doses of SAGE-718 using ketamine challenge to evaluate the electrophysiology, safety, tolerability, and pharmacokinetics in healthy subjects.
This study is a phase 1, double-blind, placebo-controlled crossover study of single, oral dose of SAGE-718 using a ketamine challenge, to evaluate the electrophysiology, safety, tolerability, and pharmacokinetics in healthy subjects
This study is a phase 1, double-blind, placebo-controlled crossover study of SAGE-718 using a ketamine challenge, to evaluate the safety, tolerability, pharmacokinetics, and pharmacodynamic response using magnetic resonance imaging in healthy subjects
The investigators are purposing a study to evaluate the use of acetaminophen given prior to an electrophysiology procedure and post procedural pain control.
Subjects will be consented to wear the CoVa-2 monitoring system prior to (baseline), during, and after an Electrophysiology Procedure (EP). During this time, the system will measure the following parameters from subjects: heart rate (HR), Heart Rate Variability (HRV), respiration rate (RR), and Cardiac Output (CO). Data will be retrospectively analyzed to determine if the system effectively operates under these conditions, and can effectively monitor subjects and allow them to be discharged early from the hospital. Subjects will not be measured while transferred in and out of the operating room. Approximate sample size is 20 subjects.
This study will test the ability of computer algorithms to predict successful ablation therapy for atrial arrhythmias.
Sudden cardiac death (SCD) remains a major cause of mortality within developed nations despite aggressive efforts to reduce its societal burden. Despite extensive clinical and genetic investigations, a subgroup of cardiac arrests remain unexplained, highlighting the potential contribution of additional cardiac conditions that may not be identified with contemporary diagnostic algorithms. The EPS ARREST study aims to evaluate the role of invasive electrophysiology study within this patient population.
Fetal research and clinical practice has been hampered by a lack of suitable investigational techniques. Currently, ultrasound is the only widely used method of studying fetal anatomy and physiology, but it has significant limitations for assessment of cardiac rhythm. The proposed study will allow the investigators to evaluate fetal magnetocardiography (fMCG) as a new tool for the study of normal and abnormal fetal heart rate and rhythm.
The goal of this study is to assess the utility of virtual reality technology to aid in the mental health of patients with cardiac disease, specifically looking at decreasing anxiety and perceptions of pain from stressful procedures in the pediatric electrophysiology laboratory.
This study examined data elements of hemodynamic, electrophysiologic and electrolyte trends comparing 2 different types of catheters used during a procedure to treat medication resistant atrial fibrillation-radiofrequency catheter ablation. A high flow catheter delivers a high volume of saline during the procedure. The low flow catheter delivers a low volume of saline during the procedure. The patient will be consented and randomized to one of the 2 groups using a computer generated randomization chart. Those that are put in the low flow catheter group will be considered the experimental group. All data will be collected before and after the procedure and each patient will act as their own control within each group.
In this pilot study the investigators will perform a double-blind randomized trial of intranasal oxytocin on measures of cardiac refractoriness, among individuals who are undergoing clinically indicated catheter ablation procedures for paroxysmal atrial fibrillation. The investigators seek to enroll 20 patients for this study, for the purpose of estimating effect sizes for a larger future study.
This study will evaluate the use of a robotic device that is remotely controlled to maneuver a circular mapping catheter in the left atrium during Atrial Fibrillation (AF) ablation procedures.
Isoproterenol is used as a cardiac stimulant in electrophysiology studies (EP). Preliminary data suggests that administration of isoproterenol increases the Bispectral index (BIS). BIS is used to monitor neuronal signals under anesthesia. The BIS level is suggested to correspond to the level of consciousness. We hypothesize that isoproterenol increases BIS values because it increases the patient's level of consciousness through its central nervous system (CNS) stimulatory effects. In this study, we will administer increasing doses of isoproterenol to EPS patients. We will measure the BIS levels continuously before and after isoproterenol administration. In addition, we will test the level of awareness of patients by their response to a modified isolated forearm technique.
The purpose of this clinical study is to collect safety and performance data to support a demonstration of substantial equivalence of the Catheter Robotics Remote Catheter System to predicate devices when used to perform EP mapping of the right heart (atrium and ventricle).
BACKGROUND Physician-guided moderate sedation, administered by a Registered Nurse has been the standard of practice for patients undergoing a wide range of electrophysiology procedures during the past decade. Currently a subjective sedation assessment tool is the standard of practice within the Electrophysiology Lab (EP Lab). Bispectral Index monitoring (BIS) is an objective measure of the depth of sedation presently employed at Baystate Medical Center in the Intensive Care Unit and within the department of anesthesia. AIM The aim of this research study is to assess the utility of BIS monitoring in measuring the depth of sedation in patients undergoing defibrillation threshold testing (DFT). Our primary endpoint is: A change in OAAS scores of one point at the 30 minute data collection time period. Our secondary endpoints are: Lack of explicit recall of DFT testing and measurement of perioperative level of comfort. STUDY DESIGN AND SCOPE The population to be studied is those patients receiving a primary ICD implant or an ICD battery change with defibrillation threshold testing (DFT). All patients who have consented for ICD placement and DFT testing with moderate sedation will be invited to participate in this research study. Patients who are not candidates for DFT testing, as is determined by the EP physician, will be excluded from the study. Demographic data including: age, gender, BMI, current medications and history of sleep apnea will be collected. Data detailing the amount of drug administered during the procedure and any use of reversal agents, will be retrieved from the medical record. The study will be conducted within the Electrophysiology lab at Baystate Medical Center. An enrollment of 60 subjects is expected to be completed within 6 months. 30 patients will originate from the outpatient population and 30 from the inpatient. Follow up assessments using the OAAS scale will be completed at 30 min, 1 hour and 4 hours post procedure. Also, perioperative comfort and recall of DFT testing will be assessed at the 4 hour mark.
The overarching goal of this multi-disciplinary research program is to develop and optimize new cross-species translational assessments of reward and cognition that will not only be assessed in parallel in humans and rats, but also produce neurophysiological and behavioral metrics that can be objectively compared across species. The research will build on prior studies by further developing and optimizing (in Phase 1), then validating via pharmacological challenge (in Phase 2), the following assays in both humans and rats: 1. advanced neurophysiological and computational modeling techniques to record and analyze EEG activity within and across species; and 2. behavioral assessments of reward learning, cognitive control, and cognitive flexibility will be analyzed within and across species. The second phase of the study will test the translational validity of these assays, by assessing the impact of a targeted drug on task performance and EEG activity in both species.
This prospective, multicenter, post-market clinical study was designed to evaluate the outcomes of lead extraction of cardiovascular implantable electronic devices (CIED) using Cook catheter and lead extraction devices for any indication it is used in the commercial setting within the United States and Europe. The purpose of this clinical study is to collect data on the performance of the Cook lead extraction devices for the purpose of supporting publications and presentations