251 Clinical Trials for Various Conditions
The objective of this research study is to understand how Deep Brain Stimulation (DBS) targeting the subthalamic nucleus (STN) affects cognitive networks in the brain, potentially leading to cognitive decline in patients with Parkinson's Disease (PD). A total of 55 participants with PD who have undergone DBS surgery will be recruited from MUSC's Clinical DBS Program. Participants will attend two post-DBS visits: a 3-hour visit for consent, demographic, and cognitive assessments, and a 3-hour DBS-MRI visit to evaluate brain network connectivity with stimulation ON and OFF. These findings will help improve patient selection for surgery and optimize the selection of stimulation targets that minimize undesirable cognitive side effects.
DBS Matchmaker (https://www.dbsmatchmaker.com) is a platform designed to connect clinicians worldwide who are treating rare movement disorders with deep brain stimulation (DBS). It facilitates global collaboration and knowledge sharing to enhance patient care by improving patient selection, counseling, treatment, and outcomes for individuals with movement disorders.
Inability to align and refocus the eyes on the objects at different depths, i.e., vergence impairment and strabismus, frequently affects the quality of life in patients with Parkinson's disease. The investigators study aims to understand the location-specific effects of subthalamic region deep brain stimulation on vergence and strabismus by integrating the patient-specific deep brain stimulation models and high-resolution eye-tracking measures. The knowledge gained will allow the investigators to find the most beneficial stimulation location and parameters for improving binocular coordination, strabismus, and vergence while preserving the ability to treat motor symptoms in Parkinson's disease.
The goal of this clinical trial is to learn if adaptive deep brain stimulation (DBS) can decrease or prevent freezing of gait in participants with Parkinson's disease.
The goal of this clinical trial is to learn if deep brain stimulation (DBS) works to treat refractory obsessive-compulsive disorder (OCD). The main questions it aims to answer are: * Assess the effects of the anteromedial sub-thalamic nucleus (amSTN)stimulation on obsessive/compulsive symptoms. * Map the amSTN using neuronal responses \[single unit and local field potentials (LFP) recordings\] at rest and under high frequency stimulation during surgery. * Record chronic brain activity with the implanted pulse generator and look for neuronal signatures correlated with symptom severity. Researchers will compare active deep brain stimulation to a placebo (sham stimulation) to see if DBS works to treat refractory OCD. Participants will: * Undergo surgery for the implantation of a deep brain stimulation device * Follow-up visits every three weeks with study staff * 6 month follow-up for the next 2-3 years after first year of study participation is complete
This study is only enrolling at Baylor College of Medicine. The other research locations listed serve to support data analysis only. This research study is to investigate the use of technology called Deep Brain Stimulation (DBS) to potentially improve Treatment-Resistant Bipolar Depression (TRBD) symptoms in patients with severe cases. DBS involves the surgical implantation of leads and electrodes into specific areas of the brain, which are thought to influence the disease. A pack implanted in the chest, called the neurotransmitter, keeps the electrical current coursing to the brain through a wire that connects the neurotransmitter and electrodes. It is believed DBS may restore balance to dysfunctional brain circuitry implicated in TRBD. The goal of this study is to enhance current approaches to DBS targeting in the brain and to use a novel approach to find a better and more reliable system for TRBD treatment. Its important for participants to understand that this is an investigational study where there could be a lack of effectiveness in improving TRBD symptoms. There may be no directly benefit from taking part in this study. This study is expected to last 20 months and involves 3 main steps. 1. Medical, psychiatric, and cognitive evaluations. 2. Implantation of a brain stimulation system. 3. Follow up after implantation of device, including programming, recording, and psychiatric testing. There are risks and benefits to this study which need to be considered when deciding to participate or not. Some of the risks are from surgery, the DBS device and programming, the tests involved, and potential loss of confidentiality, as well as other unknown risks. Some of the more serious risks involved in this study and the percentage that they occur: 1. Bleeding inside the Brain (1 to 2 percent). 2. Infection from the procedures (3 percent) 3. Seizure caused from the procedures (1.2 percent) However, the benefit of this study is that it may help relieve or decrease TRBD symptoms. This form of treatment has shown to reduce symptom severity in other cases. This could potentially improve quality of life and activities in daily routines. There is also a potential benefit to society in that the data the investigators will obtain from this study may help increase the understanding of the mechanisms underlying TRBD symptoms, as well as enhanced Deep Brain Stimulation techniques. Study participation is expected to last 20 months from the time the DBS device is activated and should include approximately 23 visits. These visits also include 8 separate, 24 hour stays at the Menninger NeuroBehvaioral Monitoring Unit (NBU). These 24-hour sessions will occur at multiple points throughout the study (1 week prior to surgery, the week preceding device activation, the week following activation, then after 2 weeks, 4 weeks, 6 months, 9 months, and 12 months). Participants will need to stay locally for the week of the NBU stay (typically Monday through Friday). Study visits will include clinician administered assessments and questionnaires, subject reported assessments, neuropsychological testing, and mobile behavioral assessments which will occur around 23 visits over the course of 20 months.
There is limited data on outcomes for children who have undergone deep brain stimulation (DBS) for movement disorders, and individual centers performing this surgery often lack sufficient cases to power research studies adequately. This study aims to develop a multicenter pediatric DBS registry that allows multiple sites to share clinical pediatric DBS data. The primary goals are to enable large-scale, well-powered analyses of the safety and efficacy of DBS in the pediatric population and to further explore and refine DBS as a therapeutic option for children with dystonia and other hyperkinetic movement disorders. Given the current scarcity of evidence available to clinicians, this centralized multicenter repository of clinical data is critical for addressing key research questions and improving clinical practice for pediatric DBS.
The goal of this clinical trial is to learn if a Decision Aid can help patients with Parkinson's disease make a decision about undergoing Deep Brain Stimulation surgery. The main questions it aims to answer are: * Is the Decision Aid acceptable to patients with Parkinson's disease considering Deep Brain Stimulation surgery? * Does the decision aid improve decision quality (informed, value-based decision) and uncertainty about the decision? Researchers will compare immediate use of the decision aid during the evaluation process for deep brain stimulation surgery to delayed introduction of the decision aid. Participants will: * Receive the decision aid at the beginning of the evaluation process or towards the end * Complete surveys at 5 visits (remote or in-person) over approximately 6 months
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.
The purpose of this study is to collect electrophysiological data related to functional brain network changes in patients undergoing deep brain stimulation for the treatment of essential tremor. Participants will either 1) have electroencephalography (EEG) scalp electrodes placed, or 2) remain seated with their head inside of a magnetoencephalography (MEG) recording system, as resting-state and task-related data are acquired. Spontaneous electrophysiological activity will be recorded in both the eyes open and eyes closed conditions with the participant seated comfortably. These recordings will be repeated in the DBS OFF and DBS ON states, with the ON state involving specific settings identified as optimal, sub-optimal, or ineffective at achieving tremor control. They will also be repeated following the optional administration non-DBS tremor mitigation techniques, which may include one or more of the following: 1) cooling the limb, 2) oral administration of alprazolam, 3) oral consumption of ethanol (alcohol), or 4) peripheral nerve stimulation.
This study is a non-randomized, open label, phase 1 clinical trial to evaluate the fesibility and safety of intrathalamic delivery of MSCs during standard of care DBS surgery for epilepsy. Subjects will be screened at our outpatient clinic and interested qualified subjects will be consented and offered participation in this trial. Once consent has been obtained, patients will undergo a standard preoperative evaluation which includes baseline laboratory values and a high-definition MRI. Patients will then undergo a stereotactic procedure for bilateral thalamic implantation of DBS leads through the ClearPoint® system. After the thalamic target for DBS is identified, cells will be infused directly into the anterior nucleus of the thalamus previous to lead implantation. Patients will be followed in the outpatient setting for up to a year after therapy application. Surgical, clinical, and radiographic data will be obtained during these visits
There are three hypotheses proposed for this study: 1) Participants will report no unanticipated serious adverse events during the eight months of treatment. 2) Investigators will successfully model psychotic versus non-psychotic brain states using support vector machine (SVM) classifiers. 3) Participants specific brain stimulation parameters can induce a change in the brain state consistent with non-psychotic states as measured by classifier output. Hypotheses 1, 2, and 3 address safety and tolerability, efficacy, and the putative mechanism of successful treatment. The overall objective is to use next generation Deep Brain Stimulation (DBS) combined with antecedent stereo electroencephalogram (SEEG) mapping to establish a new therapy for treatment-refractory schizophrenia given the limitations of current treatment modalities. The primary objective is to demonstrate safety of acute and chronic network guided stimulation for treatment-refractory schizophrenia. Exploratory Objectives: 1. Use intracranial mapping (SEEG) combined with pharmacological manipulation of psychotic states to create a protocol for participant specific deep brain stimulation to treat treatment-refractory schizophrenia. 2. Develop closed loop stimulation protocols to modify brain states during psychotic brain activity induced by low-dose ketamine administration. 3. Investigate the use of mnemonic similarity to characterize brain networks related to symptoms of treatment-refractory schizophrenia. 4. Treatment-related objectives: Record a reduction in psychotic symptoms, as well as an improvement in psychosocial function and cognition.
The objective of this project is to evaluate next generation visualization tools and surgical targeting models for clinical deep brain stimulation (DBS). This study will evaluate the performance of HoloDBS software in comparison to the current standard (SOC) clinical planning tools to prepare for DBS surgery. The investigators hypothesize that HoloDBS will provide more detailed and anatomically useful information to the neurosurgeon and neurologist than the current clinical standard. The study team reviews electronic medical records (EMR) from patients who are undergoing DBS surgery. There are no study visits involved in this study as only data from standard clinical care will be used. All study activities are executed by the study team and there are no interventions.
The purpose of this study is to test the safety of placing Deep Brain Stimulators (DBS) in a part of the brain called the cerebellum and using electrical stimulation of that part of the brain to treat movement symptoms related to cerebral palsy. Ten children and young adults with dyskinetic cerebral palsy will be implanted with a Medtronic Percept Primary Cell Neurostimulator. We will pilot videotaped automated movement recognition techniques and formal gait analysis, as well as collect and characterize each subject's physiological and neuroimaging markers that may predict hyperkinetic pathological states and their response to therapeutic DBS.
Over the last 30 years, deep brain stimulation (DBS) has allowed tens of thousands of patients to receive relief of neurological symptoms that were refractory to standard medical treatment. Furthermore, by providing a rare window into the electrophysiological activity of the awake, human brain, DBS has facilitated invaluable advances in scientific understanding. These advances have then, in turn, allowed for further therapies to be developed for an ever growing population of patients that benefit from DBS therapy. This study hopes to add to this growing body of knowledge by implanting leads within, and recording from, the sensory thalamus and periaqueductal gray (PAG) in patients with chronic pain. Specifically, we hope to establish the long-term safety of DBS leads within the periaqueductal gray and sensory thalamus for the treatment of chronic pain. Furthermore, by recording from the electrodes of DBS patients implanted for treatment of their chronic pain, we hope to understand how the pain network responds to sensory stimuli and how DBS changes this response.
The goal of this clinical trial is to evaluate the safety and tolerability of a novel deep brain stimulation (DBS) of the Subthalamic Nucleus (STN) and Nucleus Basalis of Meynert (NBM) to treat cognitive and cognitive-motor symptoms in individuals with Parkinson's disease. The main question it aims to answer is: Is a combined deep brain stimulation approach targeting the STN and NBM with four DBS leads safe and tolerable for cognitive and cognitive-motor symptoms in individuals with Parkinson's disease with Mild Cognitive Impairment. Ten participants are anticipated to be enrolled. Participants will undergo a modification of the traditional STN DBS approach for motor symptoms of PD. In addition to the two leads placed within the STN, two additional leads will be placed with the NBM for treatment of cognitive and cognitive-motor symptoms. Novel stimulation patterns will be used within the NBM to target cognitive and cognitive-motor symptoms using an investigational software. Participants will be followed over two years while receiving this therapy with assessments at baseline and every six months. Assessments will include a combination of neuropsychological evaluations, cognitive assessments, motor tasks (including gait/walking), and questionnaires to evaluate the treatment. Two different surgical trajectories will be used, with half the cohort randomized to each group. This will allow comparison of the impact of surgical trajectory on the intervention.
The study aims to investigate cognitive impairment associated with Deep Brain Stimulation (DBS) in Parkinson's Disease patients, with a focus on identifying neurophysiology biomarkers of DBS associated cognitive changes. Using neurophysiology data recorded during DBS surgeries and post-implantation, the research intends to identify biomarkers in order to optimize electrode placement, enhance programming, and ultimately minimize DBS-related cognitive side effects.
Obsessive-compulsive disorder effects approximately 2-3% of the population. The only established first-line treatments for OCD are cognitive-behavioral therapy (CBT) with exposure/response prevention and serotonin reuptake inhibitor medications (SRIs). Approximately 30-40% of patients fail to respond to either modality and few patients experience complete symptom resolution. Up to 25% of patients have difficulty tolerating CBT, and the risk of relapse after therapies remains significant. Symptoms of OCD include unwanted, distressing thoughts and rituals such as excessive washing of hands or other body parts, rechecking things such as locks or switches because of obsessional doubt, and avoidance of anxiety-provoking situations. In some cases, compulsions can consume several hours per day and in the most extreme cases can involve most of the patient's waking hours (e.g. washing hands hundreds of times per day, 18-hour showers). Medical complications may result from repeated washing or other repetitive behaviors. Significant social and occupational impairment can result from this disorder and some patients are housebound or even bed-ridden. Effective evidence-based treatments include behavior therapy and certain medications. Despite these therapies, a significant number of patients are treatment resistant and suffer persistent, debilitating symptoms. In severe cases, neurosurgical intervention is sometimes performed to alleviate symptoms. A common surgical option is deep brain stimulation (DBS), a procedure that involves placing two electrodes in a specific region in the brain and connecting them to a pacemaker-like device implanted under the skin in the upper chest. The clinician adjusts the stimulation parameters on the device to find the settings that best relieve symptoms. One of the challenges of treating a psychiatric disorder is the absence of reliable and valid biomarkers for diagnosing and objectively monitoring treatment outcomes. There is also problem of heterogeneity, which introduces additional barriers to predicting who will respond best to a particular treatment. A better understanding of the dysfunction in key brain circuits underlying OCD symptomatology will allow us to improve outcomes with DBS. The pathophysiology of OCD is associated with dysfunction in prefrontal cortico-basal ganglia circuits. The electrodes of the DBS system are placed at a critical hub within this circuit. This target is called the ventral capsule/ventral striatum (VC/VS). DBS targeting the VC/VS is approved for the treatment of severe OCD under an FDA Humanitarian Device Exemption (HDE). In this project, the investigators will recruit patients treated with DBS for OCD under the standard clinical (HDE) pathway. The FDA/HDE-approved device for these procedures is the Medtronic Percept DBS system. The Percept implanted pulse generator (IPG; pacemaker-like device mentioned above that delivers stimulation) has the ability to not only stimulate, but also record electrical activity measured from the brain electrodes, store the recordings in memory, and wirelessly transmit them to the clinician. The investigators will ask consenting patients to perform and transmit these recordings to the investigators for analysis. The investigators hope that these recordings will help them understand the relationship between electrical network activity in the brain and patient symptoms. A closer understanding of this relationship may eventually enable the investigators to make better informed programming adjustments and therefore achieve better symptom control. The main objective is to obtain recordings from the VC/VS, a key network hub in OCD, in patients already implanted with a DBS system for severe OCD. The Investigators will use these recordings to better understand the relationship between brain activity and OCD symptoms, with the hope that this understanding will lead to more effective utilization of DBS therapy to treat severe OCD.
The purpose of this clinical study is to investigate the safety, tolerability, and feasibility of Deep Brain Stimulation (DBS) of the nucleus accumbens (NAc) and ventral internal capsule (VC) for participants with treatment refractory opioid use disorder (OUD) who have cognitive, behavioral, and functional disability.
Deep brain stimulation (DBS) is a surgical procedure for the treatment of Essential Tremor (ET). A novel approach to current DBS approaches is called coordinated reset DBS (CR-DBS) which uses different patterns of stimulation at lower currents and can address the limitations of traditional DBS that uses continuous high amplitude, high frequency stimulation. This study will evaluate the feasibility, safety and short-term efficacy of thalamic CR-DBS in upper extremity ET. The goal of this study is to evaluate the safety and short-term efficacy of thalamic CR- DBS in ET, including the acute (during CR-DBS) and carryover (following DBS cessation) effects, and compare these to those induced by clinically optimized T-DBS. To achieve our goal, a low-risk, two-phase clinical study will be conducted in patients with upper extremity (UE) ET. The first aim is to identify the spatial location and peak frequency of tremor related oscillatory activities in VIM (Phase I). The second aim is to compare the acute effects of thalamic CR-DBS to clinically optimized T-DBS (Phase II).
This project will investigate the potential of Deep Brain Stimulation to improve cognitive abilities and counteract the effects of Alzheimer's disease. Deep Brain Stimulation electrodes targeting the Nucleus Basalis of Meynert (NB) will be implanted bilaterally in a cohort of patients. NB is the sole source of acetylcholine to the neocortex. Such stimulation may not only treat the cognitive symptoms but may have disease-modifying effects. Drawing from animal experiments in non-human primates that showed success of this approach, intermittent stimulation will be delivered at 60 pulses per second for 20 seconds of each minute for one hour per day. The study team will recruit patients, shortly after first being diagnosed with Alzheimer's disease. The study design will test the safety and efficacy of stimulation, potential benefits in cognitive function assessed with a battery of neurocognitive tests, cholinergic neurotransmission evaluated with Positron Emission Tomography, and ability to reverse Alzheimer's biomarkers, including beta amyloid and tau in the cerebrospinal fluid. Successful completion of this project will lead to a potential new intervention for the cognitive impairments of Alzheimer's disease.
This research study aims to identify MRI-based brain biomarkers that predict an individual's response to Deep Brain Stimulation (DBS). In particular, this study will focus on changes in cognition associated with DBS. A total of 55 participants with Parkinson's Disease planning to undergo DBS will be recruited from MUSCs Clinical DBS Program. Participants will undergo four visits, including a 1-hour screening visit, a 1.5-hour pre-DBS MRI scanning visit, and a 3.5-hour post-DBS cognitive assessment visit. In addition control participants without Parkinson's Disease will be recruited to undergo MRI scanning and cognitive assessments.
This is a study to evaluate Deep brain stimulation (DBS) burst-type electrical stimulation programming verses standard DBS programming. Burst-type DBS is defined as a novel stimulation protocol in which intermittent bursts of traditional high-frequency rectangular wave stimulation are delivered. Burst type DBS may improve the efficacy and durability of DBS pulse generator.
This study will help us better understand how the brain works in people with Parkinson's disease (PD). PD is a brain disease that gets worse over time, and affects over 10 million people world-wide. A common treatment for PD is Deep Brain Stimulation (DBS). To improve DBS therapy for PD, we need a deeper understanding of how the different parts of the brain work together in PD, and how this relates to movement and thinking problems that people with PD experience. We may be able to use the results of this study to improve DBS treatments in the future.
The purpose of this study is to map the acute, short-term cortical evoked responses to thalamic electrical stimulation in persons with intractable epilepsy
We will evaluate the effects of deep brain stimulation (DBS) of bilateral nucleus accumbens (NAc) added to background treatment for treatment refractory Methamphetamine Use Disorder (MUD). This is a small randomized cross-over study to demonstrate feasibility and safety, test treatment outcomes (use, craving), and identify novel biological targets (NAc local field potentials (LFP) and functional MRI).
This protocol will characterize the effects of deep brain stimulation (DBS) location (both adverse and beneficial) on motor signs in people with Parkinson's disease (PD). This information can be used to inform future DBS protocols to tailor stimulation to the specific needs of a patient. If targeted dorsal GP stimulation is shown to significantly improve motor features that are typically resistant to dopamine replacement therapy, these experiments will likely have major impact on clinical practice by providing a potential strategy to these medically intractable symptoms.
The purpose of this clinical study is to investigate the safety, tolerability, and feasibility of Deep Brain Stimulation (DBS) of the limbic pallidum in participants with severe alcohol use disorder (AUD) who have advanced but compensated liver fibrosis.
Deep Brain Stimulation (DBS) is a neurosurgical procedure used to treat tremors, and dystonia. This study will enroll people who have a form of focal dystonia that affects their vocal cords called Adductor Laryngeal dystonia (ADLD). Participants will undergo Deep Brain Stimulation surgery to treat laryngeal dystonia as part of their clinical care. Before surgery, as part of the study they will have specialized testing to study the movement of the vocal cords, as well as functional magnetic resonance imaging (fMRI). While in the operating room, researchers will examine brain waves to better understand how faulty brain firing patterns lead to dystonia. After surgery, and activation of the deep brain stimulator, participants will repeat speech testing and vocal cord imaging as well as magnetic resonance imaging (MRI).
The purpose of this study is to see if mental functions take place during different levels of anesthesia. The researchers expect to gain a deeper understanding of mental function during different levels of anesthesia, and to evaluate if the use of ultrasonic brain stimulation accelerates return to consciousness.