576 Clinical Trials for Various Conditions
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
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 the project is to assess the efficacy of parietal transcranial magnetic stimulation in misophonia. N=60 participants will undergo two transcranial magnetic stimulation sessions: one inhibitory and another excitatory. During both sessions, the parietal region will be stimulated. Participants will perform computerized tasks immediately before and after the stimulation, while EEG, heart rate, and skin temperature will be recorded. These recordings will be used to assess if TMS can be used to improve tolerance to misophonia triggers.
This is a randomized, sham controlled study of the Electroencephalogram (EEG) based Transcranial Magnetic Stimulation (eTMS) treatment for Post-Traumatic Stress Disorder (PTSD). The recruitment goal is 110 participants who are United States Military veterans or first responders (e.g., firefighters, police, paramedics, etc.). The Study includes an EEG recording in order to determine the optimal treatment parameters for the eTMS system, followed by 15 in-office visits that take place over 21-28 total days. Two eTMS treatment sessions are administered during each office visit.
The purpose of this study is to test if Variable Pulse TMS (Transcranial Magnetic Stimulation) can result in objective improvements in patients with Post COVID Syndrome (PCS).
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
The purpose of this study is to learn more about how accelerated theta burst stimulation affects methamphetamine craving and brain activity. Theta burst stimulation is a unique transcranial magnetic stimulation (TMS) paradigm that is efficient and potent.
The study will recruit 50 adults with stimulant use disorder currently in treatment and abstinent for at least 2 weeks. The study will also recruit up to 10 healthy controls (adults without StUD) for initial study configuration. The study will consist of five steps that are expected to be completed over two lab visits. Step 1: The 3T MRI scan will provide accurate prefrontal cortex anatomy for using neuronavigation for TMS. In addition, the study will use an analysis of resting fMRI connectivity to determine the location in the left DLPFC that has the maximum connectivity with the incentive-salience network. Step 2: The study will use the data collected at the MRI to select the individual TMS location. EEG will be used to collect TEPs in response to single pulse TMS at the left DLPFC. Participants will then be randomized to one of three conditions: A) TMS unsynchronized with EEG, B) TMS synchronized with EEG theta frequency trough, and C) TMS synchronized with EEG theta frequency peak. The stimulation will be applied with an intensity of up to 120% of the resting motor threshold (which is a safe and common practice; Rossi et al., 2021). The intensity can be decreased for individual participants. Step 3: Following randomization, the study will administer a pre-iTBS assessment. Step 4: The study will compare brain and behavioral responses before and after the iTBS session with TMS and EEG synchronization as assigned by their randomized group. Step 5: The study will administer a post-iTBS assessment.
Alcohol use disorder (AUD) is a complex chronic brain disease characterized by compulsive alcohol use, loss of control over drinking, and negative emotional states. Extensive research has identified the general neural circuitry underlying AUD. There is an exciting opportunity to intervene in AUD using neuromodulation. Transcranial magnetic stimulation (TMS) offers a non-invasive method to modulate brain activity, making it a promising tool for investigating, modulating, and potentially treating AUD. However, the precise effects of TMS on neural circuits involved in AUD and the mechanisms underlying these effects must first be understood. Magnetoencephalography (MEG) is a neuroimaging method that provides direct measurement of brain activity within neural circuits with high temporal resolution. Critically, MEG can measure brain activity in a wide range of frequencies that are consistent with those targeted by TMS. The goal of this proposal is therefore to collect preliminary and feasibility data to support a future NIH grant application that would use MEG to investigate TMS effects in individuals with AUD (iAUD).
In this pilot study, investigators propose to design and create a portable TMS unit, in a van, and then test out delivering TMS in three different locations in South Carolina, all affiliated with MUSC and within 2-hours driving from Charleston, SC. This study would test out this new delivery mode, and provide valuable feasibility, safety, and efficacy lessons for later refinement and potential widespread adoption of mobile TMS as a treatment option, both in our state and across the US.
The purpose of this study is to assess impact of repetitive transcranial magnetic stimulation (rTMS)+Episodic Future Thinking (EFT) vs. sham rTMS+EFT on delay discounting and methamphetamine (MA) demand, on vividness of future positive events during EFT training and on frequency of episodic thinking during the week following EFT training
This study is testing a new treatment called IR-TMS (image-guided, robot navigated transcranial magnetic stimulation) to see if it can help people who drink too much alcohol to reduce the amount they drink. Participants will be placed into one of three groups, each receiving a slightly different version of this treatment. The study involves going through a few sessions of IR-TMS, having brain scans (MRI), providing blood and urine samples, and answering questions about their drinking and mental health. These activities are part of the study and aren't usually part of regular treatment for alcohol use. IR-TMS is different from regular treatments like therapy or medication because it uses magnetic fields to target specific parts of the brain. The goal is to see if this treatment can help reduce the urge to drink. There are other options, like sticking with therapy or medication, which are less intense but have been used for a longer time.
The investigators propose to expand our previous work to test whether 10 repeated administrations of the cTBS procedure over a two-week period can lead to longer-term improvements in sleep, perhaps up to 3-months. For this 3-year study, 120 people with insomnia will be recruited to participate. There will be an initial screening, with the first consent form being for the screening questions, a psychological interview, and a one night at home sleep monitoring session with our equipment. If participants pass this first phase, they will reconsent for the main portion of the study. They will then undergo a physical examination, then a week-long at-home monitoring phase where they will wear a wristwatch sleep monitor as well as wear a portable brain wave monitor to bed each night to record sleep. Participants will continue to use this equipment throughout the treatment phase and for one week post treatment. After the first monitoring phase, each participant will be randomly assigned to one of four different conditions (i.e., 30 assigned to each group). Three of the conditions will involve cTBS focused on different brain locations (i.e., stimulation to the middle front, middle back, or side of the skull), while the fourth condition will provide inactive sham stimulation as a control. All participants will complete 10 treatment visits to the lab over two-to-three weeks, during which they will get a brief cTBS or sham stimulation each time. In addition, all participants will complete a brain scanning and cognitive testing session at the beginning and end of the two-to-three week treatment period. Participants will also complete 1-month and 3-month online follow-up assessments to examine long-term effects.
The goal of this clinical trial is to learn if using deep repetitive transcranial magnetic stimulation (rTMS) targeting the precuneus is feasible, tolerable, and potentially efficacious for memory in Probable Alzheimer's Dementia. Previous work studying rTMS in Alzheimer's is mixed, but recent work studying rTMS of the precuneus is encouraging for both its short-term and long-term effects. The main questions this study aims to answer are: * Is deep rTMS of the precuneus feasible and tolerable in Alzheimer's? * Are there signs of positive brain changes in response to deep rTMS? * Is deep rTMS potentially efficacious for memory in Alzheimer's? Researchers will compare active stimulation to placebo stimulation while obtaining memory testing and measurements of the brain (imaging, scalp electrode measurements, bloodwork) to see if active treatment works to treat mild-to-moderate probable Alzheimer's Dementia. Participants will: * Engage with memory testing, brain scans, and bloodwork during a comprehensive assessment * Visit the clinic 3 times for 12 consolidated rTMS sessions, followed by 4 once weekly maintenance sessions * Be offered a full open-label active treatment course after completing their treatment course if they are initially in the placebo group
Posttraumatic stress disorder (PTSD) among military service members and veterans is as high as 32% and is the third most service-connected disability, resulting in over $1.5 billion in direct costs over a five-year period. According to Clinical Practice Guidelines, strong evidence exists for psychotherapies, such as prolonged exposure (PE) for PTSD. However, psychotherapies are often met with high drop-out rates, treatment non-compliance, and emotional stress due to trauma recall. A successful approach to reduce drop-out rates and maintain efficacy is to compress psychotherapy into daily, day-long PE sessions. Yet another deficit exists regarding the feasibility of this approach outside of residential treatment facilities, which are typically reserved for the most extreme cases. The newest study from the our team aimed to augment PE residential treatment with a neuromodulatory treatment: image-guided, robot-navigated transcranial magnetic stimulation (IR-TMS). Along with the PE-focused intensive inpatient program (IIP-PE), participants received IR-TMS targeting the right dorsolateral prefrontal cortex (DLPFC) daily for 20 consecutive days. Results demonstrated superiority of the combined IIP-PE/IR-TMS approach, compared to IIP-PE and a sham condition. However, it is not yet established whether a standalone IR-TMS approach will achieve similar results. Our goal is to implement an open-label trial of IR-TMS for PTSD, in which veterans and active-duty service members with PTSD will receive accelerated IR-TMS throughout a 2-week timeframe. Results will be used as a foundation for future extramural funding to scale-up the stand alone IR-TMS intervention for PTSD treatments.
In this research study we want to learn more about the effects of non-invasive brain stimulation on memory and brain-network function in cognitively unimpaired older adults and in patients with amnestic mild cognitive impairment (aMCI). This study will use a form of non-invasive brain stimulation called repetitive Transcranial Magnetic Stimulation (rTMS). rTMS will slightly alter activity in an area of your brain that controls memory. Changes resulting from this stimulation will be measured with behavioral tests of memory and general cognition, as well as by taking images of your brain with Magnetic Resonance Imaging (MRI). Participants will come in for one baseline visit followed by 10 days of daily rTMS study visits (Monday through Friday) and an evaluation visit. Then, there will be a 2-week break. After this break, they will return for another baseline visit, an additional 10 days of rTMS, and a final evaluation visit.
This study will focus on the use of Virtual Reality (VR) technology in patients receiving treatment using Transcranial Magnetic Stimulation (TMS) for Obsessive-Compulsive Disorder (OCD)
A prospective study to evaluate symptoms following repetitive transcranial Magnetic stimulation.
Participants will receive Transcranial Magnetic Stimulation (TMS) at a random location in the left prefrontal cortex, excluding sites that are potentially unsafe. Extensive behavioral testing will be conducted to determine which behaviors are modulated by stimulating which circuits.
The goal of this single-arm, observational pilot study is to learn about the safety, feasibility, preliminary efficacy of TMS for the treatment of depression in people with MS. Participants will receive outpatient TMS treatment over the course of 5-6 weeks. Participants will complete validated questionnaires and exams before, during, and after treatment.
Our specific aim is to examine the effects of TMS on reward processing during goal-directed behavior. In these experiments the investigators will utilize a scalp-recorded brain oscillation called frontal midline theta that is believed to index the sensitivity of the cingulate cortex to reward feedback. Here the investigators will asked whether this electrophysiological signal can be modulated up or down using TMS while participants engage in decision making tasks, and if so, whether it would affect the encoding of rewards and subsequent choices during task performance.
The purpose of this research study is to understand how the brain processes and controls speech in healthy people. The investigators are doing this research because it will help identify the mechanisms that allow people to perceive their own speech errors and to learn new speech sounds, which may be applied to people who have communication disorders. 15 participants will be enrolled into this part of the study and can expect to be on study for 4 visits of 2-4 hours each.
This study aims to assess the efficacy of Personalized Repetitive Transcranial Magnetic Stimulation (PrTMS) therapy to reduce chronic neck for military health system beneficiaries.
The goal of this observational study is to test the modulation effect of different transcranial magnetic stimulation (TMS) on the neural network supporting our ability to create mental representations of others (also known as mentalizing) in young adults with autism. The main question it aims to answers is can stimulation of the right temporoparietal junction can change brain activity related to mentalizing during social interaction in the stimulation area and other brain areas connected to it. Researchers will compare results to a group of individuals without autism to see if the patterns of neural activity change are similar between the groups. Participants will undergo assessment of their clinical traits and social skills and baseline MRI scan. They will attend three additional visits that include TMS session and functional MRI scans before and right after TMS.
This study will assess clinical and behavioral measures along with electroencephalogram (EEG), event-related potentials (ERPS), and eye-tracking (ET) prior to and following a single intermittent Theta Burst Stimulation (iTBS) session to provide preliminary insight into the potential of TMS as an intervention for depression in individuals with Autism Spectrum Disorder (ASD).
This study aims to examine the long-term effect of repetitive transcranial magnetic stimulation (rTMS), a non-invasive brain stimulation technique, on chronic headaches following mild traumatic brain injury (mTBI). rTMS has been shown to be effective in reducing chronic headaches without side effects commonly seen in medications, such as sleepiness and addiction. This study uses rTMS to manage chronic headaches to improve post-concussion symptoms and reduce the economic burden due to delayed recovery. This project aims to better identify biomarkers for diagnosis and prognosis and maximize recovery from mTBI.
This is an open-label safety pilot study of the Electroencephalogram (EEG) Transcranial Magnetic Stimulation (eTMS) treatment for Post-Traumatic Stress Disorder (PTSD). The recruitment goal is 30 participants who are United States Military veterans or first responders (e.g., firefighters, police, paramedics, etc.). The Study includes an EEG recording in order to determine the optimal treatment parameters for the eTMS system, followed by 10 in-office visits that take place over 21 total days. Two eTMS treatment sessions are administered during each office visit.
This study will attempt to use magnetic resonance imaging (MRI) to take a picture of the brain to learn about changes that occur in the brain during Transcranial Magnetic Stimulation (TMS) in people receiving this treatment for depression.
In this study, the investigators will examine whether a type of repetitive transcranial magnetic stimulation called accelerated intermittent theta burst stimulation (iTBS) can augment neurocognition in individuals who receive treatment with clozapine. Following a baseline evaluation and magnetic resonance imaging (MRI), participants will undergo a session of iTBS +MRI and session of sham delivery + MRI. The order for these sessions will be blinded and randomized. The investigators predict that accelerated iTBS will enhance neurocognition relative to sham delivery.
The goal of this phase II study is to establish the dose-response curves of a safe and clinically feasible non-invasive brain stimulation technique (accelerated Transcranial Magnetic Stimulation (TMS)) to improve both depression and cognitive function in Mild Cognitive Impairment (MCI) patients with comorbid depression. It is known that TMS can effectively treat depression. Identifying the right dose of accelerated TMS in MCI patients is necessary prior to designing subsequent trials to determine efficacy. These results will inform future clinical trials of accelerated TMS for MCI, with the long-term goal of developing an efficacious treatment to prevent dementia.