139 Clinical Trials for Various Conditions
The purpose of this research study is to study a closed-loop transcranial alternating current stimulation (tACS) device to evaluate feasibility of the product in a clinical trial and collect preliminary data on potential effects on symptoms of depression in people with major depressive disorder.
The purpose of this study is to learn more about how brain stimulation affects word finding problems in people who have a traumatic brain injury (TBI). The type of brain stimulation used is called transcranial direct current stimulation (tDCS). tDCS delivers low levels of electric current to the brain and high definition tDCS (HD-tDCS) delivers the current with multiple electrodes on the scalp. This current is delivered with HD-tDCS to parts of the brain that may help with remembering things. The investigators hope that this can help to improve word finding and memory problems in people with TBI.
The study is about using a brain stimulation technique called rTMS (Repetitive Transcranial Magnetic Stimulation) to help improve hand muscles in people who had a stroke. Researchers want to understand how this device can help stroke patients use their hands better.
This study explores whether rapid non-invasive brain stimulation can help reduce hoarding disorder symptoms.
The goal of this randomized controlled trial is to investigate the effectiveness of non-invasive brain stimulation in treating adults with amblyopia. The main questions it aims to answer are: 1. What are the effects of non-invasive brain stimulation on neuronal plasticity in the visual cortex of adults with amblyopia, and does it produce lasting changes? 2. Do cumulative sessions of non-invasive brain stimulation influence neural plasticity and higher-order visual functions in adults with amblyopia? The investigators hypothesize that non-invasive brain stimulation will show a positive cumulative effect after five (5) consecutive days of stimulation on visual perception and function in adults with amblyopia. Participants will be randomized into one of two treatment groups: 1. High-frequency transcranial random noise stimulation (hf-tRNS). 2. Sham stimulation. Researchers will compare baseline measurements of crowded visual acuity, contrast sensitivity, stereoacuity, phosphene thresholds, global motion perception, form pattern recognition and pattern-reversal visual evoked potentials (VEPs) to post-treatment measurements for each group.
This study will test the clinical efficacy of an accelerated TMS (accel-TMS) protocol that rapidly addresses PTSD symptoms with 1 week (25 sessions over 5 days) of condensed treatment.
The purpose of the proposed study is to use transcranial magnetic stimulation (TMS) to evaluate a neurobiological model of spoken word learning in older youth. Specifically, it is hypothesized that: (1) inhibition of the left dorsal stream will impact subsequent learning, processing, and retention of phonologically similar pseudowords; (2) the impact of dorsal stream inhibition on word learning will be associated with baseline levels of variability in neural activity, indicative of underlying differences in cortical excitability.
Stroke is a leading cause of disability with many patients suffering chronic motor function impairments that affect their day-to-day activities. The goal of this proposal is to provide a first assessment of the efficacy of an innovative non-invasive brain stimulation system, kTMP, in the treatment of motor impairment following stroke.
The goal of this clinical trial is to test the effects of repetitive transcranial magnetic stimulation (theta burst stimulation) on movement biomechanics (jump landing) among individuals with and without a concussion history. The main question it aims to answer is if theta burst stimulation to the left dorsolateral prefrontal cortex improves single- and dual-task jump landing reaction time and jump landing biomechanics compared to a control site (vertex) for individuals with and without a concussion history. Participants will be asked to perform a jump landing before and after the experimental (left dorsolateral prefrontal cortex) and control (vertex) theta burst stimulation protocol. The researchers will compare individuals with and without a concussion history to see if the effects differ between groups.
Walking is a complex and continuous task that entails repetitive motions of the body. Relatively high gait variability sensitively predicts falls and cognitive decline in older adults. Previous work has identified an unique brain network relationship linked to gait variability and its relevant cognitive function (i.e., sustained attention). This project aims to develop a non-invasive brain stimulation montage designed to modulate the shared brain networks dynamics and to demonstrate its effects on resting state functional connectivity, gait and cognitive performance in older adults at risk for falls.
The goal of this randomized controlled trial is to test the effectiveness of non-invasive brain stimulation in treating adults with symptomatic convergence insufficiency compared to vergence/accommodative therapy. The main questions it aims to answer are: 1. Can non-invasive brain stimulation shorten the treatment time of office-based vergence/accommodative therapy for convergence insufficiency? 2. Is non-invasive brain stimulation alone just as effective as office-based vergence/accommodative therapy in treating convergence insufficiency? The investigators hypothesize that non-invasive brain stimulation will shorten the treatment time from 12 weeks to 8 weeks of office-based vergence/accommodative therapy and that non-invasive brain stimulation alone would be equally effective as office-based vergence/accommodative therapy in improving symptomatic convergence insufficiency. Participants will be randomized into one of three treatment groups: 1. Non-invasive brain stimulation with office-based vergence/accommodative therapy. 2. Sham stimulation with office-based vergence/accommodative therapy. 3. Non-invasive brain stimulation only. Researchers will compare baseline measurements of near point of convergence (NPC) and positive fusional vergence (PFV) to post-treatment measurements for each group.
This project aims to examine the efficacy of remote, caregiver-led tES/brain stimulation intervention targeted to improve memory, mobility, and executive functioning among older adults with mild cognitive impairment or mild dementia.
The goal of this project is to address the urgent need for effective, scalable adult literacy interventions by integrating breakthroughs in two separate fields: 1.) the brain network science of resilience to reading disorders and 2.) high-definition non-invasive brain network stimulation. This study will first establish the efficacy of a novel, noninvasive stimulation protocol on reading behavior and brain metrics; then will determine how stimulation-induced effects interact with baseline reading comprehension ability; and lastly, will identify whether stimulation-induced effects are more clinically-beneficial than canonical behavioral interventions. Results may change the foundation for how we treat low adult literacy, and have the potential for wider reaching impacts on non-invasive stimulation protocols for other clinical disorders.
The purpose of the study is to test whether low level electric stimulation, called transcranial Direct Current Stimulation (tDCS), on the part of the brain (i.e., pre-supplementary motor area and left inferior frontal gyrus) thought to aid in memory will improve speech and language difficulties in patients with primary progressive aphasia (PPA) and progressive apraxia of speech (PAOS). The primary outcome measures are neuropsychological assessments of speech and language functions, and the secondary measures are neuropsychological assessments of other cognitive abilities and electroencephalography (EEG) measures.
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.
Although many children diagnosed with autism spectrum disorder (ASD) make significant progress in learning and their cognitive skills improve with applied behavior analysis (ABA), there are a significant number of children who show an absence or a plateau in various skills. Deficits in executive functioning are likely to be involved in many of these cognitive and learning disabilities due to poor functioning of the prefrontal cortex. Currently, the use of biological methods for improving learning and cognition is largely unexplored in research and practice. The aim of this study is to use of transcranial direct current stimulation (tDCS) in combination with ABA to improve the acquisition of educational programs for students with ASD. tDCS is a low-level electrical neurostimulation and is most effective when used in combination with an active training or teaching, facilitating the neuronal circuits used for that task. tDCS has been used for various indications over a couple of decades and has been shown to be very safe and has been well-tolerated by children with ASD. The mechanism of tDCS is not clear, however animal studies show that tDCS can stimulate the flow of calcium ions through channels in the astrocytes, activating them, and facilitating their role in synapse formation and therefore learning.
The goal of this small (n=75) proof-of-concept randomized clinical trial is to test the effects of transcranial alternating current stimulation (tACS) during motivational interviewing (MI) sessions with participants who drink at above the low-risk level. Participants will be randomized to receive either MI with active stimulation, MI with sham stimulation, or a delayed treatment group that receives MI with no stimulation. Measures will include brain imaging, alcohol use, cannabis use, risk-taking behavior, emotions, and others. Participants who are randomized to the delayed-treatment group will not receive brain imaging.
This project will assess the feasibility of traveling wave transcranial alternating current stimulation (tACS) to modify working memory performance and large-scale brain connectivity in surgical epilepsy patients.
The overall goal of this project is to improve cognitive control abilities in adults with mild cognitive impairment (MCI) through a form of non-invasive brain stimulation, transcranial alternating current stimulation (tACS).
Quadriceps muscle dysfunction persists for years after anterior cruciate ligament reconstruction (ACLR) and is related to poor self-reported outcomes, altered movement patterns and joint loading associated with post-traumatic knee osteoarthritis (OA), and higher risk of reinjury. Emerging evidence indicates that central drive (pathway from the brain to the muscle of interest, i.e corticospinal excitability) to the quadriceps muscle is reduced as early as 2 weeks after surgery and can persist for years after ACLR, meaning that current rehabilitation strategies may not be addressing potential maladaptive changes in central drive. Anodal tDCS is a neurostimulation technology that increases brain excitability (i.e. central drive) and has the potential to address alterations in central drive and quadriceps muscle performance. The purpose of this study is twofold: 1) to determine the effects of anodal tDCS on central drive and quadriceps muscle performance in patients after ACLR, and 2) determine the relationship between central drive and quadriceps muscle performance in patients after ACLR. Central drive will be defined by two measures: 1) active motor thresholds, and 2) slope of a stimulus response curve. Quadriceps muscle performance will be defined by two measures: 1) isometric quadriceps strength, and 2) rate of torque development (RTD). For purpose 1 the investigators hypothesize that measures of central drive and quadriceps muscle performance will increase with administration of active anodal tDCS compared to no change with sham tDCS. For purpose 2 the investigators hypothesize that both measures of central drive will be associated with both measures of quadriceps performance, with a stronger association between central drive and RTD. Following a cross-over design patients 3-6 months from ACLR will receive active and sham anodal tDCS at different sessions separated by 7-10 days while they ride a stationary bike for 20 minutes. Bike position and intensity will be standardized for all patients to maximize quadriceps activity. Findings from this study will expand our basic science knowledge on how tDCS effects different aspects of corticospinal excitability and quadriceps strength, and lead to subsequent studies to determine the effects of multiple sessions of tDCS on corticospinal excitability and quadriceps muscle performance in patients recovering from ACLR.
The overarching goal of this project is to expand the traditional expertise in non-invasive neuromodulation at the University of Minnesota towards developing novel paired-neuromodulation approaches using transcrancial direct current stimulation (tDCS) for new addiction treatments that support long-term abstinence. This study will investigate whether the pairing of dorsolateral prefrontal cortex (DLPFC) stimulation and cognitive training can enhance functional connectivity between DLPFC and nucleus accumbens (NAcc). We have identified higher functional connectivity between DLPFC and NAcc in alcoholics that have successfully maintained abstinence for extended periods of time (7 years). This paired-neuromodulation approach can potentially be used as a therapeutic intervention to decrease substance use probability in addiction (e.g. opioid use disorder). The long term goal is to develop new addiction treatments that support long-term abstinence in opioid use disorder. The overall objective of this proposal is to enhance functional connectivity between DLPFC and NAcc as a therapeutic intervention to enhance cognition and reduce substance use rates in opioid use disorder.
The primary aims of this study are to identify impaired cognitive control in opioid use disorder (OUD) and subsequently to examine the effects of transcranial magnetic stimulation (TMS) on reward processing, as measured by the reward positivity (an electrophysiological signal) in people with OUD. To this end, the investigators will adopt a randomized sham-controlled trial to evaluate the efficacy of Ri-TMS on cognitive control in OUD. The investigators hypothesize that Ri-TMS will be successful in modulating the reward positivity in opioid users in the active TMS condition.
Non-invasive brain stimulation has been shown to alter performance in both clinical and healthy populations on cognitive tasks. While the performance alterations have generally been shown to result in enhancement, mixed results remain in the literature. Much of the mixed results within the literature have been attributed to the use of different stimulation parameters, targeting of different brain areas, and using a variety of performance measures or assessing different constructs. However, non-invasive brain stimulation is a desirable method for enhancing Soldier performance given the ease of administration and minimal side effects as compared to other forms of performance enhancement (e.g., pharmaceuticals, caffeine). The objective of the current study is to evaluate the effects of non-invasive brain stimulation to the left dorsolateral prefrontal cortex in enhancing Soldier cognitive skills and performance on military tasks. A double blind within-subjects design will be used with healthy, rested Soldiers who will receive non-invasive brain stimulation and perform basic cognitive and operationally relevant tasks.
Purpose: In this study, the investigators will delineate how brain network dynamics are modulated by experimentally induced elevated blood glucose levels and examine how glucose levels gate neuronal excitability measured by the response to TMS. Participants: Participants must be between the ages of 18 and 65 with no known diabetes, no known adverse reaction to finger prick blood draw, and no known neurological or psychiatric illness. Participants must have a body-mass index less than 30. Procedures: Participants will consume either a drink that contains 75 g of glucose or a placebo, and their response to TMS will be measured to examine the effect of glucose on motor cortex excitability.
This pilot study for stroke patients with chronic upper limb hemiplegia will examine the effects of non-invasive brain stimulation and neuromuscular electrical stimulation on hand motor control and corticospinal excitability. Specifically, this study will investigate the effects of timing and delivery of tDCS in conjunction with contralaterally controlled functional electrical stimulation.
The purpose of this study is to examine whether non-invasive brain stimulation can be used to improve cognitive deficits in patients with delirium.
The study aims to identify neural locus critical for dual-task walking (walking and talking) in individuals with stroke. To achieve this aim, the investigators apply repetitive transcranial magnetic stimulation (rTMS) to different parts of the brain and evaluate the effects of brain stimulation on dual-task walking speed.
Research studies in stuttering have shown that activity patterns in certain brain areas differ in people who stutter compared to people who do not stutter when speaking. The purpose of this study is to investigate how mild, non-invasive brain stimulation applied consecutively for five days affects speech relevant brain areas, which may in turn affect speech fluency and speaking-related brain activity in people who stutter.
The purpose of this study is to understand how cortical stimulation affects Obsessive-Compulsive Disorder (OCD) symptoms.
In this pilot study, the feasibility of using tDCS (a non-invasive brain stimulation technique) while performing a task requiring cognitive flexibility will be examined in smokers and initial data will be collected regarding the effect of tDCS on smoking cessation behaviors. Smokers will be randomized to receive either active or sham tDCS daily for 5 days after which they will attempt to quit smoking. Smoking behavior after the attempted quit date will be assessed at four weekly visits.