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This study is being done to test whether low-intensity focused ultrasound (LIFU) (low energy sound waves) cause temporary changes in brain activity and behavior when directed at particular parts of the brain. By targeting LIFU to the parts of the brain thought to be responsible for essential tremor (ET), and measuring any associated improvement in tremor, the investigators hope to show that LIFU can be a useful tool for studying the brain circuits responsible for tremor and other brain disorders.
Investigators are conducting this study to test if temporarily and non-invasively stimulating the brain will affect the emotional response to stress in healthy participants. Participants will perform a series of tasks while completing an MRI scan. After this, participants will be randomized to undergo transcranial magnetic stimulation (TMS) at two visits, undergoing active stimulation at one visit and undergoing 'sham' stimulation at another visit. Immediately following both stimulation sessions, participants will repeat the tasks during MRI scanning.
We will recruit 10 patients with OCD meeting established criteria for surgical evaluation. Following informed consent and baseline evaluations, each will be implanted with permanent DBS SenSight leads and the Medtronic Percept RC IPG, which has on-device neural recording capability and rechargeability. We will collect a broad array of neurobehavioral data across two environments with complementary advantages: the clinic and the home. The first 2 Aims test our mechanistic hypothesis by studying the pattern of VS neural activity in the controlled environment of the lab/clinic during two complementary paradigms: one based on a psychophysical behavioral task, the other based on ERP, a therapeutic behavioral intervention. The third aim tests this hypothesis in an ambulatory, naturalistic setting with chronic neural on-device recordings paired with time resolved behavioral measures. We will investigate a possible common neural basis underlying approach and avoidance across these 3 paradigms. Subjects will participate in research at 7 critical timepoints during routine clinic visits (Fig. 4): before implant, 1 day before DBS activation, immediately after DBS activation, 2 weeks, 3 months, 6 months, and 12 months after DBS initiation. At these timepoints, patients will complete clinical assessments, perform the Probabilistic Approach Avoidance Task (PAAT), and conduct exposure trials under the guidance of a psychologist. The clinic offers the most controlled environment and provides opportunities for collecting high temporal resolution behavior synchronized to local field potential (LFP) recordings. These data will allow us to identify the degree of overlap in the time-resolved neural activity driving individual decisions to approach potential rewards or avoid potential aversive stimuli (Aim 1), and resist performing compulsions in order to achieve relief after OCD symptoms are triggered (Aim 2). At home, our goal is to investigate patient trajectories along the approach-avoidance axis as OCD symptoms improve (Aim 3). We will leverage passive, on device recordings that occur in the background of everyday life activities and synchronize these neural recordings with data collected via wearables, ecological assessments, and video diaries. Capturing neural and behavioral data in the home environment is essential for understanding the neural and behavioral changes that occur over longer timescales than individual clinical visits. The neurobehavioral biomarkers generated by this dataset will provide trackable readouts of clinical status that could inform therapeutic decision-making and enable data driven intervention.
This study aims to examine the effects of Low-Intensity Focused Ultrasound (LIFU) on brain activity in patients with alcohol use disorder.
Spasticity is characterized by increased muscle tension and is a classic consequence of upper motor neuron (UMN) damage in the central nervous system, such as from stroke or trauma. Clinically, it presents as muscle resistance to passive stretching, along with clasp-knife rigidity, clonus, increased tendon reflexes, and muscle spasms. An imbalance of the descending inhibitory and muscle stretch reflexes is thought to be the cause of spasticity. Post-stroke spasticity is a common condition that occurs in 37.5-45% of cases in the acute stage and 19-57.4% in the subacute stage after a stroke. At 6 months post-stroke, spasticity develops in 42.6-49.5% of cases, and at one year, it affects 35-57.4% of individuals. In patients with cerebral palsy (CP), incidence is almost 80% while in those living with spinal cord injury the number approaches up to 93%. Traumatic brain injury (TBI) patients have a higher prevalence on initial admission to neurorehabilitation but one in three patients will have chronic spasticity. However, the Defense and Veterans Brain Injury Center report a rate of TBIs amongst deployed veterans to be around 11-23% mostly from blast and explosive trauma. There have been studies as early as the 1980s exploring the efficacy of SCS for spasticity control, however, the credibility of many of these studies is constrained due to an incomplete comprehension of spasticity's underlying mechanisms, outdated research methods, and early limitations in implantable device technology. Intrathecal pumps for baclofen have remained as the mainstay for refractory spasticity, however, it comes with associated risks such as chemical dependence leading to acute baclofen withdrawal and requiring frequent refill requirement. Most importantly, it does not yield functional improvement of muscle activity, just suppression of spasticity. Botox is also routinely used but due to heterogeneity in muscle involvement as well as variability in provider skill, results may be inconsistent and short-lasting, requiring frequent clinic visits for repeat injections to the affected muscle groups. SCS may be able to address that gap in spasticity management.
People with spinal cord injuries may experience muscle tightness or uncontrollable spasms. This study is being conducted to investigate whether transcutaneous spinal stimulation can improve these symptoms. Transcutaneous spinal stimulation is a non-surgical intervention by applying electrical currents using skin electrodes over the lower back and belly. The investigators want to see how well the intervention of transcutaneous spinal stimulation performs by testing different levels of stimulation pulse rates. Also, transcutaneous spinal stimulation is compared to muscle relaxants such as baclofen and tizanidine, commonly given to people with spinal cord injuries, to reduce muscle stiffness and spasms. By doing this, the investigators hope to discover if transcutaneous spinal stimulation similarly reduces muscle spasms and stiffness or if combining both methods works best. This could help improve treatment options for people with spinal cord injuries in the future.
Fibromyalgia (FM) is a chronic disorder that affects the musculoskeletal system, causing widespread pain, tenderness, and fatigue. It is estimated to affect 1-5% of the population. The primary symptom of fibromyalgia is widespread pain throughout the body, accompanied by tenderness and sensitivity to pressure. Pharmacological treatments include drugs such as antidepressants, anticonvulsants, and painkillers. Another treatment option for fibromyalgia is the use of devices such as Quell. Other non-pharmacological treatment options for fibromyalgia include cognitive-behavioral therapy (CBT), biofeedback, and relaxation techniques. Remote Electrical Neuromodulation (REN) is a non-pharmacological technology that induces subthreshold, non-painful neurostimulation signals that activate an endogenic pain-management system termed Conditioned Pain Modulation (CPM), to produce generalized pain relief in remote body areas. Multiple studies have shown that REN is safe and effective for the acute treatment of migraine in adults and adolescents, as well as migraine prevention. The current study examines the safety and efficacy of REN technology, implemented via the FibroNova device for treating fibromyalgia pain and related symptoms.
It has been demonstrated that the human lumbosacral spinal cord can be neuromodulated with epidural (ESS) and transcutaneous (TSS) spinal cord stimulation to enable recovery of standing and volitional control of the lower limbs after complete motor paralysis due to spinal cord injury (SCI). The work proposed herein will examine and identify distinct electrophysiological mechanisms underlying transcutaneous spinal stimulation (TSS) and epidural spinal stimulation (ESS) to define how these approaches determine the ability to maintain self-assisted standing after SCI.
The primary goal of this clinical trial is to evaluate whether Personalized Augmented Cognitive Training (PACT) plus intermittent theta burst stimulation (iTBS) is effective for treating depression in Service Members, Veterans, and civilians who have sustained a mild TBI. Participants will receive PACT plus 20 sessions of iTBS or sham iTBS over 4 weeks. Assessments will occur at baseline, 2 weeks, 4 weeks, and 8 weeks. Researchers will compare the PACT+iTBS group to the PACT+sham iTBS group to see if PACT+iTBS is associated with more depression improvement.
This study will comprehensively investigate the insula as a brain target for neuromodulation to treat chronic neuropathic pain.