View clinical trials related to Essential Tremor.
Filter by:This is a feasibility study based on physician-initiated Investigational Device Exemption (IDE) including intraoperative experiments and chronic testing of implanted dual thalamic DBS lead systems. This study will inform protocols for optimal use of implanted next-gen DBS systems for primarily tremor control in refractory essential tremor.If the approach appears to be successful, the pilot data generated will be used to base a future pivotal trial for FDA approval for enhanced tremor control and adaptive DBS (aDBS) functionality of DBS systems.
The purpose of the Chinese Essential Tremor Registry (CETR) is to develop a database of patients with Essential tremor in China.
This is a multicenter, open-label, non-controlled, non-randomized, phase 3 clinical study to compare the SPECT findings after a single IV administration of DaTSCAN™ ioflupane (123I) injection for patients with a clinical diagnosis of Parkinsonian syndrome (PS) involving striatal dopaminergic deficit (SDD; specifically, Parkinson's disease [PD] [SDD], multiple system atrophy [MSA] [SDD] or or progressive supranuclear palsy [PSP] [SDD]) as compared with patients with a clinical diagnosis of essential tremor (ET) (no SDD) and age-matched healthy controls.
The purpose of this study is to see if the MR-guided focused ultrasound (MRgFUS) thalamotomy procedure can be performed on both sides of the brain safely and effectively to reduce bilateral tremor.
Context. Essential tremor (ET) is a common disease, disabling in severe forms and resistant to drug treatment. In patients with severe ET, invasive neurosurgical technique such as deep brain stimulation of the Ventral Intermediate (VIM) nucleus of the thalamus is used. Focused ultrasound therapy, creating a small lesion of VIM represents an effective therapeutic alternative of low morbidity with the advantage of not requiring the opening of the skull and penetration into the brain. This therapy is performed under stereotactic guidance. Validation of the target before lesioning is done by testing the clinical effect by a gradual increase in temperature, resulting in tremor reduction. However, the gradual temperature increase in the targeting phase is suboptimal because it can decrease the efficiency of the lesioning procedure. The aim of this research project is to test an innovation of fundamental physics developed by the Langevin Institute, which would allow the reversible modulation of nerve tissue by ultrasonic waves without heating, to predict the effectiveness of treatment of the chosen target within the VIM before creating an irreversible lesion. Methodology: Fifteen patients with severe and resistant essential tremor will be included in the study. A multimodal MRI will be performed for target calculation using several targeting methods for VIM developed during step 1. For each target, the application of neuro-modulation by ultrasound will allow determine the effect obtained on the tremor (quantified with adequate clinical scales - as Tremor rating scale (CRST), and the recording of electromyographic activity of the upper limbs) and the absence of side effects. A definitive millimetric lesion will be performed at the level of the most relevant target in order to maintain the clinical effect obtained. The procedure will be controlled by thermal MRI sequences. Post-therapy clinical and MRI multimodal follow-up will take place on D1, D7, M1, M2, M3, M6, M12 and M24. Perspectives and Innovation: This project will test clinically the low intensity ultrasound neuromodulation jointly developed by the Langevin Institute and the Brain and Spine Institute ( ICM) in order to refine the targeting procedure of high intensity transcranial focused ultrasound therapy. In perspective, reversible neuromodulation performed in vivo in humans represents a considerable advance in the exploration and future treatment of neurological and psychiatric diseases such as depression. The translational collaboration between the physicists of the Langevin Institute, the ICM and the medical services of the Pitié-Salpêtrière guarantees the feasibility and quality of this first joint therapeutic trial.
The purpose of this international study is to evaluate long-term safety and effectiveness of Abbott deep brain stimulation (DBS) systems for all indications, including Parkinson's disease, essential tremor or other disabling tremor and dystonia.
Transcranial alternating current stimulation (tACS) is a noninvasive neuromodulation method that works by passing alternating electric current between electrodes where at least one of them is attached to the head. This has been shown to have effects on the motor system, cognition and behavior. The exact mechanism by which tACS causes such effects is not fully understood. Some studies suggests a contribution from the stimulated peripheral nerves present in the scalp rather than direct brain effects. To test this hypothesis two arms will be done. First, 12 subjects (arm 1) will be stimulated using focused 4x1 montage with gel-filled cup-electrodes over the motor cortex and the effects will be compared between anesthetized and non-anesthetized scalp. The effects of anesthetizing the scalp will be tested on three different stimulation amplitudes off (0 mA), low (0.5 mA) and high (2.5 mA). Then, 10 subjects (arm 2) will be stimulated over the contralateral arm to exclude any direct brain stimulation effects and to test if peripheral nerve stimulation can entrain the tremor. Three outcome measurements will be measured during the experiments which are: tremor entrainment, sensation intensity and sensation threshold.
To compile characteristics of real-world outcomes for Boston Scientific Corporation's commercially approved Deep Brain Stimulation (DBS) Systems, when used according to the applicable Directions for Use, for the treatment of Essential Tremor.
The object of this study is to longitudinally collect clinical outcomes of patients receiving deep brain stimulation for movement disorders with the objective of making retrospective comparisons and tracking of risks, benefits, and complications.
Deep brain stimulation (DBS) targeting the Vim thalamus (ventralis intermedius nucleus) is an FDA-approved neuromodulation therapy for treating postural and action tremor in individuals with essential tremor (ET). The success of this treatment, however, is highly dependent on the ability of clinicians to identify therapeutic stimulation settings through a laborious programming process. There is a strong and growing clinical need for new approaches to provide clinicians with more efficient guidance on how to titrate stimulation settings. This study will leverage subject-specific computational models that can predict neural activation of axonal pathways adjacent to the active electrode(s) and implicated in the therapeutic mechanisms of Vim-DBS to in turn guide clinicians with which stimulation settings are likely to be the most therapeutic on tremor.