View clinical trials related to Essential Tremor.
Filter by:This study evaluates the effectiveness of tremor control using various strategies for implementing demand-driven thalamic deep brain stimulation (DBS) for essential tremor. Therapeutic stimulation at the Vim nucleus of the thalamus will be initiated and modulated using signals derived from external sensors (e.g. EMG, accelerometer) and cortical or thalamic electrodes.
Recently, there has been increasing interest in performing DBS under general anesthesia, where the stimulated targets are located anatomically (i.e. on MRI) rather than physiologically via microelectrode recordings and intra-operative test stimulation. This technology has been termed "asleep" DBS and is performed with the patient under general anesthesia. Intraoperative imaging is utilized to verify the stereotactic accuracy of DBS electrodes placement at the time of surgery. Because stereotactic accuracy (and surgical safety) is the surgical endpoint, there is no need for the patient to be awake during the procedure.
Essential tremor (ET) is a frequent and disabling disorder with progressive worsening of postural tremor of the upper limbs that impairs most of the manual activities of every day life (feeding, drinking, etc.). Although the pathophysiology of essential tremor (ET) is not fully elucidated, tremor is associated with abnormal activity within different brain regions, in particular the thalamus and the cerebellum. Deep brain stimulation (DBS) of the ventral intermediate nucleus of the thalamus (VIM-Thal) reverses the symptoms of tremor but is an invasive procedure. Transcranial stimulation of the cerebellum may represent a non-invasive therapeutic option for ET patients. Here, the investigators propose to test the efficacy of cerebellar stimulation in 15 ET patients previously operated for DBS of the thalamus. To further understand how this treatment provokes tremor reduction, the investigators will analyse the brain neuronal activity in 13 others ET patients candidate to thalamic DBS by using combined electrophysiological recordings of the thalamus (with the electrodes implanted), the cerebellum and the cortex with magnetoencephalography.
Deep brain stimulation (DBS) is an FDA approved, and widely used method for treating the motor symptoms of Parkinson's disease (PD), Essential Tremor (ET), Dystonia and Obsessive Compulsive disorder (OCD). Over 100,000 patients worldwide have now been implanted with DBS devices. Current approved methods to locate the DBS target regions in the brain use a combination of stereotactic imaging techniques and measurements of the electrical activity of brain cells. As part of the standard clinical technique, electrical data are collected from individual nerve cells. The target brain region emits unique electrical signals. At certain brain locations, during DBS surgery, additional electrical data that are generated in response to sound will be collected. Regions of the brain that have a decreased response to repeated sound (auditory gating) may be important DBS targets for improving thinking. The aims are (i) during DBS surgery, in addition to EEG, use microelectrodes in the brain to find brain regions, along the normal path to the DBS target, where auditory gating occurs and then (ii) determine if stimulation of the identified region(s) alters auditory gating measured by EEG. Also an additional aim (iii) is to measure electrical activity at the scalp with EEG to characterize auditory gating in patients before and after DBS surgery and also a healthy control population.
The objective of this prospective, multi site, single-arm study is to capture the efficacy of treatment using the ExAblate Transcranial System and to further demonstrate safety in medication-refractory tremor in patients with essential tremor (ET).
Stage 1 is a double-blind, proof-of-concept study designed to evaluate the safety, tolerability, pharmacokinetics (PK), and efficacy of SAGE-547 Injection in male and female participants with essential tremor in the upper limb. Stage 2 is an open-label arm designed to evaluate the safety, tolerability, PK, and effectiveness of SAGE-547 Injection at a higher dose than in Stage 1. Participants who completed Stage 1 were invited to participate in Stage 2.
The objective of this study is to characterize through spectral analysis intra-thalamic local field potentials (LFPs) recorded through implanted DBS leads during periods with and without tremor in patients suffering from severe essential tremor.
The purpose of this study is to examine effects (good and bad) of gamma knife radiosurgery for essential tremor. The gamma knife places a small lesion in the brain to suppress tremors.
The proposed study is to evaluate the effectiveness of ExAblate Transcranial MRgFUS as a tool for creating a unilateral lesion in the Vim thalamus or the globus pallidus (GPi) in patients with treatment-refractory symptoms of movement disorders.
The objective of this study is to assess the efficacy and safety of a single, kinematic-analysis-based intramuscular injection of NT 201, compared with placebo, in moderate to marked essential tremor of the upper limb.