Active clinical trials for "Depressive Disorder, Treatment-Resistant"

Recent research in mice models of Alzheimer's disease (AD) has demonstrated that one hour per day of exposure to 40 Hz flickering light therapy can halt the disease's progression, and improve cognition and memory. Moreover, recent data suggest that 40 Hz light stimulation may induce neuroplasticity and reduce neuroinflammation. In this study, the investigators aim to evaluate the antidepressant effects of 40 Hz light stimulation in Major Depressive Disorder (MDD). Patients will be exposed to 40 Hz invisible spectral flickering light (active setting) or continuous non-flickering white light (sham setting) in a home setting for 1 hour each day.

To explore the effectiveness and safety of rTMS intervention with different targets in the left prefrontal cortex defined using the pBFS method, in adult patients with moderate and severe depressive disorder. Second, investigate the neural circuit that responds to the rTMS intervention using individualized brain image analysis, which may help to establish an effective target for the neuromodulation of patients with major depressive disorder.

INTRODUCTION Recent findings from three small studies (total n=59) suggest that three changes in repetitive Transcranial Magnetic Stimulation (rTMS) protocols, called the Stanford Neuromodulation Therapy (SNT) protocol, contribute to extreme high overall remission of 79% in patients with treatment resistant depression (TRD), whereas remission using a standard 10 Hz rTMS protocol is 25%. The improvement using the SNT protocol is achieved by combining 1) accelerated treatment with multiple sessions per day, 2) applying a higher overall pulse dose of stimulation, using intermittent Theta Burst Stimulation (iTBS), and 3) precise targeting of the region in the left dorsolateral prefrontal cortex (DLPFC), using functional MRI guided neuronavigation. OBJECTIVE To determine if the SNT protocol is more (cost-) effective compared to standard 10 Hz rTMS in patients with TRD, even though the number of pulses given in both protocols is equal, i.e., 90,000. STUDY DESIGN Multicenter randomized controlled trial comparing SNT with standard 10Hz rTMS with a follow-up of 25 weeks. STUDY POPULATION 108 Patients with TRD (no response to 2 or more evidence-based treatments). INTERVENTION 50 sessions using the SNT protocol in 5 days. The region of the left DLPFC most anticorrelated with the subgenual anterior cingulate cortex in each participant will be targeted based on subject-specific functional resting state MRI. COMPARISON 30 standard daily 10 Hz rTMS sessions in six weeks, targeting the left DLPFC based on standard measurement procedures of the skull. OUTCOME MEASURES Remission, based on the Hamilton depression rating scale Cost effectiveness, based on healthcare resource use Quality of life and positive mental health Tolerability and safety Relapse Description of opportunities and difficulties with regard to implementation SAMPLE SIZE The investigators will enrol 108 patients (α=0.05, power is 0.80) including adjustment for attrition. COST EFFECTIVENESS ANALYSIS SNT is faster and possibly more effective than 10Hz rTMS leading to a total cost reduction of 22 million each year considering less expensive healthcare, reduced illness duration and absence from work. TIME SCHEDULE Within 36 months, the investigators will recruit and treat 108 patients with TRD: each center will recruit 9 patients per year. After the last follow-up assessments, the investigators will finalise the study within 12 months and report the results.

This is a study that will recruit patients from the neurosurgery clinic and the regular TMS clinic. It's a smaller study designed to collect brain imaging pre-treatment and then use image guided TMS to treat patient with a one week "accelerated" rTMS protocol using the research TMS machine that is housed in Dr. Sean Nestor's lab. The idea is to examine whether severe treatment resistant depression has a different brain signature than less severe/TRD and whether we can get a therapeutic response from patients that would otherwise undergo neurosurgery or will ultimately undergo neurosurgery.

Heartbeat is controlled by the brain and is regular but flexible to change in response to environmental and internal stimuli. This feature is known as heart rate variability (HRV). Major depressive disorder (MDD) has been associated with diminished HRV and this is a reflection of abnormal brain function caused by MDD. Repetitive transcranial magnetic stimulation (rTMS) is a treatment that stimulates specific areas of the brain. The goal of this study is to test the hypothesis that rTMS induces changes in connectivity between the area of the brain stimulated with rTMS and deeper areas in the brain associated to heart rate regulation. 110 patients with TRD will be recruited and will undergo a concurrent TMS-fMRI session before receiving a course of iTBS to the L-DLPFC for 30 sessions at 120% rMT.

Of the estimated 30 million Americans who suffer from Major Depressive Disorder, approximately 10% are considered treatment resistant. Deep brain stimulation (DBS) to a region of the brain called the subcallosal cingulate (SCC) is an emerging strategy for treatment resistant depression (TRD), which involves placement of electrodes in a specific region of the brain and stimulating that area with electricity. This is believed to reset the brain network responsible for symptoms and results in a significant antidepressant response. A series of open-label studies have demonstrated sustained, long-term antidepressant effects in 40-60% of patients who received this treatment. A challenge to the effective dissemination of this fledgling treatment is the absence of biomarkers (objective, measureable indications of the state of the body and brain) to guide device placement and select stimulation parameters during follow-up care. By using an experimental prototype DBS device called the Summit RC+S (Medtronic, Inc) which has the ability to both deliver stimulation to and record electrical signals directly from the brain, this study aims to identify changes in local field potentials (LFPs), specific electrical signals that are thought to represent how the brain communicates information from one region to another, to see how this relates to DBS parameter settings and patient depressive symptomatology. The goal of this study is to study LFPs before and during active DBS stimulation to identify changes that correlate with the antidepressant effects of SCC DBS. The study team will recruit 10 patients with TRD and implant them with the Summit RC+S system. Participants will be asked to complete short questionnaires and collect LFP data twice daily for the first year of the study, as well as have weekly in person research procedures and assessments with the study team for up to one year. These include meetings with the study psychiatrist, psychologist, symptom ratings, and periodic EEGs (scalp brainwave recordings). A brief discontinuation experiment will be conducted after 6 months of stimulation, in which the device will be turned off and patterns of LFP changes will be recorded. The entire study is expected to last about 10 years, which is the expected life of the battery that powers the device. All participants are required to live in the New York metropolitan area for the first two years of the study.

Treatment resistant depression (TRD) is a frequent, debilitating condition mostly treated by antidepressants. Repeated magnetic transcranial stimulation (rTMS) has proven adjuvant efficacy in TRD in the acute phase of treatment with a very good tolerance and acceptability. Maintenance rTMS (mTMS) is a strategy consisting in adding regular single TMS sessions after response to an acute course in order to keep the benefit of initial treatment over several month or years. Demonstrating that rTMS is efficient to improve long-term prognosis and decrease economic burden would have a tremendous impact in clinical practice in psychiatry. Thus the investigator's aim is to analyze the long term impact of mTMS treatment on costs, but also quality of life and clinical issues.

Major depressive disorder (MDD), is a major medical and economic burden for today's society. About 30% of MDD patients develop treatment-resistant depression - TRD with the related sequelae in terms of worse prognosis. If several risk factors can be assessed readily on presentation, it can guide treatment planning and ultimately improve clinical outcomes. Currently, unlike other areas of medicine, poly-risk tools to facilitate this stratification in practice among patients with MDD are lacking but demanded in the era of personalised/precision medicine - a challenge that the project takes up. Ketamine - a glutamate N-methyl-d-aspartate (NMDA) receptor antagonist, is the first exemplary agent with rapid (within hours) antidepressant effects, even in TRD patients.Its mechanisms of actions (MoA) are still unclear but greatly demanded. So far, insights about ketamine's MoA come from preclinical animal studies but it's known that animal models have limited ability/effectiveness in mimicking the clinical complexity and were not subjected to sequential application of different treatments - a key requisite in humans to be defined as TRD. This ambitious inter/multidisciplinary project, has 3 goals: To develop a clinical risk stratification tool for predicting TRD development. To unravel ketamine's fast-acting antidepressant mechanisms of action (MoA) on mature neurons obtained from human induced pluripotent stem cells (iPSCs) obtained from (ketamine-responsive & non-responsive) patients with TRD. To give maximum visibility to the project and spreading its contents & findings to and in a way understood by all target groups variously implicated/interested in project research & innovation.

This study is designed to evaluate the safety and efficacy of exosome deployment with concurrent transcranial ultrasound in patients with refractory, treatment resistant depression, anxiety, and neurodegenerative dementia.

Healthy controls (HC) will be studied once to provide data needed to validate the virtual neuro-navigation system. All subjects will undergo a single MRI session and will then participate in an on-line neuro-navigation session in which various TMS coil positions will be recorded. The brain/head images will be provided to the programmer to permit development of the virtual neuro-navigation algorithm. Data from Yr1 will be used by the programmer as a training sample, and from Yr2 as a test sample.