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

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 a DBS device called the Percept PC (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 Percept PC 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 movement, voice, and video recordings. A brief discontinuation experiment will be conducted after 6 months of stimulation, in which the stimulation will be turned off and patterns of LFP changes will be recorded. The entire study is expected to last about 5 years, parcellated into several study phases. All participants are required to live in the New York metropolitan area for the first several months of the study.

The main goal is to compare the antidepressant effects of psilocybin and ketamine in patients with TRD versus the antidepressant inactive substance midazolam. The primary endpoint will be the antidepressant effect on the Montgomery- Asberg Depression Rating Scale (MADRS) 24 hours after treatment, the key secondary endpoints being the duration of antidepressant effect, the number of responses and remissions, and the time to standard antidepressant treatment during 3 months of observation. The exploratory part of the study aims to monitor changes in the functional brain states using simultaneous EEG / fMRI, before treatment versus 1 day and 1 week after. Based on literature data and recent data from healthy volunteers who participated in a previous study with psilocybin, the investigator will correlate antidepressant effects of drugs (using psychometric scales and reactions to emotionally salient stimuli (eye tracker)) with entropy and functional connectivity measures. Finally the investigator will explore the role of plasmatic neurobiological biomarkers in depression (BDNF, prolactin, ACTH and oxytocin).

Background: People with TRD are often helped by electroconvulsive therapy (ECT). But ECT can affect memory and thinking. Researchers want to study a treatment called TEST that uses less electricity. Objective: To study the safety and feasibility of TEST and assess its antidepressant effects. Eligibility: Adults aged 25-64 with major depression that has not been relieved by current treatments. Design: Participants will be admitted to the NIH Clinical Center for 5 18 weeks over 2 3 treatment phases. Their medications may be adjusted. Participants will be interviewed about their depression, side effects, and other treatments they are receiving. They will complete questionnaires. They will give blood and urine samples. Their brain waves and heart rhythm will be recorded. They will take tests of memory, attention, mental functioning, and thinking. Participants will have magnetic resonance imaging (MRI) scans of the head and brain. They will lie on a table that slides in and out of the scanner. Pictures of brain chemicals will also be taken. They may complete tasks during the MRI. Participants will receive TEST and/or sham treatments. They may receive optional ECT. An intravenous catheter will be placed in an arm vein to receive general anesthesia. Two electrodes will be placed on the front of their head. An electric current will be passed from the ECT machine through the electrodes. For sham treatments, they will not receive the electric current. Their breathing, heart rate, brain function, blood pressure, and body movements will be measured. Participants will have 7 follow-up visits over 6 months. Visits can be done via telehealth. Participation will last for up to 42 weeks.

This experimental medicine study will examine the effects of a brief period (seven days) of 'add on' ebselen (SPI-105) treatment in patients with resistant depression to see if ebselen produces changes in emotional responses consistent with a potential clinical antidepressant effect. The investigators will also seek to confirm ebselen's mode of action on IMPase by measuring changes in a brain chemical called inositol, using a magnetic imaging method. Half of the participants will receive ebselen and the other half placebo.

The research study is being conducted to test whether using high dose spaced theta-burst rTMS (a form of transcranial magnetic stimulation) produces a significant reduction in depressive symptoms compared with sham. This project will recruit patients aged 18-70 with symptoms of bipolar depression who have failed (or not shown signs of improvement) after at least two prior treatments.

Treatment resistant depression remains a major problem for individuals and society. Surgical procedures may provide relief for some of these patients. The most frequently considered surgical approach is deep brain stimulation (DBS) of a part of the brain called the subcallosal cingulate region. However, the effectiveness and safety is not well established. The investigators will use a novel approach using advanced imaging technique (magnetic resonance tractography) to evaluate the feasibility and safety of this surgical approach. An innovative method for the definition of DBS target will be applied that redefines the concept of targeting as one of targeting a symptomatic network rather than a structural brain region using subject-based brain anatomy to define the target location. The correlation between imaging findings at baseline with the mood score changes at different time points of the study will be investigated.

Our overall hypothesis is that sleep slow-wave potentiation by propofol is a therapeutic pathway for enhancing slow wave sleep and alleviating treatment-resistant depression (TRD).

The goal of this clinical trial is to learn about the characteristics, identify early and intervene effectively in time in Treatment-Resistant Depression. The main questions are: • TRD is difficult to identify early and lacks objective detection indicators; • Existing treatment strategies for TRD are associated with side effects and high treatment resistance; • Current non-invasive brain stimulation therapy lacks precision. it aims to answer are: • Construct a multimodal TRD early identification model based on clinical characteristics, blood factors, functional magnetic resonance and brain electrophysiological indicators; • Develop non-invasive transcranial deep brain stimulation technology based on focused electric field; • In TRD patients, an individualized non-invasive transcranial deep electrical stimulation technology based on precise magnetic resonance targets and EEG phase guidance was constructed. Participants will:• be collected data multiple times including clinical symptoms, peripheral biology, functional magnetic resonance, electrophysiology and other clinical data before and after the intervention; • receive non-invasive transcranial deep brain stimulation or sham stimulation of different deep brain target points; • be collected EEG data while receiving stimulation. Researchers will • compare the biological characteristics of TRD, n-TRD patients and health controls to build early identification models and find potential spatial and temporal intervention targets dependent on TRD status; • verify the safety of non-invasive transcranial deep brain stimulation device in health controls; • compare TRD with different modes of stimulation to find the best treatment plan for non-invasive transcranial deep brain stimulation and verify safety.

Ketamine's efficacy as an antidepressant is now well established yet the mechanisms underlying its antidepressant effect are yet to be fully described. Work in the animal literature and research in humans is suggestive of specific effects on anhedonia and memory reconsolidation. In this study the investigators will further explore the effects of ketamine on learning and memory as well as measuring the associated changes at neural level in a sample of healthy volunteers. Participants will be assigned to receive ketamine or placebo and complete a set of tasks which will allow the investigators to quantify the effect of ketamine on learning about reward and punishment and memory for learned reward associations 24 hours after ketamine infusion. This study will help the investigators to understand the basis of ketamine's antidepressant effects and aid the development of new treatments for depression.

In this proposal the investigators will use an accelerated TMS protocol that concentrates the magnetic stimulation that would usually occur over 6 weeks into 10 treatment sessions per days, for 5 consecutive days in patient with treatment-refractory depression. This protocol will build on a previously published study demonstrating clinical efficacy of intermittent theta-burst stimulation (iTBS) on left dorsolateral prefrontal cortex (L-dlPFC) in a treatment refractory population.