Active clinical trials for "Depressive Disorder, Major"

Placebo groups in clinical trials on depression show impressive improvements. Yet, there is little research on the mechanism underlying this effect. The aim of this study is to assess how patients' treatment expectations modulate the placebo treatment effects. We expect that patients' treatment expectation determines placebo responses and treatment outcomes, and that this expectation is influenced by the disorder explanations (information about the illness models) typically provided during the initial medical encounters that precede treatment. In the study we aim to manipulate depressed patients' expectations by providing two different clinician-delivered illness and treatment rationales (biological/ psychological). Patients will then receive placebo treatment (pharmacological/ psychological), that is either congruent or incongruent with the previously communicated treatment rationale. Hypotheses: Providing a treatment-congruent treatment rationale leads to a better outcome than providing treatment-incongruent rationales. Treatment-congruent explanations reduce the risk of side effect development, in particular in the medication arm. Inter-individual differences in the effect of provided treatment rationale are associated with pre-treatment experiences and expectations, depression severity and comorbid anxiety.

A randomized, controlled, prospective, multicenter, patient and rater blinded study with 2 arms: Treatment as Usual (TAU) and Predictix Guided Treatment (PGT). The study will compare the rate of treatment response and remission among both groups; TAU vs PGT.

Repetitive transcranial magnetic stimulation (rTMS) with theta bursts (i.e. TBS) of the dorsolateral prefrontal cortex (DLPFC) is an innovative treatment for major depressive disorder (MDD). Indeed, the U. S. Food and Drug Administration (FDA) has only recently approved TBS (in August 2018). However, fewer than 50% of patients show sufficient response to this treatment; markers for response prediction are urgently needed. Moreover, there is a lack of knowledge of the mechanism of action of TBS of the DLPFC. This is due to difficulties of directly measuring prefrontal stimulation effects, as compared to the stimulation of motor cortex and utilizing motor evoked potentials as direct readout. However, knowledge of immediate DLPFC modulation by TBS is necessary to extrapolate downstream effects on the neural and symptoms level. Thus, there is a need for research that aims to quantify the direct and immediate after-effects of TBS on DLPFC function. Most importantly, with regard to precision medicine, there is a need for research that explores the utility of immediate DLPFC reactivity to TBS for the prediction of antidepressant treatment response. There is common agreement that certain forms of rTMS inhibit or excite brain activity, respectively. However, evidence indicates that there is considerable individual variability in the brain responses to rTMS. Whether differences in individual DLPFC modulation by rTMS can be utilized as a predictive marker for treatment response remains to be investigated. This research program will exploit the combination of functional near-infrared spectroscopy (fNIRS) with brain stimulation. Concurrent TBS/fNIRS measurements will allow us to systematically investigate TBS-induced modulation of blood oxygenation as a proxy for induced brain activity changes. The findings from this study will (1) elucidate the immediate effects of excitatory and inhibitory TBS on prefrontal activity in TBS treatment-naïve patients with MDD and (2) validate the potential utility of TBS-induced brain modulation at baseline for the prediction of antidepressant response to four weeks of daily TBS treatment. Major depression is a severe mental disorder and is associated with considerable economic costs but adequate treatments are poorly explored. This research program will pave the way towards an affordable and easy-to-implement method for response prediction before treatment commencement. Thus, our research proposal has high potential to inform tailored treatment strategies, as envisaged in precision medicine.

Despite large-scale, nationwide efforts to better address suicidal behavior in Veterans at high risk, the development of interventions that target some of the key risk factors associated with suicide remains limited. This study aims to collect pilot data to test feasibility/acceptability of a novel adjunctive evidence-based cognitive remediation (CR) therapy with manualized "Bridging" sessions for transfer and practice of problem-solving strategies for real-world stressors, including those that trigger suicidal thoughts. This 10-week (20 session) Neuropsychological Educational Approach to Cognitive Remediation CR+Bridging telehealth intervention will be administered virtually via HIPPA-compliant services to 36 Veterans with major depressive disorder and a history of suicide attempt(s). Pre-, post-treatment, and follow-up assessments of neurocognitive, clinical, social, and real-world functioning also will be conducted. This study has potential for high public health impact and promise to help improve quality of life for Veterans at high risk for suicide.

Targeted and individualized treatments for mental health disorders are critically needed. Repetitive transcranial magnetic stimulation (rTMS) represents the front-line of new and innovative approaches to normalizing dysfunctional brain networks in those with mental illness. rTMS is FDA-approved for depression and obsessive-compulsive disorder with clinical trials underway for PTSD and addiction, among others. However, remission rates are suboptimal and ideal stimulation parameters are unknown. We recently completed a randomized, double blind clinical trial and a depression severity biomarker that predicts clinical outcome. The overarching goal of this study is to develop the first broadly generalizable platform for real-time biomarker monitoring and personalized rTMS treatment. We plan to recruit patients with medication-resistant depression and in perform a four-phase, cross-over, double-blind, placebo-controlled trial to 1) identify how standard and optimized rTMS patterns engage the depression severity biomarker, and 2) determine the dose-response of these rTMS patterns. Findings from this study will provide the basis for a double-blind, randomized clinical trial comparing rTMS optimized to the individual against standard rTMS.

The purpose of this study is to confirm binding of MIJ821 to the NR2B-containing NMDA receptors in the human brain and assess the PC-RO relationship over time using positron emission tomography (PET).

This study will examine if brain insulin resistance is a feature of depression in humans using magnetic resonance imaging (MRI) measures sensitive to brain insulin action. This study will examine adolescents, as depression onset commonly occurs during this age, and the impacts of cumulative medication exposure and other lifestyle-related confounds are also lower in this age group, improving our ability to understand the underlying biology.

Transcranial pulse stimulation (TPS) is a newly developed brain stimulation therapy from Austria & Germany with highly promising applicability in neuropsychiatric disorders. Major depressive disorder (MDD) is the world's leading cause of disability. Novel treatment approaches are urgently needed given that a significant fraction of patients does not sufficiently respond to standard antidepressant treatments. Our open-label pilot study using TPS in MDD indicates preliminary efficacy. However, experimental control is necessary to infer reliable scientific evidence for the efficacy of TPS. Here, we propose a randomized, double-blind, sham-controlled clinical trial to probe the utility of TPS as a modern antidepressant treatment.

Patients, physicians, and those who fund depression research are keenly interested in depression treatments that do not involve taking medications. One promising candidate treatment is transcranial direct current stimulation (tDCS), a low-cost technique that involves placing electrodes on specific scalp locations and using a 9-volt battery to cause a small amount of electricity to pass through parts of the brain. Depending on the direction of electrical flow, tDCS can make brain cells (neurons) more likely or less likely to generate their own electrical signals. When evaluated as a treatment, tDCS is typically done in daily sessions over a period of two weeks. One of the challenges of tDCS is to work out the best possible positioning of electrodes and direction of electricity flow to gradually cause lasting changes in brain activity in ways that might be expected to improve depression. To address this challenge, the investigators are using MRI to take pictures of the brain during tDCS. This data will help us better understand the short-term effects of tDCS in depression and help us learn how to customize future treatments to cause a lasting beneficial response. Patients with depression between the ages of 20-55 years are eligible to take part in this research. Potential participants will undergo: An assessment to confirm eligibility. This will take place over a secure videoconference call lasting no more than 3 hours. Two in-person study visits lasting 30 min and 2-1/2 hours respectively. In the first visit, the investigators will use the MRI to take a picture of the brain and head structure to determine appropriate locations for placing the tDCS electrodes at the start of the second visit. Following electrode placement, an MRI scan will be performed to take pictures of the brain during tDCS. Depending on the study arm, Participants may receive 'active' or 'sham' tDCS. The 'sham' condition is identical to the 'active' tDCS in every way except that it involves minimal tDCS and is designed to help rule out effects unrelated to the administered tDCS electricity. Participants may also be asked to perform a mental task during MRI. All participants will be compensated $150 + parking upon completion of all study-visits.

Depression is a highly prevalent condition characterized by persistent low mood, energy, and activity that can affect one's thoughts, mood, behavior, and sense of well-being. Repetitive transcranial magnetic stimulation (rTMS), a non-invasive neuromodulatory technique, is an effective treatment for depression when targeting the dorsolateral prefrontal cortex (dlPFC) of the central executive network (CEN). However, remission rates are suboptimal and individual methods to target the dlPFC are lacking. In this study, we will enroll 50 patients with major depression and in a single rTMS 'dose,' prospective, randomized, double-blind, cross-over design will assess whether rTMS targeted to an individual's central executive network (CEN) assessed by single pulse TMS can enhance network modulation. If successful, this work will lead to a clinical rTMS trial comparing this personalized targeting approach against standard rTMS.