Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT06439797 |
| Other study ID # |
5040-18-SMC |
| Secondary ID |
|
| Status |
Completed |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
November 29, 2018 |
| Est. completion date |
July 9, 2020 |
Study information
| Verified date |
May 2024 |
| Source |
The Chaim Sheba Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
Background: ECT is an effective treatment indicated for patients with treatment resistant
depression. Although most patients display some degree of recovery, 32-52% do not respond or
remit at all. Considering the possible side effects and the considerably high cost of
treatment, it is important to identify sub-populations that would benefit the most from ECT.
In the current study we sought to identify predictive molecular markers in the blood of
depressed patients who are responsive to ECT.
Methods: Patients, ages 18-70, with the diagnosis of treatment-resistant depression will be
recruited. Participants will undergo psychiatric and psychological assessments, before
(baseline) and 12 weeks after ECT initiation. Assessments will include the Montgomery-Asberg
Depression Rating Scale (MADRAS), Clinical Global Improvement and Severity Scales (CGI-S,
CGI-I), Inventory of Depressive Symptomatology (IDS), and the State-Trait Anxiety Inventory
(STAI). Blood samples for serum and isolation of peripheral blood mononuclear cells
(PBMCs)will be collected at baseline and the 12-week end-of-treatment time points for
molecular analysis.
Description:
Despite impressive progress in our understanding of the molecular, cellular and circuit-level
correlates of major depression, the biological mechanisms that causally underlie this
disorder remain unclear, hindering the development of effective novel therapeutic procedures.
One possible reason for this situation is that almost all research in this area focuses on
the involvement of abnormalities in neuronal functioning, whereas the involvement of
non-neuronal brain cells, particularly microglia, has not been thoroughly investigated.
Recent studies indicate that impairments of the normal structure and function of microglia,
caused by either intense inflammatory activation or by decline and senescence of these cells,
can lead to depression and associated impairments in neuroplasticity and neurogenesis.
Accordingly, we argued that at least some forms of depression can be considered as
microgliopathies, in which either microglial activation or microglial decline and suppression
constitute the direct etiology of the depressive syndrome. This implies that depression
cannot be treated uniformly but should rather be treated by a personalized medical approach
based on the microglial status of the individual depressed patient (Yirmiya et al., TiNS,
2015). In the current proposal we aim to lay foundations for a thorough examination of the
personalized medical approach to depression, by examining the benefits of personalized
utilization of anti-depressive procedures based on screening for inflammatory/ microglial
markers, and by developing state-of-the-art tools for microglia manipulations that will allow
to directly examine the causal role of these cells in various animal models of depression.
We specifically aim to develop a personalized approach to the utilization of
electroconvulsive therapy (ECT), because our preliminary findings in a mouse model of
depression associated with impaired microglia functioning conclusively show that ECT-induced
microglia activation is causally related to the anti-depressive effects of this treatment. We
propose to utilize a translational approach, assessing the inflammatory/microglia-related
molecular factors (measured before treatment) that predict and contribute to the efficacy of
ECT in major depression patients. Specifically, we expect that ECT will be more beneficial in
patients with low expression of inflammatory/microglia-related genes, and thus based on the
findings of this experiment we shall be able to devise a molecular screening for the
suitability of ECT (and possibly other anti-depressant procedures) for the individual
depressed patient. Furthermore, we aim to establish the transcriptomic effects of ECT, with a
particular emphasis on inflammatory-related pathways. We expect differential transcriptomic
effects of ECT in patients with high vs. low baseline inflammatory status. The results should
significantly contribute to our knowledge regarding the molecular mechanisms that underlie
the therapeutic effects of ECT in specific sub-groups of depressed patients.
In parallel studies we aim to develop molecular tools for selective and region-specific
microglia activation or inhibition and to use these tools for: 1) examining the effects of
these manipulations in animal models of depression that involve either hyper-or hypo-activity
of microglia. 2) defining the causal role of microglia in mediating the anti-depressive
effects of ECT in a depression model associated with low microglia status. These studies
should complement the clinical part in humans, by providing definitive evidence for the
inverted U-shape pattern of relations between inflammatory status and depression, which
constitutes the basis for the personalized medical approach to this disease.
