Abstract
As ketamine is increasingly used as an effective antidepressant with rapid action, sustaining its short-lived efficacy over a longer period of time using a schedule of repeated injections appears as an option. An open question is whether repeated and single administrations would affect convergent neurocircuits. We used a combination of one of the most robust animal models of depression with high-field neuroimaging to perform a whole-brain delineation of functional mechanisms underlying ketamine’s effects. Rats from two genetic strains, depressive-like and resilient, received seven treatments of 10 mg/kg S-ketamine (N = 14 depressive-like, N = 11 resilient) or placebo (N = 12 depressive-like, N = 10 resilient) and underwent resting-state functional magnetic resonance imaging. Using graph theoretical models of brain networks, we compared effects of repeated ketamine with those of single administration from a separate dataset of our previous study. Compared to single treatment, repeated ketamine evoked strain-specific brain network randomization, resembling characteristics of the depressive-like strain and patients. Several affected regions belonged to the auditory, visual, and motor circuitry, hinting at possible cumulative side effects. Finally, when compared to saline, repeated ketamine affected only a few local topological properties and had no effects on global properties. In combination with the lack of clear differences compared to placebo, our findings point toward an inefficacy of ketamine’s long-term administration on brain topology, making questionable the postulated effect of repeated administration and being consistent with the recently reported absence of repeated ketamine’s antidepressant efficacy in several placebo-controlled studies.
Highlights
Ketamine has a rapid antidepressant action, which is, relatively short-lived, typically lasting 7 days[1,2,3]
In our previous study we investigated the long-term effects of a single administration of ketamine[16] using the negative cognitive (NC) model[17], one of the most robust and wellvalidated animal models of treatment-resistant depression (TRD)[18]
We suggested that ketamine mediates its pro-cognitive effects by normalizing the disrupted functional wiring within the habenula-thalamic-hippocampal cognitive circuitry, which might be a key imaging correlate of its long-term effect
Summary
Ketamine has a rapid antidepressant action, which is, relatively short-lived, typically lasting 7 days[1,2,3]. In our previous study we investigated the long-term effects of a single administration of ketamine[16] using the negative cognitive (NC) model[17], one of the most robust and wellvalidated animal models of treatment-resistant depression (TRD)[18]. It comprises breeding two genetic strains of rats, based on their susceptibility to develop stress-escape behavior, when exposed to electrical footshocks[17].
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