Subanesthetic ketamine alters EEG signal complexity: Implications for treatment stratification in depression.

Journal of affective disorders  – October 01, 2025

Source: PubMed

Summary

Brain activity patterns may predict who will benefit from ketamine therapy for depression. By analyzing EEG recordings, researchers found that lower electrical complexity in specific brain regions before treatment indicated better outcomes. Ketamine temporarily increased overall brain signal complexity during infusion, while patients with depression showed unique responses that could serve as biomarkers for treatment success.

Abstract

Major depressive disorder, particularly its treatment-resistant form (TRD), poses significant treatment challenges. Ketamine, an N-methyl-d-aspartate receptor antagonist, has shown promise in rapidly alleviating depressive symptoms by influencing neuroplasticity and glutamatergic modulation, which are thought to influence brain activity complexity. In this placebo-controlled study, we examined the effects of subanesthetic doses of intravenous ketamine on EEG signal complexity in 24 MDD patients, 21 of whom had TRD. Treatment response was defined by a ≥ 33 % reduction in Montgomery-Åsberg Depression Rating Scale (MADRS) after ketamine administration. Patients underwent eyes-closed resting state EEG recording pre-, start-, end- and 24 h post-infusion, analyzed for temporospatial and spatiotemporal Lempel-Ziv complexity (LZCT and LZCS). Results indicated that ketamine significantly increased whole-brain LZCT during infusion compared to placebo (sodium chloride 0.9 %) (16.90 % vs. -4.84 %, 95 % CI 4.29 to 39.18, p = 0.017). Elevated LZCT at end-pre was associated with less short-term symptom improvement the following day. Conversely, lower pretreatment occipital LZCT (0.33 vs. 0.46, 95 % CI 0.007 to 0.26, p = 0.040) predicted a favorable response to ketamine, supported by a logistic regression model with an ROC area of 0.75. No significant changes were observed in LZCS, suggesting limited utility as a biomarker. In conclusion, occipital LZCT could serve as an effective predictive biomarker for ketamine's therapeutic effects in MDD, with implications for patients with TRD. This underscores the potential of EEG complexity measures in stratifying treatment and enhancing our understanding of the neural impacts of ketamine in depressive disorders.

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