High-order brain interactions during ketamine-induced state changes: A functional marker of response in late-life treatment-resistant depression?
Krisha Shah, Rubén Herzog, Alan C. Swann, Brittany O’brien, Rahul Balakrishnan, Sanjay J. Mathew, Nicholas Murphy
Translational Psychiatry July 4, 2026 Peer reviewed DOI: 10.1038/s41398-026-04212-1 via OpenAlex
Summary
Ketamine treatment in 30 late-life veterans with treatment-resistant depression resulted in significant changes in brain connectivity, particularly in the alpha-band, one hour after infusion. The strongest effects were observed in redundancy metrics, with a Cohen's d of 2.57. Improvements in depressive symptoms at Day 7 were linked to increased alpha-band redundancy at 24 hours. The study suggests that ketamine induces complex reorganization of brain interactions, which may relate to clinical outcomes.
Study at a glance
| Design | randomized controlled trial |
|---|---|
| Sample size | 30 |
| Population | late-life veterans with treatment-resistant depression |
| Key finding | Ketamine induced significant alterations in brain connectivity, with greater increases in alpha-band redundancy associated with improved depressive symptoms. |
Abstract
Ketamine is a fast-acting intervention for treatment-resistant depression (TRD), yet only a subset of patients show robust clinical response, and the underlying neural mechanisms remain unclear. High-order interactions (HOI) derived from multivariate information theory provide a framework for examining nonlinear dependencies among brain regions beyond pairwise connectivity. One such metric, the O-information, captures the balance between synergistic and redundant interactions across three or more variables. In this secondary analysis of a randomized, double-blind, midazolam-controlled trial (NCT02556606), we examined EEG-derived HOI in 30 late-life veterans with TRD following a single 40-minute intravenous infusion of ketamine (0.1, 0.25, 0.5 mg/kg; n = 18) or midazolam (0.03 mg/kg; n = 12). Resting state and mismatch negativity data were analyzed at baseline, 1 h, 24 h, and 7 d post-infusion. Ketamine induced temporally dynamic alterations in redundancy-dominant O-info, with maximal effects in the alpha-band at 1 h (Cohen's d = 2.57), attenuation at 24 h that shifted toward the theta-band, and partial resurgence in beta and gamma by Day 7. Linear mixed-effects modeling identified significant group effects across most band x metric families, with the strongest effects in alpha, beta, and gamma redundancy. Greater increases in 24-hour alpha-band redundancy were associated with greater improvement in depressive symptoms at Day 7 (β = 69.31, q = 0.05). HOI metrics also tracked acute dissociative states, with several 24-hour alpha and beta features remaining positively associated with symptom severity after correction. These findings extend prior HOI work in healthy samples to a controlled TRD cohort and suggest that ketamine induces temporally structured reorganization of higher-order brain interactions, with exploratory associations to clinical outcomes.