Olfactory bulb circuits drive ketamine-enhanced high-frequency oscillations via kainate and GABAergic mechanisms.
Taisiia Prosvirova, Wiktoria Podolecka, Jacek Wrobel, Mark Jeremy Hunt
Neuropharmacology September 15, 2026 Peer reviewed DOI: 10.1016/j.neuropharm.2026.111012 via PubMed
Summary
Ketamine alters fast brain rhythms in male Wistar rats, increasing neocortical gamma power while suppressing gamma in the olfactory bulb (OB), where high-frequency oscillations (HFO) are enhanced. Infusions of certain glutamate receptor antagonists reduced HFO without affecting neocortical gamma, indicating different circuit mechanisms. Additionally, blocking GABA-A receptors decreased HFO power but increased gamma power, suggesting that fast inhibition is necessary for HFO expression.
Study at a glance
| Design | observational cohort |
|---|---|
| Population | freely moving male Wistar rats |
| Key finding | Ketamine increases neocortical gamma power and enhances HFO in the olfactory bulb while suppressing local gamma activity. |
Abstract
Ketamine produces rapid antidepressant effects accompanied by marked changes in fast brain rhythms. High-frequency oscillations (HFO; 130-180 Hz) are an increasingly recognized signature of ketamine across species. However, their relationship to classical gamma activity and their circuit-level organization remain unclear. Using simultaneous multiregion recordings in freely moving male Wistar rats, we show that ketamine differentially reorganizes fast oscillations across cortical networks: neocortical gamma power increased broadly, whereas the olfactory bulb (OB) showed suppressed gamma alongside robust, highly coherent HFO. Local OB infusion of the non-NMDA ionotropic glutamate receptor antagonists CNQX or NBQX suppressed ketamine-enhanced HFO both locally and in ventral striatum and prefrontal cortex without affecting neocortical gamma, indicating dissociable circuit mechanisms. Within the OB, the kainate receptor antagonist UBP310 markedly reduced HFO, whereas AMPA receptor blockade with IEM-1925 had minimal effect. Local GABA-A receptor blockade with bicuculline significantly reduced HFO power while increasing gamma power, demonstrating that intact fast inhibition is required for HFO expression. Based on these findings and known receptor kinetics, we propose that tonic kainate-dependent depolarization recruits interneurons to generate an inhibitory network rhythm, producing synchronized bursts that modulate mitral cell dendrites and drive HFO propagation through olfactory-limbic circuits.