Temporal dynamics of the pharmacological MRI response to subanaesthetic ketamine in healthy volunteers: A simultaneous EEG/fMRI study
Rebecca McMillan, Anna Forsyth, Doug Campbell, Gemma Malpas, Elizabeth A. Maxwell, Juergen Dukart, Joerg F. Hipp, Suresh Muthukumaraswamy
Journal of Psychopharmacology January 21, 2019 DOI: 10.1177/0269881118822263 via OpenAlex
Summary
Ketamine infusion in healthy men increases blood-oxygen-level dependent signals across the cortex and decreases them in the subgenual anterior cingulate cortex, but the decrease is largely due to physiological noise, especially cardiac pulsatility, rather than neural activity. Modeling the pharmacological MRI response with a single time course misses the full range of neural dynamics; using simultaneously recorded electroencephalography power time series reveals distinct temporal responses to ketamine, though no EEG band correlated with the subgenual anterior cingulate cortex decrease.
Study at a glance
| Characteristics | Observational cohort Peer reviewed |
|---|---|
| Sample size | 30 |
| Population | Healthy male participants |
| Intervention | subanaesthetic intravenous ketamine infusion |
| Dose | subanaesthetic intravenous ketamine infusion |
| Topics | Ketamine |
| Keywords | Blood-oxygen-level dependent Electroencephalography Anterior cingulate cortex Magnetic resonance imaging |
| Citations | 23 |
| Key finding | Ketamine-induced decreases in subgenual anterior cingulate cortex blood-oxygen-level dependent signal are largely attributable to physiological noise, and a single temporal model does not capture the full spectrum of neural dynamics. |
Abstract
BACKGROUND: Pharmacological magnetic resonance imaging has been used to investigate the neural effects of subanaesthetic ketamine in healthy volunteers. However, the effect of ketamine has been modelled with a single time course and without consideration of physiological noise. AIMS: This study aimed to investigate ketamine-induced alterations in resting neural activity using conventional pharmacological magnetic resonance imaging analysis techniques with physiological noise correction, and a novel analysis utilising simultaneously recorded electroencephalography data. METHODS: Simultaneous electroencephalography/functional magnetic resonance imaging and physiological data were collected from 30 healthy male participants before and during a subanaesthetic intravenous ketamine infusion. RESULTS: Consistent with previous literature, we show widespread cortical blood-oxygen-level dependent signal increases and decreased blood-oxygen-level dependent signals in the subgenual anterior cingulate cortex following ketamine. However, the latter effect was attenuated by the inclusion of motion regressors and physiological correction in the model. In a novel analysis, we modelled the pharmacological magnetic resonance imaging response with the power time series of seven electroencephalography frequency bands. This showed evidence for distinct temporal time courses of neural responses to ketamine. No electroencephalography power time series correlated with decreased blood-oxygen-level dependent signal in the subgenual anterior cingulate cortex. CONCLUSIONS: We suggest the decrease in blood-oxygen-level dependent signals in the subgenual anterior cingulate cortex typically seen in the literature is the result of physiological noise, in particular cardiac pulsatility. Furthermore, modelling the pharmacological magnetic resonance imaging response with a single temporal model does not completely capture the full spectrum of neuronal dynamics. The use of electroencephalography regressors to model the response can increase confidence that the pharmacological magnetic resonance imaging is directly related to underlying neural activity.