Modulation of motor cortical theta and gamma oscillations using phase-targeted, closed-loop optogenetic stimulation of local excitatory and inhibitory neurons

Theta and gamma oscillations are prominent features of cortical local field potentials (LFPs) and stimulation of the motor cortex at these frequencies can enhance motor learning. Phase-targeted closed-loop stimulation could provide a more precise and effective method to modulate these oscillations, particularly if stimulation parameters could harness the dynamics of the specific circuit mechanisms underpinning the generation of these activities.

To address this question, we defined the response of theta-and gamma-frequency oscillations in the motor cortex to closed-loop optogenetic stimulation of excitatory pyramidal neurons and inhibitory interneurons transfected with Channelrhodopsin-2 in awake, head-fixed RBP4-Cre (retinol-binding-protein-4) and PV-Cre (parvalbumin) mice, respectively. Phase-targeted blue-light pulses were delivered using the OscillTrack algorithm to track theta phase in the cortical LFP in real time and trigger stimulation at one of four target theta phases. Stimulation was delivered over a quarter of the target theta cycle, either as a single continuous pulse (“continuous” protocol) or three short pulses at gamma (75Hz) frequency (“gamma” protocol).

Stimulation of both neuron types, using either stimulation protocol, modulated theta power in a phase-dependent manner, with continuous stimulation of excitatory cells leading to stronger modulation. Phase-dependent amplification during stimulation of excitatory vs inhibitory neurons was offset by 90°, in line with predictions from computational models. Open-loop replay of previously recorded closed-loop stimulation patterns did not elicit the same phase-specific effects, demonstrating the necessity of the closed-loop interaction to produce these effects. Stimulation of pyramidal neurons using the gamma protocol amplified gamma power, independently of target theta phase.

These findings reveal phase-dependent amplification of cortical theta power can be induced by stimulation of local excitatory or inhibitory neurons, with a phase-offset likely resulting from circuit interactions. This approach can be used to inform the development of brain stimulation methods to modulate these activities more effectively in humans.