Litcius/Paper detail

Stable, interactive modulation of neuronal oscillations produced through brain-machine equilibrium

Colin G. McNamara, Max Rothwell, Andrew Sharott

2022Cell Reports38 citationsDOIOpen Access PDF

Abstract

Closed-loop interaction has the potential to regulate ongoing brain activity by continuously binding an external stimulation to specific dynamics of a neural circuit. Achieving interactive modulation requires a stable brain-machine feedback loop. Here, we demonstrate that it is possible to maintain oscillatory brain activity in a desired state by delivering stimulation accurately aligned with the timing of each cycle. We develop a fast algorithm that responds on a cycle-by-cycle basis to stimulate basal ganglia nuclei at predetermined phases of successive cortical beta cycles in parkinsonian rats. Using this approach, an equilibrium emerges between the modified brain signal and feedback-dependent stimulation pattern, leading to sustained amplification or suppression of the oscillation depending on the phase targeted. Beta amplification slows movement speed by biasing the animal's mode of locomotion. Together, these findings show that highly responsive, phase-dependent stimulation can achieve a stable brain-machine interaction that leads to robust modulation of ongoing behavior.

Topics & Concepts

StimulationModulation (music)Oscillation (cell signaling)NeuroscienceControl theory (sociology)SIGNAL (programming language)PhysicsBrain activity and meditationBrain stimulationComputer scienceBiological systemElectroencephalographyBiologyArtificial intelligenceGeneticsProgramming languageAcousticsControl (management)Neural dynamics and brain functionNeuroscience and Neural EngineeringNeurological disorders and treatments