Litcius/Paper detail

Cortico-subcortical β burst dynamics underlying movement cancellation in humans

Darcy A. Diesburg, Jeremy D.W. Greenlee, Jan R. Wessel

2021eLife51 citationsDOIOpen Access PDF

Abstract

Dominant neuroanatomical models hold that humans regulate their movements via loop-like cortico-subcortical networks, which include the subthalamic nucleus (STN), motor thalamus, and sensorimotor cortex (SMC). Inhibitory commands across these networks are purportedly sent via transient, burst-like signals in the β frequency (15-29 Hz). However, since human depth-recording studies are typically limited to one recording site, direct evidence for this proposition is hitherto lacking. Here, we present simultaneous multi-site recordings from SMC and either STN or motor thalamus in humans performing the stop-signal task. In line with their purported function as inhibitory signals, subcortical β-bursts were increased on successful stop-trials. STN bursts in particular were followed within 50 ms by increased β-bursting over SMC. Moreover, between-site comparisons (including in a patient with simultaneous recordings from SMC, thalamus, and STN) confirmed that β-bursts in STN temporally precede thalamic β-bursts. This highly unique set of recordings provides empirical evidence for the role of β-bursts in conveying inhibitory commands along long-proposed cortico-subcortical networks underlying movement regulation in humans.

Topics & Concepts

BurstingNeuroscienceThalamusSubthalamic nucleusInhibitory postsynaptic potentialMotor cortexMotor controlBiologyPsychologyDeep brain stimulationStimulationMedicineParkinson's diseaseDiseasePathologyNeurological disorders and treatmentsEEG and Brain-Computer InterfacesNeural dynamics and brain function