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Neural population dynamics reveals disruption of spinal circuits’ responses to proprioceptive input during electrical stimulation of sensory afferents

Natalija Katic, Josep-Maria Balaguer, Oleg Gorskii, Natalia Pavlova, Lucy Liang, Jonathan Ho, Erinn M. Grigsby, Peter C. Gerszten, Д. Д. Карал-оглы, Dmitry Bulgin, Sergei N. Orlov, Elvira Pirondini, Pavel Musienko, Staniša Raspopović, Marco Capogrosso

2024Cell Reports11 citationsDOIOpen Access PDF

Abstract

While neurostimulation technologies are rapidly approaching clinical applications for sensorimotor disorders, the impact of electrical stimulation on network dynamics is still unknown. Given the high degree of shared processing in neural structures, it is critical to understand if neurostimulation affects functions that are related to, but not targeted by, the intervention. Here, we approach this question by studying the effects of electrical stimulation of cutaneous afferents on unrelated processing of proprioceptive inputs. We recorded intraspinal neural activity in four monkeys while generating proprioceptive inputs from the radial nerve. We then applied continuous stimulation to the radial nerve cutaneous branch and quantified the impact of the stimulation on spinal processing of proprioceptive inputs via neural population dynamics. Proprioceptive pulses consistently produce neural trajectories that are disrupted by concurrent cutaneous stimulation. This disruption propagates to the somatosensory cortex, suggesting that electrical stimulation can perturb natural information processing across the neural axis.

Topics & Concepts

NeuroscienceSensory systemProprioceptionStimulationPopulationBiological neural networkDynamics (music)BiologyMedicinePsychologyPedagogyEnvironmental healthNeural dynamics and brain functionEEG and Brain-Computer InterfacesNeuroscience and Neural Engineering