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Towards enhanced functionality of vagus neuroprostheses through in silico optimized stimulation

Federico Ciotti, Robert John, Natalija Katic, Noemi Gozzi, Andrea Cimolato, Naveen Jayaprakash, Weiguo Song, Viktor Tóth, Theodoros P. Zanos, Stavros Zanos, Staniša Raspopović

2024Nature Communications18 citationsDOIOpen Access PDF

Abstract

Bioelectronic therapies modulating the vagus nerve are promising for cardiovascular, inflammatory, and mental disorders. Clinical applications are however limited by side-effects such as breathing obstruction and headache caused by non-specific stimulation. To design selective and functional stimulation, we engineered VaStim, a realistic and efficient in-silico model. We developed a protocol to personalize VaStim in-vivo using simple muscle responses, successfully reproducing experimental observations, by combining models with trials conducted on five pigs. Through optimized algorithms, VaStim simulated the complete fiber population in minutes, including often omitted unmyelinated fibers which constitute 80% of the nerve. The model suggested that all Aα-fibers across the nerve affect laryngeal muscle, while heart rate changes were caused by B-efferents in specific fascicles. It predicted that tripolar paradigms could reduce laryngeal activity by 70% compared to typically used protocols. VaStim may serve as a model for developing neuromodulation therapies by maximizing efficacy and specificity, reducing animal experimentation.

Topics & Concepts

NeuromodulationVagus nerve stimulationIn silicoStimulationVagus nerveNeurostimulationNeurosciencePopulationComputer scienceIn vivoMedicineBiologyBiochemistryGeneBiotechnologyEnvironmental healthVagus Nerve Stimulation ResearchEEG and Brain-Computer InterfacesNeuroscience of respiration and sleep
Towards enhanced functionality of vagus neuroprostheses through in silico optimized stimulation | Litcius