Open Access
Simultaneous decoding of cardiovascular and respiratory functional changes from pig intraneural vagus nerve signals
Author(s) -
Fabio Vallone,
Matteo Maria Ottaviani,
Francesca Dedola,
Annarita Cutrone,
Simone Romeni,
Adele Macri' Panarese,
Fabio Bernini,
Marina Cracchiolo,
Ivo Strauss,
Khatia Gabisonia,
Nikoloz Gorgodze,
Annalisa Mazzoni,
Fabio A. Recchia,
Silvestro Micera
Publication year - 2021
Publication title -
journal of neural engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.594
H-Index - 111
eISSN - 1741-2560
pISSN - 1741-2552
DOI - 10.1088/1741-2552/ac0d42
Subject(s) - decoding methods , computer science , functional electrical stimulation , neuroscience , vagus nerve stimulation , artificial intelligence , vagus nerve , algorithm , stimulation , psychology
Objective . Bioelectronic medicine is opening new perspectives for the treatment of some major chronic diseases through the physical modulation of autonomic nervous system activity. Being the main peripheral route for electrical signals between central nervous system and visceral organs, the vagus nerve (VN) is one of the most promising targets. Closed-loop VN stimulation (VNS) would be crucial to increase effectiveness of this approach. Therefore, the extrapolation of useful physiological information from VN electrical activity would represent an invaluable source for single-target applications. Here, we present an advanced decoding algorithm novel to VN studies and properly detecting different functional changes from VN signals. Approach . VN signals were recorded using intraneural electrodes in anaesthetized pigs during cardiovascular and respiratory challenges mimicking increases in arterial blood pressure, tidal volume and respiratory rate. We developed a decoding algorithm that combines discrete wavelet transformation, principal component analysis, and ensemble learning made of classification trees. Main results . The new decoding algorithm robustly achieved high accuracy levels in identifying different functional changes and discriminating among them. Interestingly our findings suggest that electrodes positioning plays an important role on decoding performances. We also introduced a new index for the characterization of recording and decoding performance of neural interfaces. Finally, by combining an anatomically validated hybrid neural model and discrimination analysis, we provided new evidence suggesting a functional topographical organization of VN fascicles. Significance . This study represents an important step towards the comprehension of VN signaling, paving the way for the development of effective closed-loop VNS systems.