Stimulation Pattern Efficiency in Percutaneous Auricular Vagus Nerve Stimulation: Experimental Versus Numerical Data

Objective: Percutaneous electrical stimulation of the auricular vagus nerve (pVNS) is an electroceutical technology. The selection of stimulation patterns is empirical, which may lead to under-stimulation or over-stimulation. The objective is to assess the efficiency of different stimulation patterns with respect to individual perception and to compare it with numerical data based on in-silico ear models. Methods: Monophasic (MS), biphasic (BS) and triphasic stimulation (TS) patterns were tested in volunteers. Different clinically-relevant perception levels were assessed. In-silico models of the human ear were created with embedded fibers and vessels to assess different excitation levels. Results: TS indicates experimental superiority over BS which is superior to MS while reaching different perception levels. TS requires about 57% and 35% of BS and MS magnitude, respectively, to reach the comfortable perception. Experimental thresholds decrease from non-bursted to bursted stimulation. Numerical results indicate a slight superiority of BS and TS over MS while reaching different excitation levels, whereas the burst length has no influence. TS yields the highest number of asynchronous action impulses per stimulation symbol for the used tripolar electrode set-up. Conclusion: The comparison of experimental and numerical data favors the novel TS pattern. The analysis separates excitatory pVNS effects in the auricular periphery, as accounted by in-silico data, from the combination of peripheral and central pVNS effects in the brain, as accounted by experimental data. Significance: The proposed approach moves from an empirical selection of stimulation patterns towards efficient and optimized pVNS settings.

[2]  T. Beems,et al.  Overview of the Clinical Applications of Vagus Nerve Stimulation , 2010, Journal of clinical neurophysiology : official publication of the American Electroencephalographic Society.

[3]  J. Ellrich,et al.  Peripheral Nerve Stimulation Inhibits Nociceptive Processing: An Electrophysiological Study in Healthy Volunteers , 2005, Neuromodulation : journal of the International Neuromodulation Society.

[4]  J. Deuchars,et al.  Mechanisms underpinning sympathetic nervous activity and its modulation using transcutaneous vagus nerve stimulation , 2017, Experimental physiology.

[5]  M. Sood,et al.  Percutaneous electrical nerve field stimulation modulates central pain pathways and attenuates post-inflammatory visceral and somatic hyperalgesia in rats , 2017, Neuroscience.

[6]  Dominique M. Durand,et al.  MODELING OF MAMMALIAN MYELINATED NERVE FOR FUNCTIONAL NEUROMUSCULAR STIMULATION. , 1987 .

[7]  A. Burger,et al.  Transcutaneous nerve stimulation via the tragus: are we really stimulating the vagus nerve? , 2018, Brain Stimulation.

[8]  L S Alvord,et al.  Anatomy and orientation of the human external ear. , 1997, Journal of the American Academy of Audiology.

[9]  Simon Brenner,et al.  In-Silico Ear Model Based on Episcopic Images for Percutaneous Auricular Vagus Nerve Stimulation , 2018, 2018 EMF-Med 1st World Conference on Biomedical Applications of Electromagnetic Fields (EMF-Med).

[10]  Eugenijus Kaniusas,et al.  Depth profiles of the peripheral blood oxygenation in diabetics and healthy subjects in response to auricular electrical stimulation: Auricular vagus nerve stimulation as a potential treatment for chronic wounds , 2015, 2015 IEEE Sensors Applications Symposium (SAS).

[11]  J. Deuchars,et al.  Cardiovascular autonomic effects of transcutaneous auricular nerve stimulation via the tragus in the rat involve spinal cervical sensory afferent pathways , 2019, Brain Stimulation.

[12]  E. Ben-Menachem,et al.  Surgically implanted and non‐invasive vagus nerve stimulation: a review of efficacy, safety and tolerability , 2015, European journal of neurology.

[13]  J. Ellrich,et al.  Effects of short and prolonged transcutaneous vagus nerve stimulation on heart rate variability in healthy subjects , 2017, Autonomic Neuroscience.

[14]  V. Brown,et al.  Vagal nerve stimulation: a review of its applications and potential mechanisms that mediate its clinical effects , 2005, Neuroscience & Biobehavioral Reviews.

[15]  Jens Ellrich,et al.  Transcutaneous vagus nerve stimulation , 2011 .

[16]  Mark S. George,et al.  Short trains of transcutaneous auricular vagus nerve stimulation (taVNS) have parameter-specific effects on heart rate , 2018, Brain Stimulation.

[17]  G. Heinze,et al.  The Short- and Long-Term Benefit in Chronic Low Back Pain Through Adjuvant Electrical Versus Manual Auricular Acupuncture , 2004, Anesthesia and analgesia.

[18]  Stéphane Bonnet,et al.  Vagus nerve stimulation: state of the art of stimulation and recording strategies to address autonomic function neuromodulation , 2016, Journal of neural engineering.

[19]  M. Alexander,et al.  Principles of Neural Science , 1981 .

[20]  A. Schulze-Bonhage,et al.  Transcutaneous Vagus Nerve Stimulation (tVNS) for Treatment of Drug-Resistant Epilepsy: A Randomized, Double-Blind Clinical Trial (cMPsE02) , 2016, Brain Stimulation.

[21]  A. Ehlis,et al.  Far field potentials from brain stem after transcutaneous Vagus nerve stimulation: optimization of stimulation and recording parameters , 2009, Journal of Neural Transmission.

[22]  E. Fallen,et al.  Afferent vagal modulation Clinical studies of visceral sensory input , 2001, Autonomic Neuroscience.

[23]  Eugenijus Kaniusas,et al.  Autonomous nervous system modulation by percutaneous auricular vagus nerve stimulation: Multiparametric assessment and implications for clinical use in diabetic foot ulcerations , 2015, 2015 IEEE Sensors Applications Symposium (SAS).

[24]  P. Carmeliet,et al.  Common mechanisms of nerve and blood vessel wiring , 2005, Nature.

[25]  Robert K. Shepherd Neurobionics: The Biomedical Engineering of Neural Prostheses: The Biomedical Engineering of Neural Prostheses , 2016 .

[26]  E. Peuker,et al.  The nerve supply of the human auricle , 2002, Clinical anatomy.

[27]  H. Nakagawa,et al.  Low-level transcutaneous electrical vagus nerve stimulation suppresses atrial fibrillation. , 2015, Journal of the American College of Cardiology.

[28]  R. Raedt,et al.  Regional brain perfusion changes during standard and microburst vagus nerve stimulation in dogs , 2014, Epilepsy Research.

[29]  F Rattay,et al.  Ways to approximate current-distance relations for electrically stimulated fibers. , 1987, Journal of theoretical biology.

[30]  V. Napadow,et al.  Evoked pain analgesia in chronic pelvic pain patients using respiratory-gated auricular vagal afferent nerve stimulation. , 2012, Pain medicine.

[31]  Andreas Straube,et al.  Treatment of chronic migraine with transcutaneous stimulation of the auricular branch of the vagal nerve (auricular t-VNS): a randomized, monocentric clinical trial , 2015, The Journal of Headache and Pain.

[32]  S. Sator-Katzenschlager,et al.  The effects of auricular electroacupuncture on obesity in female patients--a prospective randomized placebo-controlled pilot study. , 2014, Complementary therapies in medicine.

[33]  J. Patrick Reilly,et al.  Electrostimulation : Theory, applications, and computational model , 2011 .

[34]  Françoise Tilotta,et al.  A study of the vascularization of the auricle by dissection and diaphanization , 2009, Surgical and Radiologic Anatomy.

[35]  Hong Jiang,et al.  The right side or left side of noninvasive transcutaneous vagus nerve stimulation: Based on conventional wisdom or scientific evidence? , 2015, International journal of cardiology.

[36]  Y. P. Guo,et al.  Pathological changes in the vagus nerve in diabetes and chronic alcoholism. , 1987, Journal of neurology, neurosurgery, and psychiatry.

[37]  A. Papanastassiou,et al.  High-frequency burst vagal nerve simulation therapy in a natural primate model of genetic generalized epilepsy , 2017, Epilepsy Research.

[38]  Wout Joseph,et al.  Current Directions in the Auricular Vagus Nerve Stimulation I – A Physiological Perspective , 2019, Front. Neurosci..

[39]  K. Tracey Reflex control of immunity , 2009, Nature Reviews Immunology.

[40]  E. Kaniušas Biomedical Signals and Sensors III: Linking Electric Biosignals and Biomedical Sensors , 2019 .

[41]  Luc Martens,et al.  Numerical modeling of percutaneous auricular vagus nerve stimulation: a realistic 3D model to evaluate sensitivity of neural activation to electrode position , 2017, Medical & Biological Engineering & Computing.

[42]  H. Wulf,et al.  Epidermal thickness at different body sites: relationship to age, gender, pigmentation, blood content, skin type and smoking habits. , 2003, Acta dermato-venereologica.

[43]  J. Patrick Reilly,et al.  Applied Bioelectricity: From Electrical Stimulation to Electropathology , 1998 .

[44]  Niels Kuster,et al.  A novel medical image data-based multi-physics simulation platform for computational life sciences , 2013, Interface Focus.

[45]  J. Fallon,et al.  Principles of Recording from and Electrical Stimulation of Neural Tissue , 2016 .

[46]  P. Pontes,et al.  Quantitative analysis of myelinic fibers in human laryngeal nerves according to age , 2015, Brazilian journal of otorhinolaryngology.

[47]  J. Kong,et al.  Effect of transcutaneous auricular vagus nerve stimulation on impaired glucose tolerance: a pilot randomized study , 2014, BMC Complementary and Alternative Medicine.

[48]  P. Roach,et al.  Modern biomaterials: a review—bulk properties and implications of surface modifications , 2007, Journal of materials science. Materials in medicine.

[49]  Wout Joseph,et al.  Current Directions in the Auricular Vagus Nerve Stimulation II – An Engineering Perspective , 2019, Front. Neurosci..

[50]  Jens Ellrich,et al.  Myelinated Axons in the Auricular Branch of the Human Vagus Nerve , 2016, Anatomical record.

[51]  Florian Zeman,et al.  The effect of transcutaneous vagus nerve stimulation on pain perception – An experimental study , 2013, Brain Stimulation.

[52]  E. Nam,et al.  Optimization of Transcutaneous Vagus Nerve Stimulation Using Functional MRI , 2017, Neuromodulation : journal of the International Neuromodulation Society.

[53]  M. Sood,et al.  Neurostimulation for abdominal pain-related functional gastrointestinal disorders in adolescents: a randomised, double-blind, sham-controlled trial. , 2017, The lancet. Gastroenterology & hepatology.

[54]  John P. Greenwood,et al.  Non-invasive Vagus Nerve Stimulation in Healthy Humans Reduces Sympathetic Nerve Activity , 2014, Brain Stimulation.

[55]  Eugenijus Kaniusas,et al.  New approaches in multi-punctual percutaneous stimulation of the auricular vagus nerve , 2013, 2013 6th International IEEE/EMBS Conference on Neural Engineering (NER).

[56]  Johannes Kornhuber,et al.  CNS BOLD fMRI Effects of Sham-Controlled Transcutaneous Electrical Nerve Stimulation in the Left Outer Auditory Canal – A Pilot Study , 2013, Brain Stimulation.

[57]  Luc Martens,et al.  Sensitivity Analysis of a Numerical Model for Percutaneous Auricular Vagus Nerve Stimulation , 2019, Applied Sciences.