Modélisation de l’interface entre une électrode multipolaire et un nerf périphérique : optimisation des courants pour la stimulation neurale sélective / Modeling the interface between a multipolar electrode and a peripheral nerve : optimization of currents for selective neural stimulation

Dali, Mélissa

21 November 2017

La stimulation électrique neurale, appliquée au système nerveux périphérique pour la restauration des fonctions motrices ou la neuromodulation, est une technologie en plein essor, en particulier la stimulation implantée avec des électrodes Cuff positionnées autour d’un nerf périphérique. Le principal frein au développement des systèmes de stimulation est la difficulté à obtenir la stimulation ou l’inhibition des fonctions cibles de manière précise et indépendante, c’est-à-dire, obtenir une sélectivité des fonctions. Les paramètres impliqués dans la sélectivité au sens large ne sont pas toujours intuitifs, et le nombre de degrés de libertés (choix de l’électrode, nombre de contacts, forme du pulse etc.) est important. Tester toutes ces hypothèses en expérimentation n’est pas faisable et inenvisageable dans le réglage des neuroprothèses en contexte clinique. La modélisation a priori nous permet d’établir des critères de choix, de déterminer les stratégies les plus efficaces et de les optimiser. Par ailleurs, un grand nombre d’études ont pu prévoir des stratégies de sélectivité inédites grâce à la modélisation, et validées a posteriori par l’expérimentation. Le schéma de calcul scientifique est composé de deux parties. On modélise, d’une part, la propagation du champ de potentiels électriques générés par les électrodes à l’intérieur d’un volume conducteur représentant le nerf (étude biophysique), et d’autre part l’interaction entre ce champ de potentiels et les neurones (réponse électrophysiologique). Notre première contribution propose une méthode originale de modélisation et d’optimisation de la sélectivité spatiale avec une électrode Cuff, sans connaissance a priori de la topographie de nerf. Partant de ce constat, nous déterminons de nouveaux critères, l’efficacité et la robustesse, complémentaires à la sélectivité, nous permettant de faire un choix entre des configurations multipolaires concurrentes. Ainsi, en fonction de la pondération de ces critères, nous avons développé un algorithme d’optimisation pour déterminer la configuration optimale en fonction de la zone choisie, du diamètre des fibres visées ainsi que de la durée de stimulation, pour un pulse type rectangulaire de référence. Des expérimentations sur modèle animal nous ont permis d’évaluer l’efficacité de la méthode et sa généricité. Ce travail est partie intégrante d’un projet plus vaste de stimulation du nerf vague (projet INTENSE), où l’une des applications concerne le traitement des troubles cardiaques. L’objectif est d’activer sélectivement une population spécifique de fibres nerveuses pour obtenir des effets plus ciblés conduisant à une thérapie améliorée, tout en diminuant les effets secondaires. La deuxième contribution consiste à combiner la sélectivité spatiale et la sélectivité au diamètre de fibre avec un modèle générique de nerf et une électrode Cuff à 12 contacts. L’utilisation d’une forme d’onde particulière (prépulse) combinée avec des configurations multipolaires permet d’activer des fibres d’un diamètre défini dans un espace ciblé. Les perspectives cliniques sont nombreuses, notamment sur la réduction de la fatigue liée à l’utilisation prolongée de la stimulation ou la diminution des effets secondaires. Dans le cadre du projet INTENSE, la seconde application liée à la stimulation du nerf vague vise le problème de l’obésité morbide. L’activation des axones cibles liés aux fonctions gastriques nécessite une quantité de charges conséquente. Plusieurs études suggèrent que les formes de pulse non rectangulaires peuvent activer les axones du système nerveux périphérique avec une quantité de charges réduite comparée à la forme de pulse rectangulaire de référence. Notre dernière contribution concerne l’étude expérimentale et de modélisation de ces formes d’ondes complexes. L’approche par modélisation, si elle est bien maîtrisée, apporte une analyse pertinente voire même indispensable au réglage clinique des neuroprothèses. / Neural electrical stimulation, applied to the peripheral nervous system for motor functions restoration or neuromodulation, is a thriving technology, especially implanted stimulation using Cuff electrodes positioned around a peripheral nerve. The main obstacle to the development of stimulation systems is the difficulty in obtaining the independent stimulation or inhibition of specific target functions (i.e. functional selectivity). The parameters involved in selectivity are not always intuitive and the number of degrees of freedom (choice of electrode, number of contacts, pulse shape etc.) is substantial. Thus, testing all these hypotheses in a clinical context is not conceivable. This choice of parameters can be guided using prior numerical simulations predicting the effect of electrical stimulation on the neural tissue. Numerous studies developed new strategies to achieve selectivity based on modeling results that have been validated a posteriori by experimental works. The computation scheme is composed of two parts : the modeling of the potential field generated by the electrodes inside a conductive medium representing the nerve on the one hand; and the determination of the interaction between this field of potentials and neurons on the other. Our first contribution is an original method of modeling and optimization of the spatial selectivity with a Cuff electrode, without prior knowledge of the nerve topography. Based on this observation, we determined new criteria, efficiency and robustness, complementary to selectivity, allowing us to choose between multipolar configurations. Thus, according to the weighting applied to these criteria, we developed an optimization algorithm to determine the optimal configuration as a function of the target zone, fiber diameter and the stimulation duration for a typical rectangular pulse. Experiments on animal model allowed us to evaluate the effectiveness and genericness of the method. This work was performed as part of a larger project on vagus nerve stimulation (INTENSE project) in which one of the applications focused on the treatment of cardiac disorders. The main objective was to selectively activate a specific population of nerve fibers to improve therapy and decrease side effects. In a second contribution, numerical simulations were used to investigate the combination of multipolar configurations and the prepulses technique, in order to obtain fiber recruitment in a spatially reverse order. The main objective was to achieve both spatial and fiber diameter selectivity. Expected clinical perspectives of this work are the reduction of fatigue related to a prolonged use of stimulation and the reduction of side effects. Within the framework of the INTENSE project, the second application investigated vagus nerve stimulation as a therapy for morbid obesity. Activation of target axons related to gastric functions requires a significant amount of charge injection. Several studies suggest that non-rectangular waveforms can activate axons of the peripheral nervous system with a reduced amount of charge compared to the reference rectangular pulse shape. Our last contribution focuses on the experimental study and the modeling of these complex waveforms. The modeling approach, if performed properly and while bearing in mind its limits, provides a relevant and even indispensable analysis tool for the clinical adjustment of neuroprostheses.

Modèles d'axones compartimentés

Stimulation neurale périphérique

Sélectivité

Stimulation du nerf vague

Electrode Cuff multipolaire

Nerve electrode models

Compartmentalized neuron model

Peripheral nerve stimulation

Selectivity

Vagus nerve stimulation

Multipolar Cuff electrode

Understanding factors affecting perception and utilization of artificial sensory location

Cuberovic, Ivana

28 January 2020

No description available.

Biomedical Engineering

Neurosciences

Rehabilitation

peripheral nerve stimulation

somatosensation

cuff electrodes

functional electrical stimulation

sensory feedback

neuroprosthetics, upper limb amputation

perception

artificial touch

limb loss rehabilitation

tactile sensation

computational modeling

Mapeamento metabólico cortical por espectroscopia funcional em sujeitos saudáveis submetidos a estimulação elétrica do nervo acessório

Bandeira, Janete Shatkoski

January 2017

A estimulação elétrica periférica (PES), que abrange diversas técnicas com respostas fisiológicas diversas, tem apresentado em alguns casos resultados clínicos promissores para o tratamento da dor e reabilitação clínica. No entanto, as respostas encontradas são heterogêneas, principalmente porque há uma falta de compreensão em relação ao seu mecanismo de ação. Neste estudo, buscamos avaliar os efeitos da PES através da medição da ativação cortical cerebral utilizando a espectroscopia funcional por infravermelho (fNIRS). A fNIRS é um método de imagem óptica funcional que avalia mudanças hemodinâmicas nas concentrações de hemoglobina oxigenada (HbO) e desoxigenada (HbR), relacionadas à atividade cortical. Nós hipotetizamos que a PES do nervo acessório espinal (ASN) pode promover a ativação do córtex motor (MC) e do córtex pré-frontal dorsolateral (DLPFC), relacionados ao processamento da dor. Quinze voluntários saudáveis receberam estimulação elétrica ativa e sham em um ensaio clínico randomizado cruzado. A resposta hemodinâmica à estimulação elétrica unilateral direita do nervo acessório com 10 Hz foi medida pela espectroscopia funcional por um sistema de 40 canais. A variação de HbO nas áreas corticais de interesse mostrou ativação do DLPFC direito (p=0,025) e do MOTOR esquerdo (p=0,042) no grupo ativo comparado com sham. Em relação ao DLPFC esquerdo (p=0,610) e ao MOTOR direito (p=0,154), não houve diferença estatística entre os grupos. Como na modulação top-down, a estimulação bottom-up do nervo acessório parece ativar as mesmas áreas corticais, relacionadas às dimensões sensório-discriminativas e afetivo-motivacionais da dor. Esses resultados fornecem evidência adicional para desenvolver e otimizar o uso clínico da estimulação elétrica periférica. / Peripheral electrical stimulation (PES), which encompasses several techniques with heterogeneous physiological responses, has shown in some cases remarkable outcomes for pain treatment and clinical rehabilitation. However, results are still mixed, mainly because there is a lack of understanding regarding its neural mechanisms of action. In this study, we aimed to assess its effects by measuring cortical activation as indexed by functional near infrared spectroscopy (fNIRS). fNIRS is a functional optical imaging method to evaluate hemodynamic changes in oxygenated (HbO) and de-oxygenated (HbR) blood hemoglobin concentrations in cortical capillary networks that can be related to cortical activity. We hypothesized that PES of accessory spinal nerve (ASN) can promote cortical activation of motor cortex (MC) and dorsolateral prefrontal cortex (DLPFC) pain processing cortical areas. Fifteen healthy volunteers received both active and sham ASN electrical stimulation in a crossover design. The hemodynamic response to unilateral right ASN burst electrical stimulation with 10 Hz was measured by a 40- channel fNIRS system. The effect of ASN electrical stimulation over HbO concentration in cortical areas of interest was observed through the activation of right- DLPFC (p=0.025) and left-MOTOR (p=0.042) in the active group but not in sham group. Regarding left-DLPFC (p=0.610) and right-MOTOR (p=0.174) there was no statistical difference between groups. As in non-invasive brain stimulation (NIBS) topdown modulation, bottom-up electrical stimulation to the accessory spinal nerve seems to activate the same critical cortical areas on pain pathways related to sensorydiscriminative and affective-motivational pain dimensions. These results provide additional mechanistic evidence to develop and optimize the effects of peripheral neural electrical stimulation.

Excitabilidade cortical

Nervo acessório

Eletroacupuntura

Dor crônica

Estimulacao eletrica

Cortical Activation (CA)

Clinical Trials NCT 03295370

Accessory Spinal Nerve (ASN)

Electroacupuncture (EA)

Electrical Nerve Stimulation (ENS)

Peripheral Nerve Stimulation (PNS)

Near infrared spectroscopy (NIRS)

Cortical Excitability (CE)

On the Role of, and Intervention in, Oxygen-Conserving Reflexes in Sudden Unexpected Death in Epilepsy

Ethan N Biggs (13199502)

04 August 2022

<p>Sudden unexpected death in epilepsy (SUDEP) is a fatal complication of epilepsy that kills 1̃2 of every 10,000 epileptic patients every year. SUDEP has proven difficult to study because it frequently occurs unobserved and cannot be predicted. What limited clinical data exists suggests that SUDEP occurs as a cardiorespiratory collapse immediately following a seizure. In this work, I explore how a group of autonomic reflexes termed collectively as “oxygen‐conserving reflexes (OCRs)” lead to sudden death when activated during seizures. I also demonstrate multiple physiological parallels between the OCR‐mediated deaths that I report and the clinical data on cases of human SUDEP. Additionally, I explore the neural pathway underlying OCRs, identify the carotid body as a potential target for intervention, and demonstrate the efficacy of electroceutical intervention in reducing the mortality risk of OCR activation during seizures. This work seeks to both offer a neural explanation for SUDEP as well as present a promising target and means for potential intervention.</p>

Systems physiology

Autonomic nervous system

Central nervous system

Peripheral nervous system

Sensory systems

Neurosciences not elsewhere classified

Biomedical instrumentation

Medical devices

Neural engineering

Analog electronics and interfaces

Electronic instrumentation

oxygen-conserving reflexes

diving reflex

mammalian diving reflex

chemoreflex

laryngeal chemoreflex

epilepsy

SUDEP

sudden death

SIDS

carotid body

carotid sinus

carotid sinus nerve

nerve stimulation

peripheral nerve stimulation

electrical nerve stimulation

Autonomic nervous system (ANS)

autonomic reflexes

pathophysiology

apnea

seizure