Enrico Ravagli, Jeffrey Ardell, David Holder, Kirill Aristovich
{"title":"利用电阻抗断层扫描技术对迷走神经进行器官特异性选择刺激的组合袖带电极阵列。","authors":"Enrico Ravagli, Jeffrey Ardell, David Holder, Kirill Aristovich","doi":"10.3389/fmedt.2023.1122016","DOIUrl":null,"url":null,"abstract":"<p><p>Previously developed spatially-selective Vagus Nerve Stimulation (sVNS) allows the targeting of specific nerve fascicles through current steering in a multi-electrode nerve cuff but relies on a trial-and-error strategy to identify the relative orientation between electrodes and fascicles. Fast Neural Electrical Impedance Tomography (FN-EIT) has been recently used for imaging neural traffic in the vagus nerves of pigs in a cross-correlation study with sVNS and MicroCT fascicle tracking. FN-EIT has the potential for allowing targeted sVNS; however, up to now, stimulation and imaging have been performed with separate electrode arrays. In this study, different options were evaluated <i>in-silico</i> to integrate EIT and stimulation into a single electrode array without affecting spatial selectivity. The original pig vagus EIT electrode array geometry was compared with a geometry integrating sVNS and EIT electrodes, and with direct use of sVNS electrodes for EIT imaging. Modelling results indicated that both new designs could achieve image quality similar to the original electrode geometry in all tested markers (e.g., co-localisation error <100 µm). The sVNS array was considered to be the simplest due to the lower number of electrodes. Experimental results from testing evoked EIT imaging of recurrent laryngeal activity using electrodes from the sVNS cuff returned a signal-to-noise ratio similar to our previous study (3.9 ± 2.4 vs. 4.1 ± 1.5, <i>N</i> = 4 nerves from 3 pigs) and a lower co-localisation error (≈14% nerve diameter vs. ≈25%, <i>N</i> = 2 nerves from 2 pigs). Performing FN-EIT and sVNS on the same nerve cuff will facilitate translation to humans, simplify surgery and enable targeted neuromodulation strategies.</p>","PeriodicalId":12599,"journal":{"name":"Frontiers in Medical Technology","volume":"5 ","pages":"1122016"},"PeriodicalIF":0.0000,"publicationDate":"2023-04-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10149952/pdf/","citationCount":"0","resultStr":"{\"title\":\"A combined cuff electrode array for organ-specific selective stimulation of vagus nerve enabled by Electrical Impedance Tomography.\",\"authors\":\"Enrico Ravagli, Jeffrey Ardell, David Holder, Kirill Aristovich\",\"doi\":\"10.3389/fmedt.2023.1122016\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Previously developed spatially-selective Vagus Nerve Stimulation (sVNS) allows the targeting of specific nerve fascicles through current steering in a multi-electrode nerve cuff but relies on a trial-and-error strategy to identify the relative orientation between electrodes and fascicles. Fast Neural Electrical Impedance Tomography (FN-EIT) has been recently used for imaging neural traffic in the vagus nerves of pigs in a cross-correlation study with sVNS and MicroCT fascicle tracking. FN-EIT has the potential for allowing targeted sVNS; however, up to now, stimulation and imaging have been performed with separate electrode arrays. In this study, different options were evaluated <i>in-silico</i> to integrate EIT and stimulation into a single electrode array without affecting spatial selectivity. The original pig vagus EIT electrode array geometry was compared with a geometry integrating sVNS and EIT electrodes, and with direct use of sVNS electrodes for EIT imaging. Modelling results indicated that both new designs could achieve image quality similar to the original electrode geometry in all tested markers (e.g., co-localisation error <100 µm). The sVNS array was considered to be the simplest due to the lower number of electrodes. Experimental results from testing evoked EIT imaging of recurrent laryngeal activity using electrodes from the sVNS cuff returned a signal-to-noise ratio similar to our previous study (3.9 ± 2.4 vs. 4.1 ± 1.5, <i>N</i> = 4 nerves from 3 pigs) and a lower co-localisation error (≈14% nerve diameter vs. ≈25%, <i>N</i> = 2 nerves from 2 pigs). 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引用次数: 0
摘要
以前开发的空间选择性迷走神经刺激(sVNS)可通过多电极神经袖带中的电流转向锁定特定的神经束,但要确定电极和神经束之间的相对方位则需要试错策略。快速神经电阻抗断层扫描(FN-EIT)最近在一项与 sVNS 和 MicroCT 神经束跟踪的交叉相关研究中被用于猪迷走神经的神经交通成像。FN-EIT 有可能实现有针对性的 sVNS;但迄今为止,刺激和成像都是通过单独的电极阵列进行的。在这项研究中,对不同的方案进行了实验室评估,以便在不影响空间选择性的情况下将 EIT 和刺激整合到一个电极阵列中。将原始的猪迷走神经 EIT 电极阵列几何形状与整合 sVNS 和 EIT 电极的几何形状进行了比较,并与直接使用 sVNS 电极进行 EIT 成像进行了比较。建模结果表明,在所有测试标记物中,两种新设计都能达到与原始电极几何形状相似的成像质量(例如,共定位误差,N = 4 条神经,来自 3 头猪),共定位误差也较低(神经直径≈14% vs. ≈25%,N = 2 条神经,来自 2 头猪)。在同一神经袖带上进行 FN-EIT 和 sVNS 将促进向人类的转化,简化手术并实现有针对性的神经调控策略。
A combined cuff electrode array for organ-specific selective stimulation of vagus nerve enabled by Electrical Impedance Tomography.
Previously developed spatially-selective Vagus Nerve Stimulation (sVNS) allows the targeting of specific nerve fascicles through current steering in a multi-electrode nerve cuff but relies on a trial-and-error strategy to identify the relative orientation between electrodes and fascicles. Fast Neural Electrical Impedance Tomography (FN-EIT) has been recently used for imaging neural traffic in the vagus nerves of pigs in a cross-correlation study with sVNS and MicroCT fascicle tracking. FN-EIT has the potential for allowing targeted sVNS; however, up to now, stimulation and imaging have been performed with separate electrode arrays. In this study, different options were evaluated in-silico to integrate EIT and stimulation into a single electrode array without affecting spatial selectivity. The original pig vagus EIT electrode array geometry was compared with a geometry integrating sVNS and EIT electrodes, and with direct use of sVNS electrodes for EIT imaging. Modelling results indicated that both new designs could achieve image quality similar to the original electrode geometry in all tested markers (e.g., co-localisation error <100 µm). The sVNS array was considered to be the simplest due to the lower number of electrodes. Experimental results from testing evoked EIT imaging of recurrent laryngeal activity using electrodes from the sVNS cuff returned a signal-to-noise ratio similar to our previous study (3.9 ± 2.4 vs. 4.1 ± 1.5, N = 4 nerves from 3 pigs) and a lower co-localisation error (≈14% nerve diameter vs. ≈25%, N = 2 nerves from 2 pigs). Performing FN-EIT and sVNS on the same nerve cuff will facilitate translation to humans, simplify surgery and enable targeted neuromodulation strategies.