Spatially Selective Retinal Ganglion Cell Activation Using Low Invasive Extraocular Temporal Interference Stimulation.

International journal of neural systems Pub Date : 2025-01-01 Epub Date: 2024-09-25 DOI:10.1142/S0129065724500667
Xiaoyu Song, Tianruo Guo, Saidong Ma, Feng Zhou, Jiaxin Tian, Zhengyang Liu, Jiao Liu, Heng Li, Yao Chen, Xinyu Chai, Liming Li
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Abstract

Conventional retinal implants involve complex surgical procedures and require invasive implantation. Temporal Interference Stimulation (TIS) has achieved noninvasive and focused stimulation of deep brain regions by delivering high-frequency currents with small frequency differences on multiple electrodes. In this study, we conducted in silico investigations to evaluate extraocular TIS's potential as a novel visual restoration approach. Different from the previously published retinal TIS model, the new model of extraocular TIS incorporated a biophysically detailed retinal ganglion cell (RGC) population, enabling a more accurate simulation of retinal outputs under electrical stimulation. Using this improved model, we made the following major discoveries: (1) the maximum value of TIS envelope electric potential ([Formula: see text] showed a strong correlation with TIS-induced RGC activation; (2) the preferred stimulating/return electrode (SE/RE) locations to achieve focalized TIS were predicted; (3) the performance of extraocular TIS was better than same-frequency sinusoidal stimulation (SSS) in terms of lower RGC threshold and more focused RGC activation; (4) the optimal stimulation parameters to achieve lower threshold and focused activation were identified; and (5) spatial selectivity of TIS could be improved by integrating current steering strategy and reducing electrode size. This study provides insights into the feasibility and effectiveness of a low-invasive stimulation approach in enhancing vision restoration.

利用低侵入性眼外时空干扰刺激进行空间选择性视网膜神经节细胞激活
传统的视网膜植入术涉及复杂的外科手术,需要进行侵入性植入。颞叶干扰刺激(TIS)通过在多个电极上传递频率差异较小的高频电流,实现了对大脑深部区域的非侵入式集中刺激。在本研究中,我们进行了硅学研究,以评估眼外干扰刺激作为一种新型视觉恢复方法的潜力。与之前发表的视网膜 TIS 模型不同,新的眼外 TIS 模型纳入了生物物理上详细的视网膜神经节细胞(RGC)群,从而能够更准确地模拟电刺激下的视网膜输出。利用这一改进模型,我们有了以下重大发现:(1) TIS 包络电势的最大值([公式:见正文]显示与 TIS 诱导的 RGC 激活密切相关;(2) 预测了实现聚焦 TIS 的首选刺激/回流电极(SE/RE)位置;(3) 就更低的 RGC 阈值和更集中的 RGC 激活而言,眼外 TIS 的性能优于同频率正弦波刺激(SSS);(4) 确定了实现较低阈值和集中激活的最佳刺激参数;以及 (5) 通过整合电流转向策略和缩小电极尺寸,可以提高 TIS 的空间选择性。这项研究深入探讨了低创刺激方法在增强视力恢复方面的可行性和有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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