大鼠神经性疼痛实验模型中的诱发复合动作电位(ECAP)控制闭环脊髓刺激。

Eline M Versantvoort, Birte E Dietz, Dave Mugan, Quoc C Vuong, Saimir Luli, Ilona Obara
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引用次数: 0

摘要

背景:脊髓刺激(SCS)的临床前模型缺乏客观的测量指标,无法提供可转化应用的脊髓刺激参数。诱发复合动作电位(ECAP)代表了背柱纤维激活的一种测量方法。这种测量方法近似于 SCS 在人体中诱发感觉的起始时间,在使用 ECAP 控制的闭环 (CL) SCS 系统时可提供有效的镇痛效果。因此,ECAP 可为临床前模型中的 SCS 剂量提供客观的替代指标,有助于更好地了解 SCS 机制并进一步应用于临床。本研究首次评估了在神经病理性疼痛实验模型中对行为自由的大鼠记录ECAPs并应用ECAP控制的CL-SCS的可行性:方法:成年雄性 Sprague-Dawley 大鼠(200-300 克)接受幸免神经损伤(SNI)。经计算机断层扫描或 X 光确认,在大鼠 T11-L3 硬膜外植入定制的六触点导线。使用专门设计的多通道系统记录ECAP,并以50 Hz 200 µs的频率应用ECAP控制的CL-SCS 30分钟。对背柱纤维对 SCS 的反应进行了鉴定,并评估了对机械和冷刺激的敏感性,以确定 ECAP 控制的 CL-SCS 的镇痛效果。采用方差分析(ANOVA)检验和 t 检验对 SNI 大鼠及其对照组以及刺激参数进行比较:记录到的ECAP显示出特征性的三相形态,SNI动物和对照组(SNI SCS-ON和假SCS-ON)的ECAP振幅(mV)随着施加的电流(mA)增加而增加。重要的是,在 ECAP 控制的 CL-SCS 中使用基于 ECAP 的 SCS 剂量,通过持续和受控地激活背柱纤维,显著降低了 SNI SCS-ON 动物的机械和冷过敏性。对诱发信号传导速度的分析证实了大的髓鞘纤维的参与:结论:在 ECAP 控制的 CL-SCS 中使用基于 ECAP 的 SCS 剂量可对神经病理性疼痛实验模型动物产生镇痛效果。这种方法可为不同物种之间的 SCS 参数转换提供更好的方法,从而增进对 SCS 作用机制的了解,进一步推动未来的临床应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evoked compound action potential (ECAP)-controlled closed-loop spinal cord stimulation in an experimental model of neuropathic pain in rats.

Background: Preclinical models of spinal cord stimulation (SCS) are lacking objective measurements to inform translationally applicable SCS parameters. The evoked compound action potential (ECAP) represents a measure of dorsal column fiber activation. This measure approximates the onset of SCS-induced sensations in humans and provides effective analgesia when used with ECAP-controlled closed-loop (CL)-SCS systems. Therefore, ECAPs may provide an objective surrogate for SCS dose in preclinical models that may support better understanding of SCS mechanisms and further translations to the clinics. This study assessed, for the first time, the feasibility of recording ECAPs and applying ECAP-controlled CL-SCS in freely behaving rats subjected to an experimental model of neuropathic pain.

Methods: Adult male Sprague-Dawley rats (200-300 g) were subjected to spared nerve injury (SNI). A custom-made six-contact lead was implanted epidurally covering T11-L3, as confirmed by computed tomography or X-ray. A specially designed multi-channel system was used to record ECAPs and to apply ECAP-controlled CL-SCS for 30 min at 50 Hz 200 µs. The responses of dorsal column fibers to SCS were characterized and sensitivity towards mechanical and cold stimuli were assessed to determine analgesic effects from ECAP-controlled CL-SCS. Comparisons between SNI rats and their controls as well as between stimulation parameters were made using omnibus analysis of variance (ANOVA) tests and t-tests.

Results: The recorded ECAPs showed the characteristic triphasic morphology and the ECAP amplitude (mV) increased as higher currents (mA) were applied in both SNI animals and controls (SNI SCS-ON and sham SCS-ON). Importantly, the use of ECAP-based SCS dose, implemented in ECAP-controlled CL-SCS, significantly reduced mechanical and cold hypersensitivity in SNI SCS-ON animals through the constant and controlled activation of dorsal column fibers. An analysis of conduction velocities of the evoked signals confirmed the involvement of large, myelinated fibers.

Conclusions: The use of ECAP-based SCS dose implemented in ECAP-controlled CL-SCS produced analgesia in animals subjected to an experimental model of neuropathic pain. This approach may offer a better method for translating SCS parameters between species that will improve understanding of the mechanisms of SCS action to further advance future clinical applications.

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