脊髓神经解剖学的作用和硬膜外诱发脊髓反应的差异。

Danny V Lam, Justin Chin, Meagan K Brucker-Hahn, Megan Settell, Ben Romanauski, Nishant Verma, Aniruddha Upadhye, Ashlesha Deshmukh, Aaron Skubal, Yuichiro Nishiyama, Jian Hao, J Luis Lujan, Simeng Zhang, Bruce Knudsen, Stephan Blanz, Scott F Lempka, Kip A Ludwig, Andrew J Shoffstall, Hyun-Joo Park, Erika Ross Ellison, Mingming Zhang, Igor Lavrov
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引用次数: 0

摘要

背景:脊髓刺激(SCS)在治疗慢性疼痛和其他与感觉运动功能障碍有关的临床疾病方面具有多种优势。然而,人们对其基本机制仍不完全了解,包括电极位置与脊髓神经解剖的关系如何影响硬膜外脊髓记录(ESR)。为了描述这种关系,本研究在脊柱的不同解剖部位(包括椎间盘水平和与背根入口区相关的区域)施加了刺激:方法:通过手术将两个电极阵列植入猪的背侧硬膜外腔。刺激导线的位置应使最尾端的电极接触到胸椎椎节水平。术中利用锥形束计算机断层扫描(CBCT)图像精确确定硬膜外导线与脊柱的相对位置。植入脊髓的高分辨率显微CT成像和三维模型重建显示了硬膜外导线相对于周围神经解剖结构的精确定位和尺寸,包括脊髓背柱和腹柱的椎弓根。在一个单独的猪群中,植入的硬膜外导线用于 SCS 和记录诱发 ESR:硬膜外导线植入猪脊髓的三维模型重建结果表明,与背根入口区(DREZ)的背根小体相比,标准工业硬膜外刺激导线上的单个电极触点的尺寸有很大不同。据观察,在椎间段,如果横向定位,单个电极触点可覆盖 20-25% 的背根进入区。据估计,当电极触点位于中线时,其与椎间根入口区边缘的距离约为 0.75 毫米。此外,还观察到腹侧小根与背侧小根在此水平靠近和平行移动,然后分离到脊髓的各自一侧。在椎间盘水平进行阴极刺激与 "椎间盘外 "刺激(喙突 7 毫米)相比,记录到的 ESR 的特征(如振幅和形状)有相当大的变化,并在较低刺激阈值下诱发意外的运动激活。这种显著变化可能是由于附近腹侧根的影响。为进一步说明小根激活对背柱激活的影响,刺激导线从中线向侧方移出约 2.88 毫米,导致较低刺激阈值下 ESR 的诱发复合动作电位(ECAP)成分和肌电图(EMG)成分出现差异:本研究结果表明,记录的 ESR 中的 ECAP 和 EMG 成分会因刺激电极在脊柱解剖结构中的位置(如椎节间水平)的微小差异而不同。此外,刺激导线从中线向外侧位移亚厘米也会导致电生理指标发生显著变化。这项试验性研究的结果揭示了电极微小位移的重要性,它可导致 SCS 诱发反应发生显著变化。这些结果可为了解其潜在机制提供更多有价值的见解,并有助于优化未来的 SCS 相关应用。
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The role of spinal cord neuroanatomy and the variances of epidurally evoked spinal responses.

Background: Spinal cord stimulation (SCS) has demonstrated multiple benefits in treating chronic pain and other clinical disorders related to sensorimotor dysfunctions. However, the underlying mechanisms are still not fully understood, including how electrode placement in relation to the spinal cord neuroanatomy influences epidural spinal recordings (ESRs). To characterize this relationship, this study utilized stimulation applied at various anatomical sections of the spinal column, including at levels of the intervertebral disc and regions correlating to the dorsal root entry zone.

Method: Two electrode arrays were surgically implanted into the dorsal epidural space of the swine. The stimulation leads were positioned such that the caudal-most electrode contact was at the level of a thoracic intervertebral segment. Intraoperative cone beam computed tomography (CBCT) images were utilized to precisely determine the location of the epidural leads relative to the spinal column. High-resolution microCT imaging and 3D-model reconstructions of the explanted spinal cord illustrated precise positioning and dimensions of the epidural leads in relation to the surrounding neuroanatomy, including the spinal rootlets of the dorsal and ventral columns of the spinal cord. In a separate swine cohort, implanted epidural leads were used for SCS and recording evoked ESRs.

Results: Reconstructed 3D-models of the swine spinal cord with epidural lead implants demonstrated considerable distinctions in the dimensions of a single electrode contact on a standard industry epidural stimulation lead compared to dorsal rootlets at the dorsal root entry zone (DREZ). At the intervertebral segment, it was observed that a single electrode contact may cover 20-25% of the DREZ if positioned laterally. Electrode contacts were estimated to be ~0.75 mm from the margins of the DREZ when placed at the midline. Furthermore, ventral rootlets were observed to travel in proximity and parallel to dorsal rootlets at this level prior to separation into their respective sides of the spinal cord. Cathodic stimulation at the level of the intervertebral disc, compared to an 'off-disc' stimulation (7 mm rostral), demonstrated considerable variations in the features of recorded ESRs, such as amplitude and shape, and evoked unintended motor activation at lower stimulation thresholds. This substantial change may be due to the influence of nearby ventral roots. To further illustrate the influence of rootlet activation vs. dorsal column activation, the stimulation lead was displaced laterally at ~2.88 mm from the midline, resulting in variances in both evoked compound action potential (ECAP) components and electromyography (EMG) components in ESRs at lower stimulation thresholds.

Conclusion: The results of this study suggest that the ECAP and EMG components of recorded ESRs can vary depending on small differences in the location of the stimulating electrodes within the spinal anatomy, such as at the level of the intervertebral segment. Furthermore, the effects of sub-centimeter lateral displacement of the stimulation lead from the midline, leading to significant changes in electrophysiological metrics. The results of this pilot study reveal the importance of the small displacement of the electrodes that can cause significant changes to evoked responses SCS. These results may provide further valuable insights into the underlying mechanisms and assist in optimizing future SCS-related applications.

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