Center for Neurological Restoration, Cleveland Clinic, Cleveland, OH, USA.
Research Service, Louis Stokes Cleveland Veterans Affairs Medical Center, Cleveland, OH, USA.
Neuromodulation. 2020 Jul;23(5):572-581. doi: 10.1111/ner.13037. Epub 2019 Aug 28.
Despite the widespread use of spinal cord stimulation (SCS) for chronic pain management, its neuromodulatory effects remain poorly understood. Computational models provide a valuable tool to study SCS and its effects on axonal pathways within the spinal cord. However, these models must include sufficient detail to correlate model predictions with clinical effects, including patient-specific data. Therefore, the goal of this study was to investigate axonal activation at clinically relevant SCS parameters using a computer model that incorporated patient-specific anatomy and electrode locations.
We developed a patient-specific computer model for a patient undergoing SCS to treat chronic pain. This computer model consisted of two main components: 1) finite element model of the extracellular voltages generated by SCS and 2) multicompartment cable models of axons in the spinal cord. To determine the potential significance of a patient-specific approach, we also performed simulations with standard canonical models of SCS. We used the computer models to estimate axonal activation at clinically measured sensory, comfort, and discomfort thresholds.
The patient-specific and canonical models predicted significantly different axonal activation. Relative to the canonical models, the patient-specific model predicted sensory threshold estimates that were more consistent with the corresponding clinical measurements. These results suggest that it is important to account for sources of interpatient variability (e.g., anatomy, electrode locations) in model-based analysis of SCS.
This study demonstrates the potential for patient-specific computer models to quantitatively describe the axonal response to SCS and to address scientific questions related to clinical SCS.
尽管脊髓刺激(SCS)在慢性疼痛管理中被广泛应用,但它的神经调节作用仍未被充分理解。计算模型为研究 SCS 及其对脊髓内轴突通路的影响提供了一种有价值的工具。然而,这些模型必须包含足够的细节,以便将模型预测与临床效果相关联,包括患者特定的数据。因此,本研究的目的是使用一种包含患者特定解剖结构和电极位置的计算机模型来研究在临床相关 SCS 参数下的轴突激活。
我们为接受 SCS 治疗慢性疼痛的患者开发了一种患者特定的计算机模型。该计算机模型由两个主要部分组成:1)SCS 产生的细胞外电压的有限元模型,2)脊髓中轴突的多腔电缆模型。为了确定患者特定方法的潜在意义,我们还使用 SCS 的标准规范模型进行了模拟。我们使用计算机模型来估计在临床测量的感觉、舒适和不适阈值下的轴突激活。
患者特定模型和规范模型预测的轴突激活有显著差异。与规范模型相比,患者特定模型预测的感觉阈值估计值与相应的临床测量值更一致。这些结果表明,在基于模型的 SCS 分析中,考虑患者间变异性的来源(例如解剖结构、电极位置)非常重要。
本研究表明,患者特定的计算机模型具有定量描述 SCS 对轴突的反应以及解决与临床 SCS 相关的科学问题的潜力。
