Department of Neurology, Emory University School of Medicine, Atlanta, GA, USA.
Acta Neurol Scand. 2012 Nov;126(5):336-43. doi: 10.1111/j.1600-0404.2012.01656.x. Epub 2012 Feb 24.
The most widely used and studied neurostimulation procedure for medically refractory epilepsy is vagus nerve stimulation (VNS) Therapy. The goal of this study was to develop a computational model for improved understanding of the anatomy and neurophysiology of the vagus nerve as it pertains to the principles of electrical stimulation, aiming to provide clinicians with a systematic and rational understanding of VNS Therapy.
Computational modeling allows the study of electrical stimulation of peripheral nerves. We used finite element electric field models of the vagus nerve with VNS Therapy electrodes to calculate the voltage field for several output currents and studied the effects of two programmable parameters (output current and pulse width) on optimal fiber activation.
The mathematical models correlated well with strength-duration curves constructed from actual patient data. In addition, digital constructs of chronic versus acute implant models demonstrated that at a given pulse width and current combination, presence of a 110-μm fibrotic tissue can decrease fiber activation by 50%. Based on our findings, a range of output current settings between 0.75 and 1.75 mA with pulse width settings of 250 or 500 μs may result in optimal stimulation.
The modeling illustrates how to achieve full or nearly full activation of the myelinated fibers of the vagus nerve through output current and pulse width settings. This knowledge will enable clinicians to apply these principles for optimal vagus nerve activation and proceed to adjust duty cycle and frequency to achieve effectiveness.
对于药物难治性癫痫,最广泛使用和研究的神经刺激程序是迷走神经刺激(VNS)疗法。本研究的目的是开发一种计算模型,以更好地理解迷走神经的解剖结构和神经生理学,以了解电刺激的原理,旨在为临床医生提供对 VNS 疗法的系统和理性理解。
计算模型允许研究外周神经的电刺激。我们使用 VNS 治疗电极的迷走神经有限元电场模型来计算几种输出电流的电压场,并研究了两个可编程参数(输出电流和脉冲宽度)对最佳纤维激活的影响。
数学模型与从实际患者数据构建的强度-持续时间曲线相关性良好。此外,慢性与急性植入模型的数字结构表明,在给定的脉冲宽度和电流组合下,存在 110μm 的纤维性组织可使纤维激活减少 50%。基于我们的发现,在 0.75 至 1.75mA 之间的一系列输出电流设置,以及 250 或 500μs 的脉冲宽度设置可能会导致最佳刺激。
该模型说明了如何通过输出电流和脉冲宽度设置实现迷走神经有髓纤维的完全或几乎完全激活。这些知识将使临床医生能够应用这些原则来实现迷走神经的最佳激活,并进一步调整占空比和频率以实现有效性。
