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引用次数: 4
摘要
运用控制理论的思想。利用根轨迹法、Lyapunov的一阶近似定理、描述函数、Nyquist稳定性理论以及非线性反馈回路中抖动注入的等效非线性概念,探讨了脑深部刺激对病理神经振荡的猝灭现象。所使用的模型包含一个二阶不稳定的线性动力系统,在一个非线性的负反馈回路中,非线性包括与“符号平方”平行的线性增益。这模仿了阿里姆·路易斯·贝纳比德(Alim Louis Benabid)所说的“激发抑制通路,导致功能性抑制”。贝纳比德是脑深部刺激的伟大先驱。描述函数分析是用来给出一个非常接近的估计固有的,几乎正弦振荡,这是由深部脑刺激淬灭。推导了深部脑刺激的临界振幅(以伏特或毫安表示)与猝灭振荡所需的脉冲宽度分数之间的关系。通过最小化误差平方和,这与Benabid等人的实验结果尽可能接近。
Insights from control theory into deep brain stimulation for relief from Parkinson's disease
Using ideas from control theory. i.e., the root locus method, Lyapunov's theorem of the first approximation, the describing function, Nyquist stability theory and the concept of the equivalent nonlinearity associated with dither injection in a nonlinear feedback loop, the phenomenon of quenching of pathological neural oscillations by deep brain stimulation is explored. The model used contains a second order unstable, linear, dynamical system, in a negative feedback loop with a nonlinearity comprising a linear gain in parallel with a “signed square”. This mimics, what is referred to by Alim Louis Benabid, the great pioneer of deep brain stimulation as “excitation of inhibitory pathways that lead to functional inhibition”. Describing function analysis is used to give a very close estimate of the inherent, almost sinusoidal oscillation, which is quenched by deep brain stimulation. The relationship between the critical amplitude of deep brain stimulation (expressed either in volts or milliamps) and the fractional pulse width needed for quenching the oscillation is derived. This is fitted as closely as possible to experimental results by Benabid et al., by minimizing a sum of squared error index.
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