基于模型的丘脑深部脑刺激闭环控制。

Frontiers in network physiology Pub Date : 2024-04-08 eCollection Date: 2024-01-01 DOI:10.3389/fnetp.2024.1356653
Yupeng Tian, Srikar Saradhi, Edward Bello, Matthew D Johnson, Gabriele D'Eleuterio, Milos R Popovic, Milad Lankarany
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引用次数: 0

摘要

导言:脑深部刺激(DBS)的闭环控制有利于对帕金森病(PD)和本质性震颤(ET)等各种神经系统疾病进行有效的自动治疗。手动(开环)DBS 编程完全基于临床观察,依赖于神经科医生的专业知识和患者的经验。开环 DBS 的持续刺激可能会缩短电池寿命并导致副作用。相反,闭环 DBS 系统使用反馈生物标志物/信号来跟踪患者症状的恶化(或改善)情况,与开环 DBS 系统相比具有多项优势。现有的闭环 DBS 控制系统没有纳入 DBS 或症状的生理机制,例如 DBS 如何调节突触可塑性的动态。方法:在这项工作中,我们提出了开发基于模型的 DBS 控制器的计算框架,其中神经模型可以描述 DBS 和神经活动之间的关系,而基于多项式的近似值可以估计神经和行为活动之间的关系。在我们的模型中,控制器以准实时的方式用于寻找能显著减轻症状恶化的 DBS 模式。通过使用所提出的计算框架,这些 DBS 模式可以在为患者提供 DBS 之前通过预测 DBS 的效果进行临床测试。我们将这一框架应用于仅根据肌电图(EMG)记录寻找治疗本质性震颤的最佳 DBS 频率的问题。腹侧中间核(Vim)是震颤的主要手术靶点,基于我们最近建立的网络模型,我们开发了神经模型模拟,其中 Vim-DBS 的生理机制与 EMG 信号的症状变化相关联。通过使用比例-积分-派生(PID)控制器,我们证明闭环系统可以跟踪肌电信号并调节 Vim-DBS 的刺激频率,从而使肌电图的功率达到预期的控制目标。结果与讨论我们证明,基于模型的 DBS 频率与临床研究中使用的频率非常一致。我们基于模型的闭环系统可以适应不同的控制目标,并有可能用于不同的疾病和个性化系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Model-based closed-loop control of thalamic deep brain stimulation.

Introduction: Closed-loop control of deep brain stimulation (DBS) is beneficial for effective and automatic treatment of various neurological disorders like Parkinson's disease (PD) and essential tremor (ET). Manual (open-loop) DBS programming solely based on clinical observations relies on neurologists' expertise and patients' experience. Continuous stimulation in open-loop DBS may decrease battery life and cause side effects. On the contrary, a closed-loop DBS system uses a feedback biomarker/signal to track worsening (or improving) of patients' symptoms and offers several advantages compared to the open-loop DBS system. Existing closed-loop DBS control systems do not incorporate physiological mechanisms underlying DBS or symptoms, e.g., how DBS modulates dynamics of synaptic plasticity. Methods: In this work, we propose a computational framework for development of a model-based DBS controller where a neural model can describe the relationship between DBS and neural activity and a polynomial-based approximation can estimate the relationship between neural and behavioral activities. A controller is used in our model in a quasi-real-time manner to find DBS patterns that significantly reduce the worsening of symptoms. By using the proposed computational framework, these DBS patterns can be tested clinically by predicting the effect of DBS before delivering it to the patient. We applied this framework to the problem of finding optimal DBS frequencies for essential tremor given electromyography (EMG) recordings solely. Building on our recent network model of ventral intermediate nuclei (Vim), the main surgical target of the tremor, in response to DBS, we developed neural model simulation in which physiological mechanisms underlying Vim-DBS are linked to symptomatic changes in EMG signals. By using a proportional-integral-derivative (PID) controller, we showed that a closed-loop system can track EMG signals and adjust the stimulation frequency of Vim-DBS so that the power of EMG reaches a desired control target. Results and discussion: We demonstrated that the model-based DBS frequency aligns well with that used in clinical studies. Our model-based closed-loop system is adaptable to different control targets and can potentially be used for different diseases and personalized systems.

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