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脑信号和解剖结构能否优化帕金森病深部脑刺激的触点选择?

Can brain signals and anatomy refine contact choice for deep brain stimulation in Parkinson's disease?

作者信息

Xu San San, Lee Wee-Lih, Perera Thushara, Sinclair Nicholas C, Bulluss Kristian J, McDermott Hugh J, Thevathasan Wesley

机构信息

Bionics Institute, East Melbourne, Victoria, Australia.

Department of Neurology, Austin Hospital, Heidelberg, Victoria, Australia.

出版信息

J Neurol Neurosurg Psychiatry. 2022 May 19. doi: 10.1136/jnnp-2021-327708.

DOI:10.1136/jnnp-2021-327708
PMID:35589375
Abstract

INTRODUCTION

Selecting the ideal contact to apply subthalamic nucleus deep brain stimulation (STN-DBS) in Parkinson's disease is time-consuming and reliant on clinical expertise. The aim of this cohort study was to assess whether neuronal signals (beta oscillations and evoked resonant neural activity (ERNA)), and the anatomical location of electrodes, can predict the contacts selected by long-term, expert-clinician programming of STN-DBS.

METHODS

We evaluated 92 hemispheres of 47 patients with Parkinson's disease receiving chronic monopolar and bipolar STN-DBS. At each contact, beta oscillations and ERNA were recorded intraoperatively, and anatomical locations were assessed. How these factors, alone and in combination, predicted the contacts clinically selected for chronic deep brain stimulation at 6 months postoperatively was evaluated using a simple-ranking method and machine learning algorithms.

RESULTS

The probability that each factor individually predicted the clinician-chosen contact was as follows: ERNA 80%, anatomy 67%, beta oscillations 50%. ERNA performed significantly better than anatomy and beta oscillations. Combining neuronal signal and anatomical data did not improve predictive performance.

CONCLUSION

This work supports the development of probability-based algorithms using neuronal signals and anatomical data to assist programming of deep brain stimulation.

摘要

引言

在帕金森病中选择理想的触点来应用丘脑底核深部脑刺激(STN-DBS)既耗时又依赖临床专业知识。这项队列研究的目的是评估神经元信号(β振荡和诱发共振神经活动(ERNA))以及电极的解剖位置是否能够预测由长期、专业临床医生进行的STN-DBS编程所选择的触点。

方法

我们评估了47例接受慢性单极和双极STN-DBS的帕金森病患者的92个脑半球。术中在每个触点记录β振荡和ERNA,并评估解剖位置。使用简单排序方法和机器学习算法评估这些因素单独或组合起来如何预测术后6个月临床选择用于慢性深部脑刺激的触点。

结果

每个因素单独预测临床医生选择的触点的概率如下:ERNA为80%,解剖结构为67%,β振荡为50%。ERNA的表现明显优于解剖结构和β振荡。结合神经元信号和解剖数据并没有提高预测性能。

结论

这项工作支持开发基于概率的算法,利用神经元信号和解剖数据来辅助深部脑刺激的编程。

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