Deep Brain Stimulation Electrode Deviations are Associated With Brain Stiffness Interfaces Measured by Magnetic Resonance Elastography.

IF 1.4 4区医学 Q3 CLINICAL NEUROLOGY

Operative Neurosurgery Pub Date : 2025-10-01 Epub Date: 2025-02-20 DOI:10.1227/ons.0000000000001523

Chengyuan Wu, Mahdi Alizadeh, Mary K Kramer, Matthew B Kroen, Robert Ziechmann, Feroze B Mohamed, Qianhong Wu, Curtis L Johnson

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引用次数: 0

Abstract

Background and objectives: The efficacy of deep brain stimulation (DBS) relies on accurate electrode placement. Unfortunately, electrode deviation poses a persistent problem, with most electrodes demonstrating some degree of bending. Although such bending does not always result in target deviation, an estimated 3% to 8% of patients still require revision surgery to address suboptimal electrode placement. DBS electrode deviation may occur at mechanical tissue interfaces, with denser internal capsule (IC) fibers being the most likely factor. Based on basic principles of physics, we hypothesized that the angle of a planned trajectory relative to tissue interfaces created by the IC induces deviation.

Methods: Ten patients with Parkinson disease scheduled for DBS surgery underwent preoperative 3T magnetic resonance elastography (MRE) using synchronized external vibrations to measure brain tissue stiffness. The IC stiffness interface (ICSI) was defined as the transition between the corona radiata and IC on MRE. The rate of transition was calculated as the change in stiffness across the ICSI. Postoperative computed tomography was used to measure target deviation . The angle of approach was calculated as the angle between the planned trajectory and the normal vector to the ICSI. Pearson correlations and t -tests were performed to evaluate associations between the angle of approach and target deviation.

Results: Twenty-one electrode trajectories were analyzed. The mean electrode deviation was 1.27 ± 0.63 mm. A significant correlation (r = 0.57, 95% CI [0.18, 0.80], P = .007) was found between angle of approach and target deviation, with larger angles associated with greater deviations. The rate of transition did not correlate with deviation ( P = .874).

Conclusion: MRE effectively quantifies in vivo brain tissue stiffness in Parkinson disease. The angle between the planned trajectory and the ICSI correlates with target deviation, supporting the hypothesis that tissue mechanics influence electrode bending. MRE has potential to quantify the likelihood of DBS electrode deviation, which could reduce revision surgeries and enhance clinical outcomes.

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脑深部刺激电极偏差与磁共振弹性成像测量的脑刚度界面相关。

背景与目的：脑深部电刺激（DBS）的疗效依赖于准确的电极放置。不幸的是，电极偏差造成了一个持久的问题，大多数电极表现出一定程度的弯曲。虽然这种弯曲并不总是导致目标偏差，但估计有3%至8%的患者仍然需要翻修手术来解决不理想的电极放置。DBS电极偏差可能发生在机械组织界面，与密集的内囊（IC）纤维是最有可能的因素。基于物理学的基本原理，我们假设一个计划的轨迹相对于组织界面的角度产生的IC诱导偏差。方法：10例帕金森病DBS手术患者术前采用同步外部振动3T磁共振弹性成像（MRE）测量脑组织刚度。集成电路刚度界面（ICSI）定义为电晕辐射与集成电路之间的过渡。过渡率是通过ICSI的刚度变化来计算的。术后计算机断层扫描测量靶偏差。进近角计算为计划弹道与ICSI法向量之间的夹角。采用Pearson相关和t检验来评价入路角度与目标偏差之间的关系。结果：分析了21个电极轨迹。平均电极偏差为1.27±0.63 mm。入路角度与目标偏差之间存在显著相关性（r = 0.57, 95% CI [0.18, 0.80], P = .007），角度越大，偏差越大。转移率与偏差无相关性（P = 0.874）。结论：MRE能有效量化帕金森病患者体内脑组织僵硬度。计划轨迹与ICSI之间的角度与目标偏差相关，支持组织力学影响电极弯曲的假设。MRE有可能量化DBS电极偏离的可能性，从而减少翻修手术并提高临床效果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Operative Neurosurgery Medicine-Neurology (clinical)

CiteScore

3.10

自引率

13.00%

发文量

530

期刊介绍： Operative Neurosurgery is a bi-monthly, unique publication focusing exclusively on surgical technique and devices, providing practical, skill-enhancing guidance to its readers. Complementing the clinical and research studies published in Neurosurgery, Operative Neurosurgery brings the reader technical material that highlights operative procedures, anatomy, instrumentation, devices, and technology. Operative Neurosurgery is the practical resource for cutting-edge material that brings the surgeon the most up to date literature on operative practice and technique