Deviation of DBS Recording Microelectrodes during Insertion Assessed by Intraoperative CT.

IF 1.9 4区医学 Q3 NEUROIMAGING

Stereotactic and Functional Neurosurgery Pub Date : 2023-01-01 DOI:10.1159/000528202

Nicolas Massager, Anthony Nguyen, Henri-Benjamin Pouleau, Sophie Dethy, Daniele Morelli

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引用次数: 1

Abstract

Introduction: Intraoperative microelectrodes recording with the Ben Gun microdrive system are often used during DBS surgery. An accurate location of these microelectrodes will directly influence the interest of this recording. We have studied the imprecision of implantation of these microelectrodes.

Methods: We have analyzed the stereotactic position of 135 microelectrodes implanted with the Ben Gun microdrive during DBS surgery of 16 patients with advanced Parkinson's disease. An intracranial CT was obtained and integrated to a stereotactic planification system. We recorded the stereotactic coordinates of the 5 microelectrodes inserted simultaneously in a cross-shape. The coordinates of each microelectrode were compared with coordinates of the other 4 electrodes inserted simultaneously with the Ben Gun and visible on the same iCT image. Thus, this procedure avoids errors from image fusion and from brain shift. We calculate (1) the three-dimensional Euclidian deviation of microelectrodes, (2) the deviation in X- and Y-axes on reconstructed probe's eye view MR images, and (3) the deviation from the 2-mm theoretical distance between the central electrode and 4 satellite microelectrodes.

Results: The median deviation was 0.64 mm in 3-D and 0.58 mm in 2-D probe's eye view. Satellite electrodes were located from the central electrode theoretically at 2.0 mm and practically within the range 1.9-2.1 mm, 1.5-2.5 mm, 1.0-3.0 mm, and 0.5-3.5 mm for, respectively, 9.3%, 53.7%, 88.0%, and 98.1%, thus highlighting the significant deviation from the theoretical distance. Position imprecisions were similar for the 4 satellite microelectrodes. The imprecision was similar in X-axis and Y-axes and statistically less in Z-axis. For bilateral implantation, the second implantation of the same patient was not associated with a greater risk of deviation of the microelectrodes than for the first side implanted.

Conclusion: A significant percentage of microelectrodes for MER can deviate substantially from their theoretical target during DBS procedures. An iCT can be used to estimate the potential deviation of microelectrodes and improve the interpretation of MER during the procedure.

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术中CT评估DBS记录微电极插入时的偏差。

术中微电极记录与Ben Gun微驱动系统在DBS手术中经常被使用。这些微电极的准确位置将直接影响记录的兴趣。我们研究了这些微电极植入的不精确性。方法:对16例晚期帕金森病患者DBS手术中植入Ben Gun微驱动器的135个微电极的立体定向位置进行分析。获得颅内CT并整合到立体定向平面化系统。我们记录了同时插入的5个微电极呈十字形的立体定向坐标。将每个微电极的坐标与与Ben Gun同时插入的其他4个电极的坐标进行比较，并在同一iCT图像上可见。因此，该方法避免了图像融合和脑偏移带来的错误。我们计算了(1)微电极的三维欧几里得偏差，(2)重建探头眼视MR图像的X轴和y轴偏差，以及(3)中心电极与4个卫星微电极之间2mm理论距离的偏差。结果:三维位差为0.64 mm，二维位差为0.58 mm。卫星电极距离中心电极的理论距离为2.0 mm，实际距离分别为1.9 ~ 2.1 mm、1.5 ~ 2.5 mm、1.0 ~ 3.0 mm和0.5 ~ 3.5 mm，分别为9.3%、53.7%、88.0%和98.1%，与理论距离偏差较大。4个卫星微电极的位置误差相似。不精度在x轴和y轴上相似，在z轴上统计上较小。对于双侧植入，同一患者的第二次植入与第一次植入相比，微电极偏离的风险并不大。结论:在DBS过程中，相当大比例的MER微电极可能会严重偏离其理论目标。iCT可用于估计微电极的潜在偏差，并在过程中改善对MER的解释。

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

Stereotactic and Functional Neurosurgery 医学-神经成像

CiteScore

3.80

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： ''Stereotactic and Functional Neurosurgery'' provides a single source for the reader to keep abreast of developments in the most rapidly advancing subspecialty within neurosurgery. Technological advances in computer-assisted surgery, robotics, imaging and neurophysiology are being applied to clinical problems with ever-increasing rapidity in stereotaxis more than any other field, providing opportunities for new approaches to surgical and radiotherapeutic management of diseases of the brain, spinal cord, and spine. Issues feature advances in the use of deep-brain stimulation, imaging-guided techniques in stereotactic biopsy and craniotomy, stereotactic radiosurgery, and stereotactically implanted and guided radiotherapeutics and biologicals in the treatment of functional and movement disorders, brain tumors, and other diseases of the brain. Background information from basic science laboratories related to such clinical advances provides the reader with an overall perspective of this field. Proceedings and abstracts from many of the key international meetings furnish an overview of this specialty available nowhere else. ''Stereotactic and Functional Neurosurgery'' meets the information needs of both investigators and clinicians in this rapidly advancing field.