Faculty of Medicine, University of Geneva, Geneva, Switzerland; Department of Neurosurgery, Geneva University Hospitals, Geneva, Switzerland.
Movement Disorders and Neuromodulation Section, Department of Neurology, Charité University Medicine, Berlin, Germany.
Neuroimage Clin. 2022;34:102971. doi: 10.1016/j.nicl.2022.102971. Epub 2022 Feb 25.
Microelectrode recordings (MERs) are often used during deep brain stimulation (DBS) surgeries to confirm the position of electrodes in patients with advanced Parkinson's disease. The present study focused on 32 patients who had undergone DBS surgery for advanced Parkinson's disease. The first objective was to confront the anatomical locations of intraoperative individual MERs as determined electrophysiologically with those determined postoperatively by image reconstructions. The second aim was to search for differences in cell characteristics among the three subthalamic nucleus (STN) subdivisions and between the STN and other identified subcortical structures. Using the DISTAL atlas implemented in the Lead-DBS image reconstruction toolbox, each MER location was determined postoperatively and attributed to specific anatomical structures (sensorimotor, associative or limbic STN; substantia nigra [SN], thalamus, nucleus reticularis polaris, zona incerta [ZI]). The STN dorsal borders determined intraoperatively from electrophysiology were then compared with the STN dorsal borders determined by the reconstructed images. Parameters of spike clusters (firing rates, amplitudes - with minimum amplitude of 60 μV -, spike durations, amplitude spectral density of β-oscillations) were compared between structures (ANOVAs on ranks). Two hundred and thirty one MERs were analyzed (144 in 34 STNs, 7 in 4 thalami, 5 in 4 ZIs, 34 in 10 SNs, 41 others). The average difference in depth of the electrophysiological dorsal STN entry in comparison with the STN entry obtained with Lead-DBS was found to be of 0.1 mm (standard deviation: 0.8 mm). All 12 analyzed MERs recorded above the electrophysiologically-determined STN entry were confirmed to be in the thalamus or zona incerta. All MERs electrophysiologically attributed to the SN were confirmed to belong to this nucleus. However, 6/34 MERs that were electrophysiologically attributed to the ventral STN were postoperatively reattributed to the SN. Furthermore, 44 MERs of 3 trajectories, which were intraoperatively attributed to the STN, were postoperatively reattributed to the pallidum or thalamus. MER parameters seemed to differ across the STN, with higher spike amplitudes (H = 10.64, p < 0.01) and less prevalent β-oscillations (H = 9.81, p < 0.01) in the limbic STN than in the sensorimotor and associative subdivisions. Some cells, especially in the SN, showed longer spikes with lower firing rates, in agreement with described characteristics of dopamine cells. However, these probabilistic electrophysiological signatures might become clinically less relevant with the development of image reconstruction tools, which deserve to be applied intraoperatively.
微电极记录 (MERs) 通常用于深部脑刺激 (DBS) 手术中,以确认患有晚期帕金森病患者的电极位置。本研究聚焦于 32 名接受 DBS 手术治疗晚期帕金森病的患者。第一个目标是比较术中根据电生理确定的单个 MER 位置与术后通过图像重建确定的位置。第二个目标是寻找 STN 三个亚区之间以及 STN 与其他确定的皮质下结构之间的细胞特征差异。使用在 Lead-DBS 图像重建工具包中实现的 DISTAL 图谱,每个 MER 位置在术后被确定,并归因于特定的解剖结构(感觉运动、联合或边缘 STN;黑质 [SN]、丘脑、网状极化核、未定带 [ZI])。然后将术中根据电生理学确定的 STN 背侧边界与通过重建图像确定的 STN 背侧边界进行比较。结构之间比较了尖峰簇的参数(放电率、幅度 - 最小幅度为 60μV - 、尖峰持续时间、β-振荡的幅度谱密度)(等级方差分析)。分析了 231 个 MER(34 个 STN 中有 144 个,4 个丘脑中有 7 个,4 个 ZI 中有 5 个,10 个 SN 中有 34 个,41 个其他部位中有 41 个)。发现与 Lead-DBS 获得的 STN 入口相比,电生理学上确定的 STN 入口的深度平均差异为 0.1mm(标准差:0.8mm)。所有在电生理上确定的 STN 上方记录的 12 个分析 MER 均被证实位于丘脑或未定带。所有电生理学上归因于 SN 的 MER 均被证实属于该核。然而,在电生理学上归因于腹侧 STN 的 6/34 个 MER 术后被重新归因于 SN。此外,在术中归因于 STN 的 3 个轨迹的 44 个 MER 术后被重新归因于苍白球或丘脑。MER 参数似乎在 STN 之间有所不同,边缘 STN 的尖峰幅度较高(H=10.64,p<0.01),β-振荡较少(H=9.81,p<0.01)。一些细胞,尤其是在 SN 中,表现出更长的尖峰和更低的放电率,这与描述的多巴胺细胞特征一致。然而,随着图像重建工具的发展,这些概率电生理特征可能变得不那么重要,这些工具值得在术中应用。
