Chen Lei, Li Nan, Gao Li, Yang Chen, Fang Wei, Wang Xue-Lian, Gao Guo-Dong
Department of Neurosurgery, TangDu Hospital, Fourth Military Medical University, Xi'an, Shaanxi, China.
Int J Neurosci. 2015 May;125(5):380-9. doi: 10.3109/00207454.2014.940524. Epub 2014 Jul 30.
Non-human primate models of deep brain stimulation (DBS) play an increasingly important role in the exploration of DBS mechanisms. The establishment and recognized usefulness of such models depend on the precise positioning of the stimulating targets and electrode implants. The optimal method of targeting remains controversial.
This paper described an improved stereotactic procedure that uses a self-developed adaptor to improve accuracy. This involved: (1) connecting clinical stereotactic devices with the skull of primates using a self-developed adaptor; (2) pre-operation targeting via magnetic resonance imaging (MRI); (3) target re-checking by microelectrode recording (MER); (4) DBS electrode implantation; (5) post-operative MRI verification of electrode placement and (6) positioning confirmation by DBS programming.
Use of the adaptor enabled clinical stereotactic surgery, pre-operative MRI targeting, microelectrode mapping and post-operative verification in primate DBS operations. Discrepancies between achieved and predetermined electrode position were around 0.6 mm. DBS programming improved the motor function of the hemiparkinsonism animals and decreased the numbers of rotation induced by apomorphine, indicating the precise positioning of the stimulating target and successful implanting of electrode using this method.
An improved stereotactic procedure was performed during a non-human primate DBS operation using a self-developed adaptor. The accuracy of DBS electrode implantation in non-human primates was improved with this method.
深部脑刺激(DBS)的非人灵长类动物模型在DBS机制探索中发挥着越来越重要的作用。此类模型的建立及其公认的实用性取决于刺激靶点和电极植入的精确定位。最佳的靶向方法仍存在争议。
本文描述了一种改进的立体定向程序,该程序使用自行开发的适配器来提高准确性。这包括:(1)使用自行开发的适配器将临床立体定向设备与灵长类动物的颅骨连接;(2)通过磁共振成像(MRI)进行术前靶向;(3)通过微电极记录(MER)重新检查靶点;(4)植入DBS电极;(5)术后通过MRI验证电极位置;以及(6)通过DBS编程确认定位。
在灵长类动物DBS手术中,使用该适配器实现了临床立体定向手术、术前MRI靶向、微电极测绘和术后验证。实际电极位置与预定位置之间的差异约为0.6毫米。DBS编程改善了偏侧帕金森病动物的运动功能,并减少了阿扑吗啡诱导的旋转次数,表明使用该方法刺激靶点定位精确且电极植入成功。
在非人灵长类动物DBS手术中,使用自行开发的适配器进行了改进的立体定向程序。该方法提高了非人灵长类动物DBS电极植入的准确性。
