Design and implementation of postoperative evaluation pipeline of deep brain stimulation by multimodality imaging_Journal of Biomedical Engineering

Authors：

 LUO Shouhua ¹ , NI Yangyang ¹ , ZHENG Huifen ² , CAO Shengwu ³

1. School of Biological Sciences and Medical Engineering, Southeast University, Nanjing 210096, P.R.China;
2. Department of Geriatric Neurology, Nanjing Brain Hospital Affiliated to Nanjing Medical University, Nanjing 210029, P.R.China;
3. Department of Neurosurgery, First Affiliated Hospital with Nanjing Medical University, Nanjing 210029, P.R.China;

Corresponding author：

LUO Shouhua, Email: luoshouhua@seu.edu.cn

Keywords：

multimodality imaging; deep brain stimulation; evaluation pipeline

DOI：

10.7507/1001-5515.201711055

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Deep brain stimulation (DBS) surgery is an important treatment for patients with Parkinson's disease in the middle and late stages. The accuracy of the implantation of electrode at the location of the nuclei directly determines the therapeutic effect of the operation. At present, there is no single imaging method that can obtain images with electrodes, nuclei and their positional relationship. In addition, the subthalamic nucleus is small in size and the boundary is not obvious, so it cannot be directly segmented. In this paper, a complete end-to-end DBS effect evaluation pipeline was constructed using magnetic resonance (MR) data of T1, T2 and SWI weighted by DBS surgery. Firstly, the images of preoperative and postoperative patients are registered and normalized to the same coordinate space. Secondly, the patient map is obtained by non-rigid registration of brain map and preoperative data, as well as the preoperative nuclear cluster prediction position. Then, a three-dimensional (3D) image of the positional relationship between the electrode and the nucleus is obtained by using the electrode path in the postoperative image and the result of the nuclear segmentation. The 3D image is helpful for the evaluation of the postoperative effect of DBS and provides effective information for postoperative program control. After analysis, the algorithm can achieve a good registration between the patient's DBS surgical image and the brain map. The error between the algorithm and the expert evaluation of the physical coordinates of the center of the thalamus is (1.590 ± 1.063) mm. The problem of postoperative evaluation of the placement of DBS surgical electrodes is solved.

Citation： LUO Shouhua, NI Yangyang, ZHENG Huifen, CAO Shengwu. Design and implementation of postoperative evaluation pipeline of deep brain stimulation by multimodality imaging. Journal of Biomedical Engineering, 2019, 36(3): 356-363. doi: 10.7507/1001-5515.201711055 Copy

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9.	Volkau I, Bhanu Prakash K N, Ananthasubramaniam A, et al. Extraction of the midsagittal plane from morphological neuroimages using the Kullback-Leibler's measure. Med Image Anal, 2006, 10(6): 863-874.
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1. Horn A, Kühn A A. Lead-DBS: a toolbox for deep brain stimulation electrode localizations and visualizations. Neuroimage, 2015, 107: 127-135.
2. 张芷齐, 耿馨佚, 徐欣, 等. 丘脑底核深部脑刺激三维空间结构可视化. 生物医学工程学杂志, 2016, 33(3): 405-412.
3. Videen T O, Campbell M C, Tabbal S D, et al. Validation of a fiducial-based atlas localization method for deep brain stimulation contacts in the area of the subthalamic nucleus. J Neurosci Methods, 2008, 168(2): 275-281.
4. da Silva N M, Rozanski V E, Silva Cunha J P. A 3D multimodal approach to precisely locate DBS electrodes in the Basal Ganglia brain region//2015 7th International IEEE/EMBS Conference on Neural Engineering (NER). Montpellier, France: IEEE, 2015: 292-295.
5. 郝斌. 丘脑底核核磁共振三维重建与脑深部电刺激治疗帕金森病的相关研究. 上海: 第二军医大学, 2008.
6. Ibanez L, Schroeder W, Ng L, et al. The ITK software guide. Comput Stat Data Anal, 2005, (21): 231-256.
7. 罗述谦, 李响. 基于最大互信息的多模医学图象配准. 中国图象图形学报, 2000, 5(7): 551-558.
8. Collins D L, Zijdenbos A P, Kollokian V, et al. Design and construction of a realistic digital brain phantom. IEEE Trans Med Imaging, 1998, 17(3): 463-468.
9. Volkau I, Bhanu Prakash K N, Ananthasubramaniam A, et al. Extraction of the midsagittal plane from morphological neuroimages using the Kullback-Leibler's measure. Med Image Anal, 2006, 10(6): 863-874.
10. Liu Yuan, Dawant B M. Automatic localization of the anterior commissure, posterior commissure, and midsagittal plane in MRI scans using regression forests. IEEE J Biomed Health Inform, 2015, 19(4): 1362-1374.
11. 安淑卿. 基于B样条的Talairach图谱与脑图像的配准与融合方法研究. 南京: 东南大学, 2008.
12. Rueckert D, Sonoda L I, Hayes C, et al. Nonrigid registration using free-form deformations: application to breast MR images. IEEE Trans Med Imaging, 1999, 18(8): 712-721.
13. Khan M F, Mewes K, Gross R E, et al. Assessment of brain shift related to deep brain stimulation surgery. Stereotact Funct Neurosurg, 2008, 86(1): 44-53.

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