標題: | Fully automated tissue segmentation of the prescription isodose region delineated through the Gamma knife plan for cerebral arteriovenous malformation (AVM) using fuzzy C-means (FCM) clustering |
作者: | Peng, Syu-Jyun Lee, Cheng-chia Wu, Hsiu-Mei Lin, Chung-Jung Shiau, Cheng-Ying Guo, Wan-Yuo Pan, David Hung-Chi Liu, Kang-Du Chung, Wen-Yuh Yang, Huai-Che 電子工程學系及電子研究所 生醫電子轉譯研究中心 Department of Electronics Engineering and Institute of Electronics Biomedical Electronics Translational Research Center |
關鍵字: | Cerebral Arterio-Venous Malformation;Gamma knife radiosurgery;Radiotherapy;Radiation side-effect;Fuzzy c-means clustering |
公開日期: | 1-Jan-2019 |
摘要: | Background: Gamma knife radiosurgery (GKRS) is a common treatment for cerebral arterio-venous malformations (AVMs), particularly in cases where the malformation is deep-seated, large, or in eloquent areas of the brain. Unfortunately, these procedures can result in radiation injury to brain parenchyma. The fact that every AVM is unique in its vascular morphology makes it nearly impossible to exclude brain parenchyma from isodose radiation exposure during the formulation of a GKRS plan. Calculating the percentages of the various forms of tissue exposed to specific doses of radiation is crucial to understanding the clinical responses and causes of brain parenchyma injury following GKRS for AVM. Methods: In this study, we developed a fully automated algorithm using unsupervised classification via fuzzy c-means clustering for the analysis of T2 weighted images used in a Gamma knife plan. This algorithm is able to calculate the percentages of nidus, brain tissue, and cerebrospinal fluid (CSF) within the prescription isodose radiation exposure region. Results: The proposed algorithm was used to assess the treatment plan of 25 patients with AVM who had undergone GKRS. The Dice similarity index (SI) was used to determine the degree of agreement between the results obtained using the algorithm and a visually guided manual method (the gold standard) performed by an experienced neurosurgeon. In the nidus, the SI was (74.86 +/- 1.30%) (mean +/- standard deviation), the sensitivity was (83.05 +/- 11.91)%, and the specificity was (86.73 +/- 10.31)%. In brain tissue, the SI was (79.50 +/- 6.01)%, the sensitivity was (73.05 +/- 9.77)%, and the specificity was (85.53 +/- 7.13)%. In the CSF, the SI was (69.57 +/- 15.26)%, the sensitivity was (89.86 +/- 5.87)%, and the specificity was (92.36 +/- 4.35)%. Conclusions: The proposed clustering algorithm provides precise percentages of the various types of tissue within the prescription isodose region in the T2 weighted images used in the GKRS plan for AVM. Our results shed light on the causes of brain radiation injury after GKRS for AVM. In the future, this system could be used to improve outcomes and avoid complications associated with GKRS treatment. |
URI: | http://dx.doi.org/10.1016/j.nicl.2018.11.018 http://hdl.handle.net/11536/148953 |
ISSN: | 2213-1582 |
DOI: | 10.1016/j.nicl.2018.11.018 |
期刊: | NEUROIMAGE-CLINICAL |
Volume: | 21 |
Appears in Collections: | Articles |