卷積類神經網路應用於脊椎之影像校準

Ho-Hsuan Lu; 呂和軒

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/76974

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	顏炳郎(Ping-Lang Yen)
dc.contributor.author	Ho-Hsuan Lu	en
dc.contributor.author	呂和軒	zh_TW
dc.date.accessioned	2021-07-10T21:42:06Z	-
dc.date.available	2021-07-10T21:42:06Z	-
dc.date.copyright	2021-03-03
dc.date.issued	2021
dc.date.submitted	2021-02-05
dc.identifier.citation	Victor Kosmopoulos, PhD, and Constantin Schizas, MD, PD, FRCS. 2007. Pedicle Screw Placement Accuracy A Meta-analysis. SPINE Volume 32, Number 3, pp E111–E120 P. Markelj, et al. 2012. A review of 3D/2D registration methods for image-guided interventions. Medical Image Analysis 16 . 642–661. J. B. Antoine Maintz and Max A. Viergeverm. 1998. Viergever. A Survey of Medical Image Registration. Med. Image Anal. 2 (1), 1–36. I. Marintschev, F. Gras, et al. 2010. Navigation of vertebro-pelvic fixations based on CT-fluoro matching. European Spine Journal, Vol.19, pp. 1921-1927 . M. Shoham, et al. 2006. Bone Mounted Miniature Robotic System for Spine Surgery . IEEE International Conference on Biomedical Robotics and Biomechatronics, Vol.19, pp.917- 920 . M.Avanzo, P.Romanell. 2009.Spinal radiosurgery: technology and clinical outcomes .Neurosurgical Review, Vol.32, pp.1-13. Aviv Hurvitz , Leo Joskowicz. Registration of a CT-like atlas to fluoroscopic X-ray images using intensity correspondences. 2008. Int J CARS. John K. Houten,et al. 2012. Clinical Assessment of Percutaneous Lumbar Pedicle Screw Placement Using the O-Arm Multidimensional Surgical Imaging System. Neurosurgery, Volume 70, Issue 4, April 2012, Pages 990–995. J. Canny. A computational approach to edge detection. 1986. IEEE Transactions on Pattern Analysis and Machine Intelligence, Vol. 8, No. 6. H. Livyatan, Z. Yaniv, L. Joskowicz. 2003. Gradient-based 2-D/3-D rigid registration of fluoroscopic X-ray to CT. IEEE Transactions on Medical Imaging, vol. 22, no. 11, pp. 1395-1406. P. J. Besl, N. D. McKay. A Method for Registration of 3-D Shapes. 1992. IEEE Transactions on Pattern Analysis and Machine Intelligence, Vol. 14, No. 2, pp. 239-256 Penny, G. P.,et al. A Comparison of Similarity Measures for Use in 2-D–3-D Medical Image Registration. Aug. 1998. IEEE Trans. Med. Imag., vol.17, no.4, pp. 586-595. Andrea Valsecchi, et al. 2013. Evolutionary intensity-based medical image registration: a review. Current Medical Imaging Reviews, 9(4), pp. 283-297. Pascale G, Troiano L. A Niche Based Genetic Algorithm for Image Registration. In Ninth International Conference on Enterprise Information Systems (ICEIS 2007). 2007. pp. 342–7. Justin Vinci. 2007. BrainLAB ExacTrac image guidance. LSU Master's Theses. R. Y. Tsai. 1987. A versatile camera calibration technique for high-accuracy 3-D machine vision based metrology using off-the-shelf TV cameras and lenses. IEEE J. Robot. Autom., vol. RA-3, no. 4, pp. 323-344, Aug. Berthold K.P. Horn. 2000. Tsai’s camera calibration method revisited. Levoy, M.. 1990. Efficient Ray Tracing of Volume Data. ACM Trans. Graph., vol. 9 ,No. 3. Ameet Kumar Jain,et al. 2004.FTRAC—A robust fluoroscope tracking fiducial. Med. Phys. 32 10. Gouthami Chintalapani1, et al. 2008. CTREC: C-arm tracking and reconstruction using elliptic curves. In: Proceedings of the CVPR IEEE, pp 596–602. Shoham et al. 2014. ROBOTIC METHOD FOR USE WITH ORTHOPEDIC INSERTS. United States Patent. M. J. Daly,et al.2008. Geometric calibration of a mobile C-arm for intraoperative cone-beam CT. Med. Phys. 355(5), May 2008. Schumann, S., X. Dong, M. Puls, L. P. Nolte, and G. Zheng. Calibration of C-arm for orthopedic interventions via statistical model-based distortion correction and robust phantom detection. In: ISBI, 2012, pp. 1204–1207 Zhenzhou Shao,et al. 2014. Robust and Fast Initialization for Intensity-Based 2D/3D Registration. Mechatronics and Embedded System. A Uneri, et al. 2017. Intraoperative evaluation of device placement in spine surgery using known-component 3D–2D image registration. Phys. Med. Biol. 62 3330. Thomas Yi,et al. 2018. Robotic drill guide positioning using known-component 3D–2D image registration. J. Med. Imag. 5(2), 021212 (2018). 張志儒.2016.電腦輔助系統用於脊椎後融合骨釘植入手術之臨床應用評估.中央大學機械系碩士論文。碩士論文。國立中央大學機械工程研究所。 Daniel B. Russakoff,et al. 2003. Evaluation of Intensity-Based 2D-3D Spine Image Registration Using Clinical Gold-Standard Data. Conference: Biomedical Image Registration, Second International Workshop, WBIR 2003, Philadelphia, PA, USA, June 23-24, 2003. Isador H. Lieberman,et al. 2006. BONE-MOUNTED MINIATURE ROBOTIC GUIDANCE FOR PEDICLE SCREW AND TRANSLAMINAR FACET SCREW PLACEMENT: PART I—TECHNICAL DEVELOPMENT AND A TEST CASE RESULT. Neurosurgery. 2006 Sep;59(3):641-50; discussion 641-50. M. Lefranc J. Peltier. 2016. Evaluation of the ROSA™ Spine robot for minimally. EXPERT REVIEW OF MEDICAL DEVICES, 2016 VOL. 13, NO. 10, 899–906 invasive surgical procedures. Julio Alvarez-Gomez,et al.Intraoperative Registration of 2D C-arm Images with Preoperative CT Data in Computer Assisted Spine Surgery: Motivation to Use Convolutional Neural Networks for Initial Pose Generator. Current Directions in Biomedical Engineering \| Volume 5: Issue 1. Lisa Kausch.et al. 2020.Toward automatic C‑arm positioning for standard projectionsin orthopedic surgery. International Journal of Computer Assisted Radiology and Surgery (2020) 15:1095–1105. Mai Bui,et al. 2017.X-ray PoseNet: 6 DoF Pose Estimation for Mobile X-ray Devices. IEEE Winter Conference on Applications of Computer Vision. David Kugler et al. 2018. i3PosNet: Instrument Pose Estimation from X-Ray in temporal bone surgery. Computer Vision and Pattern Recognition (cs.CV); Image and Video Processing. Alex Kendall,et al. 2015.PoseNet: A Convolutional Network for Real-Time 6-DOF Camera Relocalization. Proceedings of the IEEE International Conference on Computer Vision (ICCV), 2015, pp. 2938-2946. Eric Wu,et al. 2019. RESIDUAL ATTENTION BASED NETWORK FOR HAND BONE AGE ASSESSMENT. 2019 IEEE 16th International Symposium on Biomedical Imaging (ISBI 2019).Venice, Italy, April 8-11, 2019. Morteza Heidari,et al. 2020. Improving the performance of CNN to predict the likelihood of COVID-19 using chest X-ray images with preprocessing algorithms. International Journal of Medical Informatics 144 (2020) 104284. Berthold K. P. Horn. 1986. Closed-form solution of absolute orientation using unit Quaternions. Vol. 4, No. 4/April 1987/J. Opt. Soc. Am. A. Christophe Lohou,et al. Augmented Digitally Reconstructed Radiographs of Aortic Dissection CTA Images. 2012. 5th International Conference on BioMedical Engineering and Informatics (BMEI 2012). I.M.J. van der Bom,et al.2011.Evaluation of optimization methods for intensity-based 2D-3D registration in x-ray guided interventions. Proceedings of SPIE - The International Society for Optical Engineering 7962:796223. A´ lvaro Bertelsen and Diego Borro. An ITK-Based Framework for 2D-3D Registration with Multiple Fixed Images. 2011. Yoshito Otake,et al.2012. Intraoperative Image-based Multiview 2D/3D Registration for Image-Guided Orthopaedic Surgery: Incorporation of Fiducial-Based C-Arm Tracking and GPU-Acceleration. IEEE TRANSACTIONS ON MEDICAL IMAGING, VOL. 31, NO. 4, APRIL 2012.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/76974	-
dc.description.abstract	影像校準的技術對於電腦輔助手術為不可或缺的一環，如何將術前到術中的影像進行校準，成為了醫生在手術定位中不可或缺的資訊。影像校準的困難度在於將不同空間場域、不同解析度甚至是不同類型的影像完成對位。本研究將影像校準應用於脊柱手術，透過術前電腦斷層影像(Computed Tomography : CT)與術中C型臂X光透視機(C-arm)影像。2D-3D影像校準的流程會涉及C-arm初始姿態定位與影像校準。而影像校準包括了數位式影像重建X光攝影(Digital Reconstructed Radiography : DRR)、相似度比對、最佳化收斂步驟。本研究第一部分會使用校正版做姿態估測，再對CT脊椎做影像校準。在姿態估測AP面與CRA45面投影誤差與3D點回推誤差都可以達到1mm之內，而lateral面則誤差較大。因此使用AP面與CRA45面接續進行影像校準，誤差為0.5896 mm。最後使用Cone-beam CT做驗證，誤差為1.2976 mm，可落在脊椎手術的安全範圍內(2mm內)。本研究第二部分為使用卷積類神經網路(Convolutional Neural Network : CNN)對CT做影像校準並建立出C-arm的姿態估測模型。本研究使用DRR影像驗證該想法是否可行，並探討如何透過修改CNN模型使估測結果能更精準。在脊椎影像校準的3D點回推誤差為0.3703mm，並於後續對校正版做影像校準，誤差為0.4988 mm。而最後模擬CT做驗證，整體誤差為0.446 mm，可推論該想法架構是可行的。	zh_TW
dc.description.abstract	Image registration is an important part of computer-assisted surgery. Register the images from preoperative and intraoperative has become an important information for doctors, which effect the total accuracy of the surgery. The difficulty of image registration lies in the alignment of different spatial fields, different resolutions and even different types of images. In this study, image registration was applied to spinal surgery, register the preoperative CT image and intraoperative C-arm image. The process will involve C-arm initial pose estimation, DRR projection, similarity comparison, optimization. In the first part of this study, use calibrator marker to estimate the C-arm pose first, and then use CT spine image to do the image registration. In the pose estimation part, the projection error of AP, CRA45 and the 3D estimation error can reach within 1mm.While the error of lateral view is larger, so we use the AP and CRA45 view to do the image registration, the error could reach to 0.5896 mm. Finally, we use the cone-beam CT to verify, the error is 1.2976 mm, which can fall within the safe range of spine surgery (2mm). Second part of the research, use the Convolutional Neural Network (CNN) to register the CT spine image and establish the C-arm pose estimation model. This study uses DRR image to verify whether the concept is feasible, and discuss about how to modify the CNN model to make the estimation results more accurate. In the CNN spine image registration process, 3D estimation error is 0.3703mm. In the following step, use the calibrator marker to do the image registration, the error is 0.4988 mm. In the final simulation verification,the error could reach to 0.4459 mm. It can be concluded that the idea of this architecture is feasible.	en
dc.description.provenance	Made available in DSpace on 2021-07-10T21:42:06Z (GMT). No. of bitstreams: 1 U0001-0302202112395600.pdf: 5231175 bytes, checksum: 90450e42ec62285c1655f4e1d1562509 (MD5) Previous issue date: 2021	en
dc.description.tableofcontents	致謝 i 摘要 ii ABSTRACT iii 目錄 iv 圖目錄 vii 表目錄 x 第1章緒論 1 1.1 研究背景 1 1.2 研究目的 2 1.3 章節瀏覽 2 第2章文獻探討與生醫影像介紹 4 2.1 2D-3D影像校準分類方式 4 2.1.1 2D-3D的比對方式(strategy to achieve spatial correspondence) 5 2.1.2 配準基礎性質(Nature of the registration basis) 7 2.2 使用的方法討論 9 2.2.1 影像校準 9 2.2.2 使用CNN姿態估測 12 2.3 使用硬體設備 14 2.3.1 電腦斷層影像(Computed Tomography : CT) 14 2.3.2 C型臂X光透視機(C-arm) 14 第3章 2D-3D 影像校準 16 3.1 目的 16 3.2 基本理論架構 17 3.2.1 2D-3D影像校準 17 3.3 坐標系/符號表說明 17 3.3.1 坐標系說明 17 3.3.2 符號表建立 21 3.4 實驗資料 23 3.5 C-arm影像前處理 25 3.6 2D-3D影像校準演算法與流程 26 3.6.1 C-arm姿態估測 26 3.6.2 CT影像初始定位 31 3.6.3 脊椎影像校準 31 3.7 操作介面 42 第4章 CNN架構2D-3D影像校準 44 4.1 目的 44 4.2 實驗資料 45 4.3 CNN姿態估測演算法與流程 46 4.3.1 資料投影模型 46 4.3.2 資料生成 47 4.3.3 CNN架構 49 4.4 CNN 2D-3D影像校準 52 4.4.1 對脊椎做影像校準並對C-arm姿態估測 52 4.4.2 校正版初始定位 53 4.4.3 校正版影像校準 53 4.5 使用軟體、硬體設備 53 第5章實驗設計與結果 54 5.1 誤差驗證方法 54 5.1.1 二維影像上的點誤差 54 5.1.2 三維空間中的點誤差 54 5.1.3 CT上模擬下鑽後的3D點驗證 57 5.2 2D-3D影像校準實驗結果 57 5.2.1 C-arm姿態估測 57 5.2.2 CT初始值給定 60 5.2.3 影像校準 61 5.3 CNN架構2D-3D影像校準實驗結果 66 5.3.1 CNN姿態估測模型 66 5.3.2 CNN 2D-3D影像校準 72 第6章結論與未來展望 78 第7章參考文獻 79
dc.language.iso	zh-TW
dc.subject	脊椎	zh_TW
dc.subject	影像校準	zh_TW
dc.subject	卷積類神經網路	zh_TW
dc.subject	spine	en
dc.subject	convolutional neural network	en
dc.subject	image registration	en
dc.title	卷積類神經網路應用於脊椎之影像校準	zh_TW
dc.title	Spine Image Registration Based on Convolutional Neural Network	en
dc.type	Thesis
dc.date.schoolyear	109-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳世芳(Shih-Fang Chen),洪碩穗(Shou-Suei Hung)
dc.subject.keyword	影像校準,卷積類神經網路,脊椎,	zh_TW
dc.subject.keyword	image registration,convolutional neural network,spine,	en
dc.relation.page	83
dc.identifier.doi	10.6342/NTU202100442
dc.rights.note	未授權
dc.date.accepted	2021-02-08
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物機電工程學系	zh_TW
顯示於系所單位：	生物機電工程學系

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