擴散光學斷層掃描術二維影像重建之模擬分析

Zong-Han Yu; 余宗翰

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/27447

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔡睿哲
dc.contributor.author	Zong-Han Yu	en
dc.contributor.author	余宗翰	zh_TW
dc.date.accessioned	2021-06-12T18:05:19Z	-
dc.date.available	2008-01-17
dc.date.copyright	2008-01-17
dc.date.issued	2008
dc.date.submitted	2008-01-09
dc.identifier.citation	1-1 http://en.wikipedia.org/wiki/X-ray 1-2 http://www.netmedicine.com/xray/ctscan/ct.htm 1-3 http://www.cis.rit.edu/htbooks/mri/ 1-4 http://neurosurgery.mgh.harvard.edu/pet-hp.htm 1-5 http://www.radiologyinfo.org/en/info.cfm?pg=genus 1-6 D. Huang, E. A. Swanson, C. P. Lin, J. S. Schuman, W. G. Stinson, W. Chang, M. R. Hee, T. Flotte, K. Gregory, C. A. Puliafito, J. G. Fujimoto, “Optical coherence tomography,” Science 254, 1178-1181 (1991). 1-7 http://en.wikipedia.org/wiki/Optical_coherence_tomography 1-8 D. A. Boas, A. M. Dale, and M. A. Franceschini, “Diffuse optical imaging of brain activation: Approaches to optimizing image sensitivity, resolution and accuracy,” NeuroImage 23, S275–S288 (2004). 1-9 T. Yates, J. C. Hebden, A. Gibson, N. Everdell, S. R. Arridge, and M.Douek, “Optical tomography of the breast using a multi-channel time-resolved imager,” Physics in Medicine and Biology 50, 2503–2517 (2005). 1-10 R. Choe, A. Corlu, K. Lee, T. Durduran, S. D. Konecky, M. Grosicka-Koptyra, S. R. Arridge, B. J. Czerniecki, D. L. Fraker, A. DeMichele, B. Chance, M. A. Rosen, and A. G. Yodh, “Diffuse optical tomography of breast cancer during neoadjuvant chemotherapy: a case study with comparison to MRI,” Medical Physics 32, 1128–1139 (2005). 1-11 http://omlc.ogi.edu/classroom/ece532/class3/scatterers.html 1-12 R. Cubeddu, A. Pifferi, P. Taroni, A. Torricelli, and G. Valentini, “Noninvasive absorption and scattering spectroscopy of bulk diffusive media: an application to the optical characterization of human breast,” Applied Physics Letters 74, 874-876 (1999). 1-13 L. Wang, P. P. Ho, C. Liu, G. Zhang, and R. R. Alfano, “Ballistic 2-D imaging through scattering walls using an ultrafast optical Kerr gate,” Science 253, 769-771 (1991). 1-14 C. -W. Sun, “Probing Biological Tissues and Phantoms with Quasi-coherent Polarized Light Based on Ultrafast Lasers,” Ph.D thesis, National Taiwan University, R.O.C., 2003 2-1 F. F. Jöbsis, “Noninvasive infrared monitoring of cerebral and myocardial oxygen sufficiency and circulatory parameters,” Science 198, 1264–1267 (1977). 2-2 Liu H, Chance B, Hielscher AH, Jacques SL, Tittel FK, “Influence of blood vessels on the measurement of hemoglobin oxygenation as determined by time-resolved reflectance spectroscopy,” Medical Physics 22, 1209-1217 (1995). 2-3 Yu G, Durduran T, Lech G, Zhou C, Chance B, Yodh AG, “Time dependent blood flow and oxygenation in human skeletal muscles measured by noninvasive near-infrared diffuse optical spectroscopies,” Journal of Biomedical Optics 10:02427.1-024027.12 (2005). 2-4 http://www.iss.com/products/oxiplex/index.html 2-5 B. Chance, Z. Zhuang, C. Unah, C. Alter, and L. Lipton, “Cognitionactivated low frequency modulation of light absorption in human brain,” Proceedings of the National Academy of Sciences of the United States of America 90, 3770–3774 (1993). 2-6 Y. Hoshi and M. Tamura, “Detection of dynamic changes in cerebral oxygenation coupled to neuronal function during mental work in man,” Neuroscience letter 150, 5–8 (1993). 2-7 S. Shimada, K. Hiraki, G. Matsuda, and I. Oda, “Decrease in prefrontal hemoglobin oxygenation during reaching tasks with delayed visual feedback: A near-infrared spectroscopy study,” Brain Rearch Cognitive Brain Research 20, 480–490 (2004). 2-8 S. R. Arridge, “Optical tomography in medical imaging,” Inverse Problem 15, R41–R93 (1999). 2-9 http://www.hitachi-medical.co.jp/product/opt/etg7100/index.html 2-10 J. Shao, L. Lin, M. Niwayama, N. Kudo, and K. Yamamoto, “Determination of a quantitative algorithm for the measurement of muscle oxygenation using CW near-infrared spectroscopy.Mean optical pathlength without the influence of adipose tissue,” Proceeding SPIE, 4082, 76-86 (2000). 2-11 Chance B, Luo Q, Nioka S, Alsop DC, Detre JA, “Optical investigations of physiology: a study of intrinsic and extrinsic biomedical contrast,” Philos. Trans. R. Soc. Lond. B Bio, Sci. 352, 707-716 (1997). 2-12 Chance B, Nioka S, Kent J et al., “Time-resolved spectroscopy of hemoglobin and myoglobin in resting and ischemic muscle,” Analytical Biochemistry 174, 698-707 (1988). 2-13 Fantini S, Fanceschini MA, Maier JS, Walker SA, Barbieri B, Gratton E., “Frequency-domain meultichannel optical detector for non-invansice tissue spectroscopy and oximetry,” Optical Engineering 34, 32-34 (1995). 2.14 http://www.medphys.ucl.ac.uk/research/borg/research/NIR topics. 2-15 Ronald X Xu, Stephen P Povoski, “Diffuse optical imaging and spectroscopy for cancer,” Expert review of medical devices 4(1), 83-95 (2007). 2-16 Arridge SR., “Optical tomography in medical imaging,” Inverse Problems 15, R41-R93 (1999). 2-17 Ntziachristos V, Yodh AG, Schnall MD, Chance B., “MRI-guided diffuse optical spectroscopy of malignant and benign breast lesions,” Neoplasia 4, 347-354 (2002). 2-18 Zhu Q, Chen N, Kurtzman SH., “Imaging tumor angiogenesis by use of combined near-infrared diffusive light and ultrasound,” Optics Letter 28, 337-339 (2003). 2-19 Li A, Miller EL, Kilmer ME et al., “Tomographic optical breast imaging guided by three-dimensional mammography,” Applied Optics 42, 5181-5190 (2003). 3-1 Ishimaru, A. 1978., “Wave Propagation and Scattering in Random Media,” Academic Press, San Diego. 3-2 B. C. Wilson, T. J. Farrell, and M. S. Patterson, “An optical fiber-based diffuse reflectance spectrometer for non-invasive investigation of photodynamic sensitizers in vivo,” Proceeding SPIE IS6, 219-231 (1990). 3-3 T. J. Farrell and M. S. Patterson, “A diffusion theory model of spatially resolved, steady-state diffuse reflectance for the noninvasive determination of tissue optical properties in vivo,” Medical Physics 19(4), 879–888 (1992). 3-4 R. C. Haskell, L. O. Svaasand, T. Tsay, T. Feng, M. S. McAdams and B. J. Tromberg, “Boundary conditions for the diffusion equation in radiative transfer,” Journal of the Optical Society of America A 11:2727-2741 (1994). 3-5 M. O’Leary, “Imaging with diffuse photon density waves,” PhD University of Pennsylvania (1996). 3-6 X. Intes, V. Ntziachristos and B. Chance, “Analytical model for dual-interfering sources diffuse optical tomography,” Optics Express 10, 2-14 (2002). 3-7 Joseph P. Culver, Andrew M. Siegel, Jonathan J. Stott, and David A. Boas, “Volumetric diffuse optical tomography of brain activity,” Optics Letters 28, 2061-2063 (2003). 3-8 R. Gordon, R. Bender, and G. T. Herman, “Algebraic Reconstruction Techniques (ART) for three-dimensional electron microscopy and x-ray photography,” Journal of Theoretical Biology 29, 471–482 (1970). 3-9 T. B. Harshbarger and D. B. Twieg, “Iterative reconstruction of single-shot spiral MRI with off resonance,” IEEE Transactions on Medical Imaging 18, 196–205 (1999). 3-10 T. M. Benson and J. Gregor., “Distributed iterative image reconstruction for micro-CT with ordered-subsets and focus of attention problem reduction,” Journal of X-ray Science and Technology 12(4), 231–240 (2004). 3-11 Thomas M. Benson and Jens Gregor, “Modified Simultaneous Iterative Reconstruction Technique for Faster Parallel Computation,” IEEE Nuclear Science Symposium Conference Record, M11-345 (2005). 4-1 X. Intes, V. Ntziachristos, J. Culver, A. Yodh and B. Chance, “Projection access order in Algebraic Reconstruction Technique for Diffuse Optical Tomography,” Physics in medicine and biology 47, N1 - N10 (2002).
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/27447	-
dc.description.abstract	在我們人體組織裡，對於波長約在600-900 nm近紅外光的吸收係數較小，光在組織中也能穿透較深。因此，善於利用此特性可以讓非侵入式的光學(醫療)儀器達到可穿透的最深深度，以一窺體內部份特徵。擴散光學斷層掃瞄術便是利用此波段的近紅外光為醫學影像檢測光源，利用這些光子的強度與分布等資訊可以重建出在生物組織內吸收及散射隨空間與時間分布的變化。在目前的臨床應用上，是以胸部腫瘤、大腦功能性造影、以及運動醫學為主要研究探討的對象，在未來也是以這些為主軸進而在發展出應用在更廣泛的層面上。此技術的優點是非侵入式、即時檢測、非輻射源、功能性生理量測。一般來說，擴散光學斷層掃瞄術的開發可大分為兩項，一是在系統上檢測光源的使用以及光偵測器的靈敏度等，二是在重建二維甚至於三維影像的演算法，影像的品質取決於演算法的使用。在此篇論文裡，我們模擬在紊亂介質中各種幾何形狀的非均勻吸收體來重建影像，並且使用數學上的同步疊代法，為了在系統運算時間與影像品質上取得平衡點，疊代過程需要一個最佳停止點。從模擬的結果裡，我們證實了這些演算法適用於擴散光學斷層掃瞄術並且能有效地重建影像。	zh_TW
dc.description.abstract	The near-infrared light is weakly absorbed between 600-900 nm in the human tissue. Therefore, the optical imaging system with the deep penetration characteristic can be applied to biomedical instrument. Diffuse optical tomography (DOT) is an emerging technique for biomedical imaging based on the near-infrared photons. It is a technique that images spatial variations in absorption and scattering properties of the biological tissues. For the clinical studies, the breast cancer detection, the functional brain imaging, and the diagnosis of exercise medicine will be concerned and focused in further research. It has the advantages of noninvasive, real-time, non-radiation and functional imaging. Generally, the categories of DOT development are divided into two parts: one is the devices choice of light source and photo-detector and the other is the image reconstruction algorithm. The image quality of DOT technique strongly depends on the reconstruction algorithm. In this thesis, inhomogeneities with various shapes of absorption distributions in turbid media are simulated. The DOT images are reconstructed based on the simultaneous iterative reconstruction technique (SIRT) method. To solve the trade-off problem between time consumption of reconstruction process and accuracy of reconstructed image, the iteration process needs an optimization criterion in algorithm. The simulation results reveal that the SIRT algorithm can offer efficient image reconstructing in DOT system.	en
dc.description.provenance	Made available in DSpace on 2021-06-12T18:05:19Z (GMT). No. of bitstreams: 1 ntu-97-R94941068-1.pdf: 3654639 bytes, checksum: 974480820067d6462fee3d3d481f34fe (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	目錄誌謝………………………………………………………i 摘要………………………………………………………ii Abstract……………………………………………… iii 目錄………………………………………………………iv 圖目錄……………………………………………………vi 表目錄……………………………………….…………viii 第一章緒論……………………………………………1 1.1 生物醫學造影…………………………………1 1.1.1 侵入式造影術……………………………1 1.1.2 非侵入式造影術…………………………2 1.2 光子與物質交互作用…………………………6 1.3 研究動機………………………………………9 第二章近紅外光醫學影像技術………………………10 2.1 歷史回顧………………………………………10 2.2 近紅外光光譜術………………………………12 2.3 擴散光學斷層掃瞄術…………………………14 第三章重建影像演算法…………………………………20 3.1 光子擴散方程式………………………………20 3.2 波恩近似法……………………………………21 3.3 雷托夫近似法…………………………………23 3.4 Forward Problem……………………………24 3.5 Inverse Problem……………………………25 3.6 同步疊代重建法………………………………27 3.7 疊代流程圖……………………………………30 第四章二維影像重建模擬……………………………31 4.1 立體組織模型…………………………………31 4.2 重建影像模型…………………………………33 4.3 方均根誤差……………………………………34 4.4 收斂速率………………………………………35 4.5 LabVIEW程式介面……………………………36 第五章模擬結果分析…………………………………37 5.1 同步疊代重建法測試………………………37 5.2 起始條件誤差…………………………………39 5.2.1 均勻介質中吸收係數的錯估…………40 5.2.2 深度資訊………………………………42 5.2.3 待測物複雜度…………………………44 5.3 疊代次數………………………………………46 第六章結論……………………………………………53 參考文獻…………………………………………………55
dc.language.iso	zh-TW
dc.subject	擴散光學斷層掃瞄術	zh_TW
dc.subject	同步疊代法	zh_TW
dc.subject	影像重建	zh_TW
dc.subject	image reconstruction	en
dc.subject	simultaneous iterative reconstruction technique	en
dc.subject	Diffusion optical tomography	en
dc.title	擴散光學斷層掃描術二維影像重建之模擬分析	zh_TW
dc.title	Simulation and analysis of two-dimensional image reconstruction in diffuse optical tomography	en
dc.type	Thesis
dc.date.schoolyear	96-1
dc.description.degree	碩士
dc.contributor.coadvisor	孫家偉
dc.contributor.oralexamcommittee	李柏磊,江卓培
dc.subject.keyword	擴散光學斷層掃瞄術,影像重建,同步疊代法,	zh_TW
dc.subject.keyword	Diffusion optical tomography,image reconstruction,simultaneous iterative reconstruction technique,	en
dc.relation.page	59
dc.rights.note	有償授權
dc.date.accepted	2008-01-10
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	光電工程學研究所	zh_TW
顯示於系所單位：	光電工程學研究所

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