参考文献
[1] 张镇西译,光与生物组织的相互作用原理及应用,科学出版社,北京,2005.
[2] 张镇西,生物医学光子学新技术及应用,科学出版社,2007。
[3] 徐可欣,高峰,赵会娟,生物医学光子学,科学出版社, 2007。
[4] 张镇西译,分子光子学--原理及应用,科学出版社,2004。
[5] 张镇西, 姚翠萍, 王晶, 梅建生, 杨洋. 激光细胞微手术的发展和应用. 光学学报, 31(9): 211-217, 2011.
[6] 王喜昌,华臻,孟兆昆,光在多层匹配生物组织中的时域传输模型,光子学报,2005,35(7),1061-1065。
[7] 梅曦, 王晶, 张镇西, 张虹. 心肌窦房结细胞数学模型比较研究. 航天医学与医学工程, 23(4): 287-291, 2010.
[8] 周炜, 刘秀丽, 吕晓华, 李家松, 骆清铭, 曾绍群,飞秒激光测控神经活动,科学通报 2008, 53(1) ,49-5。
[9] 王晶, 张镇西, 徐正红, 金妍姝, 季晓璐, 金印彬. 基于ANEP染料荧光光谱迁移的单波长心脏光学标测系统. 光谱学与光谱分析, 28(3): 617-620, 2008.
[10] 刘刚, 邢达,王海珉,吴杰,胆结石中蛋白质的傅里叶变换红外光谱和表面增强拉曼光谱研究,光学学报, 2002,04。
[11] 谷怀民,邢达,激光散射法测量溶液中蛋白质含量,应用激光 , 2001,21(4)。
[12] 李步洪; 谢树森,不同理论模型下猪肌肉组织的光学特性参数,中国生物医学工程学报,2005,01。
[13] 谢树森, 李晖,牛憨笨,秦玉文,何杰,潘庆,生物医学光子学的发展与前瞻,中国科学:G辑, 2007,10。
[14] 李忠明, 张镇西. 激光针灸治疗机理探讨. 激光生物学报, 14(1): 8-11, 2005.
[15] 姚翠萍, 李政, 张镇西. 激光高精度细胞微手术机理的研究. 光学学报, 25(12): 1664-1669 , 2005.
[16] 熊建文, 刘桂香, 陈丽, 肖化, 张镇西. 激光等离子体诱导蚀除眼内病体组织的机理分析. 激光杂志, 26(1): 69-72, 2005.
[17] 张镇西, 张苏娟, 张宝琴, 陈美兰. 5-氨基酮戊酸-光动力学疗法作用于白血病细胞的研究—细胞实验中PDT剂量计算的数学模型. 中国激光医学杂志, 13(4): 212-217, 2004.
[18] 张虹, 张镇西, 杨琳, 金印彬, 黄诒焯. 心脏记忆现象及其产生机制的研究现状. 生物医学工程与临床, 8(4): 240-243, 2004.
[19] 张宝琴, 肖谧, 苗丽霞, 张镇西. ALA-PDT对多种白血病细胞破坏作用的实验研究. 激光生物学报, 13(6): 447-452, 2004.
[20] 徐正红, 张镇西, 王晶. 生物组织光学特性检测中的探头设计. 激光生物学报,13(1): 78-80 ,2004.
[21] 肖化, 熊建文, 吴继明, 张镇西. ALA-PDT对白血病肿瘤细胞作用的参数研究. 激光生物学报, 13(5): 353-357, 2004.
[22] 李政, 张镇西. 激光诱导的基因转染方法研究. 激光生物学报, 13(3): 219-223, 2004.
[23] Arridge S R and Schweiger M and Delpy D T, Iterative reconstruction of near-infrared absorption images, Proc. SPIE, Vol. 1767, p.372-383, 1992.
[24] Arridge S R, Schweiger M, Hiraoka M and Delpy D T, A finite element approach for modeling photon transport in tissue, Med. Phys., Vol. 20, p.299-309, 1993.
[25] Arridge S R and Schweiger M, “Direct calculation of the moments of the distribution of photon time of flight in tissue with a finite-element method,” Appl. Opt., Vol. 34, 2683-2687,1995.
[26] Arridge S R and Schweiger M, A gradient-based optimisation scheme for optical tomography, Opt. Exp., Vol. 2, p.213-226, 1998.
[27] Arridge S R and Lionheart W R B, Nonuniqueness in diffusion-based optical tomography, Opt. Lett., Vol. 23, p. 882-884
[28] Arridge S R, Optical tomography in medical imaging, Inverse problems, Vol. 15, p.R41-R93, 1999
[29] Barbour R L, Graber H L, Pei Y, Zhong S, and Schmitz C H, Optical tongraphic imaging of dynamic features of dense-scattering media, J. Opt. Soc. Am., Vol.A14, p. 3018-3036, 2001.
[30] Boas D A, Brooks D H, DiMarzio C, Kilmer M, Gaudette R J and Zhang Q, Imaging the body with diffuse optical tomography, IEEE Signal Processing Magazine, November, p.57-75, 2001.
[31] Boas D A, Gaudette T, Strangman G, Cheng X, Marota J A, and Mandeville J B, The accuracy of near infrared spectroscopy and imaging during focal changes in cerebral hemodynamics, Neuroimage, Vol. 13, No. 1, p.76-90, 2001.
[32] Boas D A, Gaudette T, Arridge S R, Simultaneous imaging and optode calibration with diffuse optical tomography, Optical Express, Vol. 8, No. 5, p.263-270, 2001.
[33] Boas D A, Culver J P, Stott J J, Dunn A K, Three dimensional Monte Carlo code for photon migration through complex heterogeneous media including the adult human head, Opt. Exp., Vol.10, p.159-170, 2002.
[34] Buxton R B, Introduction to functional magnetic resonance imaging-principles & techniques, Cambridge University Press,2002.
[35] Chance B, Anday E, Nioka S, Zhou S, Hong L, Worden K, Li C, Murray T, Overtsky Y, Pidikiti D and Thomas R, A novel method for fast imaging of brain function, non-invasively with light, Optics Express, Vol. 2, p.411-418, 1998.
[36] Chance B, Cope M, Gratton E, Ramanujam N, Tromberg B, Phase measurement of light absorption and scatter in human tissue, Rev. Sci. Instr. Vol. 69 (10), p.3457-3480, 1998.
[37] Chance B, Noninvasive optical study of the human brain, Proc. SPIE, Vol. 4955, p.XV, 2003.
[38] Cheong W, Prahl S A and Welch A J, A review of the optical properties of Biological Tissues, IEEE J. Of Quamtum Electronics, Vol.26 (12), 2166-2184, 1990.
[39] Cope M, The application of near infrared spectroscopy to non invasive monitoring of cerebral oxygenation in the newborn infant, PHD thesis of The department of Medical Physics and Bioengineering, University of London, 1991
[40] Essenpreis M, Elwell C E, Cope M, van der Zee P, Arridge S R and Delpy D T, Spectral dependence of temporal point spread functions in human tissues, Appl. Opt., Vol.32, p.418-425, 1993
[41] Fantini S, Walker S A, Franceschini M A, Kaschke M, Schlag P M, Moesta K T, Assessment of the size, position, and optical properties of breast tumors in vivo by noninvasive optical methods, Appl. Opt., Vol.37, p.1982-1989, 1998.
[42] Fumio G and Takahiro A, Functional neuroanatomy for clinical practice, Chugai Igaku Co., Tokyo, 1992. (In Japanese)
[43] Cuiping Yao, Zheng Li, and Zhenxi Zhang. New algorithm and system for measuring size distribution of blood cells. Chinese Optics Letters, 2(6): 343-346, 2004.
[44] Oliver Werner Duscheck and Zhenxi Zhang. Laser Application in Medical Engineering. Acta Laser Biology Sinica, 13(3): 161-166, 2004.
[45] Sujuan Zhang and Zhenxi Zhang. 5-Aminolevulinic Acid–Based Photodynamic Therapy in Leukemia Cell HL60. Photochemistry and Photobiology, 79(6): 545-550, 2004.
[46] Hua Xiao, Junfang Chen, and Zhenxi Zhang. Influence of Deposition Temperature on the Structure of Si3N4 Thin Film Prepared by MWECR-PECVD. Plasma Science&Technology, 6(5): 2485-2488, 2004.
[47] Ye Yang, Zhenxi Zhang, Xinhui Yang, Joon Hock Yeo, Lijun Jiang, and Dazong Jiang. Blood cell counting and classification by nonflowing laser light scattering method. Journal of Biomedical Optics, 9(5): 995-1001, 2004.
[48] Buhong Li, Fuwen Yang, Zhenxi Zhang, Shusen Xie. Time Dependence and Concentration of Cellular Uptake of Hematoporphyrin Monomethyl Ether in Nasopharyngeal Carcinoma Cells. Acta Laser Biology Sinica, 14(5): 368-371, 2005.
[49] Hua Xiao, Jianwen Xiong, Li Chen, Mingsheng Liu, Guixiang Liu, Zhenxi Zhang. The characteristic research of emission spectrum and excitation spectrum about ALA. Proceedings of SPIE 5630: 660-667, 2005.
[50] Hong Zhang, Zhenxi Zhang, Lin Yang, Yinbin Jin, Yizhuo Huang. Relevance of ventricular electrical dispersion to arrhythmogenesis in ischemic myocardium-a simulation study. General physiology and biophysics, 24: 365-380, 2005.
[51] Zhao H, Gao F, Tanikawa Y, Homma K, Yamada Y, NIR time domain diffuse optical tomography experiments on human forearm, Proc. SPIE, Vol. 4955, 2003.
[52] Jianwen Xiong, Liangbin Hu, Zhenxi Zhang. Suppression of Direct Spin Hall Currents in Two-Dimensional Electronic Systems with both Rashba and Dresselhaus Spin-Orbit Couplings. Chinese Physics Letters, 23(5): 1278-1281, 2006.
[53] Hamamatsu, Photonmultiplier tube –principle to application, Hamamatsu produce manual, 1994.
[54] Haruna M, Ohmi M, Mitsuyama T, Tajiri H, Maruyama H, and Hashimoto M, Simultaneous measurement of the phase and group indicies and the thickness of transparent plates by low-coherence interferometry, Opt. Lett., Vol.23, p. 966-968, 1998
[55] Hebden J C and Wong K S, Time-resolved optical tomography, Appl. Opt., Vol.32, p.372-380, 1993.
[56] Hebden J C, Veenstra H, Dehghani H, Hillman M C, Schweiger M, Arridge S R, and Delpy D T, Three-dimensional time-resolved optical tomography of a concical breast phantom, Appl. Opt., Vol.40, p.3278-3287, 2001
[57] Hebden J C, Gibson A, Yusof R M, Everdell N, Hillman E M C, Delpy D T, Arridge S R, Austin T, Meek J H, and Wyatt J S, Three-dimensionaloptical tomography of the premature infant brain, Phys. Med. Boil., Vol.47, p. 4155-4166, 2002
[58] Hielscher A H, Liu H L, Chance B, Tittel F K and Jacques S L, Time-resolved photn emission from layerd turbid media, Apl. Opt. Vol.35, p719-728, 1996
[59] Hielscher A H, Klose A D and Hanson K M, Gradient-based iterative image reconstruction scheme for time-resolved optical tomography, IEEE Trans. on Med. Imag., Vol.18, p.262-71, 1999
[60] Hillman E M C, Hebden J C, Schmidt F E W, Arridge S R, Schweiger M, Dehghani H, and Delpy D T, Calibration techniques and datatype extraction for time-resolved optical tomography, Rev. Sci. Instru., Vol.71, p.3415-3427, 2000.
[61] Hillman E M C, Hebden J C, Schweiger M, Dehghani H, Schmidt F E W, Delpy D T and Arridge S R, Time resolved optical tomography of the human forearm, Phys. Med. Biol., Vol.46, No. 7, p.1117-1130, 2001.
[62] Hillman E M C, Experimental and theoretical investigations of near infrared tomographic imaging methods and clinical applications, PHD Thesis of University college London, 2002.
[63] Hiraoka M, Firbank M, Essenpreis M, Cope M, Arridge S R, van der Zee P and Delpy D T, Monte Carlo simulation of light transport through inhomogeneous tissue, Phys. Med. Biol., Vol.38, p.1859-1876, 1993
[64] Ishimaru A, Wave propagation and scattering in random media, Academic Press, New York, 1978, Chap. 7, p.157.
[65] Jiang H, Optical image reconstruction based on the third order diffusion equations, Opics Express, Vol.4 (8), p.241-246, 1999.
[66] Jobsis F F, Noninvasive infrared monitoring o verebral and myocardial oxygen sufficiency and circulatory parameters,, Science , Vol.198, p.1264-1267, 1977.
[67] Kienle A and Hibst R, New optical wavelength for treatment of portwine stains, Phys. Med. Biol., Vol. 40, p.1559-1576, 1995
[68] Kienle A, Lilge L, Patterson M S, Hibst R, and Wilson B C, Spatially resolved absolute diffuse reflectance measurements for noninvasive determination of the optical scattering and absorption coefficients of biological tissue, Appl. Opt., Vol.35, p.2304-2314, 1996
[69] Kienle A and Patterson M S, Improved solutions of the steady-state and time-resolved diffusion equations for reflectance from a semi-infinite turbid medium, J. Opt. Soc. Am., Vol.14, p.246-254, 1997
[70] Kienle A, Patterson M S, Dognitz-Utke N, Bays R, Wagnieres G and der Bergh H, Noninvasive determination of the optical properties of two-layered turbid media, Appl. Opt. Vol.37, p.779-791, 1998.
[71] Kienle A and Glanzmann T, In vivo determination of the optical properties of muscle with time-resolved reflectance using a layered model, Phy. Med. Biol., Vol. 44, p.2689-2702, 1999
[72] Youli Yu, Zhenxi Zhang, Rui Jia, Qiulao Yan. Compare for calibration methods to optical trapping force upon non-spherical biological cells. Acta Photonica Sinica, 35(3): 394-397, 2006.
[73] Matcher S J, Cope M and Delpy D T, In vivo measurements of the wavelength dependence of tissue-transport scattering coefficients between 760 and 900 nm measured with time-resolved spectroscopy, Appl. Opt., Vol.36, p.386-396, 1997
[74] Martelli F, Sassaroli A, Yamada Y and Zaccanti G, Analytical approximate solutions of the time-domain diffusion equation in layer slabs, J. Opt. Soc. Am. A, Vol. 19, p.71-80, 2002
[75] Martelli F, Analytical Solutions and Characteristics of the Diffusion Equation to Describe Photon Migration Through Homogeneous and Layered Diffusive Media: Applications to Tissue Optics, PHD thesis of The University of Electro-Communications, Japan, 2002.
[76] Ntziachristos V, Ma X H, Yodh A G, and Chance B, Multichannel photon counting instrument for spatially resolved near infrared spectroscopy, Rev. Sci. Instrum., Vol.70, p.193-201, 1999
[77] Okada E, Firbank M, Schweiger M, Arridge S R, Cope M, and Delpy D T, Theoretical and experimental investigation of near-infrared light propagation in a model of the adult head, Applied Optics, Vol. 36(1), 21-31, 1997.
[78] Patterson M S, Chance B, Wilson B C, Time resolved reflectance and transmittance for the non-invasive measurement of tissue optical properties, Appl. Opt., Vol. 28, p.2331-2336
[79] Patterson M. S, Ebgels S A, Wilson B C, and Osei E K, Absorption spectroscopy in tissue-simulating materials: a theoretical and experimental study of photon path, Appl. Opt., Vol. 34(1), p.22-30
[80] Paunescu, L A, Tissue blood flow and oxygen consumption measured with near-infrared frequency-domain spectroscopy, PHD thesis of Univeristy of Illinois at Urbana-Champaign, 2001.
[81] Pogue B W, Testorf M, McBridge T, Osterberg U, and Paulsen K, Instrumentation and design of a frequency domain diffuse optical tomographic imager for breast cancer detection, Opt. Express, Vol.1, p.391-403, 1997
[82] Pogue B W, Diffusion optical tomography: introduction, Opt. Express Vol.4, p.230, 1999
[83] Sassaroli A, Fundamental studies of near infrared spectroscopy and diffuse optical tomography for biomedical diagnosis, PHD thesis of The University of Electro-Communications, Japan, 2002.
[84] Schmidt F E W, Development of a time-resolvedoptical tomography system for neonatal brain imaging, PHD thesis of University College London, UK, 1999.
[85] Schmidt F E W, Hebden J C, Hillman E M C, Fry M E, Schweigr M., Dehghani H, Delpy D T, Arridge S R, Multiple-slice imaging of a tissue-eqivalent phantom by use of time-resolved optical tomography, Appl. Opt., Vol.39, p.3380-3387, 2000.
[86] Schmitz C H, Graber H L, Luo H, Barbour R L Pei Y, Zhong S, Insturmentation and calibration protocol for imaging dynamic features in dense-scattering media by optical tomography, Appl. optics, Vol. 39, p.6466-6486, 2000.
[87] Schweiger M, Arridge S R and and Delpy D T, Application of the finite element method for the forward and inverse models in optical tomography, J. Math. Imag. Vision, Vol. 3, p.263-283, 1993.
[88] Schweiger M and Arridge S R, Comparison of 2D and 3D reconstruction algorithm in optical tomography, Appl. Opt., Vol.37, p.7419-7428, 1998.
[89] Schweiger M and Arridge S R, Application of temporal filters to time resolved data in optical tomography, Phys. Med. Biol. Vol. 44, p.1699-1717, 1999.
[90] Simpson C R, Kohl M, Essenpreis M and Cope M, Near infrared optical properties of ex vivo human skin and sybcutaneous tissues measured using the Monte Carlo inversion technique, Phys. Med. Biol., Vol. 43, p.2465-2478, 1998.
[91] Tromberg B, Yodh A, Sevick-Muraca E, and Pine D, Diffusing photons in turbid media: introduction, Appl. Opt., Vol.36, p.9, 1997
[92] van der Zee P, Measurment and modelling of the optical properties of human tissue in the near infrared, Ph.D thesis, University of London, 1993
[93] van der Zee P, Cope M, Arridge S R, Essenpreis M, Potter L A, Edwards A D, Wyatt J S, McCormick D C, Roth S C, Reynolds E O R and Delpy D T, Experimentally measured optical pathlengths for the adult head, calf and forearm and the head of the new born infant as a function of inter optode spacing, Adv. Exp. Med. Biol., Vol. 316, p.143-153, 1992.
[94] van der Zee P, Essenpreis M, and Delpy D T, Optical properties of brain tissue, Proc. SPIE, Vol. 1888, p.454-465, 1993.
[95] Wang L, Jacques S.L, and Zheng L, MCML-Monte Carlo modeling of light transport in multi-layered tissues, Computer Methods and Programs in Biomedicine, Vol. 47, p.131-146, 1995.
[96] Wilson B C, Patterson M S, and Burns D M, Effect of photo-sensitizer concentration in tissue on the penetration depth of photoactivating light, Lasers Med. Sci., Vol.1, p.235-244, 1986
[97] Y Yamada, Light-tissue interaction and optical imaging in biomedicine, Chapter 1, Annual Review of heat transfer, Vol. VI, Begell House, Inc., 1995.
[98] Youli Yu, Zhenxi Zhang, Zheng Li, Xiaoli Wang. Methods of calibration to optical trapping force upon non-spherical cells. Chinese Optics Letters, 4(12): 722-724, 2006.
[99] Zhenghong Xu, Zhenxi Zhang, Yinbin Jin, Jing Wang. Examination of depth-weighted optical signals during cardiac optical mapping: a simulation study. Computers in biology and medicine, 37(5): 732-738, 2007.
[100] Cuiping Yao, Zhenxi Zhang, Ramtin Rahmanzadeh, Gereon Huettmann. Laser-Based Gene Transfection and Gene Therapy. IEEE Transactions on NanoBioscience, 7(2): 111-119, 2008.
[1] 张镇西译,光与生物组织的相互作用原理及应用,科学出版社,北京,2005.
[2] 张镇西,生物医学光子学新技术及应用,科学出版社,2007。
[3] 徐可欣,高峰,赵会娟,生物医学光子学,科学出版社, 2007。
[4] 张镇西译,分子光子学--原理及应用,科学出版社,2004。
[5] 张镇西, 姚翠萍, 王晶, 梅建生, 杨洋. 激光细胞微手术的发展和应用. 光学学报, 31(9): 211-217, 2011.
[6] 王喜昌,华臻,孟兆昆,光在多层匹配生物组织中的时域传输模型,光子学报,2005,35(7),1061-1065。
[7] 梅曦, 王晶, 张镇西, 张虹. 心肌窦房结细胞数学模型比较研究. 航天医学与医学工程, 23(4): 287-291, 2010.
[8] 周炜, 刘秀丽, 吕晓华, 李家松, 骆清铭, 曾绍群,飞秒激光测控神经活动,科学通报 2008, 53(1) ,49-5。
[9] 王晶, 张镇西, 徐正红, 金妍姝, 季晓璐, 金印彬. 基于ANEP染料荧光光谱迁移的单波长心脏光学标测系统. 光谱学与光谱分析, 28(3): 617-620, 2008.
[10] 刘刚, 邢达,王海珉,吴杰,胆结石中蛋白质的傅里叶变换红外光谱和表面增强拉曼光谱研究,光学学报, 2002,04。
[11] 谷怀民,邢达,激光散射法测量溶液中蛋白质含量,应用激光 , 2001,21(4)。
[12] 李步洪; 谢树森,不同理论模型下猪肌肉组织的光学特性参数,中国生物医学工程学报,2005,01。
[13] 谢树森, 李晖,牛憨笨,秦玉文,何杰,潘庆,生物医学光子学的发展与前瞻,中国科学:G辑, 2007,10。
[14] 李忠明, 张镇西. 激光针灸治疗机理探讨. 激光生物学报, 14(1): 8-11, 2005.
[15] 姚翠萍, 李政, 张镇西. 激光高精度细胞微手术机理的研究. 光学学报, 25(12): 1664-1669 , 2005.
[16] 熊建文, 刘桂香, 陈丽, 肖化, 张镇西. 激光等离子体诱导蚀除眼内病体组织的机理分析. 激光杂志, 26(1): 69-72, 2005.
[17] 张镇西, 张苏娟, 张宝琴, 陈美兰. 5-氨基酮戊酸-光动力学疗法作用于白血病细胞的研究—细胞实验中PDT剂量计算的数学模型. 中国激光医学杂志, 13(4): 212-217, 2004.
[18] 张虹, 张镇西, 杨琳, 金印彬, 黄诒焯. 心脏记忆现象及其产生机制的研究现状. 生物医学工程与临床, 8(4): 240-243, 2004.
[19] 张宝琴, 肖谧, 苗丽霞, 张镇西. ALA-PDT对多种白血病细胞破坏作用的实验研究. 激光生物学报, 13(6): 447-452, 2004.
[20] 徐正红, 张镇西, 王晶. 生物组织光学特性检测中的探头设计. 激光生物学报,13(1): 78-80 ,2004.
[21] 肖化, 熊建文, 吴继明, 张镇西. ALA-PDT对白血病肿瘤细胞作用的参数研究. 激光生物学报, 13(5): 353-357, 2004.
[22] 李政, 张镇西. 激光诱导的基因转染方法研究. 激光生物学报, 13(3): 219-223, 2004.
[23] Arridge S R and Schweiger M and Delpy D T, Iterative reconstruction of near-infrared absorption images, Proc. SPIE, Vol. 1767, p.372-383, 1992.
[24] Arridge S R, Schweiger M, Hiraoka M and Delpy D T, A finite element approach for modeling photon transport in tissue, Med. Phys., Vol. 20, p.299-309, 1993.
[25] Arridge S R and Schweiger M, “Direct calculation of the moments of the distribution of photon time of flight in tissue with a finite-element method,” Appl. Opt., Vol. 34, 2683-2687,1995.
[26] Arridge S R and Schweiger M, A gradient-based optimisation scheme for optical tomography, Opt. Exp., Vol. 2, p.213-226, 1998.
[27] Arridge S R and Lionheart W R B, Nonuniqueness in diffusion-based optical tomography, Opt. Lett., Vol. 23, p. 882-884
[28] Arridge S R, Optical tomography in medical imaging, Inverse problems, Vol. 15, p.R41-R93, 1999
[29] Barbour R L, Graber H L, Pei Y, Zhong S, and Schmitz C H, Optical tongraphic imaging of dynamic features of dense-scattering media, J. Opt. Soc. Am., Vol.A14, p. 3018-3036, 2001.
[30] Boas D A, Brooks D H, DiMarzio C, Kilmer M, Gaudette R J and Zhang Q, Imaging the body with diffuse optical tomography, IEEE Signal Processing Magazine, November, p.57-75, 2001.
[31] Boas D A, Gaudette T, Strangman G, Cheng X, Marota J A, and Mandeville J B, The accuracy of near infrared spectroscopy and imaging during focal changes in cerebral hemodynamics, Neuroimage, Vol. 13, No. 1, p.76-90, 2001.
[32] Boas D A, Gaudette T, Arridge S R, Simultaneous imaging and optode calibration with diffuse optical tomography, Optical Express, Vol. 8, No. 5, p.263-270, 2001.
[33] Boas D A, Culver J P, Stott J J, Dunn A K, Three dimensional Monte Carlo code for photon migration through complex heterogeneous media including the adult human head, Opt. Exp., Vol.10, p.159-170, 2002.
[34] Buxton R B, Introduction to functional magnetic resonance imaging-principles & techniques, Cambridge University Press,2002.
[35] Chance B, Anday E, Nioka S, Zhou S, Hong L, Worden K, Li C, Murray T, Overtsky Y, Pidikiti D and Thomas R, A novel method for fast imaging of brain function, non-invasively with light, Optics Express, Vol. 2, p.411-418, 1998.
[36] Chance B, Cope M, Gratton E, Ramanujam N, Tromberg B, Phase measurement of light absorption and scatter in human tissue, Rev. Sci. Instr. Vol. 69 (10), p.3457-3480, 1998.
[37] Chance B, Noninvasive optical study of the human brain, Proc. SPIE, Vol. 4955, p.XV, 2003.
[38] Cheong W, Prahl S A and Welch A J, A review of the optical properties of Biological Tissues, IEEE J. Of Quamtum Electronics, Vol.26 (12), 2166-2184, 1990.
[39] Cope M, The application of near infrared spectroscopy to non invasive monitoring of cerebral oxygenation in the newborn infant, PHD thesis of The department of Medical Physics and Bioengineering, University of London, 1991
[40] Essenpreis M, Elwell C E, Cope M, van der Zee P, Arridge S R and Delpy D T, Spectral dependence of temporal point spread functions in human tissues, Appl. Opt., Vol.32, p.418-425, 1993
[41] Fantini S, Walker S A, Franceschini M A, Kaschke M, Schlag P M, Moesta K T, Assessment of the size, position, and optical properties of breast tumors in vivo by noninvasive optical methods, Appl. Opt., Vol.37, p.1982-1989, 1998.
[42] Fumio G and Takahiro A, Functional neuroanatomy for clinical practice, Chugai Igaku Co., Tokyo, 1992. (In Japanese)
[43] Cuiping Yao, Zheng Li, and Zhenxi Zhang. New algorithm and system for measuring size distribution of blood cells. Chinese Optics Letters, 2(6): 343-346, 2004.
[44] Oliver Werner Duscheck and Zhenxi Zhang. Laser Application in Medical Engineering. Acta Laser Biology Sinica, 13(3): 161-166, 2004.
[45] Sujuan Zhang and Zhenxi Zhang. 5-Aminolevulinic Acid–Based Photodynamic Therapy in Leukemia Cell HL60. Photochemistry and Photobiology, 79(6): 545-550, 2004.
[46] Hua Xiao, Junfang Chen, and Zhenxi Zhang. Influence of Deposition Temperature on the Structure of Si3N4 Thin Film Prepared by MWECR-PECVD. Plasma Science&Technology, 6(5): 2485-2488, 2004.
[47] Ye Yang, Zhenxi Zhang, Xinhui Yang, Joon Hock Yeo, Lijun Jiang, and Dazong Jiang. Blood cell counting and classification by nonflowing laser light scattering method. Journal of Biomedical Optics, 9(5): 995-1001, 2004.
[48] Buhong Li, Fuwen Yang, Zhenxi Zhang, Shusen Xie. Time Dependence and Concentration of Cellular Uptake of Hematoporphyrin Monomethyl Ether in Nasopharyngeal Carcinoma Cells. Acta Laser Biology Sinica, 14(5): 368-371, 2005.
[49] Hua Xiao, Jianwen Xiong, Li Chen, Mingsheng Liu, Guixiang Liu, Zhenxi Zhang. The characteristic research of emission spectrum and excitation spectrum about ALA. Proceedings of SPIE 5630: 660-667, 2005.
[50] Hong Zhang, Zhenxi Zhang, Lin Yang, Yinbin Jin, Yizhuo Huang. Relevance of ventricular electrical dispersion to arrhythmogenesis in ischemic myocardium-a simulation study. General physiology and biophysics, 24: 365-380, 2005.
[51] Zhao H, Gao F, Tanikawa Y, Homma K, Yamada Y, NIR time domain diffuse optical tomography experiments on human forearm, Proc. SPIE, Vol. 4955, 2003.
[52] Jianwen Xiong, Liangbin Hu, Zhenxi Zhang. Suppression of Direct Spin Hall Currents in Two-Dimensional Electronic Systems with both Rashba and Dresselhaus Spin-Orbit Couplings. Chinese Physics Letters, 23(5): 1278-1281, 2006.
[53] Hamamatsu, Photonmultiplier tube –principle to application, Hamamatsu produce manual, 1994.
[54] Haruna M, Ohmi M, Mitsuyama T, Tajiri H, Maruyama H, and Hashimoto M, Simultaneous measurement of the phase and group indicies and the thickness of transparent plates by low-coherence interferometry, Opt. Lett., Vol.23, p. 966-968, 1998
[55] Hebden J C and Wong K S, Time-resolved optical tomography, Appl. Opt., Vol.32, p.372-380, 1993.
[56] Hebden J C, Veenstra H, Dehghani H, Hillman M C, Schweiger M, Arridge S R, and Delpy D T, Three-dimensional time-resolved optical tomography of a concical breast phantom, Appl. Opt., Vol.40, p.3278-3287, 2001
[57] Hebden J C, Gibson A, Yusof R M, Everdell N, Hillman E M C, Delpy D T, Arridge S R, Austin T, Meek J H, and Wyatt J S, Three-dimensionaloptical tomography of the premature infant brain, Phys. Med. Boil., Vol.47, p. 4155-4166, 2002
[58] Hielscher A H, Liu H L, Chance B, Tittel F K and Jacques S L, Time-resolved photn emission from layerd turbid media, Apl. Opt. Vol.35, p719-728, 1996
[59] Hielscher A H, Klose A D and Hanson K M, Gradient-based iterative image reconstruction scheme for time-resolved optical tomography, IEEE Trans. on Med. Imag., Vol.18, p.262-71, 1999
[60] Hillman E M C, Hebden J C, Schmidt F E W, Arridge S R, Schweiger M, Dehghani H, and Delpy D T, Calibration techniques and datatype extraction for time-resolved optical tomography, Rev. Sci. Instru., Vol.71, p.3415-3427, 2000.
[61] Hillman E M C, Hebden J C, Schweiger M, Dehghani H, Schmidt F E W, Delpy D T and Arridge S R, Time resolved optical tomography of the human forearm, Phys. Med. Biol., Vol.46, No. 7, p.1117-1130, 2001.
[62] Hillman E M C, Experimental and theoretical investigations of near infrared tomographic imaging methods and clinical applications, PHD Thesis of University college London, 2002.
[63] Hiraoka M, Firbank M, Essenpreis M, Cope M, Arridge S R, van der Zee P and Delpy D T, Monte Carlo simulation of light transport through inhomogeneous tissue, Phys. Med. Biol., Vol.38, p.1859-1876, 1993
[64] Ishimaru A, Wave propagation and scattering in random media, Academic Press, New York, 1978, Chap. 7, p.157.
[65] Jiang H, Optical image reconstruction based on the third order diffusion equations, Opics Express, Vol.4 (8), p.241-246, 1999.
[66] Jobsis F F, Noninvasive infrared monitoring o verebral and myocardial oxygen sufficiency and circulatory parameters,, Science , Vol.198, p.1264-1267, 1977.
[67] Kienle A and Hibst R, New optical wavelength for treatment of portwine stains, Phys. Med. Biol., Vol. 40, p.1559-1576, 1995
[68] Kienle A, Lilge L, Patterson M S, Hibst R, and Wilson B C, Spatially resolved absolute diffuse reflectance measurements for noninvasive determination of the optical scattering and absorption coefficients of biological tissue, Appl. Opt., Vol.35, p.2304-2314, 1996
[69] Kienle A and Patterson M S, Improved solutions of the steady-state and time-resolved diffusion equations for reflectance from a semi-infinite turbid medium, J. Opt. Soc. Am., Vol.14, p.246-254, 1997
[70] Kienle A, Patterson M S, Dognitz-Utke N, Bays R, Wagnieres G and der Bergh H, Noninvasive determination of the optical properties of two-layered turbid media, Appl. Opt. Vol.37, p.779-791, 1998.
[71] Kienle A and Glanzmann T, In vivo determination of the optical properties of muscle with time-resolved reflectance using a layered model, Phy. Med. Biol., Vol. 44, p.2689-2702, 1999
[72] Youli Yu, Zhenxi Zhang, Rui Jia, Qiulao Yan. Compare for calibration methods to optical trapping force upon non-spherical biological cells. Acta Photonica Sinica, 35(3): 394-397, 2006.
[73] Matcher S J, Cope M and Delpy D T, In vivo measurements of the wavelength dependence of tissue-transport scattering coefficients between 760 and 900 nm measured with time-resolved spectroscopy, Appl. Opt., Vol.36, p.386-396, 1997
[74] Martelli F, Sassaroli A, Yamada Y and Zaccanti G, Analytical approximate solutions of the time-domain diffusion equation in layer slabs, J. Opt. Soc. Am. A, Vol. 19, p.71-80, 2002
[75] Martelli F, Analytical Solutions and Characteristics of the Diffusion Equation to Describe Photon Migration Through Homogeneous and Layered Diffusive Media: Applications to Tissue Optics, PHD thesis of The University of Electro-Communications, Japan, 2002.
[76] Ntziachristos V, Ma X H, Yodh A G, and Chance B, Multichannel photon counting instrument for spatially resolved near infrared spectroscopy, Rev. Sci. Instrum., Vol.70, p.193-201, 1999
[77] Okada E, Firbank M, Schweiger M, Arridge S R, Cope M, and Delpy D T, Theoretical and experimental investigation of near-infrared light propagation in a model of the adult head, Applied Optics, Vol. 36(1), 21-31, 1997.
[78] Patterson M S, Chance B, Wilson B C, Time resolved reflectance and transmittance for the non-invasive measurement of tissue optical properties, Appl. Opt., Vol. 28, p.2331-2336
[79] Patterson M. S, Ebgels S A, Wilson B C, and Osei E K, Absorption spectroscopy in tissue-simulating materials: a theoretical and experimental study of photon path, Appl. Opt., Vol. 34(1), p.22-30
[80] Paunescu, L A, Tissue blood flow and oxygen consumption measured with near-infrared frequency-domain spectroscopy, PHD thesis of Univeristy of Illinois at Urbana-Champaign, 2001.
[81] Pogue B W, Testorf M, McBridge T, Osterberg U, and Paulsen K, Instrumentation and design of a frequency domain diffuse optical tomographic imager for breast cancer detection, Opt. Express, Vol.1, p.391-403, 1997
[82] Pogue B W, Diffusion optical tomography: introduction, Opt. Express Vol.4, p.230, 1999
[83] Sassaroli A, Fundamental studies of near infrared spectroscopy and diffuse optical tomography for biomedical diagnosis, PHD thesis of The University of Electro-Communications, Japan, 2002.
[84] Schmidt F E W, Development of a time-resolvedoptical tomography system for neonatal brain imaging, PHD thesis of University College London, UK, 1999.
[85] Schmidt F E W, Hebden J C, Hillman E M C, Fry M E, Schweigr M., Dehghani H, Delpy D T, Arridge S R, Multiple-slice imaging of a tissue-eqivalent phantom by use of time-resolved optical tomography, Appl. Opt., Vol.39, p.3380-3387, 2000.
[86] Schmitz C H, Graber H L, Luo H, Barbour R L Pei Y, Zhong S, Insturmentation and calibration protocol for imaging dynamic features in dense-scattering media by optical tomography, Appl. optics, Vol. 39, p.6466-6486, 2000.
[87] Schweiger M, Arridge S R and and Delpy D T, Application of the finite element method for the forward and inverse models in optical tomography, J. Math. Imag. Vision, Vol. 3, p.263-283, 1993.
[88] Schweiger M and Arridge S R, Comparison of 2D and 3D reconstruction algorithm in optical tomography, Appl. Opt., Vol.37, p.7419-7428, 1998.
[89] Schweiger M and Arridge S R, Application of temporal filters to time resolved data in optical tomography, Phys. Med. Biol. Vol. 44, p.1699-1717, 1999.
[90] Simpson C R, Kohl M, Essenpreis M and Cope M, Near infrared optical properties of ex vivo human skin and sybcutaneous tissues measured using the Monte Carlo inversion technique, Phys. Med. Biol., Vol. 43, p.2465-2478, 1998.
[91] Tromberg B, Yodh A, Sevick-Muraca E, and Pine D, Diffusing photons in turbid media: introduction, Appl. Opt., Vol.36, p.9, 1997
[92] van der Zee P, Measurment and modelling of the optical properties of human tissue in the near infrared, Ph.D thesis, University of London, 1993
[93] van der Zee P, Cope M, Arridge S R, Essenpreis M, Potter L A, Edwards A D, Wyatt J S, McCormick D C, Roth S C, Reynolds E O R and Delpy D T, Experimentally measured optical pathlengths for the adult head, calf and forearm and the head of the new born infant as a function of inter optode spacing, Adv. Exp. Med. Biol., Vol. 316, p.143-153, 1992.
[94] van der Zee P, Essenpreis M, and Delpy D T, Optical properties of brain tissue, Proc. SPIE, Vol. 1888, p.454-465, 1993.
[95] Wang L, Jacques S.L, and Zheng L, MCML-Monte Carlo modeling of light transport in multi-layered tissues, Computer Methods and Programs in Biomedicine, Vol. 47, p.131-146, 1995.
[96] Wilson B C, Patterson M S, and Burns D M, Effect of photo-sensitizer concentration in tissue on the penetration depth of photoactivating light, Lasers Med. Sci., Vol.1, p.235-244, 1986
[97] Y Yamada, Light-tissue interaction and optical imaging in biomedicine, Chapter 1, Annual Review of heat transfer, Vol. VI, Begell House, Inc., 1995.
[98] Youli Yu, Zhenxi Zhang, Zheng Li, Xiaoli Wang. Methods of calibration to optical trapping force upon non-spherical cells. Chinese Optics Letters, 4(12): 722-724, 2006.
[99] Zhenghong Xu, Zhenxi Zhang, Yinbin Jin, Jing Wang. Examination of depth-weighted optical signals during cardiac optical mapping: a simulation study. Computers in biology and medicine, 37(5): 732-738, 2007.
[100] Cuiping Yao, Zhenxi Zhang, Ramtin Rahmanzadeh, Gereon Huettmann. Laser-Based Gene Transfection and Gene Therapy. IEEE Transactions on NanoBioscience, 7(2): 111-119, 2008.