[1] LARIN K V, MOTAMEDI M, ASHITKOV T V, et al.. Specificity of noninvasive blood glucose sensing using optical coherence tomography technique: a pilot study ［J］. Phys. Med. Biol., 2003, 48(10): 1371-1390.

[2] JOHN S M, SCOTT A W, SERGIO F, et al.. Possible correlation between blood glucose concentration and the reduced scattering coefficient of tissues in the near infrared［J］. Opt. Lett., 1994, 19(24): 2062-2064.

[3] CHEN X D, GAO J, DING H Q. Infrared spectroscopy for non-invasive blood glucose monitoring(invited)［J］. Chin. Opt., 2012(4): 317-326. ( in Chinese)

[4] CHEN C, LU J Q, DING H, et al.. A primary method for determination of optical parameters of turbid samples and application to Intralipid between 550 and 1 630 nm ［J］. Opt. Express, 2006, 14(16): 7420-7435.

[5] TYCHO A, JOGENSEN T M, YURA H T, et al.. Derivation of a Monte Carlo method for modeling heterodyne detection in optical coherence tomography systems ［J］. Appl. Opt., 2002, 41(31): 6676-6691.

[6] JIANGHAI W, GUANGHUI W, YING C, et al.. Refractive index sensor using microfiber-based Mach-Zehnder interferometer Monte Carlo simulation of photon migration in 3D turbid media accelerated by graphics processing units ［J］. Opt. Lett., 2012, 37(1): 67-69.

[7] TRUDE S, ARNE R, LARS O S, et al.. Measurement of dye diffusion in scattering tissue phantoms using dual-wavelength low-coherence interferometry ［J］. J. Biomed. Opt., 2006, 11(1): 014017-1-9.

[8] MIKHAIL Y K,ALEXANDER V P, MATTI K, et al.. Glucose sensing in aqueous intralipid suspension with an optical coherence tomography system: experiment and Monte Carlo simulation［J］. SPIE, 2004, 5325: 164-173.

[9] DAVID L, LARS T, MICHAEL H F, et al.. Determination of optical scattering properties of highly-scattering media in optical coherence tomography images ［J］. Opt. Express, 2004, 12(2): 250-259.

[10] KINNUNEN M, MYLLYL R, JOKELA T, et al.. In vitro studies toward noninvasive glocuse monitoring with optical coherence tomography ［J］. Appl. Opt., 2006, 45(10): 2251-2260.

[11] XU Q SH, FENG SH, YE D T. Evaluation of non-invasive detection of blood glucose using OCT ［J］. Opt. Precision Eng., 2010,18(2): 2688-2694. ( in Chinese)

[12] HAYAKAWA C K, SPANIER J. Perturbation Monte Carlo methods to solve inverse photon migration problems in heterogeneous tissues［J］. Opt. Lett., 2001, 26(17): 1335-1337.

[13] WANG L H, JACQUES S L, ZHENG L Q. MCML-Monte Carlo modeling of photon transport in multi-layered tissues ［J］. Comput. Methods Programs Biomed., 1995, 47(2): 131-146.

[14] STAVEREN H J, MOES C J M, MARLE J. Light scattering in Intralipid-10% in the wavelength range of 400-1 100 nm［J］. Appl. Opt., 1991, 30(31): 4507-4514.

[15] JOHN S M, SCOTT A W, SERGIO F, et al.. Possible correlation between blood glucose concentration and the reduced scattering coefficient of tissues in the near infrared ［J］. Opt. Lett., 1994, 19(24): 2062-2064.

[16] HULST H C. Light Scattering by Small Particles［M］. New York: Dover, 1981: 254.

[17] ZHANG M, LIN L, GAO Y J, et al.. Reverse calculation of optical parameters of scattering medium based on fast Monte Carlo simulation ［J］. Acta Photonica Sinica, 2012, 41(7): 781-785. (in Chinese)