[1] L. Heinemann, G. Schmelzeisen. Non-invasive continuous glucose monitoring in type I diabetic patients with optical glucose sensors[J]. Diabetologia, 1998, 41: 848~854
[2] J. T. Bruulsema, J. E. Hayward, T. J. Farrell et al.. Correlation between blood glucose concentration in diabetics and noninvasively measured tissue optical scattering coefficient[J]. Opt. Lett., 1997, 22(3): 190~192
[3] John S. Maier, Scott A. Walker, Sergio Fantini 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
[4] Matthias Kohl, Matthias Essenpreis, Mark Cope. The influence of glucose concentration upon the transport of light in tissue-simulating phantoms[J]. Physics in Medicine and Biology, 1995, 40: 1267~1287
[5] Matthias Kohl, Mark Cope, Mattias Essenpreis et al.. Influence of glucose concentration on light scattering in tissue simulation phantom[J]. Opt. Lett., 1994, 19(24): 2170~2172
[6] S. R. Arridge, M. Cope, D. T. Delpy. The theoretical basis for the determination of optical pathlengths in tissue: temporal and frequency analysis[J]. Physics in Medicine and Biology, 1992, 37(7): 1531~1560
[7] Matthew A. Bartlett, Huabei Jiang. Effect of refractive index on the measurement of optical properties in turbid media[J]. Appl. Opt., 2001, 40(10): 1735~1741
[8] Robert C. Weast, Melvin J. Astle. CRC Handbook of Chemistry and Physics[M]. 63th. Boca raton: CRC Press, 1982. D-239
[9] H. C. van de Hulst. Light Scattering by Small Particles[M]. New York: Dover, 1981
[10] C. Lentner, ed. Geigy Scientific Tables[M]. 1984, Vol. 3,69
[11] F. A. Duck. Physical Properties of Tissue[M]. London: Academic Press, 1990. 63
[13] Scott A. Prahl, Martin J. C. van Gemert, Ashley J. Welch. Determining the optical properties of turbid media using the adding-doubling method[J]. 1993, 32(4): 559~568
[14] Scott Prahl. Optical Property Measurements Using the Inverse Adding-Doubling Program[M]. http:∥omlc.ogi.edu