• Optics and Precision Engineering
  • Vol. 18, Issue 12, 2688 (2010)
XU Quan-sheng*, FENG Shu, and YE Da-tian
Author Affiliations
  • [in Chinese]
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    DOI: Cite this Article
    XU Quan-sheng, FENG Shu, YE Da-tian. Evaluation of non-invasive detection of blood glucose using OCT[J]. Optics and Precision Engineering, 2010, 18(12): 2688 Copy Citation Text show less
    References

    [1] FENG S, YUAN K, YE D. Precision of glucose measurement in intralipid suspensions with optical coherence tomography [J]. SPIE, 2008:510-513.

    [2] ZHENG Y, LI G, ZHANG T, et al..Performance analysis of an optical coherence tomography system with special coating beam splitter [J]. Opt. Precision Eng., 2006,14(6):1082-1087. (in Chinese)

    [3] LI G, ZHANG T, ZHENG Y, et al.. Calibration of phase shifter in spectral domain OCT system [J]. Opt. Precision Eng., 2008,16(1):114-121. (in Chinese)

    [4] ZHENG Y, LI G, LIU J J, et al.. Correction algorithm of restriction of linear phase-shift in complex spectral OCT system [J]. Opt. Precision Eng., 2007,15(5):753-759. (in Chinese)

    [5] KINNUNEN M, MYLLYL R, JOKELA T, et al.. In vitro studies toward noninvasive glucose monitoring with optical coherence tomography [J]. Applied Optics, 2006,45(10):2251.

    [6] LARIN K, MOTAMEDI M, ASHITKOV T, etal.. Specificity of noninvasive blood glucose sensing using optical coherence tomography technique: a pilot study[J]. Physics in Medicine and Biology, 2003,48(10):1371.

    [7] LARIN K, ELEDRISI M, MOTAMEDI M, et al.. Noninvasive blood glucose monitoring with optical coherence tomography: a pilot study in human subjects [J]. Diabetes Care, 2002,25(12):2263.

    [8] LARIN K, ASHITKOV T, LARINA I, et al.. Optical coherence tomography and noninvasive blood glucose monitoring: a review [J].SPIE, 2004,5474:285.

    [9] FENG S, YUAN K, YE D. Effect of multiple scattering on measured signal losses using optical coherence tomography studied by monte carlo simulation [J]. International Journal of Innovative Computing, Information and Control, 2010,6(3):4249-4262.(in press)

    [10] KHOLODNYKH A, PETROVA I, LARIN K. Optimization of low coherence interferometry for quantitative analysis of tissue optical properties [J]. SPIE, 2002,4624:36.

    [11] KHOLODNYKH A, PETROVA I, MOTAMEDI M, et al.. Bifocal technique for accurate measurement of total attenuation coefficient in scattering media with OCT [C]. Proceeding of the Second Joint EMBSBMES Conference Houston, TX, USA, 2002:2251.

    [12] FENG S, YUAN K, YE D. Efficient fitting range for scatter measurement with optical coherence tomography [J]. SPIE, 2009,7280(0M):1-7.

    [13] FENG S, YUAN K,YE D. Efficient fitting range for glucose measurement with optical coherence tomography [J]. Journal of Innovative Optical Health Sciences, 2009,2(1):107-115.

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    XU Quan-sheng, FENG Shu, YE Da-tian. Evaluation of non-invasive detection of blood glucose using OCT[J]. Optics and Precision Engineering, 2010, 18(12): 2688
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