[1] Cho N H, Shaw J E, Karuranga S et al. IDF Diabetes Atlas: global estimates of diabetes prevalence for 2017 and projections for 2045[J]. Diabetes Research and Clinical Practice, 138, 271-281(2018).
[2] Villena Gonzales W, Mobashsher A T, Abbosh A. The progress of glucose monitoring-a review of invasive to minimally and non-invasive techniques, devices and sensors[J]. Sensors, 19, 800(2019).
[3] Zhang R C, Liu S Y, Jin H R et al. Noninvasive electromagnetic wave sensing of glucose[J]. Sensors, 19, 1151(2019).
[6] Maruo K, Tsurugi M, Tamura M et al. In vivo noninvasive measurement of blood glucose by near-infrared diffuse-reflectance spectroscopy[J]. Applied Spectroscopy, 57, 1236-1244(2003).
[9] Pirnstill C W, Malik B H, Gresham V C et al. In vivo glucose monitoring using dual-wavelength polarimetry to overcome corneal birefringence in the presence of motion[J]. Diabetes Technology & Therapeutics, 14, 819-827(2012).
[11] Esenaliev R O, Larin K V, Larina I V et al. Noninvasive monitoring of glucose concentration with optical coherence tomography[J]. Optics Letters, 26, 992-994(2001).
[12] 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]. Physics in Medicine and Biology, 48, 1371-1390(2003).
[13] El-Busaidy S, Baumann B, Wolff M et al. Experimental and numerical investigation of a photoacoustic resonator for solid samples: towards a non-invasive glucose sensor[J]. Sensors, 19, 2889(2019).
[16] Lan Y, Kuang Y, Zhou L et al. Noninvasive monitoring of blood glucose concentration in diabetic patients with optical coherence tomography[J]. Laser Physics Letters, 14, 035603(2017).
[17] Kohl M, Essenpreis M, Cope M. The influence of glucose concentration upon the transport of light in tissue-simulating phantoms[J]. Physics in Medicine and Biology, 40, 1267-1287(1995).
[18] Kohl M, Cope M, Essenpreis M et al. Influence of glucose concentration on light scattering in tissue-simulating phantoms[J]. Optics Letters, 19, 2170-2172(1994).
[19] Bruulsema J T, Hayward J E, Farrell T J et al. Correlation between blood glucose concentration in diabetics and noninvasively measured tissue optical scattering coefficient[J]. Optics Letters, 22, 190-192(1997).
[20] Chen W L, Liu R, Luo Y H et al. Preliminary study of mechanism of non-invasive blood glucose measurement based on near-infrared diffuse reflectance spectroscopy[J]. Proceedings of SPIE, 5696, 91-100(2005).
[22] Zhang Z Y, Sun D, Liu B J et al. Reasonable selection of wavelengths for glucose absorption spectrum from a wide waveband of 1000-2500 nm[J]. Nanotechnology and Precision Engineering, 15, 199-204(2017).
[23] Sordillo L A, Pu Y, Pratavieira S et al. Deep optical imaging of tissue using the second and third near-infrared spectral windows[J]. Journal of Biomedical Optics, 19, 056004(2014).
[24] Parrish J A. New concepts in therapeutic photomedicine; photochemistry, optical targeting and the therapeutic window[J]. Journal of Investigative Dermatology, 77, 45-50(1981).
[25] Troy T L, Thennadil S N. Optical properties of human skin in the near infrared wavelength range of 1000 to 2200 nm[J]. Journal of Biomedical Optics, 6, 167-176(2001).
[26] Swinehart D F. The Beer-Lambert law[J]. Journal of Chemical Education, 39, 333(1962).
[27] Amerov A K, Chen J, Arnold M A. Molar absorptivities of glucose and other biological molecules in aqueous solutions over the first overtone and combination regions of the near-infrared spectrum[J]. Applied Spectroscopy, 58, 1195-1204(2004).
[28] Zhang H Y. Study on NIR spectroscopy application in human blood glucose noninvasive measure[D]. Beijing: University of Chinese Academy of Sciences(2005).