无创及微创血糖仪研究进展

doi:10.3969/j.issn.0258-8021.2016.05.012

Abstract
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[1] International Diabetes Federation[R]. Annual Report 2014. www.idf.org.
[2] Yang WY, Lu JM, Weng JP, et al. Prevalence of diabetes among men and women in China[J]. N Engl J Med, 2010,362(25):2425-2425.
[3] Xu Y, Wang LM, He J, et al. Prevalence and control of diabetes in Chinese adults[J]. JAMA, 2013,310(9):948-959.
[4] Porte D, Schwartz MW. Diabetes complications: why is glucose potentially toxic?[J]. Science,1996,272(5262):699-700.
[5] Georgia P, Tina C, Demetrius E, et al. The 30-year natural history of type 1 diabetes complications: the Pittsburgh Epidemiology of Diabetes Complications Study experience[J]. Diabetes, 2006,55(5):1463-1469.
[6] Perkins BA, Aiello LP, Krolewski AS. Diabetes complications and the renin-angiotensin system[J]. N Engl J Med,2009,361(1):83-85.
[7] Intine RV, Sarras MP. Metabolic memory and chronic diabetes complications: Potential role for epigenetic mechanisms[J]. Curr Diab Rep, 2012,12(5):551-559.
[8] Buckloh LM, Lochrie AS, Holly A, et al. Diabetes complications in youth[J]. Diabetes Care, 2008,31(8):1516-1520.
[9] MP Gilbert. Screening and treatment by the primary care provider of common diabetes complications[J]. Med Clin North Am, 2015,99(1):201-219.
[10] Shah BR, Hwee J, Cauch-Dudek K, et al. Diabetes self-management education is not associated with a reduction in long-term diabetes complications: an effectiveness study in an elderly population[J]. Journal Eval in Clin Pract,2015,21(4):656-661.
[11] Kuhn M, Kuhn P, Villeval MC. Self control and inter temporal choice: evidence from glucose and depletion interventions[C]//CESifo Working Paper Series. Munich: CES, 2014: No 4609.
[12] Beedie CJ,Lane AM. The role of glucose in self-control: Another look at the evidence and an alternative conceptualization[J]. Pers Soc Psychol Rev, 2011,16(2):143-153.
[13] Zamzow KL, Schmidt DG, Shults MC, et al. Development and evaluation of a wearable blood glucose monitor[J]. Assaio Transactions,1990,36(3):M588-M591.
[14] Rayman G, Spencer PD, Tillyer CR, et al. Evaluation of a self-calibrating blood glucose monitor[J]. Diabetes Care, 1984,7(4):378-380.
[15] Jones PM. Use of a course on self-control behavior techniques to increase adherence to prescribed frequency for self-monitoring blood glucose[J]. Diabetes Educ,1990,16(4):296-303.
[16] Fine J. Glucose content of normal urine [J]. British Medical Journal. 1965,1(5444):1209-1214.
[17] Street HV. Determination of glucose in biological fluids with ethylenediaminetetra-acetic acid[J]. Analyst,1958,83(992):628-634.
[18] Bantle JP, Thomas W. Glucose measurement in patients with diabetes mellitus with dermal interstitial fluid[J]. J Lab Clinl Med,1997,130(4):436-441.
[19] Vesper HW, Wang PM, Archibold E, et al. Assessment of trueness of a glucose monitor using interstitial fluid and whole blood as specimen matrix[J]. Diabetes Technol Ther,2006,8(1):76-80.
[20] Rebrin K, Sheppard NF, Steil GM. Use of subcutaneous interstitial fluid glucose to estimate blood glucose: revisiting delay and sensor offset[J]. J Diabetes Sci Technol,2010, 4(5):1087-1098.
[21] Weiss TR. Google Testing Smart Contact Lenses for Diabetes Patients[N]. Eweek,2014.
[22] Zhang J, Hodge W, Hutnick C, et al. Noninvasive diagnostic devices for diabetes through measuring tear glucose[J].J Diabetes Sci Technol,2011,5(1):166-172.
[23] Baca JT, Finegold DN, Asher SA. Tear Glucose Analysis for the noninvasive detection and monitoring of diabetes mellitus[J]. Ocul Surf,2007,5(4)280-293.
[24] Yao HF, Shum AJ, Cowan M. et.al. A contact lens with embedded sensor for monitoring tear glucose level[J]. Biosens Bioelectron, 2011. 15:26(7): 3290-3296.
[25] Yang X, Pan X, Blyth J, et al. Towards the real-time monitoring of glucose in tear fluid: holographic glucose sensors with reduced interference from lactate and pH[J]. Biosens Bioelectron, 2008,23(6):899-905.
[26] Lee H, Choi TK, Lee YB, et al. A graphene-based electrochemical device with thermoresponsive microneedles for diabetes monitoring and therapy[J]. Nat Nanotechnol, 2016,11(6):566-572.
[27] Cengiz E, Tamborlane WV. A tale of two compartments: interstitial versus blood glucose monitoring[J]. Diabetes Technol Ther, 2009,11(Suppl 1):S11-S16.
[28] Mraovic B. Analysis: Continuous glucose monitoring during intensive insulin therapy[J]. Diabetes Technol Ther, 2009.3(4):960-963.
[29] Buckingham B, Caswell K, Wilson DM. Real-time continuous glucose monitoring[J]. Curr Opin Endocrinol Diabetes Obes, 2007,14(4):288-295.
[30] Taylor JR. What′s new in continuous glucose monitors?[J]. Endocrine Today,2009(8):1-2.
[31] Hermanns N, Schumann B, KulzerB, et al. The impact of continuous Glucose monitoring on low interstitial glucose values and low blood glucose values assessed by point-of-care blood glucose meters: Results of a crossover trial[J]. J Diabetes Technol Ther, 2014.8(3):516-522.
[32] Facchinetti A, Del Favero S, Sparacino G. et al. Model of glucose sensor error components: identification and assessment for new Dexcom G4 generation devices[J]. Med Biol Eng Comput, 2015, 53(12):1-11
[33] Facchinetti A, Del Favero S, Sparacino G. et al. Modeling the glucose sensor error[J].IEEE Trans Biomed Eng, 2014,61(3):620-629.
[34] Peyser TA, Nakamura K, Price D, et al. Hypoglycemic accuracy and improved low glucose alerts of the latest Dexcom G4 platinum continuous glucose monitoring system[J]. Diabetes Technol Ther, 2015,17(8):548-554.
[35] Hirsch IB. Clinical review: Realistic expectations and practical use of continuous glucose monitoring for the endocrinologist[J]. J Clin Endocrinol Metab,2009;94(7):2232-2238
[36] Dassau E, Cameron F, Lee H, et al. Real-time hypoglycemia prediction suite using continuous glucose monitoring: a safety net for the artificial pancreas[J]. Diabetes Care,2010,33(6):1249-1254.
[37] Turner A, Gifford R. Implanted sensors[J]. Springer Series on Chemical Sensors and Biosensors, 2012.13:159-189.
[38] Tierney MJ, Tamada JA, Potts RO, et al. The GlucoWatch biographer: a frequent automatic and noninvasive glucose monitor[J].Ann Med, 2000, 32(9):632-641.
[39] Keenan DB, Mastrototaro JJ, Voskanyan G, et al. Delays in minimally invasive continuous glucose monitoring devices: a review of current technology[J]. J Diabetes Sci Technol, 2009, 3(5):1207-1214.
[40] Mazze RS, Strock E, Borgman S, et.al. Evaluating the accuracy, reliability, and clinical applicability of continuous glucose monitoring(CGM):Is CGM ready for real time?[J]. Diabetes Technol Ther, 2009,11(1):11-18.
[41] Fischbacher C, Jagemann KU, Danzer K, et al. Enhancing calibration models for non-invasive near-Infrared spectroscopicalblood glucose determination[J]. Fresen J Anal Chem,1997, 359(1):78-82.
[42] Liakat S, Bors KA, Huang TY, et al. In vitro measurements of physiological glucose concentration in biological fluids using mid-infrared light[J]. Biomed Opt Express, 2013,4(7):1083-1090.
[43] Cooper PJ, Barker TQ. Individual Calibration of blood glucose for supporting noninvasive self-monitoring blood glucose[P]. EP, US6309884 B1. 2001.
[44] Barman I. Unraveling the puzzles of spectroscopy-based non-invasive blood glucose detection[D]. Boston: Massachusetts Institute of Technology, 2011.
[45] Liakat S, Bors KA, Xu L, et al. Noninvasive in vivo glucose sensing on human subjects using mid-infrared light[J]. Biomed Opt Express, 2014,5(7):2397-2404.
[46] Gao L,Tao W,Zhao H,et al. Research and design of photoacoustic cell of noninvasive blood glucose measurement[J]. Optical Instruments, 2012,34(2):55-60.
[47] Xing Zhang, Li Xiaoqing. Strictly regulated blood glucose oscillations linked to rat mortality after severe burn injury[J]. Faseb J, 2012, 26(9):832-842.
[48] Zhao Z, Myllyla RA. Photoacoustic blood glucose and skin measurement based on optical scattering effect[J]. Proceedings of SPIE,2002,4707:1-5.
[49] Ren Z, Liu G, Huang Z, et al. Laser-induced photoacoustic glucose spectrum denoising using an improved wavelet threshold translation-invariant algorithm[J]. Proceedings of SPIE, 2009, 7382:1-8.
[50] Firdous S, Nawaz M, Ahmed M, et al. Measurement of diabetic sugar concentration in human blood using Raman spectroscopy[J]. Laser Physics, 2012, 22(6):1090-1094
[51] Dingari NC, Barman I, Singh GP, et al. Investigation of the specificity of Raman spectroscopy in non-invasive blood glucose measurements[J]. Anal Bioanal Chem,2011,400(9):2871-2880
[52] Enejder AM, Koo TW, Oh J, et al. Blood analysis by Raman spectroscopy[J]. Optics Lett, 2002, 27(22):2004-2006.
[53] Shao J, Lin M, Li Y, et al. In vivo blood glucose quantification using raman spectroscopy[J]. PLoS ONE, 2012, 7(10):e48127
[54] Segman Y. Finger mounted non-invasive device for measuring physiological parameters[P]. US687150. 2013
[55] Segman Y. Finger deployed device for measuring blood and physiological characteristics[P]. US8489165. 2013
[56] Lipson J, Bernhardt J, Block U, et al. Non-invasive technologies for glucose monitoring: requirements for calibration in noninvasive glucose monitoring by Raman spectroscopy[J]. J Diabetes Sci Technol, 2009,3(2):233-241.
[57] Lipson J,Bernhardt J,U Block, et al. Requirements for calibration in noninvasive glucose monitoring by Raman spectroscopy[J]. J Diabetes Sci Technol, 2009,3(2): 233-241.
[58] Harman\|BoehmI I, Gal A, Raykhman AM, et al. Noninvasive glucose monitoring: Increasing accuracy by combination of multi-technology and multi-sensors[J]. J Diabetes Sci Technol, 2010,4(3):583-595.
[59] Harman-Boehm I, Gal A, Raykhman AM, et al. Noninvasive glucose monitoring: a novel approach[J]. J Diabetes Sci Technol, 2009,3(2):253-60.
[60] Ramchandani N, Heptulla RA. New technologies for diabetes: a review of the present and the future[J]. Int J of Pediatric Endocrinol,2012,2012(1):1-10.
[61] Gravesen P, Raaby PK, Dirac H. Lab-on-a-chip technology for continuous glucose monitoring[J]. J Diabetes Sci Technol,2007, 1(3):372-374.
[62] Pedersen A. GlucoTrack offers painless glucose-monitoring option[J]. Medical Device Daily, 2013, 17(197): 1-7.