Minimally-invasive blood glucose detection instrument based on surface plasmon resonance sensor decorated with GGBP

LI Da-chao; LI Guo-qing; ZHANG Jing-xin; YU Hai-xia; XU Ke-xin

doi:10.3788/ope.20132109.2333

Optics and Precision Engineering, Volume. 21, Issue 9, 2333(2013)

Minimally-invasive blood glucose detection instrument based on surface plasmon resonance sensor decorated with GGBP

LI Da-chao*... LI Guo-qing, ZHANG Jing-xin, YU Hai-xia and XU Ke-xin |Show fewer author(s)

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References(12)

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[8] [8] HSIEH H V, PFEIFFER Z A, AMISS T J. Direct detection of glucose by surface plasmon resonance with bacterial glucose/galactose-binding protein ［J］. Biosensors and Bioelectronics, 2004, 19(7): 653-660.

[9] [9] KRETSCHMANN E, RAETHER H. Radiative decay of non-radiative surface plasmons excited by light［J］. Z. Naturforsch, 1968, 23A: 2135-2136.

[10] [10] MAHONEY W C , HOGG R W, HERMODSON M A. The amino acid sequence of the galactose binding protein f rom Escherichia coli ［J］ . Journal of Biological Chemistry, 1981, 256 (9) : 4350-4356.

[11] [11] WARE R A, ENSOR C M, DAUNERT S, et al.. A novel reagentless sensing system for measuring glucose based on the galactose/ glucose-binding protein［J］. Analytical Biochemistr, 2001, 294(1): 19-26.

[12] [12] MELENDEZ J R, BARTHOLOMEW D U. A commercial solution for surface plasmon sensing［J］. Sensors and Actuators B: Chemical, 1996, 35 (1-3): 212-216.

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[3] Yi Mingfang, Zhu Zusong, Li Lingli. Electric field properties of coupled structure based on silver nanocube and silver film[J]. Infrared and Laser Engineering, 2017, 46(7): 720003

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LI Da-chao, LI Guo-qing, ZHANG Jing-xin, YU Hai-xia, XU Ke-xin. Minimally-invasive blood glucose detection instrument based on surface plasmon resonance sensor decorated with GGBP[J]. Optics and Precision Engineering, 2013, 21(9): 2333

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