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    Journals >Chinese Journal of Lasers >Volume 45 >Issue 2 >Page 207003 > Article
    • Chinese Journal of Lasers
    • Vol. 45, Issue 2, 207003 (2018)
    Research Advances in Blood Glucose Monitoring System
    Sun Kai1、*, Zhou Hua1, Yang Yingkun1, and Wu Changfeng1、2
    Author Affiliations
  • 1[in Chinese]
  • 2[in Chinese]
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    DOI: 10.3788/CJL201845.0207003 Cite this Article Set citation alerts
    Sun Kai, Zhou Hua, Yang Yingkun, Wu Changfeng. Research Advances in Blood Glucose Monitoring System[J]. Chinese Journal of Lasers, 2018, 45(2): 207003 Copy Citation Text show less
    Pancreas's glucose regulatory pathways[13]
    Fig. 1. Pancreas's glucose regulatory pathways[13]
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    Bihormonal closed-loop insulin and glucagon delivery system[21]
    Fig. 2. Bihormonal closed-loop insulin and glucagon delivery system[21]
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    Nanotechnology-based glucose sensor technologies[23]
    Fig. 3. Nanotechnology-based glucose sensor technologies[23]
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    Three generations of amperometric enzyme electrodes for glucose based on the use of (a) natural oxygen cofacto, (b) artificial redox mediators (b), and (c) direct electron transfer between GOx and the electrode [45]
    Fig. 4. Three generations of amperometric enzyme electrodes for glucose based on the use of (a) natural oxygen cofacto, (b) artificial redox mediators (b), and (c) direct electron transfer between GOx and the electrode [45]
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    Cross section of a commercial strip for self-testing of blood glucose
    Fig. 5. Cross section of a commercial strip for self-testing of blood glucose
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    Sensor design of percutaneous (left) and fully implantable subcutaneous (right) biosensors
    Fig. 6. Sensor design of percutaneous (left) and fully implantable subcutaneous (right) biosensors
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    Images and schematic illustrations of the FISA for multiplexed perspiration analysis[61]
    Fig. 7. Images and schematic illustrations of the FISA for multiplexed perspiration analysis[61]
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    Schematic illustration of wearable sensor for tears analysis[62]
    Fig. 8. Schematic illustration of wearable sensor for tears analysis[62]
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    Schematic illustration of detection principle of LSPR-based optical enzyme biosensor[73]
    Fig. 9. Schematic illustration of detection principle of LSPR-based optical enzyme biosensor[73]
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    Schematic illustration of detection principle of H2O2-based optical enzyme biosensor
    Fig. 10. Schematic illustration of detection principle of H2O2-based optical enzyme biosensor
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    Schematic diagram of a layer-by-layer hydrogel pad and the entrapped Q-Concanavalin A/R_dextran glucose-sensing system[81]
    Fig. 11. Schematic diagram of a layer-by-layer hydrogel pad and the entrapped Q-Concanavalin A/R_dextran glucose-sensing system[81]
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    Schematic illustration of detection principle of PBA-based optical glucose biosensor[89]
    Fig. 12. Schematic illustration of detection principle of PBA-based optical glucose biosensor[89]
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    Schematic illustration of detection principle of PBA-SWNT-based near infrared optical glucose biosensor[99]
    Fig. 13. Schematic illustration of detection principle of PBA-SWNT-based near infrared optical glucose biosensor[99]
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    Schematic illustration of the injectable fluorescent microbeads for in vivo CGM[100]
    Fig. 14. Schematic illustration of the injectable fluorescent microbeads for in vivo CGM[100]
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    Schematic illustration of the formation of Pdot-GOx bioconjugates for in vivo glucose monitoring[106]
    Fig. 15. Schematic illustration of the formation of Pdot-GOx bioconjugates for in vivo glucose monitoring[106]
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    Sun Kai, Zhou Hua, Yang Yingkun, Wu Changfeng. Research Advances in Blood Glucose Monitoring System[J]. Chinese Journal of Lasers, 2018, 45(2): 207003
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