{"title":"硼酸修饰碳点荧光探针血糖仪的研制","authors":"A. Maddu, Sejahtera Ahmad, T. Sumaryada","doi":"10.4302/plp.v13i3.1080","DOIUrl":null,"url":null,"abstract":"A glucose meter has been developed utilizing boric acid-modified carbon dots as a fluorescence probe. Boric acid-modified carbon dots produces varying fluorescence emission with varying glucose concentration in water. Boric acid-modified carbon dots mixed with glucose addition was excited by a violet laser (405 nm), then the emission intensity was detected by a photodetector to be converted to an electrical signal that as an input signal for a microcontroller for glucose concentration measurement. The output voltage of the glucose meter is corresponding to the fluorescence emission measured by using a spectrofluorometer with glucose concentration in the boric acid-modified carbon dots. Full Text: PDF ReferencesH. Teymourian, A. Barfidokht, J. Wang, \"Electrochemical glucose sensors in diabetes management: an updated review (2010–2020)\", Chem. Soc. Rev. 49, 7671 (2020). CrossRef D.C. Klonoff, \"Overview of Fluorescence Glucose Sensing: A Technology with a Bright Future\", J Diabetes Sci. Technol. 6(6), 1242 (2012). CrossRef J.C. Pickup, F. Hussain, N.D. Evans, O.J. Rolinski, David J.S. Birch, \"Fluorescence-based glucose sensors\", Biosens. Bioelectron. 20, 2555 (2005). CrossRef H. Fang, G. Kaur, B. Wang, \"Progress in Boronic Acid-Based Fluorescent Glucose Sensors\", J. Fluoresc. 14(5), 481 (2004). CrossRef T. Kawanishi, M.A. Romey, P.C. Zhu, M.Z. Holody, S. Shinkai, \"A Study of Boronic Acid Based Fluorescent Glucose Sensors\", J. Fluoresc. 14(5), 499 (2004). CrossRef A.S. Krishna, P.A. Nair, C. Radhakumary, K. Sreenivasan, \"Carbon dot based non enzymatic approach for the detection and estimation of glucose in blood serum\", Mater. Res. Express 3(1), 055001 (2016). CrossRef G.P.C. Mello, E.F.C. Simões, D.M.A. Crista, J.M.M. Leitão, L. Pinto da Silva, J.C.G. Esteves da Silva, \"Glucose Sensing by Fluorescent Nanomaterials\", Crit. Rev. Anal. Chem. 49(6), 542 (2019). CrossRef X. Shan, L. Chai, J. Ma, Z. Qian, J. Chen, H. Feng, \"B-doped carbon quantum dots as a sensitive fluorescence probe for hydrogen peroxide and glucose detection\", Analyst 139, 2322 (2014). CrossRef J. Dong, S. Li, H. Wang, Q. Meng, L. Fan, H. Xie, C. Cao, W. Zhang, \"Simple Boric Acid-Based Fluorescent Focusing for Sensing of Glucose and Glycoprotein via Multipath Moving Supramolecular Boundary Electrophoresis Chip\", Anal. Chem. 85(12), 5884 (2013). CrossRef Y. Cui, F. Chen, X-B. Yin, \"A ratiometric fluorescence platform based on boric-acid-functional Eu-MOF for sensitive detection of H2O2 and glucose\", Biosens. Bioelectron. 135, 208 (2019). 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Boric acid-modified carbon dots mixed with glucose addition was excited by a violet laser (405 nm), then the emission intensity was detected by a photodetector to be converted to an electrical signal that as an input signal for a microcontroller for glucose concentration measurement. The output voltage of the glucose meter is corresponding to the fluorescence emission measured by using a spectrofluorometer with glucose concentration in the boric acid-modified carbon dots. Full Text: PDF ReferencesH. Teymourian, A. Barfidokht, J. Wang, \\\"Electrochemical glucose sensors in diabetes management: an updated review (2010–2020)\\\", Chem. Soc. Rev. 49, 7671 (2020). CrossRef D.C. Klonoff, \\\"Overview of Fluorescence Glucose Sensing: A Technology with a Bright Future\\\", J Diabetes Sci. Technol. 6(6), 1242 (2012). CrossRef J.C. Pickup, F. Hussain, N.D. Evans, O.J. Rolinski, David J.S. Birch, \\\"Fluorescence-based glucose sensors\\\", Biosens. Bioelectron. 20, 2555 (2005). CrossRef H. Fang, G. Kaur, B. Wang, \\\"Progress in Boronic Acid-Based Fluorescent Glucose Sensors\\\", J. Fluoresc. 14(5), 481 (2004). CrossRef T. Kawanishi, M.A. Romey, P.C. Zhu, M.Z. Holody, S. Shinkai, \\\"A Study of Boronic Acid Based Fluorescent Glucose Sensors\\\", J. Fluoresc. 14(5), 499 (2004). CrossRef A.S. Krishna, P.A. Nair, C. Radhakumary, K. Sreenivasan, \\\"Carbon dot based non enzymatic approach for the detection and estimation of glucose in blood serum\\\", Mater. Res. Express 3(1), 055001 (2016). CrossRef G.P.C. Mello, E.F.C. Simões, D.M.A. Crista, J.M.M. Leitão, L. Pinto da Silva, J.C.G. Esteves da Silva, \\\"Glucose Sensing by Fluorescent Nanomaterials\\\", Crit. Rev. Anal. Chem. 49(6), 542 (2019). CrossRef X. Shan, L. Chai, J. Ma, Z. Qian, J. Chen, H. Feng, \\\"B-doped carbon quantum dots as a sensitive fluorescence probe for hydrogen peroxide and glucose detection\\\", Analyst 139, 2322 (2014). CrossRef J. Dong, S. Li, H. Wang, Q. Meng, L. Fan, H. Xie, C. Cao, W. Zhang, \\\"Simple Boric Acid-Based Fluorescent Focusing for Sensing of Glucose and Glycoprotein via Multipath Moving Supramolecular Boundary Electrophoresis Chip\\\", Anal. Chem. 85(12), 5884 (2013). CrossRef Y. Cui, F. Chen, X-B. Yin, \\\"A ratiometric fluorescence platform based on boric-acid-functional Eu-MOF for sensitive detection of H2O2 and glucose\\\", Biosens. Bioelectron. 135, 208 (2019). 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引用次数: 0
摘要
利用硼酸修饰的碳点作为荧光探针开发了葡萄糖计。硼酸修饰的碳点随着水中葡萄糖浓度的变化而产生不同的荧光发射。通过紫激光(405nm)激发与添加葡萄糖混合的硼酸改性碳点,然后通过光电检测器检测发射强度,以将其转换为电信号,该电信号作为用于葡萄糖浓度测量的微控制器的输入信号。葡萄糖计的输出电压对应于通过使用具有硼酸改性碳点中的葡萄糖浓度的分光荧光计测量的荧光发射。全文:PDF参考文献H。Teymourian,A.Barfidokht,J.Wang,“糖尿病管理中的电化学葡萄糖传感器:最新综述(2010-2020)”,化学。Soc.修订版49/7671(2020)。CrossRef D.C.Klonoff,“荧光葡萄糖传感综述:一项前景光明的技术”,糖尿病科学杂志。Technol。6(6),1242(2012)。CrossRef J.C.Pickup,F.Hussain,N.D.Evans,O.J.Rolinski,David J.S.Birch,“基于荧光的葡萄糖传感器”,Biosens。生物电子。2022555(2005)。CrossRef H.Fang,G.Kaur,B.Wang,“硼酸基荧光葡萄糖传感器的研究进展”,J.Fluoresc。14(5),481(2004)。CrossRef T.Kawanishi,M.A.Romey,P.C.Zhu,M.Z.Holody,S.Shinkai,“硼酸基荧光葡萄糖传感器的研究”,J.Fluoresc。14(5),499(2004)。CrossRef A.S.Krishna,P.A.Nair,C.Radhakumary,K.Sreenivasan,“检测和估计血清中葡萄糖的基于碳点的非酶法”,Mater。Res.Express 3(1),055001(2016)。CrossRef G.P.C.Mello、E.F.C.Simões、D.M.A.Crista、J.M.M.Leitão、L.Pinto da Silva、J.C.G.Esteves da Silva,“荧光纳米材料的葡萄糖传感”,Crit。修订版分析。化学。49(6),542(2019)。CrossRef Shan,L.Chai,J.Ma,Z.Qian,J.Chen,H.Feng,“掺硼碳量子点作为过氧化氢和葡萄糖检测的灵敏荧光探针”,分析师1392322(2014)。CrossRef董,李,王,孟,范,谢,曹,张,“基于简单硼酸的多路径移动超分子边界电泳芯片检测葡萄糖和糖蛋白的荧光聚焦”,分析。化学。85(12),5884(2013)。交叉参考崔,陈,X-B。Yin,“基于硼酸功能性Eu-MOF的比率荧光平台,用于H2O2和葡萄糖的灵敏检测”,Biosens。生物电子。135208(2019)。CrossRef
Development of Glucose Meter Using Boric Acid-Modified Carbon Dots as Fluorescent Probe
A glucose meter has been developed utilizing boric acid-modified carbon dots as a fluorescence probe. Boric acid-modified carbon dots produces varying fluorescence emission with varying glucose concentration in water. Boric acid-modified carbon dots mixed with glucose addition was excited by a violet laser (405 nm), then the emission intensity was detected by a photodetector to be converted to an electrical signal that as an input signal for a microcontroller for glucose concentration measurement. The output voltage of the glucose meter is corresponding to the fluorescence emission measured by using a spectrofluorometer with glucose concentration in the boric acid-modified carbon dots. Full Text: PDF ReferencesH. Teymourian, A. Barfidokht, J. Wang, "Electrochemical glucose sensors in diabetes management: an updated review (2010–2020)", Chem. Soc. Rev. 49, 7671 (2020). CrossRef D.C. Klonoff, "Overview of Fluorescence Glucose Sensing: A Technology with a Bright Future", J Diabetes Sci. Technol. 6(6), 1242 (2012). CrossRef J.C. Pickup, F. Hussain, N.D. Evans, O.J. Rolinski, David J.S. Birch, "Fluorescence-based glucose sensors", Biosens. Bioelectron. 20, 2555 (2005). CrossRef H. Fang, G. Kaur, B. Wang, "Progress in Boronic Acid-Based Fluorescent Glucose Sensors", J. Fluoresc. 14(5), 481 (2004). CrossRef T. Kawanishi, M.A. Romey, P.C. Zhu, M.Z. Holody, S. Shinkai, "A Study of Boronic Acid Based Fluorescent Glucose Sensors", J. Fluoresc. 14(5), 499 (2004). CrossRef A.S. Krishna, P.A. Nair, C. Radhakumary, K. Sreenivasan, "Carbon dot based non enzymatic approach for the detection and estimation of glucose in blood serum", Mater. Res. Express 3(1), 055001 (2016). CrossRef G.P.C. Mello, E.F.C. Simões, D.M.A. Crista, J.M.M. Leitão, L. Pinto da Silva, J.C.G. Esteves da Silva, "Glucose Sensing by Fluorescent Nanomaterials", Crit. Rev. Anal. Chem. 49(6), 542 (2019). CrossRef X. Shan, L. Chai, J. Ma, Z. Qian, J. Chen, H. Feng, "B-doped carbon quantum dots as a sensitive fluorescence probe for hydrogen peroxide and glucose detection", Analyst 139, 2322 (2014). CrossRef J. Dong, S. Li, H. Wang, Q. Meng, L. Fan, H. Xie, C. Cao, W. Zhang, "Simple Boric Acid-Based Fluorescent Focusing for Sensing of Glucose and Glycoprotein via Multipath Moving Supramolecular Boundary Electrophoresis Chip", Anal. Chem. 85(12), 5884 (2013). CrossRef Y. Cui, F. Chen, X-B. Yin, "A ratiometric fluorescence platform based on boric-acid-functional Eu-MOF for sensitive detection of H2O2 and glucose", Biosens. Bioelectron. 135, 208 (2019). CrossRef
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