A Highly Sensitive Electrochemical Glucose Sensor By Nickel-Epoxy Electrode With Non-Enzymatic Sensor
electrode for electroanalysis of glucose in NaOH was R2 = 0.9984. LOQ, LOD and recovery of theÂ Nickel-Epoxy electrode towards glucose were found to be 4.4 Î¼M, 1.48 Î¼M and 98.19%, respectively.Â The Nickel-Epoxy wire based electrochemical glucose sensor demonstrates good sensitivity, wideÂ linear range, outstanding detection limit, attractive selectivity, good reproducibility, high stability asÂ well as prominent feasibility use of non-enzymatic sensor for monitoring glucose in human urineÂ owing to its advantages of low cost, simple preparation and excellent properties for glucose detection.
Chung, T.D. Park, S. and Boo, H., 2006, Electrochemical non-enzymatic glucose sensors, Anal. Chim. Acta, 556, 46â€“57.
Ding, Y. Wang, Y. Su, L. Zhang, H. and Lei, Y., 2010, Preparation and characterization of NiOâ€“Ag Nanoï¬bers, NiO nanoï¬bers, and porous Ag: towards the developmentof a highly sensitive and selective non-enzymatic glucose sensor, J. Mater. Chem. 20, 9918â€“9926.
Newman, J.D. and Turner, A.P.F., 2005, Home blood glucose biosensors: a commercial per-spective, Biosens. Bioelectron. 20, 2435â€“2453.
Nie, H.G. Yao, Z. Zhou, X.M. Yang, Z. and Huang, S.M., 2011, Nonenzymatic electrochemical detection of glucose using well-distributed nickel nanoparticles on straight multi-walled carbon nanotubes, Biosens. Bioelectron. 30, 28â€“34.
Peng, X. Yu, S.J. Cao, G.Z. Zhou, M. Qiao, L. Yao, J.Y. and He, H.C., 2012, Ni nanoparticles decorated titania nanotube arrays as efï¬cient nonenzymatic glucose sensor, Electrochim. Acta, 76, 512â€“517.
Pisoshi, A.M., Danet, A.F., and Negulscu, G.P., 2007, Influense of the buffer capacity on glucose potentiometric determination in synthetic solutions and in real sampels with different acidities, Pro. Rom, Acad., Series B, 75-81.
Shervedani, R.K. Motahareh. K. Akbar. A and Prickly, 2014, Nickel nanowires grown on Cu substrate as a supersensitive enzyme-free electrochemical glucose sensor, Sensor and actuator B: Chemical, 204, 783-790.
Shervedani, R.K. Mehrjardi, A.H., 2007, Electrochemical characterization of directly immobilized glucose oxidase on gold mercaptosuccinic anhydride self-assembled monolayer, Sens. Actuators B 126, 415â€“423.
Sun, A. Zheng, J. and Sheng, Q., 2012, A highly sensitive non-enzymatic glucose sensor based on nickel and multi-walled carbon nanotubes nanohybrid ï¬lmsfabricated by one-step co-electrodeposition in ionic liquids, Electrochim. Acta, 65, 64â€“69.
Tian, H. Jia, M. Zhang, M. and Hu, J., 2013, Nonenzymatic glucose sensor based on nickel ion implanted-modiï¬ed indium tin oxide electrode, Electrochim. Acta. 96, 285â€“290.
Turner, A.P.F. and Wilson, R. 1992, Glucose oxidase: an ideal enzyme, Biosens. Bioelectron. 7, 165â€“185.
Veeramani,V., Madhua,R., Chena,S.M., ,Veerakumar,P., Hungb, C.T, and Liub, S.B., 2015, Heteroatom-enriched porous carbon/nickel oxide nanocomposites as enzyme-free highly sensitive sensors for detection of glucose, Sensor and Actuators: B, 1384-1390
Wang, J., 2008, Electrochemical glucose biosensors, Chem. Rev. 108, 814â€“825.
Wang, L. Lu, X. Ye, Y. Sun, L. and Song Y., 2013, Nickel-cobalt nanostructures coated reduced graphene oxide nanocomposite electrode for nonenzymatic glucose biosensing, Electrochim. Acta 114, 484â€“493.
Yang. H., Chung. T.D. Kim, Y.T. Choi, C.A. Jun, C.H. and Kim, H.C. 2002, Glucose sensor using a microfabricated electrode and electropolymerized bilayer films, Biosens, Bioelectron,17, 251-259.
Metrics powered by PLOS ALM
Eksakta: Jurnal Ilmu-Ilmu MIPA
Journal of Mathematics and Natural Sciences