“A review of classifications of enzymatic and non-enzymatic electrodes-based nano-carbon for detection of glucose”

المؤلفون

  • Wed Al-Graiti College of Dentistry, University of Thi-Qar, Thi-Qar, Iraq

DOI:

https://doi.org/10.32792/jeps.v11i2.118

الكلمات المفتاحية:

GLUCOSE DETECTION، ELECTROCHEMICAL SENSORS، CARBON NANOTUBES، GRAPHENE، ENZYMATIC AND NON-ENZYMATIC GLUCOSE SENSORS

الملخص

In recent years, the number of people having diabetes mellitus is steadily increasing in countries known by low and middle income. Millions of them have been diagnosed with high blood sugar. Diabetes mellitus is related to irregular carbohydrates metabolism with difficulty managing blood glucose which by the time leads to serious damage to nervous system or even macrovascular, or blood vessels. Therefore, the demand for advanced devices for glucose monitoring is highly growing. A bio-sensor is a signal detecting device generated from reactions either biological or chemical. They can be used for many purposes, for example, detection of biological molecules using in vitro and in vivo samples. Electrochemical sensors represent one of the technologies could be used for this purpose. It shows high sensitivity and mechanical strength while utilizing in physiological conditions which is a promising advantage for glucose determination. The aim of current study is to review electrodes generations for glucose detection, as well as, commonly prepared and investigated electrochemical electrodes for glucose determination. In addition, types of glucose electrodes have been mentioned here based carbon nanotubes and/or graphene as excellently conductive, stable, reproducible, and sensitive materials. The aim of current study is listing and discussing the progression of glucose generations as well as the development of glucose sensors in recent years. Enzymatic and non-enzymatic nanocarbon sensors were mainly studies and classified as glucose sensors also explained with further details regarding limit of detection

المراجع

REFERENCES: 1. Si, P., et al., Nanomaterials for electrochemical non-enzymatic glucose biosensors. RSC Advances, 2013. 3: p. 3487-3502. 2. Tian, K., M. Prestgard, and A. Tiwari, A review of recent advances in nonenzymatic glucose sensors. Materials science & engineering. C, Materials for biological applications, 2014. 41C: p. 100-118. 3. Yoo, E.H. and S.Y. Lee, Glucose biosensors: an overview of use in clinical practice. Sensors (Basel), 2010. 10(5): p. 4558-76. 4. Yoo, E.-H. and S.-Y. Lee, Glucose biosensors: an overview of use in clinical practice. Sensors (Basel, Switzerland), 2010. 10(5): p. 4558-4576. 5. Zhang, Z.-Y., et al., Molecular Mechanisms of Glucose Fluctuations on Diabetic Complications. Frontiers in Endocrinology, 2019. 10(640). 6. Sridara, T., et al., Non-Enzymatic Amperometric Glucose Sensor Based on Carbon Nanodots and Copper Oxide Nanocomposites Electrode. Sensors, 2020. 20(3): p. 808. 7. Mujeeb-U-Rahman, M., D. Adalian, and A. Scherer, Fabrication of Patterned Integrated Electrochemical Sensors. Journal of Nanotechnology, 2015: p. 467190. 8. Bezzon, V.D.N., et al., Carbon Nanostructure-based Sensors: A Brief Review on Recent Advances. Advances in Materials Science and Engineering, 2019: p. 4293073. 9. You, W., et al., Electrochemical Sensors for Clinic Analysis. Sensors, 2008. 8. 10. Li, R., et al., A flexible and physically transient electrochemical sensor for real-time wireless nitric oxide monitoring. Nature Communications, 2020. 11(1): p. 3207. 11. Negut Cioates, C., Review—Electrochemical Sensors Used in the Determination of Riboflavin. Journal of The Electrochemical Society, 2020. 167(3): p. 037558. 12. Zhu, Z., et al., A critical review of glucose biosensors based on carbon nanomaterials: carbon nanotubes and graphene. Sensors (Basel, Switzerland), 2012. 12(5): p. 5996-6022. 13. Wang, J., Electrochemical Glucose Biosensors. Chemical Reviews, 2008. 108(2): p. 814-825. 14. Hassan, M.H., et al., Recent Advances in Enzymatic and Non-Enzymatic Electrochemical Glucose Sensing. Sensors, 2021. 21(14): p. 4672. 15. Park, S., H. Boo, and T.D. Chung, Electrochemical non-enzymatic glucose sensors. Analytica Chimica Acta, 2006. 556(1): p. 46-57. 16. Zhu, Z., et al., A Critical Review of Glucose Biosensors Based on Carbon Nanomaterials: Carbon Nanotubes and Graphene. Sensors, 2012. 12(5): p. 5996-6022. 17. Vigneshvar, S., et al., Recent Advances in Biosensor Technology for Potential Applications – An Overview. Frontiers in Bioengineering and Biotechnology, 2016. 4(11). 18. Bhalla, N., et al., Introduction to biosensors. Essays Biochem, 2016. 60(1): p. 1-8. 19. Zhu, Z., An Overview of Carbon Nanotubes and Graphene for Biosensing Applications. NanoMicro Letters, 2017. 9(3): p. 25. 20. Cho, I.-H., D.H. Kim, and S. Park, Electrochemical biosensors: perspective on functional nanomaterials for on-site analysis. Biomaterials Research, 2020. 24(1): p. 6. 21. Grieshaber, D., et al., Electrochemical Biosensors - Sensor Principles and Architectures. Sensors (Basel), 2008. 8(3): p. 1400-1458. 22. Current Advances in Biosensor Design and Fabrication, in Encyclopedia of Analytical Chemistry. p. 1-25. 23. Pineda, S., Z.J. Han, and K. Ostrikov, Plasma-Enabled Carbon Nanostructures for Early Diagnosis of Neurodegenerative Diseases. Materials (Basel, Switzerland), 2014. 7(7): p. 4896-4929.

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Su, S., et al., Nanomaterials-based sensors for applications in environmental monitoring. Journal of Materials Chemistry, 2012. 22(35): p. 18101-18110. 25. Thévenot, D.R., et al., Electrochemical biosensors: recommended definitions and classification. Biosens Bioelectron, 2001. 16(1-2): p. 121-31. 26. Panjan, P., V. Virtanen, and A.M. Sesay, Determination of stability characteristics for electrochemical biosensors via thermally accelerated ageing. Talanta, 2017. 170: p. 331-336. 27. Some, S., et al., Highly Sensitive and Selective Gas Sensor Using Hydrophilic and Hydrophobic Graphenes. Scientific Reports, 2013. 3(1): p. 1868. 28. Munonde, T.S. and P.N. Nomngongo, Nanocomposites for Electrochemical Sensors and Their Applications on the Detection of Trace Metals in Environmental Water Samples. Sensors, 2021. 21(1): p. 131. 29. Zhang, S., G. Wright, and Y. Yang, Materials and techniques for electrochemical biosensor design and construction. Biosensors & bioelectronics, 2000. 15: p. 273-82. 30. Tîlmaciu, C.-M. and M.C. Morris, Carbon nanotube biosensors. Frontiers in Chemistry, 2015. 3(59). 31. Ameta, R., et al., Carbon Nanotubes as Chemical Sensors and Biosensors: A Review. 2019. 32. Hu, C. and S. Hu, Carbon Nanotube-Based Electrochemical Sensors: Principles and Applications in Biomedical Systems. Journal of Sensors, 2009: p. 187615. 33. Tilmaciu, C. and M. Morris, Carbon Nanotube Biosensors. Frontiers in Chemistry, 2015. 3. 34. Shao, Y., et al., Graphene Based Electrochemical Sensors and Biosensors: A Review. Electroanalysis, 2010. 22(10): p. 1027-1036. 35. Fang, Y. and E. Wang, Electrochemical biosensors on platforms of graphene. Chemical Communications, 2013. 49(83): p. 9526-9539. 36. Chaohe, X., et al., Graphene-based electrodes for electrochemical energy storage. Energy & Environmental Science, 2013. 6: p. 1388-1414. 37. Nikoleli, G.-P., et al., Nanobiosensors Based on Graphene Electrodes: Recent Trends and Future Applications. 2018. p. 161-177. 38. Szunerits, S. and R. Boukherroub, Graphene-based nanomaterials in innovative electrochemistry. Current Opinion in Electrochemistry, 2018. 10: p. 24-30. 39. Al-Graiti, W., et al., Hybrid Graphene/Conducting Polymer Strip Sensors for Sensitive and Selective Electrochemical Detection of Serotonin. ACS Omega, 2019. 4(26): p. 22169-22177. 40. Shestakova, M. and M. Sillanpää, Electrode materials used for electrochemical oxidation of organic compounds in wastewater. Reviews in Environmental Science and Bio/Technology, 2017. 16(2): p. 223-238. 41. Yan, Y., et al., Noble metal-based materials in high-performance supercapacitors. Inorganic Chemistry Frontiers, 2017. 4(1): p. 33-51. 42. Yoo, H. and K. Kim, Reuse of indium tin oxide film electrode in electrochemical application. Electrochemistry Communications, 2013. 34: p. 64–67. 43. Muzyka, K., et al., Boron-doped diamond: current progress and challenges in view of electroanalytical applications. Analytical Methods, 2019. 11(4): p. 397-414. 44. Hu, Q., et al., Carbon-Based Nanomaterials as Novel Nanosensors. Journal of Nanomaterials, 2017. 2017: p. 3643517. 45. Carneiro, P., S. Morais, and M.C. Pereira, Nanomaterials towards Biosensing of Alzheimer's Disease Biomarkers. Nanomaterials (Basel, Switzerland), 2019. 9(12): p. 1663.

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Aqel, A., et al., Carbon nanotubes, science and technology part (I) structure, synthesis and characterisation. Arabian Journal of Chemistry, 2012. 5(1): p. 1-23. 47. Pandey, P. and M. Dahiya, Carbon nanotubes: Types, methods of preparation and applications. International Journal of Pharmaceutical Science and Research, 2016. 1: p. 15-21. 48. Al-Graiti, W., et al., Probe Sensor Using Nanostructured Multi-Walled Carbon Nanotube Yarn for Selective and Sensitive Detection of Dopamine. Sensors (Basel, Switzerland), 2017. 17. 49. Yang, G., et al., Structure of graphene and its disorders: a review. Science and technology of advanced materials, 2018. 19(1): p. 613-648. 50. Palanisamy, S., S. Ku, and S.-M. Chen, Dopamine sensor based on a glassy carbon electrode modified with a reduced graphene oxide and palladium nanoparticles composite. Microchimica Acta, 2013. 180(11): p. 1037-1042. 51. Smith, A.T., et al., Synthesis, properties, and applications of graphene oxide/reduced graphene oxide and their nanocomposites. Nano Materials Science, 2019. 1(1): p. 31-47. 52. Brownson, D.A.C., G.C. Smith, and C.E. Banks, Graphene oxide electrochemistry: the electrochemistry of graphene oxide modified electrodes reveals coverage dependent beneficial electrocatalysis. Royal Society Open Science, 2017. 4(11): p. 171128. 53. Ray, S., Chapter 2. Application and Uses of Graphene Oxide and Reduced Graphene Oxide. 2015. p. 39-55. 54. Zhang, D., et al., Direct electrodeposion of reduced graphene oxide and dendritic copper nanoclusters on glassy carbon electrode for electrochemical detection of nitrite. Electrochimica Acta, 2013. 107: p. 656-663. 55. Camargo, J.S.G.d., et al., Morphological and Chemical Effects of Plasma Treatment with Oxygen (O2) and Sulfur Hexafluoride (SF6) on Cellulose Surface. Materials Research, 2017. 20: p. 842850. 56. Ma, K., et al., A study of the effect of oxygen plasma treatment on the interfacial properties of carbon fiber/epoxy composites. Journal of Applied Polymer Science, 2010. 118(3): p. 1606-1614. 57. Rhee, K.Y., et al., Effect of oxygen plasma-treated carbon fibers on the tribological behavior of oilabsorbed carbon/epoxy woven composites. Composites Part B: Engineering, 2012. 43(5): p. 23952399. 58. Chen, Z. and L.Y.L. Wu, CHAPTER 14 - Scratch resistance of protective sol-gel coatings on polymeric substrates, in Tribology and Interface Engineering Series, K. Friedrich and A.K. Schlarb, Editors. 2008, Elsevier. p. 325-353. 59. Grill, A., Cold Plasma Materials Fabrication: From Fundamentals to Applications. 1994: Wiley. 60. Gerard, M., A. Chaubey, and B.D. Malhotra, Application of conducting polymers to biosensors. Biosens Bioelectron, 2002. 17(5): p. 345-59. 61. Xiao, Y., et al., Surface modification of neural probes with conducting polymer poly(hydroxymethylated-3,4-ethylenedioxythiophene) and its biocompatibility. Applied Biochemistry and Biotechnology, 2006. 128(2): p. 117-129. 62. Pontius, K., et al., Automated Electrochemical Glucose Biosensor Platform as an Efficient Tool Toward On-Line Fermentation Monitoring: Novel Application Approaches and Insights. Frontiers in Bioengineering and Biotechnology, 2020. 8(436). 63. Lee, H., et al., Enzyme-Based Glucose Sensor: From Invasive to Wearable Device. Advanced Healthcare Materials, 2018. 7(8): p. 1701150.

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Teymourian, H., A. Barfidokht, and J. Wang, Electrochemical glucose sensors in diabetes management: an updated review (2010–2020). Chemical Society Reviews, 2020. 49(21): p. 76717709. 65. Updike, S.J., et al., Enzymatic glucose sensors. Improved long-term performance in vitro and in vivo. Asaio j, 1994. 40(2): p. 157-63. 66. Folly, R., et al., THE DEVELOPMENT OF ENZYMATIC SENSORS FOR THE CONTINUOUS MONITORING OF GLUCOSE AND SUCROSE. Brazilian Journal of Chemical Engineering, 1997. 14. 67. Munawar, A., et al., Nanosensors for diagnosis with optical, electric and mechanical transducers. RSC Advances, 2019. 9(12): p. 6793-6803. 68. Zhao, Z., et al., Multiple functionalization of multi-walled carbon nanotubes with carboxyl and amino groups. Applied Surface Science, 2013. 276: p. 476–481. 69. Viswanathan, S., et al., Graphene–protein field effect biosensors: glucose sensing. Materials Today, 2015. 18(9): p. 513-522. 70. Zhang, Y., et al., Nonenzymatic glucose sensor based on graphene oxide and electrospun NiO nanofibers. Sensors and Actuators B: Chemical, 2012. 171-172: p. 580-587. 71. Sakr, M.A., et al., Performance-Enhanced Non-Enzymatic Glucose Sensor Based on GrapheneHeterostructure. Sensors, 2020. 20(1): p. 145. 72. Zhang, M., et al., Highly sensitive glucose sensors based on enzyme-modified whole-graphene solution-gated transistors. Scientific Reports, 2015. 5(1): p. 8311. 73. Wang, R., et al., Solution-gated graphene transistor based sensor for histamine detection with gold nanoparticles decorated graphene and multi-walled carbon nanotube functionalized gate electrodes. Food Chemistry, 2021. 347: p. 128980. 74. Juska, V.B. and M.E. Pemble, A Critical Review of Electrochemical Glucose Sensing: Evolution of Biosensor Platforms Based on Advanced Nanosystems. Sensors (Basel), 2020. 20(21). 75. Cui, Y., et al., Study on Glucose Sensing Materials Based on CNT/Graphene-Ag Composite for Nano-Electrode Sensor. ECS Meeting Abstracts, 2020. MA2020-02(68): p. 3549-3549. 76. Saei, A.A., et al., Electrochemical biosensors for glucose based on metal nanoparticles. TrAC Trends in Analytical Chemistry, 2013. 42: p. 216-227. 77. Anamaria, B., et al., Non-Enzymatic Electrochemical Determination of Glucose on Silver-Doped Zeolite-CNT Composite Electrode. Advanced Science, Engineering and Medicine, 2011. 3: p. 1319. 78. Cai, D., et al., Glucose sensors made of novel carbon nanotube-gold nanoparticle composites. Biofactors, 2007. 30(4): p. 271-7. 79. Akrema and Rahisuddin, Metal Nanoparticles as Glucose Sensor, in Nanomaterials and Their Applications, Z.H. Khan, Editor. 2018, Springer Singapore: Singapore. p. 143-168. 80. Carbone, M., L. Gorton, and R. Antiochia, An Overview of the Latest Graphene-Based Sensors for Glucose Detection: the Effects of Graphene Defects. Electroanalysis, 2015. 27. 81. Jui-Lin, L., et al. Electrochemical enzyme-electrode biosensor for Glucose detection. in 2008 International Conference on Communications, Circuits and Systems. 2008. 82. Huang, H., et al., Graphene-Based Sensors for Human Health Monitoring. Frontiers in Chemistry, 2019. 7(399).

التنزيلات

منشور

2022-04-07