Graphene nanocomposites for transdermal biosensing.
glucose
graphene
hydrogen peroxide
microneedles
transdermal biosensing
Journal
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology
ISSN: 1939-0041
Titre abrégé: Wiley Interdiscip Rev Nanomed Nanobiotechnol
Pays: United States
ID NLM: 101508311
Informations de publication
Date de publication:
07 2021
07 2021
Historique:
revised:
23
12
2020
received:
07
11
2020
accepted:
26
12
2020
pubmed:
23
1
2021
medline:
5
11
2021
entrez:
22
1
2021
Statut:
ppublish
Résumé
Transdermal biosensors for the real-time and continuous detection and monitoring of target molecules represent an intriguing pathway for enhancing health outcomes in a cost-effective and non-invasive fashion. Many transdermal biosensor devices contain microneedles and other miniaturized components. There remains an unmet clinical need for microneedle transdermal biosensors to obtain a more accurate, rapid, and reliable insight into the real-time monitoring of disease. The ability to monitor biomarkers at an intradermal molecular level in a non-invasive manner remains the next technological gap to solve real-world clinical problems. The emergence of the two-dimensional material graphene with unique material properties and the ability to quantify analytes and physiological status can enable the detection of critical biomarkers indicative of human disease. The development of a user-friendly, affordable, and non-invasive transdermal biosensing device for continuous and personalized monitoring of target molecules could be beneficial for many patients. This focus article considers the use of graphene-based transdermal biosensors for health monitoring, evaluation of these sensors for glucose and hydrogen peroxide detection via in vitro, in vivo, and ex vivo studies, recent technological innovations, and potential challenges. This article is categorized under: Diagnostic Tools > Biosensing.
Substances chimiques
Graphite
7782-42-5
Types de publication
Journal Article
Review
Langues
eng
Sous-ensembles de citation
IM
Pagination
e1699Informations de copyright
© 2021 Wiley Periodicals LLC.
Références
Choi, C., Lee, Y., Cho, K. W., Koo, J. H., & Kim, D. H. (2018). Wearable and implantable soft bioelectronics using two-dimensional materials. Accounts of Chemical Research, 52(1), 73-81.
Chowdhury, S., & Balasubramanian, R. (2014). Recent advances in the use of graphene-family nanoadsorbents for removal of toxic pollutants from wastewater. Advances in Colloid and Interface Science, 204, 35-56.
Chung, C., Kim, Y. K., Shin, D., Ryoo, S. R., Hong, B. H., & Min, D. H. (2013). Biomedical applications of graphene and graphene oxide. Accounts of Chemical Research, 46(10), 2211-2224.
Coroş, M., Pruneanu, S., & Stefan-van Staden, R. I. (2019). Recent progress in the graphene-based electrochemical sensors and biosensors. Journal of the Electrochemical Society, 167(3), 037528.
Cuartero, M., Parrilla, M., & Crespo, G. A. (2019). Wearable potentiometric sensors for medical applications. Sensors, 19(2), 363.
Forrester, S. J., Kikuchi, D. S., Hernandes, M. S., Xu, Q., & Griendling, K. K. (2018). Reactive oxygen species in metabolic and inflammatory signaling. Circulation Research, 122(6), 877-902.
Geim, A. K. (2011). Nobel lecture: Random walk to graphene. Reviews of Modern Physics, 83(3), 851-862.
Henry, S., McAllister, D. V., Allen, M. G., & Prausnitz, M. R. (1998). Microfabricated microneedles: A novel approach to transdermal drug delivery. Journal of Pharmaceutical Sciences, 87(8), 922-925.
Hughes, M. D. (2009). The business of self-monitoring of blood glucose: A market profile. Journal of Diabetes Science and Technology, 3(5), 1219-1223.
Jiang, D., Du, X., Liu, Q., Zhou, L., Qian, J., & Wang, K. (2015). One-step thermal-treatment route to fabricate well-dispersed ZnO nanocrystals on nitrogen-doped graphene for enhanced electrochemiluminescence and ultrasensitive detection of pentachlorophenol. ACS Applied Materials & Interfaces, 7(5), 3093-3100.
Jin, Q., Chen, H. J., Li, X., Huang, X., Wu, Q., He, G., … Zhang, A. (2019). Reduced graphene oxide nanohybrid-assembled microneedles as mini-invasive electrodes for real-time transdermal biosensing. Small, 15(6), 1804298.
Kim, Y. C., Park, J. H., & Prausnitz, M. R. (2012). Microneedles for drug and vaccine delivery. Advanced Drug Delivery Reviews, 64(14), 1547-1568.
Krishnan, S. K., Singh, E., Singh, P., Meyyappan, M., & Nalwa, H. S. (2019). A review on graphene-based nanocomposites for electrochemical and fluorescent biosensors. RSC Advances, 9(16), 8778-8881.
Lipani, L., Dupont, B. G., Doungmene, F., Marken, F., Tyrrell, R. M., Guy, R. H., & Ilie, A. (2018). Non-invasive, transdermal, path-selective and specific glucose monitoring via a graphene-based platform. Nature Nanotechnology, 13(6), 504-511.
Liu, G. S., Kong, Y., Wang, Y., Luo, Y., Fan, X., Xie, X., Yang, B. R., & Wu, M. X. (2020). Microneedles for transdermal diagnostics: Recent advances and new horizons. Biomaterials, 232, 119740.
Liu, Y., Dong, X., & Chen, P. (2012). Biological and chemical sensors based on graphene materials. Chemical Society Reviews, 41(6), 2283-2307.
Niu, Z., Liu, L., Zhang, L., & Chen, X. (2014). Porous graphene materials for water remediation. Small, 10(17), 3434-3441.
Pandey, P. C., Shukla, S., Skoog, S. A., Boehm, R. D., & Narayan, R. J. (2019). Current advancements in transdermal biosensing and targeted drug delivery. Sensors, 19(5), 1028.
Perreault, F., De Faria, A. F., & Elimelech, M. (2015). Environmental applications of graphene-based nanomaterials. Chemical Society Reviews, 44(16), 5861-5896.
Pumera, M. (2010). Graphene-based nanomaterials and their electrochemistry. Chemical Society Reviews, 39(11), 4146-4157.
Pumera, M. (2011). Graphene in biosensing. Materials Today, 14(7-8), 308-315.
Qiao, Y., Li, X., Hirtz, T., Deng, G., Wei, Y., Li, M., & Shen, Y. (2019). Graphene-based wearable sensors. Nanoscale, 11(41), 18923-18945.
Seshadri, D. R., Li, R. T., Voos, J. E., Rowbottom, J. R., Alfes, C. M., Zorman, C. A., & Drummond, C. K. (2019). Wearable sensors for monitoring the physiological and biochemical profile of the athlete. NPJ Digital Medicine, 2(1), 1-16.
Shamkhalichenar, H., & Choi, J. W. (2020). Non-enzymatic hydrogen peroxide electrochemical sensors based on reduced graphene oxide. Journal of the Electrochemical Society, 167(3), 037531.
Shi, G., Lowe, S. E., Teo, A. J., Dinh, T. K., Tan, S. H., Qin, J., … Zhao, H. (2019). A versatile PDMS submicrobead/graphene oxide nanocomposite ink for the direct ink writing of wearable micron-scale tactile sensors. Applied Materials Today, 16, 482-492.
Shi, G., Zhao, Z., Pai, J. H., Lee, I., Zhang, L., Stevenson, C., Ishara, K., Zhang, R., Zhu, H., & Ma, J. (2016). Highly sensitive, wearable, durable strain sensors and stretchable conductors using graphene/silicon rubber composites. Advanced Functional Materials, 26(42), 7614-7625.
Singh, E., Meyyappan, M., & Nalwa, H. S. (2017). Flexible graphene-based wearable gas and chemical sensors. ACS Applied Materials & Interfaces, 9(40), 34544-34586.
Son, D., Lee, J., Qiao, S., Ghaffari, R., Kim, J., Lee, J. E., & Yang, S. (2014). Multifunctional wearable devices for diagnosis and therapy of movement disorders. Nature Nanotechnology, 9(5), 397-404.
Tabish, T. A. (2018). Graphene-based materials: The missing piece in nanomedicine? Biochemical and Biophysical Research Communications, 504(4), 686-689.
Tabish, T. A., Pranjol, M. Z. I., Horsell, D. W., Rahat, A. A., Whatmore, J. L., Winyard, P. G., & Zhang, S. (2019). Graphene oxide-based targeting of extracellular cathepsin D and cathepsin L as a novel anti-metastatic enzyme cancer therapy. Cancers, 11(3), 319.
Tabish, T. A., Pranjol, M. Z. I., Jabeen, F., Abdullah, T., Latif, A., Khalid, A., & Zhang, S. (2018). Investigation into the toxic effects of graphene nanopores on lung cancer cells and biological tissues. Applied Materials Today, 12, 389-401.
Tabish, T. A., Zhang, S., & Winyard, P. G. (2018). Developing the next generation of graphene-based platforms for cancer therapeutics: The potential role of reactive oxygen species. Redox Biology, 15, 34-40.
Takeuchi, K., & Kim, B. (2018). Functionalized microneedles for continuous glucose monitoring. Nano Convergence, 5(1), 1-10.
Tasca, F., Tortolini, C., Bollella, P., & Antiochia, R. (2019). Microneedle-based electrochemical devices for transdermal biosensing: A review. Current Opinion in Electrochemistry, 16, 42-49.
Teymourian, H., Moonla, C., Tehrani, F., Vargas, E., Aghavali, R., Barfidokht, A., & Wang, J. (2019). Microneedle-based detection of ketone bodies along with glucose and lactate: Toward real-time continuous interstitial fluid monitoring of diabetic ketosis and ketoacidosis. Analytical Chemistry, 92(2), 2291-2300.
Tiangco, C., Fon, D., Sardesai, N., Kostov, Y., Sevilla, F., III, Rao, G., & Tolosa, L. (2017). Fiber optic biosensor for transdermal glucose based on the glucose binding protein. Sensors and Actuators B: Chemical, 242, 569-576.
Toi, P. T., Trung, T. Q., Dang, T. M. L., Bae, C. W., & Lee, N. E. (2019). Highly electrocatalytic, durable, and stretchable nanohybrid fiber for on-body sweat glucose detection. ACS Applied Materials & Interfaces, 11(11), 10707-10717.
Tonyushkina, K., & Nichols, J. H. (2009). Glucose meters: A review of technical challenges to obtaining accurate results. Journal of Diabetes Science and Technology, 3(4), 971-980.
Torrente-Rodríguez, R. M., Tu, J., Yang, Y., Min, J., Wang, M., Song, Y., & Gao, W. (2020). Investigation of cortisol dynamics in human sweat using a graphene-based wireless mHealth system. Matter, 2(4), 921-937.
Turner, A. P. (2013). Biosensors: sense and sensibility. Chemical Society Reviews, 42(8), 3184-3196.
Ventrelli, L., Marsilio Strambini, L., & Barillaro, G. (2015). Microneedles for transdermal biosensing: Current picture and future direction. Advanced Healthcare Materials, 4(17), 2606-2640.
Wang, M., Hu, L., & Xu, C. (2017). Recent advances in the design of polymeric microneedles for transdermal drug delivery and biosensing. Lab on a Chip, 17(8), 1373-1387.
Wang, Z., Hao, Z., Wang, X., Huang, C., Lin, Q., Zhao, X., & Pan, Y. (2020). A flexible and regenerative aptameric graphene-Nafion biosensor for cytokine storm biomarker monitoring in undiluted biofluids toward wearable applications. Advanced Functional Materials, 2005958. https://doi.org/10.1002/adfm.202005958.
Windmiller, J. R., Valdés-Ramírez, G., Zhou, N., Zhou, M., Miller, P. R., Jin, C., & Wang, J. (2011). Bicomponent microneedle array biosensor for minimally-invasive glutamate monitoring. Electroanalysis, 23(10), 2302-2309.
Yang, J., Luo, S., Zhou, X., Li, J., Fu, J., Yang, W., & Wei, D. (2019). Flexible, tunable, and ultrasensitive capacitive pressure sensor with microconformal graphene electrodes. ACS Applied Materials & Interfaces, 11(16), 14997-15006.
Zhou, Y., Fang, Y., & Ramasamy, R. P. (2019). Non-covalent functionalization of carbon nanotubes for electrochemical biosensor development. Sensors, 19(2), 392.
Zhu, H., Tamura, T., Fujisawa, A., Nishikawa, Y., Cheng, R., Takato, M., & Hamachi, I. (2020). Imaging and profiling of proteins under oxidative conditions in cells and tissues by hydrogen-peroxide-responsive labeling. Journal of the American Chemical Society, 142(37), 15711-15721.