Novel nanostructured MIL-101(Cr)/XC-72 modified electrode sensor: A highly sensitive and selective determination of chloramphenicol

Sensors and Actuators, B: Chemical

Volumn 247, Issue , 2017, Pages 756-764

  Zhang, Wanqing ^a,b   Zhang, Zhongyin ^b   Li, Yuanchao ^b   Chen, Jun ^b   Li, Xiaobo ^b   Zhang, Yadong ^a   Zhang, Yuping ^b  

^a ZHENGZHOU UNIVERSITY   (China)

^b HENAN INSTITUTE OF SCIENCE AND TECHNOLOGY   (China)

Author keywords

Characterization; Chloramphenicol; Electrochemical sensor; MIL 101(Cr) XC 72; Recoveries

Indexed keywords

ANTIBIOTICS; CHARACTERIZATION; CYCLIC VOLTAMMETRY; GLASS MEMBRANE ELECTRODES; RECOVERY;

CHLORAMPHENICOL; DIFFERENTIAL PULSE VOLTAMMETRY; ELECTROCHEMICAL PERFORMANCE; MIL-101(CR)/XC-72; MODIFIED GLASSY CARBON ELECTRODE; OPTIMIZED CONDITIONS; PHOSPHATE BUFFER SOLUTIONS; SELECTIVE DETERMINATION;

ELECTROCHEMICAL SENSORS;

EID: 85016319699     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.snb.2017.03.104     Document Type: Article

References (61)

1. [1] Kim, D.M., Rahman, M.A., Do, M.H., Ban, C., Shim, Y.B., An amperometric chloramphenicol immunosensor based on cadmium sulfide nanoparticles modified-dendrimer bonded conducting polymer. Biosens. Bioelectron. 25 (2010), 1781–1788.
2. [2] Miao, Y., Gan, N., Li, T., Cao, Y., Hu, F., Chen, Y., An ultrasensitive fluorescence aptasensor for chloramphenicol based on FRET between quantum dots as donor and the magnetic SiO2@Au NPs probe as acceptor with exonuclease-assisted target recycling. Sensor. Actuators B-Chem. 222 (2016), 1066–1072.
3. [3] Rodríguez, J.L.S., García, M.E.D., Fluorescent competitive flow-through assay for chloramphenicol using molecularly imprinted polymers. Biosens. Bioelectron. 16 (2001), 955–961.
4. [4] Šatínský, D., Chocholouš, P., Salabová, M., Solich, P., Simple determination of betamethasone and chloramphenicol in a pharmaceutical preparation using a short monolithic column coupled to a sequential injection system. J. Sep. Sci. 29 (2006), 2494–2499.
5. [5] Stidl, R., Markl, M.C., Sample clean-up by sol-gel immunoaffinity chromatography for determination of chloramphenicol in shrimp. J. Sol-Gel Sci. Technol. 41 (2007), 175–183.
6. [6] Chen, H., Chen, H., Ying, J., Huang, J., Liao, L., Dispersive liquid-liquid microextraction followed by high-performance liquid chromatography as an efficient and sensitive technique for simultaneous determination of chloramphenicol and thiamphenicol in honey. Anal. Chim. Acta 632 (2009), 80–85.
7. [7] Zhang, S., Liu, Z., Guo, X., Cheng, L., Wang, Z., Shen, J., Simultaneous determination and confirmation of chloramphenicol thiamphenicol, florfenicol and florfenicol amine in chicken muscle by liquid chromatography-tandem mass spectrometry. J. Chromatogr. B 875 (2008), 399–404.
8. [8] Van de riet, J.M., Potter, R.A., Fougere, M.C., Burns, B.G., Simultaneous determination of residues of chloramphenicol, thiamphenicol, florfenicol, and florfenicol amine in farmed aquatic species by liquid chromatography/mass spectrometry. J. AOAC Int. 86 (2003), 510–514.
9. [9] Impens, S., Reybroeck, W., Vercammen, J., Courtheyn, D., Ooghe, S., De Wasch, K., Smedts, W., De Brabander, H., Screening and confirmation of chloramphenicol in shrimp tissue using ELISA in combination with GC–MS2 and LC–MS2. Anal. Chim. Acta 483 (2003), 153–163.
10. [10] Zhuang, Y.F., Zhu, S.N., Wei, W., Li, J.L., Flow-injection chemiluminescence method for the determination of chloramphenicol based on luminol-sodium periodate order-transform second-chemiluminescence reaction. J. Lumin. 26 (2011), 696–702.
11. [11] Taylor, B.G., Palomeque, M., García Mateo, J.V., Calatayud, J.M., Photoinduced chemiluminescence of pharmaceuticals. J. Pharm. Biomed. Anal. 41 (2006), 347–357.
12. 12] Mamani, M.C.V., Farfan, J.A., Reyes, F.G.R., Silva, J.A.F.D., Rath, S., Use of experimental design and effective mobility calculations to develop a method for the determination of antimicrobials by capillary electrophoresis. Talanta 76 (2008), 1006–1014.
13. [13] Sun, M., Ding, B., Lin, J., Yu, J., Sun, G., Three-dimensional sensing membrane functionalized quartz crystal microbalance biosensor for chloramphenicol detection in real time. Sensor. Actuators B-Chem. 160 (2011), 428–434.
14. [14] Yang, T., Chen, H., Ge, T., Wang, J., Li, W., Jiao, K., Highly sensitive determination of chloramphenicol based on thin-layered MoS2/polyaniline nanocomposite. Talanta 144 (2015), 1324–1328.
15. [15] Yang, R., Zhao, J., Chen, M., Yang, T., Luo, S., Jiao, K., Electrocatalytic determination of chloramphenicol based on molybdenum disulfide nanosheets and self-doped polyaniline. Talanta 131 (2015), 619–623.
16. [16] Yadav, S.K., Agrawal, B., Chandra, P., Goyal, R.N., In vitro chloramphenicol detection in a haemophilus influenza model using an aptamer-polymer based electrochemical biosensor. Biosens. Bioelectron. 55 (2014), 337–342.
17. [17] Borowiec, J., Wang, R., Zhu, L., Zhang, J., Synthesis of nitrogen-doped graphene nanosheets decorated with gold nanoparticles as an improved sensor for electrochemical determination of chloramphenicol. Electrochim. Acta 99 (2013), 138–144.
18. [18] Ebarvia, B.S., Ubando, I.E., Sevilla, F.B., Biomimetic piezoelectric quartz crystal sensor with chloramphenicol-imprinted polymer sensing layer. Talanta 144 (2015), 1260–1265.
19. [19] Codognoto, L., Winter, E., Doretto, K.M., Monteiro, G.B., Rath, S., Electroanalytical performance of self-assembled monolayer gold electrode for chloramphenicol determination. Microchim. Acta 169 (2010), 345–351.
20. [20] Rosy, R., Goyal, R.N., Shim, Y.B., Glutaraldehyde sandwiched amino functionalized polymer based aptasensor for the determination and quantification of chloramphenicol. RSC Adv. 5 (2015), 69356–69364.
21. [21] Wang, C., Du, J., Wang, H., Zou, C.E., Jiang, F., Yang, P., Du, Y., A facile electrochemical sensor based on reduced graphene oxide and Au nanoplates modified glassy carbon electrode for simultaneous detection of ascorbic acid, dopamine and uric acid. Sensor. Actuators B-Chem. 204 (2014), 302–309.
22. [22] Zou, C., Yang, B., Bin, D., Wang, J., Li, S., Yang, P., Wang, C., Shiraishi, Y., Du, Y., Electrochemical synthesis of gold nanoparticles decorated flower-like graphene for high sensitivity detection of nitrite. J. Colloid Interface Sci. 488 (2017), 135–141.
23. [23] Asl, E.H., Dardenne, F., Blust, R., De Wael, K., An improved electrochemical aptasensor for chloramphenicol detection based on aptamer incorporated gelatine. Sensors 15 (2015), 7605–7618.
24. [24] Tu, W., Lei, J., Ding, L., Ju, H., Sandwich nanohybrid of single-walled carbon nanohorns-TiO2-porphyrin for electrocatalysis and amperometric biosensing towards chloramphenicol. Chem. Commun. 28 (2009), 4227–4229.
25. [25] Mukherjee, S., Kansara, A.M., Saha, D., Gonnade, R., Mullangi, D., Manna, B., Desai, A.V., Thorat, S.H., Singh, P.S., Mukherjee, A., Ghosh, S.K., An ultrahydrophobic fluorous metal-organic framework derived recyclable composite as a promising platform to tackle marine oil spills. Chemistry 22 (2016), 10937–10943.
26. [26] Pundir, C.S., Narwal, V., Batra, B., Determination of lactic acid with special emphasis on biosensing methods: a review. Biosens. Bioelectron. 86 (2016), 777–790.
27. [27] Stock, N., Biswas, S., Synthesis of metal-organic frameworks (MOFs): routes to various MOF topologies, morphologies, and composites. Chem. Rev. 112 (2012), 933–969.
28. [28] Davydovskaya, P., Pohle, R., Tawil, A., Fleischer, M., Work function based gas sensing with Cu-BTC metal-organic framework for selective aldehyde detection. Sensor. Actuators B-Chem. 187 (2013), 142–146.
29. [29] Wan, X., Wu, L., Zhang, L., Song, H., Lv, Y., Novel metal-organic frameworks-based hydrogen sulfide cataluminescence sensors. Sensor. Actuators B-Chem. 220 (2015), 614–621.
30. [30] Wang, Z., Liu, H., Wang, S., Rao, Z., Yang, Y., A luminescent Terbium-Succinate MOF thin film fabricated by electrodeposition for sensing of Cu2+ in aqueous environment. Sensor. Actuators B-Chem. 220 (2015), 779–787.
31. [31] Fernandes, D.M., Barbosa, A.D.S., Pires, J., Balula, S.S., Silva, L.C., Freire, C., Novel composite material polyoxovanadate@MIL-101(Cr): a highly efficient electrocatalyst for ascorbic acid oxidation. ACS Appl. Mater. Interfaces 5 (2013), 13382–13390.
32. [32] Bromberg, L., Hatton, T.A., Aldehyde-Alcohol reactions catalyzed under mild conditions by chromium(III) terephthalate metal organic framework (MIL-101) and phosphotungstic acid composites. Acs Appl. Mater. Interfaces 3 (2011), 4756–4764.
33. [33] Saedi, Z., Tangestaninejad, S., Moghadam, M., Mirkhani, V., Baltork, I.M., MIL-101 metal-organic framework: a highly efficient heterogeneous catalyst for oxidative cleavage of alkenes with H2O2. Catal. Commun. 17 (2012), 18–22.
34. [34] Liu, Q., Yang, Y., Liu, X.P., Wei, Y.P., Mao, C.J., Chen, J.S., Niu, H.L., Song, J.M., Zhang, S.Y., Jin, B.K., Jiang, M., A facile in situ synthesis of MIL-101-CdSe nanocomposites for ultrasensitive electrochemiluminescence detection of carcinoembryonic antigen. Sensor. Actuators B-Chem. 242 (2017), 1073–1078.
35. [35] Fang, J.M., Leng, F., Zhao, X.J., Hu, X.L., Li, Y.F., Metal-organic framework MIL-101 as a low background signal platform for label-free DNA detection. Analyst 139 (2014), 801–806.
36. [36] Xie, L., Liu, S., Han, Z., Jiang, R., Liu, H., Zhu, F., Zeng, F., Su, C., Ouyang, G., Preparation and characterization of metal-organic framework MIL-101(Cr)-coated solid-phase microextraction fiber. Anal. Chim. Acta 853 (2015), 303–310.
37. [37] Wang, Y., Du, K., Chen, Y., Li, Y., He, X., Electrochemical determination of lead based on metal-organic framework MIL-101(Cr) by differential pulse anodic stripping voltammetry. Anal. Methods 8 (2016), 3263–3269.
38. [38] Yang, J., Liang, J., A modified model of electrical conduction for carbon black-polymer composites. Polym. Int. 60 (2011), 738–742.
39. [39] Ma, Y., Wang, H., Ji, S., Goh, J., Feng, H., Wang, R., Highly active Vulcan carbon composite for oxygen reduction reaction in alkaline medium. Electrochim. Acta 133 (2014), 391–398.
40. [40] Ren, X., Shao, D., Yang, S., Hu, J., Sheng, G., Tan, X., Wang, X., Comparative study of Pb(II) sorption on XC-72 carbon and multi-walled carbon nanotubes from aqueous solutions. Chem. Eng. J. 170 (2011), 170–177.
41. [41] Mahapatra, S.P., Sridhar, V., Tripathy, D.K., Dielectric studies of conductive carbon black reinforced microcellular ethylene-propylene-diene monomer vulcanizates. J. Appl. Polym. Sci. 106 (2007), 192–204.
42. [42] Zhang, W., Xu, G., Liu, R., Chen, J., Li, X., Zhang, Y., Zhang, Y., Novel MOFs@XC-72-Nafion nanohybrid modified glassy carbon electrode for the sensitive determination of melamine. Electrochim. Acta 211 (2016), 689–696.
43. [43] Ullah, S., Khan, I.A., Choucair, M., Badshah, A., Khan, I., Nadeem, M.A., A novel Cr2O3-carbon composite as a high performance pseudo-capacitor electrode material. Electrochim. Acta 171 (2015), 142–149.
44. [44] Ferey, G., Draznieks, C.M., Serre, C., Millange, F., Dutour, J., Surble, S., Margiolaki, I., A chromium terephthalate-based solid with unusually large pore volumes and surface area. Science 309 (2005), 2040–2042.
45. [45] Cao, N., Liu, T., Su, J., Wu, X., Luo, W., Cheng, G., Ruthenium supported on MIL-101 as an efficient catalyst for hydrogen generation from hydrolysis of amine boranes. New J. Chem., 38, 2014, 4032.
46. [46] Du, W., Chen, G., Nie, R., Li, Y., Hou, Z., Highly dispersed Pt in MIL-101: an efficient catalyst for the hydrogenation of nitroarenes. Catal. Commun. 41 (2013), 56–59.
47. [47] Hong, D.Y., Hwang, Y.K., Serre, C., Férey, G., Chang, J.S., Porous chromium terephthalate MIL-101 with coordinatively unsaturated sites: surface functionalization, encapsulation, sorption and catalysis. Adv. Funct. Mater. 19 (2009), 1537–1552.
48. [48] Liu, Y., Zeng, J., Zhang, J., Xu, F., Sun, L., Improved hydrogen storage in the modified metal-organic frameworks by hydrogen spillover effect. Int. J. Hydrogen Energy 32 (2007), 4005–4010.
49. [49] Wang, S.B., Murata, K., Hayakawa, T., Hamakawa, S., Suzuki, K., Oxidative dehydrogenation of ethane by carbon dioxide over sulfate-modified Cr2O3/SiO2 catalysts. Catal. Lett. 63 (1999), 59–64.
50. [50] Liu, B., Peng, Y., Chen, Q., Adsorption of N/S-heteroaromatic compounds from fuels by functionalized MIL-101(Cr) metal-organic frameworks: the impact of surface functional groups. Energy Fuels 30 (2016), 5593–5600.
51. [51] Aliev, S.B., Samsonenko, D.G., Maksimovskiy, E.A., Fedorovskaya, E.O., Sapchenko, S.A., Fedin, V.P., Polyaniline-intercalated MIL-101: selective CO2 sorption and supercapacitor properties. New J. Chem. 40 (2016), 5306–5312.
52. [52] Li, P.C., Hu, C.C., Noda, H., Habazaki, H., Synthesis and characterization of carbon black/manganese oxide air cathodes for zinc-air batteries: effects of the crystalline structure of manganese oxides. J. Power Sources 298 (2015), 102–113.
53. [53] Pilehvar, S., Mehta, J., Dardenne, F., Robbens, J., Blust, R., De Wael, K., Aptasensing of chloramphenicol in the presence of its analogues: reaching the maximum residue limit. Anal. Chem. 84 (2012), 6753–6758.
54. [54] Kor, K., Zarei, K., Electrochemical determination of chloramphenicol on glassy carbon electrode modified with multi-walled carbon nanotube-cetyltrimethylammonium bromide-poly (diphenylamine). J. Electroanal. Chem. 733 (2014), 39–46.
55. [55] Casalini, S., Berto, M., Bortolotti, C.A., Foschi, G., Operamolla, A., Lauro, M.D., Omar, O.H., Liscio, A., Pasquali, L., Montecchi, M., Farinola, G.M., Borsari, M., Electrowetting of nitro-functionalized oligoarylene thiols self-assembled on polycrystalline gold. ACS Appl. Mater. Interfaces 7 (2015), 3902–3909.
56. [56] Lund, H., Hammerich, O., Organic Electrochemistry. 2001, Marcel Dekker, New York.
57. [57] Yang, G., Zhao, F., Electrochemical sensor for chloramphenicol based on novel multiwalled carbon nanotubes@molecularly imprinted polymer. Biosens. Bioelectron. 64 (2015), 416–422.
58. [58] Karthik, R., Govindasamy, M., Chen, S.M., Mani, V., Lou, B.S., Devasenathipathy, R., Hou, Y.S., Elangovan, A., Green synthesized gold nanoparticles decorated graphene oxide for sensitive determination of chloramphenicol in milk powdered milk, honey and eye drops. J. Colloid Interface Sci. 475 (2016), 46–56.
59. [59] Alizadeh, T., Ganjali, M.R., Zare, M., Norouzi, P., Selective determination of chloramphenicol at trace level in milk samples by the electrode modified with molecularly imprinted polymer. Food Chem. 130 (2012), 1108–1114.
60. [60] Zhai, H., Liang, Z., Chen, Z., Wang, H., Liu, Z., Su, Z., Zhou, Q., Simultaneous detection of metronidazole and chloramphenicol by differential pulse stripping voltammetry using a silver nanoparticles/sulfonate functionalized graphene modified glassy carbon electrode. Electrochim. Acta 171 (2015), 105–113.
61. [61] Tan, Z., Xu, H., Li, G., Yang, X., Choi, M.M.F., Fluorescence quenching for chloramphenicol detection in milk based on protein-stabilized Au nanoclusters. Spectrochim. Acta Part A 149 (2015), 615–620.