Synthesis of Melanin Mediated Silver Nanoparticles from Aeromonas sp. SNS Using Response Surface Methodology: Characterization with the Biomedical Applications and Photocatalytic Degradation of Brilliant Green
Tóm tắt
Melanin is ubiquitous in nature and has wide applications in cosmetics, agriculture, and medicine. The synthesized melanin from bacterium Aeromonas sp. SNS was further used as capping and reducing agents for synthesis of silver nanoparticles (AgNPs). The influence of the experimental parameters (AgNO3, melanin concentrations, and temperature) and their interactions on the nanoparticle synthesis was optimized using response surface methodology (RSM). The Central Composite Design (CCD) with three independent variables was optimized for the effective synthesis of AgNPs. The optimized synthesis of AgNPs was achieved at the shortest time of 14.12 h in the presence of 2.62 mM AgNO3, and 32.30 µg ml−1 melanin concentration at 54.86 °C temperature. The synthesized AgNPs were characterized by means of UV–visible spectroscopy, FTIR, SEM, TEM, and PSD respectively. The AgNPs exhibited excellent antimicrobial activity against human and food-related pathogens. These AgNPs also have strong antioxidant potential which was estimated by DPPH, DMPD and FRAP radical scavenging assays. The 92.62% photocatalytic degradation of 250 PPM brilliant green was observed in 120 min. The present finding accelerates the melanin associated AgNPs could be used in the cosmetic and pharmaceutical industries as well as in textile industries as they have superior antimicrobial, antioxidant, and photocatalytic activity.
Tài liệu tham khảo
Surwase SN, Jadhav S, Phugare S, Jadhav JP (2012) 3 Biotech 3:187–194
Zhang F, Kearns SL, Orr PJ, Benton MJ, Zhou Z, Johnson D et al (2010) Nature 463:1075–1078
Wogelius RA, Manning PL, Barden HE, Edwards NP, Webb SM, Sellers WI et al (2011) Science 333:1622–1626
Lindgren J, Uvdal P, Sjövall P, Nilsson DE, Engdahl A, Schultz BP, Thiel V (2012) Nat Commun 3:824
Hung YC, Sava V, Hong MY, Huang GS (2004) Life Sci 74:2037–2047
Vasanthabharathi V, Lakshminarayanan R, Jayalakshmi S (2011) Afr J Biotechnol 10:11224–11234
Sivaperumal P, Kamala K, Rajaram R (2015) Nat Product Res 29:2117–2121
Rózanowska M, Sarna T, Land EJ, Truscott TG (1999) Free Radic Biol Med 26:518–525
Hung YC, Sava VM, Makan SY, Chen THJ, Hong MY, Huang GS (2002) Food Chem 78:233–240
Roy S, Rhim JW (2019) Colloids Surf B 176:317–324
Raman NM, Shah PH, Mohan M, Ramasamy S (2015) AMB Exp 5:72
Zhang M, Xiao G, Thring RW, Chen W, Zhou H, Yang H (2015) Appl Biochem Biotechnol 176:253–266
Zou Y, Hou X (2016) Food Sci Technol Camp 37:153–157
Sun S, Zhang X, Sun S, Zhang L, Shan S, Zhu H (2016) Food Chem 190:801–807
El-Batal AI, Al Tamie MS (2016) Der Pharm Lett 8:315–333
Manivasagan P, Venkatesan J, Senthilkumar K, Sivakumar K, Kim SK (2013) Int J Biol Macromol 58:263–274
Tarangini K, Mishra S (2014) Biotechnol Rep 4:139–146
Drewnowska JM, Zambrzycka M, Kalska-Szostko B, Fiedoruk K, Swiecicka I (2015) PLoS ONE 3:150. https://doi.org/10.1371/journal.pone.0125428
El-Naggar NEA, El-Ewasy SM (2017) Sci Rep 7:42129. https://doi.org/10.1038/srep42129
El-Batal AI, El-Sayyad GS, El-Ghamery A, Gobara M (2017) J Clust Sci 28(3):1083–1112
Jiang H, Liu NN, Liu GL, Chi Z, Wang JM, Zhang LL, Chi ZM (2016) Extremophiles 20:567–577
Saleh H, Abdelrazak A, Elsayed AE, Osman Y (2018) J Biol Life Sci 9:24–38
Alarfaj NA, El-Tohamy MF (2016) Luminescence 31:1194–1200
Alim S, Vejayan J, Yusoff MM, Kafi AK (2018) Biosens Bioelectron 3:150. https://doi.org/10.1016/j.bios.2018.08.051
Płaza G, Chojniak J, Ibrahim MB (2014) Int J Mol Sci 15:13720–13737
Kiran GS, Dhasayan A, Lipton AN, Selvin J, Arasu MV, Al-Dhabi NA (2014) J Nanobiotechnol 12(1):18
Apte M, Girme G, Bankar A, RaviKumar A, Zinjarde S (2013) J Nanobiotechnol 11:1–9
Liopo A, Su R, Oraevsky AA (2015) Photoacoustics 3:35–43
Monira MR, EL-Gebaly RH, Abou-Shady H, Amin DG (2015) Mol Cell Biochem 399:59–69
Kim DJ, Ju KY, Lee JK (2012) Bull Korean Chem Soc 33(11):3788–3792
Cos P, Vlietinck A, Berghe D, Maes L (2006) J Ethnopharm 106:290–302
Brand-Williams W, Cuvelier ME, Berset C (1995) Lebensm Wiss Technol 28:25–30
Thaipong K, Boonprakob U, Crosby K, Cisneros-Zevallos L, Byrne DH (2006) J Food Compos Anal 19:669–675
Fogliano V, Verde V, Randazzo G, Ritieni A (1999) J Agric Food Chem 47:1035–1040
Benzie IF, Strain JJ (1996) Anal Biochem 239:70–76
Patil S, Surwase S, Jadhav S, Jadhav J (2013) Biochem Eng J 74:36–45
Naoya M, Tomohiro I, Watano S (2015) Nanomater Nanotechnol 5:13
Apte M, Sambre D, Gaikawad S, Joshi S, Bankar A, Kumar AR, Zinjarde S (2013) AMB Express 3:32
Apte M, Girme G, Nair R, Bankar A, Kumar AR, Zinjarde S (2013) Mater Lett 95:149–152
Roy S, Rhim JW (2019) J Nanomater. https://doi.org/10.1155/2019/2840517
Patil S, Sistla S, Bapat V, Jadhav J (2018) Appl Biochem Microbiol 54:163–172
Babu G, Gunasekaran P (2009) Colloids Surf B 74:191–195
Panacek A, Kvitek L, Prucek R, Kolar M, Vecerova R, Pizurova N, Sharma V, Nevena T, Zboril R (2006) J Phys Chem B 110:16248–16253
Bursal E, Köksal E (2011) Food Res Int 44:2217–2221
Huang S, Pan Y, Gan D, Ouyang X, Tang S, Ekunwe SIN, Wang H (2011) Med Chem Res 20:475–481
Tu YG, Sun YZ, Tian YG, Xie MY, Chen J (2009) Food Chem 114:1345–1350
El-Naggar NEA, El-Ewasy SM (2017) Sci Rep 7:42129. https://doi.org/10.1038/srep42129
Zerrad A, Anissi J, Ghanam J, Sendide K, Mohammed EH (2014) J Biotechnol Lett 5:87–94
Kaur S, Sharma S, Umar A, Singh S, Mehta SK, Kansal SK (2017) Superlattices Microstruct 103:365–375