AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Nano Biomedicine and Engineering Article
PDF (4.7 MB)
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article | Open Access

Microwave-assisted and Ultrasonic Phyto-synthesis of Copper Nanoparticles: A Comparison Study

Farinaz Hadinejad1Mohsen Jahanshahi1Hamed Morad2,3( )
Nanotechnology Research Institute, Faculty of Chemical Engineering Babol Noushirvani University of Technology, Babol, Iran
Department of Pharmaceutics, Faculty of Pharmacy, Mazandaran University of Medical Sciences, Sari, Iran
Student research committee, Mazandaran University of Medical Sciences, Sari, Iran
Show Author Information

Abstract

Elimination of hazardous chemicals in the process of synthesis, which guarantees the safety of the nanoparticles (NPs) for therapeutic utilization, could be obtained by using the phyto-synthesis method. The present project is a multidimensional survey that aimed to optimize the phyto-synthesis conditions of copper nanoparticles (Cu NPs) using the microwave and ultrasound-assisted methods and facilitate approaching the dilemma of choosing between these two methods by characterizing the final products of each method. Based on the transmission electron microscopy (TEM), the obtained NPs were sub 10 nm in both methods. The optimized NPs were achieved in 5 min using 6 mL of phytoextract at 95 ℃ in a microwave oven, and amplitude 100% and cycle 0.8 in an ultrasonic processor. In addition to the antibacterial property and molecular wound healing stimulation of Cu NPs, these amorphous nanoscale particles could provide desirable absorption and distribution over the wounds to be suggested as an effective transdermal drug delivery system. The ultrasound-assisted method was the most appropriate way to obtain an amorphous mixture of Cu NPs with a majority of copper oxide while the microwave-assisted method was more suitable for synthesis procedures using plant extracts with heat-sensitive and volatile components.

Keywords

Regenerative medicineDrug delivery systemPhytonanotechnologyPhyto-synthesisCopper nanoparticlesFraxinus excelsior

References

[1]
M. Nasrollahzadeh, M. Atarod, M. Sajjadi, et al., Plant-mediated green synthesis of nanostructures: mechanisms, characterization, and applications. Interface Sci. Technol., 1st edition. Elsevier Ltd., 2019: 199-322.
Crossref
[2]

P. Singh, Y.J. Kim, D. Zhang, et al., Biological synthesis of nanoparticles from plants and microorganisms. Trends Biotechnol, 2016, 34(7): 588-599.
Crossref Google Scholar
[3]

I. Kostova, T. Iossifova, Chemical components of Fraxinus species. Fitoterapia, 2007, 78(2): 85-106.
Crossref Google Scholar
[4]

J.N. Solanki, R. Sengupta, Z.V.P. Murthy, Synthesis of copper sulphide and copper nanoparticles with microemulsion method. Solid State Sci, 2010, 12(9): 1560-1566.
Crossref Google Scholar
[5]

S. Singh, N. Kumar, M. Kumar, et al., Electrochemical sensing and remediation of 4-nitrophenol using bio-synthesized copper oxide nanoparticles. Chem Eng J, 2017, 313: 283-292.
Crossref Google Scholar
[6]

G. Polino, R. Abbel, S. Shanmugam, et al., A benchmark study of commercially available copper nanoparticle inks for application in organic electronic devices. Org Electron physics, Mater Appl, 2016, 34: 130-138.
Crossref Google Scholar
[7]

M. Ge, R. Gondosiswanto, C. Zhao, Electrodeposited copper nanoparticles in ionic liquid microchannels electrode for carbon dioxide sensor. Inorg Chem Commun, 2019, 107: 107458.
Crossref Google Scholar
[8]

D. Gupta, S.R. Meher, N. Illyaskutty, et al., Facile synthesis of Cu2O and CuO nanoparticles and study of their structural, optical and electronic properties. J Alloys Compd, 2018, 743: 737-745.
Crossref Google Scholar
[9]

M.A. Qader, A. Vishina, L. Yu, et al., The magnetic, electrical and structural properties of copper-permalloy alloys. J Magn Magn Mater., 2017, 442: 45-52.
Crossref Google Scholar
[10]

E.M. Bakhsh, F. Ali, S.B. Khan, et al., Copper nanoparticles embedded chitosan for efficient detection and reduction of nitroaniline. Int J Biol Macromol, 2019, 131: 666-675.
Crossref Google Scholar
[11]

P.J. Fule, B.A. Bhanvase, and S.H. Sonawane, Experimental investigation of heat transfer enhancement in helical coil heat exchangers using water based CuO nanofluid. Adv Powder Technol, 2017, 28(9): 2288-2294.
Crossref Google Scholar
[12]

J. John, R.M. Mathew, I. Rejeena, et al., Nonlinear optical limiting and dual beam mode matched thermal lensing of nano fluids containing green synthesized copper nanoparticles. J Mol Liq, 2019, 279: 63-66.
Crossref Google Scholar
[13]

N. Cioffi, L. Torsi, N. Ditaranto, et al., Copper nanoparticle/polymer composites with antifungal and bacteriostatic properties. Chem Mater, 2005, 17(21): 5255-5262.
Crossref Google Scholar
[14]

K.Y. Yoon, J. Hoon Byeon, J.H. Park, et al., Susceptibility constants of Escherichia coli and Bacillus subtilis to silver and copper nanoparticles. Sci Total Environ, 2007, 373(2-3): 572-575.
Crossref Google Scholar
[15]

A. Gopal, V. Kant, A. Gopalakrishnan, et al., Chitosan-based copper nanocomposite accelerates healing in excision wound model in rats. Eur J Pharmacol, 2014, 731: 8-19.
Crossref Google Scholar
[16]

S. Hamdan, I. Pastar, S. Drakulich, et al., Nanotechnology-Driven Therapeutic Interventions in Wound Healing: Potential Uses and Applications. ACS Cent Sci, 2017, 3(3): 163-175.
Crossref Google Scholar
[17]

A. Enayati-Fard, R. Akbari, J. Saeedi, et al., Preparation and Characterization of Atenolol Microparticles Developed by Emulsification and Solvent Evaporation. Lat Am J Pharm, 2019, 38(7): 1342-1349.
Google Scholar
[18]

J.J. Hinman, K.S. Suslick, Nanostructured Materials Synthesis Using Ultrasound. Top Curr Chem, 2017, 375(1): 59-94.
Crossref Google Scholar
[19]
J. Cheeke, Fundamentals and applications of ultrasonic waves, 2nd edition. CRC Press, 2016.
Crossref
[20]

R.R. Mishra, A.K. Sharma, Microwave-material interaction phenomena: Heating mechanisms, challenges and opportunities in material processing. Compos Part A Appl Sci Manuf, 2016, 81: 78-97.
Crossref Google Scholar
[21]

J. Sun, W. Wang, and Q. Yue, Review on microwave-matter interaction fundamentals and efficient microwave-associated heating strategies. Materials (Basel), 2016, 9(4).
Crossref Google Scholar
[22]

T. Abiraman, E. Ramanathan, G. Kavitha, et al., Synthesis of chitosan capped copper oxide nanoleaves using high intensity (30 kHz) ultrasound sonication and their application in antifouling coatings. Ultrason Sonochem, 2017, 34: 781-791.
Crossref Google Scholar
[23]

M.A. Bhosale, B.M. Bhanage, A simple approach for sonochemical synthesis of Cu2O nanoparticles with high catalytic properties. Adv Powder Technol, 2015, 2(3).
Google Scholar
[24]

S. Yallappa, J. Manjanna, M.A. Sindhe, et al., Microwave assisted rapid synthesis and biological evaluation of stable copper nanoparticles using T. arjuna bark extract. Spectrochim Acta Part A Mol Biomol Spectrosc, 2013, 110: 108-115.
Crossref Google Scholar
[25]

M. Parveen, F. Ahmad, A. Mohammed, et al., Microwave-assisted green synthesis of silver nanoparticles from Fraxinus excelsior leaf extract and its antioxidant assay. Appl Nanosci, 2015.
Crossref Google Scholar
[26]
S. Jain. Bentley's Textbook of pharmaceutics, 1st edition. Elsevier, 2011: 776.
[27]

H. Dang, R.K. Brundavanam, G.E. Jai, et al., Rapid sonochemical synthesis and characterisation of copper oxide nanoparticles from Schweizer's reagent. Alkhaer Pub, 2015.
Google Scholar
[28]

E. Hutter, J.H. Fendler, Exploitation of localized surface plasmon resonance. Adv Mater, 2004, 16(19): 1685-1706.
Crossref Google Scholar
[29]

P.M. Lisiecki I, Synthesis of copper metallic clusters using reverse micelles as microreactors. Am Chem Soc, 1993, 115(4): 3887-3896.
Crossref Google Scholar
[30]

S. Peng, J.M. McMahon, G.C. Schatz, et al., Reversing the size-dependence of surface plasmon resonances. Proc Natl Acad Sci USA, 2010, 107(33): 14530-14534.
Crossref Google Scholar
[31]

N. Sreeju, A. Rufus, and D. Philip, Microwave-assisted rapid synthesis of copper nanoparticles with exceptional stability and their multifaceted applications. J Mol Liq, 2016.
Crossref Google Scholar
[32]

N.A. Dhas, C.P. Raj, and A. Gedanken, Synthesis, characterization, and properties of metallic copper nanoparticles. Chem Mater, 1998, 10(5): 1446-1452.
Crossref Google Scholar
[33]

M. Valodkar, R.N. Jadeja, M.C. Thounaojam, et al., Biocompatible synthesis of peptide capped copper nanoparticles and their biological effect on tumor cells. Mater Chem Phys, 2011, 128(1-2): 83-89.
Crossref Google Scholar
[34]

M.U. Anu Prathap, B. Kaur, and R. Srivastava, Hydrothermal synthesis of CuO micro-/nanostructures and their applications in the oxidative degradation of methylene blue and non-enzymatic sensing of glucose/H2O2. J Colloid Interface Sci, 2012, 370(1): 144-154.
Crossref Google Scholar
[35]
D.L. Pavia, G.M. Lampman, and G.S.K. Jr, Introduction to spectroscopy, 2001: 680.
[36]

J. Xiong, Y. Wang, Q. Xue, et al., Synthesis of highly stable dispersions of nanosized copper particles using l-ascorbic acid. Green Chem, 2011, 13(4): 900-904.
Crossref Google Scholar
[37]

S. Jain, A. Jain, P. Kachhawah, et al., Synthesis and size control of copper nanoparticles and their catalytic application. Trans Nonferrous Met Soc China (English Ed), 2015, 25(12): 3995-4000.
Crossref Google Scholar
[38]

A. Rajan, V. Vilas, and D. Philip, Studies on catalytic, antioxidant, antibacterial and anticancer activities of biogenic gold nanoparticles. J Mol Liq, 2015, 212: 331-339.
Crossref Google Scholar
[39]

M. Genc, B. Inci, Z.K. Genc, et al., Preparation and investigations of thermal properties of copper oxide, aluminium oxide and graphite based on new organic phase change material for thermal energy storage. Bull Mater Sci., 2015, 38(2): 343-350.
Crossref Google Scholar
[40]
A.R. Barron, Physical methods in chemistry and nano science. Connexions, Rice University, 2012: 702.
[41]
M.A. Gatoo, S. Naseem, M.Y. Arfat, et al., Physicochemical properties of nanomaterials : Implication in associated toxic manifestations. 2014, 2014.
Crossref
[42]

M. Rad, M. Taran, and M. Alavi, Effect of incubation time, CuSO4 and glucose concentrations on biosynthesis of copper oxide (cuo) nanoparticles with rectangular shape and antibacterial activity: taguchi method approach. Nano Biomed Eng, 2018, 10(1): 25-33.
Crossref Google Scholar
[43]

M.I. Nabila, K. Kannabiran, Biosynthesis, characterization and antibacterial activity of copper oxide nanoparticles (CuO NPs) from actinomycetes. Biocatal Agric Biotechnol, 2018, 15: 56-62.
Crossref Google Scholar
[44]

H. Gu, X. Chen, F. Chen, et al., Ultrasound-assisted biosynthesis of CuO-NPs using brown alga Cystoseira trinodis: Characterization, photocatalytic AOP, DPPH scavenging and antibacterial investigations. Ultrason Sonochem, 2018, 41: 109-119.
Crossref Google Scholar
[45]

Y. Kawabata, K. Wada, M. Nakatani, et al., Formulation design for poorly water-soluble drugs based on biopharmaceutics classification system: Basic approaches and practical applications. Int J Pharm, 2011, 420(1): 1-10.
Crossref Google Scholar
[46]

R. Jog, D.J. Burgess, Pharmaceutical amorphous nanoparticles. J Pharm Sci, 2017, 106(1): 39-65.
Crossref Google Scholar
[47]

G.B. Romero, A. Arntjen, C.M. Keck, et al., Amorphous cyclosporin A nanoparticles for enhanced dermal bioavailability. Int J Pharm, 2016, 498(1-2): 217-224.
Crossref Google Scholar
[48]

K.S. Suslick, S.B. Choe, A.A. Cichowlas, et al., Sonochemical synthesis of amorphous iron. Nature, 1991, 353(6343): 414-416.
Crossref Google Scholar
[49]

R.V. Kumar, Y. Mastai, Y. Diamant, et al., Sonochemical synthesis of amorphous Cu and nanocrystalline Cu2O embedded in a polyaniline matrix. J. Mater. Chem. , 2001: 1209-1213.
Crossref Google Scholar
[50]

S. Makhluf, R. Dror, Y. Nitzan, et al., Microwave-assisted synthesis of nanocrystalline MgO and its use as a bacteriocide. Adv Funct Mater, 2005, 15(10): 1708-1715.
Crossref Google Scholar
Nano Biomedicine and Engineering
Volume 13 Issue 1,
March 2021
Pages 6-19
DOI: 10.5101/nbe.v13i1.p6-19
Cite this article:
Hadinejad F, Jahanshahi M, Morad H. Microwave-assisted and Ultrasonic Phyto-synthesis of Copper Nanoparticles: A Comparison Study. Nano Biomedicine and Engineering, 2021, 13(1): 6-19. https://doi.org/10.5101/nbe.v13i1.p6-19

753

Views

71

Downloads

2

Crossref

9

Scopus

Altmetrics
Received: 21 March 2020
Accepted: 21 August 2020
Published: 28 December 2020
© Farinaz Hadinejad, Mohsen Jahanshahi, and Hamed Morad.

This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Return