Int J App Pharm, Vol 9, Issue 6, 2017, 71-74Original Article



1Dept of Biochemistry, Acharya Nagarjuna University, 2Dept of biochemistry,Acharya Nagarjuna University, 3Dept of Physics, acharya Nagarjuna University, NH16, Nagarjuna Nagar, Guntur, Andhra Pradesh 522510

Received: 01Aug 2017, Revised and Accepted: 10 Oct 2017


Objective:In the present study copper oxide (CuO) nanoparticles were synthesized and characterized. The antibacterial activity of CuO nanoparticles was carried out against Escherichia coli, Proteus vulgaris,Staphylococcus aureus and Streptococcus mutans.

Methods: The synthesis was carried out bycoprecipitation method using coppersulfate and sodium hydroxide as precursors.The synthesized copper oxide nanoparticles were characterized by using X-ray diffraction (XRD), Fourier transforms infrared spectroscopy (FT-IR), UV-vis spectroscopyandscanning electron microscope (SEM) with Energy Dispersive X-ray Analysis (EDX) techniques. Besides, this study determines the antibacterial activity and minimum inhibitory concentration (MIC) of CuO nanoparticles against gram-positive (Staphylococcus aureus and Streptococcus mutans) and gram-negative (E. coli and Proteus vulgaris) bacteria.

Results: The average crystallite size of CuOnanoparticles was found to be 19 nm by X-ray diffraction.FT-IR spectrumexhibited vibrational modes at 432 cm-1, 511 cm-1 and 611 cm-1were assigned for Cu-O stretching vibration. According to UV-Vis spectrum, two bands were observed at 402 nm and 422 nm. ED’s spectrum shows only elemental copper (Cu) and oxide (O) and no other elemental impurity was observed.The antimicrobial assay revealed thatProteus vulgaris showed a maximum zone of inhibition (37 mm) at 50 mg/ml concentration of CuOnanoparticles.

Conclusion: In conclusion, copper oxide is a good antibacterial agent against both gram positive and gram-negative organisms.

Keywords: CuO nanoparticles, XRD, FTIR,SEM,EDS, Antibacterial activity


The properties of materials change as their size come close to the nanoscale[1]. The size of nanoparticles is similar to that of most biological molecules and structures. This makes them an interesting candidate for application in both invivo and invitro biomedical research [2]. Metal nanoparticles with antimicrobial activity, when coated on to surfaces, can find enormous applications in synthetic textiles, biomedicaland surgical devices,water treatment, food processing and packaging [3]. Copper oxide is a compound of two elements,copper and oxygen, which are dandp block elements in theperiodic table respectively. In a crystal, copper ion is coordinated by four oxygen ions [4].Compared to the common copper oxide powder, nano copper oxide shows better catalytic activity and selectivity [5]. CuO nanoparticles are prominent due to their diverse applications in superconductors, optical [6], electrical [7],nanofluids [8], catalytic [9],photocatalytic degradation [10], gas sensors, and in biosensors [11]. Thefactors including size, shape and composition of nanoparticles affects the interaction between thenanoparticles and living cells[12].Currently, antimicrobial properties are seriously studied due to an enormous increase in bacterial resistance against the excessive and repeated use of antibiotics[13]. The antibiotic resistance crisis has been attributed to the overuse and misuse of these medications, as well as lack of new drug development by the pharma industry due to reduced economic encouragements and challenging regulatory requirements [14-17]. There are very few studies available about the antimicrobial activity of nanoCuO.So an attempt has been made to investigate the antibacterial activity and minimum inhibitory concentration of Cuo nanoparticles synthesized by coprecipitation method.



Copper sulphate, Sodium hydroxide, Nutrient agar, Tripticase soy yeast agar, Brain heart infusion agar were obtained from Hi-Media Pvt Ltd.All the chemicals purchased were of analytical grade.


The CuO nanoparticles were prepared by coprecipitation method using copper sulphate and sodium hydroxide as precursors. Copper sulphate, 1M was dissolved in distilled water.After complete dissolution of copper sulphate, 2M of sodium hydroxide solution was added under constant stirring, drop by drop touching the walls of the vessel. The reaction was allowed to proceed for 2 h. The solution was allowed to settle for an overnight and the supernatant solution was then discarded carefully. The precipitate was washed several times using distilled water.The washed precipitate was dried at 80 °C for overnight.


The structure of the compounds was investigated using X-ray diffraction (XRD-6100 diffractometer, Shimadzu) with Cu Kα radiation (λ= 1.54060 Å).Molecular analysis of the sample was performed by Fourier transform infrared (FT-IR) spectroscopy using IR Affinity-1s (Shimadzu) spectrometer, recorded in the wave number range of 4,000–400 cm‑1. UV-Vis spectroscopy was used to characterize the optical absorption properties of CuO. The absorption spectra of the sample were recorded in the wavelength range of200-800 nm using a JASCO V 670.Morphological study of the nanoparticles was carried out with scanning electron microscope (EVO 18 carlzeiss).

Antibacterial activity of the CuOnanopowder

E. coli (MCC 2412) and Staphylococcus aureus (MCC2408) were procured from MCC, Pune, India and Proteus vulgaris (MTCC 426) and Streptococcus mutans (MTCC 497) were procured from MTCC, Chandigarh, India.

Agar well diffusion method

The antibacterial activity of the CuOnanopowder was determined by agar well diffusion method[18] against both Gram-negative and Gram-positive microorganisms.Once the medium was solidified, a suspension of each sample ofthe bacteria was diluted prior to 10-1, 10-2and10-3 (1 ml of 108 cells/ml) and was spread on a solid agar medium inPetri plates(E. coli and Proteus vulgaris-Nutrient agar medium; Staphylococcus aureus-Trypticase soy yeast extract agar medium; Streptococcus mutans–Brain heart infusion agar medium). The wells were prepared by using sterile cork borer (6 mm). Each well was filled with different concentrations of nanomaterial ranging from 10-50 mg/ml. The plates were incubated at 37 ° C for 24 h, the zone of inhibition was measured.

Minimum inhibitory concentration

The lowest concentration of material that inhibits the growth of an organism [19] is defined as theminimum inhibitory concentration (MIC).MIC for metal oxide nanoparticles was determined by the broth dilution method. A series of 4 test tubes were taken. Add 10 ml of mediumanda loop full of culture to all the test tubes and finally add 2 mg/ml, 4 mg/ml, 6 mg/ml and 8 mg/ml of nanoparticle suspension to each test tube. The test tube without bacterial suspension was considered as control. Keep the test tubes for overnight incubation at 37 °C temperature. Read the absorbance at 600 nm using aspectrophotometer. MIC is where the absorbance value of the sample equals to or near to control [20].


X-ray diffraction studies

Powder XRD was a rapid analytical technique primarily used for phase identification of a crystallite material and can provide information on unit cell dimensions. The XRD pattern of the CuOnanopowderwas in monoclinic phasewasshown in the fig. 1. The average crystallite size was calculated using Debye Scherrer’s formula:

D = 0.9λ/βcosθ

Where D is the crystallite size, λ is the wavelength (1.5406 A ° for Cu Kα) of the X-ray radiation, β is the full width at half maximum of the peaks at the diffract­ing angle θ[21]. Crystallite size wascalculated to be 19 nm. According to JCPDS data (80-0076), the exhibited diffraction peaks at 2θ = 32.51 ° (1 1 0), 35.53 ° (-1 1 1), 38.75 °(111), 46.28 ° (-1 12), 48.76 ° (-2 02), 53.58 ° (0 2 0), 58.31 ° (2 0 2), 61.58 ° (-1 1 3), 66.24 ° (-311) and 68.08 ° (2 2 0) corresponds to different planes ofmonoclinic phase of CuOnano particles(table 1). The lattice parameters of CuO sample were calculated from the XRD data. The evaluated cell parameters were a = 0.46891 nm, b = 0.34214 nm, and c = 0.51276 nm in agreement with the reported values.

Fig.1: X-ray diffraction patterns of CuO nanoparticles

Table 1:The observed and calculated 2θ values of XRD data of copper oxide nanoparticles

Observed 2θ Standard 2θ hkl
32.51 32.48 11 0
35.53 35.53 -1 1 1
38.75 38.64 1 1 1
46.28 46.25 -1 1 2
48.76 48.85 -202
53.58 53.35 0 2 0
58.31 58.16 2 02
61.58 61.51 -1 1 3
66.24 66.34 -311
68.08 68.01 2 2 0

Fourier transform infrared spectroscopy (FT-IR) studies

FT-IR spectroscopy is useful in measuring the absorption of IR radiations by a sample, and the results were shown by means of a wavelength. The evaluation of the IR spectrum includes the correlation of the absorption bands (vibrational bands) and the chemical compounds in the sample [22].

The FTIR spectrum of CuOnanopowderwas shown in fig. 2. TheCuO nanoparticles exhibited vibrational modes at 432 cm-1, 511 cm-1 and 611 cm-1were assigned for Cu-O stretching vibration, rocking vibrational mode of water molecule at 886 cm-1, the band at 1125 cm-1 indicates triply degenerative ν3 mode of SO4-2ion and the absorption bands at 1630 cm-1and 3398 cm-1were bending and stretching mode of vibration of watermolecule(table 2).

UV-visible studies

The optical properties of CuO nanoparticles have been studied by UV-Vis spectrum, which was shown in fig. 3. UV-Visible spectroscopy is amost widely used technique to investigate the optical properties of the particles. The analysis was done in the range of 200-800 nm. Two bands were observed at 402 nm and 422 nm, assigned to the absorption of copper oxide nanoparticles.

Fig.2:FT-IR spectrum of CuO nanoparticles

Table 2:Assignment of FT-IR bands of CuOnanopowder

Wavenumber (cm-1) Band assignment
432 Cu-O stretching vibration
511 Cu-O stretching vibration
611 Cu-O stretching vibration
886 Rocking vibrational mode of watermolecule
1125 Triply degenerativeν3 mode of So4-2ion
1630 Bending vibration of water molecule
3398 Stretching vibration of water molecule

Fig.3: Optical absorption spectrum of CuO nanoparticles

Scanning electron microscope and energy dispersive X-rayspectroscopyanalysis

Fig. 4 a shows the SEM images of the nanomaterial. The surface morphology of the synthesized CuO nanoparticles wasflower-shaped structure examined by SEM analysis. The Energy dispersive spectra of the sample were carried out to examine the purity and chemical composition of the synthesized materials.As seen in fig. 4 b, the EDS spectrum contains only elemental copper (Cu) and oxide (O) and no other elemental impurity was observed.

Antibacterial activity of the CuOnanopowder

The antibacterial activity of the CuO nanomaterial was determined by using well diffusion method against Gram positive and Gram negative bacteria (table 3). Due to variation in the strains employed, adirect comparison between the inhibitory zones formed by organisms was difficult. Table 3 lists different concentrations of CuO nanoparticles and their activity against different organisms. The variation in the sensitivity or resistance to both gram positive and gram negativebacterial populations might be due to the differences in the cell structure, physiology, metabolism or degree of contact of organisms with nanoparticles [23]. At biological pH values,the overall charge of bacterial cells was negative due to the additional carboxylic groups present in the lipoproteins on the bacterial surface, which, upon dissociation, makesthe cell surface negative [24]. According to Ren et al. [25], CuO nanoparticles were effective in killing a wide range of bacterial pathogens, but higher concentrations of nanoCuO were required to achieve a bactericidal effect. In the present study, the antimicrobial activity study shows that the gram-positive bacterial strains were less affected than gram negative. The opposite charges of bacteria and copper ions released from nanoparticles are thought to cause adhesion and bioactivity due to electrostatic forces. Since peptidoglycans are negatively charged molecules, they bind Cu2+ions released from copper nanoparticles in liquid growth medium. Being gram-negative, the bacterium E. coli may allow more Cu2+ions to reach the plasma membrane but is generally considered less susceptible to antibiotics and antibacterial agents than gram-positive bacteria [26]. Finally, it can be concluded that, due to the increased resistance of microorganisms to conventional drugs, it’s important to find out new solutions to avoid the development of multiresistant strains [27]. Gram-negative bacterial strains are showing more sensitivity than gram-positive because of their membrane structure. It was interesting to note that as the concentration of CuO nanoparticles increases, the zone of inhibition also increases.

Fig.4: a. SEM images of CuOnanoparticles, b. Energy dispersive spectrum of CuO nanoparticles

Table 3: Antimicrobial activity ofCuO nanoparticles by agar well diffusion method

S. No. Name of the organism Zone of Inhibition(in mm)
10 mg/ml 20 mg/ml 30 mg/ml 40 mg/ml 50 mg/ml
1 E. coli 6±0.10 11±0.20 17±0.25 24±0.15 30±0.30
2 Proteus vulgaris 9±0.20 17±0.10 23±0.30 30±0.15 37±0.20
3 Staphylococcus aureus 5±0.35 9±0.25 12±0.30 17±0.40 23±0.10
4 Streptococcus mutans 8±0.25 13±0.30 18±0.40 24±0.30 30±0.45

Number experiments n=2, mean±SD

Minimum inhibitory concentration

The results showed significant MIC values between 4 mg/ml to 6 mg/ml concentration (table 4). Proteus vulgaris, Streptococcus mutans and staphylococcus aureusshowed MIC at 4 mg/mlandE. colishowed MIC at 6 mg/ml. Determination of the MIC is important in diagnosticlaboratoriesbecause it helps in confirming resistance of amicroorganism to an antimicrobial agent and it monitors the activity of new antimicrobial agents.

Table 4: Minimum inhibitory concentration (MIC) values in (mg/ml)of CuOnanopowder

Bacterial strain MIC (mg/ml)
E. coli 6
Proteus vulgaris 4
Streptococcus mutans 4
Staphylococcus aureus 4


In the present study, CuOnanoparticleswith monoclinic structure were synthesized by using coprecipitation method.The crystalline and particle size determined was19 nm by using XRD. The surface morphology of the synthesized CuO nanoparticles was flower shaped confirmed by SEM analysis. According to the EDS spectrum, no elemental impurity was observed.The well diffusion assay and MIC indicate the future potential of CuO nanoparticles for combating pathogenic microorganisms. 


Declared none


  1. Eustis MA, El-Sayed. Why gold nanoparticles are more precious than pretty gold: noble metal surfaceplasmon resonance and its enhancement of the radiative and nonradiative propertiesnanocrystals of different shapes. Chem Soc Rev 2006;35:209-17.

  2. Samia ACS, Dayal S, Burda C. Quantum Dot-Based energy transfer: Perspectivespotential for applications in photodynamic therapy. J PhotochemPhotobiol2006;82:617-25.

  3. Gutierrez FM,Olive PL, Banuelos A, Orrantia E, Nino N,Sanchez EM,et al.A study on theantibacterial activity of Zno nanoparticles. J Nanomed2010;6:681-8.

  4. Guajardo-Pachecoa MJ, Morales-Sanchz JE, González-Hernándezc J, Ruiz F. Synthesis of copper nanoparticles using soybeans as a chelant agent.Mater Lett 2010;64:1361-4.

  5. Singh J, Kaur G, Rawat M.A brief review on synthesis and characterization of copper oxidenanoparticles and its applications.J BioelectronNanotechnol2016;1:1-9.

  6. SawsanDagher, YousefHaik, Ahmad I, Ayesh, Nacir Tit. Synthesis and optical properties of colloidalCuO nanoparticles. J Luminesce 2014;151:149-54.

  7. Bouazizi N, Bargougui R,Oueslati A,Benslama R.Effect of synthesis time on structural,optical and electrical properties of CuO nanoparticles synthesized by reflux condensation method. Adv Mat Lett 2015;6:158.

  8. RohiniPriya K, Suganthi KS,Rajan KS. Transport properties of ultra low concentration CuO water nanofluids containing nonspherical nanoparticles. Int J Heat Mass Transfer2012;55:4734-43.

  9. Hosseinpour M, Ahmadi SJ, Mousavand T,Outokesh MJ. Production of granulated-copper oxide nanoparticles for catalytic application. J Mat Res2010;25:2025-34.

  10. Henam Sylvia Devi, Thiyam David Singh. Synthesis of copper oxide nanoparticles by a novel method and its application in the degradation of methyl orange. AdvElectr Electric Eng 2014;4:83-8.

  11. Hong L, Liu AL, Li GW,Chen W,Lin XH. Chemiluminescent cholesterol sensor based on Peroxidase like activity of cupric oxide nanoparticles.BiosensBioelectron 2013;43:1-5.

  12. Li XM, Wang L, Fan YB, Feng QL, Cui FZ. Biocompatibility and toxicity of nanoparticles and nanotubes.J Nanomater 2012;19.

  13. Seil JT, Webster TJ.Antimicrobial applications of nanotechnology: methods and literature.Int JNanomed 2012;7:2767-81.

  14. Sengupta S, Chattopadhyay MK, Grossart HP. The multifaceted roles of antibiotics and antibiotic resistance in nature. Front Microbiol 2013;4:47-60.

  15. Wright GD. Something new: revisiting natural products in antibiotic drug discovery. Can J Microbiol 2014;60:147-54.

  16. Viswanathan VK. Off–label abuse ofantibiotics by bacteria. Gut Microbes 2014;5:3-4.

  17. Michael CA,Dominey-Howes D, Labbate M. The antimicrobial resistance crisis: causes,consequences, and management.Front Public Health2014;2:145.

  18. Ravi Chandrika K, Kiranmayi P, Ravikumar RVSSN.Synthesis, characterization and antibacterial activity of ZnO nanoparticles. Asian J PharmClin Res 2012;5:97-9.

  19. Qi L, Xu Z, Jiang X, Hu C, Zou X. Preparation and antibacterial activity of chitosan nanoparticles. Carbohydr Res 2004;339:2693-700.

  20. Ruparelia JP, Arup KC, Siddhartha P, Duttagupta,Suparna M. Strain specificity in antimicrobial activity of silver and copper nanoparticles. ActaBiomater 2008;4:707-16.

  21. Vijayalakshmi R, Rajendran V. Synthesis and characterization of nano-TiO2 via different methods. Arch ApplSci Res 2012;4:1183-90.

  22. Dobrucka R, Długaszewska J. Biosynthesis and antibacterial activity of Zno nanoparticlesusingTrifoliumpratense flower extract. Saudi J BiolSci2016;23:517-23.

  23. GopalakrishnanK, Ramesh C, Ragunathan V, Thamilselvan M.Antibacterial activity of copperoxide nanoparticles on E. colisynthesized from Tridaxprocumbensleaf extract and surface coating with polyaniline. Digest J Nanomater Biostructures2012;7:833-9.

  24. Stoimenov PK, Klinger RL,Marchin GL,Klabunde KJ. Metal oxide nanoparticles as bactericidal agents. Langmuir 2002;18:6679-86.

  25. Ren G, Hu D, Cheng EWC,Vargas-Reus MA, Reip P, Allaker RP. Characterization of copper oxide nanoparticles for antimicrobial applications.Int J Antimicrob Agents 2009;33:587-90.

  26. Koch AL, Woeste SW. The elasticity of the sacculus of Escherichia coli. JBacteriol1992;174:4811-9.

  27. Elizabath Antony, Mythili Sathiavelu, Sathiavelu Arunachalam. Synthesis of silver nanoparticles from the medicinal plant bauhiniaacuminata and biophytumsensitivum–a comparative study of its biological activities with plant extract. Int J Appl Pharm 2017;9:22-9.

About this article




CuO nanoparticles, XRD, FTIR, SEM, EDS, Antibacterial activity





Additional Links

Manuscript Submission


International Journal of Applied Pharmaceutics
Vol 9, Issue 6 (Oct-Nov), 2017 Page: 71-74

Online ISSN



40 Views | Downloads

Authors & Affiliations

Manyasree D
Dept of Biochemistry, Acharya Nagarjuna University, NH16, Nagarjuna Nagar, Guntur, Andhra Pradesh 522510

Kiran Mayi Peddi
Dept of biochemistry, Acharya Nagarjuna University Nagarjuna University, NH16, Nagarjuna Nagar, Guntur, Andhra Pradesh 522510

Ravikumar R
Dept of Physics, acharya Nagarjuna University, NH16, Nagarjuna Nagar, Guntur, Andhra Pradesh 522510


  • There are currently no refbacks.