J. Nig. Soc. Phys. Sci. 3 (2021) 144–147

Journal of the
Nigerian Society

of Physical
Sciences

Antimicrobial activity of green synthesized tri-metallic oxide
Ni/Cr/Cu nanoparticles

Sathish Kumar Ka,∗, G. R. Venkatakrishnanb, R. Rengarajb, P. K. Gayathria, G. Lavanyaa, D.
Hemapriyaa

aDepartment of Chemical Engineering, Sri Sivasubramaniya Nadar College of Engineering, Kalavakkam, Chennai, Tamil Nadu, India
bDepartment of Electrical & Electronics Engineering, Sri Sivasubramaniya Nadar College of Engineering, Kalavkkam, Chennai, Tamilnadu, India

Abstract

The tri-metallic oxide Ni/Cr/Cu nanoparticles (NPs) were synthesized using Coriander sativum extract as the reducing agent. The precursors
namely CuSO4.5H2O, Ni(NO3)2·6H2O and Cr (NO3)3·9H2O were used for the green synthesis. Further, the prepared NPs were characterized
using Ultraviolet-Visible (UV-Vis) spectroscopy and X-ray diffraction (XRD) studies. Its antimicrobial property against two fungal and two
bacterial species was determined by measuring the respective zone of inhibition (ZOI) in well diffusion method. A dose dependent inhibition
was observed in all the four species of pathogens including Escherichia coli, Staphylococcus aureus, Aspergillus flavus and Penicillium sp. This
antimicrobial property of tri-metallic oxide NPs may be utilized in the field of medical research, pharmaceutical industries and environmental
sciences.

DOI:10.46481/jnsps.2021.237

Keywords: Tri-metallic oxide NPs, UV-Vis, XRD, antimicrobial activity, zone of inhibition.

Article History :
Received: 23 May 2021
Received in revised form: 21 June 2021
Accepted for publication: 01 July 2021
Published: 29 August 2021

c©2021 Journal of the Nigerian Society of Physical Sciences. All rights reserved.
Communicated by: E. Edward Anand

1. Introduction

The common methods to synthesize of multi metallic NPs
includes laser ablation, ultrasonication, sol-gel, hydrothermal,
co-precipitation and green synthesis [1,2]. The physical and
chemical methods involve higher cost and are not eco-friendly.
On the other hand, use of green synthesis methods offer several
advantages such as cost-effectiveness, simplicity, and environ-
mentally friendliness. The green sources used for synthesizing

∗Corresponding author tel. no:
Email addresses: sathishkumark@ssn.edu.in (Sathish Kumar K ),

gayathri.kothandaraman@gmail.com. (P. K. Gayathri),
lavanya17026@chemical.ssn.edu.in;

hemapriya17021@chemical.ssn.edu.in (D. Hemapriya )

NPs are micro-organisms and plants [3-6]. The choice of these
sources as bioreducing agents should be delicately considered
in the green synthesis approach [7,8]. On comparing, the choice
of plants is less expensive than micro-organisms.

Coriander sativum is an important medical plant belong-
ing to Umbelliferae family comprising several bio-active com-
pounds such as flavonoid, phenol, terpenoid, tannin and gly-
cosides with high level of in vitro radical scavenging activity
[9,10]. These bio-active compounds were believed to play a
major role in the synthesis of metal oxide NPs.

Due to the distinctive properties of bimetallic NPs, it has
attracted the attention of research community [11,12]. For var-
ious applications, the most suitable methods were to fabricate
multi-metallic NPs followed by core-shell and/or alloy forma-

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Sathish et al. / J. Nig. Soc. Phys. Sci. 3 (2021) 144–147 145

tion. Extensive research has been established on traditional sin-
gle metallic methods. Exploration tri-metallic nanostructures
have been initiated recently [13] since an elaborate study with
respect to its application is still at its infancy.

The greatest obstacle for scientists trying to eradicate dan-
gerous pathogens such as bacteria, moulds, yeast and viruses
has been growing resistance to antibiotics. Multi-metallic NPs
have been heavily studied against these dangerous pathogens as
feasible therapeutic and diagnostic methods [14,15]. An effec-
tive approach to overcome these issues is to synergistically en-
gineer these NPs with various formulations, such as the creation
of multi-metallic composites, to strengthen current vulnerabili-
ties.

The antimicrobial resistance has long been of concern to re-
searchers and the use of metal oxide NPs has increased the in-
terest in nanomaterial researchers. Hence in the present study,
a green method to synthesize tri-metallic oxide NPs compris-
ing Nickel (Ni), Copper (Cu), and Chromium (Cr) using the
Coriander sativum extract will be developed. Subsequently, its
antimicrobial efficacy against two bacterial species and two fun-
gal species will be assessed. This investigation of antimicrobial
activity of tri-metallic oxide NPs could be encouraging for a
pharmaceutical application.

2. Materials and Methods

2.1. Materials required

Chemicals including CuSO4·5H2O, Ni(NO3)2·6H2O,
Cr (NO3)3·9H2O were purchased from SRL India. Double dis-
tilled water was used for the preparation of chemical reagents..
All antibacterial and antifungal media were purchased from Hi-
media. Laboratory grade solvents were used for our study. The
bacterial and fungal species were obtained from MTCC.

2.2. Collection of plant

Coriander sativum leaves were used for our study. The col-
lected leaves were washed with tap and double distilled water
and finally dried. The leaves were crushed and grounded to fine
powder. The extract was prepared using 5 g of fine powder in
100 mL distilled water for 15 min at 400W. It was filtered using
Whatman no.1 filter paper and filtrate was used as a reducing
agent for green synthesis of tri-metallic oxide NPs.

2.3. Green synthesis of tri-metallic oxide NPs

The method involves simultaneous reduction of precursor
salts CuSO4·5H2O, Ni(NO3)2·6H2O and Cr(NO3)3·9H2O with
the C. sativum extract [16]. Typically, 0.01M of salt solution
comprising all three metals was mixed with the leaf extract in
250 mL Erlenmeyer flask. The temperature of the reaction mix-
ture was maintained 40◦C for 45 min in a water bath. After
completion of the reaction, mixture was cooled to achieve room
temperature. The mixture was centrifuged at 3000 rpm for 15
min and washed several time with distilled water. Finally the
mixture was washed with ethanol to remove impurities. The
sediment comprising the tri-metallic NPs were stored in vac-
uum oven at 45◦C to maintain its stability and integrity.

2.4. Characterization of NPs
The synthesized tri-metallic oxide NPs were characterized

using UV-Vis spectroscopy and X-ray diffraction (XRD). The
composition of the Ni/Cr/Cu NPs were investigated using a
Empyrean X-ray diffractometer, operated at 45 kV, 40 mA, with
CuKα1 radiation (wavelength λ=1.5406 Å) and copper filter.
The X-ray diffractogram was recorded in the 2θ range from 10◦

to 80◦ at scanning steps of 0.026◦. An UV-Vis spectrum was
measured between 190-800 nm using Jasco spectrophotometer
to determine the characteristic peaks of the synthesized NPs.

2.5. Antimicrobial activity
The antimicrobial activity of tri-metallic NPs was evaluated

against two bacterial and two fungal species by well diffusion
method [17,18]. 1 mL of the selected microbial species was
inoculated over the entire agar surface. A well with 5 mm di-
ameter was bored aseptically, and 50µL of the NPs solution at
desired concentration was introduced into the well. The inoc-
ulated plates were incubated under suitable conditions depend-
ing upon the test microorganism. The details of the medium,
species and incubation conditions are provided below.

2.5.1. Antibacterial activity
Mueller Hinton Agar plates were prepared and inoculated

with standardized bacterial strains comprising E. coli and S.
aureus in individual plate. Five different wells were bored on
the agar plates where, four different concentrations of the NPs
were added in four separate wells and control (amoxicillin) was
added in the other well. The plates were incubated (37◦C/24
hours) and observed for zone of inhibition (ZOI).

2.5.2. Antifungal activity
Sabouraud Dextrose Agar plates were prepared and inocu-

lated with standardized fungal strains of A. flavus and Penicil-
lium sp. Five different wells were bore on the agar plates where,
four different concentrations of the NPs were added in four in-
dividual wells and control (fluconazole) was added in the other
well. The plates were then incubated at 25◦C for 72 hours and
observed for zone of inhibition (ZOI).

2.6. Statistical analysis
All results of antimicrobial activity are expressed only nu-

merically as mean ± standard deviation (SD) without any anal-
ysis.

3. Results and discussions

3.1. Synthesis and characterization of tri-metallic NPs
Initially, the extract and the precursor solution looked tanned

brown colour. After the reduction reaction, the solution turned
dark brown in colour. After centrifugation and drying, a dark
brown powder was collected. The UV-Vis absorption of the
C. sativum extract was compared with the collected tri-metallic
oxide NPs. The tri-metallic oxide NPs showed three charac-
teristic peaks at 261 nm, 426 nm and 564 nm (Figure 1) that
correspond to tri-metallic oxide Ni/Cr/Cu NPs reported earlier

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Figure 1. UV-Visible spectrum of tri-metallic oxide Ni/Cr/Cu NPs

Figure 2. Powder XRD of tri-metallic oxide Ni/Cr/Cu NPs

[16]. Similar results were obtained in monometallic NPs syn-
thesized using individual metallic precursors [19–21].

The Ni, Cu, and Cr NPs tend to show characteristic XRD
peaks at 40-50◦ and 50-60◦ [19–21] individually. A combina-
tion of peaks was observed in XRD (Figure 2) and new peak
at 20◦ characteristic to that of graphene nanomaterials was also
observed. This may be due to the reduction reaction of phyto-
chemical that is present in the leaf extract of C. sativum. Using
Scherrer’s equation, the crystallite size of the tri-metallic oxide
NPs was calculated as 17.72 nm from the XRD. In the present
study, the cumulative peaks of all the three metal were exhib-
ited in both UV-Vis and XRD. This shows that tri-metallic oxide
NPs comprising Ni, Cr and Cu were synthesized.

3.2. Antibacterial activity
The antibacterial activity of the tri-metallic NPs was deter-

mined against E. coli and Staph. aureus by measuring the ZOI
after incubation (37◦C/ 24 h) (Table 1). The observed results
are presented in figure 3. It can be seen that the tri-metallic
NPs exhibited dose-dependent antibacterial activity. That is,
the zone of inhibition increased proportionally with the concen-
tration of NPs. Among the tested species, the tri-metallic NPs
showed better antibacterial activity against E. coli than Staph.
aureus. There are reports that discussed the antibacterial ac-
tivity of these metals. In a study by O. Dlugosz et. al., cop-

Figure 3. Agar plates showing ZOI against (a) E. coli and (b) Staph
aureus. Control - Amoxicillin

Figure 4. Agar plates showing ZOI against (a) A. flavus and (b) Penicil-
lium sp. Control - Fluconazole

per showed improved antibacterial activity against E. coli and
Staph. aureus with respect to increasing size. But its effect re-
duced when it is combined with silver. On the other hand, it ex-
hibited inhibition against broader spectrum of microbes. In an-
other study, the bimetallic NPs made of gold and silver showed
that the size and the antimicrobial property are inversely pro-
portional to each other [15]. There is only one study which dis-
cussed similar antibacterial property of similar tri-metallic NPs
wherein all the three metals showed synergistic antimicrobial
effect [16]. Hence as per the earlier studies and the present re-
sults, it can be understood that the antibacterial property of the
metallic NPs was due to the size and the charge of the active
surface area.

3.3. Antifungal activity

The antifungal activity of the tri-metallic NPs was deter-
mined against A. flavus and Penicillium sp. by a similar method
to that of antibacterial activity. The measured ZOI and its re-
spective plates are provided in Table 1 and figure 4. It was
observed that the organism showed resistance towards the tri-
metallic NPs at 125 µg/mL concentration. But as the nanoparti-
cle’s concentration increased, the diameter of the zone of inhibi-
tion also increased. Thus, the dose and inhibition were directly
proportional to each other. In earlier studies, the bimetallic NPs
showed good activity towards fungal species Candida sp. and
B. cinerea [22,23] due to their external charge and size. The
tri-metallic NPs showed better antifungal activity against Peni-
cillium sp. than A. flavus that can be attributed towards even

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Table 1. Zone of inhibition (mm) measured for each microbes across the concentration gradient. All the values are given as mean value.
S No NPs Concentration (µg/mL) E. coli (mm) Staph aureus (mm) A. flavus(mm) Penicillium sp. (mm)
1 125 19 13 Nil Nil
2 250 17 15 13 12
3 500 21 17 18 14
4 1000 27 24 23 15
5 Control 16 18 18 16

size distribution and cumulative charge of the NPs.

4. Conclusion

Tri-metallic NPs comprising Ni, Cr and Cu were synthe-
sized using the leaf extract of Coriander sativum. Characteris-
tic peaks were observed in both UV-Vis spectroscopy and XRD
diffractogram. The main objective of this research is to investi-
gate the recognition and targeting capability of the tri-metallic
oxide NPs and use it to deliver the antimicrobial drugs for re-
sistant species. As per the results, these NPs showed good an-
timicrobial property against E. coli, Staph. aureus, Penicillium
sp. and A. flavus. Further investigation is required to determine
other parameters like minimum inhibitory concentration, criti-
cal dose and lethal dose.

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