Preparation, formation mechanism, photocatalytic, cytotoxicity and antioxidant activity of sodium niobate nanocubes


RESEARCH ARTICLE

Preparation, formation mechanism,

photocatalytic, cytotoxicity and antioxidant

activity of sodium niobate nanocubes

Muhammad NawazID
1*, Sarah Ameen Almofty2, Faiza Qureshi1,3

1 Department of Nano-Medicine Research, Institute for Research and Medical Consultations (IRMC), Imam

Abdulrahman Bin Faisal University, Dammam, Saudi Arabia, 2 Department of Stem Cell Research, Institute

for Research and Medical Consultations (IRMC), Imam Abdulrahman Bin Faisal University, Dammam, Saudi

Arabia, 3 Deanship of Scientific Research, Imam Abdulrahman Bin Faisal University, Dammam, Saudi Arabia

* mnnmuhammad@iau.edu.sa, nawwaz@gmail.com

Abstract

A hydrothermal method was employed to prepare the sodium niobate (NaNbO3) nano-

cubes. We executed time dependent experiments to illustrate the formation mechanism of

sodium niobate nanocubes. It was observed that the morphology of NaNbO3 nanocubes

was dependent on the reaction time and 12hr reaction time was found to be suitable. Mor-

phology, composition, structure and optical properties of sodium niobate nanocubes were

evaluated by scanning electron microscope, X-ray energy-dispersive spectrometer, X-ray

diffraction and UV-visible diffuse reflectance spectrometer. The photocatalytic activity of

sodium niobate was studied for photocatalytic hydrogen production. It was anticipated that

the sodium niobate (NaNbO3) cubes exhibited good photocatalytic activity under UV light

irradiation using lactic acid as sacrificial agent. The cytotoxicity activity of sodium niobate

nanocubes was studied as well at different concentrations (5 mg/mL, 3 mg/mL, 1 mg/mL,

and 0.25 mg/mL) against human colon colorectal carcinoma cell line (HCT116) by MTT

assay and EC50 was found to be 1.9 mg/mL. Sodium niobate proved to be a good DPPH

free radical scavenging material, tested at different concentrations. It was noticed that peak

intensity at 517 nm was decreased after 30 minute incubation, further supporting the antioxi-

dant activity. This study will be useful for design and engineering of materials that can be

used in biomedical applications and in photocatalysis.

Introduction

Excess consumption of fossil fuel and increased pollution has make scientists actively looking

for solutions in terms of energy and environmental issues. Hydrogen is as an eco-friendly fuel

and an alternative source of energy. Currently, hydrogen is mostly used as energy source via

fossil fuels and electrolysis of water, the use of latter, however is economically not feasible as

the process consumes high energy. Solar energy is the alternatively favored renewable energy

source that can satisfy the global energy requirements. In order to resolve energy crisis and

environmental problems, photocatalytic hydrogen evolution using photocatalysts of

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OPEN ACCESS

Citation: Nawaz M, Almofty SA, Qureshi F (2018)

Preparation, formation mechanism, photocatalytic,

cytotoxicity and antioxidant activity of sodium

niobate nanocubes. PLoS ONE 13(9): e0204061.

https://doi.org/10.1371/journal.pone.0204061

Editor: Yogendra Kumar Mishra, Institute of

Materials Science, GERMANY

Received: June 2, 2018

Accepted: August 31, 2018

Published: September 14, 2018

Copyright: © 2018 Nawaz et al. 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.

Data Availability Statement: All relevant data are

within the paper.

Funding: The authors would like to thank King

Abdulaziz City for Science and Technology (KACST)

for financial support of this work through project

number 259-37- مص .

Competing interests: The authors have declared

that no competing interests exist.

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semiconductors such as oxides, sulfides and nitrides has been considered as an attractive and

clean way, low-cost and eco-friendly production of hydrogen [1–5].

The engineering and design of nanomaterials with controlled morphology has been getting

more attention and significance owing to their unique physical and chemical properties. The

photocatalytic properties of nanomaterials are vastly dependent on shape, size, crystal facets,

size distribution and phases [6–10] which makes it much more challenging for the researchers

to prepare the perfectly engineered materials that can be used as biomaterial, photocatalyst,

catalyst support and adsorbent [11–18].

Sodium niobate (NaNbO3) is a fascinating material with pervoskite structure at a low cost.

It has high crystallinity and good chemical stability with low environmental impact [19–21],

attracts scientists due to its ionic conductivity, photorefractive properties, nonlinear optics and

photocatalytic properties [22–25]. Different morphologies of nano NaNbO3, such as nano-

plates, nanocubes and nanowires have been studied for photocatalytic activities with the con-

clusion that photocatalytic activity improved with controlled morphology of NaNbO3 [26–29].

Current research indicates that sodium niobate is an efficient photocatalyst for hydrogen pro-

duction [30], photocatalytic decomposition of organic contaminants [25] and CO2 reduction

[30–32].

Several methods had been reported for the preparation of sodium niobate (NaNbO3), how-

ever, most of them involved complicated polymerized complex methods [32, 33], and there-

fore, the need to develop simple and economic method for the preparation of sodium niobate

(NaNbO3) was felt. As we discussed above, to resolve the energy crisis there is need to prepare

the low-cost and eco-friendly photocatalyst for hydrogen production. This study involved the

preparation of sodium niobate (NaNbO3) by hydrothermal method and its application as

photocatalyst and biomaterial. Furthermore, the formation mechanism and cytotoxicity of

sodium niobate has never been explored and studied so far. This study is useful to provide the

details of formation mechanism of NaNbO3 and to study the cytotoxicity, antioxidant and

photocatalytic activity.

Materials and methods

Chemical and materials

All chemicals, kits and reagents were purchased from commercial sources and used as it.

Preparation of sodium niobate cubes

A mixture of niobium pentoxide (Nb2O5, 0.265g) and sodium hydroxide (0.6g), was stirred in

deionized water at room temperature for certain period. The solution was then transferred

into Teflon-lined autoclave and heated at 200˚C for 12h. After cooling, Teflon-lined autoclave

at room temperature; the white precipitates obtained were centrifuged and washed several

times with deionized water and ethanol. Lastly, the product was dried at 60˚C for 12h.

Characterization

X-ray diffraction pattern of NaNbO3 was recorded on a Rigaku X-ray diffractometer using Cu

Kα radiation. Morphology of the product was observed by field emission scanning electron
microscope (FE-SEM) and elemental composition was determined by X-ray energy-dispersive

(EDX). The UV-visible spectrum was obtained on Shimadzu UV-Vis spectrophotometer using

BaSO4 as a reference.

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Photocatalytic activity

Photocatalytic activity of NaNbO3 was studied in a closed gas circulation system under a

300W xenon lamp. 50 mg of catalyst was added to aqueous lactic acid solution and dispersed

ultrasonically. The solution was evacuated for 20–30 minutes to remove the dissolved gases

before irradiation and then exposed to irradiation by Xe lamp. The hydrogen gas generated

was determined in situ by a gas chromatogram (TECHCOMP, GC 7890-II) equipped with a
TCD detector [8].

Cell culture and cytotoxicity activity

Human colon colorectal carcinoma cell line (HCT116) was purchased from ATTC (American

Type Culture Collection, USA) and maintained in DMEM medium. Cytotoxicity activity of

NaNbO3 nanocubes were evaluated against HCT116 cells by MTT assay Vybrant
1

MTT Cell

Proliferation Kit (Thermo Fisher Scientific). HCT116 cells were seeded in 96-well plates at

(10
4

cells/well) in DMEM medium supplied with 10% fetal bovine serum and 1% penicillin-

streptomycin. Different concentrations of NaNbO3 nanocubes (5 mg/mL, 3mg/mL, 1 mg/mL,

and 0.25 mg/mL) were added to the wells. Cells were maintained in humidified atmosphere

with 5% CO2 at 37˚C and incubated for 24 h. After incubation, culture medium was removed

and fresh medium was added with 10 μL of MTT solution, cells were further incubated for 4h
at 37˚C. Medium was removed after incubation and sterile DMSO (100 μL) was added to solu-
bilize the formazan blue crystals. SYNERGY Neo2 multi-mode microplate reader (Biotek) was

employed to record the absorbance at 570 nm. Cell viability was then calculated using follow-

ing formula:

Cell viability ð%Þ¼ absorbance of sample=absorbance of control � 100

Antioxidant activity

The antioxidant activity of NaNbO3 was studied using DPPH as free radicals source. To assess

the antioxidant activity of NaNbO3, different concentration such as 5 mg/mL, 3 mg/mL and

1mg/mL were prepared. 1 mL of DPPH solution (0.1 mM in methanol) was mixed with 3 mL

of NaNbO3 different concentrations and incubated in dark for 30 minutes. Mixture was centri-

fuged and supernatant was analyzed at 517 nm against blank using UV-visible spectrophotom-

eter. The % inhibition of DPPH scavenging activity was computed as:

% DPPH radical scavenging activity ¼ðAbsblank � Abssample=AbsblankÞ� 100

Where Abs blank is the absorbance of blank and Abs sample absorbance of sample.

Results & discussion

Characterization

NaNbO3 nanocubes were prepared by hydrothermal method and morphology of the product

was observed by SEM. Fig 1a shows representative images of NaNbO3 nanocubes at different

magnifications. It is clear from SEM images that the product has nanocubes morphology with

500 nm in size.

The crystal structure of NaNbO3 was probed by X-ray diffraction. Fig 1b shows the XRD

pattern of NaNbO3 prepared at 200˚C for 12 h. The sharp and strong diffraction peaks suggest

a nanocrystalline structure. All the diffraction peaks can be indexed as cubic phase of NaNbO3

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(JCPDS card no. 75–2102). No impurities can be detected in this pattern, which implies cubic

phase of NaNbO3 can be obtained under the described experimental conditions.

Energy-dispersive X-ray spectroscopy (EDX) was performed to confirm the composition of

the as-prepared product. We selected different surface as collection areas and found the same

results. Fig 1c shows energy-dispersive X-ray spectroscopy (EDX) spectra of NaNbO3; con-

firming the presence of Na, Nb and O in the product and also shows there is no impurity in

the product. A UV-visible diffuse reflectance (DRS) spectrum of NaNbO3 is revealed in Fig 1d.

The diffuse reflectance spectra of the product demonstrated an absorption edge at 386 nm in

the UV region, corresponding to the band gap energy of 3.21 eV.

Formation mechanism

In order to check the effect of different solvents on the morphology and size of NaNbO3,

experiments were conducted in water, methanol and ethanol at 200˚C. SEM results obtained

Fig 1. Characterization data of NaNbO3. (a) FESEM images of NaNbO3. (b) XRD pattern of NaNbO3. (c) EDX pattern of NaNbO3. (d) DR-UV-

visible spectrum of NaNbO3.

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in different solvents are shown in Fig 2a–2c. As we can see in the Fig 2a, when reaction was

conducted in the water, the product was nanocubes. On the other hand, when reaction was

performed in methanol and ethanol, nanocubes were not formed (Fig 2b and 2c). Hence water

was selected as a reaction medium for the preparation of NaNbO3 nanocubes. To optimize the

reaction temperature and to see the effect of temperature on the morphology and size of

NaNbO3 nanocubes, we performed the reaction at different temperatures (150˚C, 180˚C and

200˚C). SEM images of the products obtained at 150˚C, 180˚C and 200˚C are shown in the Fig

3a–3c. It is clear from SEM results, the product obtained at 150˚C has big block like morphol-

ogy with aggregates (Fig 3a). On the other hand, when reaction was performed at 180˚C,

nanorods and aggregated nanocubes were formed (Fig 3b). Furthermore, the product obtained

at 200˚C was consisted of nanocubes (Fig 3c). These results suggested that reaction tempera-

ture 200˚C is optimal to get NaNbO3 nanocubes. To further understand the formation mecha-

nism of NaNbO3 nanocubes at 200˚C, we conducted reactions at different times. As it is

evident from Fig 4a, the product obtained after 30 minute of reaction comprises of spheres.

After 1h, nanocubes are formed with the co-existence of small particles (Fig 4b). The SEM

image in Fig 4c indicates that nanocubes are formed as the reaction proceeded for 3 h. Fig 4d

is SEM image of nanocubes formed after 6 h reaction time with some aggregates. Finally, well-

developed nanocubes (having size from 100–500 nm) were observed upon increasing further

reaction time to 12h (Fig 4e).

Fig 2. Effect of solvents on the morphology and size of NaNbO3. (a) Water. (b) Methanol. (c) Ethanol.

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Fig 3. Effect of temperature on the morphology and size of NaNbO3. (a) 150˚C. (b) 180˚C. (c) 200˚C.

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Fig 4. FESEM images of NaNbO3 at different times. (a) 30 min. (b) 1h. (c) 3h. (d) 6h. (e) 12h at 200˚C.

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Based on the above discussion, it can be deduced that oriented attachment and Ostwald rip-

ening are involved for the formation of NaNbO3 nanocubes. Fig 5 displays proposed formation

mechanism for NaNbO3 nanocubes. In the course of reaction, NaOH reacts with Nb2O5 and it

results in the formation of primary nanocrystals. The primary nanocrystals undergo oriented

attachment to form small cubes. These primary nanocubes undergo mutual orientation and

self-assembled to form nanocubes (Fig 5). When reaction was preceded further, reaction rate

further decreased and at this stage Ostwald ripening became more dominant. Due to higher

surface energy, small particles slowly dissolved to form nanocubes [34]. Stepwise formation

mechanism is illustrated in Fig 5.

Photocatalytic activity

The photocatalytic activity of synthesized NaNbO3 nanocubes for hydrogen production was

evaluated under UV light and expressed in terms of hydrogen evolution rate (Fig 6). As it can

be seen in Fig 6, the photocatalytic activity of NaNbO3 started increasing with passage of time.

However, after certain time the photocatalytic activity was dramatically decreased. It could be

possible that with the lapse of time the concentration of sacrificial reagent was decreased

which result in the lower rate of hydrogen production. The photocatalytic activity of NaNbO3

could be ascribed to its light harvesting ability and can accelerate the transportation of photo-

generated electron hole pairs, making the photocatalytic process more efficient [9]. Further-

more, good crystallinity of NaNbO3 also reduces the chance of electron hole recombination

and enhances the photocatalytic activity. Proposed mechanism for the photocatalytic hydrogen

production of NaNbO3 under UV light irradiation is illustrated in Fig 7.

Cytotoxicity activity

The cytotoxicity activity of NaNbO3 nanocubes was studied against human colon colorectal

carcinoma cell line (HCT116) at different concentrations such as 5 mg/mL, 3 mg/mL and 1

mg/mL and 0.25 mg/mL. The cytotoxicity activity of NaNbO3 nanocubes was observed from 1

mg/mL concentration and at the higher concentrations, whereas no detectable effect at the

Fig 5. Stepwise illustration for the formation mechanism of NaNbO3 nanocubes.

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lowest concentration (0.25 mg/mL) was observed. The effective concentration (EC50) of

NaNbO3 was calculated using the equation generated from exponential chart of the cell viabil-

ity percentage against concentrations. EC50 was found 1.9 mg/mL. The cell viability % of the

NaNbO3 nanocubes treated cells at different concentration is shown in Fig 8.

Antioxidant activity

We considered different concentration of NaNbO3 nanocubes to study the antioxidant activ-

ity. During the experiment, a change in color of DPPH solution from violet to pale yellow was

noticed in the presence of NaNbO3 nanocubes. Furthermore, intensity of peak at 517 was

decreased after 30 minute (Fig 9), indicated the free radical scavenging activity of NaNbO3

nanocubes. The free radical scavenging activity of NaNbO3 was perceived between 71.33 to

72.79% at different concentrations. The decline in intensity of peak at 517 nm could be attrib-

uted due to the transfer of electron density situated at oxygen to the odd electron found at

nitrogen atom in DPPH.

The results of this study were promising; sodium niobate (NaNbO3) with controlled mor-

phology (nanocubes) was prepared at 200˚C. NaNbO3 revealed good photocatalytic activity

Fig 6. H2 evolution rate by NaNbO3 for 6 h irradiation.

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for hydrogen production by splitting water indicating that it can be used as photocatalyst. The

effective concentration (EC50) of NaNbO3 nanocubes against human colon colorectal carci-

noma cell line (HCT116) was observed 1.9 mg/mL. NaNbO3 also demonstrated good antioxi-

dant activity at different concentrations. Biological results indicate that NaNbO3 can be used

as biomaterial.

Conclusion

NaNbO3 nanocubes were successfully produced via facile hydrothermal method. Time depen-

dent study was conducted to deduce the formation mechanism of NaNbO3 nanocubes. Results

revealed development of nuclei that transitioned to segregated nanocubes as the reaction time

progressed. Band gap of NaNbO3 was observed 3.21 eV and it exhibited good photocatalytic

activity for hydrogen production under UV light irradiation. EC50 of NaNbO3 nanocubes

against human colon colorectal carcinoma cell line (HCT116) was found to be 1.9 mg/mL.

The antioxidant activity was found to be significant too and coupled with anticancer potential

can be a good candidate as an engineered biomaterial. This work provides insights for the

Fig 7. Proposed mechanism for the photocatalytic hydrogen production of NaNbO3 under UV light irradiation using lactic acid

as sacrificial agent.

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Fig 8. Percentage of cell viability using MTT assay. HCT116 cells were treated with different concentrations of NaNbO3 nanocubes (5

mg/mL, 3 mg/mL, 1 mg/mL and 0.25 mg/mL) and MTT assay was performed 24h post incubation to measure the cell viability. The

statistical analysis was performed using oneway ANOVA- Dunnett’s test, whereas � = p<0.05.

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preparation of NaNbO3 nanocubes with well-regulated morphologies, serving as promising

photocatalyst.

Acknowledgments

The authors would like to thank King Abdulaziz City for Science and Technology (KACST)

for financial support of this work through project number: 259-37- مص .

Author Contributions

Conceptualization: Muhammad Nawaz.

Investigation: Sarah Ameen Almofty, Faiza Qureshi.

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