Cytotoxic Activity of CuO NPs Prepared by PLAL Against Liver Cancer (Hep-G2) Cell Line and HdFn Cell Lines

Main Article Content

Huda Hussein Abbas
Sabah N. Mazhir

Abstract

A simple physical technique was used in this study to create stable and cost-effective copper oxide (CuO) nanoparticles from pure copper metal using the pulsed laser ablation technique. The synthesis of crystalline CuO nanoparticles was confirmed by various analytical techniques such as particle concentration measurement using atomic absorption spectrometry (AAS), field emission scanning electron microscopy (FE-SEM), the energy dispersive X-ray (EDX), and X-ray diffraction (XRD) to determine the crystal size and identify of the crystal structure of the prepared particles. The main characteristic diffraction peaks of the three samples were consistent. The corresponding 2θ is also consistent, and the cytotoxicity of the nanoparticles was also investigated. After 24 hours of exposure, the percentage of cytotoxicity was calculated. The maximum toxicity of Hep-G2 was 37.81% at the maximum concentration of (500) µg mL-1 after 24 hours of exposure. Also, the maximum toxicity of the normal cell line was 27.85% at a maximum concentration of (500) µg mL-1.

Article Details

How to Cite
1.
Abbas HH, Mazhir SN. Cytotoxic Activity of CuO NPs Prepared by PLAL Against Liver Cancer (Hep-G2) Cell Line and HdFn Cell Lines. IJP [Internet]. 2023 Jun. 1 [cited 2024 Nov. 23];21(2):9-16. Available from: https://ijp.uobaghdad.edu.iq/index.php/physics/article/view/1092
Section
Articles
Author Biographies

Huda Hussein Abbas, Department of Physics/College of Science for Women/ University of Baghdad, Baghdad, Iraq

 

 

 

 

Sabah N. Mazhir, Department of Physics/College of Science for Women/ University of Baghdad, Baghdad, Iraq

 

 

 

References

M. Bagherzadeh, M. Safarkhani, A. M. Ghadiri, M. Kiani, Y. Fatahi, F. Taghavimandi, H. Daneshgar, N. Abbariki, P. Makvandi, and R. S. Varma, Sci. Rep. 12, 15351 (2022).

F. A. Bezza, S. M. Tichapondwa, and E. M. Chirwa, Sci. Rep. 10, 16680 (2020).

Y. Ma, Laser Technology and its Applications. (London, UK, IntechOpen, 2019).

J. O. Ighalo, P. A. Sagboye, G. Umenweke, O. J. Ajala, F. O. Omoarukhe, C. A. Adeyanju, S. Ogunniyi, and A. G. Adeniyi, Envir. Nanotech., Monit. Manag. 15, 100443 (2021).

C. Petridis, K. Savva, E. Kymakis, and E. Stratakis, J. Coll. Interf. Sci. 489, 28 (2017).

S. N. Mazhir, N. A. Abdullah, A. F. Rauuf, A. H. Ali, and H. I. Al-Ahmed, Bagh. Sci. J. 15, 81 (2018).

Z. Yan, R. Bao, and D. B. Chrisey, Phys. Chemis. Chem. Phys. 15, 3052 (2013).

B. Bai, S. Saranya, V. Dheepaasri, S. Muniasamy, N. S. Alharbi, B. Selvaraj, V. S. Undal, and B. M. Gnanamangai, J. King Saud Univer.-Sci. 34, 102120 (2022).

J. M. Gaucin-Delgado, A. Ortiz-Campos, L. G. Hernandez-Montiel, M. Fortis-Hernandez, J. J. Reyes-Pérez, J. A. Gonzáles-Fuentes, and P. Preciado-Rangel, Plants 11, 912 (2022).

N. Acacia, F. Barreca, E. Barletta, D. Spadaro, G. Currò, and F. Neri, Appl. Surf. Sci. 256, 6918 (2010).

D. Alagarasan, A. Harikrishnan, M. Surendiran, K. Indira, A. S. Khalifa, and B. H. Elesawy, Appl. Nanosci., 1 (2021).

N. K. Abdalameer and S. N. Mazhir, Inter. J. Nanosci. 20, 2150044 (2021).

L. S. Alqarni, M. D. Alghamdi, A. A. Alshahrani, and A. M. Nassar, J. Chem. 2022, 1 (2022).

Z. Alhalili, Arab. J. Chem. 15, 103739 (2022).

R. Katwal, H. Kaur, G. Sharma, M. Naushad, and D. Pathania, J. Indus. Engin. Chem. 31, 173 (2015).

S. Nations, M. Long, M. Wages, J. D. Maul, C. W. Theodorakis, and G. P. Cobb, Chemosphere 135, 166 (2015).

S. N. Mazhir, K. A. Aadim, M. M. Al-Halbosiy, and N. K. Abdalameer, Indian J. Foren. Medic. Toxic. 15, 2072 (2021).

Q. Zhang, K. Zhang, D. Xu, G. Yang, H. Huang, F. Nie, C. Liu, and S. Yang, Prog. Mat. Sci. 60, 208 (2014).

V. A. Arzumanian, O. I. Kiseleva, and E. V. Poverennaya, Inter. J. Molec. Sci. 22, 13135 (2021).

S. Khorrami, A. Zarrabi, M. Khaleghi, M. Danaei, and M. Mozafari, Inter. J. Nanomedic. 13, 8013 (2018).

M. Ott, V. Gogvadze, S. Orrenius, and B. Zhivotovsky, Apoptosis 12, 913 (2007).

A. Wongrakpanich, I. A. Mudunkotuwa, S. M. Geary, A. S. Morris, K. A. Mapuskar, D. R. Spitz, V. H. Grassian, and A. K. Salem, Envir. Sci.: Nano 3, 365 (2016).

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