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Sains
Malaysiana 51(5)(2022): 1353-1362
http://doi.org/10.17576/jsm-2022-5105-07
Sensitivity of Proteus vulgaris to Zinc Oxide
Nanoparticles
(Kesensitifan Proteus
vulgaris terhadap
Nanozarah Zink Oksida)
SINOUVASSANE DJEARAMANE1,*, THARANI RAVINTHARAN1, SHAROLYNNE XIAO TONG
LIANG1, LING SHING WONG2, MAHADEVA RAO U.S.3 & SENTHILKUMAR
BALASUBRAMANIAN4
1Department of Biomedical
Science, Faculty of Science, Universiti Tunku Abdul
Rahman, 31900 Kampar, Perak Darul
Ridzuan, Malaysia
2Life Science Division,
Faculty of Health and Life Sciences, INTI International
University, 71800 Nilai, Negeri Sembilan Darul Khusus, Malaysia
3Biochemistry Unit,
Faculty of Medicine, Universiti Sultan Zainal Abidin, 20400,
Kuala Terengganu, Terengganu Darul Iman, Malaysia
4Department of Zoology,
Thiruvalluvar University, 632115 Vellore, Tamilnadu, India
Diserahkan: 25 September 2020/Diterima: 21 September 2021
Abstract
Zinc oxide nanoparticle (ZnO NP) has become a popular choice
in nanomedicine and in the treatment of infections. The present study
investigated the sensitivity of Proteus vulgaris to ZnO NPs. The
bacteriostatic and bactericidal effects on P. vulgaris were determined
by using turbidity and colony count methods. The oxidative stress induced by
the treatment of ZnO NPs was evaluated by investigating the level of
intracellular reactive oxygen species (ROS) along with lipid peroxidation (LP)
analysis. The results showed the highest bacterial growth
inhibition of 76.21±1.91
and 87.49±3.29% determined using the turbidity and colony count methods,
respectively. The highest oxidative stress effects were
observed in P. vulgaris exposed to 100 µg/mL of ZnO NPs for 24 h as
shown by 510.90±108.53% increase in ROS production and 328.77±44.36% increase in LP level.
The Fourier transform infrared
spectroscopy (FTIR) spectrum illustrated the possible involvement of functional
groups such as amine, alkane, acid and alkene from the bacterial cell wall in
allowing the surface attachment of nanoparticles on the bacterial cells. Hence,
the present study clearly demonstrated the sensitivity of P. vulgaris to
ZnO NPs.
Keywords: Antibacterial property; oxidative stress; Proteus
vulgaris; sensitivity; zinc oxide nanoparticles
Abstrak
Nanozarah zink oksida (ZnO NP)
telah menjadi pilihan popular dalam nanoperubatan serta dalam rawatan
jangkitan. Kajian ini meneliti kesensitifan Proteus vulgaris terhadap
ZnO NP. Kesan bakteriostatik dan bakterisid P. vulgaris ditentukan
dengan menggunakan kaedah kekeruhan dan penghitungan koloni. Tekanan oksidatif
yang disebabkan oleh rawatan ZnO NP dinilai dengan menentukan tahap spesies
oksigen reaktif (ROS) intrasel bersama dengan analisis peroksidasi lipid (LP). Hasil
menunjukkan perencatan pertumbuhan bakteria tertinggi iaitu 76.21±1.91 dan
87.49±3.29% masing-masing ditentukan menggunakan kaedah kekeruhan dan
penghitungan koloni. Kesan tekanan oksidatif tertinggi diperhatikan pada P.
vulgaris yang terdedah kepada 100 µg/mL ZnO NP selama 24 jam seperti yang
ditunjukkan oleh peningkatan pengeluaran ROS sebanyak 510.90±108.53% dan
peningkatan tahap LP sebanyak 328.77±44.36%. Spektrum transformasi Fourier
inframerah (FTIR) menunjukkan kemungkinan penglibatan kumpulan berfungsi
seperti amina, alkana, asid dan alkena daripada dinding sel bakteria
yang membolehkan pelekatan permukaan nanozarah pada sel bakteria. Oleh itu,
kajian ini menunjukkan dengan jelas kesensitifan P. vulgaris terhadap
ZnO NP.
Kata kunci: Kesensitifan;
nanozarah zink oksida; Proteus vulgaris; sifat antibakteria; tekanan
oksidatif
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*Pengarang
untuk surat-menyurat; email: sinouvassane@utar.edu.my
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