THE CALCINATION TEMPERATURE EFFECT ON  THE ANTIOXIDANT AND RADIOPROTECTION  PROPERTIES OF CeO2 NANOPARTICLES

Iis Nurhasanah; Weni Safitri; Tri Windarti; Agus Subagio

doi:10.14710/reaktor.18.1.22-26

DOI: https://doi.org/10.14710/reaktor.18.1.22-26

THE CALCINATION TEMPERATURE EFFECT ON THE ANTIOXIDANT AND RADIOPROTECTION PROPERTIES OF CeO2 NANOPARTICLES

*Iis Nurhasanah - Department of Physics, Faculty of Science and Mathematics, Diponegoro University, Indonesia

Weni Safitri - Department of Physics, Faculty of Science and Mathematics, Diponegoro University

Tri Windarti - Department of Chemistry, Faculty of Science and Mathematics, Diponegoro University

Agus Subagio - Department of Physics, Faculty of Science and Mathematics, Diponegoro University

Received: 1 Nov 2017; Published: 28 May 2018.

BibTex Citation Data :

@article{Reaktor16431,
    author = {Iis Nurhasanah and Weni Safitri and Tri Windarti and Agus Subagio},
    title = {THE CALCINATION TEMPERATURE EFFECT ON  THE ANTIOXIDANT AND RADIOPROTECTION  PROPERTIES OF CeO2 NANOPARTICLES},
    journal = {Reaktor},
  volume = {18},
    number = {1},
    year = {2018},
    keywords = {},
    abstract = { The CeO 2  nanoparticles are very interesting to be studied as biomedical materials due to its unique physical and chemical properties. The non-stoichiometric properties of CeO 2  play a role in the redox/catalytic processes that scavenging free radicals. These properties make CeO 2  nanoparticles as being potentially antioxidant and radioprotector materials. In this paper, we report the calcination temperature effect on the antioxidant properties and  radioprotective effect of CeO 2  nanoparticles synthesized by precipitation method. The CeO 2  nanoparticles were synthesized by precipitation method at various calcinations temperatures (300 o C – 700 o C). The formation of CeO 2  nanoparticles and crystallite size was analyzed using X-ray diffractometers. The DPPH method was used to investigate antioxidant properties of CeO 2 .  Dose Enhancement Factor (DEF) of CeO 2  nanoparticles were determined by measurement of the absorbed dose of X-ray radiation (Linac 6 MV 200 MU). X-ray diffraction pattern showed formation of cubic fluorite of CeO 2  nanoparticles with crystallite size in the range 9 nm-18 nm.  Calcination temperature of 500 o C resulted in CeO 2  nanoparticles with the best antioxidant properties and lowest DEF value. The radioprotection effect of CeO 2  nanoparticles was evaluated based on  Escherichia coli  survival toward X-ray radiation with a dose of 2 Gy. The CeO 2  nanoparticles increased  Escherichia coli  survival of about 24.8% order.  These results suggested that CeO 2  nanoparticles may potentially be as radioprotector of X-ray Linac 6 MV.      Keywords : Antioxidant, CeO 2  nanoparticles, Dose Enhancement Factor (DEF), radioprotector },
   issn = {2407-5973},   pages = {22--26}  doi = {10.14710/reaktor.18.1.22-26},
    url = {https://ejournal.undip.ac.id/index.php/reaktor/article/view/16431}
}

Citation Format:

Abstract

The CeO₂ nanoparticles are very interesting to be studied as biomedical materials due to its unique physical and chemical properties. The non-stoichiometric properties of CeO₂ play a role in the redox/catalytic processes that scavenging free radicals. These properties make CeO₂ nanoparticles as being potentially antioxidant and radioprotector materials. In this paper, we report the calcination temperature effect on the antioxidant properties and radioprotective effect of CeO₂ nanoparticles synthesized by precipitation method. The CeO₂ nanoparticles were synthesized by precipitation method at various calcinations temperatures (300^oC – 700^oC). The formation of CeO₂ nanoparticles and crystallite size was analyzed using X-ray diffractometers. The DPPH method was used to investigate antioxidant properties of CeO₂. Dose Enhancement Factor (DEF) of CeO₂ nanoparticles were determined by measurement of the absorbed dose of X-ray radiation (Linac 6 MV 200 MU). X-ray diffraction pattern showed formation of cubic fluorite of CeO₂ nanoparticles with crystallite size in the range 9 nm-18 nm. Calcination temperature of 500^oC resulted in CeO₂ nanoparticles with the best antioxidant properties and lowest DEF value. The radioprotection effect of CeO₂ nanoparticles was evaluated based on Escherichia coli survival toward X-ray radiation with a dose of 2 Gy. The CeO₂ nanoparticles increased Escherichia coli survival of about 24.8% order. These results suggested that CeO₂ nanoparticles may potentially be as radioprotector of X-ray Linac 6 MV.

Keywords: Antioxidant, CeO₂ nanoparticles, Dose Enhancement Factor (DEF), radioprotector

Fulltext View|Download

Article Metrics:

Article Info

Section: Research Article

Language : EN

In Volume 18 No. 1 March 2018

Recent articles

Front Mattter Vol 18 No. 1 March 2018 THE CALCINATION TEMPERATURE EFFECT ON THE ANTIOXIDANT AND RADIOPROTECTION PROPERTIES OF CeO2 NANOPARTICLES The Kinetics of Calcium Oxide Catalyzed Esterification of Glycerol with Free Fatty Acids Using Pseudo-homogeneous Model Approach Recovery of Aluminum from Aluminum Coated Plastic Waste using Pyrolysis Process Back Matter Vol 18 No. 01 March 2018 More recent articles

Most cited articles

OPTIMASI PRODUKSI PULP FORMACELL DARI TANDAN KOSONG KELAPA SAWIT (TKKS) DENGAN METODE PERMUKAAN RESPON INFLUENCE OF INITIAL pH SOLUTION ON BIOFILM FORMATION AND CORROSION OF CARBON STEEL BY Serratia marcescens PADDY DRYING IN MIXED ADSORPTION DRYER WITH ZEOLITE: DRYING RATE AND TIME ESTIMATION NON-DISSOLVED SOLIDS REMOVAL DURING PALM KERNEL OIL ULTRAFILTRATION PENGOLAHAN PRIMER LIMBAH TEKSTIL DENGAN ELEKTROKOAGULASI More cited articles

Last update:

The Effect of Calcination Temperature on the Characteristics of CeO2 Synthesized Using the Precipitation Method
Zidan Alfian Bahtiar, Tri Windarti, Dwi Hudiyanti. Jurnal Kimia Sains dan Aplikasi, 27 (5), 2024. doi: 10.14710/jksa.27.5.226-231
Cerium oxide nanoparticles application for rapid adsorptive removal of tetracycline in water
Iis Nurhasanah, Kadarisman, Vincensius Gunawan, Heri Sutanto. Journal of Environmental Chemical Engineering, 8 (1), 2020. doi: 10.1016/j.jece.2019.103613
Feasibility of Ceria Nanocrystal Adsorbent for Amoxicillin Removal from Water
Iis Nurhasanah, Kadarisman, Vincensius Gunawan, Heri Sutanto. Key Engineering Materials, 860 , 2020. doi: 10.4028/www.scientific.net/KEM.860.338
The Effect of Precursor Concentration on the Particle Size, Crystal Size, and Optical Energy Gap of CexSn1−xO2 Nanofabrication
Naif Mohammed Al-Hada, Rafiziana Md. Kasmani, Hairoladenan Kasim, Abbas M. Al-Ghaili, Muneer Aziz Saleh, Essam M. Banoqitah, Abdulsalam M. Alhawsawi, Anwar Ali Baqer, Jian Liu, Shicai Xu, Qiang Li, Azlan Muhammad Noorazlan, Abdullah A. A. Ahmed, Moayad Husein Flaifel, Suriati Paiman, Nazirul Nazrin, Bandar Ali Al-Asbahi, Jihua Wang. Nanomaterials, 11 (8), 2021. doi: 10.3390/nano11082143

Last update: 2025-02-01 09:22:04

No citation recorded.

In order for REAKTOR to publish and disseminate research articles, we need non-exclusive publishing rights (transferred from the author(s) to the publisher). This is determined by a publishing agreement between the Author(s) and REAKTOR. This agreement deals with transferring or licensing the publishing copyright to REAKTOR while Authors still retain significant rights to use and share their published articles. REAKTOR supports the need for authors to share, disseminate, and maximize the impact of their research and these rights in any databases.

As a journal author, you have the right to use your article for many purposes, including by your employing institute or company. These Author rights can be exercised without the need to obtain specific permission. Authors publishing in BCREC journals have wide rights to use their works for teaching and scholarly purposes without needing to seek permission, including, but not limited to:

use for classroom teaching by the Author or the Author's institution and presentation at a meeting or conference and distributing copies to attendees;
use for internal training by the author's company;
distribution to colleagues for their research use;
use in a subsequent compilation of the author's works;
inclusion in a thesis or dissertation;
reuse of portions or extracts from the article in other works (with full acknowledgment of the final article);
preparation of derivative works (other than commercial purposes) (with full acknowledgment of the final article);
voluntary posting on open websites operated by the author or the author’s institution for scholarly purposes,

(but it should follow the open access license of Creative Common CC-by-SA License).

Authors/Readers/Third Parties can copy and redistribute the material in any medium or format and remix, transform, and build upon the material for any purpose, even commercially. Still, they must give appropriate credit (the name of the creator and attribution parties (authors detail information), a copyright notice, an open access license notice, a disclaimer notice, and a link to the material), provide a link to the license, and indicate if changes were made (Publisher indicates the modification of the material (if any).

Authors/Readers/Third Parties can read, print and download, redistribute or republish the article (e.g., display in a repository), translate the article, download for text and data mining purposes, reuse portions or extracts from the article in other works, sell or re-use for commercial purposes, remix, transform, or build upon the material, they must distribute their contributions under the same license as the original Creative Commons Attribution-ShareAlike (CC BY-SA).