Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria

Pervaiz Ahmad; Mayeen Uddin Khandaker; Abdulhameed Khan; Fida Rehman; Salah Ud Din; Hazrat Ali; Muhammad Imtiaz Khan; Nawshad Muhammad; Nasar Ahmed; Zahoor Ullah; Ghulamullah Khan; Sirajul Haq; Talha Bin Emran; Rohit Sharma; I. M. Ashraf

doi:10.1155/2022/3605054

Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria

Pervaiz Ahmad
, Mayeen Uddin Khandaker
, Abdulhameed Khan
, Fida Rehman
, Salah Ud Din
, Hazrat Ali
, Muhammad Imtiaz Khan
, Nawshad Muhammad
, Nasar Ahmed
, Zahoor Ullah
, Ghulamullah Khan
, Sirajul Haq
, Talha Bin Emran
, Rohit Sharma
, I. M. Ashraf

Research output: Contribution to journal › Article › peer-review

Abstract

A simple process based on the dual roles of both magnesium oxide (MgO) and iron oxide (FeO) with boron (B) as precursors and catalysts has been developed for the synthesis of borate composites of magnesium and iron (Mg2B2O5-Fe3BO6) at 1200 degrees C. The as-synthesized composites can be a single material with the improved and collective properties of both iron borates (Fe3BO6) and magnesium borates (Mg2B2O5). At higher temperatures, the synthesized Mg2B2O5-Fe3BO6 composite is found thermally more stable than the single borates of both magnesium and iron. Similarly, the synthesized composites are found to prevent the growth of both gram-positive (Staphylococcus aureus) and gram-negative (Escherichia coli) pathogenic bacteria on all the tested concentrations. Moreover, the inhibitory effect of the synthesized composite increases with an increase in concentration and is more pronounced against S. aureus as compared to E. coli.

Original language	English
Article number	3605054
Number of pages	7
Journal	BioMed Research International
Volume	2022
DOIs	https://doi.org/10.1155/2022/3605054
State	Published - 14 Nov 2022
Externally published	Yes

Keywords

Chemical-vapor-deposition
Antibacterial
Fe3bo6
Nanoparticles
Crystallites
Nanorods
Route
Glass

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10.1155/2022/3605054

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Ahmad, P., Khandaker, M. U., Khan, A., Rehman, F., Din, S. U., Ali, H., Khan, M. I., Muhammad, N., Ahmed, N., Ullah, Z., Khan, G., Haq, S., Bin Emran, T., Sharma, R., & Ashraf, I. M. (2022). Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria. BioMed Research International, 2022, Article 3605054. https://doi.org/10.1155/2022/3605054

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title = "Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria",

abstract = "A simple process based on the dual roles of both magnesium oxide (MgO) and iron oxide (FeO) with boron (B) as precursors and catalysts has been developed for the synthesis of borate composites of magnesium and iron (Mg2B2O5-Fe3BO6) at 1200 degrees C. The as-synthesized composites can be a single material with the improved and collective properties of both iron borates (Fe3BO6) and magnesium borates (Mg2B2O5). At higher temperatures, the synthesized Mg2B2O5-Fe3BO6 composite is found thermally more stable than the single borates of both magnesium and iron. Similarly, the synthesized composites are found to prevent the growth of both gram-positive (Staphylococcus aureus) and gram-negative (Escherichia coli) pathogenic bacteria on all the tested concentrations. Moreover, the inhibitory effect of the synthesized composite increases with an increase in concentration and is more pronounced against S. aureus as compared to E. coli.",

keywords = "Chemical-vapor-deposition, Antibacterial, Fe3bo6, Nanoparticles, Crystallites, Nanorods, Route, Glass",

author = "Pervaiz Ahmad and Khandaker, \{Mayeen Uddin\} and Abdulhameed Khan and Fida Rehman and Din, \{Salah Ud\} and Hazrat Ali and Khan, \{Muhammad Imtiaz\} and Nawshad Muhammad and Nasar Ahmed and Zahoor Ullah and Ghulamullah Khan and Sirajul Haq and \{Bin Emran\}, Talha and Rohit Sharma and Ashraf, \{I. M.\}",

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Ahmad, P, Khandaker, MU, Khan, A, Rehman, F, Din, SU, Ali, H, Khan, MI, Muhammad, N, Ahmed, N, Ullah, Z, Khan, G, Haq, S, Bin Emran, T, Sharma, R & Ashraf, IM 2022, 'Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria', BioMed Research International, vol. 2022, 3605054. https://doi.org/10.1155/2022/3605054

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AU - Rehman, Fida

AU - Din, Salah Ud

AU - Ali, Hazrat

AU - Khan, Muhammad Imtiaz

AU - Muhammad, Nawshad

AU - Ahmed, Nasar

AU - Ullah, Zahoor

AU - Khan, Ghulamullah

AU - Haq, Sirajul

AU - Bin Emran, Talha

AU - Sharma, Rohit

AU - Ashraf, I. M.

PY - 2022/11/14

Y1 - 2022/11/14

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AB - A simple process based on the dual roles of both magnesium oxide (MgO) and iron oxide (FeO) with boron (B) as precursors and catalysts has been developed for the synthesis of borate composites of magnesium and iron (Mg2B2O5-Fe3BO6) at 1200 degrees C. The as-synthesized composites can be a single material with the improved and collective properties of both iron borates (Fe3BO6) and magnesium borates (Mg2B2O5). At higher temperatures, the synthesized Mg2B2O5-Fe3BO6 composite is found thermally more stable than the single borates of both magnesium and iron. Similarly, the synthesized composites are found to prevent the growth of both gram-positive (Staphylococcus aureus) and gram-negative (Escherichia coli) pathogenic bacteria on all the tested concentrations. Moreover, the inhibitory effect of the synthesized composite increases with an increase in concentration and is more pronounced against S. aureus as compared to E. coli.

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KW - Crystallites

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KW - Route

KW - Glass

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Enhanced Thermal Stability and Synergistic Effects of Magnesium and Iron Borate Composites against Pathogenic Bacteria

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Keywords

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