Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds

This research aimed to prepare, characterise and study the effectiveness of twomagnetic graphene oxide-based nanocomposites, namely gellan gum-grapheneoxide (GG-GO-Fe3O4) and pectin-graphene oxide (PEC-GO-Fe3O4) a...

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Main Author:	Wong, Susana Siew Tin
Format:	thesis
Language:	eng
Published:	2022
Subjects:	QD Chemistry
Online Access:	https://ir.upsi.edu.my/detailsg.php?det=8818
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record_format	uketd_dc
institution	Universiti Pendidikan Sultan Idris
collection	UPSI Digital Repository
language	eng
topic	QD Chemistry
spellingShingle	QD Chemistry Wong, Susana Siew Tin Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
description	<p>This research aimed to prepare, characterise and study the effectiveness of two</p><p>magnetic graphene oxide-based nanocomposites, namely gellan gum-graphene</p><p>oxide (GG-GO-Fe3O4) and pectin-graphene oxide (PEC-GO-Fe3O4) as</p><p>nanocarriers for permethrin and cinnamaldehyde insecticide compounds. This</p><p>research is divided into three parts, namely preparation, characterisation and</p><p>effectiveness studies. Nanocomposites with amorphous structure were</p><p>successfully produced based on the existence of conjugation mechanism between</p><p>GG and PEC with iron oxide at wavenumber peak 650 cm-1. Results from</p><p>thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC)</p><p>have shown that the nanocomposites loaded with insecticides are thermally stable.</p><p>Performance study of nanocomposites loaded with insecticides towards Aedes</p><p>aegypti larvae was analysed through Abbotts and Probits formula via in vitro at</p><p>different pH using ultraviolet-visible (UV-Vis) spectrometer. The encapsulation</p><p>of insecticide to nanocarriers was successfully carried out based on the change in</p><p>intensity and wavenumber of absorption bands from Fourier Transform Infrared</p><p>Spectrometer (FTIR) analysis and size increment of nanocarriers in the range of</p><p>18.2 to 70.1%. The formulated nanocarriers have successfully prolonged the</p><p>release duration of permethrin and cinnamaldehyde by 15 and 24 hours,</p><p>respectively. The release profiles of insecticide compounds were best fitted by</p><p>Korsemeyer-Peppas kinetic model. Formulation of GG-GO-Fe3O4 nanocarrier</p><p>loaded with cinnamaldehyde was found as the most effective formulation to</p><p>control A. aegypti larvae. In conclusion, both nanocarriers studied have shown</p><p>outstanding performance in loading and releasing permethrin and cinnamaldehyde</p><p>in larvicide formulations. In implication, the application of both environmental</p><p>friendly nanocarriers in larvicide formulations could reduce mosquito borne</p><p>diseases and sustain the environment.</p>
format	thesis
qualification_name
qualification_level	Master's degree
author	Wong, Susana Siew Tin
author_facet	Wong, Susana Siew Tin
author_sort	Wong, Susana Siew Tin
title	Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
title_short	Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
title_full	Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
title_fullStr	Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
title_full_unstemmed	Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds
title_sort	preparation, characterisation and effectiveness of nanocomposites based on go-fe3o4 as nanocarriers for insecticide compounds
granting_institution	Universiti Pendidikan Sultan Idris
granting_department	Fakulti Sains dan Matematik
publishDate	2022
url	https://ir.upsi.edu.my/detailsg.php?det=8818
_version_	1776104568380194816
spelling	oai:ir.upsi.edu.my:88182023-03-29 Preparation, characterisation and effectiveness of nanocomposites based on Go-Fe3O4 as nanocarriers for insecticide compounds 2022 Wong, Susana Siew Tin QD Chemistry <p>This research aimed to prepare, characterise and study the effectiveness of two</p><p>magnetic graphene oxide-based nanocomposites, namely gellan gum-graphene</p><p>oxide (GG-GO-Fe3O4) and pectin-graphene oxide (PEC-GO-Fe3O4) as</p><p>nanocarriers for permethrin and cinnamaldehyde insecticide compounds. This</p><p>research is divided into three parts, namely preparation, characterisation and</p><p>effectiveness studies. Nanocomposites with amorphous structure were</p><p>successfully produced based on the existence of conjugation mechanism between</p><p>GG and PEC with iron oxide at wavenumber peak 650 cm-1. Results from</p><p>thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC)</p><p>have shown that the nanocomposites loaded with insecticides are thermally stable.</p><p>Performance study of nanocomposites loaded with insecticides towards Aedes</p><p>aegypti larvae was analysed through Abbotts and Probits formula via in vitro at</p><p>different pH using ultraviolet-visible (UV-Vis) spectrometer. The encapsulation</p><p>of insecticide to nanocarriers was successfully carried out based on the change in</p><p>intensity and wavenumber of absorption bands from Fourier Transform Infrared</p><p>Spectrometer (FTIR) analysis and size increment of nanocarriers in the range of</p><p>18.2 to 70.1%. The formulated nanocarriers have successfully prolonged the</p><p>release duration of permethrin and cinnamaldehyde by 15 and 24 hours,</p><p>respectively. The release profiles of insecticide compounds were best fitted by</p><p>Korsemeyer-Peppas kinetic model. Formulation of GG-GO-Fe3O4 nanocarrier</p><p>loaded with cinnamaldehyde was found as the most effective formulation to</p><p>control A. aegypti larvae. In conclusion, both nanocarriers studied have shown</p><p>outstanding performance in loading and releasing permethrin and cinnamaldehyde</p><p>in larvicide formulations. In implication, the application of both environmental</p><p>friendly nanocarriers in larvicide formulations could reduce mosquito borne</p><p>diseases and sustain the environment.</p> 2022 thesis https://ir.upsi.edu.my/detailsg.php?det=8818 https://ir.upsi.edu.my/detailsg.php?det=8818 text eng closedAccess Masters Universiti Pendidikan Sultan Idris Fakulti Sains dan Matematik <p>AbellaMedrano, C. A., Roiz, D., Islas, C. G. R., SalazarJurez, C. L., & OjedaFlores,</p><p>R. (2020). Assemblage variation of mosquitoes (Diptera: Culicidae) in different</p><p>land use and activity periods within a lowland tropical forest matrix in</p><p>Campeche, Mexico. 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