dc.contributor.advisor |
Maity, A.
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dc.contributor.advisor |
Chetty, A.
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dc.contributor.author |
Mahlangu, Thembisile Patience
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dc.date.accessioned |
2016-02-17T12:42:25Z |
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dc.date.available |
2016-02-17T12:42:25Z |
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dc.date.issued |
2015-06 |
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dc.identifier.citation |
Mahlangu, Thembisile Patience (2015) Synthesis of smart nanomaterials for preconcentration and detection of E.coli in water, University of South Africa, Pretoria, <http://hdl.handle.net/10500/19941> |
en |
dc.identifier.uri |
http://hdl.handle.net/10500/19941 |
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dc.description.abstract |
It is common knowledge that water is one of the basic needs for human beings. However, the consumption of contaminated water can lead to waterborne diseases and fatalities. It is, therefore imperative to constantly monitor the quality of potable water. There are numerous technologies used for water quality monitoring. These technologies are relatively effective however these tests are expensive and complex to use, which then require experienced technicians to operate them. Other tests are not rapid, making consumers of water susceptible to waterborne diseases. In this study, dye-doped, surface functionalized silica nanoparticles (SiNPs) and surface-functionalized magnetic nanocomposites (MNCs) were proposed as materials that can be applied in order to reduce the time taken to get results as well as to make the processes less complex and portable.
The aim of this study was to synthesize and characterize surface functionalized dye-doped SiNPs and surface functionalized MNCs for detection and preconcentration of in water. Additionally, proof of concept had to be shown using the synthesized materials.
SiNPs were the materials of choice due to their easily functionalized surfaces and their strong optical properties. SiNPs are photostable and they do not leach in solution due to the inert nature of the silica matrix in aqueous media. MNCs were chosen as materials of choice for preconcentration of E. coli in water because they are easy to synthesize and they can be applied in various biological applications due to their functional groups. SiNPs were synthesized using the water-in-oil microemulsion. The SiNPs were further functionalized with amine and carboxyl groups and avidin. Thereafter, they were bioconjugated with biotinylated anti-E. coli antibodies. The pure and surface functionalized SiNPs were characterized using ATR-FTIR spectroscopy, FE-SEM, HR-TEM, Zeta Sizer, UV-vis spectroscopy and spectrofluorometry. The application of the dye—doped surface functionalized SiNPs in E. coli detection was characterized using the fluorescence plate reader. The SiNPs were spherical and uniform in size. They increased in size as they were being functionalized, ranging from 21.20 nm to 75.06 nm. The SiNPs were successfully functionalized with amine and carboxyl groups as well as with avidin and antibodies. Two methods were investigated for carboxyl group attachment (direct and indirect attachment) and the direct attachment method yielded the best results with a surface charge of -31.9 mV compared to -23.3 mV of the indirect method. The dye loading was found to be 1% after particle synthesis. The optical properties of the Ru(Bpy) dye were enhanced 3 fold when they were encapsulated in the Si matrix. The SiNPs were binding to the E. coli cells and enabled detection.
MNCs were synthesized through in-situ polymerization. The MNCs were characterized using ATR-FTIR spectroscopy, SEM, TEM and XRD. The MNCs were successfully functionalized with carboxyl groups. The increase in size of the nanocomposites as seen in SEM images proved that the Fe3O4 was successfully encapsulated in the polymer matrix. The MNCs were proven to be magnetic by a simple magnetism test whereby they were separated in an aqueous solution using an external magnetic field. The antibody-labelled MNCs were binding to the E. coli cells as shown in TEM images. E. coli cells were removed from water at varying concentrations of 1x106 CFU/mL to 1x109 CFU/mL at 10 mL volumes.
This study has demonstrated that dye-doped SiNPs amplify the signal of E. coli cells using fluorescence. The study has also demonstrated that the MNCs can be applied in sample preconcentration and enrichment for E. coli detection. However, further studies should investigate and optimize the combination of the two techniques in a point of use device for water quality testing of 100 mL-samples as per the requirement of the SANS 241 standard. |
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dc.format.extent |
1 online resource (xv, 111 leaves) : illustrations (chiefly color) |
en |
dc.language.iso |
en |
en |
dc.subject.ddc |
628.161 |
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dc.subject.lcsh |
Drinking water -- Contamination -- Testing |
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dc.subject.lcsh |
Escherichia coli -- Detection |
en |
dc.subject.lcsh |
Nanocomposites (Materials) -- Synthesis |
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dc.subject.lcsh |
Smart materials |
en |
dc.subject.lcsh |
Water quality -- Measurement |
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dc.title |
Synthesis of smart nanomaterials for preconcentration and detection of E.coli in water |
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dc.type |
Dissertation |
en |
dc.description.department |
Civil and Chemical Engineering |
en |
dc.description.degree |
M. Tech. (Chemical Engineering) |
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