Gold Nanoparticles For Biomolecular Assays

The amalgamation of nanotechnology and biology has led to the development ofnew types of hybrid materials that are expected to produce major advances in areas such as materials science, therapeutics and diagnostics. One of the most promising developments is the use ofnanoparticles (NPs) as labels for the detection of analytes in biological assays. The aim of this research project was to prepare gold nanoparticle (GNP) labels for use in such assays. In chapter 1, the optical properties and the use of GNPs in homogeneous and heterogeneous colorimetric assays are reviewed. In chapter 2 a simple conjugation method is introduced that not only allows almost any biological molecule or hapten to be attached to GNPs but also allows the user to control or vary the mean number of molecules per particle. In this method a high molecular weight aminodextran polymer is functionalized with the molecule of choice and chemical attachment groups that are used to covalently anchor the polymer to the GNPs. This method was used to conjugate biotin and 1125 functionalized dextrans to GNPs. These functionalized dextrans were then used to investigate the conjugation procedure in more_detail. Results from GNP titrations and microbead assays demonstrate that the minimum amount of functionalized dextran required to prevent salt-induced flocculation ofthe GNPs (equivalence point) is the amount required to coat all of the GNPs and at this point there is no free functionalized dextran in solution. In chapter 3 the described method was used to conjugate different numbers DNP haptens to GNPs and then these labels were used in non-traditional reagent-limited lateral flow immunoassays. The number of molecules per GNP is varied by simply adjusting the stoichiometry of reagents in the dextran functionalization reaction. Controlling the number of molecules per particle can have important consequences on the sensitivity of a biological assay. Results showed that when the number of DNP molecules per particle decreased, there was an increase in the sensitivity of the assay. Furthermore when the results from these immunoassays were compared to those obtained from traditional reagent-limited lateral flow immunoassays, the nontraditional format proved to be over 50 % more sensitive. In chapter 4 the conjugation method was used to attach oligonucleotides to GNPs for use in a nucleic acids lateral flow (NALF) device. Although NALF devices are available commercially, detection is usually achieved with the use of antibodies or haptens which can be both problematic and expensive. In addition, many of these devices have issues with sensitivity and are often interfaced with complicated target amplification / purification protocols. In chapter 4 an antibody / hapten independent NALF device is described that can be used to detect the un-purified products from a simple polymerase chain reaction (PCR) amplification protocol. Using the developed NALF device it was possible to detect specific amplification products corresponding to ~1 attomole oftemplate molecules with the unaided eye

Gold Nanoparticles For Biomolecular Assays

The amalgamation of nanotechnology and biology has led to the development ofnew types of hybrid materials that are expected to produce major advances in areas such as materials science, therapeutics and diagnostics. One of the most promising developments is the use ofnanoparticles (NPs) as labels for the detection of analytes in biological assays. The aim of this research project was to prepare gold nanoparticle (GNP) labels for use in such assays. In chapter 1, the optical properties and the use of GNPs in homogeneous and heterogeneous colorimetric assays are reviewed. In chapter 2 a simple conjugation method is introduced that not only allows almost any biological molecule or hapten to be attached to GNPs but also allows the user to control or vary the mean number of molecules per particle. In this method a high molecular weight aminodextran polymer is functionalized with the molecule of choice and chemical attachment groups that are used to covalently anchor the polymer to the GNPs. This method was used to conjugate biotin and 1125 functionalized dextrans to GNPs. These functionalized dextrans were then used to investigate the conjugation procedure in more_detail. Results from GNP titrations and microbead assays demonstrate that the minimum amount of functionalized dextran required to prevent salt-induced flocculation ofthe GNPs (equivalence point) is the amount required to coat all of the GNPs and at this point there is no free functionalized dextran in solution. In chapter 3 the described method was used to conjugate different numbers DNP haptens to GNPs and then these labels were used in non-traditional reagent-limited lateral flow immunoassays. The number of molecules per GNP is varied by simply adjusting the stoichiometry of reagents in the dextran functionalization reaction. Controlling the number of molecules per particle can have important consequences on the sensitivity of a biological assay. Results showed that when the number of DNP molecules per particle decreased, there was an increase in the sensitivity of the assay. Furthermore when the results from these immunoassays were compared to those obtained from traditional reagent-limited lateral flow immunoassays, the nontraditional format proved to be over 50 % more sensitive. In chapter 4 the conjugation method was used to attach oligonucleotides to GNPs for use in a nucleic acids lateral flow (NALF) device. Although NALF devices are available commercially, detection is usually achieved with the use of antibodies or haptens which can be both problematic and expensive. In addition, many of these devices have issues with sensitivity and are often interfaced with complicated target amplification / purification protocols. In chapter 4 an antibody / hapten independent NALF device is described that can be used to detect the un-purified products from a simple polymerase chain reaction (PCR) amplification protocol. Using the developed NALF device it was possible to detect specific amplification products corresponding to ~1 attomole oftemplate molecules with the unaided eye.EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Gold Nanoparticles For Biomolecular Assays

The amalgamation of nanotechnology and biology has led to the development ofnew types of hybrid materials that are expected to produce major advances in areas such as materials science, therapeutics and diagnostics. One of the most promising developments is the use ofnanoparticles (NPs) as labels for the detection of analytes in biological assays. The aim of this research project was to prepare gold nanoparticle (GNP) labels for use in such assays. In chapter 1, the optical properties and the use of GNPs in homogeneous and heterogeneous colorimetric assays are reviewed. In chapter 2 a simple conjugation method is introduced that not only allows almost any biological molecule or hapten to be attached to GNPs but also allows the user to control or vary the mean number of molecules per particle. In this method a high molecular weight aminodextran polymer is functionalized with the molecule of choice and chemical attachment groups that are used to covalently anchor the polymer to the GNPs. This method was used to conjugate biotin and 1125 functionalized dextrans to GNPs. These functionalized dextrans were then used to investigate the conjugation procedure in more_detail. Results from GNP titrations and microbead assays demonstrate that the minimum amount of functionalized dextran required to prevent salt-induced flocculation ofthe GNPs (equivalence point) is the amount required to coat all of the GNPs and at this point there is no free functionalized dextran in solution. In chapter 3 the described method was used to conjugate different numbers DNP haptens to GNPs and then these labels were used in non-traditional reagent-limited lateral flow immunoassays. The number of molecules per GNP is varied by simply adjusting the stoichiometry of reagents in the dextran functionalization reaction. Controlling the number of molecules per particle can have important consequences on the sensitivity of a biological assay. Results showed that when the number of DNP molecules per particle decreased, there was an increase in the sensitivity of the assay. Furthermore when the results from these immunoassays were compared to those obtained from traditional reagent-limited lateral flow immunoassays, the nontraditional format proved to be over 50 % more sensitive. In chapter 4 the conjugation method was used to attach oligonucleotides to GNPs for use in a nucleic acids lateral flow (NALF) device. Although NALF devices are available commercially, detection is usually achieved with the use of antibodies or haptens which can be both problematic and expensive. In addition, many of these devices have issues with sensitivity and are often interfaced with complicated target amplification / purification protocols. In chapter 4 an antibody / hapten independent NALF device is described that can be used to detect the un-purified products from a simple polymerase chain reaction (PCR) amplification protocol. Using the developed NALF device it was possible to detect specific amplification products corresponding to ~1 attomole oftemplate molecules with the unaided eye.EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Antimicrobial nitric oxide releasing contact lens gels for the treatment of microbial keratitis.

Microbial keratitis is a serious sight threatening infection affecting approximately two million individuals worldwide annually. Whilst antibiotic eye drops remain the gold standard treatment for these infections, the significant problems associated with eye drop drug delivery and the alarming rise in antimicrobial resistance has meant that there is an urgent need to develop alternative treatments. In this work, a nitric oxide releasing contact lens gel displaying broad spectrum antimicrobial activity against two of the most common causative pathogens of bacterial keratitis is described. The contact lens gel is comprised of poly-ɛ-lysine (pɛK) functionalised with nitric oxide (NO) releasing diazeniumdiolate moieties which enables the controlled and sustained release of bactericidal concentrations of NO at physiological pH over a period of 15 hrs. Diazeniumdiolate functionalisation was confirmed by Fourier transform infrared (FTIR) and UV Vis spectroscopy and the concentration of NO released from the gels was determined by chemiluminescence. The bactericidal efficacy of the gels against Pseudomonas aeruginosa and Staphylococcus aureus was ascertained and between 1 and 4 log reductions in bacterial populations were observed over 24 hrs. Additional cell cytotoxicity studies with human corneal epithelial cells (HCE-T) also demonstrated that the contact lens gels were not cytotoxic suggesting that the developed technology could be a viable alternative treatment for bacterial keratitis