Delayed gate fluorescence detection of dipicolinic acid (DPA), a universal and specific component of bacterial spores, has been appraised for use in a rapid analytical method for the detection of low concentrations of bacterial spores. DPA was assayed by fluorimetric detection of its chelates with lanthanide metals. The influence of the choice and concentration of lanthanide and buffer ions on the fluorescence assay was studied as well as the effects of pH and temperature. The optimal system quantified the fluorescence of terbium monodipicolinate in a solution of 10 microM terbium chloride buffered with 1 M sodium acetate, pH 5.6 and had a detection limit of 2 nM DPA. This assay allowed the first real-time monitoring of the germination of bacterial spores by continuously quantifying exuded DPA. A detection limit of 10(4) Bacillus subtilis spores ml-1 was reached, representing a substantial improvement over previous rapid tests.
The bonding of enzymes to self-assembled monolayers (SAMs) of alkanethiols onto gold electrode surfaces is exploited to produce an enzyme biosensor. The attachment of glucose oxidase to a SAM of 3-mercaptopropionic acid was achieved using carbodiimide coupling. The resultant biosensor showed good sensitivity to glucose and a large dynamic range when measured amperometrically via the p-benzoquinone mediator. On the other hand, subsequent platinization of the enzyme-SAM electrode allowed hydrogen peroxide produced in the enzyme reaction to be detected directly, thus obviating the need for an artificial redox mediator. The performance of such sensors constructed on bulk gold electrodes was evaluated and finally compared to that of some preliminary thin-film gold electrodes. Biosensors constructed using the two alternative electrode surfaces have quite different sensitivities, thus reflecting the influence of the anchoring surface on the performance of the biosensor.
Carboxy-terminated polydiacetylene vesicles are known to undergo dramatic color transitions in response to exposure to external stimuli such as pH, temperature, and receptor-ligand binding. FTIR spectroscopy was used to identify the breakdown in the interfacial hydrogen-bonding interactions of the carboxylic acid headgroups of polymerized 10,12-tricosadiynoic acid (TRCDA) vesicles in aqueous solution during pH chromic transition. The headgroup structure was monitored as the chromic transition takes place and the dissociation dependence of the pKa was determined. Due to the attenuated acidity of the interfacially confined carboxy groups, which exhibit pKa values in the range 9.5-9.9, it was found that the deprotonation-triggered blue-red chromic transition occurred in the pH range 9.0-10.1 and that the mechanism of the transition required interaction with the surface carboxyl group, which is of importance in the design of a biochromic mechanism using PDA assemblies. Transmission electron microscopy and FTIR spectroscopy revealed that the surface ionization and the pH-induced chromogenic transition was also accompanied by a dramatic vesicle-planar morphological transition alongside subtle changes to the alkyl chain conformation and packing. A two-step mechanism was implicated as causing the chromic transition that first involves surface deprotonation and then specific cation binding, which can aid the design of sensitive surface-ligand chemistry for new PDA structures.
A laminated shell microcapsule is described resisting aggregation and withstanding ultrasound destruction, showing a good backscatter signal, as shown in the figure. Templated synthesis produces versatile monodisperse capsules <3 µm, with ultrasound‐pressure dependency allowing rupture above MI ∼ 1.5 (at 2 MHz), suitable for future development as both controlled‐delivery agent and contrast agent.
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