A large-scale study of microplastic abundance in sediment cores from the UK continental shelf and slope.

To inform risk assessments, reliable, time efficient and affordable quantification methods are required for creating a microplastic (MP) pollution baseline in the world's oceans. To facilitate this, MP abundance was investigated in sediments of three contrasting areas of the UK continental shelf: North West of Jones Bank, the Canyons in the Celtic Sea and Dogger Bank in the North Sea, utilising the Nile Red tagging method to assess its time efficiency and cost. Average MP abundance in the top 10 cm was 1050-2700 MP kg-1. MP abundance decreased with increasing sediment depth and increased with increasing water depth. The findings emphasise the extent of MP pollution and illustrate the value of Nile Red for large scale mapping at relatively low cost.

The in situ synthesis of PbS nanocrystals from lead(II) n-octylxanthate within a 1,3-diisopropenylbenzene-bisphenol A dimethacrylate sulfur copolymer.

The synthesis of lead sulfide nanocrystals within a solution processable sulfur 'inverse vulcanization' polymer thin film matrix was achieved from the in situ thermal decomposition of lead(II) n-octylxanthate, [Pb(S2COOct)2]. The growth of nanocrystals within polymer thin films from single-source precursors offers a faster route to networks of nanocrystals within polymers when compared with ex situ routes. The 'inverse vulcanization' sulfur polymer described herein contains a hybrid linker system which demonstrates high solubility in organic solvents, allowing solution processing of the sulfur-based polymer, ideal for the formation of thin films. The process of nanocrystal synthesis within sulfur films was optimized by observing nanocrystal formation by X-ray photoelectron spectroscopy and X-ray diffraction. Examination of the film morphology by scanning electron microscopy showed that beyond a certain precursor concentration the nanocrystals formed were not only within the film but also on the surface suggesting a loading limit within the polymer. We envisage this material could be used as the basis of a new generation of materials where solution processed sulfur polymers act as an alternative to traditional polymers.

Synthetic strategies for the generation of molecularly imprinted organic polymers.

Molecular imprinting is a method of inducing molecular recognition properties in synthetic polymers in response to the presence of a template species during formation of the three-dimensional structure of the polymer. The molecularly imprinted polymers (MIPs) prepared in this way have been termed "plastic antibodies" and combine the robustness of the polymer scaffold with binding properties more readily associated with biological receptors. Smart polymers of this type may find applications in drug delivery, controlled release and monitoring of drug and metabolite concentrations. In this review the main synthetic strategies used in the preparation of imprinted organic polymers are described in terms of the chemical principles used in the templating step. These are illustrated with examples taken from the literature and are classified as covalent, semi-covalent, non-covalent, metal-mediated and non-polar. Finally strategies for the selection of monomers, optimisation and modification of the properties of imprinted polymers are reviewed.

Molecularly imprinted polymer beads: suspension polymerization using a liquid perfluorocarbon as the dispersing phase.

A suspension polymerization technique suitable for molecular imprinting is described, based on the use of a liquid perfluorocarbon as the dispersing phase. This dispersant does not interfere with the interactions between functional monomers and print molecules required for the recognition process during molecular imprinting. The method produces polymer beads, with almost quantitative yield, which can be used after only a simple washing step. An acrylate polymer with perfluorocarbon and poly(oxyethylene) ester groups was used to stabilize an emulsion of functional monomer, cross-linker, print molecule, initiator, and porogenic solvent in perfluoro(methylcyclohexane). Initiation of polymerization by UV irradiation resulted in polymer beads. The average bead size could be controlled between about 50 and 5 µm by varying the amount of stabilizing polymer. SEM of the beads indicated spherical particles with morphology typical of beads made by suspension polymerization. The technique was applicable to a range of conditions typically used for molecular imprinting. A detailed chromatographic study of the polymer beads confirmed that α values and resolution factors were similar to those achieved with traditional ground and sieved imprinted polymers. Small (5 µm) beaded packings gave low back pressure and rapid diffusion, giving good separation even at high flow rates.

Sugar binding polymers showing high anomeric and epimeric discrimination obtained by noncovalent molecular imprinting.

Noncovalent molecular imprinting of sugar compounds in ethylene glycol dimethacrylate-methacrylic acid copolymers yielded materials containing highly selective sugar binding sites. Investigation of a range of polymers demonstrated that the resulting polymer imprints have a high degree of both anomeric and epimeric selectivity favoring the original print molecule. In HPLC assays, a polymer imprinted using p-nitrophenyl-alpha-D-galactoside could separate the alpha and beta anomers of the same compound with near baseline resolution. A polymer imprinted using p-nitrophenyl-beta-D-galactoside showed similar results but with the beta anomers retained longer as expected. Anomeric discrimination of closely related sugars was also possible, with the degree of separation depending on the structural resemblance to the print molecule. Similarly, a polymer imprinted with p-nitrophenyl-alpha-L-fucoside could separate alpha/beta mixtures of p-nitrophenyl-L-fucoside with baseline resolution. Using radioligand displacement assays a polymer imprinted using octyl-alpha-D-glucoside was shown to bind methyl-alpha-D-glucoside with a 40-fold higher affinity than that for the beta-anomer. The epimeric selectivity was even more impressive: methyl-alpha-D-mannoside and methyl-alpha-D-galactoside had 130- and 240-fold lower affinity, respectively, than methyl-alpha-D-glucoside. The results are discussed in relation to possible uses of such polymers in separation and analysis.

Binding isotherms for soluble immobilized affinity ligands from spectral titration.

The method of spectral titration has been applied to binding equilibria between proteins and soluble immobilized ligands and evaluated using the interaction between Cibacron blue-dextran conjugates and lysozyme. The method is both simple and rapid and provides a convenient screening technique for characterization of soluble adsorbents designed for use in aqueous two-phase affinity extraction or as liquid-phase models for affinity chromatography systems. The results indicate that regardless of ligand density a constant 28% of the total coupled dye is available for high-affinity protein binding at saturation. The dissociation constant for the dye-protein interaction, however, decreases with dye loading. The potential for kinetic investigations has been demonstrated using a stopped-flow apparatus. The results indicate that a simple rate equation is inadequate to describe the data for lysozyme binding to dye-dextran conjugates. A modified model, which better describes the data, was developed by including a second rate limiting process, the transition from stacked to unstacked dye ligands on the dextran backbone. This effect could have practical significance for protein binding kinetics in affinity chromatography, especially in high-performance liquid affinity chromatography applications where mass transfer is rapid.

A holographic sensor based on a rationally designed synthetic polymer.

A new silver halide-containing holographic recording material has been designed and developed specifically for holographic chemical sensors. The hologram enables very small volume changes to be measured in a polymer layer throughout which the hologram is located. The holographic film is based on a fine-grain silver bromide emulsion suspended in a poly(vinyl alcohol) matrix crosslinked with Cr(III) ions. Cross-linking gives the material sufficient spatial integrity to allow a holographic image to be recorded, while maintaining adequate porosity and elasticity of the polymer matrix for sensing applications. The new material has been characterized with respect to its response to pH and compared with a traditional gelatin holographic film. The response to some ions and small molecules typically found in analytical samples has also been measured. Functional groups introduced covalently into the poly(vinyl alcohol) matrix transform the base matrix into a pH-responsive polymer with predictable swelling properties and which can be further derivatized to incorporate specific ligands. A rationally designed holographic sensor for trypsin has been developed from chemically synthesized artificial polymers. A trypsin substrate, the poly(amino acid) poly(L-lysine), was incorporated into poly(vinyl alcohol) holograms to create a 'designed' holographic material which was degraded in a concentration-dependent manner by trypsin. Extensions of this approach to other hydrolytic enzymes are briefly discussed.

Holographic sensor for water in solvents.

The diffraction color of a gelatin holographic diffraction grating changed as a function of the water activity when immersed in a "wet" hydrophobic liquid. Quantification of the absorption maximum of the diffracted light showed that it was related, after calibration, to either the water content or the water activity of the solvent. The holographic diffraction grating measured water contents of hydrocarbon solvents at sensitivities comparable to that of the Karl Fischer coulometric titrator and over a wide range of water contents. A grating immersed in xylene revealed a visible color change when the water content was increased from 47 to 120 ppm. Conversely, the holographic grating responded to ethanol in water in the range 0-1% (w/w). The inexpensiveness and simplicity of silver halide holographic reflection gratings, combined with their relatively high sensitivity, suggests that these devices might find widespread application as immersible water activity sensors for hydrophobic liquids.

Investigation of binding site density: effects on the interaction between cibacron blue-dextran conjugates and lysozyme.

Cibacron-blue-dextran conjugates have been produced with a range of ligand loadings using a dextran preparation of average molecular weight of 2 x 10(6). The equilibrium binding capacity of these ligand conjugates for lysozyme was determined using a gel permeation procedure to separate bound from free protein. The results obtained give clear evidence for at least two types of binding showing a marked difference in affinity. For the higher-affinity interaction the half-saturation constant decreases with increasing ligand loading. The number of dye molecules participating in binding is proportional to loading up to 154 mol dye/mol dextran but is reduced at the highest loading used (315 mol dye/mol dextran). This may be due to steric interference or to dye stacking reducing the number of dye molecules available for binding.