Abstract: The present invention provides silica shell encapsulated polyaromatic-core microparticles and methods for producing and using the same. In particular, the silica shell encapsulated polyaromatic-core microparticles of the invention are hydrophilic microparticle scintillators comprising (i) polyaromatic-core microparticle (1), wherein said polyaromatic-core microparticle (1) is doped with a scintillator material (2); and (ii) a silica-shell portion (3) encapsulating said polyaromatic-core microparticle (1), wherein said silica-shell portion (3) comprises an outer surface (4). The polyaromatic-core portion is formed from an aromatic vinyl compound selected from the group consisting of styrene, vinyl toluene, and a mixture thereof.

Abstract: The present invention provides compositions and methods for determining a saccharide level in a sample. In particular, compositions and methods of the invention include a boronic acid moiety that forms a complex with a saccharide.

Abstract: The present invention provides a process for producing a nanocomposite particle (“nanoSCINT particle”) adapted for use in scintillating proximity assay in a relatively high quantity. The nanoSCINT particle comprises a silica shell that encapsulates a nanoparticle organic polymer that is doped with at least one scintillating compound. In particular, the process of the invention includes adding a plurality of batch-wise portions of a polymerization initiator to an emulsion comprising a relatively high amount of polymerizable organic compound to produce a nanoparticle organic polymer, which is then doped with at least one scintillating compound, and then encapsulated with a silica shell to produce nanoSCINT particles in gram quantities in a single process. Unlike conventional methods, a single process of the invention provides at least about 5 g, typically at least about 7.5 g, and often at least about 10 g of nanocomposite particles.

Abstract: Surface-modified glass and polymer membrane interfaces form high-electrical resistance seals that can be used in microfluidic valves and array devices tailored for electrophysiological measurements. The incorporation of high seal resistance valves into the array device allows only the desired electrophysiological signal to be detected by a patch clamp amplifier, enabling parallel experiments with one patch clamp amplifier, which can greatly improve the cost efficiency. To achieve the desired high seal resistance, surface modification was performed on the glass components to increase the interaction between the glass and the membrane surfaces. The valves exhibit seal resistance of >500 G? after modification, which is 100× higher than reported for unmodified valves.

Abstract: Scintillant-doped polystyrene core nanoparticles surrounded by a silica shell can be used to quantify low-energy radionuclides. The nanoparticles are recoverable and re-useable, which may reduce waste and allow for sample recovery. Unlike traditional liquid scintillation cocktail (LSC) formulations, the nanoparticles are made from non-toxic and non-volatile components, and can be used without the aid of surfactants, making them a possible alternative to LSC for reducing the environmental impact of studies that employ radioactive tracers. Recognition elements attached to the functionalized silica surfaces of the nanoparticles allow for separation-free scintillation proximity assay (SPA) applications in aqueous samples. Lipid membrane coatings deposited on the nanoparticle surface can significantly reduce the non-specific adsorption of proteins and other biomolecules, and allow for the incorporation of membrane proteins or other membrane associated binding molecules.

Abstract: Surface-modified silica microparticles that are functionalized with stabilized phospholipid vesicles are described herein. These stabilized vesicles can be functionalized with either transmembrane receptors or membrane associated receptors and used for affinity pull-down assays or other chromatographic separation modalities to provide affinity capture/concentration of low abundance ligands in complex mixtures with minimal sample preparation. Further described are methods and apparatus for forming polymer frits in a fused silica capillary. The capillary containing a monomer solution is placed between one or more heat sources connected to each other via a jig and operatively coupled to a temperature controller. The polymer frits are synthesized via thermal polymerization of the monomer solution using the heat sources, which allows for placement of the polymer frits at a spatially-defined location in the capillary.

Abstract: Direct polymerization of lipid monomers or polymer scaffolding of non-lipid monomers coupled with irradiation or redox polymerization performed at neutral pH resulted in stabilized lipid assemblies. An initiator-buffer component and NaHS03 redox mixture polymerizes reactive lipid monomers at near neutral pH conditions to preserve functionality of reconstituted membrane proteins. Improved stability of black lipid membranes (BLMs) is attained by chemical cross-linking of polymerizable, hydrophobic and commercially available non-lipid monomers partitioned into the suspended lipid membranes, and by suspending the BLMs across low surface energy apertures. Substrate apertures having low surface energy modifiers with amphiphobic properties facilitated a reproducible formation of BLMs by promoting interactions between the lipid tail and the substrate material.

Abstract: Microarray platforms and methods of fabricating said microarrays without traditional high aspect ratio barriers used to define individual array elements are described herein. Self-assembled nanoshells were stabilized with a polymerized scaffold to enhance the stability in physiological conditions and serve as an optical transducer upon molecular recognition events. Soft photolithography combined with surface chemistry was developed for covalent immobilization of nanoshells onto the pre-patterned arrayed microspots for rapid multiplexed detection of membrane-binding analytes. This robust fabrication methodology is amenable for general lipid structures, and thus facilitates the integration of stable membrane architectures into diagnostic and prognostic platforms. In particular, the microarray platform may be used in diverse applications ranging from the detection of pathogens, such bacterial toxin in biological matrices, to cellular membrane studies.

Abstract: Surface-modified glass and polymer membrane interfaces form high-electrical resistance seals that can be used in microfluidic valves and array devices tailored for electrophysiological measurements. The incorporation of high seal resistance valves into the array device allows only the desired electrophysiological signal to be detected by a patch clamp amplifier, enabling parallel experiments with one patch clamp amplifier, which can greatly improve the cost efficiency. To achieve the desired high seal resistance, surface modification was performed on the glass components to increase the interaction between the glass and the membrane surfaces. The valves exhibit seal resistance of >500G? after modification, which is 100× higher than reported for unmodified valves.

Abstract: Surface-modified silica microparticles that are functionalized with stabilized phospholipid vesicles are described herein. These stabilized vesicles can be functionalized with either transmembrane receptors or membrane associated receptors and used for affinity pull-down assays or other chromatographic separation modalities to provide affinity capture/concentration of low abundance ligands in complex mixtures with minimal sample preparation. Further described are methods and apparatus for forming polymer frits in a fused silica capillary. The capillary containing a monomer solution is placed between one or more heat sources connected to each other via a jig and operatively coupled to a temperature controller. The polymer frits are synthesized via thermal polymerization of the monomer solution using the heat sources, which allows for placement of the polymer frits at a spatially-defined location in the capillary.

Abstract: Scintillant-doped polystyrene core nanoparticles surrounded by a silica shell can be used to quantify low-energy radionuclides. The nanoparticles are recoverable and re-useable, which may reduce waste and allow for sample recovery. Unlike traditional liquid scintillation cocktail (LSC) formulations, the nanoparticles are made from non-toxic and non-volatile components, and can be used without the aid of surfactants, making them a possible alternative to LSC for reducing the environmental impact of studies that employ radioactive tracers. Recognition elements attached to the functionalized silica surfaces of the nanoparticles allow for separation-free scintillation proximity assay (SPA) applications in aqueous samples. Lipid membrane coatings deposited on the nanoparticle surface can significantly reduce the non-specific adsorption of proteins and other biomolecules, and allow for the incorporation of membrane proteins or other membrane associated binding molecules.

Abstract: Direct polymerization of lipid monomers or polymer scaffolding of non-lipid monomers coupled with irradiation or redox polymerization performed at neutral pH resulted in stabilized lipid assemblies. An initiator-buffer component and NaHS03 redox mixture polymerizes reactive lipid monomers at near neutral pH conditions to preserve functionality of reconstituted membrane proteins. Improved stability of black lipid membranes (BLMs) is attained by chemical cross-linking of polymerizable, hydrophobic and commercially available non-lipid monomers partitioned into the suspended lipid membranes, and by suspending the BLMs across low surface energy apertures. Substrate apertures having low surface energy modifiers with amphiphobic properties facilitated a reproducible formation of BLMs by promoting interactions between the lipid tail and the substrate material.