Abstract: The present invention relates to the use of transition metal-carbene complexes in organic light-emitting diodes (OLEDs), to a light-emitting layer, to a blocking layer for electrons or excitons, or to a blocking layer for holes, each comprising these transition metal-carbene complexes, to OLEDs comprising these transition metal-carbene complexes, to devices which comprise an inventive OLED, and to transition metal-carbene complexes.

Abstract: Methods and compositions for enriching a population of particles containing an analyte are disclosed. In one embodiment, enrichment beads are used that are larger in size than the beads used for amplification. A separation device is employed that can retain larger beads with bound amplified beads. The technique finds many uses, including enriching for beads with clonally amplified template, which can be used in a variety of assays, including nucleic acid sequencing.

Abstract: Methods and compositions for enriching a population of particles containing an analyte are disclosed. In one embodiment, enrichment beads are used that are larger in size than the beads used for amplification. A separation device is employed that can retain larger beads with bound amplified beads. The technique finds many uses, including enriching for beads with clonally amplified template, which can be used in a variety of assays, including nucleic acid sequencing.

Abstract: Methods and compositions for enriching a population of particles containing an analyte are disclosed. In one embodiment, enrichment beads are used that are larger in size than the beads used for amplification. A separation device is employed that can retain larger beads with bound amplified beads. The technique finds many uses, including enriching for beads with clonally amplified template, which can be used in a variety of assays, including nucleic acid sequencing.

Abstract: Methods and compositions for enriching a population of particles containing an analyte are disclosed. In one embodiment, enrichment beads are used that are larger in size than the beads used for amplification. A separation device is employed that can retain larger beads with bound amplified beads. The technique finds many uses, including enriching for beads with clonally amplified template, which can be used in a variety of assays, including nucleic acid sequencing.

Abstract: Methods and compositions for enriching a population of particles containing an analyte are disclosed. In one embodiment, enrichment beads are used that are larger in size than the beads used for amplification. A separation device is employed that can retain larger beads with bound amplified beads. The technique finds many uses, including enriching for beads with clonally amplified template, which can be used in a variety of assays, including nucleic acid sequencing.

Abstract: Optical bio-disc assays and synthesis of bio-active nanoparticles and nanocapsules for use therewith. Related methods for synthesis of polymeric nanoparticles for use in disc assays include forming reverse micelles having an outer non-polar shell and an inner polar cavity and solubilizing in the reverse micelles a polymerizing mixture including monomers, co-monomers, weakly polar monomers, and/or polymerizable surfactants. This may also include an initiator of polymerization. The methods also include polymerizing the mixture. The invention is also directed to the use of the nanoparticles and nanocapsules in optical bio-disc assays for the detection of analytes including nucleic acid sequences. Related optical assay discs and disc systems are also provided.

Abstract: Modified external guide sequence (EGS) molecules that mediate cleavage of specific target RNAs have been constructed. The modified molecules are external guide sequence molecules for RNAse P which are designed to specifically bind to and promote RNAse P-mediated cleavage of target RNA molecules and to have enhanced nuclease resistance. Specific regions are modified to achieve enhanced stability while maintaining RNAse P activity. Modified external guide sequence molecules suitable for use in the treatment of hepatitis B viral infections have been constructed.

Abstract: External guide sequence (EGS) molecules for eukaryotic RNAse P are engineered to target efficient and specific cleavage of target RNA. Engineered RNA molecules are designed and synthesized which contain specific nucleotide sequences which enable an external guide sequence for RNAse P to preferentially bind to and promote RNAse P-mediated cleavage of target RNA molecules. Short External Guide Sequence (SEGS) molecules have been constructed that, when hybridized to a target molecule, provide a minimal structure recognized as a substrate by RNAse P. The SEGS/target structure is comprised of a structures similar to the A stem and the T stem of a tRNA, the natural substrate of RNAse P. The SEGS makes up only half of these stem structures. The other half of the stem structures is provided by the target molecule. By allowing the target molecule to form more of the RNAse P substrate structure, the disclosed SEGS molecules can be significantly smaller than previous EGS molecules.

Abstract: Modified external guide sequence (EGS) molecules that mediate cleavage of specific target RNAs have been constructed. The modified molecules are external guide sequence molecules for RNAse P which are designed to specifically bind to and promote RNAse P-mediated cleavage of target RNA molecules and to have enhanced nuclease resistance. Specific regions are modified to achieve enhanced stability while maintaining RNAse P activity. Modified external guide sequence molecules suitable for use in the treatment of hepatitis B viral infections have been constructed.