Abstract: The invention concerns a particle having a code from a library of codes embedded in its physical structure by refractive index changes between different regions of the particle. In preferred embodiments, a thin film possesses porosity that varies in a manner to produce a code detectable in the reflectivity spectrum. An assay detection method uses such a particle and detects a spectral shift in the presence of an analyte. Additional embodiments are disclosed including additional features.

Abstract: A graphene nanomesh based charge sensor and method for producing a graphene nanomesh based charge sensor. The method includes generating multiple holes in graphene in a periodic way to create a graphene nanomesh with a patterned array of multiple holes, passivating an edge of each of the multiple holes of the graphene nanomesh to allow for functionalization of the graphene nanomesh, and functionalizing the passivated edge of each of the multiple holes of the graphene nanomesh with a chemical compound that facilitates chemical binding of a receptor of a target molecule to the edge of one or more of the multiple holes, allowing the target molecule to bind to the receptor, causing a charge to be transferred to the graphene nanomesh to produce a graphene nanomesh based charge sensor for the target molecule.

Abstract: Aspects of the present invention are drawn to methods and compositions for the genetic analysis of regions of interest (ROI) from one or more starting polynucleotide sample(s). In certain aspects, adapter tagged polynucleotide fragments from a plurality of initial polynucleotide samples are pooled, circularized and amplified to produce an immortalized library. Multiple ROI's from this immortalized library are amplified (e.g., in independent iPCR reactions) to generate amplicons, and, in some embodiments, pooled to form a pooled ROI amplicon sample. In certain embodiments, the amplicons for each ROI amplicon in the pooled ROI amplicon sample are present at known molar or mass ratios. The pooled ROI amplicon sample can be analyzed/processed as desired, e.g., sequenced using next generation sequencing technology.

Abstract: This invention relates to a kit and a method for the collection and analysis of complex protein mixtures. More particularly, the invention relates to a kit comprising a single barrel filtration well or a multi-well filtration plate wherein each well comprises an upper filtration zone; a lower filtration zone; a conical flow director zone; and, an elution tip, wherein the upper filtration zone and the lower filtration zone are separated by a retainer ring disposed within the lower filtration zone. The upper filtration zone comprises an upper collection zone, a sponge zone, and a deep bed filtration zone; and, the lower filtration zone comprises the retainer ring, a supported hydrophilic membrane and a lower bed filtration media. When used with an array of selected buffer solutions, the multi-well filtration plate can provide accurate, automated, high-throughput protein analysis by affinity chromatography.

Abstract: The invention provides a method of printing, onto a substrate (12), an array (14) of spots of reagent compositions for use in a chemical and/or biochemical analysis. The method includes displacing an array of reagent composition containing capillary tubes (22) arranged alongside one another from an inoperative position to an operative position in which open ends of the capillary tubes (22) simultaneously impinge against a substrate and thereafter displacing the array of tubes (22) from the operative position back to the inoperative position. The invention extends to a printing apparatus (10), a method of printing a layered array of spots of reagent compositions, a method of introducing reagent compositions into the tubes, a reagent introducing device for introducing reagent compositions into the tubes and a printing installation which includes the printing apparatus (10) and the reagent introducing device.

Abstract: The invention provides a method of printing, onto a substrate (12), an array (14) of spots of reagent compositions for use in a chemical and/or biochemical analysis. The method includes displacing an array of reagent composition containing capillary tubes (22) arranged alongside one another from an inoperative position to an operative position in which open ends of the capillary tubes (22) simultaneously impinge against a substrate and thereafter displacing the array of tubes (22) from the operative position back to the inoperative position. The invention extends to a printing apparatus (10), a method of printing a layered array of spots of reagent compositions, a method of introducing reagent compositions into the tubes, a reagent introducing device for introducing reagent compositions into the tubes and a printing installation which includes the printing apparatus (10) and the reagent introducing device.

Abstract: The invention provides a method of printing, onto a substrate (12), an array (14) of spots of reagent compositions for use in a chemical and/or biochemical analysis. The method includes displacing an array of reagent composition containing capillary tubes (22) arranged alongside one another from an inoperative position to an operative position in which open ends of the capillary tubes (22) simultaneously impinge against a substrate and thereafter displacing the array of tubes (22) from the operative position back to the inoperative position. The invention extends to a printing apparatus (10), a method of printing a layered array of spots of reagent compositions, a method of introducing reagent compositions into the tubes, a reagent introducing device for introducing reagent compositions into the tubes and a printing installation which includes the printing apparatus (10) and the reagent introducing device.

Abstract: An apparatus and method for counting nanoparticle probes is disclosed. In one embodiment, quantum dot-tagged proteins on optically transparent membranes or slides are counted. The transparent membranes or slides are loaded onto a stage (e.g., an X-Y stage or X-Y-Z stage), which can automatically reposition the transparent membrane or slides for image capture at varying locations. A microscope can be used for providing a light source to fluoresce the nanocrystals and for providing the magnification needed for image capture. Once one or more images are captured, the nanoparticles can be automatically counted using post-processing software that maintains a total count across multiple images, if desired.

Abstract: A mechanism is provided for utilizing a nanodevice to distinguish molecules with different structure. The molecules translocate through or across a nanochannel filled with a electrolyte solution. An electrical signal through the nanochannel is measured for every translocation event. Inner surfaces of the nanochannel include a functional layer, which is a coating to functionalize the nanochannel, in which the functional layer is configured to interact with predetermined ones of the molecules during translocation events. It is determined that a combination of at least two different molecules is formed based on predetermined ones of the molecules interacting with the functional layer to change the electrical signal and/or change a translocation time for the translocation event.

Abstract: A method of immobilizing matter for imaging that includes providing an array of nanofibers and directing matter to the array of the nanofibers. The matter is immobilized when contacting at least three nanofibers of the array of nanofibers simultaneously. Adjacent nanofibers in the array of nanofibers may be separated by a pitch as great as 100 microns. The immobilized matter on the array of nanofibers may then be imaged. In some examples, the matter may be cell matter, such as protoplasts.

Abstract: The present technology relates to methods and systems for detection of pyrophosphate. As such, disclosed herein are methods and systems that permit improved pyrophosphate detection. Also disclosed herein are methods and systems which utilize improved pyrophosphate detection for nucleotide sequencing.

Abstract: Methods of generating nucleic acid fragments of substantially uniform length from sample nucleic acids comprising linearly stretching the sample nucleic acids over a substrate having a plurality of cleavage regions separated by relatively consistent distances, cleaving the linearly stretched sample nucleic acids at the cleavage regions, and collecting the resulting nucleic acid fragments. The method may further include collecting and concentrating the resultant nucleic acid fragments of substantially uniform length.

Abstract: The present invention relates to methods, compositions and systems for detecting perchlorate in a sample. Compositions useful for detecting perchlorate in a sample include those comprising a perchlorate reductase, a reductant and an electron shuttle. In an exemplary embodiment, the composition comprises perchlorate reductase from Dechloromonas agitata, reduced nicotinamide adenine dinucleotide and N-methylphenazinium methylsulfate. The present invention also provides for methods of using the compositions disclosed herein, as well as systems thereof. In some exemplary embodiments, the methods comprise a concentration step, in which, for example, the sample is contacted with a cationic solid phase extraction column. Employing this step provides certain advantages such as a lowered detection limit and the removal of contaminants.

Abstract: A system and method of quantitating the concentration of a molecule of interest in one embodiment includes establishing a plurality of test environments at a plurality of test sites, each of the plurality of test environments associated with one of a plurality of response curves, each of the plurality of response curves different from the other of the plurality of response curves, storing a combined response curve resulting from a summation of the plurality of response curves, exposing the plurality of test sites to a sample having a concentration of a molecule of interest, obtaining a plurality of quantitation signals, each of the plurality of quantitation signals associated with one of the plurality of test sites, associating a summation of the plurality of quantitation signals with the stored combined response curve, and generating a signal related to the concentration of the molecule of interest based upon the association.

Abstract: Described are methods and means for enhancing enzyme activity toward insoluble substrates. This is achieved by means of in vitro compartmentalization in which an insoluble microparticle functions both as the enzyme substrate and as a structure for negative selection. Enhanced enzymes expressed from a microparticle-linked polynucleotide library preferentially degrade the microparticle releasing specific gene variants into solution. Gene variants encoding less active enzyme variants remain linked to the microparticle and may be removed through centrifugation, thus enriching the polynucleotide library for more active enzyme variants. These methods may be used to enhance cellulase and ligninase activity toward insoluble cellulosic biomass.

Abstract: The invention includes compositions comprising a S. cerevisiae yeast library, and methods of identifying an epigenetic marker for the diagnosis of infertility or a disorder associated with gametogenesis in an individual.

Abstract: The invention relates to a method for analysing interactions of a nucleic acid with at least one polypeptide, comprising (a) providing a reaction vessel with a composition comprising cross-linked complexes comprising at least one nucleic acid and at least one polypeptide; (b) immobilizing at least part of the cross-linked complexes to the reaction vessel; (c) at least partially reversing said cross-links in said immobilized complexes by performing a heat incubation step thereby at least partially releasing the nucleic acids from the complexes; (d) analyzing the released nucleic acid. wherein steps (a) to (d) are performed in one reaction vessel. Also provided are specific reaction vessels and kits.

Abstract: The present technology relates to methods and systems for detection of pyrophosphate. As such, disclosed herein are methods and systems that permit improved pyrophosphate detection. Also disclosed herein are methods and systems which utilize improved pyrophosphate detection for nucleotide sequencing.