Abstract: This invention provides high unit density arrays of microparticles and methods of assembling such arrays. The microparticles in the arrays may be functionalized with chemical or biological entities specific to a given target analyte. The high unit density arrays of this invention are formed on chips which may be combined to form multichip arrays according to the methods described herein. The chips and/or multichip arrays of this invention are useful for chemical and biological assays.

Abstract: A method of fragmentation of double stranded DNA is disclosed for use in nucleic acid analysis, notably in the multiplexed analysis of polymorphisms and mutations. The method produces a multiplicity of labeled sense and anti-sense fragments which are not complementary, and thus do not significantly re-anneal under conditions suitable for hybridization analysis (or capture-mediated elongation analysis) of the polymorphisms and/or mutations. The fragments display a desired or predicted length distribution. Cleavage sites can be selected such that the fragments are short, yet long enough to allow discrimination among fragments in an assay, and as a matter of statistical probability, such that the majority of fragments contain at least one labeled nucleotide to facilitate detection.

Abstract: Described are methods of assay design and assay image correction, useful for multiplexed genetic screening for mutations and polymorphisms, including CF-related mutants and polymorphs, using an array of probe pairs (in one aspect, where one member is complementary to a particular mutant or polymorphic allele and the other member is complementary to a corresponding wild type allele), with probes bound to encoded particles (e.g., beads) wherein the encoding allows identification of the attached probe. The methods relate to avoiding cross-hybridization by selection of probes and amplicons, as well as separation of reactions of certain probes and amplicons where a homology threshold is exceeded. Methods of correcting a fluorescent image using a background map, where the particles also contain an optical encoding system, are also disclosed.

Abstract: Disclosed are proteins which are covalently bound to a solid support at a first temperature where they have a first configuration, and then biomolecules are attached to the bound proteins at a higher temperature at which the proteins have more exposed functional groups, each such group being capable of covalently bonding to a biomolecule. The biomolecule can be, for example, a nucleic acid, including an amine functionalized oligonucleotide. The proteins can include, BSA (Bovine Serum Albumin) which can be bound using a reaction with the surface of a tosyl-activated microparticle.

Abstract: This invention provides compositions and methods for genetic testing of an organism and for correlating the results of the genetic testing with a unique marker that unambiguously identifies the organism. The markers may be internal markers, such as for example single nucleotide polymorphisms (SNPs), short tandem repeats (STRs), or other sites within a genomic locus. Alternatively, the markers may be external, such that they are separately added to the genetic sample before testing.

Abstract: Disclosed are methods for detecting antibody in a sample, where the antibody targets an antigen expressed by red blood cells or red blood cell ghosts. Rather than detecting the binding events between a particular antigen antibody pair (as in traditional agglutination based assays) the methods herein allow for multiplexed detection of clinically important allo-immune antibodies to blood group antigens. Specifically the method involves generating fluorescently encoded red blood cells or red blood cell ghosts with known antigen presentation and using them to detect the presence of antibody in serum/plasma with a fluorescent sandwich type immunoassay. The assay results can be read using flow cytometric or fluorescent microscope based imaging techniques.

Abstract: Disclosed are a method and an algorithm for genetic cross-matching based on the comparison of recipient and donor genotypes—and the underlying combinations of alleles and haplotypes. The method of the invention, rather than focusing on phenotype prediction, instead relies on a comparison of genetic variants identified in the recipient and available donors, whose information preferably will be compiled in a widely available donor registry, to maximize molecular compatibility. The genotypes can be matched based on the weighted clinical significance of a genotypic difference between donor and recipient, such that certain mismatches are more acceptable than others.

Abstract: A dynamically configurable electrode includes a first planar electrode and a planar array of pixels in a different plane, wherein a polarizable liquid medium (including electrolyte solutions) is to reside in the gap between electrodes. The pixels are individually addressable by a time-varying voltage, and adjacent pixels receive, at any instant in time, either the same voltage waveform or a different voltage waveform. Adjacent pixels receiving different voltage waveforms generate corresponding movement of dipolar entities, including dipolar particles, ions, or dipolar molecules in the polarizable liquid medium between the electrodes, which can in turn generate fluid flow and movement of particles suspended in the fluid along the planar array surface.

Abstract: A polyelectrolyte having multiple exposed functional groups, each such group being capable of covalently bonding to a molecule, is immobilized on a surface for the purpose of bonding to a biomolecule. The biomolecule can be, for example, a nucleic acid, e.g., an amine functionalized oligonucleotide. The polyelectrolyte can include, e.g., BSA (Bovine Serum Albumin) which is bound to a functionalized surface using a covalent immobilization strategy, e.g., reaction with the surface of a tosyl-activated microparticle. Following such reaction, exposed reactive functional groups on the protein, such as amine, carboxyl, thiol, hydroxyl groups can further be utilized to covalently couple the oligonucleotide of interest using suitable chemistry.

Abstract: Disclosed is a method of iteratively optimizing two (or more) interrelated sets of probes for the multi-step analysis of sets of designated sequences, each such sequence requiring, for conversion, at least one conversion probe (“primer”), and each converted sequence requiring, for detection, at least one capture probe. The iterative method disclosed herein for the concurrent optimization of primer and probe selection invokes fast logical string matching functions to perform a complete cross-correlation of probe sequences and target sequences. The score function assigns to each probe-target alignment a “degree of matching” score on the basis of position-weighted Hamming distance functions introduced herein. Pairs of probes in the final selection may differ in several positions, while other pairs of probes may differ in only a single position. Not all such positions are of equal importance, and a score function is introduced, reflecting the position of the mismatch within the probe sequence.

Abstract: Systems and methods are provided the autocentering, autofocusing, acquiring, decoding, aligning, analyzing and exchanging among various parties, images, where the images are of arrays of signals associated with ligand-receptor interactions, and more particularly, ligand-receptor interactions where a multitude of receptors are associated with microparticles or microbeads. The beads are encoded to indicate the identity of the receptor attached, and therefore, an assay image and a decoding image are aligned to effect the decoding. The images or data extracted from such images can be exchanged between de-centralized assay locations and a centralized location where the data are analyzed to indicate assay results. Access to data can be restricted to authorized parties in possession of certain coding information, so as to preserve confidentiality.

Abstract: Described are methods of assay design and assay image correction, useful for multiplexed genetic screening for mutations and polymorphisms, including CF-related mutants and polymorphs, using an array of probe pairs (in one aspect, where one member is complementary to a particular mutant or polymorphic allele and the other member is complementary to a corresponding wild type allele), with probes bound to encoded particles (e.g., beads) wherein the encoding allows identification of the attached probe. The methods relate to avoiding cross-hybridization by selection of probes and amplicons, as well as separation of reactions of certain probes and amplicons where a homology threshold is exceeded. Methods of correcting a fluorescent image using a background map, where the particles also contain an optical encoding system, are also disclosed.

Abstract: Solute-loaded polymer microparticles are obtained by immersing microparticles in a bath comprising a selected solute dissolved in a ternary solvent system. A first solvent of the ternary system is a strong solvent for both the solute and the polymer from which the microparticle was formed. A second solvent is a weak solvent or non-solvent for the solute and the polymer (tuning solvent). A third solvent is a weak solvent or non-solvent for the solute and polymer, but serves as a co-solvent with respect to the first and second solvents in that it is miscible with both the first and second solvents. The amount of solute incorporated into the microparticles is controlled by adjusting the ratio of solute with respect to the microparticle polymer, and by adjusting the composition of the ternary solvent system, principally the amount of tuning solvent.

Abstract: A method and apparatus for the manipulation of colloidal particulates and biomolecules at the interface between an insulating electrode such as silicon oxide and an electrolyte solution. Light-controlled electrokinetic assembly of particles near surfaces relics on the combination of three functional elements: the AC electric field-induced assembly of planar aggregates; the patterning of the electrolyte/silicon oxide/silicon interface to exert spatial control over the assembly process; and the real-time control of the assembly process via external illumination. The present invention provides a set of fundamental operations enabling interactive control over the creation and placement of planar arrays of several types of particles and biomolecules and the manipulation of array shape and size. The preset invention enables sample preparation and handling for diagnostic assays and biochemical analysis in an array format, and the functional integration of these operations.

Abstract: A method and apparatus for the manipulation of colloidal particulates and biomolecules at the interface between an insulating electrode such as silicon oxide and an electrolyte solution. Light-controlled electrokinetic assembly of particles near surfaces relies on the combination of three functional elements: the AC electric field-induced assembly of planar aggregates; the patterning of the electrolyte/silicon oxide/silicon interface to exert spatial control over the assembly process; and the real-time control of the assembly process via external illumination. The present invention provides a set of fundamental operations enabling interactive control over the creation and placement of planar arrays of several types of particles and biomolecules and the manipulation of array shape and size. The present invention enables sample preparation and handling for diagnostic assays and biochemical analysis in an array format, and the functional integration of these operations.

Abstract: This invention provides compositions and methods for genetic testing of an organism and for correlating the results of the genetic testing with a unique marker that unambiguously identifies the organism. The markers may be internal markers, such as for example single nucleotide polymorphisms (SNPs), short tandem repeats (STRs), or other sites within a genomic locus. Alternatively, the markers may be external, such that they are separately added to the genetic sample before testing.

Abstract: The present invention relates to molecular constructs and methods of their use in detecting biochemical reactions. In particular, the invention relates to a molecular construct having a capture portion and a substrate portion, where the capture portion isolates the construct from a sample medium, and the substrate portion enables the construct to be acted upon and undergo a physical change which can be detected and measured. These molecular constructs may be used in diagnostic assays, genetic screening for potential risks of certain diseases in individuals, and drug discovery and toxicogenomics, using high throughput screening of compounds.

Abstract: Disclosed are methods of processing images, and in particular aligning and orienting grids from a fluorescent array of signal sources, by linking nearest neighbor sources to form a hexagon, and then using the hexagon lines for alignment and orientation of the grid. Also disclosed are methods and algorithms for aligning image with grid and correcting for signal beads which are smaller than a grid field and the shift in a grid field. These methods can be used where the signal sources are fluorescent images from a microarray. Also disclosed are methods of automated watershed clustering following transformation.

Abstract: The present invention provides a method of performing analyses and assays involving multiple interactions of reagent-containing fluid flows with liquid and solid target substances. The methods of the invention allow the simultaneous manipulation of different fluids on a small planar surface. The invention also provides a flow cell and method of use thereof for analyzing fluid-fluid and fluid-solid interactions in a substantially planar system. The flow cell contains at least one chamber and a plurality of inlets thereto allowing the introduction of a plurality of fluids in fluidic contact. The cell depth is the smallest dimension of the flow cell, and is of a magnitude, from about 50 to about 1000 microns such that any mixing of adjacent fluids in the chamber is substantially limited to mixing by passive diffusion.

Abstract: This invention provides compositions and methods for genetic testing of an organism and for correlating the results of the genetic testing with a unique marker that unambiguously identifies the organism. The markers may be internal markers, such as for example single nucleotide polymorphisms (SNPs), short tandem repeats (STRs), or other sites within a genomic locus. Alternatively, the markers may be external, such that they are separately added to the genetic sample before testing.