Abstract: The present invention is directed to methods for conducting multiplexed assays. The methods are particularly well suited for measuring a plurality of analytes that may be present in very different abundances. The invention also relates to systems, devices, equipment, kits and reagents for use in such methods.

Abstract: Methods are disclosed for the capture, detection, separation, isolation and quantification of contaminants in a starting material. Also disclosed are competitive assay methods for the detection and quantification of contaminants in a starting material. Kits for use with the method are disclosed as well. A system for capturing, separating and/or concentrating contaminants from a material is also presented. The system captures, separates and/or concentrates contaminants such as bacteria, viruses, other microorganisms, and/or larger items, such as insects, from a variety of materials, such as food, and environmental and clinical materials. In general, the system uses a rotating magnetic field to mix the material with magnetic particles to capture the target contaminants, and a fixed magnetic field to separate and concentrate the captured target contaminants.

Abstract: The invention relates to analytical methods in which the partition of a labeled substance between a liquid and a solid phase is determined. The assays include solid-phase reagents which can be particulate or monolithic such as, for example, a coated tube. Assays of this type are known per se to the person skilled in the art and include immunoassays and immunometric assays.

Abstract: A coated magnetic particle comprising an optionally porous magnetic polymer particle of a matrix polymer, said polymer particle having on a surface and/or in the pores thereof superparamagnetic crystals, said coated particle having a coat formed of a coating polymer, wherein said coated magnetic particle is essentially non-autofluorescent.

Abstract: Magnetic particles with a metal coat holding target substance captors are made to react with a target substance contained in a specimen in a solution where the magnetic particles are dispersed in a liquid medium. Subsequently, the dispersion of the magnetic particles is applied to a surface having a periodic structure that is adapted to generate plasmon resonance and a change in the plasmon resonance attributable to the concentration of the target substance held on the magnetic particles fixed magnetically to the surface is optically detected to determine the concentration of the target substance in the specimen.

Abstract: Magnetic nanoparticles and methods for their use in detecting biological molecules are disclosed. The magnetic nanoparticles can be attached to nucleic acid molecules, which are then captured by a complementary sequence attached to a detector, such as a spin valve detector or a magnetic tunnel junction detector. The detection of the bound magnetic nanoparticle can be achieved with high specificity and sensitivity.

Abstract: The invention includes devices and methods for forming random arrays of magnetic particles, arrays formed using these devices and methods, and to methods of using the arrays. The invention provides an assembly (chip) with magnetic domains that produce localized magnetic fields capable of immobilizing magnetic particles such as commercially available magnetic beads. Probe or sensor molecules can be coupled to the beads, which are then dispersed on the assembly, forming a random order array. The arrays can be used for analyzing samples, targets, and/or the interaction between samples and targets. The invention finds particular use in processes such as high-throughput genotyping and other nucleic acid hybridization-based assays.

Abstract: A method and composition for detecting and measuring analytes, such as antibodies, which are capable of binding with certain binding partners such as antigens. A homogenous assay is performed in the presence of free unbound antibodies. Such a homogeneous assay testing for specific antibodies is herein possible by defining of test subsets of microparticles having specific antigens thereon which are capable of binding with specific target antibodies. The microparticle suspension also includes at least two calibration subsets of microparticles having a binding partner thereon with at least two known levels of concentration which is capable of binding with human antibodies for the purpose of assay calibration. A verification subset of microparticles is included with another binding partner thereon at a known concentration, capable of binding with anti-human antibodies. This suspension is incubated with a human sample and then is incubated with a tagging component.

Abstract: A method and apparatus for detecting a target molecule in a sample are disclosed. The method optionally includes, but is not limited to, contacting the sample with a substrate having a metallic surface and receptors configured to bind to a target molecule, optionally in the presence of one or more metallic nanoparticles also including receptors configured to bind to a target molecule. The method optionally further includes dispersing a dye over the substrate; and applying a magnetic field to the substrate.

Abstract: The present invention relates to a method for the selective purification of bacterial cells and/or cell components, whereby the purification is performed by means of a solid support.

Abstract: Apparatuses and methods for separating, immobilizing, and quantifying biological substances from within a fluid medium. Biological substances are observed by employing a vessel (6) having a chamber therein, the vessel comprising a transparent collection wall (5). A high internal gradient magnetic capture structure may be on the transparent collection wall (5), magnets (3) create an externally-applied force for transporting magnetically responsive material toward the transparent collection wall (5). V-shaped grooves on the inner surface of the viewing face of the chamber provide uniform. The invention is also useful in conducting quantitative analysis and sample preparation in conjunction with automated cell enumeration techniques.

Abstract: The present invention relates to a method for differentially detecting a multimeric form from a monomeric form of a multimer-forming polypeptide in a biosample, which comprises the steps of: (a) preparing a carrier-capturing antibody conjugate by binding a capturing antibody to the surface of a solid phase carrier in a three dimensional manner, wherein the capturing antibody is capable of recognizing an epitope on the multimer-forming polypeptide; (b) preparing a detection antibody, wherein an epitope recognized by the detection antibody is present at a position in the multimer-forming polypeptide to cause a steric hindrance by the capturing antibody bound to its epitope to prevent the binding of the detection antibody to the multimer-forming polypeptide; (c) contacting simultaneously the carrier-capturing antibody conjugate and the detection antibody to the biosample; and (d) detecting the formation of a carrier-capturing antibody-multimeric form-detection antibody complex.

Abstract: A device for treating an analyte using magnetic beads is provided wherein the surfaces of the magnetic beads are effectively available as a whole. The device comprises a housing having a channel therein, through which channel the analyte is moved; a pair of electromagnets which are oppositely arranged in such a manner that the channel is interposed therebetween; a moving means for moving the pair of electromagnets along the channel while the electromagnets are facing the channel; and a controlling means for controlling magnetic forces generated by the electromagnets. The device is characterized in that the magnetic forces of the electromagnets are alternately generated with time. This will cause the magnetic beads to collide successively with the inner surface of the channel, which in turn gives a more efficient dispersion of the magnetic beads even if they are clustered or agglutinated to each other.

Abstract: A device includes a plurality of structures, each structure including at least one ferromagnetic layer having fringe fields. Fringe fields of the structures interact to form a magnetic well for nanoparticles. This device may be adapted for biosensing, wherein the magnetic well is formed about a probe area.

Abstract: Methods for detecting analytes in a sample are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for the analyte, is combined with the sample to form a plurality of analyte-particle complexes. The system also includes a transport arrangement for transporting the sample to the sensor surface, and a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of analyte-particle complexes that are bound to the sensor surface.

Abstract: The invention relates to a simple and rapid method for the detection of cells and biomolecules by means of paramagnetic particles (beads) without separating the detected biomolecules or target cells from the beads before evaluating the specific bond.

Abstract: A method and system for the detection and identification of a target pathogen in a sample is disclosed. The method and system involve the use of a capture matrix throughout resuscitation, growth, and detection. The method includes the steps of: placing the sample in a sampling container containing a medium (preferably a growth/resuscitation medium); optionally homogenizing the sample; placing a capture matrix in the sampling container with the sample; incubating the sample in the medium for a pre-determined amount of time at an appropriate temperature; optionally removing the capture matrix from the sampling container; and detecting the presence of the target pathogen in the sample.

Abstract: A method for suppressing non-specific bindings between molecules includes providing magnetic particles dispersed in a liquid, wherein each of the magnetic particles has a magnetization. The magnetic particles are coated with coating molecules. Binding molecules mixed of first-type binding molecules and second-type binding molecules are applied to the liquid, wherein the coating molecules are specifically binding with the first-type binding molecules and non-specifically binding with the second-type binding molecules. An alternating current (ac) magnetic field is applied at an axis with a frequency level, wherein the frequency level causes suppression of the second-type binding molecules in binding with the coating molecules.

Abstract: A method of reporting a binding event having increased sensitivity and multiplex capabilities. A reporter supra-nanoparticle assembly is provided that has an inner core made of a polymeric material, a coating on the inner core made of a polymeric material and a plurality of reporter nanoparticles, and a first active group on the surface of the coating.

Abstract: The present invention proves instruments and methods for detecting and/or quantitating an analyte in a fluid sample. The fluid sample is placed in a sample chamber having a small, shallow detection region. The analyte is magnetically labeled using magnetic particles coated with a binding reagent, and is detectably labeled using a fluorescent dye or other detection reagent. The magnetically labeled analyte is concentrated into the detection region using a focusing magnet positioned underneath the sample chamber detection region. Concentrated analyte is measured using excitation optics positioned on top of the sample chamber detection region, adapted to illuminate only the detection region, and detection optics positioned on top of the detection region, adapted to detect only light emitted from the detection region. In a preferred embodiment, the invention provides a simple, rapid assay for measuring the concentration of CD4+T cells in a whole blood sample.

Abstract: It is an object of the present invention to provide magnetic substance-encapsulated particles which have uniform magnetism, high dispersion stability and a narrow particle size distribution, a method of producing the same, particles for immunoassay formed by using the magnetic substance-encapsulated particles and a method of immunoassay in which the magnetic substance-encapsulated particles or the particles for immunoassay are used. The present invention relates to a magnetic substance-encapsulated particle, which comprises an organic polymer material and a magnetic substance having an average particle size of 1 to 30 nm, the magnetic substance being contained within a particle in a state of being dispersed.

Abstract: Methods for detecting viruses are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for the virus, is combined with the sample to form a plurality of analyte-particle complexes. The system also includes a transport arrangement for transporting the sample to the sensor surface, and optionally a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of analyte-particle complexes that are bound to the sensor surface.

Abstract: Methods for detecting bacteria are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for the bacteria, is combined with the sample to form a plurality of analyte-particle complexes. The system also includes a transport arrangement for transporting the sample to the sensor surface, and optionally a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of analyte-particle complexes that are bound to the sensor surface.

Abstract: A magnetic transfer method for sorting, collecting, transferring or dosing microparticles (22) or magnetic particles either in the same liquid (23) or from one liquid (23a) into another (23b) by using a magnetic field. The transfer device (10) comprises a magnet (13) placed inside a protective coating (21), and the collection or dozing is accomplished by changing the magnetic field of the magnet (13). The changing of the magnetic field is effected by using a ferromagnetic body, such as a plate or tube (12), comprised in the transfer device, in such manner that, when micro-particles are to be collected, the magnet is partially or completely outside the ferromagnetic body and, when the particles are to be released or dozed, the magnet is partially or completely inside or behind the ferromagnetic body.

Abstract: The present invention provides a magnetic sifter that is small in scale, enables three-dimensional flow in a direction normal to the substrate, allows relatively higher capture rates and higher flow rates, and provides a relatively easy method of releasing captured biomolecules. The magnetic sifter includes at least one substrate. Each substrate contains a plurality of slits, each of which extends through the substrate. The sifter also includes a plurality of magnets attached to the bottom surface of the substrate. These magnets are located proximal to the openings of the slits. An electromagnetic source controls the magnitude and direction of magnetic field gradient generated by the magnets. Either one device may be used, or multiple devices may be used in series. In addition, the magnetic sifter may be used in connection with a detection chamber.

Abstract: Methods for detecting estradiol and metabolites thereof in a sample are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for estradiol, is combined with the sample to form a plurality of estradiol-particle complexes. The system also includes a transport arrangement for transporting the sample and/or particles to the sensor surface, and optionally a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of estradiol-particle complexes that are bound to the sensor surface.

Abstract: Methods for therapeutic drug monitoring are provided. A plurality of particles, each of which is coated with a capture agent capable of binding a therapeutic drug of choice is combined with the sample to form a plurality of therapeutic drug-particle complexes. The system also includes a transport arrangement for transporting the sample and/or particles to the sensor surface, and optionally a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of therapeutic drug-particle complexes that are bound to the sensor surface.

Abstract: The invention relates to a magnetic immunodiagnostic method for the demonstration of antibody-antigen complexes. One such method involves the research and/or identification of antibodies or antigens, preferably anti-antigen antibodies or antigens of a blood group, and comprises a suspension of magnetic particles coated with antigens that can be carried by cells such as erythrocytes. The invention also relates to a device and a kit for carrying out one such method.

Abstract: Immunological assays for several biological markers for thyroid disorders in a biological sample are performed in a single test with a combination of sandwich-type, sequential competitive, and serological assays by the use of particles classified into groups that are distinguishable by flow cytometry, one group for the assay of each marker. Each group of particles is coated with a different immunological binding member, and coating densities, co-coating materials, and special buffer solutions are used to adjust for differences in the sensitivities and dynamic ranges of each of the markers in the typical sample.

Abstract: An assay exhibiting improved sensitivity for achieving a factor of ten times (10×) better sensitivity than current sensitivity levels achieved by prior-art immunoassays, as exemplified by ELISA. Three main implementations are described: IA/MPD, Super-ELISA and Reverse Geometry Immunoassay, including specific panel biomarker relationships for the early detection and recognition patterns of breast and prostate cancers. More sensitive immunoassays are achieved through a better understanding of sources of biological background, and by the rejection of particular sources thereof. Super-sensitive immunoassays permit measurement of blood sample biomarkers, and show distribution of low abundance proteins included relationships between cytokine non-Gaussian distributions, very large dynamic ranges and strong age dependence, and including new algorithms based on 2D correlations of studied biomarkers.

Abstract: The present invention relates to methods, kits and assay system for detecting drug-resistant Mycobacterium tuberculosis of suspected patient. The system of the present invention largely reduces the whole process of drug-resistant M. tuberculosis detection in less than 5 hours.

Abstract: Methods for detecting cardiac injury by detecting one or more cardiac markers are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for a cardiac marker, is combined with the sample to form a plurality of analyte-particle complexes. The system also includes a transport arrangement for transporting the sample to the sensor surface, and optionally a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of analyte-particle complexes that are bound to the sensor surface.

Abstract: A single microchannel is combined with external electromagnets for performing a fast immunoassay within a very small volume. Magnetic/luminescent nanoparticles serve as carriers for the antibodies and as internal luminescent standard. The immunoreaction is accelerated by applying alternating magnetic field by means of the external electromagnets, thus inducing oscillation of the particles and achieving better diffusion during the incubation steps. Using the electromagnets the particles are held into the channel for washing and luminescence detection steps. The luminescence of the particles serves as an internal calibration for the assay and helps to avoid experimental error from particle loss.

Abstract: The invention involves methods, assays, and components for the detection and analysis of binding between biological or chemical species, and can specifically be used for drug discovery. In an example where drug discovery is carried out, different candidate drugs can be attached to different articles such as magnetic beads. The beads can be exposed to colloid particles carrying signaling entities, or other signaling entities, immobilized with respect to protein targets of the drug candidates. After incubation, all beads are drawn to separate surface locations magnetically. Beads are released from surface locations where it is determined that signaling entities do not exist, and are removed from the assay. Beads held at other surface locations then are released, re-distributed, and re-attracted to surface locations. This is repeated with appropriate wash steps, until individual drug candidates can be isolated and identified.

Abstract: The present invention relates to an assay system, kits and methods for detecting microorgansims (especially for M. tuberculosis) of suspected patient. The present invention also relates to an apparatus for performing the integration of thermal and magnetic control in the same apparatus to largely reduce the whole process of M. tuberculosis detection is less than 5 hours.

Abstract: This invention relates to a method for detecting an analyte in a sample. The method comprises the steps of exposing the sample to a transducer having a pyroelectric or piezoelectric element and electrodes which is capable of transducing a change in energy to an electrical signal, the transducer having at least one reagent proximal thereto, the reagent having a binding site which is capable of binding the analyte or a complex or derivative of the analyte, wherein at least one of the analyte or the complex or derivative of the analyte has a label attached thereto which is capable of absorbing the electromagnetic radiation generated by the radiation source to generate energy by non-radiative decay; irradiating the reagent with a series of pulses of electromagnetic radiation, transducing the energy generated into an electrical signal; detecting the electrical signal and the time delay between each pulse of electromagnetic radiation from the radiation source and the generation of the electric signal.

Abstract: Heterogeneous assays for different analytes in a single biological sample are performed simultaneously in a multiplexed assay that combines flow cytometry with the use of magnetic particles as the solid phase and yields an individual result for each analyte. The particles are distinguishable from each other by characteristics that permit them to be differentiated into groups, each group carrying an assay reagent bonded to the particle surface that is distinct from the assay reagents of particles in other groups. The magnetic particles facilitate separation of the solid and liquid phases, permitting the assays to be performed by automated equipment. Assays are also disclosed for the simultaneous detection of antibodies of different classes and a common antigen specificity or of a common class and different antigen specificities.

Abstract: The present invention relates to a method of transporting an analyte present in a sample, to a method of concentrating an analyte present in a sample, and to a device for implementing these methods. In the method of transporting an analyte present in a sample of the present invention, a solution A in which the analyte is attached to magnetic particles is prepared from the sample; the solution A is introduced into a first container connected via a bottleneck to a second container; and the analyte attached to the magnetic particles is moved, by means of a magnetic system, from the first container to the second container via the bottleneck, the second container being filled with all or part of the solution A and/or with another solution.

Abstract: A biosensor capable of analyzing an object, such as antigen, antibody, DNA or RNA, through detection of magnetic field to thereby allow washout of unbound label molecules to be unnecessary, which biosensor is compact and available at low price, excelling in detection precision. Coils are arranged at an upper part and a lower part of a magnetic sensor using a hall element as a magnetic field detection element. An object and magnetic particles having an antibody capable of specific bonding with the object bound to the surface thereof are introduced in the magnetic sensor having a molecular receptor capable of specific bonding with the object attached to the surface thereof. Therefore, a change in magnetic field by magnetic particles bonded through the molecular receptor to the surface of the magnetic sensor is detected by means of the hall element.

Abstract: A method for improving the sensitivity of an immunoassay by a factor of at least 10 to about 25, and perhaps greater. Furthermore, in addition to increasing the sensitivity of the assay, the method of this invention also improves assay specificity. In order to match or improve upon sensitivity of 0.2 pg/mL for an analyte, this invention provides an immunoassay involving amplification of a signal, e.g., a chemiluminescent signal, a specific binding member, e.g., a monoclonal antibody, and microparticle separation, e.g., magnetic microparticle separation, from large volumes of sample (e.g., from about 0.2 to about 3 mL). Such an immunoassay can be carried out with an automated immunoassay analyzers, e.g., an automated immunoassay analyzer in the ARCHITECT® family of analyzers.

Abstract: The present invention is directed to methods for quantitatively measuring biomolecules by using magnetic nanoparticles. Through the use of the magnetic nanoparticles and the bioprobes coated to the magnetic nanoparticles, the biomolecules conjugated with the bioprobes result in the formation of particle clusters. By measuring the changes in magnetic properties resulting from the existence of the bio-targets, the amount of the bio-targets in a sample to be tested can be measured.

Abstract: The present invention is related to a method for re-enabling transport by means of a magnetic field gradient transport mechanism of magnetic beads comprising a ligand in a solution on top of a surface comprising a receptor bound with said ligand, comprising the step of changing the properties of said solution such that dissociation occurs between said ligand and said receptor, and such that a sufficient repulsive interaction is created between said surface and said bead to allow transport of said bead.

Abstract: The invention relates generally to in vivo collection of circulating molecules, tumor cells and other biological markers using a collecting probe. The probe is configured for placement within a living organism for an extended period of time to provide sufficient yield of biological marker for analysis. In some embodiments of the invention, active attraction of biological markers are provided. A partial or complete analytic/detection assembly may also be integrated with the probe.

Abstract: A specific coupling reaction measuring method of this invention for measuring a content of a subject substance in a sample includes the steps of (a) constructing a reaction system including the sample and a magnetic particle on which a specific coupling substance for specifically coupling with the subject substance is immobilized; (b) measuring an optical characteristic of the reaction system; and (c) removing, from the reaction system, an agglutination complex including the subject substance, the specific coupling substance and the magnetic particle by utilizing magnetic force.

Abstract: Methods for detecting analytes in a sample are provided. A plurality of particles, each of which is coated with a capture agent having an affinity for the analyte, is combined with the sample to form a plurality of analyte-particle complexes. The system also includes a transport arrangement for transporting the sample to the sensor surface, and a magnetic field inducing structure constructed and arranged to establish a magnetic field at and adjacent to the sensor surface. The resonant sensor produces a signal corresponding to an amount of analyte-particle complexes that are bound to the sensor surface.

Abstract: A method of single parameter and multiparameter characterizing of cells, particularly immunophenotyping of cells, is provided. The method preferably uses antibody coated microspheres which are adapted to bind to specific types of cells. One or more sets of coated microspheres are added simultaneously or sequentially to a suspension of cells and bind the cells they are adapted to bind. Cells may bind to one or more microspheres. The suspension is then filtered to trap bead-cell complexes. The complexes are preferably stained and then examined to characterize the cells, preferably the cells bound to the microspheres. A kit and apparatus for performing the method are also provided.

Abstract: A method is provided for detecting biomarkers in rare circulating cells by forming an enriched population of cells immunomagnetically followed by biomarker detection using binding compounds having releasable molecular tags. Preferably, biomarkers comprising one or more protein-protein complexes are detected in circulating cancer cells metastasized from a solid tumor. In the presence of biomarkers, the molecular tags of the binding compounds are released and separated from the assay mixture for detection and/or quantification.

Abstract: A metallic nanoparticle coated water-soluble polymeric substrate and the process for preparing and using the same is described.

Abstract: The present invention relates to the field of detection of analytes, and in particular to detection of viruses, cells, bacteria, lipid-membrane containing organisms, proteins, nucleic acids, carbohydrates and other biomolecules, organic molecules and inorganic molecules using a liquid crystal assay format.

Abstract: The application relates to a method for detecting a target in a sample suspected of containing the target. The method comprises contacting the sample and a first binding molecule attached to a magnetic particle with a second binding molecule attached to a solid support. The first binding molecule is capable of binding to the second binding molecule, and the target is capable of interfering with this binding. Magnetic force is applied to bring the magnetic particle into close proximity with the solid support. The number of magnetic particles bound to the solid support is detected.