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: A method for detecting a ligand is provided. Antibodies to a predetermined ligand are attached to substrates. The substrates are superparamagnetic, dyed beads. The beads are exposed to an electromagnetic field to immobilize the beads. The beads are contacted with a sample and the antibodies are allowed to recognize and capture the ligand in the sample. The electromagnetic field is optionally removed. The beads are contacted with a liquid crystalline material and the light transmission properties of the liquid crystalline material are examined for alteration caused by the presence of aggregates of the beads and the ligand.

Abstract: An embodiment of the invention relates to a device for detecting an analyte in a sample. The device comprises a fluidic network and an integrated circuitry component. The fluidic network comprises multiple zones such as a sample zone, a cleaning zone and a detection zone. The fluidic network contains a magnetic particle and/or a signal particle. A sample containing an analyte is introduced, and the analyte interacts with the magnetic particle and/or the signal particle through affinity agents. A microcoil array or a mechanically movable permanent magnet is functionally coupled to the fluidic network, which are activatable to generate a magnetic field within a portion of the fluidic network, and move the magnetic particle from the sample zone to the detection zone. A detection element is present which detects optical or electrical signals from the signal particle, thus indicating the presence of the analyte.

Abstract: A method for removing excess unbound ferrofluid and imaging immunomagnetically enriched circulating tumor cells is provided. A vessels having a preformed grooves in the viewing surface is optimally designed for cell alignment and imaging. After separating the unbound particles by centrifugation, an externally-applied force is applied to transport magnetically responsive particle-CTC complex toward the transparent collection wall. The grooved inner surface of the viewing face of the chamber provide uniform distribution of the particles for easy imaging. The invention is also useful in conducting quantitative analysis and sample preparation in conjunction with automated cell enumeration techniques as in quantitative analysis of CTC in disease.

Abstract: Materials and methods for making small magnetic particles, e.g. clusters of metal atoms, which can be employed as a substrate for immobilizing a plurality of ligands. Also disclosed are uses of these magnetic nanoparticles as therapeutic and diagnostic reagents, and in the study of ligand-mediated interactions.

Abstract: Contemplated herein is an automated microscope slide antigen recovery and staining apparatus and method that features a plurality of individually operable miniaturized pressurizable reaction compartments for individually and independently processing a plurality of individual microscope slides. The apparatus preferably features independently movable slide support elements each having an individually heatable heating plate. Each slide support element preferably supports a single microscope slide. Each microscope slide can be enclosed within an individual pressurizable reaction compartment. Pressures exceeding 1 atm or below 1 atm can be created and maintained in the reaction compartment prior to, during or after heating of the slide begins.

Abstract: The invention describes a family of sensors for assaying macro-molecules and/or biological cells in solution. Each sensor has the form of a well (a hollow cylinder having a floor but no lid) or a trench whose walls comprise a plurality of GMR or TMR devices. Suitably shaped magnets located below each well's floor pull labeled particles into the well/trench and up against the inner wall where a field gradient orients them for optimum detection. Any unattached labels that happen to also be in the well/trench are removed through suitably sized holes in the floor.

Abstract: A particle suspension for use in immunoassay, comprising: particles for use in immunoassay; and a silicone antifoam agent, is disclosed. And a reagent kit for use in immunoassay, comprising: a reagent containing particles and a silicone antifoam agent; another reagent containing an antigen or antibody capable of binding to a target substance and particles; and a further reagent containing a labeled antigen or antibody capable of binding to the target substance, is disclosed.

Abstract: The present invention relates to droplet-based affinity assays. According to one embodiment, a method of detecting a target analyte in a sample is provided, wherein the method includes: (a) executing droplet operations to combine affinity-based assay reagents on a droplet microactuator with a sample potentially comprising the target analyte to generate a signal indicative of the presence, absence and/or quantity of analyte; and (b) detecting the signal, wherein the signal corresponds to the presence, absence and/or quantity of the analyte in the sample.

Abstract: The present invention provides a method for the generation of novel libraries of encoded magnetic particles from sub-libraries of by the generation of novel sub-libraries of magnetic nanoparticles and encoded particles. The sub-libraries are functionalized on demand are useful in the formation of arrays. The present invention is especially useful for performing multiplexed (parallel) assays for qualitative and/or quantitative analysis of binding interactions of a number of analyte molecules in a sample.

Abstract: The invention is to provide a magnetic sensor capable of detecting magnetic particles over a wide range of number and of suppressing an increase in a detection area. The magnetic sensor includes a detection part, a selecting device connected electrically to an end of the detecting part, and a sensing amplifier for receiving a signal from the detecting part, wherein the detecting part includes at least two magnetoresistive films serially connected.

Abstract: An automated microscope slide staining system and staining apparatus and method that features a plurality of individually operable miniaturized pressurizable reaction compartments or a pressurizable common chamber for individually and independently processing a plurality of microscope slides. The apparatus preferably features independently movable slide support elements each having an individually operable heating element.

Abstract: A sensing method for biopolymers by detecting the magnetic signal generated from a labeled biopolymer under AC magnetic field with thermo-responsive magnetic nano particles as label having a critical solution temperature across which the particles have the ability to aggregate or disperse with cooling or heating.

Abstract: A magnetic sifter is adapted for manipulation of biological cells by providing a greater pore density at the edge of the sifter than at the center. Application of an external magnetic field to the sifter causes high magnetic fields and field gradients at the sifter pores. These conditions are suitable for capturing magnetically tagged or labeled cells at the sifter pores. Altering the external magnetic field can provide controlled capture and/or release of magnetically labeled cells from the sifter pores. The purpose of having a greater pore density at the periphery of the sifter than at the center is to provide improved flow rate uniformity through the sifter. Such flow rate uniformity is advantageous for cell quantification.

Abstract: The invention features a method of attaching a ligand that has a free carboxyl group to a solid support by adding an amino group to the ligand to form a ligand-amino derivative, converting the ligand amino derivative to a ligand sulfhydryl derivative, attaching the ligand sulfhydryl derivative to a protein to form a ligand-linker-protein conjugate, and applying the ligand-linker-protein conjugate to the solid support. The method is particularly useful for immobilizing small molecule ligands having a free carboxyl group, such as cloxicillin, to a lateral-flow test strip, in order to make a detection zone on the test strip that exhibits a clear signal and enhanced sensitivity.

Abstract: A method (800) of detecting a target within a population of molecules comprising: contacting a plurality of labeled probe molecules with the population of molecules potentially containing a target of the probe molecules (810); acquiring a probe specific signal emitted by said labeled probe molecules that bound to said target together with a background signal (820); modulating said probe specific signal by at least one of modulating said acquisition and modulating an emission of said probe specific signal (830); and detecting said probe specific signal over said background signal using said preferential modulation (840). The target comprises one or more molecule type selected from the group consisting of a nucleic acid sequence, an amino acid sequence, a carbohydrate sequence, an ion and a feature of a protein determined by non-primary structure. The probe specific signal may be a fluorescent signal.

Abstract: A method for the fluorescent detection of a substance, the method comprising providing particles comprising a metal or a metal oxide core, wherein one or more optionally fluorescently tagged antibodies or human specific peptide nucleic acid (PNA) oligomers for binding to a substance is/are bound, directly or indirectly, to the surface of the metal or metal oxide; contacting a substrate, which may or may not have the substance on its surface, with the particles for a time sufficient to allow the antibody/PNA oligomer to bind with the substance; removing those particles which have not bound to the substrate; if the antibodies or PNA oligomers are not fluorescently tagged, contacting the substrate with one or more fluorophores that selectively bind with the antibody and/or substance, then optionally washing the substrate to remove unbound fluorophores; and illuminating the substrate with appropriate radiation to show the fluorophores on the substrate.

Abstract: Embodiments of the invention relate generally to ferromagnetic microdisks, methods of detecting target bioanalyte using ferromagnetic microdisks, and kits (such as for using in the laboratory setting) containing the reagents necessary to make, and/or use ferromagnetic microdisks for bioanalyte detection, depending on the user's planned application. The methods and products allow the fabrication of ferromagnetic microdisks, and their use in the detection of biological molecules with high sensitivity, little or no signal decay, improved safety, convenience, and lowered cost for use and disposal.

Abstract: A method for increasing a spectroscopic signal in a biological assay is provided. The method includes forming a suspension of magnetically attractable particles. The method also includes introducing a first magnetic field at a first location to draw the magnetically attractable particles towards the first location and form a first agglomeration. The method also includes removing the first magnetic field. The method further includes introducing a second magnetic field at a second location to draw the first agglomeration towards the second location and form a second agglomeration. The method further includes focusing an excitation source on the second agglomeration formed at the second location.

Abstract: The present invention concerns a novel means by which chemical preparations can be made. Reactions can be accelerated on special cartridges using microwave energy. The chips contain materials that efficiently absorb microwave energy causing chemical reaction rate increases. The invention is important in many chemical transformations including those used in protein chemistry, in nucleic acid chemistry, in analytical chemistry, and in the polymerase chain reaction.