Abstract: The present invention relates to a method and apparatus for detecting analytes in a medium, and more particularly the present invention relates to an assay based on light diffraction which appears or changes upon the binding of analytes to their specific receptors laid out in patterns on a substrate, which has high sensitivity due to the appropriate choice of such patterns. The present invention is based on the principle that the pattern of recognition elements, which gives rise to the diffraction of the incident light in a diffraction-based assay, can be chosen in such a way so as to facilitate detection, and to enhance the signal to be detected compared to known gratings such as parallel straight lines. In one aspect the substrate itself has a surface topography designed to enhance the diffraction pattern signals. In another aspect the substrate is a diffractive optic element having the analyte-specific receptors affixed to the optic element.

Abstract: Improved surface-enhanced Raman scattering (SERS) substrates comprising chemically-derivatized magnetic microparticles complexed with metal colloidal particles or substrates. The SERS substrates permit collection, detection, measurement, and/or analysis of analytes present at concentrations ranging parts per trillion to parts per billion. Further, compositions, methods, and devices that provide for rapid and/or sensitive detection of chemical compounds of interest present in small concentrations. The subject matter has use in the areas of homeland security and force protection, for example, in the detection of trace samples including, for example, BTEX (benzene, toluene, ethylbenzene, and xylenes), chlorinated solvents, TNT, nerve agents, blister agents, metal ions, anions, antigens, peptides, nucleic acids, spores, fungi, viruses, and bacteria.

Abstract: A method of laser forward transfer is disclosed. Photon energy is directed through a photon-transparent support and absorbed by a polymer interlayer coated thereon. The energized interlayer causes the transfer of a biological material coated thereon across a gap and onto a receiving substrate.

Abstract: A magnetic particle and fabrication method thereof. The magnetic particle comprises a polymer core, a magnetic material layer covering the polymer core, and a silicon containing layer covering the magnetic material layer. In addition, the magnetic particle may further comprise a coupling agent on the silicon containing layer, and an active molecule connected to the coupling agent. The magnetic particles provide controllable size, uniform diameter distribution, high magnetization, improved storage stability, and modified surface for targeting biomolecules for biomaterial separation and environmental analysis.

Abstract: An apparatus and method for real time, label-free imaging and quantitation of binding events at an array of positions are provided. Total internal reflection from a planar side wall of a well of a multiwell plate is used to create an evanescent field in the plane of a pattern of ligands immobilized on the wall. Embodiments include imaging and multiple analyte detection and quantitation of a single wall of a single well as well as the simultaneous imaging and multiple analyte detection and quantitation of a number of wells.

Abstract: Multiwell plates commonly used for immunoassay are increased in capacity and adapted for ease and speed of testing by forming a plurality of solid posts in each well of a plate. The posts and plate material and the dimensions of the posts are chosen to allow the immobilization of ligand patterns on an exterior wall of a post in a well and to permit a collimated beam of light directed to the post in a direction to achieve total internal reflection from a wall to generate an evanescent field in the plane of the ligands immobilized on the exterior wall of the post. The reflected light carries an image of localized intensity variations due to binding events between the ligand patterns and analytes in a sample introduced into a well. A cover plate seals the wells and provides for through holes for introducing sample material to the wells.

Abstract: A grating-based sensor is disclosed that has a grating structure constructed and designed for both evanescent resonance (ER) fluorescence detection and label-free detection applications. Some embodiments are disclosed which are optimized for ER detection in an air mode, in which the sample is dry. Other embodiments are optimized for ER detection in liquid mode, in which the sample is suspended in liquid medium such as water. One and two-dimensional gratings are also disclosed, including gratings characterized by unit cells with central posts, central holes, and two-level, two-dimensional gratings. A readout system for such sensors is also disclosed. One embodiment includes a first light source optimized for collecting label-free detection data, a second light source optimized for collecting ER fluorescence amplification data, and at least one detector. In one embodiment, the detector is an imaging system and includes a CCD camera for collecting both ER and label-free data.

Abstract: This invention involves the nano-structured support used for separation or/and analysis, especially the chip substrate, ELISA plate substrate, planar chromatography strip and chromatography gel. Besides, it involves the functionalized nano-structured support of high sensibility for separation or/and analysis, especially the analysis-chip, ELISA plate, planar chromatography reagent strip and chromatography gel. In addition, this invention also involves the nano-structured marking system for analysis. Moreover, it concerns the test kit; especially the chip kit, ELISA kit, and planar chromatography kit. What's more, this invention involves the preparing methods and the applications of all those mentioned above, especially the chip analysis, analyses with ELISA plate, planar chromatography strip and chromatography separation.

Abstract: Reagents are disclosed for use in assays for analytes. The reagents are dry assay reagents that may be readily reconstituted for use in the assays. The dry assay reagents comprise a solid support and one or more molecules of a receptor immobilized on the solid support. The receptor comprises one or more binding sites for a ligand. A portion of a total number of the binding sites is bound to a conjugate comprising the ligand linked to a specific binding pair member and a portion of the total number of the binding sites is free. In use in an assay, a combination is provided in an aqueous medium comprising the sample and reagents for detecting the analyte wherein at least one of the reagents comprises the dry assay reagent mentioned above. The combination is incubated under conditions for binding of the analyte to one or more of the reagents.

Abstract: The present invention relates to a system and a method for the immunological detection of several substances or a substance having several features in one step, the detection reaction being based on an immunological sandwich type method and being in particular characterized in that it can easily be carry out and is designed as a “one-pot method”, which means that all detection steps are carried out in one reaction batch without any wash steps and with only one addition of reagents.

Abstract: An optical waveguide type antibody chip includes a transparent substrate, an incident-side optical element and an emitting-side optical element placed at a distance from each other on a primary face of the substrate, a water repellent resin film formed on the primary face of the substrate including an optical waveguide layer formed between the optical elements, the water repellent resin film includes a reaction hole having exposed the optical waveguide layer on its bottom and a frame-shaped trench surrounding the reaction hole, a rectangular frame-shaped cell wall which is fixed in the trench of the water repellent resin film and which forms a cell capable of infusion and discharge of a specimen solution together with the reaction hole, and an antibody immobilization layer formed on the bottom of the reaction hole, the surface of the antibody immobilization layer being masked with at least a buffer agent and a salt.

Abstract: A blood crossmatching apparatus, kit and methods for testing the compatibility of mammals for blood transfusion. Particulate layers in the apparatus allow nonagglutinated red blood cells to permeate through, while agglutinated red blood cells cannot. The apparatus also has a density solution. The density solution separates white blood cells from red blood cells in the whole blood when centrifuged, without lysing the red blood cells. Thus, the apparatus can be used to test whole blood.

Abstract: A photosensitizer that is excitable via infrared radiation and is adapted to be used to treat a selected biological target. The photosensitizer comprises a core nanoparticle adapted to convert infrared radiation into a visible light emission, and a coating disposed about the core nanoparticle. The coating contains a light excitable agent that is adapted to be excited by the visible light emission from the core nanoparticle. The photosensitizer can be surface modified with an antibody to make the photosensitizer specific to the biological target that is to be treated. Such surface modified photosensitizer is introduced to the target site and irradiated with infrared radiation.

Abstract: Acoustic wave devices coated with a biolayer are described for the detection target bio-molecules. The acoustic wave device is connected in an oscillator circuit, and the frequency shift ?f resulting from a biomolecular event is recorded. Further described are the use of Rayleigh wave surface acoustic wave devices for vapor phase detection as well as quartz crystal microbalance devices for liquid phase measurements. A biofilm on the surface of the acoustic wave device comprises of a layer of antibodies raised against a specific target molecule or antigen. Signatures for detection events are presented in the form of frequency shifts ?f(t).

Abstract: An optically detectable analytical composition comprising a rare earth dopant, a carrier incorporating the rare earth dopant, and at least one of: a chemical linker suitable to bind to a biological binding agent and a biological binding agent is disclosed. Preferred embodiments include a glass micro bead carrier treated to attach a biological binding agent such as a protein, or a nucleic acid. The binding agent can bind to a target species in a sample and thereafter be used to determine the presence, concentration or absence of the target in the sample. The composition can be used in a number of different applications, such as to perform fragment analysis of DNA. The narrow bands emitted by rare earth dopants when excited, allows for a large number of such dopants to be incorporated into an individual carrier, allowing detailed characterisation of the sample to be conducted in a reduced number of sample test runs.

Abstract: A support carrying an immobilized selective binding substance, that the support surface has a polymer containing the structural unit represented by the following General Formula (1) in an amount of 10% or more with respect all monomer units, and a selective binding substance is immobilized on the support surface by binding to the carboxyl group formed thereon via a covalent bond: (in General Formula (1), R1, R2, and R3 each represent an alkyl or aryl group or a hydrogen atom.

Abstract: A grating-based sensor is disclosed that has a grating structure constructed and designed for both evanescent resonance (ER) fluorescence detection and label-free detection applications. One and two-dimensional gratings are also disclosed, including gratings characterized by unit cells with central posts, central holes, and two-level, two-dimensional gratings. A readout system for such sensors is also disclosed. Various applications for the biosensors are described, including cell-based assays for assessing the effect of drug compounds on cell function. A biosensor embodiment optimized for a luminescent response at two different wavelengths is also described. Such luminescent response could be produced by fluorescence (either native or from an attached fluorophore), phosphorescence, chemi-luminescence, or other luminescence technology. Two different luminescence technologies could be combined on the same biosensor chip.

Abstract: An acoustic wave sensor assembly includes piezoelectric material, a first acoustic wave resonator element structure mounted on the piezoelectric material for interacting with an electrical signal, the acoustic wave resonator element structure being operable to interact with an acoustic wave propagating within the piezoelectric material to produce a first frequency response. Further acoustic wave resonator element structures are mounted on the piezoelectric material for interacting with electrical signals, the further acoustic wave resonator element structures being operable to interact with further acoustic waves propagating within the piezoelectric material to produce subsequent frequency responses. The first acoustic wave resonator element structure and further acoustic wave resonator element structures are combined to form a ladder or lattice filter network to produce an overall frequency response.

Abstract: A non-linear optical material comprising a plurality of non-centrosymmetric nanoparticles juxtaposed to non-linear optical (NLO) film at a localized surface Plasmon resonance (LSPR) of the nanoparticles. The LSPR is resonant at a wavelength of an incident light source, wherein a second-order non-linear susceptibility (?(2)) of the NLO film with respect to the incident light is enhanced by the juxtaposition to the LSPR of the nanoparticles. The non-linear optical material lacks global inversion symmetry.

Abstract: Disclosed are devices for detecting the presence of a preselected analyte in a fluid sample. The devices comprise a substrate microfabricated to define a sample inlet port, and a mesoscale flow system that includes a sample flow channel extending from the inlet port. The mesoscale flow system further includes an analyte detection region in fluid communication with the flow channel comprised of a binding moiety for specifically binding the analyte. The detection region is constructed with a mesoscale dimension sufficiently small to enhance binding of the binding moiety and the analyte. The binding moiety may be immobilized in the detection region. The mesoscale detection systems of the invention may be used in a wide range of applications, including the detection of cells or macromolecules, or for monitoring reactions or cell culture growth.

Abstract: Methods for reducing time to result in blood bank diagnostic testing with an agitation device and a low ionic strength solution are disclosed. Specifically provided are methods for reducing incubation time for antigen-antibody reactions in an immunohematologic assay by subjecting the assay reactants to incubation with agitation and optionally additionally a low ionic strength diluent.

Abstract: The present invention is based on the realization that the bonds between a target molecule, or a target molecule attached to a particle, and a surface, can be ruptured by mechanically oscillating the surface at increasing amplitude, leading to detachment of the target molecule or particle from the surface. The required acceleration, and hence force, will depend on a variety of factors, including the mass of the molecule or particle, the nature of the bond to the surface and the geometric shape or size of the target molecule or particle. The present invention may therefore be used to separate or to size different target molecules, or to detect their presence.

Abstract: The invention provides an optical sensor for detecting chemical reaction activity, including, e.g., enzyme activity and catalytic or reactive molecule activity. An optical sensor of the invention includes a porous photonic film that produces a predetermined spectral reflectance response. In preferred embodiments, the film has a chemical coating (such as a hydrophobic layer) within its pores with an affinity for the reaction product(s) of the catalytic or otherwise reactive analyte A coating can also act as a protective layer in preferred embodiment. A thin substrate susceptible to reaction by at least one analyte of interest is on the surface of the thin film to block pores of the thin film. A method of detecting chemical reaction activity of the invention exposes the optical sensor to an analyte of interest, such as an enzyme or otherwise catalytic or reactive molecule.

Abstract: The invention relates to methods for the determination of pharmacological properties of substances, such as, e.g., chemical substances. The invention also relates to methods and kits for use in the determination of the free fraction, fu, of pharmacologically active compounds in aqueous solutions and serum. The invention also relates to the above methods in which solid particles, coated with a lipophilic medium, are used.

Abstract: Methods for forming cell arrays of multiple cell samples arranged substantially in a monolayer on a single substrate particularly suited for diagnostic analysis are disclosed. The cell arrays are formed with a high-speed dispensing apparatus capable of dispensing small volumes in precise, complex patterns. Also disclosed are substrates upon which cell arrays may be formed, and methods for conducting diagnostic analyses on the formed cell arrays.

Abstract: Disclosed is a diagnostic testing device that may be used to detect one or more analytes in a sample. The device comprises a receptacle and a holder for a test strip. The test strip may be, for example, a lateral flow test strip. The device and holder permit analysis of a sample, wherein the device is substantially sealed during testing and detection of results. To use, the holder containing a test strip is inserted into the receptacle containing sample to be analyzed. Capillary flow along the test strip is initiated by contact of the sample with the distal end of the test strip. The receptacle is such that results of the assay may be detected visually or using standard instrumentation such as by measuring light absorption or reflectance.

Abstract: A method and an apparatus for enumerating one or more specific elements within a biologic fluid sample are provided. An embodiment of the method includes the steps of: a) providing a chamber formed between a first planar member that is transparent and a second planar member, which members are separated from one another by a substantially uniform height; b) introducing the biologic fluid sample into the chamber, wherein the chamber height is sized such that the sample extends between the first and second members, and sized relative to the specific elements within the sample such that the specific elements non-uniformly distribute within the sample upon introduction into the chamber; c) examining substantially all of the sample within the chamber and enumerating all of at least one of the specific elements; d) determining the volume of sample contained within the chamber; and e) determining the number of the at least one of the specific elements per unit volume.

Abstract: Provided are a nanoparticle for detecting biomaterials and a biosensor by using the nanoparticle. The nanoparticle includes a metal nanostructure around which an electric field is induced by localized surface plasmon resonance when light is irradiated onto a surface of the metal nanostructure, a spacer covering the surface of the metal nanostructure, and capture molecules specifically reacting with fluorophore-labeled target molecules, and immobilized on a surface of the spacer.

Abstract: Disclosed is a system using a large area flat panel imager which is specifically adapted for rare cell detection methods. The system generally includes an imager having a sample receiving surface which can provide a digital or electronic image of a sample deposited on the surface. The system also includes a selectively positionable microscope and/or camera which are used to obtain high resolution images of the deposited samples. An electronic controller can also be used in conjunction with the imager, microscope, and/or camera to selectively position at least one of those components to focus on desired regions of the deposited sample. The noted system is particularly adapted for use with chemiluminescence or other tagging technologies.

Abstract: Methods for producing plasma-treated, functionalized inorganic oxide surfaces are provided. The methods include the steps of subjecting an oxide surface to a plasma to create hydroxyl functionalities on the surface and reacting the hydroxyl functionalities with epoxy group-containing molecules in situ in the absence of plasma. Biomolecules may be immobilized on the resulting functionalized surfaces. The methods may be used to treat a variety of oxide surfaces, including glass, quartz, silica and metal oxides.

Abstract: Method and apparatus which uses harmonic cantilevers, such as used in atomic force microscopy, to detect variations in the attractive and repulsive forces on a solid surface as a result of macromolecular binding, for example, hybridization of a single stranded DNA molecule attached to the surface with another DNA molecule. The complexed macromolecule is less flexible than an uncomplexed molecule. It will typically have more negative charge due to amino acids or DNA monomers. Both stiffness of the surface and the attractive capillary forces will change after binding and may be detected. By scanning the harmonic cantilever across a surface with macromolecules attached in tapping-mode and by recording the signals at the high frequency vibrations provided by harmonic cantilever, complexed molecules on a surface may be identified and quantified.

Abstract: The present invention provides methods for the identification and use of diagnostic markers for differential diagnosis of diseases. In a various aspects, the invention relates to methods and compositions able to determine the presence or absence of one, and preferably a plurality, of diseases that exhibit one or more similar or identical symptoms. Such methods and compositions can be used to provide assays and assay devices for use in determining the disease underlying one or more non-specific symptoms exhibited in a clinical setting.

Abstract: A method for patterning a one or more biomolecules on a substrate that includes coating the substrate with a coating of the one or more biomolecules, applying a laser to the coating, and ablating a portion of the one or more biomolecules with the laser in a predetermined pattern.

Abstract: A method for detecting binding of biological and/or chemical components of liquid or gaseous mixtures and solutions, which are of mainly biological origin and/or determine parameters of living activity of biological objects, to substances that bind said components due to a biological, chemical or physical interaction; and analysis of mixtures and solutions to determine presence of biological and/or chemical components. Binding substances are arranged on a surface of or inside a sensor layer, which changes its thickness due to the binding being detected; the layer is affected by light of different wavelengths; a signal due to interference on the sensor layer is registered in the reflected or transmitted light.

Abstract: The present invention relates to a method and a device for determining a concentration of a biological active substance in a sample by the means of an enzyme-linked immunosorbent assay (ELISA). The device comprises a solid support within a tubing for binding an immunosorbent and an inlet for fluids, a detector for detecting radiation due to an activity in the tubing, wherein the tubing is arranged inside a microchip extending substantially in one plane, for conducting the fluids along the plane of the microchip. The tubing forms a reaction cell having a large detection area. The reaction cell of the microchip is arranged perpendicular to the detector. The method comprises the steps of introducing the fluids into the tubing, conducting the fluids through the tubing forming a reaction cell, in which reaction cell the radiation emitting activity takes place, and detecting the light emitted from the reaction cell substantially perpendicular to the plane.

Abstract: Compositions and methods of modifying surfaces using hydroxyl terminated PEG are described herein. The surfaces so modified are useful in detection of synthetic and natural product organic molecules, organometallics, biomolecules, particles, or cells.

Abstract: The invention relates to a biochip comprising a substrate presenting a reflecting main surface and wherein the main surface presents localized sites that are made sensitive to fluorescence detection by a transparent layer having optical thickness (2k+1)?/4 where k is a positive or zero integer and where ? designates a wavelength lying between a wavelength ?0 at which fluorescence is excited and a wavelength ?1 at which fluorescence is emitted. The biochip can be manufactured by depositing a transparent layer of thickness m??/2 on a substrate and by making studs or wells of thickness (2k+1)?/4 in said layer to form said sensitive sites.

Abstract: It is intended to provide an analysis method for a biological sample with clinical significance, which is a system being simple to such an extent that it can be applied to a clinical field, and capable of capping a molecule ionization suppression in mass spectrometry. Mass spectrometry of a biological sample using immunoprecipitation, comprising the steps of: preparing a sample containing an objective biological molecule; concentrating the biological molecule in the sample by immunoprecipitation using an antibody-bound carrier or a carrier to which a molecule capable of specifically binding to an antibody is bound; washing an immunoprecipitate of the biological molecule by using an aqueous solution containing a charge neutralizing agent as a washing liquid; and detecting the biological molecule by subjecting the washed immunoprecipitate to mass spectrometry.

Abstract: A method for immobilizing amino-group containing molecules onto surfaces and devices having immobilized isocyanate-group containing molecules prepared by the method are disclosed. The method comprises reacting a surface (i.e., glass surface) having free hydroxyl groups with a silyl isocyanate derivatizing agent to provide immobilized reactive moieties, the agent having a formula: (R1O)(R2O)(R3O)Si—X—NCO wherein R1, R2 and R3 are independently represents C1-C6 alkyl, phenyl, or aryl substituted with one or more groups selected from the group consisting of C1-C6 alkyl and C1-C6 alkoxy; X represents linear or branched C1-C20 alkyl or aryl substituted with one or more groups selected from the group consisting of C1-C6 alkyl and C1-C6 alkoxy, optionally substituted with one or more heteroatoms comprising oxygen, nitrogen, and sulfur and reacting the immobilized reactive moieties with the amino group-containing molecule so as to immobilize said molecule on the surface.

Abstract: The present invention relates to a method of characterizing a surface and to a device for implementing this method. In particular, this method makes it possible to measure, qualitatively and/or quantitatively, interactions that may be physical, chemical, biochemical or biological.

Abstract: In a sensor device and a sensing method capable of simultaneously extracting plural pieces of information including information about the presence/absence, distribution, and so on, of targets, in case of measuring changes in nature of a detecting portion (11) upon coupling with targets (a and b), information about changes in quantities of the targets (a and b) with time is extracted in addition to information about the presence/absence, distribution, and so on, of the targets (a and b) from geometrical structures of the detecting portion (11), such as locations and/or shapes of bonding sites (A and B) for selectively coupling with the targets (a and b), respectively.

Abstract: Optical assay apparatus and methods are provided having an optical assay cup for detecting analytes in a sample fluid. The cup's sidewall may include an optical waveguide having a detection coating on its inner surface. During use, the waveguide receives evanescent or darkfield interrogation light, interrogates at least part of cup's interior volume with it, and emits signal light as a function of the analytes. The detection coating may have fluid or non-fluid detection layers, at least part of which may form at least part of a waveguide for the interrogation light. The cup may be spun during use, such as to centrifugally-concentrate any high-density analytes towards cup's sidewall. The assay apparatus may further include an interrogation light source, a cover or spinning apparatus for the cup, and an optical detector for the signal light.

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: The present invention relates to a systematic process for the creation of functionally organized, spatially patterned assemblies polymer-microparticle composites including the AC electric field-mediated assembly of patterned, self supporting organic (polymeric) films and organic (polymeric)-microparticle composite films of tailored composition and morphology; the present invention further relates to the incorporation of said assemblies into other structures. The present invention also relates to the application of such functional assemblies in materials science and biology. Additional areas of application include sensors, catalysts, membranes, micro-reactors, smart materials. Miniaturized format for generation of multifunctional thin films. Provides a simple set-up to synthesize thin films of tailored composition and morphology.

Abstract: A flow cell device is incorporated in the sensor unit for surface plasmon resonance (SPR) assay. A box shaped flow cell body has a lower surface, and is disposed in contact of the lower surface with a sensing surface for detecting reaction of sample. Two flow channels are formed in the flow cell body, for flow of the sample. Each of the flow channels include a fluid passageway, formed in the lower surface, for flow of the sample in contact with the sensing surface. Two end cavities are formed in an upper surface of the flow cell body and open therein, to extend from ends of the fluid passageway. The flow channels are arranged adjacent to one another, disposed to extend in a direction of the flow. Fluid passageways of the flow channels are overlapped partially on one another in a flow cell longitudinal direction of the flow cell body.

Abstract: The invention relates to a a microtiter plate and its use in a method of the invention, which microtiter plate comprises a plurality of containers, wherein the bottom of each container comprises a (semi-)permeable membrane capable of directly or indirectly binding an analyte, and wherein each container is separated from an adjacent container by a container dividing wall, wherein the containers are grouped in one or more clusters, each cluster comprising at least two containers, wherein said clusters are separated from adjacent clusters by a cluster dividing wall and wherein at least part of the container dividing wall is lower than the cluster dividing wall or wherein the container dividing wall contains at least one passageway connecting at least two adjacent containers within a cluster, said passageway being at a distance from the bottom of the container and at least partly below the top of the container.

Abstract: Malarial parasite Plasmodium falciparum is responsible for the most severe form of malaria in humans, causing about 2 million deaths every year. Lack of effective vaccines and emergence of drug-resistant strains necessitate the need of novel drug targets to treat the disease. The present invention describes a novel assay method of identifying candidate compounds as anti-malarials based on the property of binding to plasmodial parasite 90 kDa heat shock protein.

Abstract: An optical assay apparatus having an optical filter, an optical sensor with a light ray redirection portion and an assay sensing portion, and a filter to block certain wavelengths of excitation light rays and to pass certain wavelengths of signal recovery light rays from the optical sensor. A method for performing an assay that includes providing at least one assay station, moving the optical sensor into position over a respective fluid in at least one assay station, immersing the assay sensing portion in the respective fluid, and removing the assay sensing portion from the respective fluid.

Abstract: This invention discloses using SPR technology to simultaneously and qualitatively detect the presence of infectious agent related antibodies and/or antigens in a serum sample, which can be used to screen for infectious agents in blood. It also discloses an efficient formula to make a mixed SAM that can greatly enhance the immobilization ability of the metal surface in SPR based techniques, which is good for the immobilization of relevant antigens and antibodies used for the screening of infectious agents in blood.

Abstract: An infrared fluorescent particle comprising a functional group or a substance that is capable of binding to an analyte, wherein fluorescence at infrared wavelength is emitted from the particle upon exposure of the particle to excitation light at infrared wavelength. The infrared fluorescent particle of the present invention is capable of binding to the analyte. Due to a high penetration of the fluorescence and the excitation light into biological substances, the infrared fluorescent particle of the present invention can reduce an influence of luminescence, light absorption or light scattering which is occurred due to the analyte and the surrounding substances.