Methods and reagents for processing samples for fluorescence analysis. Processing methods include treating samples containing riboflavin to reduce riboflavin-dependent autofluorescence by adding riboflavin binding protein to the sample, irradiating the sample, or a combination thereof. Processing methods also include clarifying samples by coagulating, precipitating, and/or otherwise removing proteins and other components that interfere with fluorescence analysis without removing the analyte. Fluorescence analysis methods include fluorescence polarization analysis (FPA) and others. Reagents suitable for performing the disclosed methods are provided.

The claimed invention provides personalized glucose and insulin information to a user in need thereof. Non-invasive body fluid capture techniques utilize saliva to provide body levels of glucose and insulin as well as optional pharmaceutical ingestion coordinated over time. Saliva captured on cellulose strips are analyzed in real time using oxidation and aptamer conjugate hybridization together with traditional analytical chemistry techniques including liquid chromatography/mass spectrometry (LC/MS) and coordinated against time of pharmaceutical administration. By embracing the P4 (Participatory, Personalized, Predictive, and Preventive) health management method the patient can determine glucose and insulin related wellness levels and if a pharmaceutical is having the correct and desired effect for maximum therapeutic benefit.

Devices that include a low sensitivity bulk acoustic wave (BAW) resonator sensor including a surface to which a low recognition component is immobilized, the low recognition component being configured to selectively bind the analyte, an analyte molecule to which a tag is linked, or a tag, or any one of these molecules to which an amplification element-linked second recognition component is bound; a high sensitivity BAW resonator sensor including a surface to which a high recognition component is immobilized, the high recognition component being configured to selectively bind the analyte, an analyte molecule to which a tag is linked, or a tag, or any one of these molecules to which an amplification element-linked second recognition component is bound; one or more containers housing an amplification molecule, the amplification element-linked second recognition component, and optionally one or both of the tag and the analyte molecule.

The invention relates to methods for conducting binding assays in an assay device that includes one or more storage and use zone. The storage zones of the assay device are configured to house one or more reagents used in an assay conducted in the use zone of the device.

The purpose of the present invention is to provide an agglutination enhancer which shows superior agglutination enhancing effect to those of conventional immunoagglutination enhancers, and the present invention relates to an agglutination enhancer for an immunoagglutination measurement method which comprises a polymer having a monomer unit shown by the following general formula [1]: ##STR00001##
(Wherein R.sub.1 represents a hydrogen atom or a methyl group; R.sub.2 and R.sub.3 independently represent a methyl group or an ethyl group, respectively; X represents —NH— or an oxygen atom; n represents an integer of 1 to 6; and m represents an integer of 1 to 3), and an immunoagglutination measurement method in which, in the coexistence of the above-described agglutination enhancer for immunoagglutination measurement method, an antibody against analyte or an antigen for the analyte is brought into contact with the analyte to cause an antigen-antibody reaction.

The present disclosure provides compositions, methods, systems, and devices for polynucleotide processing and analyte characterization from a single cell. Such polynucleotide processing may be useful for a variety of applications, including cell lineage analysis. Cell lineage analysis may comprise the use of one or more lineage tracing nucleic acid molecules. The disclosed methods may comprise using a lineage tracing nucleic acid molecule to identify a biological particle with one or more progenitor cells.

This invention provides, and in certain specific but non-limiting aspects relates to: —assays that can be used to predict whether a given ISV will be subject to protein interference as described herein and/or give rise to an (aspecific) signal in such an assay (such as for example in an ADA immunoassay). Such predictive assays could for example be used to test whether a given ISV could have a tendency to give rise to such protein interference and/or such a signal; to select ISV's that are not or less prone to such protein interference or to giving such a signal; as an assay or test that can be used to test whether certain modification(s) to an ISV will (fully or partially) reduce its tendency to give rise to such interference or such a signal; and/or as an assay or test that can be used to guide modification or improvement of an ISV so as to reduce its tendency to give rise to such protein interference or signal; —methods for modifying and/or improving ISV's to as to remove or reduce their tendency to give rise to such protein interference or such a signal; —modifications that can be introduced into an ISV that remove or reduce its tendency to give rise to such protein interference or such a signal; —ISV's that have been specifically selected (for example, using the assay(s) described herein) to have no or low(er)/reduced tendency to give rise to such protein interference or such a signal; —modified and/or improved ISV's that have no or a low(er)/reduced tendency to give rise to such protein interference or such a signal.

The present invention relates to systems and methods that utilize a combination of immunoassay and magnetic immunoassay techniques to detect an analyte within an extended range of specified concentrations. In particular, a device includes a housing, a heterogeneous surface capture immunosensor within the housing and configured to generate a first signal indicative of the concentration of the analyte in an upper concentration range, and a homogeneous magnetic bead capture immunosensor within the housing and configured to generate a second signal indicative of the concentration of the analyte in a lower concentration range.

This application relates to assays, devices, and methods for conducting highly sensitive assays that employ two binding agents and are useful in detecting specific targets such as antigens. These devices and methods provide the ability to detect minute amounts of the specific target with reduced risk of false positive results.

A method for measuring TAT complexes in a sample separated from a living body includes measuring TAT by performing latex immunoagglutination reaction under a condition of pH 5.8 to 6.6 using a TAT assay reagent. The TAT assay reagent includes a first antibody bound to a first latex particle, which binds to the antithrombin part of the TAT complex and recognizes the complex, and a second antibody bound to a second latex particle, which binds to the thrombin part of the TAT complex and recognizes the complex.