Non-limiting embodiments of methodologies for preparing diagnostic assay(s) calibrator(s), calibration material(s), and/or control(s), as well as kits, devices, and method(s) of calibration related thereto.

Non-limiting embodiments of a modified devices that comprise at least one dye for determining whether results obtained from the conductance of at least one diagnostic assay are biased, as well as kits and methods of use related thereto.

The present invention relates to a method for predicting the prognosis of ischemic disease using an AGE-RAGE-based biomarker. The biomarker can be used as an indicator factor of the clinical severity of ischemic disease, can maximize the efficiency of stem-cell treatment by determination of the optimal timing of the stem-cell treatment on the basis of changes in the biomarker according to the severity of ischemic disease, and can also be used as a useful indicator factor for verifying efficacy after the stem-cell treatment.

The invention relates to new antibodies against specific glycosylation sites within the ApoJ protein as well as their application thereof in the diagnosis and prognosis of ischemia and the determination of the risk of a recurrent ischemic event.

Disclosed is a method for detecting a target substance, comprising: forming on a carrier a complex comprising Wisteria floribunda lectin (WFA) and a target substance by mixing the WFA immobilized on the carrier with the target substance comprising a sugar chain that binds to the WFA in the presence of an alcohol having 1 to 7 carbon atoms consisting of carbon atoms, hydrogen atoms, and oxygen atoms; and detecting the target substance by detecting the complex.

An object of the present invention is to provide a measurement method and a reagent for measurement which can measure LRG in a biological sample simply in a short time. The present inventors have intensively studied to achieve the object and made findings that LRG in a biological sample can be measured simply in a short time by an immunoagglutination measurement method in which the biological sample is brought into contact with insoluble carrier particles carrying a first anti-LRG monoclonal antibody and insoluble carrier particles carrying a second anti-LRG monoclonal antibody in a liquid phase, and the invention has been thus completed.

Methods of analyzing glycosylated biomolecules include the steps of producing a deglycosylation mixture of biomolecules deglycosylated by natural or synthetic enzymatic or chemical techniques; providing a reagent solution having a labeling reagent in a polar aprotic, non-nucleophilic organic solvent; and mixing the deglycosylation mixture with the reagent solution in an excess of labeling reagent to produce derivatized glycosylamines. The method steps can be carried out purposefully without depletion of protein matter. A quenching solution can be added to the reaction mixture so that the pH of the reaction mixture is shifted to above 10. The yield of derivatized glycosylamines can be in an amount of about 80 to about 100 mole percent of the reaction mixture with minimal overlabeling, less than 0.2 mole percent. The derivizated glycosylamines can be separated from the reaction mixture and detected by chromatographic detection, fluorescence detection, mass spectrometry (“MS”), or Ultra Violet (“UV”) detection and/or a combination thereof.

Embodiments described herein generally relate to technologies for analyzing peptide structures for diagnosing and/or treating a disease state advancing through a disease progression. A non-limiting example of a method relating to the technologies described in the subject application may include receiving peptide structure data corresponding to the biological sample obtained from the subject, identifying a peptide structure profile, and diagnosing a disease state within a disease progression. The example may further include generating a diagnosis output relating to the disease state. In at least some cases, the peptide structure profile may include glycosylated peptides, aglycosylated peptides, or both.

The present invention provides glycated Amadori products of the CD59 peptide and fragments thereof to be used as tools and among methods for the diagnosis and prognosis of pre-diabetes and diabetes. Certain aspects of the invention include glycated Amadori products of CD59 and fragments thereof to be used for the generation of antibodies and antibody fragments. Still other aspects of the invention include methodologies for the preparation of glycated Amadori products of CD59, fragments thereof, the inventive antibodies, and antibody fragments.

Non-limiting embodiments of methodologies for preparing diagnostic assay(s) calibrator(s), calibration material(s), and/or control(s), as well as kits, devices, and method(s) of calibration related thereto.