Methods, devices, and systems are disclosed for performing high throughput analysis of conformational change in biological molecules or other biological entities using surface-selective nonlinear optical detection techniques.

Disclosed herein are isolated compositions including at least 2 of mutant peptides selected from the group consisting of SEQ ID NOS: 1-149, or polypeptides comprising the mutant peptides; wherein the composition comprises mutant peptides encoded by 2 or more genes. Also disclosed are methods for personalized treatment of breast cancer involving creating a peptide array of mutant peptides comprising the mutations in protein-encoding regions of the high-frequency cancer genes or the exome in a subject and screening the peptide array with a biological sample from the subject to detect antibodies in the biological sample that bind to the array, to detect antigenic targets for therapy in treating the subject.

The present invention provides novel fluorescent dyes and kits containing the same, which are useful for labeling a wide variety of biomolecules, cells and microorganisms. The present invention also provides various methods of using the fluorescent dyes for research and development, forensic identification, environmental studies, diagnosis, prognosis and/or treatment of disease conditions.

A biological sample processing apparatus having an enclosure. A plurality of sample processing modules are held by the enclosure. Each sample processing module is configured to hold a removable sample cartridge and to only perform sample processing on a sample within the corresponding removable sample cartridge. Each sample processing module is configured to perform at least one of a plurality of testing processes on the sample within the removable sample cartridge. At least one module in the apparatus is configured to perform nucleic acid amplification and detection.

The present invention relates to a method for screening a substance inhibiting protein-protein interactions, and more particularly to a method for screening a substance inhibiting protein-protein interactions, the method comprising using a protein chip having immobilized thereon spots comprising a mixture of a sol-gel material and a protein. According to the invention, a protein chip can be easily manufactured in a 96-well plate using a sol-gel material, whereby an inhibitor that inhibits protein-protein interactions can be easily screened from a library of natural substances.

The present disclosure relates to compositions and methodology for revealing binding sites between proteins, proteins and nucleic acids, or proteins and small molecules. The disclosure provides rapid and direct positive identification and sequencing of the contact region between such molecules, and can be applied to individual interacting pairs, as well as large-scale or global interactions.

Triazabutadiene molecules as cleavable cross-linkers adapted to cross-link components with click chemistry, e.g., clickable triazabutadienes. For example, in some embodiments, the triazabutadienes feature alkyne handles attached to the imidazole portion or the aryl portion of the triazabutadienes, wherein the alkyne handles can link to azide handles (e.g., azide handles disposed on other components) via click chemistry. Also described are methods of producing said clickable triazabutadienes and methods of use of said clickable triazabutadienes. The present invention also features methods of cleaving said clickable triazabutadienes, e.g., for liberating the diazonium species for further chemical reactions.

The present invention relates to a method of detecting one or more tissue-derived aggregated proteins in a biological sample.

The present invention relates to multiplex microarrays and methods for the quantification of analytes. In particular, the invention relates to improved methods which standardize a target analyte concentration in a test sample against a reference standardization curve derived from validated, approved and recognized reference standards for the target analyte of known concentrations. The present invention also relates to methods and checks for simultaneous measurement of confidence confirming normalization standards and controls.

The present invention provides kits and assay methods for the early detection of pathogens, precise identification of the etiologic agent, and improved disease surveillance. More specifically, the present invention discloses an immunoassay leading to the rapid and simultaneous detection of antibodies to a wide range of infectious pathogens in biological fluids of infected patients. This immunoassay involves the covalent and oriented coupling of fusion proteins comprising an AGT enzyme and a viral antigen on an identifiable solid support (e.g. fluorescent microspheres), said support being previously coated with an AGT substrate. This coupling is mediated by the irreversible reaction of the AGT enzyme on its substrate. The thus obtained antigen-coupled microspheres show enhanced capture of specific antibodies as compared to antigen-coupled microspheres produced by standard amine coupling procedures. The methods of the invention possess the ability to multiplex, minimize the amount of biological sample, and have enhanced sensitivity and specificity toward target antibodies as compared with classical ELISA or Radio-Immunoprecipitation assays.