Bead-based analytical assays suitable for detecting changes in the abundance of target analytes in biological samples are disclosed. In an embodiment, an assay involves incubating a sample with one or several beads that are capable of binding several distinct analytes in an amount sufficient for detection by mass spectrometry from a single bead.

Disclosed are methods of quantifying multiple quality attributes, such as post translational modifications, of multiple samples in a single mass spectrometry (MS) run, including contacting two or more samples with a digesting solution under conditions sufficient to digest samples, wherein each sample is digested separately and the digesting solution is a Tris-free buffer solution; contacting each of the two or more digested samples with a specific Tandem Mass Tag (TMT) labeling reagent under conditions sufficient to label peptides within each of the digested samples with the specific TMT labeling reagent; quenching labeling of peptides within each of the two or more digested samples; combining equal volumes of the two or more labeled, digested samples into a single combined sample solution; and analyzing the single combined sample solution by targeted mass spectral analysis, thereby allowing multiple quality attributes of the two or more samples to be quantified in a single mass spectrometry (MS) run.

The present systems and methods are directed to de novo identification of peptide sequences from tandem mass spectrometry data. The systems and methods uses unconverted mass spectrometry data from which features are extracted. Using unconverted mass spectrometry data reduces the loss of information and provides more accurate sequencing of peptides. The systems and methods combine deep learning and neural networks to sequencing of peptides.

The disclosure provides methods and kits for preparing a protein analyte for characterization. The method comprises pretreating a protein analyte in the presence of a magnetic bead in a changing magnetic field; and enzymatically digesting the protein analyte with an endopeptidase enzyme to provide a plurality of peptides for analysis by, for example, LC-MS/MS. The process can be performed in a single tube without the need for desalting or buffer exchange, in less than 2 hours.

The present invention relates to methods and products associated with in vivo enzyme profiling. In particular, the invention relates to methods of in vivo processing of exogenous molecules followed by detection of signature molecules as representative of the presence of active enzymes associated with diseases or conditions. The invention also relates to products, kits, and databases for use in the methods of the invention.

An integrated sample processing system including an analyzer and a mass spectrometer is disclosed. The integrated sample processing system can perform multiple different types of detection, thereby providing improved flexibility and better accuracy in processing samples. The detection systems in the sample processing system may include an optical detection system and a mass spectrometer.

Systems, architectures, devices, and methods for matching experimentally acquired mass spectrometry data with a peptide database are provided. The system architecture can include a host central processing unit (CPU) system, a bridge connecting the CPU system with a core control register (or registers), a plurality of processing elements (PEs), and a bus arbiter. The PEs can execute the computations in a parallel and asynchronous manner. The bus arbiter can be a first-come first-serve (FCFS)-based bus arbiter (i.e., can utilize an FCFS-based arbitration scheme).

The invention relates to a method for the preparation of living, microbial samples and microorganisms for subsequent mass spectrometric measurement and evaluation. Findings which can be derived from such a measurement can particularly serve the faster identification of microorganisms in the microbial sample according to species/subspecies and/or the fast determination of resistance/sensitivity of the microorganisms to antimicrobial substances and/or the further characterization of microorganisms, for example in respect of pathogenicity, virulence and metabolism. According to a preferred embodiment of the invention, the preparation particularly takes place directly on a mass spectrometric sample support.

The present disclosure is directed at an antibody conjugate having an antibody and a tag, wherein one or more element(s) present in the antibody exhibit an isotope ratio which differs from the naturally occurring isotope ratio of the one or more element(s), wherein the amount of the isotope which is less-common in nature, is increased to at least 4% of the atoms of the respective element in the antibody, as well as uses thereof.

The disclosed methods are directed to detecting polypeptide fragments (“clips”) of parental polypeptides. Parental polypeptides and clips are optionally denatured and then fractionated using a matrix. After a first elution (high molecular weight fraction), an additional elution step retrieves a low molecular weight fraction containing clips. If the clips are an appropriate size for the targeted detection method, such as mass spectrometry, then analysis of this fraction proceeds separately from the high molecular weight fraction, or the clips fraction is mixed with the proteolyzed high molecular weight fraction before analysis. However, if the clips are too large for the intended analytical method(s), then the clips are also proteolyzed. The digested high molecular weight and low molecular weight fractions can be analyzed separately or combined. Analysis of combined samples favors clip quantitation because the clips are analyzed together with the remaining counterpart of the parental polypeptide.