Mass Spectrometry has been widely used to identify microbes present in a sample. However, rapid analysis (e.g. 1-5 minutes) of spectral data to identify microbes has proven to be very challenging due to the high level of processing required and complexity associated with identification from a large pool of candidate microbes. Disclosed herein are methods and systems for rapidly identifying microbes present in a sample through the application of conditional likelihoods that certain proteoforms are particularly indicative of a candidate microbe.

A method of purification and/or separation of glycopeptides and quantitation of same. The method includes contacting a sample comprising glycopeptides to a hydrophilic enrichment substrate under conditions that permit the glycopeptides to bind to the hydrophilic enrichment substrate. The glycopeptides are eluted from the hydrophilic enrichment substrate with an ammonium formate and acetonitrile (ACN) in water solution to create an enriched glycopeptide sample, which may be subjected to analysis to identify specific glycopeptides.

A Liquid Chromatography Mass Spectrometry system comprises: a chromatograph; a mass spectrometer configured to ionize separated fractions of a sample received from the chromatograph; and a programmable processor operable to repeatedly execute the steps of: (i) causing the mass spectrometer to perform a data-independent analysis of the precursor ion species using a mass analyzer of the mass spectrometer; (ii) calculating one or more degree-of-matching scores that relate to detection of an internal standard; and (iii) if each of the degree-of-matching scores meets a respective degree-of-matching condition, performing a quantitative tandem mass spectrometric analyses of both the internal standard and the analyte; the programmable processor further operable to calculate a quantity of the analyte in the sample by comparison between intensities of one or more mass spectral signals generated by the quantitative tandem mass spectrometric analyses of the analyte and the internal standard.

Disclosed is a kit including an oral wash composition and post collection stabilization solution for collection of analyte in oral fluid sample. The oral wash optionally includes an internal tracer, agents to induce salivation, maintain oral wash integrity at room temperature, and stabilize the collected oral fluid, and one or more dyes. The post collection stabilization solution includes agents which maintain collected analyte integrity at room temperature. The oral wash is used to collect saliva from the oral cavity, to determine the presence of an analyte in the saliva. The method includes rinsing the oral cavity with the oral wash for a period of time effective to stimulate saliva production, collecting the resulting fluid, contacting the resulting fluid with the post collection stabilization solution and subjecting the resulting fluid to a suitable analytical method to detect the presence of analyte in the sample.

A method for analyzing a microorganism including an identification step for determining which of Abony and Pakistan which are two serotypes of Salmonella bacteria is contained in a sample which contains either Abony or Pakistan, based on the presence or absence of a peak (or peaks) at a predetermined mass-to-charge ratio (or ratios) in a mass spectrum obtained by a mass spectrometric analysis of the sample, or a method for analyzing a microorganism including an identification step for determining which of Minnesota, Infantis and Brandenburg which are three serotypes of Salmonella bacteria is contained in a sample which contains Minnesota, Infantis or Brandenburg, based on the presence or absence of a peak (or peaks) at a predetermined mass-to-charge ratio (or ratios) in a mass spectrum obtained by a mass spectrometric analysis of the sample, or a method for analyzing a microorganism including an identification step for determining which of Schwarzengrund and Montevideo which are two serotypes of Salmonella bacteria is contained in a sample which contains either Schwarzengrund or Montevideo, based on the presence or absence of a peak (or peaks) at a predetermined mass-to-charge ratio (or ratios) in a mass spectrum obtained by a mass spectrometric analysis of the sample.

This document relates to methods and materials for assessing radiation exposure. For example, methods and materials that can be used to determine whether a mammal (e.g., a human) has been exposed to radiation and/or whether a mammal (e.g., a human) is at risk of developing one or more radiation injuries (e.g., cutaneous radiation injury (CRI) and/or acute radiation syndrome (ARS)) following radiation exposure (e.g., radiation therapy) are provided.

A practical and effective method for low abundance host cell protein (HCP) identification and quantification, which facilitates the downstream purification process in eliminating potentially problematic HCPs. In particular, the method comprises performing a native digestion followed by characterization using Multiple Reaction Monitoring approach.

Particular disclosed embodiments disclosed herein concern using a one or more various mass tags, which can be specifically deposited at targets through direct or indirect enzymatic-catalyzed transformation, to provide a method for identifying targets in tissue samples. The mass tags may be labeled with stable isotopes to produce mass tags having the same chemical structure but different masses. Mass codes produced by ionizing the mass tags are detected and/or quantified using mass spectrometry. The method can be used for multiplexed detection of multiple targets in a particular sample. In some embodiments, a map divided into sections representing sections of the tissue sample may be prepared, with the map sections including data corresponding to quantification data wherein the size of a mass peak is determined and correlated with the amount of a target for the corresponding tissue sample section.

Methods are provided for determining the amount of an IGF-I and/or IGF-II protein in a sample using high resolution/high accuracy mass spectrometry. The methods generally comprise enriching an IGF-I and/or IGF-II protein in a sample, ionizing an IGF-I and/or IGF-II protein from the sample to generate IGF-I and/or IGF-II protein ions, and determining the amount of IGF-I and/or IGF-II protein ions with high resolution/high accuracy mass spectrometry.

The invention relates to the quantitative measurement of steroidal compounds by mass spectrometry. In a particular aspect, the invention relates to methods for quantitative measurement of steroidal compounds from multiple samples by mass spectrometry.