The invention provides a mass spectrometry analysis method and a mass spectrometry system. During implementation of the mass spectrometry analysis method, intensity data of the daughter ions, a first parameter of the daughter ions associated with the first physicochemical property, and a second parameter of the daughter ions associated with the second physicochemical property are all recorded to form a spectrogram data set. In a deconvolution step, the spectrogram data set is deconvoluted to categorize the daughter ions from the same parent ion according to two-dimensional features including the first parameter and the second parameter. In the above manner, the mass spectrometry analysis method and the mass spectrometry system provided by the invention can detect ions that partially overlap spectral peaks of other ions significantly, thereby improving the qualitative and quantitative ability of data analysis for data independent acquisition.

An apparatus is disclosed including a tool comprising a first device for generating aerosol from a target, the first device being deployed through an opening in a tubing of the tool, wherein the tubing is provided with aspiration ports or fenestrations such that the generated aerosol is aspirated into the tubing via the aspiration ports or fenestrations. The aspirated aerosol is then transferred to a mass spectrometer for subsequent mass analysis.

In a method for analyzing a microorganism using a matrix assisted laser desorption/ionization mass spectrometer, a matrix-and-additive mixture solution prepared by mixing one or both of an alkylphosphonic acid and a surfactant with a matrix substance is used for matrix assisted laser desorption/ionization. Either an alkylphosphonic acid or a surfactant, or both of them are used as matrix additives and are mixed with the matrix substance beforehand to prepare a matrix-and-additive mixture solution. After a solution which contains a microorganism to be analyzed has been dropped onto a sample plate, the matrix-and-additive mixture solution is dropped onto that solution and dried to form a mixed crystal which contains both the constituents of the microorganism and the matrix substance. This crystal is used as a sample for MALDI-MS analysis. The sensitivity of analysis is thereby improved, without increasing the amount of time and labor required for sample preparation.

Systems and methods are used to analyze a sample using variable mass selection window widths. A tandem mass spectrometer is instructed to perform at least two fragmentation scans of a sample with different mass selection window widths using a processor. The tandem mass spectrometer includes a mass analyzer that allows variable mass selection window widths. The selection of the different mass selection window widths can be based on one or more properties of sample compounds. The properties may include a sample compound molecular weight distribution that is calculated from a molecular weight distribution of expected compounds or is determined from a list of molecular weights for one or more known compounds. The tandem mass spectrometer can also be instructed to perform an analysis of the sample before instructing the tandem mass spectrometer to perform the at least two fragmentation scans of the sample.

The invention relates to the detection of fatty acids. In a particular aspect, the invention relates to methods for detecting very long chain fatty acids and branched chain fatty acids by mass spectrometry.

A method is disclosed comprising obtaining or acquiring chemical or other non-mass spectrometric data from one or more regions of a target (2) using a chemical sensor (20). The chemical or other non-mass spectrometric data may be used to determine one or more regions of interest of the target (2). An ambient ionisation ion source 1 may then be used to generate aerosol, smoke or vapour (5) from one or more regions of the target (2).

A miniature electrode apparatus is disclosed for trapping charged particles, the apparatus includes, along a longitudinal direction, a first end cap electrode, a central electrode having an aperture, and a second end cap electrode. The aperture is elongated in the lateral plane and extends through the central electrode along the longitudinal direction and the central electrode surrounds the aperture in a lateral plane perpendicular to the longitudinal direction to define a transverse cavity for trapping charged particles. Electric fields can be applied in a y-direction of the lateral plane across one or more planes perpendicular to the longitudinal axis to translocate and/or manipulate ion trajectories.

A precursor ion selection processing unit (22) sequentially selects precursor ions having different mass-to-charge ratios, and causes an MS/MS spectrum data acquisition processing unit (23) to acquire MS/MS spectrum data corresponding to each precursor ion. The precursor ion selection processing unit (22) sequentially selects the precursor ion having a mass-to-charge ratio which is not included in a predetermined range with respect to a mass-to-charge ratio of the precursor ion for which the MS/MS spectrum data has already been acquired.

In one aspect, a method for detecting the labelling state of unknown species of molecules M contained in a sample exposed to a non-changing isotope labelling process using mass spectrometry is described.

An analysis method includes: subjecting a sample to liquid chromatography; performing first mass spectrometry of the sample subjected to the liquid chromatography to detect a first ion corresponding to cholesteryl ester and a second ion corresponding to cholesteryl ester peroxide; and analyzing a degree of oxidation of the sample based on a ratio between an intensity of the detected first ion and an intensity of the detected second ion.