A mass spectrometer support apparatus includes a peak shape logic to determine one or more peak shapes using a calibration mass spectrum and known peak locations; and a tuning logic to adjust instrument parameters to achieve a selected peak width. A method for tuning a quadrupole-based mass spectrometer includes determining one or more peak shapes using a calibration mass spectrum and known peak locations; and adjusting instrument parameters to achieve a selected peak width.

The present invention addresses ways to facilitate the detection and analysis of ion abundance, in particular for analysis of elemental ions, and in particular embodiments for isotope ratio analysis, by use of collision cells that employ an axial drag field, i.e. an axial electric field that exerts a drag force on ions within the cell. By means of the invention, the drag field allows an increase in the transmission in the case of Li from a few % up to almost 100%. The drag field is generated by electric fields and can be switched on and off within microsecond (μs) timescales and thus improves the sensitivity for the lighter elements dramatically. The invention allows use of collision cells for analysis of elemental ions in a simple and fast workflow with high throughput and without compromising transmission.

Method and kits for detecting cancer, and in particular breast cancer, in a subject by measuring the levels of at least one of a series of biomarkers, as compared to a control sample lacking cancer. The expression of the biomarker either increases or decreases in samples from subjects with cancer, as compared to the expression level in subjects without cancer. The sample is optimally an ocular sample, such as an isolated tear sample or ocular wash, but can also be from saliva, or other bodily fluid. Kits can include a collection tube and protease inhibitors or protein stabilizers.

A method for cleaning a first electrospray emitter of a mass spectrometer comprises: changing an operating mode of the first electrospray emitter from a stable jet mode of operation to a dripping or pulsating mode of operation by lowering a magnitude of a voltage applied between a counter electrode and the first electrospray emitter, |V.sub.1|; moving the first electrospray emitter from a first emitter position from which electrospray ions are delivered to a mass spectrometer inlet to a second emitter position and, simultaneously, moving a second electrospray emitter from a third emitter position to a fourth emitter position; causing a cleaning solvent to flow through the first electrospray emitter at least until a droplet of the cleaning solvent forms on an exterior surface of the first electrospray emitter while operating the electrospray emitter in the dripping mode of operation; and causing the droplet to dislodge from the emitter exterior.

A method of mass spectrometry is disclosed comprising: a) providing temporally separated precursor ions; b) mass analyzing separated precursor ions, and/or product ions derived therefrom, during a plurality of sequential acquisition periods, wherein the value of an operational parameter of the spectrometer is varied during the different acquisition periods; c) storing the spectral data obtained in each acquisition period along with its respective value of the operational parameter; d) interrogating the stored spectral data and determining which of the spectral data for a precursor ion or product ions meets a predetermined criterion, and determining the value of the operational parameter that provides this mass spectral data as a target operational parameter value; and e) mass analyzing again the precursor or product ions whilst the operational parameter is set to the target operational parameter value.

The invention relates to a method for the determination and visualization of the spatial distribution of tissue states of a tissue sample, wherein a mass/mobility map is acquired at each of a plurality of sample sites of the tissue sample, the signal heights at each sample site are determined at characteristic signal positions in the corresponding mass/mobility map, from which a tissue state for each sample site is calculated with the aid of a mathematical/statistical classification algorithm, and the spatial distribution of the tissue states calculated for the sample sites is represented graphically.

The present invention discloses a method for rapid on-site detection of fentanyl analogs using a miniature mass spectrometer, comprising the following steps: (1) selecting a spotting plate; (2) loading a sample: depositing the sample and 3-nitrobenzonitrile solution in acetonitrile on the spotting plate to form a crystalline mixture; (3) carrying out analysis and detection: setting the parameters of the miniature mass spectrometer, placing the crystalline mixture on the spotting plate in close proximity to the inlet of the miniature mass spectrometer, and facilitating the ionization of the crystalline mixture for the analysis and detection of fentanyl analogs. The method for rapid on-site detection of fentanyl analogs using a miniature mass spectrometer provided by the present invention requires no extraction solvent, no voltage, no laser, no gas, and the method is simple, rapid, and suitable for rapid on-site detection of fentanyl analogs.

Provided is a mass spectrometer including: an ion generation unit configured to provide an ion generation path; an ion selection unit configured to provide an ion selection path connected to the ion generation path; a reaction unit configured to provide a reaction path connected to the ion selection path; a second ion selection unit configured to provide a second ion selection path connected to the reaction path; and an ion detection unit coupled to the second ion selection unit. The ion selection path and the reaction path extend in a first direction, and the reaction unit includes: a reaction pipe extending in the first direction to define the reaction path; and a sample inflow pipe coupled to the reaction pipe. The sample inflow pipe provides a sample inflow path connected to the reaction path, and the sample inflow path includes an inclined path. The inclined path extends to form an acute angle (α) with respect to the first direction.

Systems and methods disclosed provide a laser-assisted micro-mass spectrometer, which can include a pulsed inlet, a multi-wavelength laser system, and a first mass spectrometer module including a plurality of first ionization sources. In an embodiment, the pulsed inlet can be configured to receive a neutral sample of analyte material and provide it to said first mass spectrometer module.

A portable ion mobility spectrometry apparatus (1) for detecting an aerosol and a method for using the apparatus. The apparatus comprises an ion mobility spectrometer (3); a portable power source (5) carried by the apparatus for providing power to the apparatus (1); an inlet (7) for collecting a flow of air to be tested by the spectrometer (3); a heater (4) configured to heat the air to be tested to vapourise an aerosol carried by the air and a controller (2) configured to control the spectrometer (3) to obtain samples from the heated air, wherein the controller is configured to increase a heat output from the heater (4) for a selected time period before obtaining samples from the heated air.