The invention proposes a methods and devices for tandem ion mobility spectrometry using at least one TIMS analyzers (TIMS=trapping ion mobility spectrometry), in particular in the field of structural biology.

Systems and methods are disclosed for determining if the dynamic range of quantitation in mass spectrometry can be extended. A DIA method is performed on a sample for a compound of interest at each acquisition time of a plurality of acquisition times. A plurality of product ion spectra are produced for each window of two or more precursor ion mass selection windows. A known product ion of the compound of interest is selected. Two or more XICs are calculated from two or more different precursor ion windows for the known product ion. A ratio of one XIC of the two or more XICs to at least one other XIC of the two or more XICs is calculated. If the ratio is above a threshold, the XIC is used in the quantitation. If not, two or more XICs can be combined into a single XIC that is used for the quantitation.

The present disclosure relates to novel and improved methods of analyzing proteins, peptides and polypeptides by mass spectrometry using ion-ion reactions. More specifically the disclosure relates to improved methods for implementing the m/z selective arresting of ion-ion reactions within the ion-ion reaction cell of a mass spectrometer system during a period where ion-ion reactions are performed.

A method and apparatus for analyzing samples using mass spectrometry are disclosed. The apparatus includes a reaction device configured to dissociate sample ions into fragments by reacting the sample ions with a charged species (e.g., electrons) such as through ECD, EID, or EIEIO. The kinetic energy of the charged species is such that the fragments may be detected and produce spectra that allow for the determination of isomeric species in the sample and the location of double bonds and/or the orientation of those double bonds within the sample molecules. The fragments may include radical fragments and non-radical fragments. Spectra resulting from analysis of the fragments may allow for the determination of the oxygen-radical fragments resulting from the dissociation of the sample molecules as confirmation of the presence of those radical fragments.

Calibration of a mass spectrometer is described. In one aspect, a mass spectrometer can generate an offset value indicative of the mass difference between the corrected and reference external calibrant ion data. By comparing the offset value to a threshold, a preliminary mass calibration can be modified, or a recalibration of the mass spectrometer is performed.

A method of mass spectrometry is disclosed comprising: performing a plurality of cycles of operation during a single experimental run, wherein each cycle comprises: mass selectively transmitting precursor ions of a single mass, or range of masses, through or out of a mass separator or mass filter at any given time, wherein the mass separator or mass filter is operated such that the single mass or range of masses transmitted therefrom is varied with time; operating the mass separator or filter in a wideband mode between at least some of said plurality of cycles, wherein in each wideband mode the mass separator or filter transmits ions in a non-mass resolving manner; and mass analysing ions.

A mass spectrometer is disclosed comprising a glow discharge device within the initial vacuum chamber of the mass spectrometer. The glow discharge device may comprise a tubular electrode located within an isolation valve, which is provided in the vacuum chamber. Reagent vapour may be provided through the tubular electrode, which is then subsequently ionised by the glow discharge. The resulting reagent ions may be used for Electron Transfer Dissociation of analyte ions generated by an atmospheric pressure ion source. Other embodiments are contemplated wherein the ions generated by the glow discharge device may be used to reduce the charge state of analyte ions by Proton Transfer Reaction or may act as lock mass or reference ions.

A method of screening or testing a sample is disclosed that comprises ionising a native human hemoglobin sample to generate parent or precursor ions, subjecting the parent or precursor ions to Electron Transfer Dissociation fragmentation so as to generate a plurality of fragment ions, mass analysing the fragment ions and determining whether or not the fragment ions include fragment ions which are indicative of a variant of hemoglobin.

A mass spectrometer is provided that includes a precursor ion candidate selector, a product ion scan measurement condition setter, a product ion spectral data obtainer, a compound database file generator, and an MRM measurement condition candidate generator. The precursor ion candidate selector selects precursor ion candidates from mass spectrometric data. The product ion scan measurement condition setter combines the precursor ion candidates with a plurality of candidate values of cleavage energy to set a product ion scan measurement condition. The product ion spectral data obtainer carries out MS/MS measurement to obtain product ion spectral data. The compound database file generator generates a compound database file in which the product ion scan measurement condition and the product ion spectral data are associated with each other.

A method for parallel accumulation and serial fragmentation of ions, wherein ions are injected into a device capable of serial ejection using a pseudopotential barrier created by an RF voltage. In all instances, the ions may be filtered prior to accumulation in the device capable of serial ejection. In some cases this filtering may take the form of discrete isolation windows using isolation waveforms with multiple notches. In some cases these waveforms may be applied to a quadrupole mass filter. Following accumulation of the precursor ions, the initial population may be serially ejected using a pseudopotential barrier created by an RF voltage. Following serial ejection, the individual precursor ion populations are analyzed. In some cases, this analysis might involve additional rounds of ion isolation and manipulation (e.g., MSn, CID, ETD, etc.).