Systems and methods are provided for identifying missing product ions after demultiplexing product ion spectra produced by overlapping precursor ion transmission windows in sequential windowed acquisition tandem mass spectrometry. Overlapping sequential windowed acquisition is performed on a sample. A first precursor mass window and the corresponding first product ion spectrum are selected from a plurality of overlapping stepped precursor mass windows and their corresponding product ion spectra. A product ion spectrum is demultiplexed for each overlapped portion of the first precursor mass window producing two or more demultiplexed first product ion spectra for the first precursor mass window. The two or more demultiplexed first product ion spectra are added together producing a reconstructed summed demultiplexed first product ion spectrum. Missing product ions are identified in the summed demultiplexed first product ion spectrum by comparing the summed demultiplexed first product ion spectrum and the first product ion spectrum.

A method is provided for detecting a polypeptide of interest in a plant without the use of a reference standard. The method comprises the steps of obtaining a plant expressing the polypeptide of interest and a negative control plant that does not express the polypeptide of interest, and analyzing a sample from each in an information-dependent acquisition (IDA) method. A method is also provided for determining the relative expression level of a polypeptide of interest in a plurality of plants without the use of a reference standard. This method comprises the steps of obtaining a plurality of plants expressing the polypeptide of interest and a negative control plant that does not express the polypeptide of interest, analyzing samples from each in an IDA method, and determining the relative expression level of the polypeptide in each of the plurality of plants.

An object of the invention is to provide a mass spectrometry apparatus capable of obtaining a highly accurate quantitative result and being low-cost. A small section measurement instruction unit 101 instructs a detector 9 to perform measurement on a plurality of small sections 5 in a channel 4, the signals detected by the detector 9 are stored in a data storage unit 102, the signals are integrated by a small section signal amount integration unit 103, and variance of the integrated signals is calculated by a signal variance calculation unit 104. A signal variance evaluation unit 105 evaluates the signal variance of signals of each small section 5 in the same channel 4. When the signal variance is evaluated to be stable, an operation control unit 106 controls operations of the ion source 6 to continue measurement without warning. When the signal variance is evaluated to be unstable, the warning is performed during the measurement or after the measurement.

Systems and methods are provided for maximizing the data acquired from a sample in a mass spectrometry imaging experiment. An ion source device is instructed to produce and transmit to a tandem mass spectrometer a plurality of ions for each location of two or more locations of a sample. A mass range is divided into two or more mass window widths. For each location of the two or more locations, the tandem mass spectrometer is instructed to fragment the plurality of ions received for each location using each mass window width of the two or more mass window widths and to analyze resulting product ions. A product ion spectrum is produced for each mass window width, and a plurality of product ion spectra are produced for each location of the two or more locations.

Systems and methods are provided for shaping an effective transmission window used to select precursor ions for a precursor mass range of a sequential windowed acquisition experiment. For at least one precursor mass range, an ion transfer function is selected that is a function of mass using a processor. A quadrupole mass filter that transmits ions from a sample is instructed to produce two or more transmission windows over time using the processor. The two or more transmission windows are produced to cumulatively create an effective transmission window for the at least one precursor mass range with a shape described by the ion transfer function.

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.

A phosphoprotein extraction method and a mass spectrometric method using a microbore hollow fiber enzymatic reactor (mHFER) based antigen-antibody reaction and, specifically, to an extraction method and a mass spectrometric method, wherein phosphoproteins or phosphopeptides present in the body are extracted using phosphoserine-, phosphothreonine-, and phosphotyrosine-antibodies, and measured by a mass spectrometer, and thus biomarker phosphoproteins for diagnosis of diseases are found, contributing to early diagnosis of diseases. The mass spectrometric method using the antigen-antibody reaction based extraction method can: minimize temporal and economic burdens resulting from a low extraction rate and a complicated sample pre-treatment; increase the extraction efficiency by using a considerable number of phosphopeptides (or phosphoproteins) and antibodies with strong affinity; and allow the extraction of low-concentration phosphopeptides or phosphoproteins, and thus is expected to have high applicability in discovering disease diagnosis protein markers and identifying and studying mechanisms thereof.

The present invention provides a method for acquiring fragment ion mass spectra with a time-of-flight mass spectrometer, whereby mixed mass spectra with fragment ions of different parent ion species are acquired and compared with each other in such a way that the signals of those fragment ions which originate from the same parent ion species are determined. The time-of-flight mass spectrometer contains an ion source, a flight path, a reflector and an ion detector. The flight path is preferably field-free and is positioned before the reflector, and the reflector preferably has a quadratically increasing reflection potential.

A method of mass spectrometry is disclosed comprising performing a plurality of experimental runs, wherein each experimental run comprises: periodically mass analysing fragment or product ions at a plurality of time intervals, wherein a delay time is provided between the start of the experimental nm and the first time interval at which the fragment or product ions are mass analysed. Different delay times are provided in different ones of the experimental runs and fragment or product ions that have been analysed in the same time interval in at least one of said experimental runs and that have been analysed in different time intervals in at least one other of said experimental runs are identified as fragment or product ions of interest. These fragment or product ions are thus determined to relate to different precursor ions and are used to identify their respective precursor ions.

A method of controlling the operation of an ion mobility separation device is disclosed. The method comprises displaying to a user via a user interface a pool of modes of operation of the ion mobility separation device, wherein each one of the modes is selectable by the user for inclusion in an experiment, and the modes are displayed in a first area 202 of the user interface. The method comprises receiving, via the user interface, an indication from the user of a selection of one or more instance of each one of a plurality of the modes from the pool to be included in an experiment, and an indication from the user of a set of one or more parameters for controlling the ion mobility separation device in respect of one or more selected instances of a mode. The selected instances of modes are displayed in a sequence in a second area 204 of the user interface. The operation of the ion mobility separation device is controlled in accordance with the received indications.