Patent Description:
An improvement on this approach was disclosed in <CIT> (Micromass), wherein precursor ions are not isolated and selected but fragment ions are assigned to parent ions by correlating their detection times to the times as which the parent species eluted from the chromatography column. This technique improves the duty cycle of the instrument and minimises biased acquisitions. However, the technique suffers from specificity limitations since at the point of fragmentation the parent ions are only separated from each other by chromatography.

<CIT> discloses a method and apparatus for acquiring time profiles of ion intensities of product ions in a mass spectrometer comprising an ion trap, a fragmentation module and a mass analyser. Precursor ions are ejected from the ion trap in order of m/z ratio, but space-charge effects may result in multiple different masses being ejected at the same time. <CIT> proposes recording and comparing time profiles of fragment and precursor ions to allow matching fragment ions with their respective precursor ions even when precursor ions of different masses are ejected at the same time.

A known mode of operation of a quadrupole-Time of Flight mass spectrometer is to operate the quadrupole mass filter in a low resolution mode with a transmission window of, for example, <NUM> Da. The mass to charge ratio range of the ions transmitted by the quadrupole mass filter is then sequentially incremented in steps of approximately <NUM> Da and in a manner that is not data dependent. Ions exiting the quadrupole mass filter are accelerated into a gas cell and the resulting fragment ions are mass analysed by the Time of Flight mass analyser. The data from each <NUM> Da window is kept separate for processing. This technique is un-biased in the nature of the acquisition and has an improved duty cycle over devices operating with narrower mass to charge ratio isolation windows. However, the technique has limited precursor ion specificity because any given fragment ion may belong to any of the precursor ions transmitted within a <NUM> Da window.

It is therefore desired to provide and improved method of mass spectrometry and an improved mass spectrometer.

The present invention provides a method of mass spectrometry according to claim <NUM>.

The present invention uses data determined from the analysis of fragment or product ions in order to determine the mass to charge ratios of precursor ions transmitted by the mass analyser. As such, the mass to charge ratios of the precursor ions can be determined with relatively high specificity even when a relatively low resolution precursor ion mass analyser is used. As the technique enables a relatively low resolution mass analyser to be used, mass filter mass analysers may be used whilst still maintaining a relatively high duty cycle. In particular, the duty cycle of the mass spectrometer may be improved since the low resolution mass filter rejects fewer precursor ions at any given time.

Preferably, the mass to charge ratios of precursor ions transmitted by the mass analyser is scanned or stepped with time according to a scan function. The scan function and said time periods at which the precursor ion was transmitted may then be used to determine the mass to charge ratio of said precursor ion.

Although methods are described herein for determining mass to charge ratios of two precursor ions from fragment ion data, it is contemplated that the mass to charge ratios of third, fourth, fifth, sixth and further precursor ions may be determined from their fragment ion data by corresponding techniques to those discussed herein.

The time period over which the first fragment or product ion is detected only partially overlaps with the time period over which the second fragment or product ion is detected. This indicates that the time period over which the mass analyser transmits the precursor ions of the first fragment or product ions overlaps with the time period over which the mass analyser transmits the precursor ions of the second fragment or product ions. Although it may not be possible to resolve these precursor ions if the precursor ions leaving the mass analyser where detected directly, the precursor ions are able to be resolved by using data relating to the times at which their fragment or product ions are detected.

The method may further comprise determining that at least one additional fragment or product ion is detected over the same time period which the first fragment or product ion is detected before using the time period of the first fragment or product ion to determine the start and end times at which a precursor ion of the first fragment or product ion is transmitted by the mass analyser. The method may additionally comprise determining that at least one additional fragment or product ion is detected over the same time period which the second fragment or product ion is detected before using the time period of the second fragment or product ion to determine the time period over which a precursor ion of the second fragment or product ion is transmitted by the mass analyser. These additional fragment or product ions can be determined as being fragment or product ions that have been detected as having a different mass to charge ratio to the first and/or second fragment or product ions.

The method preferably comprises using the start and end times of the time period over which the precursor ion of the first fragment or product ion is transmitted by the mass analyser to determine first lower and upper mass to charge ratio limits for this precursor ion. Additionally, or alternatively, the method may comprise using the start and end times at which the precursor ion of the second fragment or product ion is transmitted by the mass analyser to determine second lower and upper mass to charge ratio limits for this precursor ion.

A mass to charge ratio centroid value may be determined for the precursor ion of the first fragment or product ion from the first lower and upper mass to charge ratio limits. Alternatively, or additionally, a mass to charge ratio centroid value may be determined for the precursor ion of the first fragment or product ion from the second lower and upper mass to charge ratio limits.

The method may comprise identifying the precursor ions from the mass to charge ratios determined for the precursor ions.

The method may comprise identifying the fragment or product ions from the mass to charge ratios determined for the fragment or product ions. The technique of the present invention may be used to correlate the fragment or product ions to their respective precursor ions. This may be used to identify the precursor ions.

The method may comprise continuously or repeatedly fragmenting precursor ions in the fragmentation or reaction device so as to produce the fragment or product ions; and continuously or repeatedly mass analysing the fragment or product ions.

The start and end times at which the first fragment or product ion is detected may be substantially the same as the start and end times at which the precursor ion of the first fragment or product ion is transmitted by the mass analyser. Similarly, the start and end times at which the second fragment or product ion is detected may be substantially the same as the start and end times at which the precursor ion of the second fragment or product ion is transmitted by the mass analyser.

Preferably, the mass to charge ratios of the precursor ions transmitted into the fragmentation or reaction device is scanned continuously with time or stepped with time.

The precursor ions are preferably transmitted to the fragmentation or reaction device by a low resolution mass analyser and the fragment or product ions are preferably mass analysed by a high resolution mass analyser.

The mass analyser that transmits the precursor ions to the fragmentation or reaction device is a mass filter. The mass analyser may be a quadrupole mass filter or another multipole mass filter. Alternatively, other types of mass may be employed.

Preferably, the mass analyser for mass analysing the fragment or product ions is a time of flight mass analyser. However, it is contemplated that other relatively high resolution mass analysers may be used to analyse the fragment or product ions.

The method may be operated in a second mode of operation, wherein one or more scans is performed in which precursor ions are detected rather than being fragmented. These unfragmented precursor ions may be used to calibrate the scan of the mass analyser that mass selectively transmits precursor ions into the fragmentation or reaction device. Alternatively, the unfragmented precursor ions may be used to determine better mass accuracies of the precursor ions than the mass analyser.

Fragment ion data from multiple separate acquisitions or experimental runs may be combined in order to determine the mass to charge ratios of the precursor ions.

An ion mobility separator may be provided upstream or downstream of the mass analyser for mass selectively transmitting the precursor ions. The mass scan function of the mass analyser may be synchronised with the ion mobility cycle time, e.g. so that the mass analyser is scanned once for each ion mobility cycle.

An ion mobility separator may be provided upstream or downstream of the mass analyser for mass selectively transmitting the precursor ions. The mass analyser has a mass transmission window that is varied with time. The rate of scanning of the mass transmission window may be chosen so as to allow multiple ion mobility separator experiments for each precursor ion transmission window time. As such, an MS-IMS-MS nested data set may be provided.

The mass analyser for analysing the fragment or product ions may be a Time-of-Flight mass analyser and the method may operated in conjunction with established Time-of-Flight modes such as Enhanced Duty Cycle (EDC).

It is contemplated that the precursor ions may themselves be fragment ions.

The fragmentation or reaction device may be a gas cell into which the precursor ions are accelerated, or within which the precursor ions are accelerated, in order to fragment or react the ions to produce fragment or product ions. The present invention also contemplates other fragmentation or reaction methods such as, for example, electron transfer dissociation (ETD), electron capture dissociation (ECD) or surface induced dissociation (SID).

An ion trap that mass selectively releases precursor ions may be provided upstream of the mass analyser that mass selectively transmits the precursor ions. The scanning of the mass analyser may be synchronised with the mass to charge ratios of the precursor ions released from the ion trap. This arrangement increases the scanning duty cycle. The ion trap may be a poor resolution ion trap.

It is contemplated herein that the time is takes the scanned mass analyser of the precursor ions to perform an analytical cycle may be varied, and that the fragmentation energy may be varied as a function of the time is takes the scanned mass analyser of the precursor ions to perform an analytical cycle.

The device may be operated in a precursor ion discovery or neutral loss type mode, wherein the Time of Flight performance is optimised for a particular fragment ion or group of fragment ions. The chosen fragment ions maybe varied as a function of MS1 time.

The present invention also provides a mass spectrometer as claimed in claim <NUM>.

The mass spectrometer may be arranged and adapted to perform any one of the methods described herein above.

The mass spectrometer may further comprise either:.

According to an embodiment the mass spectrometer further comprises a device arranged and adapted to supply an AC or RF voltage to the electrodes. The AC or RF voltage preferably has an amplitude selected from the group consisting of: (i) < <NUM> V peak to peak; (ii) <NUM>-<NUM> V peak to peak; (iii) <NUM>-<NUM> V peak to peak; (iv) <NUM>-<NUM> V peak to peak; (v) <NUM>-<NUM> V peak to peak; (vi) <NUM>-<NUM> V peak to peak; (vii) <NUM>-<NUM> V peak to peak; (viii) <NUM>-<NUM> V peak to peak; (ix) <NUM>-<NUM> V peak to peak; (x) <NUM>-<NUM> V peak to peak; and (xi) > <NUM> V peak to peak.

The AC or RF voltage preferably has a frequency selected from the group consisting of: (i) < <NUM>; (ii) <NUM>-<NUM>; (iii) <NUM>-<NUM>; (iv) <NUM>-<NUM>; (v) <NUM>-<NUM>; (vi) <NUM>-<NUM>; (vii) <NUM>-<NUM>; (viii) <NUM>-<NUM>; (ix) <NUM>-<NUM>; (x) <NUM>-<NUM>; (xi) <NUM>-<NUM>; (xii) <NUM>-<NUM>; (xiii) <NUM>-<NUM>; (xiv) <NUM>-<NUM>; (xv) <NUM>-<NUM>; (xvi) <NUM>-<NUM>; (xvii) <NUM>-<NUM>; (xviii) <NUM>-<NUM>; (xix) <NUM>-<NUM>; (xx) <NUM>-<NUM>; (xxi) <NUM>-<NUM>; (xxii) <NUM>-<NUM>; (xxiii) <NUM>-<NUM>; (xxiv) <NUM>-<NUM>; and (xxv) > <NUM>.

The preferred embodiment comprises at least two different ion mass analysers and a fragmentation or reaction device placed between the two mass analysers. A first of the mass analysers may be a mass filter which is scanned so as to mass selectively transmit precursor ions to the fragmentation or reaction device. The second mass analyser may be a Time of Flight mass analyser for analysing the fragment or product ions produced by the fragmentation or reaction device. The fragment or product ions produced are preferably analysed at a much faster rate than the precursor ions. The times at which the fragment ions are detected may be used to determine the times at which their precursor ions were transmitted by the first mass analyser and hence may be used to determine the mass to charge ratios of the precursor ions.

The preferred embodiment operates by scanning a low resolution mass filter at a scan rate that allows multiple Time of Flight mass spectra to be acquired across the time of a scanned precursor ion mass spectral peak. The Time of Flight acquisition system may operate in a manner similar to that described in <CIT>. In this mode each Time of Flight spectrum is tagged with its effective time or increment relative to some other start event. In the case of <CIT> the start event is the start of an ion mobility experiment. In the preferred embodiment the start event is the start of a low resolution mass scan of the precursor ions. The time at which fragment ion data is obtained can therefore be correlated to the low resolution scan of the precursor ions.

The precursor ion mass analyser is preferably of relatively low resolution and so has an improved duty cycle over conventional devices which isolate and transmit only a single precursor ion at once. Nevertheless, the use of the fragment or product ion data enables the preferred embodiment to maintain relatively high precursor ion specificity, i.e. improved mass measurement of the precursor ions, as compared with other known arrangements. The preferred embodiment improves the specificity of the precursor ions in an un-targeted, un-biased acquisition.

Various embodiments of the present invention will now be described, by way of example only, and with reference to the accompanying drawings in which:.

<FIG> shows a schematic of a preferred embodiment of a mass spectrometer according to the present invention. The mass spectrometer comprises a quadrupole mass filter <NUM>, a gas cell <NUM> and an orthogonal acceleration Time-of-Flight mass analyser <NUM>. During operation, the quadrupole mass filter <NUM> is set so as to have a relatively low resolution. For example, the quadrupole <NUM> may transmit precursor ions <NUM> within a transmission window having a width of <NUM> Da. Precursor ions <NUM> that are transmitted by the quadrupole mass filter <NUM> are accelerated into the gas cell <NUM> such that they fragment to produce fragment ions. These fragment ions are then mass analysed in the Time-of-Flight mass analyser <NUM>. The quadrupole mass filter <NUM> is scanned with time such that the range of mass to charge ratios of the transmission window changes with time. The timing at which fragment ions are detected may be correlated to the timing of the transmission window in which their precursor ions <NUM> were transmitted by the mass filter <NUM>. The gas cell <NUM> preferably maintains the fidelity of the temporally separated fragment ions by use of a travelling wave or a linear accelerating electric field.

<FIG> shows a graph representing precursor ions that may be transmitted by the quadrupole mass filter. The y-axis indicates the intensity of the ion signal and the x-axis indicates the mass to charge ratio of the ion signal. It will be appreciated that since the transmission window of the quadrupole mass filter is stepped with time, the x-axis is related to the time of analysis of the precursor ions. Each peak corresponds to a separate precursor ion species. If these precursor ions were transmitted by the quadrupole mass filter then the first and last peaks could be resolved by the quadrupole mass filter. However, the two central, dashed peaks would overlap and the low resolution of the quadrupole mass filter would not be able to resolve these two precursor ion peaks.

It may be desirable to use a relatively low resolution mass analyser, such as the quadrupole mass filter described above, because fewer precursor ions are then discarded at any given point in the mass analysis and so the duty cycle of the mass spectrometer is increased. However, this has conventionally been seen as detrimental in that the resolution of the instrument may be too low to resolve two similar precursor ion mass peaks. The present invention provides a technique for resolving such peaks that interfere with each other.

<FIG> shows a graph obtained from analysing the four precursor ions of <FIG> in accordance with the technique described above in relation to <FIG>. The graph shows the mass to charge ratios of the fragment ions detected (y-axis), plotted as a function of the precursor ion mass to charge ratios transmitted by the quadrupole mass filter (x-axis). As mentioned above, the quadrupole mass filter is scanned with time and so the graph represents the mass to charge ratios of the fragment ions detected (y-axis), plotted as a function of time. It will be seen that the plots of the fragment ions are aligned in four columns and that all of the fragment ions were detected over four time windows. The first column, which contains only a single plot, corresponds to the fragment ion generated from the fragmentation of the precursor ion shown in the first peak of <FIG>. The second column, which contains three plots, corresponds to the three species of fragment ions generated from the fragmentation of the precursor ion shown in the second peak of <FIG>. The third column, which contains four plots, corresponds to the four species of fragment ions generated from the fragmentation of the precursor ion shown in the third peak of <FIG>. The fourth column, which contains five plots, corresponds to the five species of fragment ions generated from the fragmentation of the precursor ion shown in the fourth peak of <FIG>.

Although the precursor ions in <FIG> are not fully resolved and some of the peaks overlap, the fragment ions in <FIG> are well separated in mass to charge ratios (along the y-axis) and hence are well resolved. The start and end times at which a particular fragment ion is detected are correlated to the start and end times at which its precursor ion is transmitted to the gas cell for fragmentation. Accordingly, the start and end times of the fragment ion signals can be used to determine the start and end times of their corresponding precursor ion signals.

In the example shown in <FIG>, the first column of fragment ion plots has start and end times corresponding to the start and end times of an ion signal for a first precursor ion. The second column of fragment ion plots has start and end times corresponding to the start and end times of an ion signal for a second precursor ion. The third column of fragment ion plots has start and end times corresponding to the start and end times of an ion signal for a third precursor ion. The fourth column of fragment ion plots has start and end times corresponding to the start and end times of an ion signal for a fourth precursor ion. It will therefore be appreciated that this technique can be used to identify the start and end times of two precursor ion peaks that would overlap in a precursor ion spectrum obtained from a low resolution mass analyser, e.g. as shown as the dashed peaks in <FIG>.

Accordingly, the preferred embodiment is able to determine the start and end times of precursor ion peaks using data from the analysis of the fragment ions. Mass measurements can then be determined for these peaks more accurately. For example, the centroids of the mass peaks can be more accurately determined by knowing the start and end times of each of the peaks. This method of determining the masses of precursor ions is improved relative to known techniques of using a quadrupole that is scanned in <NUM> Da steps.

According to an example, a scanning quadrupole is operated at a scan rate of <NUM>,<NUM> Da per second over a mass to charge ratio range of <NUM> Da. A single scan would therefore take approximately <NUM>. If the quadrupole is operated with a transmission window having a width of <NUM> Da then ions are transmitted in each mass to charge ratio window for <NUM>. If the Time-of-Flight mass analyser is operated at a cycle time of <NUM> then the mass analyser will take <NUM> samples during this period. If the mass to charge ratio is assumed to be uniformly distributed then it can be shown that the precision of the mass measurement according to the technique of the preferred embodiment is given by the following equation: <MAT> wherein N is the number of ions used to produce the apparent precursor ion peak profile and σ is the standard deviation. If <NUM> fragment ions were detected and used to produce the precursor ion peak profile then the standard deviation of the mass measurement would be approximately <NUM> Da according to the above equation. The nature of the quadrupole transmission window also means that the mass precision is bounded by +/- <NUM> Da. These calculations take no account of any calibration error or residuals.

Although the present invention has been described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the scope of the invention as set forth in the accompanying claims.

For example, although a Time of Flight acquisition system has been described that operates in an asynchronous, time locked manner, the Time of Flight acquisition system may be synchronised with scan cycle of the quadrupole mass filter.

Although the mass transmission window has been described as having a width of <NUM> Da, the mass transmission window may have other widths. Furthermore, the width of the mass transmission window may be varied with time.

Although the mass transmission window has been described as having constant scan rate, the scan rate of the mass transmission window may be varied with time.

Claim 1:
A method of mass spectrometry comprising:
mass selectively transmitting precursor ions (<NUM>) from a mass analyser (<NUM>) into a fragmentation or reaction device (<NUM>), wherein the mass to charge ratios of the ions transmitted varies with time;
fragmenting the precursor ions in the fragmentation or reaction device so as to produce fragment or product ions;
mass analysing and detecting the fragment or product ions;
determining a time period over which a first fragment or product ion is detected; using said time period to determine a time period over which a precursor ion of said first fragment or product ion was transmitted by said mass analyser; and using the time period over which the precursor ion was transmitted by said mass analyser to determine a mass to charge ratio of said precursor ion;
determining a time period over which a second fragment or product ion is detected; using this time period to determine a time period over which a precursor ion of said second fragment or product ion is transmitted by said mass analyser; and using the time period over which this precursor ion is transmitted by said mass analyser to determine a mass to charge ratio of this precursor ion;
wherein the time period over which the first fragment or product ion is detected only partially overlaps with the time period over which the second fragment or product ion is detected;
wherein the mass analyser that transmits the precursor ions to the fragmentation or reaction device is a mass filter.