The present invention relates generally to the field of mass spectrometry.
Mass spectrometers are used for producing a mass spectrum of a sample to find its composition. This is normally achieved by ionizing the sample and separating ions of differing masses and recording their relative abundance by measuring intensities of ion flux.
Typically, the mass spectra are subject to background noise, obscuring the real signal.
The applicants have accordingly recognized a need for new systems and methods for reducing or removing noise from mass spectra.
In one aspect, the present invention is directed towards a method for reducing background noise in a mass spectrum. The method includes the following steps:
Step (b) of the method may include the steps of:
A) effecting a transformation of the original mass spectrum into the frequency domain to obtain an original frequency spectrum;
B) identifying at least one dominant frequency in the original frequency spectrum;
C) generating a noise frequency spectrum by selectively filtering for said at least one dominant frequency; and
D) determining the noise mass spectrum by effecting a transformation of the noise frequency spectrum into the mass domain.
With the method as claimed, the original mass spectrum may be provided with a plurality of original intensity data points and the noise mass spectrum may also be provided with a plurality of noise intensity data points such that each noise intensity data point correlates to an original intensity data point. The method may further include the following step:
E) for each correlated pair of original and noise intensity data points:
The present invention will now be described, by way of example only, with reference to the following drawings, in which like reference numerals refer to like parts and in which:
Referring to
Data storage 17 is also preferably provided in which may be stored mass spectrum and frequency domain data.
As will be understood, the system 10 may be a stand-alone analysis system for reducing noise in a mass spectrum (or frequency domain data). In the alternative, the system 10 may (but does not necessarily have to) comprise part of a spectrometer system having an ion source 20, configured to emit a beam of ions, generated from a sample to be analyzed.
A detector 22 (having one or more anodes or channels) may also be provided as part of the spectrometer system, which can be positioned downstream of the ion source 20, in the path of the emitted ions. Optics 24 or other focusing elements, such as an electrostatic lens can also be disposed in the path of the emitted ions, between the ion source 20 and the detector 22, for focusing the ions onto the detector 22.
Referring now to
The engine 14 can be programmed to effect a transformation of the original mass spectrum 40 into the frequency domain (typically by subjecting the original mass spectrum 40 data to a Fourier Transformation, sine/cosine transform or any mathematical or experimental method known in the art) to obtain an original frequency spectrum 50, as illustrated in the graph 52 of
The original frequency spectrum 50 comprises distinct peaks 58 corresponding to dominant frequencies. As will be understood, background noise is often periodic in nature, typically having a period of one atomic mass unit. Accordingly, a significant portion of the intensity of the dominant frequencies 58 may often be attributed to the noise component of the original mass spectrum 40. These dominant frequencies 58 will often correspond to the background noise's base frequency and corresponding harmonics thereof.
The engine 14 preferably identifies at least one and preferably all of the dominant frequencies 58 in the original frequency spectrum 50 (although as will be understood, this step could be performed manually by a system 10 user) (Block 208). Next, the original frequency spectrum 50 is filtered for the identified dominant frequencies 58, in order to generate a noise frequency spectrum 60, as illustrated in the graph 61 of
To accomplish this, a filter 62, such as that depicted for illustrative purposes in the schematic graph 64 of
Subsequently, the engine 14 is preferably configured to determine a noise mass spectrum 72 illustrated in the graph 74 of
As will be understood, the noise mass spectrum 72 data represents an estimate of the background noise signal component of the original mass spectrum 40.
Referring to
Referring to exemplary data points 74A and 74B (and 75A and 75B) of the original mass spectrum 40 and the noise mass spectrum 72, respectively, each pair is correlated to the same m/z value (as indicated by the dotted lines). It can be seen that the noise mass spectrum 72 may have a higher intensity value at certain m/z values than the original mass spectrum 40. However, as will be understood, this indicates an artifact in estimation of the background noise signal component, as the noise component should not exceed the combined background and real signals of the original mass spectrum 40 (at corresponding m/z values). This artifact is a result of the real peak(s) in the original mass spectrum 40, for example at points 74A, 75A where the original mass spectrum 40 has a higher intensity value than the corresponding points 74B, 75B on the noise mass spectrum 72.
Accordingly, to further refine the background signal estimate, the noise mass spectrum 72 data is revised such that for each correlated data point in the noise mass spectrum 72 and original mass spectrum 40 (having the same m/z value), the minimum intensity value of the two data points is determined (Block 214). In turn, the noise mass spectrum is preferably modified by making the noise intensity data point equal to the minimum value (Block 216).
For the sake of clarity, the steps of Blocks 214 and 216 may be implemented using the function set out in Equation 1, below:
f′(x)=min(f(x), g(x)) EQ. 1:
where x represents m/z and f(x) represents the intensity value of the noise mass spectrum 72 and g(x) represents the intensity value of the original mass spectrum 40, and f′(x) represents the modified noise mass spectrum.
Completion of Block 216 for all of the correlated data points in the original and noise mass spectrums 40, 72, results in a modified noise mass spectrum 80, as illustrated in the graph 82 of
Next, a transformation of the modified noise mass spectrum 80 into the frequency domain is effected (again, typically by subjecting the noise mass spectrum 80 data to a Fourier Transformation) to obtain a noise frequency spectrum 90, as illustrated in the graph 92 of
Next, at least one and preferably all of the dominant frequencies 94 in the noise frequency spectrum 90 are identified (Block 222). The noise frequency spectrum 90 is then filtered for the identified dominant frequencies 94, in order to generate a filtered noise frequency spectrum 98, a portion of which is illustrated in the graph 99 of
Typically, the filter 62 of
Subsequently, a noise mass spectrum 100 as illustrated in the graph 102 of
To further refine the background signal estimate, in a manner similar to that discussed in relation to Block 216, the noise mass spectrum 100 data is revised such that for each correlated data point in the noise mass spectrum 100 and original mass spectrum 40 (correlated by sharing the same m/z value), the minimum intensity value of the two data points is determined (Block 228). In turn, the noise mass spectrum 100 is preferably modified by making the noise intensity data point equal to the minimum value (Block 230). As will be understood, the steps of Blocks 228 and 230 may be implemented using Equation 1, above.
Completion of Block 230 for all of the correlated data points in the original and noise mass spectrums 40, 100, results in a modified noise mass spectrum 102, as illustrated in the graph 104 of
The steps of Blocks 220 to 232 will preferably (but not necessarily) be repeated multiple times (as indicated by the line 233 in
Once the final version of the modified noise mass spectrum 102 has been determined, the noise mass spectrum 102 is subtracted from the original mass spectrum 40, resulting in a corrected mass spectrum 110 as illustrated in graph 112 in
In an alternate embodiment 200′, it has been found that improved results may sometimes be obtained by segmenting the original mass spectrum 40 into a plurality of initial windows 120 (as illustrated in
Of course, as will be understood, the description above of each of Blocks 206 through 212 refer to mass spectrums and corresponding frequency domains as a whole. However, if the original mass spectrum 40 is to be processed by initial windows 120 separately pursuant to Block 234, as appropriate, references to whole mass spectrums and frequency domains in the descriptions for the Blocks 206 through 212 should be understood to refer to the mass spectrum and frequency domain segments corresponding to the initial window 120 being processed during the specific iteration of those Blocks.
Once the segmentation of the original mass spectrum 40 into initial windows 120 pursuant to Block 222 and the subsequent completion of Blocks 206 through 212 for each initial window 12 and the modified noise mass spectrum 80 has been generated pursuant to Blocks 214 through 218, the noise mass spectrum 80 is segmented into a series of a plurality of subsequent windows 130 (as illustrated in
Accordingly, if the subsequent windows 130 are configured to be generally of the same size as the initial windows 12, the subsequent window segments 130 will be shifted in the mass domain such that the first 130′ and last 130″ subsequent window segments will typically be smaller than the remainder of the subsequent windows 130.
Each of Blocks 220 through 226 inclusive is completed separately for one subsequent window 130 (including 130′, 130″), before Blocks 220 through 226 are completed for another (typically successive) subsequent window 130, as indicated by dotted line 240. As with the initial embodiment discussed above, Blocks 220 through 232, may be repeated—for each subsequent repetition (as indicated by dotted line 233′ instead of line 233) preferably a series of new subsequent windows is created in Block 238 such that no new subsequent window 130 is coextensive with any subsequent window 130 in any previous series. It is also preferable if (other than at the beginning and end of the mass spectrums), any new subsequent windows 130 do not share a leading or termination edge (indicated by the dotted lines in
To avoid or minimize the overlap of leading or terminating edges, for each subsequent repetition, a series of new subsequent windows 130 may be configured to generally have the same size as previous series of windows 130, but be shifted in location relative to m/z value. Alternatively, the size of the windows 130 may be changed for different series of windows 130 to minimize the overlapping of leading or terminating edges.
Thus, while what is shown and described herein constitute preferred embodiments of the subject invention, it should be understood that various changes can be made without departing from the subject invention, the scope of which is defined in the appended claims.
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