The present invention relates generally to ion trap mass spectrometers, and more particularly to methods for operating an ion trap mass spectrometer to optimize ejection peak characteristics.
Ion trap mass analyzers have been described extensively in the literature (see, e.g., March et al., “Quadrupole Ion Trap Mass Spectrometry”, John Wiley & Sons (2005)) and are widely used for mass spectrometric analysis of a variety of substances, including small molecules such as pharmaceutical agents and their metabolites, as well as large biomolecules such as peptides and proteins. Mass analysis is commonly performed in ion traps by the resonant excitation method, wherein a resonant ejection voltage is applied across a pair of electrodes while the amplitude of the main radio-frequency (RF) trapping voltage is ramped, causing ions to come into resonance and be ejected from the ion trap to the detector(s) in order of their mass-to-charge ratios (m/z's).
It is known that the characteristics of a mass spectral peak, e.g., peak height, width, and isotope spacing/ratio, acquired by resonant ejection will vary with the amplitude of the resonant ejection voltage, and that the amplitude that optimizes certain peak characteristics depends on the m/z of the ejected ion. The prior art contains a number of references that describe methods for varying the resonant ejection voltage amplitude during an analytical scan in order to produce high quality mass spectral peaks across the measured range of m/z's. For example, U.S. Pat. No. 5,298,746 to Franzen et al. (“Method and Device for Control of the Excitation Voltage for Ion Ejection from Ion trap Mass Spectrometers”) prescribes controlling the resonant ejection voltage during the analytical scan such that its amplitude is set proportionally to the square root of the main RF trapping voltage amplitude. In another example, U.S. Pat. No. 5,572,025 to Cotter et al. (“Method and Apparatus for Scanning an Ion Trap Mass Spectrometer in the Resonance Ejection Mode”) discloses operating an ion trap to maintain a constant ratio between the RF trapping voltage and resonant ejection voltage amplitudes. It is also known in the art to utilize empirical calibrations using mass spectra acquired for calibrant ions of known m/z to attempt to optimize selection of the resonant ejection voltage amplitude for desirable peak characteristics, such as width.
It has been observed, however, that a simple relation between m/z and resonant ejection voltage amplitude may not provide optimized performance when an ion trap is operated under certain conditions, such as when the resonant ejection voltage and main RF trapping voltage are maintained in a phase-locked state, and/or when low ion trap pressures are utilized. Experimental studies of ion traps operated under such conditions indicate that as the resonant ejection voltage amplitude is varied, several regions of acceptable peak characteristics are seen, separated by transition regions having poor peak characteristics. Against this background, there is a need for a method for calibrating and operating an ion trap mass spectrometer operated under conditions which produce behavior more complex than is addressed by prior art methods.
Roughly described, a method for calibrating an ion trap mass spectrometer in accordance with an illustrative embodiment of the present invention includes steps of selecting a phase of the resonant ejection voltage that optimizes a peak quality representative of one or more mass spectral peak characteristics; identifying, for each of a plurality of calibrant ions having different m/z's, a resonant ejection voltage amplitude that optimizes the peak quality when the ion trap is operated at the selected phase; and, deriving a relationship between m/z and resonant ejection voltage amplitude based on the optimized resonant ejection voltage amplitude identified for the plurality of calibrant ions. Data representing the m/z-resonant ejection voltage amplitude relationship thus derived may be stored and subsequently utilized to control the resonant ejection voltage amplitude during analytical scanning of the ion trap, such that at any time during the scan the resonant ejection voltage amplitude is set to optimize the peak quality of the ion being ejected.
According to a more specific implementation of the calibration method, the m/z-resonant ejection voltage amplitude relationship that optimizes peak quality is derived for each of a plurality of available analytical scan rates. At each scan rate, a phase that produces optimal peak quality is selected by monitoring the variation in peak quality with phase and identifying the phase at which the peak quality value is optimized. The peak quality is calculated from one or more peak characteristics, which may include any one or all of peak width, height, valley, isotope spacing and isotope ratio. The peak quality calculation may be identical or different for each scan rate. The resonant ejection voltage amplitude that optimizes peak quality is then determined, for each of the calibrant ions, by monitoring the variation in peak quality with resonant ejection voltage amplitude while the phase is maintained at the experimentally optimized value. An m/z-resonant ejection voltage amplitude calibration that optimizes peak quality may then be derived, for example, by fitting a line, piecewise linear segments, or a curve to the several (m/z, optimized resonant ejection voltage amplitude) points representing the calibrant ions.
In the accompanying drawings:
The ions are transported from ion source chamber 110, which for an electrospray source will typically be held at or near atmospheric pressure, through several intermediate chambers 120, 125 and 130 of successively lower pressure, to a vacuum chamber 135 in which ion trap 140 resides. Efficient transport of ions from ion source 105 to ion trap 140 is facilitated by a number of ion optic components, including quadrupole RF ion guides 145 and 150, octopole RF ion guide 155, skimmer 160, and electrostatic lenses 165 and 170. Ions may be transported between ion source chamber 110 and first intermediate chamber 120 through an ion transfer tube 175 that is heated to evaporate residual solvent and break up solvent-analyte clusters. Intermediate chambers 120, 125 and 130 and vacuum chamber 135 are evacuated by a suitable arrangement of pumps to maintain the pressures therein at the desired values. In one example, intermediate chamber 120 communicates with a port of a mechanical pump (not depicted), and intermediate pressure chambers 125 and 130 and vacuum chamber 135 communicate with corresponding ports of a multistage, multiport turbo-molecular pump (also not depicted). Ion trap 140 includes axial trapping electrodes 180 and 185 (which may take the form of conventional plate lenses) positioned axially outward from the ion trap electrodes to assist in the generation of a potential well for axial confinement of ions, and also to effect controlled gating of ions into the interior volume of ion trap 140. A damping/collision gas inlet (not depicted), coupled to a source of an inert gas such as helium or argon, will typically be provided to controllably add a damping/collision gas to the interior of ion trap 140 in order to facilitate ion trapping, fragmentation and cooling. Ion trap 140 is additionally provided with at least one set of detectors 190 (wherein each set may consist of a single detector or multiple detectors) that generate a signal representative of the abundance of ions ejected from the ion trap.
Ion trap 140, as well as other components of mass spectrometer 100, communicate with and operate under the control of a data and control system (not depicted), which will typically include a combination of one or more general purpose computers and application-specific circuitry and processors. Generally described, the data and control system acquires and processes data and directs the functioning of the various components of mass spectrometer 100. The data and control system will have the capability of executing a set of instructions, typically encoded as software or firmware, for carrying out the calibration methods described herein.
While
θreseject=(Δt/P)*360
where P is equal to the period of the resonant ejection voltage.
In step 410, an analytical scan rate is set to one of the values available on the instrument. Many commercial ion trap mass spectrometers provide the operator with the ability to specify an analytical scan rate (typically expressed in units of Dalton/sec) based on performance requirements, notably throughput and resolution. For example, the Finnigan LTQ® ion trap mass spectrometer (Thermo Fisher Scientific, San Jose, Calif.) offers five analytical scan rates, referred to as turbo, normal, enhanced, zoom, and ultra-zoom. In some mass spectrometers, switching between analytical scan speeds may be performed automatically in a data-dependent manner. Since the analytical scan rate affects the ejection peak characteristics, it is beneficial to calibrate the ion trap at each of the available scan rates in order to obtain maximum performance and more reliable and accurate calibrations.
Next, in step 415, a plurality of analytical scans of ions produced from a calibration standard are performed at different values of θreseject that span a range of interest, while holding the resonant ejection voltage amplitude (Areseject) fixed. The phase range of interest may include all possible values of θreseject (e.g., 0-120 degrees for the example depicted in
For high scan rate:
Peak Quality=N(I(12C))−N(Width(12C))
For medium scan rate:
Peak Quality=N(I(12C))−N(Width(12C)+Width(13C)+4*valley(12C)+2*isoShift(12C))
For low scan rate:
Peak Quality=N(I(12C))−N(Width(12C)+2*isoShift(12C))
where N denotes a normalized value, Width is the full-width half-maximum (FWHM) peak width, I is the peak intensity, 12C and 13C respectively denote the mass spectral peaks arising from the 12C and 13C isotopes of the calibrant ion, and the isoshift and valley parameters are calculated as follows:
isoShift=|(M(12C)observed+1)−M(13C)observed)|
where M(12C)observed and M(13C)observed are, respectively, the measured masses of the 12C and 13C isotopes of the calibrant ion; and
Valley=I(12C+0.5)observed/I(13C)observed
where I(12C+0.5)observed is the measured intensity at an m/z value equal to 0.5 plus the m/z of the 12C isotope of the calibrant ion.
Those skilled in the art will recognize that the foregoing equations will yield a relatively high value for “good” peaks and a relatively low value for “bad” peaks.
In other implementations, the equations used to calculate peak quality may be selected or adjusted in accordance with operator input. Such input may include information identifying or weighing the importance of certain peak characteristics.
Once peak quality has been calculated for mass spectra acquired at each value of θreseject, the data are analyzed to identify the value of θreseject that produces optimal peak quality, step 420. This value is stored in the data and control system for subsequent use.
In the foregoing example, the global optimum resonant ejection voltage phase is identified by acquiring peak quality data for a selected calibrant ion at a fixed value of amplitude while θreseject is varied. Alternative implementations of the phase optimization step may utilize a procedure wherein peak quality measurements are obtained for different values of θreseject over a range of resonant ejection voltage amplitudes. Such implementations may employ any one or combination of suitable two-dimensional optimization techniques known in the art (including, without limitation, mapping, simplex, particle swarm and the like) to identify the optimal phase from the acquired peak quality data.
In step 425, a plurality of analytical scans of ions produced from a calibration standard are performed at different values of the resonant ejection voltage amplitude (Areseject) that span a range of interest, while holding θreseject at the optimal value derived in the previous step. As is discussed further below, this step is performed for each of n calibrant ions, for example the five calibrant ions mentioned above (m/z 195, 524, 1222, 1522 and 1822). The range of values over which Areseject is varied may be automatically determined based on, among other factors, the analytical scan rate selected in step 410 and the m/z of the calibrant ion, and the increment by which Areseject is stepped over. The range of values may also depend on the analytical scan rate and calibrant ion m/z. In one specific implementation, Areseject is varied from about 3-12 Vp-p for the m/z 195 calibrant ion, and from about 10-45 Vp-p for the m/z 1522 calibrant ion.
Each of the mass spectra acquired in step 425 is analyzed to determine a peak quality of the ejection peak of a selected calibrant ion. Peak quality may be calculated using the same equations utilized to calculate peak quality in step 415, or a different set of equations may be employed. As discussed above, the peak quality may be calculated in a different fashion for each analytical scan rate.
Following the calculation of peak quality for mass spectra acquired at each value of θreseject, the data are analyzed to identify the value of Areseject that produces optimal peak quality, step 430. In a manner analogous to step 415, identification of the peak-quality optimized value of Areseject may be performed simply by locating a maximum in the peak quality vs. Areseject curve, or may instead involve a more complex analysis utilizing, for example, averaging and/or filtering steps.
Steps 425 and 430 are repeated for each of the n calibrant ions to identify the value Areseject that produces optimal peak characteristics for each calibrant ion. This yields a set of n experimentally determined (m/z, Areseject) points. The calibration relationship between m/z and Areseject may then be derived by fitting a line, piecewise linear, or curve to the n experimentally determined points using well-known statistical methods (e.g., a least-squares fit), step 435. In a simple implementation, the calibration relationship will take the form of a line; in other implementations, the calibrated relationship may be a polynomial or cubic-spline curve or piecewise linear relationship. Data representing the derived calibration relationship (e.g., a slope and intercept for a linear relationship or a set of coefficients for a polynomial relationship) are stored in the memory of the data and control system of mass spectrometer 100 for use in operating ion trap 140, in the manner described below.
As indicated on
The foregoing example assumes that the ion trap is configured to operate at a selected one of several discrete scan rate values, and m/z-amplitude calibration curves are derived at each of the available scan rate values. Certain mass spectrometers may allow the ion trap scan rate to be set (either under manual or automatic control) at any value within a continuous range. To accommodate such continuously variable operation, peak quality data may be acquired at a series of specified values of scan rate, and calibrated relationships (for example, in the form of a linear or polynomial function) may be derived between scan rate and optimal resonant ejection voltage phase, and between scan rate and optimal resonant ejection voltage amplitude. These calibrated relationships may be stored and subsequently invoked to determine optimal values of the phase and amplitude parameters corresponding to the scan rate at which the ion trap is operated.
After all calibration steps have been completed, ion trap 140 may then be operated for analysis of sample substances using the experimentally-derived calibration information, step 440. More specifically, analytical scans are performed (via appropriate control of main RF trapping voltage source 240 and resonant ejection voltage source 250) at the optimized value of θreseject for the scan rate being utilized, and the Areseject is varied during the analytical scan in accordance with the stored calibration relationship. To effect proper control of Areseject during the scan, a set of look-up tables may be generated and stored in memory, each table containing a list of (time, Areseject) values calculated using the known correspondence between time and m/z at a specified analytical scan rate. Of course, other suitable techniques may be employed to control Areseject during analytical scans in conformance with the derived calibration relationships.
In an alternative implementation of the calibration method depicted in
The calibration methods described herein are also applicable to ion traps in which resonant excitation is achieved by the application of two or more resonant ejection voltages of differing frequencies. As used herein, the term “resonant ejection voltage” is intended to denote any oscillatory voltage (exclusive of the main RF trapping voltage) applied to the ion trap electrodes for the purpose of resonantly exciting and ejecting ions. In instances where a combination of a plurality of resonant ejection voltages of differing frequencies are utilized for excitation, the optimal phase and m/z-amplitude relationship may be separately determined for each of the component voltages and stored, such that, during operation of the ion trap for analysis of samples of unknown composition, each of the resonant ejection voltages may be set to optimized values of phase and amplitude.
In a further variation of the above-described method, optimum calibration relationships between the resonant ejection voltage amplitude, resonance ejection phase, and m/z may be determined by first acquiring peak quality data while holding the phase at a fixed default value, and varying the resonant ejection amplitude for a particular m/z. This value can be then used to scale a default resonant ejection amplitude relationship with m/z. Subsequently, the optimum phase for each m/z may be identified by varying the phase while holding the amplitude at a fixed value determined by the rescaled default relationship between resonance ejection amplitude and m/z.
It is to be understood that while the invention has been described in conjunction with the detailed description thereof, the foregoing description is intended to illustrate and not limit the scope of the invention, which is defined by the scope of the appended claims. Other aspects, advantages, and modifications are within the scope of the following claims.
The present application is a continuation-in-part and claims the priority benefit under 35 U.S.C. §120 of U.S. patent application Ser. No. 12/205,624 by Remes et al., filed Sep. 5, 2008 now U.S. Pat. No. 7,804,065, the contents of which are incorporated herein by reference.
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4540884 | Stafford et al. | Sep 1985 | A |
4686367 | Louris et al. | Aug 1987 | A |
5285063 | Schwartz et al. | Feb 1994 | A |
5298746 | Franzen et al. | Mar 1994 | A |
5347127 | Franzen | Sep 1994 | A |
5397894 | Wells et al. | Mar 1995 | A |
5448061 | Wells | Sep 1995 | A |
5479012 | Wells | Dec 1995 | A |
5572025 | Cotter et al. | Nov 1996 | A |
6124591 | Schwartz et al. | Sep 2000 | A |
6831275 | Franzen et al. | Dec 2004 | B2 |
7804065 | Remes et al. | Sep 2010 | B2 |
Number | Date | Country |
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0 747 929 | Dec 1996 | EP |
Number | Date | Country | |
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20110012013 A1 | Jan 2011 | US |
Number | Date | Country | |
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Parent | 12205624 | Sep 2008 | US |
Child | 12890980 | US |