This invention relates generally to methods of ion fragmentation in mass spectrometers and more particularly to methods of calibrating and determining fragmentation excitation energy in terms of a mass variable.
As is well known in the field of life sciences, tandem mass spectrometry (MS/MS) is a powerful tool for structural elucidation of analytes, and in its many permutations, MS/MS is commonly used to dissociate and analyze such diverse species as peptides, proteins, small molecule drug compounds, synthetic polymers, and metabolites. The most common method of causing ion fragmentation in MS/MS analyses is collision induced dissociation (CID), in which a population of analyte precursor ions are accelerated into target neutral gas molecules such as nitrogen (N2) or argon (Ar), causing the precursors to gain internal energy and fragment. The ionic fragments ions are analyzed so as to provide useful information regarding the structure of the precursor ion.
When performing MS/MS in an ion trap, there are various ways to activate ions in order to cause ion fragmentation by means of collision induced dissociation or otherwise. The most efficient and widely used method involves collision-induced dissociation by means of a resonance excitation process. This method, which may be referred to as RE-CID, utilizes an auxiliary alternating current voltage (AC) that is applied to the ion trap in addition to the main RF trapping voltage. This auxiliary voltage typically has relatively low amplitude (on the order of 1 Volt (V)) and duration on the order of tens of milliseconds. The frequency of this auxiliary voltage is chosen to match an ion's frequency of motion, which in turn is determined by the main trapping field amplitude and the ion's mass-to-charge ratio (m/z). As a consequence of the ion's motion being in resonance with the applied voltage, the ion takes up energy from this voltage, and its amplitude of motion grows.
A variant of the CID technique, referred to as pulsed-q dissociation (PQD or, alternatively, PQ-CID) and described in U.S. Pat. No. 6,949,743 to Schwartz, may be employed in place of conventional CID by resonance excitation. In the PQD technique, the RF trapping voltage is increased prior to or during the period of kinetic excitation, and then reduced after a short delay period following termination of the excitation voltage in order to retain relatively low mass product ions in the trap. The PQD technique provides for more energetic collisional activation of target ions than does the original resonance excitation CID technique, while still retaining the lower mass product ions for subsequent analysis.
Photo-dissociation is another commonly employed fragmentation method in the field of mass spectrometry. For instance, in the technique known as Infrared Multiphoton Dissociation (IRMPD), infrared light from a laser is introduced into a vacuum chamber containing ions, such as an ion trap, so as to excite certain vibrational modes and thereby cause fragmentation. The IRMPD technique only works well under low pressure (high-vacuum) conditions. At higher pressures, ultraviolet light (for instance, from an ultraviolet lamp or a laser) can be used to excite electronic states within a molecule or ion, and thereby cause dissociation (or ionization). The infrared or UV light may be applied either continuously (that is, as a continuous wave) or else pulsed or chopped over a certain time period. Thus, in these photo-dissociation techniques, the power of the laser light or the energy per pulse is an important experimental variable as are, also, the light wavelength and the total time duration of exposure.
One remarkable aspect of the various ion fragmentation techniques is the fact that they are applicable to such a wide variety of precursors; masses, charges, shapes, and ion stabilities. However, to achieve the most efficient conversion of precursor ions to product ions, certain experimental parameters must be optimized, such as the collision energy, the target gas pressure, laser power or energy per pulse (for IRMPD and APPI) and possibly target gas constituents. Precursor ions of different size and structure have different internal energy requirements to maximize their unimolecular dissociation rates, and in general, collision energy must be increased as the mass of the precursor goes up and the charge of the precursor goes down. To maximize experimental throughput, a fragmentation energy dependence on mass and charge is typically calibrated and stored in the instrument, so that the appropriate parameters may be automatically varied in a data-dependent manner. The object of this disclosure is to provide an improved fragmentation energy calibration method that increases the likelihood that a given user-input fragmentation energy setting will appropriately fragment a precursor of a given mass and charge.
Methods of calibrating the MS/MS fragmentation energy are provided which utilize a range of “useable” fragmentation energies (UCE) at each mass. According to some embodiments, two reference points may be fixed at each mass respectively corresponding to, for example, the onset of fragmentation and the optimum of fragmentation. These two points set the slope and intercept of the graph of the linear equation
V=(UCE×slope(mass))+intercept(mass)
for a particular mass, where V is a collision-energy-related variable (generally an instrumental voltage) and the dimensionless UCE variable represents a proportion, possibly as a percentage, of a range of the fragmentation-energy-related variable corresponding to useable fragmentation energy range for ions of the particular mass.
Accordingly, in a first aspect, there is provided method of calibrating ion fragmentation energy used for fragmenting ions in a mass spectrometer, comprising: (a) obtaining fragment ion yield data for each of a plurality of precursor ion populations having respective mass-to-charge ratios at each of a plurality of settings of a fragmentation-energy-related variable; (b) locating, for each mass-to-charge ratio, reference values of the fragmentation-energy-related variable, each reference value corresponding to a respective reference feature of the ion yield data at the mass-to-charge ratio; (c) determining, from the plurality of locating steps, the variation, with mass-to-charge-ratio, of each of the reference values of the fragmentation-energy-related variable; (d) associating each of the reference values of the fragmentation-energy related variable with respective reference values of a dimensionless useable-fragmentation-energy variable; and (e) storing parameters describing the variation of each of the reference values of the fragmentation-energy-related variable with mass-to-charge ratio, wherein the parameters comprise coefficients of at least one non-linear equation.
In a second aspect, there is provided a method of fragmenting precursor ions comprising a plurality of precursor ion mass-to-charge ratios so as to create fragment ions in a mass spectrometer, comprising: (a) choosing a value of a useable fragmentation energy variable to be referenced for the fragmenting the precursor ions, the useable fragmentation energy value representing a proportion or percentage of a range of values of a fragmentation-energy-related variable, said range varying non-linearly with precursor ion mass-to-charge ratio; (b) isolating a precursor ion of a particular mass-to-charge ratio in the mass spectrometer; (c) determining a value of a fragmentation-energy-related variable that corresponds to the chosen useable fragmentation energy value at the particular mass-to-charge ratio; (d) generating fragment or product ions from the precursor ion of the particular mass-to-charge ratio in the mass spectrometer using a control setting of the mass spectrometer corresponding to the determined fragmentation-energy-related variable; and (e) mass analyzing the fragment or product ions using the mass spectrometer.
In a third aspect, there is provided a method of calibrating ion fragmentation energy used for fragmenting ions in a mass spectrometer, comprising: (a) obtaining fragment ion yield data for each of a plurality of precursor ion populations having respective values of a mass variable at each of a plurality of settings of a fragmentation-energy-related variable; (b) locating, for each value of the mass variable, reference values of the fragmentation-energy-related variable, each reference value corresponding to a respective reference feature of the fragment ion yield data obtained at the value of the mass variable; (c) determining, from the plurality of locating steps, the variation, with the mass variable, of each of the reference values of the fragmentation-energy-related variable; (d) associating each of the reference values of the fragmentation-energy related variable located for each value of the mass variable with respective reference values of a dimensionless useable-fragmentation-energy variable so as to set up, for each value of the mass variable, a relationship between the useable fragmentation energy variable and the fragmentation-energy related variable; and (e) storing parameters describing the variation of each of the reference values of the fragmentation-energy-related variable with the mass variable, wherein a zero value of the useable fragmentation energy variable corresponds to a non-zero value of the fragmentation-energy related variable for at least one value of the mass variable.
The fragmentation-energy-related variable may comprise an amplitude of an auxiliary alternating current voltage that is applied to an ion trap. Under such circumstance, the auxiliary alternating current voltage may be applied in conjunction with pulsed-q dissociation of the precursor ions. Alternatively, the fragmentation-energy-related variable may comprise an accelerating voltage that propels the precursor ions into a collision cell or the energy-per-pulse or continuous-wave power of a laser light to which the precursor ions are exposed.
Various embodiments of methods for calibrating may include additional steps of: (a1) determining, for each mass-to-charge ratio or other mass variable, a respective model curve relating at least a portion of the fragment ion yield data to the fragmentation-energy-related variable, and (a2) determining at least one reference feature of the fragment ion yield data obtained at each value of the mass-to-charge ratio or mass variable from parameters relating to the respective model curve. In such cases, separate reference values of the fragmentation-energy-related variable that are located for each mass-to-charge ratio or mass variable may respectively correspond to a mean and a standard deviation of the model curve determined for the mass-to-charge ratio or other mass variable. Alternatively, a reference value of the fragmentation-energy-related variable that is located for each mass-to-charge ratio or other mass variable may correspond to a threshold value of the model curve determined for the mass-to-charge ratio or mass variable.
In various embodiments of methods for calibrating, the step of storing parameters describing the variation of each of the reference values of the fragmentation-energy-related variable with mass-to-charge ratio or other mass variable may comprise storing at least one parameter that is a coefficient or exponent of a power law equation or may comprise storing parameters that are coefficients of at least one polynomial equation.
This method alleviates problems associated with current methods, especially PQD and collision-cell CID, where efficient MS/MS is observed over only a very narrow range of relative collision energies.
The above noted and various other aspects of the present invention will become apparent from the following description which is given by way of example only and with reference to the accompanying drawings, not drawn to scale, in which:
The following description is presented to enable any person skilled in the art to make and use the invention, and is provided in the context of a particular application and its requirements. Various modifications to the described embodiments will be readily apparent to those skilled in the art and the generic principles herein may be applied to other embodiments. Thus, the present invention is not intended to be limited to the embodiments and examples shown but is to be accorded the widest possible scope in accordance with the features and principles shown and described. The particular features and advantages of the invention will become more apparent with reference to the appended
It is generally observed that, as collision energy is increased from a low value, a threshold or onset collision energy will be observed at which the number of observed fragment ions rapidly increases from an initial value of nil. This yield of fragment ions is further observed to increase, with increasing collision energy, up to some maximum value. Further increase in collision energy beyond that corresponding to the maximum corresponds to diminishing fragment yield which decreases back to essentially zero yield at some energy. U.S. Pat. No. 6,124,591, in the names of inventors Schwartz et al. and assigned to the assignee of the present invention discloses a linear calibration of an optimum or “best” collision energy versus mass to charge ratio (m/z). In practice, a measure of the magnitude of the collision energy is exposed to a mass spectrometer end-user as a “normalized collision energy” (NCE, also referred to by the acronym NRCE for “normalized relative collision energy”). The slope and intercept of this relationship are derived from the points, given here as co-ordinate pairs, ((m/z)1, (V1/BESTCE)) and ((m/z)2, (V2/BESTCE)), where (m/z)1 and (m/z)2 are a first and second precursor ion mass-to-charge ratio, V1 and V2 are voltage settings which correspond to the respective optimum collision energies, and the parameter “BESTCE” is an arbitrary number which is presented as percentage (or percentage×100) corresponding to the pre-determined “best collision energy value”, that is to say, the collision energy that gives the optimum fragment yield. The percentage value, as used here, is a percentage of the maximum instrumentally allowable collision energy at the particular (m/z) under consideration. For instance, let BESTCE be equal to 30%. The collision energy (volts) is then set by the equation,
V=NCE×(slope×mass+intercept)
where NCE is a number from 0%-100%. Thus if the user sets NCE=30%, the “best” voltages (corresponding maximum fragmentation) from a prior calibration will be used for any given entered m/z. Any other NCE gives an actual collision energy scaled by the factor NCE/30 relative to this best voltage. In addition, the slope and intercepts will be unique to each individual mass spectrometer system such that the same optimum dissociation conditions are accomplished for all systems.
The normalized relative collision energy method performs very well for CID as performed by resonant excitation in a quadrupole ion trap mass spectrometer (QIT), for which high quality MS/MS spectra are produced over the NCE range 25%-50% for most precursor ions (e.g., see curve 201 of
A solution to this high NCE sensitivity problem is to implement a scale whose lower bound and possibly width changes with mass, such that the zero-point (minimum allowable voltage) and the voltage range may change with mass. Such a moveable collision energy or fragmentation energy scale is referred to herein as “useable collision energy” (UCE). To illustrate this process, consider
From inspection of
For the experimental results illustrated in
VCE=a(m/z)2+b(m/z)+c Eq. 1
where the parameters a, b and c are fit coefficients. For instance, the curves 303 and 305 may be respectively approximated by the two equations
VCE0=a0(m/z)2+b0(m/z)+c0 Eq. 2a
and
VCEmax=a1(m/z)2+b1(m/z)+c1 Eq. 2b
in which VCE0 and VCEmax are the collision energy voltages for the fitted fragmentation onset and fragmentation maximum curves as functions of the mass variable, m/z, respectively, and a0, b0, c0, a1, b1 and c1 are the appropriate fit coefficients. Alternatively, other mathematical relationships that describe V in terms of mass could be used, such as linear, power law etc.
For consistency and compatibility with the existing NCE-type treatment, it is desirable that the useable collision energy voltage setting, V, is cast in the form
VCE=UCE×(Slopem/z)+(Interceptm/z)
in which subscripts are utilized to indicate that the values of slope and intercept are (m/z)-dependent. At any given (m/z), the values of “slope” and “intercept” may be calculated according to the following example and with reference to
Dotted-line curve 404 in
By performing the above-noted steps at several mass values, the variation of VCEmax and V2 with the mass variable may be determined and used to determine the values of the coefficients a1, b1, c1 and a2, b2 and c2 in the equations:
VCEmax=a1(m/z)2+b1(m/z)+c1 Eq. 2b
V2=a2(m/z)2+b2(m/z)+c2. Eq. 2c
Then, at any mass, the slope and intercept of a linear equation that provides VCE as a function of a desired UCE value are:
so that VCE is given by
VCE(UCE;m/z)=Interceptm/z+(Slopem/z×UCE) Eq. 4
and, thus, can be set for a desired UCE at any value of mass. Modifications to the above-described method can be envisioned to account for the fragmentation energy dependence of ions having different charge states. For example, the resulting UCE value could be multiplied by a charge state dependent factor which decreases the applied fragmentation energy as charge state increases. Alternatively, different calibrations could be developed for different precursor charge states, in which case the (m/z)-dependence illustrated in the above equations becomes a pure mass-dependence.
The step 602 of obtaining fragmentation data at several values of the mass variable will generally comprise fragmenting several precursor ions having various different ionic masses. The mass variable need not specifically be mass-to-charge ratio but could actually be mass (if all ionic charges are the same) or could be some mathematical transformation of mass or mass-to-charge. The fragmentation-energy-related variable may be any independently controlled instrumental variable that may be adjusted so as to vary fragmentation energy (or other form of energy) that is imparted to the precursor ions so as to cause ion fragmentation. The fragmentation-energy-related variable may be (or may correspond to) a voltage that is applied to electrodes so as to accelerate ions, or for example, be the energy-per-pulse or continuous-wave power of a laser for doing photodissociation. If the voltage is oscillatory, as in the resonance excitation technique, the relevant fragmentation-energy-related variable may be (or may correspond to) the amplitude of the voltage oscillations.
In step 604 of the method 600, the fragmentation-yield data obtained in step 602 is fit to a mathematical relationship between yield and the fragmentation-energy-related variable. This fitting procedure comprises generating a mathematical model approximation to at least a portion of the fragmentation-yield data, as a function of the fragmentation-energy-related variable. For instance, the Gaussian curve 404 in
In step 608 of the method 600, results obtained from the fitting procedure performed in the prior step are used to determine parameters that describe the variation, with mass, of the fragmentation-energy-related variable corresponding to the UCE reference points. For instance, this step could include determining the values of the coefficients a1, b1, c1 and a2, b2 and c2 in the equations 2a, 2b so that the variation of the UCE reference points may be calculated at any mass. Examples of the variation with mass of two UCE reference points are given as curves 303, 305 in
One aspect of collision energy calibration for MS/MS that this technique does not address is the fact that despite the general applicability of CID to many ionic species, variations in structure can cause some ions to require more or less voltage than a typical ion at that mass and charge. This problem is fundamentally beyond the scope of this invention, and must be addressed either through the MS/MS technique itself, or other calibration techniques, although this invention still allows adjustability to higher collision energy values required for these particular ions.
The discussion included in this application is intended to serve as a basic description. Although the present invention has been described in accordance with the various embodiments shown and described, one of ordinary skill in the art will readily recognize that there could be variations to the embodiments and those variations would be within the spirit and scope of the present invention. The reader should be aware that the specific discussion may not explicitly describe all embodiments possible; many alternatives are implicit. Accordingly, many modifications may be made by one of ordinary skill in the art without departing from the spirit, scope and essence of the invention. Neither the description nor the terminology is intended to limit the scope of the invention. Any publications, patents or patent application publications mentioned in this specification are explicitly incorporated by reference in their respective entirety.
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