The present disclosure relates generally to mass spectrometry instruments, and more specifically to single particle mass spectrometry employing an orbitrap to measure ion m/z and charge.
Mass Spectrometry provides for the identification of chemical components of a substance by separating gaseous ions of the substance according to ion mass and charge. Various instruments and techniques have been developed for determining the masses of such separated ions, and the choice of such instruments and/or techniques generally will typically depend on the mass range of the particles of interest. For example, in the analysis of “lighter” particles in the sub-megadalton range, e.g., less than 10,000 Da, conventional mass spectrometers may typically be used, some examples of which may include time-of-flight (TOF) mass spectrometers, reflectron mass spectrometers, Fourier transform ion cyclotron resonance (FTICR) mass spectrometers, quadrupole mass spectrometers, triple quadrupole mass spectrometers, magnetic sector mass spectrometers, and the like.
In the analysis of “heavier” particles in the megadalton range, e.g., 10,000 Da and greater, conventional mass spectrometers of the type just described are not well-suited due to well-known, fundamental limitations of such instruments. In the riegadalton range, one alternate mass spectrometry technique, known as charge detection mass spectrometry (CDMS), is generally more suitable. In CDMS, ion mass is determined for each ion individually as a function of measured ion mass-to-charge ratio, typically referred to as “mlz,” and measured ion charge. Some such CDMS instruments employ an electrostatic linear ion trap (FLIT) detector in which ions are made to oscillate back and forth through a charge detection cylinder. Multiple passes of ions through such a charge detection cylinder provides for multiple measurements for each ion, and such multiple measurements are then processed to determine ion mass and charge.
Uncertainty in ion charge measurements in an FLIT can be made to be negligible, or nearly so, through appropriate design and operation of the detector. However, uncertainty in ion mass-to-charge ratio measurements remains undesirably high with current FLIT designs. In this regard, the mass-to-charge ratio resolving power obtainable with an orbitrap is generally understood to far surpass that which can be obtained in an FLIT used for CDMS, although poor charge measurement accuracy plagues current orbitrap designs.
The present disclosure may comprise one or more of the features recited in the attached claims, and/or one or more of the following features and combinations thereof. In one aspect, an orbitrap may comprise an elongated inner electrode defining a longitudinal axis centrally therethrough and a transverse plane centrally therethrough normal to the longitudinal axis, the inner electrode having a curved outer surface defining a maximum radius R1 about the longitudinal axis through which the transverse plane passes, an elongated outer electrode having a curved inner surface defining a maximum radius R2 about the longitudinal axis through which the transverse plane passes, wherein R2>R1 such that a cavity is defined between the inner surface of the outer electrode and the outer surface of the inner electrode, and means for establishing an electric field configured to trap an ion in the cavity and cause the trapped ion to rotate about, and oscillate axially along, the inner electrode, wherein the rotating and oscillating ion induces a charge on at least one of the inner and outer electrode, wherein R1 and R2 are selected to have values that maximize a percentage of the induced charge as a function of ln(R2/R1).
In another aspect, an orbitrap may comprise an elongated inner electrode defining a longitudinal axis centrally therethrough and a transverse plane centrally therethrough normal to the longitudinal axis, an elongated outer electrode defining a curved inner surface having a maximum radius R2, about the longitudinal axis, through which the transverse plane passes, wherein a cavity is defined between an outer surface of the inner electrode and the inner surface of the outer electrode, means for establishing an electric field configured to trap an ion in the cavity and to cause the trapped ion to rotate about, and oscillate axially along, the inner electrode, wherein the rotating and oscillating ion induces a charge on at least one of the inner and outer electrode, and a characteristic radius Rm, about the longitudinal axis, corresponding to a radial distance from the longitudinal axis at which the established electric field no longer attracts ions toward the longitudinal axis, wherein values of Rm and R2 are selected to maximize a percentage of the induced charge as a function of (Rm/R2).
In yet another aspect, an orbitrap may comprise an elongated inner electrode defining a longitudinal axis centrally therethrough and a transverse plane centrally therethrough normal to the longitudinal axis, the inner electrode defining two axially spaced apart inner electrode halves with the transverse plane passing therebetween, an elongated outer electrode defining two axially spaced apart outer electrode halves with the transverse plane passing therebetween, a cavity defined radially about the longitudinal axis and axially along the inner and outer electrodes between an outer surface of the inner electrode and an inner surface of the outer electrode, means for establishing an electric field configured to trap an ion in the cavity and to cause the trapped ion to rotate about, and oscillate axially along, the inner electrode, wherein the rotating and oscillating ion induces charges on the inner and outer electrode halves, and charge detection circuitry configured to detect charges induced by the rotating and oscillating ion on the inner electrode halves and on the outer electrode halves, and to combine the detected charges for each oscillation to produce a measured ion charge signal.
In still another aspect, a system for separating ions may comprise an ion source configured to generate ions from a sample, at least one ion separation instrument configured to separate the generated ions as a function of at least one molecular characteristic, and the orbitrap as described above in any one or combination of the above aspects, further comprising an opening configured to allow passage of an one ion exiting the at least one ion separation instrument into the cavity for rotation about, and oscillate axially along, the inner electrode.
In a further aspect, a system for separating ions may comprise an ion source configured to generate ions from a sample, a first mass spectrometer configured to separate the generated ions as a function of mass-to-charge ratio, an ion dissociation stage positioned to receive ions exiting the first mass spectrometer and configured to dissociate ions exiting the first mass spectrometer, a second mass spectrometer configured to separate dissociated ions exiting the ion dissociation stage as a function of mass-to-charge ratio, and a charge detection mass spectrometer (CDMS), including the orbitrap as described above in any one or combination of the above aspects, coupled in parallel with and to the ion dissociation stage such that the CDMS can receive ions exiting either of the first mass spectrometer and the ion dissociation stage, wherein masses of precursor ions exiting the first mass spectrometer are measured using CDMS, mass-to-charge ratios of dissociated ions of precursor ions having mass values below a threshold mass are measured using the second mass spectrometer, and mass-to-charge ratios and charge values of dissociated ions of precursor ions having mass values at or above the threshold mass are measured using the CDMS.
For the purposes of promoting an understanding of the principles of this disclosure, reference will now be made to a number of illustrative embodiments shown in the attached drawings and specific language will be used to describe the same.
This disclosure relates to apparatuses and techniques for carrying out single particle mass spectral analysis of substances which may typically, although not exclusively, include particles having particle masses in the megadalton (MDa) range. As will be described in detail below, the apparatuses and techniques include as one component thereof at least one embodiment of a so-called “orbitrap.” For purposes of this disclosure, an “orbitrap” is defined as an electrostatic ion trap which employs orbital trapping in an electrostatic field and in which particles oscillate both radially about and along a central longitudinal axis of an elongated center or “inner” electrode.
Referring now to
The outer barrel-like electrode 14 is split between two axial halves 14A and 14B with a space 16 between the two halves generally aligned with the axial center of the inner electrode 12. A cavity 15 is formed between the inner surfaces of the outer electrodes 14A and 14B and the outer surface of the inner electrode 12 and, like the outer surface of the inner electrode 12, inner surfaces of the two axial halves 14A and 14B of the outer electrode 14 are symmetrical such that the shape of the cavity 15 between the outer electrode half 14A and the inner electrode 12 is the same as the shape of the cavity between the outer electrode half 14B, i.e., on each side of the space 16. Opposite the outer surface of the inner electrode 12, the inner surface of the outer electrode 14 has a maximum inner radius R2 at the longitudinal center, i.e., at the opposing edges of the space 16, which tapers downwardly in the axial direction to a minimum radius at or adjacent to each end. Like the maximum outer radius R1 of the inner electrode 12, the maximum inner radius R2 of the outer electrode 14 is measured radially from the Z-axis. As illustrated by example in
Each of the inner electrode 12 and the outer electrode 14 are electrically coupled to one or more voltage sources 22 operable to selectively apply control voltages to each. In some implementations, the one or more voltage sources 22 are electrically connected to a processor 24 via N signal paths, where N may be any positive integer. In such implementations, a memory 26 has instructions stored therein which, when executed by the processor 24, cause the processor 24 to control the one or more voltage sources 22 to selectively apply control or operating voltages to each of the inner and outer electrodes 12, 14 respectively.
Each of the outer electrodes 14A and 14B are electrically coupled to respective inputs of a conventional differential amplifier 28, and the output of the differential amplifier 28 is electrically coupled to the processor 24. The memory 26 has instructions stored therein which, when executed by the processor 24, cause the processor 24 to process the output signal produced by the differential amplifier to determine mass-to-charge information of particles trapped within the orbitrap 11.
In operation, the one or more voltage sources 22 are first controlled to apply suitable potentials to the inner and outer electrodes 12, 14 to create a corresponding electric field oriented to draw charged particles, i.e., ions, into the cavity 15 via the external opening 16A of the space 16. The one or more voltage sources 22 are then controlled to apply suitable potentials to the inner and outer electrodes 12, 14 to create an electrostatic field within the cavity 15 which traps the charged particles therein. This electrostatic field between the inner and outer electrodes 12, 14 has a potential distribution U(r, z) which is defined by the following equation:
U(r,z)=k/2(z2)−(r2−R12)/2(k/2×Rm2×ln[r/R1])−Ur (1),
where r and z are cylindrical coordinates (with z=0 being the plane of symmetry of the field), k is the field curvature, R1 is the maximum radius of the inner electrode 12 (as described above) and Ur is the potential applied to the inner electrode 12. Rm is a so-called “characteristic radius,” which is the radial distance from the Z-axis at which the electrostatic field no longer attracts ions toward the Z-axis, and it is generally understood that for stable radial oscillations of ions during electrostatic trapping the relationship Rm/R2>21/2 must typically be satisfied. This electrostatic field is the sum of a quadrupole field of the ion trap 11 and a logarithmic field of a cylindrical capacitor, and is accordingly generally referred to as a quadro-logrithmic field.
Trajectories 25 of ions trapped within the cavity 15 of the orbitrap 11 under the influence of the quadro-logrithmic field are a combination of orbital motion about the inner electrode 12 and oscillations along the inner electrode 12 in the direction of the Z-axis, as illustrated by example in
By solving equation (1) for the boundary condition U(R2, 0)=0, the field curvature k is defined by the following equation:
k=2Ur×(1/(Rm2×ln(R2/R1)−½(R22−R12))) (2).
Because the field curvature k is defined by equation (2) in terms of electrode geometry, the frequency ω of axial ion oscillations can be related to ion mass-to-charge ratio (m/z) by the following equation:
ω=SQRT(e×k/(m/z)) (3),
where e is the elemental charge. Equation (3) shows that the ion axial oscillation frequency (and hence the rn/z ratio) is independent of ion kinetic energy. Inserting (2) into (3) produces the following relationship:
ω=SQRT[(e/(m/z))×(2Ur×(1/(Rm2×ln(R2/R1)−½(R22−R12))))] (4).
Equation (4) shows that the frequency ω of ion oscillations is proportional to the square root of the potential Ur applied to the inner electrode 12, is correlated with the inner electrode maximum radius R1 and is inversely correlated with the remaining radial dimensions of the orbitrap 11. Using equation (1), the shapes z12(r) and z
Using equation (1), the radial shapes, i.e., contours, z12(r) and z14(r) of the outer and inner surfaces of the inner and outer electrodes 12, 14 respectively along the z direction can be deduced as follows:
z12(r)=SQRT[½r2−½R12+Rm2×ln(R1/r)] (5).
z14(r)=SQRT[½r2−½R22+Rm2×ln(R2/r)] (6).
Referring now to
In the embodiment illustrated in
The outer surface of the inner electrode 112 has a maximum outer radius R1 at its axial center, and the inner surface of the outer electrode 114 likewise has a maximum inner radius R2 at its axial center. The outer surface of the inner electrode 112 illustratively tapers downwardly along the Z-axis from the maximum radius R1 at its axial center to a reduced radius R3 at or near each opposed end, i.e., such that R1>R3. The inner surface of the outer electrode 114 likewise illustratively tapers downwardly along the Z-axis from the maximum radius R2 at its axial center to a reduced radius R4 at or near each opposed end, i.e., such that R2>R4. Generally, R2>R1>R4>R3.
Each of the inner electrode 112 and the outer electrode 114 are electrically coupled to one or more voltage sources 122 operable to selectively apply control voltages to each. In the illustrated embodiment, the one or more voltage sources 122 are electrically connected to a processor 124 via N signal paths, where N may be any positive integer. A memory 126 illustratively has instructions stored therein which, when executed by the processor 124, cause the processor 124 to control the one or more voltage sources 122 to selectively apply control or operating voltages to each of the inner and outer electrodes 112, 114 respectively. In alternate embodiments, the one or more voltage sources 122 may be or include one or more programmable voltage sources which can be programmed to selectively apply control or operating voltages to either or both of the electrodes 112, 114. In some such embodiments, operation of the one or more such programmable voltage sources may be synchronized with the processor 124 in a conventional manner.
Each of the inner electrode 112 and the outer electrode 114 are electrically coupled to respective inputs of charge detection circuitry 128, and a charge detection output of the circuitry 128 is electrically coupled to the processor 124. The memory 126 illustratively has instructions stored therein which, when executed by the processor 124, cause the processor 124 to process the charge detection output signal CD produced by the circuitry 128 to determine mass-to-charge and charge information of a single particle trapped within the orbitrap 110. In embodiments in which the inner electrode 112 is provided in the form of a single, unitary body, the circuitry 128 may illustratively take the fora of a differential amplifier of the type illustrated in
Some of the dimensions and relationships between various components of the orbitrap 110 illustrated in
In order to increase the fraction of detected ion charge, the orbitrap 110 is illustratively designed to provide for consistency in the radial and axial trajectories of single charged particles trapped in the orbitrap 110. With respect to the radial ion trajectory, the following simplified equation relates the radial motion of an ion to a circular trajectory in which the radius, r, of the circular trajectory is a function of the kinetic energy and of the electric field within the cavity 115:
R=2×Ek/F (7),
where Ek is the entrance kinetic energy, i.e., the kinetic energy of an ion entering the cavity 115, and F is the force experienced by the ion due to the electric field established within the cavity 115. Only a narrow distribution of ions close to the outer surface of the inner electrode 112 is trappable when the trapping electric field, resulting from application of corresponding potentials supplied by the one or more voltage sources 122, is applied. This distribution, along with the distribution of entrance kinetic energies, contributes to the radial distribution of ions in the orbitrap 110. The entrance kinetic energy required for trapping an ion in the orbitrap cavity 115 is defined by the following equation:
Ek=(k/4)×(Rm2−R2)×(R/Ri)2 (8),
where R is the final radial position of the ion in the trap (also referred to as the orbital radius of the ion) and Ri is the injection radius of the ion, i.e., the radial position of the ion relative to the Z-axis when injected into the cavity 115. Equation (8) reveals that the effect on ion charge measurements of ion kinetic energy distribution is dependent on the ratio R/Ri, and that this effect can be minimized by maximizing the value of R1 relative to the value of R. However, if only the outer electrode 114 is to be used to detect ion charge, then the orbital radius R should be maximized to increase the fraction of the ion's charge that is induced, and thus detectable, on the outer electrode 114. The range of values of the ratio R/Ri is defined by the minimum and maximum values of R1 and R2.
The fraction of ion charge induced on the detection electrode also depends on the ion's trajectory along the Z-axis; more specifically, on how the fraction of induced charge changes relative to the geometries, i.e., the curved contours; of the outer surfaces of the inner electrode 112 and outer electrode 114 as an ion moves along the Z-axis. The radial shapes; i.e., curved contours, z12(r) and z14(r) of the outer and inner surfaces of the inner and outer electrodes 112, 114 respectively are defined by the equations (5) and (6) and are thus dependent primarily on the values of R1, R2 and Rm.
The values of R1, R2 and Rm, and the relationships therebetween; are thus the primary variables which influence the radial and axial trajectories of single charged particles trapped in the orbitrap 110, and are thus the primary variables which may be optimized to maximize the fraction of charge induced on the detection electrode. In this regard, a plot is shown in
Simulations were run comparing the measured fraction of charge induced by a single trapped ion on the outer electrode 14 of two different conventional orbitraps 11 of the type illustrated in
In the orbitrap 110 of
In the embodiment illustrated in
Referring now to
Referring now to
Referring now to
Referring now to
Referring now to
Referring now to
Those skilled in the art will recognize that, in some of the embodiments, e.g., those illustrated in
Simulations were also run comparing the measured fraction of charge induced by a single trapped ion on the combination of two outer electrodes 14 and two (split) inner electrodes implemented in the two different conventional orbitraps 11 described above with the fraction of charge induced by a single trapped ion on the combination of the two outer electrodes 114A and 114B and the two (split) inner electrodes 112A, 112B of the orbitrap 110 of
Thus, regardless of the geometries of the orbitrap components, splitting the inner electrode into axial halves and using all four of the electrode halves to measure the induced ion charge results in a reduction in the charge uncertainty as compared with the same instrument in which a single, unitary inner electrode is implemented. Because the induced charge on the inner and outer detection electrodes on each side of the orbitrap are summed and the two sums are then subtracted from one another, the effects of differences in curvature between the MO sets of inner and outer electrodes on measured charge can be reduced. Substantial improvements in charge detection error can be realized in orbitraps having large differences in curvature between the inner and outer electrodes, such as those found in conventional orbitraps. Implementing a split inner electrode in such conventional orbitraps results in the percent measured charge approaching 100% as just described in the above simulations, thus demonstrating that substantial improvements in charge measurement accuracy can be realized in conventional orbitraps without modifying the geometric parameters of the orbitrap in the manner described herein. However, the combination of implementing a split inner electrode and optimizing the geometric parameters of an orbitrap as described herein yields the highest degree of charge measurement accuracy as also demonstrated in the above-described simulations.
Referring now to
The on source 202 illustratively includes at least one conventional ion generator configured to generate ions from a sample. The ion generator may be, for example, but not limited to, one or any combination of at least one ion generating device such as an electrospray ionization source, a matrix-assisted laser desorption ionization (MALDI) source or the like. In some embodiments, the ion source 202 may further include any number of ion processing instruments configured to act on some or all of the generated ions prior to detection by the orbitrap 110 as described above. In this regard, the ion source 202 is illustrated in
In some embodiments, the instrument 200 may include an ion processing instrument 204 coupled to the ion outlet of the orbitrap 110. As illustrated by example in
As one specific implementation of the ion separation instrument 200 illustrated in
As another specific implementation of the ion separation instrument 200 illustrated in
As yet another specific implementation of the ion separation instrument 200 illustrated in
As still another specific implementation of the ion separation instrument 200 illustrated in
Referring now to
MS/MS, e.g., using only the ion separation instrument 220, is a well-established approach where precursor ions of a particular molecular weight are selected by the first mass spectrometer 222 (MS1) based on their m/z value. The mass selected precursor ions are fragmented, e.g., by collision-induced dissociation, surface-induced dissociation, electron capture dissociation or photo-induced dissociation, in the ion dissociation stage 224. The fragment ions are then analyzed by the second mass spectrometer 226 (MS2). Only the m/z values of the precursor and fragment ions are measured in both MS1 and MS2. For high mass ions, the charge states are not resolved and so it is not possible to select precursor ions with a specific molecular weight based on the m/z value alone. However, by coupling the instrument 220 to the CDMS 206 as illustrated in
It will be understood that one or more charge detection optimization techniques may be used with the orbitrap 110 alone and/or in any of the systems 200, 210 illustrated in the attached figures and described herein e.g., for charge detection events. Examples of some such charge detection optimization techniques are illustrated and described in U.S. Patent Application Ser. No. 62/680,296, filed Jun. 4, 2018 and in International Patent Application No. PCT/US2019/013280, filed Jan. 11, 2019, both entitled APPARATUS AND METHOD FOR CAPTURING IONS IN AN ELECTROSTATIC LINEAR ION TRAP, the disclosures of which are both expressly incorporated herein by reference in their entireties.
It will be further understood that one or more charge calibration or resetting apparatuses may be used with the inner and/or outer electrodes of the orbitrap 110 alone and/or in any of the systems 200, 210 illustrated in the attached figures and described herein. An example of one such charge calibration or resetting apparatus is illustrated and described in U.S. Patent Application Ser. No. 62/680,272, filed Jun. 4, 2018 and in International Patent Application No. PCT/US2019/013284, filed Jan. 11, 2019, both entitled APPARATUS AND METHOD FOR CALIBRATING OR RESETTING A CHARGE DETECTOR, the disclosures of which are both expressly incorporated herein by reference in their entireties.
It will be still further understood that one or more ion source optimization apparatuses and/or techniques may be used with one or more embodiments of a source from which ions entering the orbitrap 110 are generated, such as in the source 202 in any of the systems 200, 210 illustrated and described herein, some examples of which are illustrated and described in U.S. Patent Application Ser. No. 62/680,223, filed Jun. 4, 2018 and entitled HYBRID ION FUNNEL-ION CARPET (FUNPET) ATMOSPHERIC PRESSURE INTERFACE FOR CHARGE DETECTION MASS SPECTROMETRY, and in co-pending International Patent Application No. PCT/US2019/013274, filed Jan. 11, 2019 and entitled INTERFACE FOR TRANSPORTING IONS FROM AN ATMOSPHERIC PRESSURE ENVIRONMENT TO A LOW PRESSURE ENVIRONMENT, the disclosures of which are both expressly incorporated herein by reference in their entireties.
It will be yet further understood that the orbitrap 110 alone and/or implemented in any of the systems 200, 210 illustrated in the attached figures and described herein may be implemented in systems configured to operate in accordance with real-time analysis and/or real-time control techniques, some examples of which are illustrated and described in U.S. Patent Application Ser. No. 62/680,245, filed Jun. 4, 2018 and co-pending International Patent Application No. PCT/US2019/013277, filed Jan. 11, 2019, both entitled CHARGE DETECTION MASS SPECTROMETRY WITH REAL TIME ANALYSIS AND SIGNAL OPTIMIZATION, the disclosures of which are both expressly incorporated herein by reference in their entireties.
It will be still further understood that the orbitrap 110 in a system, such as any of the systems 200, 210 illustrated in the attached figures and described herein, may be provided in the form of at least one orbitrap array having two or more orbitraps, and that the concepts described herein are directly applicable to systems including one or more such orbitrap arrays. Examples of some such array structures in which two or more orbitraps 110 may be arranged are illustrated and described in U.S. Patent Application Ser. No. 62/680,315, filed Jun. 4, 2018 and in co-pending International Patent Application No. PCT/US2019/013283, filed Jan. 11, 2019, both entitled ION TRAP ARRAY FOR HIGH THROUGHPUT CHARGE DETECTION MASS SPECTROMETRY, the disclosures of which are both expressly incorporated herein by reference in their entireties.
While this disclosure has been illustrated and described in detail in the foregoing drawings and description, the same is to be considered as illustrative and not restrictive in character, it being understood that only illustrative embodiments thereof have been shown and described and that all changes and modifications that come within the spirit of this disclosure are desired to be protected. For example, some improvements in single ion charge detection accuracy in an orbitrap have been described which include designing various orbitrap component geometries to achieve specified geometry goals. Other improvements in single ion charge detection accuracy in an orbitrap have also been described which include split the inner electrode into identical axial halves and using the two inner electrode halves as a second ion charge detector, wherein charge detection signals measured on the outer electrodes are combined with charge detection signals measured on the inner electrodes to produce a composite charge detection signal. In accordance with this disclosure, it will be understood that in some embodiments either set of improvements may be implemented in an orbitrap to the exclusion of the other, and that in other embodiments both sets of improvements may be implemented together in an orbitrap.
This application is a U.S. national stage entry of PCT Application No. PCT/US2019/013278, filed Jan. 11, 2019, which claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 62/769,952, filed Nov. 20, 2018, the disclosures of which are incorporated herein by reference in their entireties.
This invention was made with government support under CHE1531823 awarded by the National Science Foundation. The United States Government has certain rights in the invention.
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Number | Date | Country | |
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20220013349 A1 | Jan 2022 | US |
Number | Date | Country | |
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62769952 | Nov 2018 | US |