EP1102984A1 - Method for separation of isomers and different conformations of ions in gaseous phase - Google Patents
Method for separation of isomers and different conformations of ions in gaseous phaseInfo
- Publication number
- EP1102984A1 EP1102984A1 EP99936208A EP99936208A EP1102984A1 EP 1102984 A1 EP1102984 A1 EP 1102984A1 EP 99936208 A EP99936208 A EP 99936208A EP 99936208 A EP99936208 A EP 99936208A EP 1102984 A1 EP1102984 A1 EP 1102984A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- ions
- ion
- analyzer region
- faims
- compensation voltage
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Ceased
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/62—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating the ionisation of gases, e.g. aerosols; by investigating electric discharges, e.g. emission of cathode
- G01N27/622—Ion mobility spectrometry
- G01N27/624—Differential mobility spectrometry [DMS]; Field asymmetric-waveform ion mobility spectrometry [FAIMS]
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D59/00—Separation of different isotopes of the same chemical element
- B01D59/44—Separation by mass spectrography
- B01D59/46—Separation by mass spectrography using only electrostatic fields
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D59/00—Separation of different isotopes of the same chemical element
- B01D59/44—Separation by mass spectrography
- B01D59/48—Separation by mass spectrography using electrostatic and magnetic fields
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J49/00—Particle spectrometers or separator tubes
- H01J49/004—Combinations of spectrometers, tandem spectrometers, e.g. MS/MS, MSn
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J49/00—Particle spectrometers or separator tubes
- H01J49/02—Details
- H01J49/04—Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components
- H01J49/0431—Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components for liquid samples
- H01J49/044—Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components for liquid samples with means for preventing droplets from entering the analyzer; Desolvation of droplets
Definitions
- the present invention relates to a method for separating isomers and different conformations of ions in gaseous phase, based on the principle of high field asymmetric waveform ion mobility spectrometry.
- ion mobility spectrometry gas-phase ion mobilities are determined using a drift tube with a constant electric field. Ions are gated into the drift tube and are subsequently separated based upon differences in their drift velocity.
- the ion drift velocity is proportional to the electric field strength at low electric fields (e.g., 200 V/cm) and the mobility, K, which is determined from experimentation, is independent of the applied field.
- the ion drift velocity may no longer be directly proportional to the applied field, and K becomes dependent upon the applied electric field (see G. Eiceman and Z. Karpas, Ion Mobility Spectrometry (CRC. Boca Raton, FL. 1994); and E.A. Mason and E.W. McDaniel, Transport Properties of Ions in Gases (Wiley, New York, 1988)).
- K is better represented by K h , a non-constant high field mobility term.
- FIMS high field asymmetric waveform ion mobility spectrometry
- transverse field compensation ion mobility spectrometry or field ion spectrometry
- Ions are separated in FAIMS on the basis of the difference in the mobility of an ion at high field K h relative to its mobility at low field K.
- MSA Mine Safety Appliances Company of Pittsburgh, Pa.
- the MSA instrument is described in U.S. Patent No. 5,420,424 and is available under the trade mark FIS (for Field Ion Spectrometer). While the use of the MSA instrument (and similar instruments based on the FAIMS concept) for trace gas analysis is known, the inventors believe that they have identified certain heretofore unrealized properties of these instruments which make them more versatile. Based on this realization, the inventors have developed what is believed to be a previously unknown method for separation of isomers and different conformations of ions. A summary and detailed description of the present invention is provided below.
- the present invention provides a method for identifying ions having substantially the same mass to charge ratio but having different ion mobility characteristics, comprising the steps of:
- the method may further comprise the step of setting said direct current compensation voltage to correspond to one of said peaks to separate a desired ion from other ions with substantially the same mass to charge ratio.
- the above method is operable at substantially at atmospheric pressure and substantially at room temperature.
- the method may further include detecting said transmitted ions by mass spectrometry.
- the method includes providing a gas flow through said analyzer region, so as to transport said ions along said analyzer region, although it will be understood that other ion transport means are possible.
- peak is not limited to the apex of the peak, and that a peak will typically have a noticeable width, or a compensation voltage range in which the peak appears.
- Figure 1 shows three possible examples of changes in ion mobility as a function of the strength of an electric field
- Figure 2 illustrates the trajectory of an ion between two parallel plate electrodes under the influence of the electrical potential V(t);
- Figures 3A and 3B show schematically an embodiment of a modified FAIMS device;
- Figure 4 illustrates two opposite waveform modes which may be used with the apparatus of Figures 3A and 3B;
- Figures 5A and 5B show schematically the coupling of the FALMS apparatus of Figures 3A and 3B together with a mass spectrometer;
- Figures 6A and 6B shows schematically a FAIMS apparatus for measuring the ion distribution in the analyzer region
- Figures 7 illustrates the high voltage, high frequency asymmetric waveform applied to the FATMS apparatus shown in Figures 6A and 6B;
- Figure 8 illustrates varying ion arrival time profiles at the innermost ion collector electrode of the FAIMS apparatus in Figures 6A and 6B;
- Figure 9 shows an ion selected compensation voltage (IS-CV) spectra at five different DV values for a leudne/isoleucine mixture;
- Figure 10 trace (a) shows the IS-CV spectra, run separately, of a solution containing leucine and a solution containing isoleucine
- Figure 10 trace (b) shows an IS-CV spectrum of a leucine/isoleucine mixture
- Figure 11 A shows mass spectra for a leucine/isoleucine mixture before filtering through a FATMS analyzer
- Figures 11B and 11C show mass spectra for a leucine/isoleucine mixture after filtering through a FAIMS analyzer at two different CV values;
- Figure 12 shows a response curve for leucine plotted as a function of concentration;
- Figure 13 shows an expanded view of an IS-CV spectrum acquired for a solution containing 0.004 ⁇ M leucine and 2.496 ⁇ M isoleucine
- Figure 14A shows an ESI mass spectrum for a solution of bovine ubiquitin
- Figure 14B shows a total ion current CV (TIC-CV) spectrum of a solution of bovine ubiquitin
- Figures 14C-14E show mass spectra obtained at several different CV values;
- Figure 15 shows normalized IS-CV spectra for various charge states of bovine ubiquitin ranging from +5 to +13 using the same solution as that used for Figure 14;
- FIG. 16 A, 16C, and 16E show mass spectra showing the effect of the amount of acetic acid on ESI mass spectra of a solution of bovine ubiquitin;
- Figures 16B, 16D, and 16F show TIC-CV spectra corresponding to the ESI-mass spectra obtained in Figures 16 A, 16C, and 16E, respectively;
- Figures 17A-17I show IS-CV spectra showing the effect of the amount of acetic acid in a solution of bovine ubiquitin on the charge states +7, +8 and +9;
- Figures 18A-18I show IS-CV spectra showing the effect of the amount of HCl in a solution of bovine ubiquitin on the charge states +7, +8 and +9;
- Figure 19 shows normalized IS-CV spectra for the charge states +5 to +13 using a 5 ⁇ M solution of bovine ubiquitin (55% water) acidified to pH 2.1 using HCl;
- Figures 20A-20F show the effect of solvent composition on mass spectra, TIC-CV spectra, and IS-CV spectra of bovine ubiquitin;
- Figures 21A and 21B show the effect of adding NaCl to a solution of bovine ubiquitin on the IS-CV spectrum for charge state +8;
- Figures 21C through 21H show mass spectra of different CV values
- Figure 22A shows an IS-CV spectrum showing the dependence of sodium adduct ion intensity on the conformation for the +6 charge state of bovine ubiquitin;
- Figures 22B and 22C show mass spectra for the solution used in Figure
- Figure 23A shows an IS-CV spectrum for the +8 charge state of bovine ubiquitin using a solution containing phosphate
- Figures 23B-23D show mass spectra for the solution used in Figure 23A at three different CV values.
- Figure 24 is a plot showing the location of the peak maxima for all conformers of bovine ubiquitin observed in this study.
- the discussion below generally uses the term “ion” to mean a charged atomic or molecular entity, the “ion” can be any electrically charged particle, solid or liquid, of any size.
- the discussion below refers to both positively charged and negatively charged ions, and it will be understood by a person skilled in the art that, for any individual analysis, only one of these types of ions will be used.
- isomers to mean compounds having identical molecular formulas but which differ in the ways in which the atoms are bonded to each other.
- isomers may be constitutional isomers or stereoisomers. Constitutional isomers differ in the order and the way in which atoms are bonded together in their molecules. Stereoisomers differ only in the arrangement of their atoms in space. Stereoisomers that are nonsuperimposable mirror images of each other are called enantiomers. Stereoisomers that are not enantiomers are called diastereomers.
- the disclosure also uses the term "ion selected compensation voltage” (IS-CV) spectra which refers to scanning the compensation voltage applied to a FAIMS analyzer, as discussed below, typically while monitoring a single mass-to- charge (m/z) value.
- the term “total ion current compensation voltage” (TIC-CV) spectra is also used to refer to a compensation voltage scan which shows the sum of a signal for all detected ions in a given m/z range.
- an ion 1 for example a type A ion shown in Figure 1, that is being carried by a gas stream 6 between two spaced apart parallel plate electrodes 2, 4 as shown in Figure 2.
- the space between the plates 2, 4 defines an analyzer region 5 in which the separation of ions may take place.
- the net motion of the ion 1 between the plates 2, 4 is the sum of a horizontal x-axis component due to a flowing stream of gas 6 and a transverse y-axis component due to the electric field between the plates 2, 4.
- V(t) motion refers to the overall translation that the ion 1 experiences, even when this translational motion has a more rapid oscillation superimposed upon it.
- One of the plates is maintained at ground potential (here, the lower plate 4) while the other (here, the upper plate 2) has an asymmetric waveform, V(t), applied to it.
- the asymmetric waveform V(t) is composed of a high voltage component, V l7 lasting for a short period of time t 2 and a lower voltage component, V 2 , of opposite polarity, lasting a longer period of time t
- Figure 2 illustrates the ion trajectory 8 (as a dashed line) for a portion of the waveform shown as V(t).
- the peak voltage during the shorter, high voltage portion of the waveform will be called the "dispersion voltage” or DV in this disclosure.
- a constant negative dc voltage can be applied to this plate 2 to reverse, or "compensate” for this transverse drift.
- This dc voltage called the “compensation voltage” or CV in this disclosure, prevents the ion 1 from migrating towards either plate 2, 4.
- the ratio of K h to K may be different for each compound. Consequently, the magnitude of the compensation voltage CV necessary to prevent the drift of the ion toward either plate 2, 4 may also be different for each compound. Under conditions in which the compensation voltage CV is appropriate for transmission of one compound, the other will drift towards one of the plates 2, 4 and subsequently be lost.
- a FAIMS instrument or apparatus is an ion filter capable of selective transmission of only those ions with the appropriate ratio of K h to K.
- FATMS refers to any device which can separate ions via the above described mechanism, whether or not the device has focussing or trapping behaviour.
- MSA Mine Safety Appliances Company
- one way to extend the capability of instruments based on the FAIMS concept, such as the FATMS-E instrument, is to provide a way to determine the make-up of the FAIMS-E CV spectra more accurately, for example, by introducing ions from the FAIMS-E device into a mass spectrometer for mass-to- charge (m/z) analysis.
- ESI is one of several related techniques that involves the transfer of ions (which can be either positively or negatively charged) from liquid phase into the gas- phase.
- Kebarle has described four major processes that occur in electrospray ionization (intended for use in mass spectrometry): (1) production of charged droplets, (2) shrinkage of charged droplets by evaporation, (3) droplet disintegration (fission), and (4) formation of gas-phase ions (Kebarle, P. and Tang, L. Analytical Chemistry, 65 (1993) pp. 972A-986A).
- a liquid solution e.g.
- 50/50 w/w water /methanol is passed through a metal capillary (e.g., 200 ⁇ m outer diameter and 100 ⁇ m ID) which is maintained at a high voltage to generate the charged droplets, say +2000 V (50 nA) for example.
- the liquid samples can be pumped through at, say, l ⁇ L/min.
- the high voltage creates a very strong, non-constant electric field at the exit end of the capillary, which nebulizes the liquid exiting from the capillary into small charged droplets and electrically charged ions by mechanisms described by Kebarle and many others.
- Several related methods also exist for creating gas-phase ions from solution phase.
- ionspray which uses mechanical energy from a high velocity gas to assist in nebulization
- thermospray which applies heat instead of a voltage to the capillary
- nanospray which uses small ID capillaries.
- ESI is used to encompass any technique that creates gas-phase ions from solution.
- the FAIMS-E device designed and built by Mine Safety Appliances Company was modified to permit the introduction of ions using ESI.
- the inventors believe that the coupling of an ESI source together with a FAIMS-E device is not obvious as it is known that ions produced by ESI have a high degree of solvation, and that a FAIMS-E device may not function properly when exposed to high levels of solvent vapour.
- the inventors have developed various practical embodiments of an apparatus that combines an ESI source together with a FAIMS device to show that such coupling is possible.
- the FAIMS-E apparatus 10 is composed of two short inner cylinders or tubes 11, 12 which are axially aligned and positioned about 5 mm apart, and a long outer cylinder 13 which surrounds the two inner cylinders 11, 12.
- the inner cylinders 11, 12 (12 mm inner diameter, 14 mm outer diameter) are about 30 mm and 90 mm long, respectively, while the outer cylinder 13 (18 mm inner diameter, 20 mm outer diameter) is about 125 mm long. Ion separation takes place in the 2 mm annular space of FAIMS analyzer region 14 between the long inner cylinder 12 and the outer cylinder 13.
- the metal capillary of the ESI needle 15 was placed along the central axis of the shorter inner cylinder 11, terminating about 5 mm short of the gap or ion inlet between the two inner cylinders 11, 12.
- the positioning of the ESI needle 15 shown in Figures 3(A) and 3(B) differs from the positioning of the ionization source found in the MSA FAIMS-E device in that the ESI needle 15 does not extend through the long inner cylinder 12 to which the asymmetric waveform V(t) is typically applied.
- the FAIMS-E device 10 can be considered as an ion "filter", with the capability of selectively transmitting one type of ion out of a mixture. If a mixture of ions is presented continuously to the entrance of the FAIMS analyzer region 14, for example by an ESI needle 15, and the ions are carried along the length of the analyzer 14 by a flowing gas under conditions in which no voltages are applied to either the inner cylinder 12 or outer cylinder 13 (i.e. the electrodes are grounded), some finite level of transmission for every ion is expected, albeit without any separation.
- the detected current of any selected ion in this mixture should never exceed the current for that ion when it is transmitted through the device 10 in the no-voltages condition. It might also be expected that application of high voltages (i.e. application of transverse fields, perpendicular to the gas flows) designed to yield ion separation should not increase the ion transmission, but should decrease transmission through collisions with the walls of the cylinders 12, 13. That is, the asymmetric waveform might effectively narrow the "width" of the FAIMS analyzer region 14, and therefore should decrease the ion transmission.
- Compressed gas e.g. air or nitrogen
- a charcoal /molecular sieve gas purification cylinder not shown
- the gas exits the FAIMS-E 10 via the carrier out (C out ) and/or sample out (S out ) ports. All four gas flow rates can be adjusted.
- Non-volatile analytes are typically introduced into the FAIMS-E 10 using an ESI needle 15.
- volatile analytes may be introduced into the FAIMS-E 10 through the S in line, and a portion may be ionized as the compound(s) pass by a corona discharge needle.
- V FAIMS adjustable electrical potential
- V FAIMS is usually ground potential in FAIMS-E.
- a high frequency high voltage asymmetric waveform is applied to the long inner cylinder 12 to establish the electric fields between the inner and outer cylinders 12, 13.
- a dc offset voltage i.e. the compensation voltage CV added to FAIMS
- the electrometer 17 has been replaced by a sampler cone 18, placed at the end of the FAIMS cylinders 12, 13 as is shown in a simplified form in Figure 5B.
- the diameter of the orifice 19 in the sampler cone 18 is approximately 250 ⁇ m.
- the gas flows in the FAIMS-MS 20 are analogous to those in the FAIMS-E 10 except that the C out is divided into two components, namely the original C out and the flow through the orifice 19 into the mass spectrometer.
- the electrical waveforms applied to the long inner cylinder 12 are identical to those used in the FAIMS-E apparatus 10.
- the sampler cone 18 may be electrically insulated from the other components so a separate voltage OR can be applied to it. Furthermore, a voltage can be applied to the cylinders of the entire FAIMS unit (V FAIMS ) for the purpose of enhancing the sensitivity of the FAIMS-MS.
- Figure 5B shows the FAIMS cylinders 12, 13 at a 45 degree angle in relation to the sampler cone 18 of the mass spectrometer.
- Figure 5A showed the FAIMS cylinders 12, 13 at a 90 degree angle in relation to the sampler cone 18.
- the way i.e., the angle between the two tubes of the FATMS and the sampler cone 18
- the location in which the ions are extracted from the two tubes can also be changed. That is, the ions can be extracted anywhere along the separation region of the FATMS.
- FIG. 6A and 6B to demonstrate the focussing effect referred to above, a special FAIMS instrument was designed by the inventors and constructed to measure the ion distribution between the two cylinders (outer and inner cylinders) of a FAIMS device.
- This instrument will be referred to in this disclosure as the FAIMS-R1 -prototype 30 and is illustrated schematically in Figures 6A and 6B.
- Ions were generated inside of an electrically grounded cylinder 31 approximately 35 mm long and 20 mm i.d..
- the tip of an ionization needle 15 was typically located near the center of this tube, and at least 15 mm from the end of the FAIMS analyzer region 34.
- the FAIMS analyzer region 34 in this embodiment is composed of an outer tube 32 which is 70 mm long and 6 mm i.d., and which surrounds a 2 mm o.d. inner shield electrode 33.
- the inner shield electrode 33 is an electrically grounded stainless steel tube which is closed at the end that faces the ionization needle 15. This inner electrode 33 surrounds, and shields, an electrically isolated conductor 35 passing into its center.
- This innermost conductor 35 i.e the ion collector electrode
- the ions which surround the inner electrode 33 are forced inwards by a pulsed voltage. These ions travel from the FAIMS analyzer region 34 to the innermost conductor 35 through a series of 50 ⁇ m holes 38 drilled through the inner shield electrode 33.
- the holes drilled in the inner shield electrode 33 are positioned about 2 cm from the end facing the ionization needle 15, and are spaced about 0.5 mm apart for a distance of 10 mm on one side of the inner shield electrode 33.
- the holes 38 drilled in the inner shield electrode 33 are located in this manner to minimize the variability in distance between the inner shield electrode 33 and the outer cylinder 32 in the vicinity of these holes 38.
- FIG. 7 the high voltage, high frequency asymmetric waveform V(t), applied to the FATMS-Rl -prototype of Figures 6A and 6B, is shown.
- the waveform is divided into two parts, the focussing period and the extraction period.
- the waveform was synthesized by an arbitrary waveform generator (e.g. Stanford Research Systems model DS340, not shown) and amplified by a pulse generator (e.g. Directed Energy Inc., model GRX-3.0K-H, not shown).
- the frequency of the waveform, and the relative duration of the high and low voltage portions of the waveform could easily be modified.
- the high voltage, high frequency asymmetric waveform was applied to the outer cylinder 32 of the FAIMS-Rl-prototype 30 shown in Figures 6A and 6B. Since all other forms of FAIMS discussed in this disclosure have the waveform applied to the inner tube or electrode, confusion may arise from the "polarity" of the waveform and the polarity of CV.
- ions of type A shown in Figure 1 are focussed during application of the opposite polarity waveform and CV than that shown for the devices in Figures 3 A, 3B, 5 A and 5B.
- a given ion will pass through the FATMS device 30.
- the unit therefore acts like an ion filter. It is possible to fix conditions such that a single type of ion is isolated in the FATMS analyzer 34 although a mixture flows uniformly out of the exit of the FAIMS device 30 although a mixture of ions are presented to the inlet of the FATMS analyzer region 34.
- the second part of the waveform shown in Figure 7 (i.e. the extraction period) was used to pulse the ions out of the FATMS analyzer region 34 between the outer electrode 32, and the inner shield electrode 33 (shown in Figures 6A and 6B).
- the asymmetric waveform was replaced by a constant dc bias of approximately +30 V. This caused the ions from the annular space 34 between the outer electrode 32 and the inner shield electrode 33 to move in the direction of the inner shield electrode 33.
- the +30 V bias created an electric field of approximately 150 V/cm across the FAIMS analyzer region 34 and most ions located within this region 34 travelled across the 2 mm space in about 1 ms.
- the ion current due to the arrival of ions at the center inner shield electrode 33 can be predicted.
- Figure 8 illustrates the ion arrival times at the innermost ion collector electrode 35 observed by conducting these experiments.
- Each trace was recorded with 2500 V applied DV, but with variable CV voltages.
- the radial distribution of ions is not uniform across the annular space of the FAIMS analyzer region 34.
- the ions are focussed into a narrow band near the inner electrode 33, and therefore are detected as a high intensity pulse occurring very early after the extraction voltage has been applied.
- the ions are much more uniformly distributed between the walls of the concentric cylinders 32 33 making up the FAIMS analyzer region 34.
- a ( Figure 1) is focussed at DV 2500 volts, CV -11 volts in a given geometry (for example, the FAIMS-E device of Figures 3A-3B), is it reasonable to expect that the ion will also be focussed if the polarity of DV and CV are reversed, i.e. DV of -2500 volts and CV of +11 volts (both applied to the inner electrode). It would seem that the reversal of polarity is a trivial exercise and the ion should be focussed, however, this is not observed. Instead, the reversal of polarity in this manner creates the mirror image effect of the ion focussing behaviour of FAIMS.
- the FAIMS device coupled to a mass spectrometer as shown in Figure 5A was used.
- the electrospray needle was held at approximately -1900 V, giving an electrospray current of about 40 nA.
- the actual asymmetric waveform that was applied to the long inner cylinder of FATMS is shown in Figure 4 (Waveform #2).
- the maximum voltage of this waveform referred to as the dispersion voltage (DV) was varied between 0 and -3300 V (which was the limit of the instrument).
- the frequency of the asymmetric waveform was constant at about 210 kHz.
- the CV which was also applied to the long inner cylinder of the FAIMS analyzer, was scanned over specified voltage ranges.
- ions were not lost to the cylinder walls during their passage through the FAIMS analyzer and were transferred through an approximately 250 ⁇ m orifice 19 to the vacuum chamber of a mass spectrometer (PE SCIEX API 300 triple quadrupole).
- the MS orifice was electrically insulated from the FAIMS and a separate orifice voltage of -45 V was applied to it.
- an offset voltage of -45 V was also applied to the entire FAIMS unit (V FAIMS ) to enhance the sensitivity of the FAIMS-MS.
- the skimmer cone 18A of the MS was held at ground potential and the small ring electrode normally located behind the orifice of the API 300 was not incorporated into the present interface, resulting in some loss of sensitivity for low mass ions such as Leu and He.
- Compressed air was introduced into the carrier gas inlet (C in ) at a flow rate of 3 L/min. Gas exited through the carrier gas outlet (C out ) at 2 L/min and through the sample gas out port (S out ) at 1 L/min. There was no flow through the "sample gas in" port (S in ) in this study.
- the pressure inside the FAIMS analyzer was kept at approximately 770 torr.
- FATMS can be operated in any one of four modes, namely PI, P2, Nl or N2, where P and N describe ion polarity (positive and negative), and "1" and "2" are indicative of instrumental conditions.
- low mass ions m/z ⁇ 300
- Leu and He are transmitted in mode 1
- larger ions are transmitted in mode 2.
- the ESI source was tuned to generate negative ions.
- All CV and mass spectra were collected using Nl mode.
- the asymmetric waveform used for Nl operation is shown in Figure 4 (Waveform #2).
- Figure 10 trace (b) is the IS-CV spectrum of the mixture, as shown previously in Figure 9 trace (e), plotted over a narrower range of CV values.
- the peaks at CV values of 7.7 V and 8.4 V in the IS-CV spectrum shown in Figure 10 trace (a) may therefore be attributed to Leu and He, respectively.
- FATMS which continuously transmits one type of ion from a complex mixture is a significant improvement over conventional chromatographic methods of ion separation, especiaUy when interfaced to relatively slow scanning mass spectrometers.
- chromatographic methods for Leu and He are time-consuming (5-15 minute retention times) and result in narrow, finite impulses of analyte (5-30 seconds).
- the transient nature of these separation methods offers little flexibility in varying detection parameters and generally limits the degree to which the capabilities of the mass spectrometer may be exploited.
- ion separation is independent of several experimental parameters associated with classical chromatography such as the stationary phase.
- problems encountered with the compatibility of LC and CE buffers e.g. high salt content
- flow rates with the electrospray process are also eliminated.
- RECTIFIED SHEET (RULE 91) spectrum is complex, a commonly observed and often detrimental characteristic of electrospray mass spectra in the low-mass region. Peaks attributable to (CO 2 (CH 3 O)-; m/z -75), oxalate (m/z -89), Leu/He (M-H; m/z -130), ((M 2 - H)-; m/z -261) and ((Na(M - H) 2 _ ; m/z -283), among others, are present.
- the peak observed at m/z -135 is due to an impurity in the solvent or the ammonium hydroxide buffer.
- the signal intensity for the dimer (M 2 - H)" is roughly twice that of the molecular ions of Leu and He at a total analyte concentration of 10 ⁇ M.
- the mass spectra collected for the same sample mixture at CV values of 7.7 V and 8.4 V, i.e., the CV values of transmission of Leu and He, respectively, are simple and show one intense peak at m/z -130 as shown in Figs. 11B and llC.
- the FATMS analyzer has effectively filtered out almost all of the background ions.
- He is sufficient to permit selective monitoring of one of the species without interference from the other.
- This was iUustrated by establishing response curves for both analytes present in a mixture.
- the response curve for Leu is shown in Figure 12.
- the total analyte concentration (i.e., [Leu] + [Tie]) in solution was kept constant at 2.500 ⁇ M, with the individual concentrations of each analyte varying over more than two orders of magnitude (i.e., from 0.004 to 2.496 ⁇ M).
- a protein is composed of a series of linked amino acids, chemically covalently bonded to each other. Since there are about 20 different types of amino acids which can be included in this chain, the first level of the description of the structure of a protein is the listing of the names of these amino acids in the sequence that they appear in the protein. This is called the amino acid sequence. Some of the amino acids have side groups which have the capability of creating chemical bonds to the side group of another amino acids someplace else in the amino acid sequence. This creates cross-linking. This cross linking is a very important structural element of proteins, because it forces certain areas of the protein sequence to be physically in close proximity to each other, in the final protein structure.
- the chains of amino acids have the capability of forming small structures including loops, and hairpin shape structures that involve only a small number of amino acids. These structures are formed because some of the side chains of the amino acids interact weakly (non-covalently) with one another, and if the appropriate amino acids are in close proximity, then these weakly held structures will spontaneously form.
- the combination of all of the smaller structures, and cross-links give the protein an overall 3 dimensional structure.
- This structure is called the 'conformation'.
- This structure can be disrupted or modified many ways. The heating of the protein will 'denature' the protein. This usually means that the protein loses its functional capability because the 3-dimensional structure has been modified. This can occur because of the breaking of a cross-linking bridge, or the disruption of small or large scale structures via addition of thermal energy to the molecule.
- Conformation therefore, describes the 3-dimensional structure of the protein.
- the protein has a conformation whether or not the protein is capable of performing it's normal chemical activity, i.e. native, or denatured.
- Some terminology which describes the 3-dimensional structure may be 'extended', 'elongated', which describes in a very non-specific way what we imagine the overall 3-dimensional structure will look like.
- Electrospray ionization (ESI) described above, has enabled the formation of intact gas-phase pseudo-molecular ions from large molecules, such as proteins. By coupling an ESI to a mass spectrometer (MS), ESI-MS has been used to provide information about conformations in solution. Since aqueous solutions at nearly physiological conditions are used in ESI-MS, this technique has been used to provide complementary structural information with other solution based methods such as Nuclear Magnetic Resonance (NMR).
- NMR Nuclear Magnetic Resonance
- FIG. 5A shows a schematic view of a ESI-F AIMS-MS instrument of the type that was used in this study of different conformations.
- the electrospray needle 15 and associated liquid delivery system were constructed by threading a 30 cm piece of fused silica capillary (50 ⁇ m i.d., 180 ⁇ m o.d.) through a 5 cm long stainless steel capillary (200 ⁇ m i.d., 430 ⁇ m o.d), with the fused silica capillary protruding about 1 mm beyond the end of the stainless steel capillary.
- This stainless steel capillary protruded about 5 mm beyond the end of a larger stainless steel capillary (500 ⁇ m i.d., 1.6 mm o.d.) that was used for structural support and application of the high voltage.
- Solutions were delivered to the electrospray needle by a syringe pump (Harvard Apparatus model 22), at a flow rate of 1 ⁇ L/min.
- the needle was held at approximately +2200 V giving an electrospray current of about 0.03 ⁇ A.
- the electrospray needle was placed on the center axis of the short inner cylinder, terminating about 5 mm short of the gap HA between the two inner cylinders 11 and 12.
- the electrospray ions were driven radially outward by the electric field to the analyzer region through the 5 mm gap HA between the two inner cylinders.
- a high frequency (210 kHz), high voltage (0 to 4950 V p-p), asymmetric waveform ( Figure 4) was applied to the long inner cylinder 12, thereby establishing the electric field between the inner and outer tubes.
- a compensation voltage CV was also applied to the long inner cylinder 12. Although the CV can be scanned from -50 V to +50 V, the CV spectra herein are only shown from -12 V to 0V since the ions of bovine ubiquitin were transmitted through FATMS within this CV window.
- the electrospray ions were carried by the gas stream along the length of the annular space between the outer cylinder and the long inner cylinder. If the combination of DV and CV was appropriate, and the ions were not lost to the tube walls, ions were transferred to the vacuum chamber of a mass spectrometer through the orifice 19 in the "sampler cone" 18 placed at the end of the FAIMS analyzer.
- a custom interface was constructed for a tandem combination of FAIMS and a PE Sciex API 300 triple quadrupole mass spectrometer.
- the voltage of the sampler cone 18 was set to 44 V, whereas the skimmer cone 18 A of the API 300 remained at ground potential for all experiments.
- the small ring electrode normally located behind the orifice of the conventional API 300 interface was not incorporated into the new interface, resulting in some loss of sensitivity.
- Q0 rf-only quadrupole
- Ion-selected CV spectra (IS-CV spectra) were obtained by scanning the compensation voltage applied to the FAIMS, while monitoring a single m/z value.
- "Total ion current" CV spectra (TIC-CV spectra) show the sum of the signal for all detected ions in a given m/z range as CV was scanned.
- the mass spectrum collected at fixed values of DV and CV revealed the identity of any ions transmitted through the FAIMS under those conditions.
- the ubiquitin ions described and used in this experiment behave as type
- an ESI-FAIMS-MS mass spectrum is shown for a solution of 5 ⁇ M bovine ubiquitin in 50/50/0.05 methanol/water/acetic acid (v/v/v) collected with FAIMS disabled.
- the solvent combination was selected for this illustration because several charge states are present.
- This mass spectrum essentially represents a conventional ESI-MS spectrum with somewhat lower sensitivity.
- Figure 14B shows a TIC-CV spectrum (m/z 30 to 2300), collected by scanning the CV from -12 V to 0 V, while
- Figures 14C-14E are mass spectra taken at specified CV values.
- Figures 14C-14E illustrate ESI-FAIMS-MS mass spectra of protein ions, taken at CV values indicated by the arrows in Figure 14B.
- the mass spectrum (FAIMS disabled) collected using a solution containing 0.4% HOAc (Figure 16C) shows a second charge state distribution, centered around [M + 12H] 12+ , in addition to the distribution centered at [M + 7H] 7+ . This second distribution is consistent with spectra collected for bovine ubiquitin in its denatured form as reported in an earlier study.
- Figures 17A-17C are the IS-CV spectra of the +7, +8, and +9 charge states, respectively, collected using 0.04% acetic acid. These spectra reflect conditions in which the bovine ubiquitin is essentially in its native state. For charge state +8 in Figure 17B, two main peaks are observed at CV ⁇ -9 V and ⁇ -7 V. With 0.4% acetic acid, in the same solution, Figure 17E, the IS-CV spectrum for charge state +8 changes significantly. The peak that is observed CV ⁇ -9V is now virtually absent from the spectrum and a new peak at CV • — 5 V is visible.
- the CV spectra and mass spectra shown in Figure 20 illustrate the effect of changing the solvent mixture from 50:50 water/MeOH Figures 20A, 20C, and 20E, to 55:45 water/MeOH v/v Figures 20B, 20D, and 20F, while maintaining low acid (0.04% HOAc) concentration.
- increasing amounts of organic solvent cause bovine ubiquitin to denature.
- Figure 23 shows ESI-FAIMS-MS data collected using an excess of potassium di-hydrogen phosphate added to a solution of 5 ⁇ M bovine ubiquitin in 50% H 2 O and 0.02% acetic acid.
- Figure 23A shows an IS-CV spectrum for the +8 charge state of bovine ubiquitin that is very similar to that observed previously in this study for solutions of 50% H 2 O, Figure 21A.
- the change in the relative abundances of the conformers at CV ⁇ -9 V and ⁇ -5 V compared with, for example, Figure 21A can be attributed to the change in pH caused by the difference in HOAc concentration, and added KH 2 PO 4 .
- Figure 15 were not a consequence of the formation of multimers or other cluster ions, different concentrations of bovine ubiquitin were studied. For the concentration range from 1 ⁇ M to 100 ⁇ M bovine ubiquitin (in 50% water and 0.04% acetic acid), no significant changes in the shapes of the IS-CV spectra for any charge state were observed. If the multiple peaks in an IS-CV spectrum were caused by the formation of cluster ions, the relative amounts of the various peaks in an IS-CV spectrum would change as a function of concentration.
- ESI-drift tube mobility spectrometry/MS has been used to examine the conformations of a number of proteins.
- the separation of conformers in a drift tube is based on the ion cross section, whereas the separation of ions in FAIMS is based on heretofore unknown properties of the ions. It is expected therefore, that there will be many similarities, and also significant differences in the array of conformations detected by these two, independent approaches.
- the "low acid” solution contained 55% H 2 O and 0.04% acetic acid while the “high acid” solution contained 55% H 2 O and the pH adjusted to 2.1 with HCl.
- the peak maxima that were observed in the IS-CV spectra were classified as being observed either in the "low acid” solution, the "high acid” solution, or both.
- the CV remains approximately constant between -5 and -6 V independent of the acid concentration (pH).
- the remaining charge states i.e., +5 through +9
- there are several resolved conformers, and the relative abundances of the conformers is dependent on the solution conditions.
- the most negative CV values are observed for conformers only present in the "low acid” solution.
- For charge states +5 through +8, Valentine et. al. reported the co-existence of elongated and partially folded conformations. Consequently, both FAIMS, and drift tube mobility spectrometry techniques identified the same charge states having a multiplicity of conformations.
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Abstract
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US9548198P | 1998-08-05 | 1998-08-05 | |
US95481P | 1998-08-05 | ||
CA2260572 | 1999-01-29 | ||
CA002260572A CA2260572A1 (en) | 1998-08-05 | 1999-01-29 | Apparatus and method for atmospheric pressure 3-dimensional ion trapping |
US09/321,820 US6504149B2 (en) | 1998-08-05 | 1999-05-28 | Apparatus and method for desolvating and focussing ions for introduction into a mass spectrometer |
US321820 | 1999-05-28 | ||
PCT/CA1999/000714 WO2000008454A1 (en) | 1998-08-05 | 1999-08-05 | Method for separation of isomers and different conformations of ions in gaseous phase |
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EP99936208A Ceased EP1102984A1 (en) | 1998-08-05 | 1999-08-05 | Method for separation of isomers and different conformations of ions in gaseous phase |
EP99936212A Expired - Lifetime EP1102986B8 (en) | 1998-08-05 | 1999-08-05 | Apparatus and method for atmospheric pressure 3-dimensional ion trapping |
EP99936210A Expired - Lifetime EP1102985B8 (en) | 1998-08-05 | 1999-08-05 | Method for separation and enrichment of isotopes in gaseous phase |
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EP99936210A Expired - Lifetime EP1102985B8 (en) | 1998-08-05 | 1999-08-05 | Method for separation and enrichment of isotopes in gaseous phase |
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EP (3) | EP1102984A1 (en) |
JP (2) | JP2002522873A (en) |
AT (2) | ATE308751T1 (en) |
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DE69928111T2 (en) | 2006-07-27 |
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