This application is a U.S. national phase filing claiming the benefit of and priority to International Patent Application No. PCT/GB2019/050494, filed on Feb. 22, 2019, which claims priority from and the benefit of United Kingdom patent application No. 1802917.3, filed on Feb. 22, 2018. The entire contents of these applications are incorporated herein by reference.
The present invention relates generally to methods of mass spectrometry, and particularly to methods and devices for performing charge detection mass spectrometry. Also provided is a method and device for attenuating an ion beam.
Charge detection mass spectrometry (CDMS) is a technique wherein the mass of an individual ion is determined by simultaneously measuring both the mass-to-charge ratio (m/z) and the charge of that ion. This approach may thus avoid the need to resolve multiple charge states associated with traditional mass spectrometry methods, especially where electrospray ionisation is used. An example of the CDMS technique is described in Keifer et al. “Charge Detection Mass Spectrometry with Almost Perfect Charge Accuracy”, Anal. Chem. 2015, 87, 10330-10337 (DOI: 10.1021/acs.analchem.5b02324).
From a first aspect there is provided a method of charge detection mass spectrometry comprising: monitoring a detector signal from a charge detector of a charge detection mass spectrometry device during a first ion trapping event within an ion trap of the charge detection mass spectrometry device to determine how many ions are present within the ion trap during the first ion trapping event.
The method may further comprise: when it is determined that no ions are present within the ion trap during the first ion trapping event, terminating the first ion trapping event and/or initiating a second ion trapping event.
The method may additionally, or alternatively, comprise: when it is determined that more than one ion is present within the ion trap during the first ion trapping event, terminating the first ion trapping event and/or initiating a second ion trapping event.
In embodiments, when it is determined that more than one ion is present within the ion trap during the first ion trapping event, the method may comprise ejecting or otherwise removing one or more of the ions from the ion trap. For example, the method may comprise ejecting or otherwise removing all of the ions from the ion trap and initiating a second ion trapping event. However, it is also contemplated that the method may comprise ejecting or otherwise removing less than all of the ions from the ion trap. For instance, the method may comprise ejecting or otherwise removing one or more of the ions from the ion trap so that (or until) only a single ion remains within the ion trap.
The number of ions that are present within the ion trap of the charge detection mass spectrometry device may, for example, be determined based on the number of masses recorded in a spectrum by the charge detection mass spectrometry device and/or based on the total charge detected by the charge detection mass spectrometry device. In embodiments, the number of ions that are present within the ion trap is determined by analysing a transient detector signal from the charge detector. For example, in embodiments, the determination may be made within less than about 1s of initiating an ion trapping event, such as within about 0.5s. In embodiments, the determination may be made within 0.2s, or within 0.1s.
The methods of the first aspect, in any of its embodiments, are generally performed using a charge detection mass spectrometry device. The charge detection mass spectrometry device may generally comprise an ion trap for holding one or more ions to be analysed and (at least) a charge detector within the ion trap for determining a charge for the one or more ions to be analysed. The charge detector may comprise one or more charge detecting electrode(s). The charge detection mass spectrometry device may also comprise control circuitry for processing the signals obtained, for example, from the charge detector. The charge detection mass spectrometry device may generally comprise part of a mass spectrometer. So, various ion guiding or manipulating components of the mass spectrometer may be provided upstream and/or downstream of the charge detection mass spectrometry device.
Accordingly, from a second aspect, there is provided a charge detection mass spectrometry device comprising: an ion trap for holding one or more ions to be analysed; one or more charge detector(s) within the ion trap for determining a charge for the one or more ions to be analysed; and control circuitry for monitoring a detector signal from the charge detector(s) during a first ion trapping event to determine how many ions are present within the ion trap during the first ion trapping event.
The present invention in the second aspect may include any or all of the features described in relation to the first aspect of the invention, and vice versa, to the extent that they are not mutually inconsistent. Thus, even if not explicitly stated herein, the device may comprise suitable means or circuitry for carrying out any of the steps of the method or invention as described herein.
In particular, when it is determined that no ions are present within the ion trap during the first ion trapping event the control circuitry may be configured to terminate the first ion trapping event and/or initiate a second ion trapping event.
Additionally, or alternatively, when it is determined that more than one ion is present within the ion trap during the first ion trapping event the control circuitry may be configured to terminate the first ion trapping event and/or initiate a second ion trapping event.
In embodiments, when it is determined that more than one ion is present within the ion trap during the first ion trapping event, the control circuitry may be configured to eject or otherwise remove one or more of the ions from the ion trap. For example, the control circuitry may cause all of the ions to be ejected or otherwise removed from the ion trap and to then initiate a second ion trapping event. However, it is also contemplated that less than all of the ions may be ejected (removed) from the ion trap. For instance, the control circuitry may be configured to eject or otherwise remove one or more of the ions from the ion trap so that only a single ion remains within the ion trap.
The number of ions that are present within the ion trap of the charge detection mass spectrometry device may be determined using suitable signal processing circuitry. The signal processing circuitry may, for example, be configured to analyse the (transient) signals in substantially real-time to determine how many ions are present within the ion trap during the first ion trapping event.
In embodiments, the geometry of the ion trap may be configured such that ion trajectories become unstable when more than one ion is present resulting in the ejection of all but one ion. In this way, when more than one is present within the ion trap during the first ion trapping period, the ion trap may be configured to naturally eject one or more ions.
In embodiments, a plurality of charge detection mass spectrometry devices are provided. Each charge detection mass spectrometry device may comprise an ion trap and one or more charge detector(s), and may each therefore be capable of performing an independent measurement. The plurality of charge detection mass spectrometry devices can then be used to perform simultaneous or parallel measurements.
For instance, in some embodiments, a plurality of such charge detection mass spectrometry devices may be arranged within an ion guide. Considered alternatively, a charge detection mass spectrometry device may be provided that comprises a plurality of ions traps, or ion trapping regions, each having an associated one or more charge detector(s), positioned within an ion guide.
In this case, the charge detection mass spectrometry device may be arranged to increase the likelihood of their being (only) a single ion within the ion traps (or trapping regions). For example, each of the ion traps may be configured such that ion trajectories become unstable when more than one ion is present resulting in the ejection of all but one ion. At the same time, the ion guide may provide overall (radial) confinement of the ions. Accordingly, when a plurality of ions are injected into the ion guide, the ions may naturally distribute themselves between the plurality of ion traps (trapping regions) due to space charge effects, and in embodiments so that no more than one ion is present in any of the ion traps (trapping regions).
The method of the first aspect described above may be implemented within such an apparatus. In that case, the method may comprise monitoring the detector signal from each (or any) of the charge detection mass spectrometry devices to determine how many ions are present within each (or an) ion trap. However, it is believed that this apparatus is novel and inventive in its own right.
Thus, from a further aspect, there is provided a charge detection mass spectrometry device comprising: an ion guide for confining a plurality of ions, wherein the ion guide comprises a plurality of ion traps, and wherein the geometry of each ion trap is configured such that ion trajectories become unstable when more than one ion is present resulting in the ejection of all but one ion from that ion trap, so that when a plurality of ions are passed to the charge detection mass spectrometry device, the plurality of ions distribute themselves between the plurality of ion traps so that no more than one ion is present in any of the ion traps. The ion guide may comprise any suitable ion guide. For instance, in embodiments, the ion guide may comprise a stacked ring ion guide but other arrangements would of course be possible. From a related aspect, there is provided a method of charge detection mass spectrometry comprising: passing a plurality of ions to be analysed to a charge detection mass spectrometry device according to this further aspect.
In some embodiments, a plurality of independent charge detection mass spectrometry devices may be used, each comprising an ion trap and one or more charge detector(s). An upstream ion optical device such as a lens or a beam splitter device may then be provided for selectively or sequentially passing a plurality of ions to be analysed to respective ion traps of the charge detection mass spectrometry devices. This arrangement may therefore allow for performing multiplexed (interleaved) measurements, thereby enhancing duty cycle. This may be used in combination with the method of the first aspect, or the apparatus of the further aspect described above. That is, the detector signal from each of the plurality of charge detection mass spectrometry devices may be monitored to determine how many ions are present within each device. However, it is also believed that this apparatus is novel and inventive in its own right.
Thus, from a yet further aspect, there is provided a charge detection mass spectrometry apparatus comprising: a plurality of charge detection mass spectrometry devices; and an ion optical device for selectively or sequentially passing a respective plurality of ions to be analysed to the plurality of charge detection mass spectrometry devices. Each charge detection mass spectrometry device comprises an ion trap and one or more charge detector(s) for detecting ions within the ion trap such that each ion trap is capable of performing an independent measurement. The ion optical device may be provided separately from and upstream of the charge detection mass spectrometry devices. However, it is also contemplated that the ion optical device may be integrated as part of a single charge detection mass spectrometry device comprising a plurality of ion traps and an ion optical device for selectively or sequentially passing a respective plurality of ions to be analysed to the plurality of ion traps From a related aspect there is provided a method of charge detection mass spectrometry comprising: selectively or sequentially passing a plurality of ions to a respective plurality of ion traps so that a single ion is passed to each of the ion traps; and analysing the ions within the respective ion traps.
In embodiments, a plurality of charge detection mass spectrometry devices can be configured in a micro-fabricated array. In this way several hundred devices can be provided working in parallel allowing spectra to be generated at a much higher rate. Depending on the mechanism used to fill the traps each trap may then contain zero, one, or more than one ion. In that case, data from traps containing zero or multiple ions can be discarded. Thus, in embodiments, a plurality of charge detection mass spectrometry devices are provided in parallel, and the measurements from any devices giving no signal (no ions) or a poor signal (multiple ions) can then be discarded during the signal processing.
In embodiments, the charge detection mass spectrometry device(s) are used for measuring single ions. For instance, in embodiments of the first aspect, as described above, when it is detected that this is not the case, the measurement may be terminated, or the device operation adjusted accordingly. Thus, embodiments relate to methods of single ion charge detection mass spectrometry. However, in other embodiments, multiple ions may be measured simultaneously using a single charge detection mass spectrometry device. That is, multiple ions may be simultaneously present within a single ion trap of a charge detection mass spectrometry device. In this case, in order to minimise interference between the ions, the ion trap geometry and electric fields may be arranged so that the ion trajectories diverge away from the charge detector such that when multiple ions are simultaneously present within the ion trap the ions diverge away from each other as they move away from the charge detector. That is, when the ions are not passing through or by the charge detector, their trajectories are such that the ions can be kept apart each other. For example, the ion trajectories may define a “dumbbell” or “H” shape such that all of the ions can pass through a central charge detector but then spread out as they move away from the charge detector. In this way, the effects of space charge interactions can be reduced. For instance, the charge detector can be positioned in the center of the trap with the ion trajectories set up such that the ions have maximum velocity as they pass through the charge detector. However, away from the charge detector, at the extremes of the trajectories where the ions are moving relatively slowly, and are therefore most susceptible to space charge effects, the trajectories can be designed to keep the ions far apart from each other.
Thus, from a yet still further aspect, there is provided a charge detection mass spectrometry device comprising: an ion trap for holding one or more ions to be analysed; and a charge detector within the ion trap for determining a charge for the one or more ions to be analysed, wherein the ion trap is configured so that the ion trajectories diverge away from the charge detector such that when multiple ions are simultaneously present within the ion trap the ions spread out from each other away from the charge detector to reduce the space charge interactions between the multiple ions.
The charge detection mass spectrometry device(s) according to any of the aspects or embodiments described above may generally contain one or more charge detector electrode(s). In some embodiments, only a single charge detector is provided which may comprise a single electrode for example in the form of a metal cylinder. However, other arrangements would of course be possible. For instance, in other embodiments, the charge detection mass spectrometry device may comprise a plurality of charge detectors (each comprising one or more electrode(s)).
From a yet still further aspect there is provided a charge detection mass spectrometry device comprising: an ion trap for holding one or more ions to be analysed; and a plurality of charge detectors within the ion trap for determining a charge for the one or more ions to be analysed. The ion trap may have a multi-pass geometry, or may have a cyclic or folded flight path geometry.
In embodiments, according to any of the aspects described herein, a substantially quadratic potential may be applied to the ion trap (or ion traps) of a charge detection mass spectrometry device such that ions undergo substantially harmonic motion within the ion trap.
Indeed, from another aspect, there is provided a charge detection mass spectrometry device comprising: an ion trap for holding one or more ions to be analysed; and one or more charge detector(s) within the ion trap for determining a charge for the one or more ions to be analysed, wherein a substantially quadratic potential is applied to the ion trap such that ions undergo substantially harmonic motion within the ion trap.
In embodiments, the signals obtained from the charge detection mass spectrometry device may be processed using forward fitting and/or Bayesian signal processing techniques. Indeed, from another aspect, there is provided a method of charge detection mass spectrometry comprising: obtaining one or more signals from a charge detector of a charge detection mass spectrometry device; and processing the one or more signals using forward fitting and/or Bayesian signal processing techniques to extract a charge value for one or more ions within the charge detection mass spectrometry device.
An ion beam may be attenuated prior to being passed to the charge detection mass spectrometry device according to any of the aspects or embodiments described above. In this way, the ion flux that is passed into the charge detection mass spectrometry device may be controlled (reduced) to reduce the likelihood of more than one ion being present in a given trap during a single ion trapping event. Any suitable ion beam attenuation device may be used. However, in embodiments, the ion beam attenuating device comprises a plurality of ion beam attenuators that are each operable to either transmit substantially 100% of the ions (a high transmission (or low attenuation) state) or to transmit substantially 0% of the ions (a low transmission (or high attenuation) state).
Each ion beam attenuator may be arranged to alternately switch between high and low ion transmission states such that a continuous ion beam passing through the ion beam attenuator is effectively chopped to generate a non-continuous attenuated ion beam. The resulting attenuated ion beam can then be homogenized and converted back to a substantially continuous ion beam by passing the attenuated ion beam through a gas-filled region such as an ion guide or generally a gas cell wherein interactions between the ions and the gas molecules cause the ions to effectively spread out in a dispersive fashion.
To improve the attenuation, a plurality of ion beam attenuators may be provided in series, with the attenuated ion beam output from each ion beam attenuator being passed through a respective gas-filled region (or regions) in order to generate a substantially continuous ion beam for input to the next ion beam attenuator in the series (and so on, where more than two ion beam attenuators are provided) in order to generate a multiple attenuated output.
The plurality of ion beam attenuators may be arranged contiguously, one after another, in an alternating sequence of one or more ion beam attenuators and one or more gas-filled regions (gas cells). However, other arrangements would of course be possible.
In this way, an incoming ion beam can thus be readily attenuated as it passes through the series of ion beam attenuators to reliably give a very low flux. It will be appreciated that this ion beam attenuating device may also find utility for other applications and is not limited to use in combination with charge detection mass spectrometry detection devices. For instance, there are various applications where it may be desired to reliably reduce the ion flux. In general, the ion beam attenuation device may be used in any experiment where it is desired to controllably reduce the ion flux. For example, the ion beam attenuating device may be provided upstream of any suitable ion trap to avoid overfilling the trap. A specific example of this might be an ion trap providing ions to an ion mobility separation device. As another example, the ion beam attenuating device may be provided as part of (or upstream of) a detector system to avoid detector saturation. A further example would be controlling the flux of ions into a reaction cell in order to optimise the efficiency of ion-molecule or ion-ion reactions. However, various other arrangements would of course be possible.
Thus, from a yet further aspect there is provided an ion beam attenuating apparatus comprising: a first ion beam attenuator that is operable in either a high ion transmission mode or a low ion transmission mode in order to selectively attenuate an ion beam, wherein the output of the first ion beam attenuator is passed through a first gas-filled region; a second ion beam attenuator that is operable in either a high ion transmission mode or a low ion transmission mode in order to selectively attenuate an ion beam; and control circuitry that is configured to: repeatedly switch the first ion beam attenuator between the high and low ion transmission modes to generate a first non-continuous ion beam at the output of the first ion beam attenuator, wherein the first non-continuous ion beam is passed through the gas-filled region and converted into a substantially continuous ion beam thereby before arriving at the second ion beam attenuator; and repeatedly switch the second ion beam attenuator between the high and low ion transmission modes to generate a second non-continuous ion beam at the output of the second ion beam attenuator.
From a related aspect there is provided method of attenuating an ion beam, comprising: passing the ion beam to a first ion beam attenuator and repeatedly switching the first ion beam attenuator between high and low ion transmission modes to generate a first non-continuous ion beam at the output of the first ion beam attenuator; passing the first non-continuous ion beam through a gas-filled region to convert the first attenuated ion beam into a substantially continuous attenuated ion beam; passing the substantially continuous ion beam to a second ion beam attenuator and repeatedly switching the second ion beam attenuator between high and low ion transmission modes to generate a second non-continuous ion beam at the output of the second ion beam attenuator.
In embodiments, the second non-continuous ion beam is passed through a second gas-filled region and converted into a substantially continuous attenuated ion beam. That is, the method may comprise passing the second attenuated ion beam through a second gas-filled region to generate a substantially continuous attenuated ion beam.
The first and/or second ion beam attenuator may comprise one or more electrostatic lenses. The one or more electrostatic lenses may comprise one or more electrodes wherein the state of the ion beam attenuator can be alternated by changing one or more voltages applied to the electrodes. However, other arrangements are of course possible. For instance, the ion beam attenuator(s) may comprise a mechanical shutter or mechanical ion beam attenuator. Alternatively, the ion beam attenuator(s) may comprise a magnetic ion gate or magnetic ion beam attenuator.
The output from each ion beam attenuator may be passed through a gas-filled region. Typically, the gas-filled region comprises an ion guide or gas cell. A differential pumping aperture may therefore be provided at the entrance and/or exit of the gas-filled region.
The gas pressure within the gas-filled region may be selected, along with the length of the gas-filled region, to allow the attenuated ion beams to be substantially fully converted into a continuous ion beam between each ion beam attenuator.
The first and second ion beam attenuators may have the same attenuation factor (and may be alternated at the same frequency). Alternatively, the first and second ion beam attenuators may provide different attenuation factors.
When more than one ion beam attenuator is utilized in this fashion there may be more than one way to achieve a desired level of attenuation. For example, if attenuation to 1% intensity is required using two lenses, the first attenuator may be set to 1% and the second to 100% or vice versa. Alternatively, both devices may be operated at intermediate values to give a combined transmission of 1%. For example, the first and second ion beam attenuators may both be operated at 10%, or one of the ion beam attenuators operated at 20% with the other of the ion beam attenuators operated at 5%, and so on. Since the attenuation devices may become contaminated during long term use, it may be desirable to balance the attenuation evenly between the first and second ion beam attenuators, or to periodically change the attenuator that is used most for attenuation to prolong the period between maintenance, cleaning and/or replacement. Thus, in embodiments, when it is desired to provide a target overall attenuation, the method may comprise adjusting the relative attenuation provided by the first and second ion beam attenuators in such a manner to maintain the targeted overall attenuation.
From a further aspect, there is provided a method of single ion charge detection mass spectrometry in which the signal is analysed in real time and used for early termination of trapping events which will not produce useful data. For example, trapping events containing no ions or where more than a maximum number of ions are present may be terminated early.
It will be appreciated that the present invention in any of these further aspects may include any or all of the features described in relation to the first and second aspects of the invention, and vice versa, at least to the extent that they are not mutually inconsistent. It will also be appreciated by those skilled in the art that all of the described embodiments of the invention described herein may include, as appropriate, any one or more or all of the features described herein.
Various embodiments will now be described, by way of example only, and with reference to the accompanying drawings in which:
Various embodiments are directed towards methods of charge detection mass spectrometry (CDMS). It will be understood that CDMS generally involves a simultaneous measurement of both the mass-to-charge ratio (m/z) and the charge (z) of an ion. In this way, the mass (m) of the ion can then be determined (indirectly). The charge of an ion may typically be measured directly using a charge detection electrode. For example, when an ion is caused to pass through (or by) a charge detection electrode, the ion will induce a charge on the charge detection electrode which can then be detected, for example, by suitable detection (signal processing) circuitry connected to the charge detection electrode. The mass-to-charge ratio of the ion can generally be determined in various suitable ways. For example, the mass-to-charge ratio may be determined from the time-of-flight of the ion within the CDMS device or the ion velocity (so long as the energy per charge is known). Thus, various examples of CDMS experiments are known and it will be appreciated the embodiments described herein may generally applied to any suitable CDMS experiment, as desired.
However, typically, the mass-to-charge ratio may be determined from the frequency of oscillation of the ion, for example, within a trapping field. Thus, the CDMS device may generally comprise an ion trap within which ions to be analysed are contained. Ions are thus analysed in discrete ‘ion trapping events’. Thus, in each ion trapping event, the ion trap is opened to allow ions to enter the ion trap for analysis. At the end of an ion trapping event those ions may then be ejected and a new ion trapping event initiated.
For example, in some CDMS experiments such as that described in Keifer et al. “Charge Detection Mass Spectrometry with Almost Perfect Charge Accuracy”, Anal. Chem. 2015, 87, 10330-10337 (DOI: 10.1021/acs.analchem.5b02324), single ions are analysed in an ion trap for periods of up to about three seconds. In the CDMS experiment described by Keifer et al. ions are caused to pass repeatedly through a metal cylinder at the centre of the ion trap which is connected to an amplifier and digitiser. When ions are at the centre of the cylinder, the magnitude of the charge induced on the cylinder is equal to the charge on the ion.
However, other arrangements would of course be possible. Thus, whilst
In a well-calibrated system, the amplitude of the recorded signal can therefore be used to measure the charge on the ion. However, because the signal to noise ratio is low, many ion passes may typically be required to make an accurate charge measurement. Current state of the art instruments are capable of producing better than unit-charge resolution, for example, so that the charge on almost all of the trapped ions can be determined exactly. The frequency of oscillation of the ion in the trap is related to its mass to charge ratio. Although the signal is typically significantly non-sinusoidal, a Fourier transform of the recorded transient allows a measurement of the mass-to-charge ratio (albeit at low resolution). Taken together, the measurements of the mass-to-charge ratio and charge allow the mass of the ion to be determined.
It will be appreciated that this approach may be particularly useful for producing mass spectra of high molecular weight species (such as in the range of mega Dalton and above) as traditional (for example) electrospray mass spectra can be hard to interpret in this regime as different charge states are often poorly resolved from each other. However, CDMS techniques can be relatively slow. For instance, thousands of ion trapping events may typically be required to build up a useful mass spectrum. Methods of shortening the time required to produce a spectrum are therefore of particular interest.
Various examples of the present disclosure will now be described.
Single Ion Selection
In some embodiments, it may be desired to select a single ion (N=1) for analysis for efficient operation of the CDMS device. According to the techniques described in Kiefer et al., the mean of the ion arrival Poisson distribution is set to one ion (in a fill period of ˜0.5 ms). However this means that in a majority of cases (˜63%) the fill will result either in no ions (N=0) or more than one ion (N>1). When N=0, the (long) acquisition time (up to ˜three seconds) is wasted. Furthermore, when more than one (N>1) ion is held in the ion trap, the signal may be badly contaminated due to space charge effects.
Thus, in embodiments, the detector signal may be monitored in real time, and if after a period of time (for example, 10 or 50 or 100 ms) signal processing suggests N=0 or N>1, the current acquisition may be terminated early and a new fill event started, resulting in increased throughput. For instance, the acquisition may be terminated by applying suitable electric fields to (rapidly) remove all of the ions from the CDMS device. For example, by removing the trapping fields and/or applying one or more ejection fields the ions can then be “ejected” (or otherwise removed) from the trap and lost to the system or to collisions with the electrodes.
Alternatively, in other embodiments, when it is determined that N>1, it may be possible to excite ions in the trap to eject N−1 ions (such that these ions are then lost, as above), leaving only a single ion for analysis. This may be done deterministically or further monitoring may be performed to check that only one ion remains. It will be appreciated that ejecting ions from the trap may be advantageous compared to starting a new fill event since in that case the success rate may be close to 100% (whereas a new fill would generally succeed in only 37% of cases—that is there is a ˜63% chance that the new fill will result either in no ions or more than one ions).
Similarly, in this way, if an ion is lost during a trapping period (so that N=0), for example, due to scattering with the residual gas, or an unstable trajectory, the acquisition may be terminated early allowing a new fill event.
Thus, by contrast to more conventional approaches where a fixed ion trapping period is used for CDMS measurement (even if there are no ions being measured, or wherein multiple ions are present compromising the signal), in embodiments, an ion trapping event can be terminated early if the signal processing suggests N=0 or N>1. Alternatively, if the signal processing suggests N>1, the operation of the CDMS device can be adjusted until N=1. Thus, the CDMS device can be dynamically controlled based on a determination of how many ions are present in the device.
The detector signal may be monitored using any suitable techniques. For instance, in some embodiments, real time signal processing may consist of a series of overlapping apodised fast Fourier transforms. Estimation of the number of ions present in the trap may, for example, be based on the number of masses present in the spectrum above a noise threshold, or the total charge detected, or a combination of these.
Embodiments are also contemplated for tuning the ion arrival rate to maximise the probability of N=1. For instance, in some examples, one or more dynamic range enhancement (DRE) lenses may be used to control the flux of the ion beam in real time over a wide dynamic range. For example, a configuration involving multiple DRE lenses separated by gas filled cells at collision cell pressure for beam remerging may assist with control of the flux of the ion beam in real time over a wide dynamic range to help maximise the probability of N=1 ions arriving at the CDMS device.
In some embodiments, instead of exciting ions from the ion trap when it is determined that more than one ion is present, the ion trap itself may be designed such that the ion trajectories become unstable when more than one ion is present, resulting in ejection of all but one ion. In other words, the ion trap may be designed as a so-called “leaky” single ion trap. For instance, this may be achieved using an appropriately designed geometry and/or by applying one or more appropriate electric fields to the ion trap. In embodiments, the ion trap(s) may be of the type described in U.S. Pat. No. 8,835,836 (MICROMASS) wherein once the charge capacity of the ion trap has been reached the force on the ions due to coulombic repulsion is such that excess ions will leak or otherwise emerge from the trap.
Ion Trap—Space Charge Effects
In particular,
By providing and analysing these data while the transient is still in progress, then by 0.08s or even earlier it is possible to determine whether more than one ion is present in the trap. This determination could be made using statistical or Bayesian model comparison (comparing the probability that one peak is present with the probability for two peaks or more than two peaks) or hypothesis testing or by simply counting peaks in a smoothed version of the spectrum, or by measuring the full width of the spectrum at a fraction of the maximum intensity compared with the expected width for a single peak, or by a wide variety of other possible methods. In this case, since the full transient length is 1s, terminating trapping after 0.2s (allowing 120 ms for data processing) saves 0.8s of wasted acquisition time.
More generally, if the full transient time is TL and a transient is ended after time TS if it contains no ions or more than one ion then the rate with which good transients are obtained is:
where λ is the average number of ions that enter the trap during a trap filling period. Rgood is maximised when Δ=1 regardless of the values of TL and TS so that the intensity of the ion beam supplying the trap should be optimised to obtain this rate as nearly as possible. For Δ=1,
High Dynamic Range Ion Beam Attenuation
As mentioned above, embodiments are contemplated for controlling the flux of the ion beam in real time over a wide dynamic range to help maximise the probability of N=1 ions arriving at the CDMS device. However, it will be appreciated that there are many scenarios in which it is desirable to reduce the intensity of an ion beam in a controlled, quantitative, unbiased manner. That is, the degree of attenuation should not depend on m/z, ion mobility, propensity to fragment or charge reduce or any other ion characteristic within a relevant range for each property.
For example, this may be desirable to avoid unwanted problems arising from high ion flux including overfilling of traps including those used in ion mobililty experiments (resulting in uncontrolled and biased loss of ions or unwanted fragmentation), space charge effects, detector saturation (resulting in loss of quantitative accuracy, mass accuracy and artificial peaks) and charging of surfaces inside an instrument resulting in further loss of ions or distortion of the onwardly transmitted ion beam in a range of applications including but not limited to producing controlled low ion fluxes to be used in experiments involving single ions or few ions such as CDMS.
When a beam has been attenuated in a quantitative and unbiased manner it is often possible to recover many of the properties of the ideal signal that would have been obtained from the original un-attenuated beam by simply rescaling or otherwise adjusting the data produced by the instrument in question (for example the intensity of a mass spectral peak produced by a mass spectrometer).
The degree of attenuation can be constant for the duration of an experiment or it may vary in a predetermined way, or in response to information obtained from data that has already been acquired during the experiment (in a data dependent way).
Beam attenuation can also result in loss of small signals which fall below a detection threshold following attenuation. For this reason, an instrument may alternate between two or more modes of operation utilizing different degrees of attenuation. A final combined data set may then be reconstructed from the two or more datasets by taking small signals from data that is less attenuated, and larger signals from data that is more attenuated.
U.S. Pat. No. 7,683,314 (MICROMASS) discloses methods of attenuation of an ion beam which operate by alternating between a mode in which transmission is substantially 100% (for time ΔT2) and a mode in which transmission is substantially 0% (for time ΔT1). For example, this may be achieved by alternating a retarding voltage to repeatedly switch the ion beam between the two states.
However, since it inevitably takes a finite time for the ion beam to fully respond to changes in voltage intended to switch between the on and off states, when the duration of the on state ΔT2 becomes too short, there is insufficient time to recover 100% transmission before the next voltage change and attenuation is no longer linear or quantitative. On the other hand, when the time interval ΔT1 becomes comparable with the time to pass through the downstream gas cell or ion guide, it is no longer possible to restore the beam to a substantially continuous beam.
This means that there is a practical limit to the degree of quantitative attenuation that can be achieved by such a device (e.g. attenuation to 1% of the original intensity in a typical device).
According to an embodiment of the present disclosure, there is provided a method of attenuation using two attenuation devices of the type described above, separated by a gas cell or ion guide designed to convert the ion beam into a substantially continuous beam.
The first attenuation device 50 alternates between full transmission mode (for time periods of length ΔTA2) and low transmission mode (for time periods of length ΔTA1). The resulting beam is then preferentially converted to a substantially continuous beam by the subsequent ion guide or gas collision cell 54, with a fraction ΔTA2/ΔTA1 of its original intensity. Similarly, the second attenuation device 52 operates with high transmission and low transmission time periods ΔTB2 and ΔTB1 respectively so that the average transmission through the second device 52 is ΔTB2/ΔTB1. Preferentially, the beam may be subsequently converted to a substantially continuous beam by a second ion guide or gas collision cell 56. The overall result of the above arrangement is that the ion beam is reduced to a fraction (ΔTA2ΔTB2)/(ΔTA1 ΔTB1) of its original intensity.
If each of the first and second attenuation devices 50,52 are independently capable of quantitatively reducing the ion beam to a fraction p of its original intensity, the combined device can quantitatively achieve a fraction p2 of the original intensity. For example if the maximum quantitative attenuation for an individual device is 1%, then the combined device can achieve 0.01%.
Clearly the concept can be extended to include more than two devices separated by ion guides or gas collision cells designed to produce substantially continuous beams. For instance, when N devices, each individually capable of reducing the ion beam to a fraction p of its original intensity, are combined in this manner, a fraction p″ of the original beam intensity may be achieved quantitatively. This power law behaviour means that extremely high attenuation factors can be achieved quantitatively using relatively few devices. This may be required, for example, to achieve the low ion arrival rates necessary to yield a high probability of populating a trap with a single ion.
In practice, it is not necessary for the attenuation devices or the associated gas cells to be arranged contiguously in an instrument. They may be separated by other devices such as reaction cells, mass filters, ion mobility devices etc. Each of these additional devices may serve several purposes or operate in several different modes, and may be configured to react, fragment or filter ions, or (possibly simultaneously) to convert a pulsed ion beam to a substantially continuous ion beam.
Additionally, one or other or both of the attenuation devices may be operated continuously in full transmission mode, with attenuation only activated as required.
Space Charge Tolerance of Trap
In embodiments, it may be desired for the CDMS device to be able to analyse multiple ions simultaneously to increase throughput. However, as mentioned above, with conventional CDMS devices, such as that described in Kiefer et al., space charge effects may significantly affect the performance when more than one ion is present in an ion trap.
Thus, in some embodiments, it is contemplated the CDMS device may comprise a plurality of ion traps. For example, the CDMS device may comprise a plurality of parallel ion traps, each having an associated one or more charge detection electrodes, arranged to receive a plurality of ions from an upstream device. In this example, multiple ions from the upstream device may be shared between the plurality of ion traps using appropriate ion optics (for example, ion lenses or beam splitting devices). Thus, the system may be arranged so that (single) ions are sequentially or selectively passed to one of a plurality of different ion traps.
As another example, the CDMS device may comprise a series of “leaky” ion traps, with each ion trap having a geometry that is configured such that trajectories become unstable when more than one ion is present. In this case, provided that the ions are suitably confined within the CDMS device, the ions will naturally distribute themselves along the series of traps as a result of space charge effects. The series of ion traps may therefore be contained within an ion guide such as a stacked ring ion guide.
In these embodiments, each of the ion traps within the CDMS device may be arranged to analyse only a single ion. For example, N ion traps (wherein N>1) may be provided for analysing N ions.
However, embodiments are also contemplated wherein multiple ions (N>1) are analysed within a single ion trap. For example, if it can be arranged for trajectories to diverge (fan out) outside the region of the charge detector electrode, it may be possible to increase the capacity of the ion trap beyond a single ion (whilst still providing sufficient signal quality). For example, in three dimensions, the trajectories could occupy a “dumbbell” (or rotated “H”) shape. In this case, ions would tend to be to be furthest apart when they are moving slowly, and therefore space charge effects would be reduced. Thus, in embodiments, multiple ions (N>1) may be analysed simultaneously, with the ion trajectories for the ions being arranged to diverge outside the region of the charge detector electrode.
Alternatively, or additionally, the ion trap may be extended to contain more than one charge detection electrode. For example, ions may be caused to take a folded flight path like trajectory within the ion trap, for example, wherein ions are caused to repeatedly pass back and forth between two reflecting electrodes in a multi-pass operation, for example, so as to travel along a substantially zigzagged, or “W”-shaped, path. Charge detection electrodes may then be periodically placed along the folded flight path (for example, in place of the periodic focussing elements that may be found within a folded flight path instrument). Each ion may thus pass through each of the multiple charge detection electrodes (so that multiple measurements can be made for each ion, thus potentially improving the signal quality). As another example, instead of using a folded flight path type geometry, a multi-detector configuration could be wrapped round in a circle to give a cyclic CDMS device with multiple charge detection electrodes. The signal from each charge detection electrode could be analysed separately or, if more convenient, some may be electronically coupled and the combined signal deconvolved in post-processing.
As yet another example, the device could be linear or circular with no orthogonal trapping and with many charge detection electrodes arranged along the flight path (for example, in a similar manner to ion velocity Fourier transform mass spectrometry techniques).
For instance,
Improved Trajectories for Higher Resolution or Faster Operation
The Applicants have further recognised that the use of an approximately quadratic potential within the ion trap may result in improved energy tolerance of the device, for example, in that ions of the same mass-to-charge ratio but differing energy will produce signals having a more similar (or substantially the same) shape. More harmonic (sinusoidal) signals may give rise to cleaner spectra (with reduced harmonics). Thus, in embodiments, a substantially quadratic potential is used to confine the ions within the ion trap so that the ions undergo substantially harmonic motion within the ion trap (and through the charge detector electrode(s)). In this case the charge detector electrode may be located at the centre of the substantially quadratic potential. However, other arrangements would of course be possible.
Various existing geometries having suitably substantially quadratic potentials could be utilised. For example, it is contemplated that an Orbitrap type device or a SpiroTOF device (for example, as described in U.S. Pat. No. 9,721,779 (MICROMASS) or US Patent Application Publication No. 2017/0032951 (MICROMASS)) may be used. Devices with a central electrode (particularly the Orbitrap) have a relatively high space charge tolerance.
A substantially quadratic axial potential can then be set up along the device to cause the ions to begin to oscillate axially with substantially simple harmonic motion, as shown in
This arrangement has the advantage that, even for a small number of ions, the average initial separation between the ions can be increased by beam expansion during the initial injection, reducing space charge effects. Furthermore, the inner electrodes 100 help to shield the ions from each other. Additionally, when ions of the same mass to charge ratio are moving slowly (at the extremes of their axial motion), and are therefore most susceptible to space charge effects, their average separation is largest owing to beam expansion.
However, other arrangements would of course be possible. For instance, an Orbitrap-type geometry using a substantially quadro-logarithmic potential may also provide similar advantages. This may also be the case, for instance, for Cassinian orbits such as those described in U.S. Pat. No. 8,735,812 (BRUKER DALTONIK GMBH), depending on the trajectory chosen.
Signal Processing
The use of Fourier Transform processing on anharmonic signals is well known to produce artefact “harmonics”. However, in embodiments, forward fitting/Bayesian signal processing using model peak shape, or shapes, may be used. This may significantly reduce the intensity of harmonics and improve signal-to-noise in the inferred spectrum. Thus, this may in turn provide a higher mass resolution in a fixed time (or similarly the same resolution to be achieved in a shorter time). For instance, the Applicants have recognised similar techniques such as those described in US Patent Application Publication No. 2016/0282305 (MICROMASS) for processing ion mobility data may also advantageously be used for processing the CDMS signals obtained according to various embodiments described herein. For example, by using similar such techniques, it may be possible in embodiments to extract a charge value from the fitted amplitude. Especially if space charge limitations are reduced, such signal processing approaches may thus be capable of extracting high quality spectra from trapping events including more than one ion.
Although the present invention has been described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the scope of the invention as set forth in the accompanying claims.
Number | Date | Country | Kind |
---|---|---|---|
1802917 | Feb 2018 | GB | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/GB2019/050494 | 2/22/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/162687 | 8/29/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5770857 | Fuerstenau et al. | Jun 1998 | A |
5880466 | Benner | Mar 1999 | A |
6480278 | Fuerstenau et al. | Nov 2002 | B1 |
6747272 | Takahashi | Jun 2004 | B2 |
7002166 | Jamieson et al. | Feb 2006 | B2 |
7365314 | Inventor | Apr 2008 | B2 |
7982871 | Inventor | Jul 2011 | B2 |
8278115 | Coon et al. | Oct 2012 | B2 |
8334504 | Finlay et al. | Dec 2012 | B2 |
8829432 | Stein | Sep 2014 | B2 |
8921772 | Verenchikov | Dec 2014 | B2 |
8933397 | Hanson | Jan 2015 | B1 |
8963075 | Chen et al. | Feb 2015 | B2 |
9018580 | Lemoine et al. | Apr 2015 | B2 |
9035245 | Glasmachers et al. | May 2015 | B2 |
9368336 | Xu et al. | Jun 2016 | B2 |
9396923 | Kodera et al. | Jul 2016 | B2 |
9666423 | Benner | May 2017 | B2 |
9786483 | Heeren et al. | Oct 2017 | B2 |
9911587 | Li et al. | Mar 2018 | B1 |
9911588 | Li | Mar 2018 | B1 |
9972480 | Ristroph | May 2018 | B2 |
10145792 | Jungwirth et al. | Dec 2018 | B2 |
10186409 | Youngner | Jan 2019 | B2 |
10297436 | Tsybin et al. | May 2019 | B2 |
10340052 | Jungwirth et al. | Jul 2019 | B2 |
10453668 | Continetti et al. | Oct 2019 | B2 |
10510524 | Sekiya et al. | Dec 2019 | B2 |
10580633 | Cooks et al. | Mar 2020 | B2 |
10585103 | Jarrold et al. | Mar 2020 | B2 |
10620121 | Zheng et al. | Apr 2020 | B2 |
10872755 | Christian | Dec 2020 | B2 |
10937638 | Cooks et al. | Mar 2021 | B2 |
10984999 | Hsieh et al. | Apr 2021 | B2 |
11069516 | Baba et al. | Jul 2021 | B2 |
11075067 | Takahashi et al. | Jul 2021 | B2 |
11127581 | Cooks et al. | Sep 2021 | B2 |
11152198 | Shaw | Oct 2021 | B2 |
11177122 | Jarrold et al. | Nov 2021 | B2 |
20080191130 | Bateman et al. | Aug 2008 | A1 |
20100059673 | Makarov | Mar 2010 | A1 |
20120112056 | Brucker | May 2012 | A1 |
20130270433 | Ding et al. | Oct 2013 | A1 |
20140061460 | Hauschild | Mar 2014 | A1 |
20150318161 | Brown | Nov 2015 | A1 |
20160379814 | Yamada | Dec 2016 | A1 |
20180005809 | Roukes et al. | Jan 2018 | A1 |
20180247805 | Continetti et al. | Aug 2018 | A1 |
20180275097 | Sandoghdar et al. | Sep 2018 | A1 |
20190066989 | Cooks et al. | Feb 2019 | A1 |
20200043716 | Taniguchi | Feb 2020 | A1 |
20200075300 | Bern | Mar 2020 | A1 |
20200249240 | Jarrold et al. | Aug 2020 | A1 |
20200300630 | Kozuma et al. | Sep 2020 | A1 |
20200357626 | Jarrold et al. | Nov 2020 | A1 |
20210013022 | Tateishi | Jan 2021 | A1 |
20210050200 | Song et al. | Feb 2021 | A1 |
20210166831 | Cao | Jun 2021 | A1 |
20210193447 | Jarrold et al. | Jun 2021 | A1 |
20210202225 | Jarrold et al. | Jul 2021 | A1 |
20210210331 | Senko et al. | Jul 2021 | A1 |
20210210332 | Jarrold et al. | Jul 2021 | A1 |
20210210335 | Jarrold | Jul 2021 | A1 |
20210217606 | Jarrold et al. | Jul 2021 | A1 |
20210262915 | Stevens et al. | Aug 2021 | A1 |
20210287892 | Lehmann | Sep 2021 | A1 |
20210327605 | Shen et al. | Oct 2021 | A1 |
20210335592 | Cooks et al. | Oct 2021 | A1 |
20210343518 | Pophristic | Nov 2021 | A1 |
Number | Date | Country |
---|---|---|
1665328 | Jun 2012 | EP |
2665084 | Nov 2013 | EP |
3505489 | Mar 2020 | EP |
3884510 | Sep 2021 | EP |
3891777 | Oct 2021 | EP |
3010527 | Mar 2015 | FR |
9931707 | Jun 1999 | WO |
2005041244 | May 2005 | WO |
2011086430 | Jul 2011 | WO |
2012083031 | Jun 2012 | WO |
2012092457 | Jul 2012 | WO |
2016073850 | May 2016 | WO |
2017190031 | Nov 2017 | WO |
2017196863 | Nov 2017 | WO |
2018011591 | Jan 2018 | WO |
2019060538 | Mar 2019 | WO |
2019140233 | Jul 2019 | WO |
2019162687 | Aug 2019 | WO |
2019231854 | Dec 2019 | WO |
2019236139 | Dec 2019 | WO |
2019236140 | Dec 2019 | WO |
2019236141 | Dec 2019 | WO |
2019236142 | Dec 2019 | WO |
2019236143 | Dec 2019 | WO |
2019236572 | Dec 2019 | WO |
2019236574 | Dec 2019 | WO |
2019243083 | Dec 2019 | WO |
2020049165 | Mar 2020 | WO |
2020106310 | May 2020 | WO |
2020117292 | Jun 2020 | WO |
2020198124 | Oct 2020 | WO |
2020198332 | Oct 2020 | WO |
2020219527 | Oct 2020 | WO |
2020219605 | Oct 2020 | WO |
2021006811 | Jan 2021 | WO |
2021061650 | Apr 2021 | WO |
2021072186 | Apr 2021 | WO |
2021126971 | Jun 2021 | WO |
2021126972 | Jun 2021 | WO |
2021158603 | Aug 2021 | WO |
2021158676 | Aug 2021 | WO |
Entry |
---|
International Search Report and Written Opinion for International Patent Application No. PCT/GB2019/050494, dated Aug. 2, 2019. |
Keifer, D. Z., et al., “Charge detection mass spectrometry: weighing heavier things”, Analyst, 142(10): 1654-1671, Apr. 26, 2017. |
Karampini, E., “The Use of Bayesian Statistics in Mass Spectrometry Data—Literature research”, Jan. 1, 2015, Retrieved from the Internet: URL:https://esc.fnwi.uva.nl/thesis/centraal/files/f1299028219.pdf [retrieved on Jul. 26, 2019]. |
International Search Report and Written Opinion for International application No. PCT/US2021/026383 dated Sep. 10, 2021, 17 pages. |
Arroyo, J.O., et al., “Interferometric scattering microscopy and its combination with single-molecule fluorescence imaging”, Nature Protocols, 11(4)1617-633 (2016). |
Austin, D.E., “Impact-Ionization Mass Spectrometry of Cosmic Dust”, Dissertation California Institute of Technology (2003) 192 pages. |
Barney, B.L., “A multi-stage image charge detector made from printed circuit boards”, Review of Scientific Instruments 84:114101-1 through 114101-6 (2013). |
Benner, W.H., “A Gated Electrostatic Ion Trap To Repetitiously Measure the Charge and m/z of Large Electrospray ons”, Anal. Chem 69:4162-4268 (1997). |
Botamanenko, D.Y., et al., “Ion-Ion Interactions in Charge Detection Mass Spectrometry”, J. Am. Soc. Mass Spectrom, online] Nov. 1, 2019 DOI: 10.101007/s13361-019-02343-y. |
Brown, B.A., et al., “Charge Detection Mass Spectrometry Measurements of Exosomes and other Extracellular Particles Enriched from Bovine Milk”, Analytical Chemistry Just Accepted Manuscript DOI: 10.1021/acs.Analchem.9b05173 Jan. 28, 2020. |
Cole, D., et al., “Label-Free Single-Molecule Imaging with Numerical-Aperture-Shaped Interferometric Scattering Microscopy”, ACS Photonics 4:211-216 (2017). |
Contino, N.C., “Ion Trap Charge Detection Mass Spectrometry: Lowering Limits of Detection and Improving Signal to Moise”, Dissertation for Doctor of Philosophy at Indiana University (2013). 205 pages. |
Contino, N.C., and Jarrold, M.F., “Charge detection mass spectrometry for single ions with a limit of detection of 30 charges”, International Journal of Mass Spectrometry 345-347:153-159 (2013). |
Contino, N.C., et al., “Charge Detection Mass Spectrometry with Resolved Charge States”, J. Am. Soc. Mass Spectrom 24:101-108 (2013). |
Curtis, A.S.G., “The Mechanism of Adhesion of Cells to Glass: A Study by Interference Reflection Microscopy”, Journal of Cell Biology 20:199-215 (1964). |
Dahan, M., et al., “A new type of electrostatic ion trap for storage fo fast ion beams”, Rev. Sci. Instrum. 69(1 ):76-83 (1998). |
Dania, Lorenzo “Investigation on a two-frequency Paul trap for a cavity optomechanics system”, Master Thesis Universita Degli Studi Di Pisa (2016-17) 89 pages. |
Doussineau, T., et al., “Charge Detection Mass Spectrometry for the Characterization of Mass and Surface Area of Composite Nanoparticles”, Journal of Physical Chemistry C 119:10844-10849 (2014). |
Doussineau, T., et al., “Charging megadalton poly(ethylene oxide)s by electrospray ionization. A charge detection mass spectrometry study”, Rapid Communications in Mass Spectrometry 25:617-623 (2011). |
Doussineau, T., et al., “Direct Molar Mass Detenmination of Self-Assembled Amphiphilic Block Copolymer Nanoobjects Using Electrospray-Charge Detection Mass Spectrometry”, ACS Macro Lett 1:414-417 (2012). |
Doussineau, T., et al., “Infrared multiphoton dissociation tandem charge detection-mass spectrometry of single megadalton electrosprayed ions”, Review of Scientific Instruments 82:084104-1 through -8 (2011). |
Doussineau, T., et al., “Mass spectrometry investigations of nanoparticles by tandem charge detection mass spectrometry”, Spectroscopy Europe 24(4) 3 pages (2012). |
Doussineau, T., et al., “Pushing the Limit of Infrared Multiphoton Dissociation to Megadalton-Size DNA Ions”, The Journal of Physical Chemistry Letters 3:2141-2145 (2012). |
Draper, B.E., and Jarrold, M.F., “Real-Time Analysis and Signal Optimization for Charge Detection Mass Spectrometry”, J. Am Soc., Mass Spectrom. 30:898-904 (2019). |
Draper, B.E., et al., “The FUNPET—a New Hybrid Ion Funnel-Ion Carpet Atmospheric Pressure Interface for the Simultaneous Transmission of a Broad Mass Range”, J. Am. Soc. Mass Spectrom Electronic Supplementary Material online]. Retrieved from Internet URL: (https://doi.org/10.1007/s13361-018-2038-3) 13 pages (2018). |
Dunbar, C.A., et al., “Probing Antibody Binding to Canine Parvovirus with Charge Detection Mass Spectrometry”, Journal of the American Chemical Society 140:15701-15711 (2018). |
Dziekonski, E.T., et al., “Determination of Collision Cross Sections Using a Fourier Transform Electrostatic Linear Ion Trap Mass Spectrometer”, J Am. Soc Mass Spectrom. 29:242-250 (2018). |
Elliot, A.G., et al., “Mass, mobility and MSn measurements of single ions using charge detection mass spectrometry”, Analyst 142:2760-2759 (2017). |
Elliott, A.G., et al., “Effects of Individual Ion Energies on Charge Measurements in Fourier Transform Charge Detection Mass Spectrometry (FT-CDMS)”, J. Am. Soc. Mass Spectrom. 30:946-955 (2018). |
Elliott, A.G., et al., “Simultaneous Measurements of Mass and Collisional Cross-Section of Single Ions with Charge Detection Mass Spectrometry”, Analytical Chemistry 89:7701-7708 (2017). |
Elliott, A.G., et al., “Single Particle Analyzer of Mass: A Charge Detection Mass Spectrometer with a Multi-Detector Electrostatic Ion Trap”, International Journal of Mass Spectrometry, 414:45-55 (2017). |
Esser, T., “A Cryogenic Mass Spectrometer for Action Spectroscopy of Single Nanoparticles”, Dissertation Universitat Leipzig Jan. 21, 2019 198 pages. |
Esser, T.K., et al., “A Cryogenic Single Nanoparticle Action Spectrometer” Supplementary Material 8 pages. No date given. |
Esser, T.K., et al., “A cryogenic single nanoparticle action spectrometer”, Review of Scientific Instruments, 90:125110 (1990), 9 pages. |
Fuerstenau, S.D., et al., “Mass Spectrometry of an Intact Virus” Angew. Chem Int. Ed. 40(3):541-544 (2001). |
Gamero-Castano, M., “Induction charge detector with multiple sensing stages”, Review of Scientific Instruments 78:043301-7 (2007). |
Goldfain, A.M., et al., “Dynamic Measurements of the Position, Orientation, and DNA Content of Individual Unlabeled Bacteriophages”, Journal of Physical Chemistry B, 120:6130-6138 (2016). |
Halim, M.A., et al., “Infrared Laser Dissociation of Single Megadalton Polymer Ions in a Gated Electrostatic Ion Trap. The Added Value of Statistical Analysis of Individual Events” Electronic Supplementary material (ESI) for Physical Chemistry Chemical Physics (2018) 10 pages. |
Han, KY., and Ha, T., “Measuring molecular mass with light”, Nature Photonics 12:378-385 (2018). |
Hao, Z., et al., “Intact Antibody Characterization Using Orbitrap Mass Spectrometry”, Chapter 10 in State-of-the-Art and Emerging Technologies for Therapeutic Monoclonal Antibody Characterization vol. 3. Defining the Next Generation of Analylical and Biophysical Techniques, DOI: 10.1021/bk-2015-1202, (2015). |
Harper, C.C., et al., “Multiplexed Charge Detection Mass Spectrometry for High-Throughput Single Ion Analysis of Large Molecules”, Analytical Chemistry 91:7458-7465 (2019). |
Hogan, J.A., and Jarrold, M.F., “Optimized Electrostatic Linear Ion Trap for Charge Detection Mass Spectrometry”, American Society for Mass Spectrometry DOI: 10.1007/s13361-018-2007-x (2018). 10 pages. |
Hogan, Joanna Arielle, “Improving Charge Detection Mass Spectrometry Instrumentation for the Analysis of Heterogeneous, Multi-Megadalton Ions”, Doctor of Philosophy Indiana University (2018) 207 pages. |
Holmes, K., et al., “Assembly pathway of hepatitis B core virus-like particles from genetically fused dimers”, JBC Papers in Press Manuscript M114.622035 (2015) 18 pages. |
Howder, C.R., et al., “Optically detected, single nanoparticle mass spectrometer with pre-filtered electrospray Nanoparticle source”, Review of Scientific Instruments 85:014104-1 through -6 (2014). 6 pages. |
Jarrold, M.F., “Helices and Sheets in vacuo” Physical Chemistry Chemical Physics 9:1659-1671 (2007). |
Julian, R.R., et al., “Ion Funnels for the Masses: Experiments and Simulations with a Simplified Ion Funnel”, J_Am. Soc. Mass Spectrom. 16:1708-1712 (2005). |
Kaplan, P.O., et al. “Light-scattering microscope”, Applied Optics 38(19):4151-4257 (1999). |
Keifer, D.Z., and Jarrold, M.F., “Single-Molecule Mass Spectrometry”, Mass Spectrometry Reviews DOI 10.1002/mas 2016). 19 pages. |
Keifer, D.Z., et al., “Acquiring Structural Information on Virus Particles with Charge Detection Mass Sprectrometry” J. Am. Soc. Mass Spectrom. 27:1026-1036 (2016). |
Keifer, D.Z., et al., “Charge Detection Mass Spectrometry with Almost Perfect Charge Accuracy”, Analytical Chemistry 87:10330-10337 (2015). |
Keifer, D.Z., et al., “Measurement of the accurate mass of a 50 MDa infections virus”, Rapid Communications in Mass Spectrometry 30: 1957-1962 (2016). |
Keifer, D.Z., et al., “Spontaneous Mass and Charge Losses from Single Multi-Megadalton Ions Studied by Charge Detection Mass Spectrometry”, J. Am. Soc. Mass Spectrom. DOI: 10.1007/s13361-016-1582-y (2017). 9 pages. |
Kondylis, P., et al., “Analytical Techniques to characterize the Structure, Properties, and Assembly of Virus Capsids”, Analytical Chemistry 91 :622-636 (2019). |
Kukura, P ., et al., “High-speed nanoscopic tracking of the position and orientation of a single virus”, Nature Methods 6 (12):923-927 (2009). |
Latimer, P., “Light Scattering vs. Microscopy for Measuring Average Cell Size and Shape”, Biophys. J., 27:117-126 (1979). |
LCMS-9030—Quadrupole Time-0f-Flight Liquid Chromatograph Mass Spectrometer, Shimadzu Scientific Instruments. No date given. |
Lee, S.F., and Klenerman, D., 'Weighing one protein with light, Science 360(6387):378-379 (2018). |
Liebel, M., et al., “Ultrasensitive Label-Free Nanosensing and High-Speed Tracking of Single Proteins”, Nano Letters 17:1277-1281 (2017). |
Lin, Y-H., et al., “Shot-noise limited localization of single 20 nm gold particles with nanometer spatial precision within microseconds”, Optics Express 22(8): 12 pages (2014). |
Lutomski, C., et al., “Resolving Subpopulations in High and Low-density Lipoproteins”, Dept, of Chem, Indiana University, PowerPoint ASMS 2018, 19 pages. |
Lutomski, C.A., et al., “Multiple Pathways in Capsid Assembly”, JACS 140(17):5784-5790 (2018). |
Lutomski, C.A., et al., “Resolution of Lipoprotein Subclasses by Charge Detection Mass Spectrometry”, Analytical Chemistry 90(11):6353-6356 (2018). |
Mabbett, S.R., et al., “Pulsed Acceleration Charge Detection Mass Spectrometry: Application to Weighing Electrosprayed Droplets”, Anal. Chem., 79:8431-8439 (2007). |
Makarov, A., et al., “Performance Evaluation of a Hybrid Linear Ion Trap/Orbitrap Mass Spectrometer”, Anal. Chem. 7 8:2113-2120(2006). |
Maze, J.T., “Charge Detection Mass Spectrometry”, pp. 387-401 Dissertation for Indiana University. No date given. |
Moerner, W.E., and Fromm, D.P., “Methods of single-molecule fluorescence spectroscopy and microscopy”, Review of Scientific Instruments 74(8):3597-3619 (2003). |
Morikis, D., and Lambris, J.D., “Physical methods for structure, dynamics and binding in immunological research”, Trends in Immunology 25(12): 700-707 (2004). |
Morris, J.D., and Payne, C.K., “Microscopy and Cell Biology: New Methods and New Questions”, Annual Review of Physical Chemistry 70:199-218 (2019). |
Nie, Z., et al., “Microscopy-Based Mass Measurement of a Single Whole Virus in a Cylindrical Ion Trap”, Angewandte Chemie 45:8131-8134 (2006). |
Pansieri, J., et al., “Mass and charge distributions of amyloid fibers involved in neurodegenerative diseases: mapping heterogeneity and polymorphism”, Chemical Science 9:2791-6 (2018). |
Park, J-S., et al., “Label-free and live cell imaging by interferometric scattering microscopy”, Chemical Science 9:2690-7 (2018). |
Patil, A.A., et al., “High Mass Ion Detection with Charge Detector Coupled to Rectilinear Ion Trap Mass Spectrometer”, J. Am. Soc. Mass Spectrom., 28:1066-1078 (2017). |
Patil, A.A., et al., “Linear and Nonlinear Resonance Ejection of High Mass Ions with charge detection rectilinear ion trap mass spectrometer”, Journal Pre-proof International Journal of Mass Spectrometry 450:116301 (2020). |
Peng, W-P., et al., “Optical Detection Methods for Mass Spectrometry of Macroions”, Mass Spectrometry Reviews 23:443-465 (2004). |
Pierson, E. E., et al., “Resolving Adeno-Associated Viral Particle Diversity With Charge Detection Mass Spectrometry”, Analytical Chemistry 88:6718-6725 (2016). |
Pierson, E., E., et al., “Charge Detection Mass Spectrometry for Single Ions with an Uncertainty in the Charge Measurement of 0.65 e”, J. Am Soc. Spectrom 26:1213-1220 (2015). |
Pierson, E.E., et al., “Charge Detection Mass Spectrometry Identifies Preferred Non-Icosahedral Polymorphs in the Self-Assembly of Woodchuck Hepatitis Virus Capsids”, J. Mol Biol 428:292-300 (2016). |
Pierson, E.E., et al., “Detection of Late Intermediates in Virus Capsid Assembly by Charge Detection Mass Spectrometry”, JACS 136:3536-3541 (2014). |
Pierson, E.E., et al., “Detection of Late Intermediates in Virus Capsid Assembly by Charge Detection Mass Spectrometry”, Supplementary Figures S1—S7 (2014). |
Pierson, Elizabeth E., “Charge Detection Mass Spectrometry: Instrumentation & Applications to Viruses”, Dissertation to Indiana University Department of Chemistry (2015) 169 pages. |
Piliarik, M., and Sandoghdar, V., “Direct optical sensing of single unlabelled proteins and super-resolution imaging of Their binding sites”, Nature Communications 5:4495 (2014). |
Racke, P., et al., “Detection of small bunches of ions using image charges”, Scientific Reports 8:9781 (2018), 10 pages. |
Schlottmann, F., et al., “A Simple Printed Circuit Board-Based Ion Funnel for Focusing Low m/z Ratio Ions with High Kinetic Energies at Elevated Pressure”, J Am. Soc Mass Spectrom 30:1813-1823 (2019). |
Schmidt, H., et al., “Conetrap: A compact electrostatic ion trap”, Nuclear Instruments and Methods in Physics Research B 173:523-527 (2001). |
Shelton, H., et al., “Electrostatic Acceleration of Microparticles to Hypervelocities”, Journal of Applied Physics 31(7):1243-6 (1960). |
Shinholt, Deven Lee, “Charge Detection Mass Spectrometry and a Frequency Scanned linear Quadrupole: Mass Analysis of Large Ions”, Doctor of Philosophy Thesis submitted to Indiana University Department of Chemistry, Dec. 2014, 255 pages. |
Sipe, D.M., et al., “Characterization of Mega-Dalton-Sized Naoparticles by Superconducting Tunnel Junction Cryodetection Mass Spectrometry”, ACS Nano 12: 2591-2602 (2018). |
Smith, J.W., et al., “Image Charge Detection Mass Spectrometry: Pushing the Envelope with Sensitivity and Accuracy” Analytical Chemistry 83(3):950-6 (2011). |
Snijder, J., et al., “Defining the Stoichiometry and Cargo Load of Viral and Bacterial Nanoparticles by Orbitrap Mass Spectrometry”, JAGS 136:7295-7299 (2014). |
Sugai, T., “Mass and Charge Measurements on Heavy Ions”, Mass Spectrometry 6:S0074 (2017). 18 pages. |
Thomas, J.J., et al., “Electrospray ion mobility spectrometry of intact viruses”, Spectroscopy 18:31-36 (2004). |
Turkowyd, B., et al., “From single molecules to life: microscopy at the nanoscale”. Anal Bioanal Chem 408:6885-6911 (2016). |
Van de Walerbeemd, M., et al., “High-fidelity mass analysis unveils heterogeneity in intact ribosomal particles”, Nature Methods [online] doi: 10.1038/nmelh.4147 (2017) 7 pages. |
Verschueren, H., “Interference Reflection Microscopy in Cell Biology: Methodology and Applications”, J. Cell Sci. 75:279-301 (1985). |
Walt, D.R., “Optical Methods for Single Molecule Detection and Analysis”, Analytical Chemistry 85:1258-1263 (2013). |
Wang, W., and Tao, N., “Detection, Counting, and Imaging of Single Nanoparticles”, Analytical Chemistry 86:2-14 (2014). |
Yavor, M.I., et al., “Ion-optical design of a high-performance multiple-reflection lime-of-flight mass spectrometer and sobar separator”, International Journal of Mass Spectrometry 381-382:1-9 (2015). |
Young, G., and Kukura, P., “Interferometric Scattering Microscopy” Annual Review of Physical Chemistry, 70:301-22 (2019). |
Young, G., et al., “Quantitative mass imaging of single biological macromolecules”, Biophysics 360:423-427 (2018). |
Zilch, Lloyd W., “Image Charge Detection and Image Charge Detection Mass Spectrometry”, Dissertation to Indiana University Analytical Department of the Department of Chemistry (2008) 143 pages. |
Brunner, T., et al., “An RF-0nly ion-funnel for extraction from high-pressure gases”, International Journal of Mass Spectrometry 379:110-120 (2015). |
Dziekonski, E.T., et al., “Fourier-Transform MS and Closed-Path Multireflection Time-0f-Flight MS Using an Electrostatic Linear Ion Trap”, Analytical Chemistry 89:10965-10972 (2017). |
Smith, Johnathan, “Charge Detection Mass Spectrometry: Pushing the Limits from Teradaltons to Kilodaltons”, Dissertation to Indiana University Department of Chemistry (2011) 175 pages. |
Number | Date | Country | |
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20200395202 A1 | Dec 2020 | US |