The invention generally relates to mass spectrometry, and more particularly to methods and apparatus utilizing an ion mobility spectrometer to remove contamination and prevent degradation of downstream components of a mass spectrometer operating in a high-vacuum chamber.
Mass spectrometry (MS) is an analytical technique for determining the elemental composition of test substances with both qualitative and quantitative applications. For example, MS can be useful for identifying unknown compounds, determining the isotopic composition of elements in a molecule, determining the structure of a particular compound by observing its fragmentation, and quantifying the amount of a particular compound in a sample. Mass spectrometers have been widely used in the fields of chemistry and physics for over a century, and increasingly in biology over the past several decades. Sub-disciplines such as environmental monitoring for pollutants, forensic analysis for drugs of abuse and toxins, biomedical research, clinical disease diagnostics, food analysis, material science, and others, have been utilizing atmospheric pressure ionization mass spectrometers toward great practical value and to help achieve significant advancements in these fields. Large numbers of highly complex samples have been interrogated for the identity and quantity of a variety of chemical constituents at levels as low as parts per trillion.
As a result, mass spectrometry instrumentation has evolved toward increased selectivity as mass spectrometric detection and quantification of analytes contained within complex matrices generally requires high resolution separation techniques to reduce the effect of interfering species within the sample. Despite advances in MS that have enabled high-resolution mass analyzers to distinguish target species from interfering species within about 0.01 Th, it is not always feasible or possible to use a high-resolution mass analyzer to separate interfering species, for example, due to availability, cost, and/or experimental conditions.
Accordingly, various approaches for increasing the resolution of analytes have been developed including, for example, improved sample preparation techniques prior to ionization such as liquid chromatography, derivatization prior to LC separation, solid-phase extraction, or turbulent-flow chromatography. Additionally, various techniques have been developed to separate charged species within an ionized sample based on characteristics beyond mass-to-charge ratio (m/z). By way of example, whereas MS generally analyzes ions based on differences in m/z, ion mobility spectrometry (IMS) and other ion mobility separation techniques (e.g., differential mobility spectrometry (DMS), high field asymmetric waveform ion mobility spectrometry (FAIMS), Field Ion Spectrometry (FIS)) instead separate ions based upon other factors such as size, shape, and charge state as ions drift through a gas (typically at atmospheric pressure) in an electric field. The drift time through an electrostatic field is characteristic of the mobility of the ion (e.g., its size and shape and its interactions with the background gas), or in the case of DMS and FAIMS devices, the compensation voltage (CV or CoV) required to preferentially prevent the drift of a particular species is characteristic of its differential mobility. However, operating parameters for ion mobility spectrometers, however, are conventionally configured to optimize the resolution of the various charged species generated from the sample (e.g., to separate isobaric species), often at the expense of decreased transmission of ions of interest. Moreover, the effects of ion mobility conditions on particular species can be unpredictable and often lead to ion loss (i.e., decreased signal/sensitivity).
Additionally, the ion optics and other mass analyzer components, which are located deep inside high-vacuum chambers where ion trajectories can be precisely controlled by electric fields, are delicate and prone to fouling by the excessive sample loads and debris generated by atmospheric pressure ion sources. While, ionization at atmospheric pressure, whether by chemical ionization processes or by electrospray, is generally a highly efficient means of generating ions and microamps of ion current of the analyte(s) of interest, contaminating/interfering ions can also be created in high abundance at ion current levels far in excess of the analyte(s) of interest. The undesirable transport of contaminating ions and charged particles from the atmospheric pressure source region to the high-vacuum chamber of a mass spectrometer can also result in contamination of ion optics within the intermediate pumping stages of a differentially pumped mass spectrometer. Such contamination can not only interfere with the mass spectrometric analysis, but also lead to increased costs or decreased throughput necessitated by the cleaning of critical components within the high-vacuum chamber and intermediate pressure regions. Because of the higher sample loads and contaminating nature of the biologically based samples being analyzed with current day atmospheric pressure ionization sources, reduction of system contamination remains a critical concern.
The concept of using a differential ion mobility (DMS) device as a pre-filter to a mass spectrometer (MS) has been developed by several groups. This includes the use of high field asymmetric waveform ion mobility spectrometers (FAIMS) which operate on the same principles of utilizing the difference in ions high and low field mobility to effect separations. The expressed purpose for coupling DMS with MS has been to increase the selectivity of the mass spectrometer by providing a high resolution ion mobility device that can separate ion species that a mass spectrometer cannot, thus increasing the specificity of the system by hyphenating two instruments that separate ions on different principles, i.e. the mobility and mass measurements are orthogonal to each other (Schneider et al, Int. J. Ion Mobility Spec., 2013, 16, 207-216). The separation of isobaric species is an example of something a DMS device can do in many cases but a mass spectrometer cannot. Compounds with different primary, secondary, or tertiary structures having the same mass (isobaric) have been shown to separate with differential ion mobility thereby improving the selectivity of the mass spectrometer when used in combination with such a device. Also, isobaric compounds with different gas phase ion chemistries can be separated by DMS adding further resolving power to the mass spectrometer. As such, the focus on the design of such mobility systems has been toward the improvement of the resolution and peak capacity. Resolution (Rs) is defined in equation 1 as:
where CoV represents the compensation voltage required to pass a specific ion through the cell and FWHM is the full width half maximum in Volts of the peak generated during a scan of the CoV. Resolution, as defined here, provides an indication of the CoV shift and differential mobility peak width for a single compound.
Peak capacity (Pc) is defined as:
Pc=CoV range/FWHM (Equation 2)
where CoV range is the compensation range in Volts over which a large number of compounds is spread and FWHM is the average full width half maximum in Volts of the peaks generated during a scan of the CoV for a large number of compounds. The peak capacity is an indicator of the number of compounds that can be separated in a complex mixture.
A third important performance characteristic of a DMS cell is the efficiency with which it transmits ions though the mobility analyzer defined as:
Te=Sd/S (Equation 3)
where Te is the ion transmission efficiency, Sd is the number of ions measured by the mass spectrometer detector with the DMS filter installed and filtering and S is the number of ions measured by the mass spectrometer detector with no DMS filter installed on the mass spectrometer. Transmission efficiency indicates how many ions are lost in the DMS cell.
Transmission efficiency tends to run counter to both resolution and peak capacity. That is in order to maximize resolution and peak capacity, the transmission efficiency is compromised. As mentioned above, the current thinking in the field of differential ion mobility instrumentation is to maximize selectivity, i.e. resolution and peak capacity. An example of this is illustrated in the designs of Shvartsburg (Shvartsburg, A. A.; Smith, R. D. 2013. “Separation of protein conformers by differential ion mobility in hydrogen rich gases” Anal. Chem. 85, 6967-6973) which set the current record for DMS devices achieving resolution values of about 400-500.
For purposes of illustration, refer to
where l, w, h, and Q are the sensor length, width, height, and volumetric gas flow, respectively.
All aspects of the design of a DMS cell are parametric, i.e. they are highly interdependent. There is no particular dimension, ratio of dimensions, or RF frequency, amplitude, or waveform that can be expected to provide optimal performance for the primary figures of merit simultaneously, those figures of merit being resolution, peak capacity, and ion transmission efficiency (sensitivity). The design of the cell and its power supplies will accentuate some of these figures of merit while at the same time compromising others. A clear understanding of the desired application is required to define the performance specification for each of these figures of merit, which then will establish the general direction of the design of the cell. To date, the evolution of DMS instrumentation has been toward improvements in resolution and peak capacity.
Three examples of altering various aspects of the design of a particular cell and the effect that has on the performance characteristics of resolution, peak capacity, and transmission will follow to serve as examples. The cell used in these examples had dimensions of 1×10×30 mm for gap height, width, and length, respectively, with the alterations as described. The general trends that the performance characteristics display as the design is altered in the fashion described in these examples would be similar regardless of what other specific geometries or power supply specifications were to be used.
The improvement in transmission efficiency for methylhistamine ions (1×10×30 mm cell dimensions) as the separation voltage increased is seen in
The above three examples illustrate some of the effects on the performance characteristics of resolution, peak capacity, and ion transmission efficiency that the key design elements of separation voltage, gap height, and ion flight time affect. Although the data were obtained with specific geometries and power supplies; the trends can be generalized to any particular DMS or FAIMS design. As mentioned earlier, the current status in the development of DMS-MS devices by both commercial and non-commercial researchers has been in the direction of improvements to resolution and peak capacity as the first consideration. Transmission efficiency is also considered, but it plays a secondary role to the optimization of selectivity.
Accordingly, there remains a need for methods and systems that enable the analysis of increasingly complex samples with improved sensitivity, while reducing potential sources for contamination.
The present teachings are based on the unexpected discovery that the use of ionization sources operating at atmospheric pressure (e.g., electrospray and chemical ionization sources) can lead to the formation of high mass ions (e.g., charged solvent clusters) that can pass through interface regions that include counter-current gas flows (curtain gas) and contaminate the optics of an ion spectrometer as well as severely degrade the signal-to-noise ratio, for example, by generating large signal transients. In some cases, these high mass ions can have a mass greater than about 2000 amu, e.g., in a range of about 2000 amu up to and greater than 2,000,000 amu. It has additionally been discovered that an ion mobility spectrometer can be configured to filter out these high mass ions while ensuring that a substantial portion of the charged species of interest (e.g., at least about 50%, or at least about 70%, or at least about 90%) pass through the ion mobility spectrometer for analysis by a downstream mass analyzer.
The present teachings are based on the unexpected discovery that a high transmission, low resolution ion mobility spectrometer device can filter the high mass ions or charged debris to keep the vacuum system of a mass spectrometer clean for long periods of time. The device configuration takes into account the residence time of the ions through the ion mobility spectrometer, the gap height between the electrodes of the ion mobility spectrometer, and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer, wherein a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between the electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.002. In various aspects, a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between the electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.0015.
Accordingly, in various aspects, certain embodiments of the Applicants' teachings relate to a method of operating a mass spectrometer system, the method comprising providing an ion source for ionizing a sample to generate a plurality of ions, providing a low resolution, high transmission ion mobility spectrometer for reducing contamination, introducing said plurality of ions into an input end of the ion mobility spectrometer, transporting said plurality of ions in a drift gas through the ion mobility spectrometer from the input end to an output end thereof, providing a mass spectrometer in fluid communication with the differential mobility spectrometer for receiving the ions from the output end of differential mobility spectrometer, and a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.002. In various aspects, a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between the electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.0015.
In various aspects, the residence time of the ions can be less than 100 ms. In various aspects, the gap height can be between 0.02 and 5 millimeters. In various aspects, the SV comprises an RF signal applied to the electrodes, and including a CoV comprised of a DC signal applied to the electrodes, and wherein the RF and DC signals are configured to generate a fringing field in proximity of said input end of the ion mobility spectrometer effective to cause said ions having a selected mass to follow off-axis trajectories to collide with said electrodes in proximity to said input end. In various aspects, the method further comprises selecting a transit time of the ions through the ion mobility spectrometer to facilitate transit of analytes of interest through the ion mobility spectrometer. In various aspects, the transit time can be selected to provide transmission efficiency of greater than 50% for a broad mass range of ions. In various aspects, the ion mobility spectrometer comprises a differential mobility spectrometer or a FAIMS system.
In various aspects, certain embodiments of the Applicants' teachings relate to a system for analyzing ions comprising an ion source, a low resolution, high transmission ion mobility spectrometer for reducing contamination having an input end for receiving ions from source and an output end, the ion mobility spectrometer having an internal operating pressure, electrodes, and at least one voltage source for providing DC and RF voltages to the electrodes, a mass spectrometer in fluid communication with the differential mobility spectrometer for receiving the ions from the output end of differential mobility spectrometer, a controller operably coupled to the ion mobility spectrometer and configured to control the DC and RF voltages; and a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.002. In various aspects, a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between the electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.0015.
In various aspects, the residence time of the ions can be less than 100 milliseconds. In various aspects, the gap height can be between 0.02 and 5 millimeters. In various aspects, the separation voltage (SV) comprises an RF signal applied to the electrodes, and including a compensation voltage (CoV) comprised of a DC signal applied to the electrodes, and wherein the RF and DC signals are configured to generate a fringing field in proximity of said input end of the ion mobility spectrometer effective to cause said ions having a selected mass to follow off-axis trajectories to collide with said electrodes in proximity to said input end. In various aspects, the system further comprises selecting a transit time of the ions through the ion mobility spectrometer to facilitate transit of analytes of interest through the ion mobility spectrometer. In various aspects, the transit time can be selected to provide transmission efficiency of greater than 50% for a broad mass range of ions. In various aspects, the ion mobility spectrometer comprises a differential mobility spectrometer or a FAIMS system.
In some embodiments, the ion mobility spectrometer can also be configured to filter out not only the above-described high mass ions, but also ions having an m/z less than a threshold (e.g., 100, 150, or 200 amu), also referred to herein as low-mass ions. Such low mass ions can be created in high abundance due to the large number of molecules subjected to ionization at atmospheric pressures (e.g., in the presence of ambient molecules within the atmospheric or near-atmospheric chamber). For example, in some cases, when liquid samples are introduced into an atmospheric pressure ion source, the solvent molecules can produce ion current levels far in excess of the ion current associated with the analyte(s) of interest in the sample. The removal of such unwanted low-mass ions can, for example, improve the signal-to-noise provided by a downstream mass analyzer.
Accordingly, the methods and systems described herein can be effective to reduce the amount of unwanted charged material from entering the vacuum system, thereby maintaining peak performance of the mass spectrometer systems over longer periods of time and during heavy use. While the operating parameters of ion mobility spectrometers are conventionally configured to maximize resolution (e.g., to separate isobaric species while maintaining sufficient signal to resolve peaks), the present teachings are based in part on the discovery that an ion mobility spectrometer can be configured to operate in a low resolution mode, e.g., operating at a high transmission efficiency with broad peaks to maximize the transit of the species of interest through the spectrometer and thereby improve sensitivity, while nonetheless filtering out high mass and low mass species. In some embodiments, the methods and systems according to the present teachings can be employed to remove up to about 99% of unwanted ions generated by the ion source, while allowing the ions of interest to pass to a downstream mass analyzer.
In accordance with various aspects, certain embodiments of the applicants' teachings relate to a method of operating a mass spectrometer system including an ion mobility spectrometer (e.g., a differential mobility spectrometer or FAIMS) and a mass spectrometer in fluid communication with the ion mobility spectrometer. According to the method, a sample is ionized to generate a plurality of ions, which are introduced into an input end of the ion mobility spectrometer. As the plurality of ions are transported in a drift gas through the ion mobility spectrometer from the input end to an output end thereof, ions having a mass less than about 200 amu (e.g., less than about 150 amu or less than about 100 amu) and greater than about 2000 amu (e.g., in a range of about 2000 amu to about 2,000,000 amu) are filtered from the drift gas as the plurality of ions are transported within the ion mobility spectrometer. The method can also include introducing ions exiting the output end of the ion mobility spectrometer into the mass spectrometer.
In some aspects, the filtering steps can comprise diverting (e.g., deflecting) a portion of the ions to collide with at least one electrode of said ion mobility spectrometer. In various aspects, filtering ions or charged particles having a mass greater than about 2000 amu comprises applying an RF signal to electrodes of the ion mobility spectrometer, the RF signal having an amplitude and frequency configured to cause said ions having a mass greater than about 2000 amu to follow unstable trajectories.
In accordance with some aspects, the ion mobility spectrometer comprises at least a pair of electrodes having a separation voltage and a compensation voltage applied thereto, the method further comprising selecting a CoV such that a broad mass range of analytes are transported through the ion mobility spectrometer to exit through said output end thereof. For example, in some aspects, the combination of CoV and SV can comprise RF and DC signals applied to at least one of the electrodes configured to generate a fringing field in proximity of said input end of the ion mobility spectrometer effective to cause said ions having a mass greater than 2000 amu to follow off-axis trajectories to collide with said electrodes in proximity to said input end.
In various aspects, the transit time of the ions through the ion mobility spectrometer can be selected to facilitate transit of analytes of interest through the ion mobility spectrometer. For example, the transit time can be selected to provide transmission efficiency of greater than 50% or more for a broad mass range of ions. By way of example, the transit time can be less than about 7 ms, less than about 6 ms, less than about 5 ms, and less than about 2 ms, in various embodiments that include a 1 mm gap height between electrodes. In various embodiments, the transmit time may vary depending upon gap height or separation voltage. In some aspects, the transit time can be selected to minimize losses of ions within a selected mass or m/z range. For example, the transit time can be selected such that ions entering the input end of the ion mobility spectrometer and having a mass in the range of about 200 amu to about 2000 amu are preferentially transported to the output end of the ion mobility spectrometer. In related aspects, the ions having a mass in the range of about 200 amu to about 2000 amu can be substantially unresolved at the output end of the ion mobility spectrometer. In this manner, the differential ion mobility spectrometer operates in a broad band pass mode, rather than the ion resolving mode used in the prior art. In some aspects, the ion mobility spectrometer can be configured with gas flows and cell dimensions scaled to provide resolutions sufficiently low to provide transmission efficiencies greater than 50% for a broad mass range of interest.
In some embodiments, the gas flow rate through the ion mobility spectrometer can be selected to ensure that ions of interest transit through the spectrometer with minimal loss, if any, e.g., a loss of less than about 50%, less than about 20%, or less than about 10%, while the high mass and low mass ions are filtered out. In various aspects, the method can comprise selecting a flow rate of the drift gas through the ion mobility spectrometer such that the transit time is less than about 1 ms and providing transmission efficiencies greater than about 50% for a broad mass range. By way of example, the flow rate of the drift gas through the ion mobility spectrometer can be greater than about 5 L/min for providing efficiencies greater than about 50% for a broad mass range when using electrode dimensions of 1×10×30 mm.
In accordance with another aspect, certain embodiments of the applicants' teachings relate to a method of operating a mass spectrometer system including an ion mobility spectrometer and a mass spectrometer in fluid communication with the ion mobility spectrometer. According to the method, a sample can be ionized to generate a plurality of charged species and the charged species can be introduced into an input end of the ion mobility spectrometer. Ions of said charged species having a mass in a range from about 200 amu to about 2000 amu can be preferentially transported to an output end of the ion mobility spectrometer, the gas flows and cell dimensions of the operating ion mobility spectrometer (e.g., non-zero DC and/or RF voltages being applied thereto) being configured to provide transmission efficiencies greater than 50% for a broad mass range.
In accordance with some aspects, certain embodiments of the applicants' teachings relate to a system for analyzing ions comprising an ion source (e.g., an atmospheric pressure ion source) and an ion mobility spectrometer having an input end for receiving ions from the ion source and an output end, the ion mobility spectrometer having an internal operating pressure, electrodes, and at least one voltage source for providing DC and RF voltages to the electrodes. The system further includes a mass spectrometer in fluid communication with the differential mobility spectrometer for receiving the ions from the output end of the differential mobility spectrometer. A controller can be operably coupled to the ion mobility spectrometer and configured to control the DC and RF voltages such that the ion mobility spectrometer preferentially transports ions having a mass in a range from about 200 amu to about 2000 amu to the output end of the ion mobility spectrometer. In some aspects, the controller can be configured to operate the ion mobility spectrometer with a transmission efficiency of greater than 50% for a broad mass range.
In some aspects, the controller can be configured to modulate the RF and DC potentials applied to the electrodes so as to generate a fringing field in proximity to the input end of the ion mobility spectrometer, the fringing field configured to filter ions having a mass greater than about 2000 amu (e.g., in a range of about 2000 amu to about 2,000,000 amu) or less than about 200 amu, from the ions received from the ion source. Alternatively or additionally, the controller can be configured to modulate the DC and RF potentials applied to the electrodes such that ions having a mass less than about 200 amu are filtered as the ions received from said source are transported through the ion mobility spectrometer.
In various aspects, a vacuum chamber can surround the mass spectrometer for maintaining the mass spectrometer at a vacuum pressure lower than the internal operating pressure of the ion mobility spectrometer, the vacuum chamber being operable to draw a drift gas flow including the ions through the differential mobility spectrometer and into the vacuum. Multiple differentially pumped vacuum stages, including ion transport optics may be disposed between the atmospheric pressure inlet and the high-vacuum region containing the mass analyzer. The system can additionally include a gas port for modifying a gas flow rate through the ion mobility spectrometer, the gas port being located between the ion mobility spectrometer and the mass spectrometer. In related aspects, the controller can be configured to modulate the gas flow rate through the ion mobility spectrometer and the at least one voltage source such that the ion mobility spectrometer can be modulated between a low-resolution mode in which the transmission efficiency is greater than 50% for a broad mass range of ions and a high-resolution mode in which ions can be resolved based on their mobility in the ion mobility spectrometer. In some aspects, the gas flow rate in the low-resolution mode is greater than the gas flow rate in the high-resolution mode. For example, the gas flow rate in the low-resolution mode can be greater than about 5 L/min. By way of example, the gas flow rate in the low-resolution mode can be scaled with the cell dimensions to provide a transmission efficiency greater than 50%.
In accordance with some aspects, certain embodiments of the applicants' teachings relate to a mass spectrometer system including a mass analyzer located in a high vacuum chamber for analyzing sample ions formed at atmospheric pressure and directed to the analyzer through an intermediate atmospheric pressure chamber. The intermediate atmospheric pressure chamber can include at least one pair of electrodes in opposition to each other defining a path through which the ions travel, said path including a region of defocusing electric fringe fields; means associated with the opposing electrodes for deflecting charged clusters and/or debris having an m/z greater than a first threshold within a gas stream entering an input end of the plurality of electrodes, the deflection preventing the charged clusters and/or debris from entering the high vacuum chamber; means associated with the opposing electrodes for deflecting unwanted ions having an m/z lower than a second threshold such that said ions of lower m/z are prevented from entering the high vacuum chamber; and means for providing a high volumetric gas flow through the plurality of electrodes, the gas flow being configured for transporting the ions to the mass spectrometer with minimal loss of ions in a m/z range between the lower m/z and the higher m/z.
These and other features of the applicants' teachings are set forth herein.
The skilled person in the art will understand that the drawings, described below, are for illustration purposes only. The drawings are not intended to limit the scope of the applicants' teachings in any way.
It will be appreciated that for clarity, the following discussion will explicate various aspects of embodiments of the applicants' teachings, while omitting certain specific details wherever convenient or appropriate to do so. For example, discussion of like or analogous features in alternative embodiments may be somewhat abbreviated. Well-known ideas or concepts may also for brevity not be discussed in any great detail. The skilled person will recognize that some embodiments of the applicants' teachings may not require certain of the specifically described details in every implementation, which are set forth herein only to provide a thorough understanding of the embodiments. Similarly it will be apparent that the described embodiments may be susceptible to alteration or variation according to common general knowledge without departing from the scope of the disclosure. The following detailed description of embodiments is not to be regarded as limiting the scope of the applicants' teachings in any manner.
Methods and systems for performing mass spectrometry utilizing an ion mobility spectrometer are provided herein. In accordance with various aspects of the applicants' teachings, the methods and systems described herein can be effective to reduce the amount of unwanted charged material from entering the vacuum system by deflecting this charged material to non-critical surfaces located in the atmospheric region of the instrument, where they can be readily accessed, cleaned and/or replaced. In some aspects, intervals between maintenance of vacuum system components may be increased by at least an order of magnitude.
While the operating parameters of ion mobility spectrometers are conventionally configured to optimize resolution (e.g., by separating isobaric species), the present teachings provide an ion mobility spectrometer operating in a low resolution mode to optimize the transit of the species of interest through the spectrometer and thereby improve sensitivity, while filtering out unwanted high mass and low mass species.
As indicated above, the present teachings are based in part on the discovery that the use of ionization sources operating at atmospheric pressure (e.g., electrospray and chemical ionization sources) can lead to the formation of high mass ions (e.g., charged solvent clusters) that may pass through mass spectrometer inlets that include curtain gas protection. With reference now to
In some cases, these high mass ions can have a mass greater than about 2000 amu, e.g., in a range of about 2000 amu up to and greater than 2,000,000 amu. As discussed below, the present teachings provide an ion mobility spectrometer configured to filter out these high mass ions while ensuring that a substantial portion of the charged species of interest (e.g., at least about 50%, or at least about 70%, or at least about 90%) pass through the ion mobility spectrometer for analysis by a downstream mass analyzer.
Additionally, in accord with various aspects of the present teachings, the ion mobility spectrometer can be configured to filter out not only the above-described high mass ions, but also ions having an m/z less than a threshold (e.g., 100, 150, or 200 amu). Such low mass ions can be created in high abundance due to the large number of molecules subjected to ionization at atmospheric pressure (e.g., in the presence of ambient molecules within the atmospheric or near-atmospheric chamber). For example, in some cases, when liquid samples are introduced into an atmospheric pressure ion source, the solvent molecules can produce ion current levels far in excess of the ion current associated with the analyte(s) of interest in the sample. The removal of such unwanted low-mass ions can, for example, improve the signal-to-noise provided by a downstream mass analyzer.
While the operating parameters of ion mobility spectrometers are conventionally configured to optimize the resolution provided by the spectrometer (e.g., to separate isobaric species), the present teachings provide an ion mobility spectrometer configured to operate in a low resolution mode, e.g., operating at a resolution sufficiently low to provide transmission efficiencies of greater than 50% for a broad mass range through the spectrometer and thereby improve sensitivity, while filtering out high mass and low mass species. In various embodiments, the methods and systems according to the present teachings can be employed to remove up to about 99% of unwanted ions generated by the ion source, while allowing the ions of interest to pass to a downstream mass analyzer.
With reference now to
In the exemplary embodiment depicted, in
In accordance with various aspects of the present teachings, a controller 122 can be operably coupled to the differential mobility spectrometer 110 and configured to control the DC and RF voltages applied to the electrodes such that ions having a mass in a selected range from about 200 amu to about 2000 amu (or in a range from about 100 amu to about 2000 amu, or in a range of about 150 amu to about 2000 amu) are preferentially transmitted to the outlet end 120. By way of example, the controller can be configured to modulate the RF and DC potentials applied to the electrodes so as to generate a fringing field in proximity to the input end 118 of the differential mobility spectrometer 110. Applicants have discovered that such a fringing field can be effective, for example, to deflect ions having a mass greater than about 2000 amu (e.g., in a range of about 2000 amu to about 2,000,000 amu) or less than about 200 amu from the axis of the differential mobility spectrometer such that these ions are neutralized (i.e., collide) with the electrodes proximate to the inlet 118. Additionally or alternatively, the controller can control the CoV and SV applied to the electrode plates 112, for example, such that low-mass ions (e.g., ions having a mass less than about 200 amu) are deflected into the electrodes 112 as they are transported through the differential mobility spectrometer 110 while entrained in the drift gas 116. Without being bound by an particular theory, it is believed that low mass ions exhibit increased mobility and/or experience an increased force as they are transmitted through the electric field within the differential mobility spectrometer such that the deflection of these low-mass ions is sufficient such that these ions collide with the electrodes 112. In some aspects, the controller can be configured to operate the differential mobility spectrometer at a resolution of less than about 10, 5, or 1.
The outlet end 120 of the differential mobility spectrometer 110 releases the drift gas 116 and ions transmitted through the differential mobility spectrometer 110 towards an inlet 154 of a vacuum chamber 152 containing the mass spectrometer 150.
The drift time through the flight tube and therefore the mobility of an ion is characteristic of the size and shape of the ion and its interactions with the background gas. As shown in
Ions can be provided from an ion source (not shown) and emitted into the curtain chamber 130 via curtain chamber inlet 144. As will be appreciated by a person skilled in the art, the ion source can be virtually any ion source known in the art, including for example, a continuous ion source, a pulsed ion source, an atmospheric pressure chemical ionization (APCI) source, an electrospray ionization (ESI) source, an inductively coupled plasma (ICP) ion source, a matrix-assisted laser desorption/ionization (MALDI) ion source, a glow discharge ion source, an electron impact ion source, a chemical ionization source, or a photoionization ion source, among others. The pressure of the curtain gases in the curtain chamber 130 (e.g., ˜760 Torr) can provide both a curtain gas outflow 142 out of curtain gas chamber inlet 144, as well as a curtain gas inflow 137 into the differential mobility spectrometer 110, which inflow 137 becomes the drift gas 116 that carries the ions through the differential mobility spectrometer 110 and into the mass spectrometer 150 contained within the vacuum chamber 152, which can be maintained at a much lower pressure than the curtain chamber 130. For example, the vacuum chamber 152 can be maintained at a pressure of 2.3 Torr by a vacuum pump.
As shown in
Thus, whereas prior art differential mobility spectrometers are configured to optimize selectivity (e.g., by increasing transit time of the drift gas 116 such that the target analyte can be separated from an interfering species at the expense of sensitivity (i.e., through neutralization of the interfering species on the electrodes by tuning the CV to preferentially transmit an ion of interest or by altering the CV such that peaks between various species can be resolved as the CV is ramped), systems in accord with the present teachings exhibit transit times that minimize losses (e.g., maximize transmission, increasing peak width and height) of species exhibiting a broad range of m/z and mobilities.
By way of example, in systems in accord with the present teachings, the drift gas 116 can impart transit times for the ions through the differential mobility spectrometer 110 of less than 7 ms (e.g., 6.5 ms, less than 5 ms, less than 2 ms, less than 1 ms). Though such transit times can result in the differential mobility spectrometer exhibiting a reduced resolution, the drift gas 116 flow rate through the ion mobility spectrometer 110 can ensure that ions of interest transit through the spectrometer with minimal loss, if any, e.g., a loss of less than about 50%, or less than about 20%, or less than about 10%, while the high mass (e.g., greater than 2000 amu) and low mass ions (e.g., less than 200 amu) are filtered out (e.g., deflected off-axis so as to collide with an electrode 112) as discussed otherwise herein.
Moreover, it will be appreciated in light of the present teachings that other variables can be selected so as to maximize transmission through the ion mobility spectrometer. By way of non-limiting example, the dimensions of the differential mobility spectrometer 110, the number gas density, the pressure of the curtain chamber, and/or the flow rate of the drift gas can be modulated so as to optimize transmission. For example, the ion mobility spectrometer can be configured with gas flows and cell dimensions scaled to provide resolutions sufficiently low to provide transmission efficiencies greater than 50% for a broad mass range of interest. By way of non-limiting example, in an ion mobility spectrometer having a length of about 30 mm (1×10×30 mm) along its transmission axis and a distance between electrodes of about 1 mm, a flow rate of about 3.8 L/min can result in a residence time of about 4.2 ms while a flow rate of about 6.5 L/min can result in a residence time of about 1.8 msec.
With reference again to
As will be appreciated by a person skilled in the art, the mass spectrometer 150 can additionally include mass analyzer elements 150a downstream from vacuum chamber 152. Ions can be transported through vacuum chamber 152 and may be transported through one or more additional differentially pumped vacuum stages containing one or more mass analyzer or ion transport elements 150a. For instance, in one embodiment, a triple quadrupole mass spectrometer may comprise three differentially pumped vacuum stages, including a first stage maintained at a pressure of approximately 2.3 Torr, a second stage maintained at a pressure of approximately 6 mTorr, and a third stage maintained at a pressure of approximately 10−5 Torr. The third vacuum stage can contain a detector, as well as two quadrupole mass analyzers with a collision cell located between them. It will be apparent to those skilled in the art that there may be a number of other ion optical elements in the system. Other type of mass analyzer such as single quadrupole, ion trap (3D or 2D), hybrid analyzer (quadrupole-time of flight, quadrupole-linear ion trap, quadrupole-orbitrap), orbitrap or time-of-flight, could also be used.
In operation, a sample containing or suspected of containing an analyte(s) of interest can be prepared in accordance with various methods as known in the art for introduction into the differential mobility spectrometer 110. The ions can be generated adjacent the inlet 150 of the curtain chamber 130 and then transported through the differential mobility spectrometer 110 that is configured to remove both low-mass ions (e.g., ionized solvent molecules exhibiting less than 200 m/z or less than 100 m/z) and high-mass ions (e.g., charged residues exhibiting greater than 2000 m/z or a mass greater than 2000 amu). The remainder of ions (e.g., ions exhibiting m/z in a range of about 200 Da to about 2000 Da) can be transmitted by the differential mobility spectrometer 110 to downstream mass analyzer elements 150, 150a for further analysis or detection, as is known in the art.
As indicated above, contamination of mass spectrometer ion paths by substances created during the electrospray ionization of samples and solvents is of major concern. Costly and time consuming cleaning procedures are required to ameliorate the problem. Extensive efforts have been employed to develop devices to minimize or eliminate this problem. To date, the field has focused on the use of shadow stops or curvatures in ion guides located in the vacuum system of the mass spectrometer to filter neutral components thought to be the cause of contamination from the ion beam. Neutral particles follow a straight trajectory through curved fields whereas ions and charged particles follow the fields. If neutral particles were the primary source of contamination, then curved ion guides or shadow stops would eliminate them and prevent them from going deeper into the vacuum system where they can do more damage. If, however, the main source of contamination was charged particles and high ion currents from electrospray solvents, this approach would serve no purpose because the charged contaminants would follow the curved fields and travel around any shadow stops.
Furthermore, the present teachings are based on the discovery that a high transmission, low resolution ion mobility device can filter the high mass ions or charged debris to keep the vacuum system of a mass spectrometer clean for long periods of time. The device configuration takes into account the residence time of the ions through the ion mobility spectrometer, the gap height between the electrodes of the ion mobility spectrometer, and the maximum separation voltage applied to the ion mobility spectrometer, wherein a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between electrodes of the ion mobility spectrometer and the maximum separation voltage being less than 0.002. In various aspects, a ratio of the residence time of the ions through the ion mobility spectrometer to the product of gap height between the electrodes of the ion mobility spectrometer and the maximum separation voltage applied to the electrodes of the ion mobility spectrometer being less than 0.0015. Conventional prior art ion mobility devices have been configured to achieve high selectivity to maximize the separation power at the expense of transmission of the ions and sensitivity differing from the Applicants' counter-intuitive teachings of a low resolution ion mobility device designed to filter charged particles prior to the vacuum system while achieving high transmission of ions.
In various aspects, the residence time of the ions can be less than 100 ms. In various aspects, the gap height can be between 0.02 and 5 millimeters. In various aspects, the SV comprises an RF signal applied to the electrodes, and including a CoV comprised of a DC signal applied to the electrodes, and wherein the RF and DC signals are configured to generate a fringing field in proximity of said input end of the ion mobility spectrometer effective to cause said ions having a selected mass to follow off-axis trajectories to collide with said electrodes in proximity to said input end. In various aspects, the method and system further comprise selecting a transit time of the ions through the ion mobility spectrometer to facilitate transit of analytes of interest through the ion mobility spectrometer. In various aspects, the transit time can be selected to provide transmission efficiency of greater than 50% for a broad mass range of ions. In various aspects, the ion mobility spectrometer comprises a differential mobility spectrometer or a FAIMS system.
Experiments were conducted to determine whether the main source of mass spectrometer contamination was from neutral particles or charged substances, the results are shown in
The experiment was repeated with all conditions identical except a DMS cell according to the Applicants' teachings was installed. As seen in
To make sure the curtain gas was deflecting neutral materials that could be generated by the spraying of Hank's buffer, a third experiment was done with the results shown in
Photographs of critical lens elements from the mass spectrometer inlet and inside the vacuum further corroborating the effectiveness of the DMS as a charged debris filter according to the Applicants' teachings are shown in
Charged materials generated by an electrospray process can take two forms. It can be in the form of charged molecules (ions); the vast majority of which is the electrospray solvent. The overwhelming abundance and intensity of the ion current from the solvent ions can be readily seen in a mass spectrum. It may be possible that they can be a source of ion burn on critical lenses inside the vacuum system. But, solvent ions are volatile and cannot be expected to build up debris to the extent as that shown in
Subsequent to this experiment, the inventors have discovered the existence of previously unknown physical entities in the form of substances with very high mass to charge ratio beyond the mass range of mass spectrometers. We have characterized their nature with a novel scan mode for a tandem mass spectrometer that we developed specifically for this purpose. These substances are ubiquitous and an inherited by-product of electrospray ionization. All indications are that they are a major source of mass spectrometer analyzer contamination. It is these substances, in combination with the extremely high ion currents that are produced by electrospray from the low mass solvent ions, which can cause the fouling of critical components in the ion path located in the vacuum system of mass spectrometers leading to distortions in the electric fields of the mass filters and focusing lenses resulting in reduced performance. An understanding of these substances and their effect on analyzer contamination is neither known nor obvious in the current state of the science involving mass spectrometry.
The scan mode we developed to prove the existence of these high mass charged particles is described below and is referred to as the “Asteroid scan.” It has no analytical purpose other than as a means to observe and quantitate these materials. The Asteroid scan can be done on a triple quadrupole mass spectrometer. All samples will produce asteroids, but the more organic and inorganic solutes in the electrospray solvent, the more asteroids are produced. The asteroids can be tracked by adding to the solvent a standard reference compound such as reserpine which becomes trapped in the asteroid during the ionization process. The sample is infused into the ion source. Quadrupole 1 mass filter is set to open resolution at m/z 1250 by dropping the mass resolving DC voltage ramp. Under these conditions, no ions below m/z 1000 pass Q1, but all ions and charged particles above m/z 1000 pass. Collision gas is put into the collision cell, and the collision energy is initially set to 0 volts. When quadrupole 3 is scanned, the resulting mass spectrum shows no ions at any mass. As the collision energy is raised to 150 eV, ions from the seed compound begin to appear in the Q3 spectrum and increase in intensity as they are released from the high mass charged particle.
The understanding of the existence of these high mass charged particles and their role in analyzer contamination is new knowledge. It presents the opportunity for a new application of a DMS based device that would require design characteristics substantially different from the current status that teaches away from optimizing the performance specifications of current generation DMS mobility cells. The ideal contamination filter would first remove charged particles before entering the vacuum system which is essentially what current DMS cells do. But, it would also have broad band pass characteristics which would limit its separation capability to only the removal of high mass charged particles and low mass solvent ions. This would mean the design would drive toward very low resolution and peak capacity instead of high resolution and peak capacity. The separation of isobars would no longer be of any relevance to the design of this device given its primary application of the maximization of ion transmission whereas in the prior art, this figure of merit was secondary to resolution and peak capacity.
In order to achieve the goal of maximum ion transmission efficiency while maintaining adequate resolution and peak capacity to serve as a broad band pass contamination filter, the relationship of three key design elements are considered. These elements are ion flight time, cell gap height, and maximum separation voltage. Following is data describing the effect that each one has on the three performance characteristics for the basic DMS described in
Gap height is considered in
Separation voltage (SV) is considered in
Flight time also known as residence time is considered in
The three most important design elements determining the performance characteristics of resolution, peak capacity and transmission are flight time, gap height, and separation voltage. They operate together in a partial inverse relationship we refer to as the Resolution-Transmission Index or RT Index mathematically expressed as:
RT=τ/hSv (Equation 5)
where τ is the flight time, h is the gap height, and Sv is the separation voltage.
RT Index is considered in
The value of a low resolution device is that it allows a large range of analyte ions with a broad range of mobilities to pass without having to alter the SV or CoV voltages. This helps keep the duty cycle of the system to a maximum.
The spectra and images in
In accordance with the Applicants' teachings, the majority of contaminating species are being kept out of the vacuum system and away from the ion entrance aperture of the mass spectrometer due to the Applicants' high transmission mobility filter ion scrubber.
The section headings used herein are for organizational purposes only and are not to be construed as limiting. While the Applicants' teachings are described in conjunction with various embodiments, it is not intended that the applicants' teachings be limited to such embodiments. On the contrary, the Applicants' teachings encompass various alternatives, modifications, and equivalents, as will be appreciated by those of skill in the art.
This application claims priority to U.S. provisional application No. 61/838,185 filed on Jun. 21, 2013, entitled “Contamination Filter for Mass Spectrometer,” which is incorporated herein by reference in its entirety and to U.S. provisional application No. 62/014,657 filed on Jun. 19, 2014, entitled “Contamination Filter for Mass Spectrometer,” which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2014/001143 | 6/20/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/203071 | 12/24/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
20080128609 | Miller et al. | Jun 2008 | A1 |
20090152455 | Wang et al. | Jun 2009 | A1 |
20100207022 | Tang | Aug 2010 | A1 |
20100213366 | Fernandez De La Mora et al. | Aug 2010 | A1 |
20110101214 | Miller | May 2011 | A1 |
20110127419 | Thomson et al. | Jun 2011 | A1 |
20110183431 | Covey | Jul 2011 | A1 |
20110253890 | Belford | Oct 2011 | A1 |
Number | Date | Country |
---|---|---|
2007-507077 | Mar 2007 | JP |
Entry |
---|
International Search Report for PCT/IB2014/001143, mailed Nov. 6, 2014. |
Number | Date | Country | |
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20160118234 A1 | Apr 2016 | US |
Number | Date | Country | |
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61838185 | Jun 2013 | US | |
62014657 | Jun 2014 | US |