The teachings herein relate to ion reaction devices, and more particularly, to methods and systems for performing electron induced dissociation (EID).
Ion reactions typically involve the reaction of either a positively or negatively charged ion with another charged species, which can be another positively or negatively charged ion or an electron. In electron induced dissociation (EID), for example, an electron is captured by an ion which can result in the fragmentation of the ion. EID has been used to dissociate bio-molecules in mass spectrometry (MS), and has provided capabilities that cover a wide range of possible applications from regular proteomics in liquid chromatography-mass spectrometer/mass spectrometer (LC-MS/MS) to top down analysis (no digestion), de novo sequencing (abnormal amino acid sequencing finding), post translational modification study (glycosylation, phosphorylation, etc.), protein-protein interaction (functional study of proteins), and also including small molecule identification.
After the first report of electron capture dissociation (ECD) using electrons having kinetic energies of 0 to 3 eV, other electron induced techniques have also been developed including electron transfer dissociation (ETD) (using reagent anions), Hot ECD (electrons with kinetic energy of 5 to 10 eV), electron ionization dissociation (EID) (electrons with kinetic energy greater than 13 eV), activated ions ECD (AI-ECD), electron detachment dissociation (EDD) (electrons with kinetic energy greater than 3 eV on negative ions), negative ETD (using reagent cations), and negative ion ECD (niECD, using electrons on negative ions), Electron Impact Excitation of Ions from Organics (EIEIO, electrons with kinetic energy greater than 3 eV on singly charged cations). ECD, ETD, Hot ECD, AI-ECD, and EIEIO are utilized for positively charged precursor ions, while others such as niECD are utilized for negatively charged precursor ions. EID can be utilized to dissociate precursor ions of both polarities, including singly charged precursors. Since their discovery, these ion reaction techniques have become very useful for analyzing biomolecular species, such as peptides, proteins, glycans, and post translationally-modified peptides/proteins. ECD, for example, allows top down analysis of proteins/peptides and de novo sequencing of them. Proton transfer reactions (PTR) can also be utilized to reduce the charge state of ions in which a proton is transferred from one charged species to another.
These electron induced dissociations are considered to be complimentary to conventional collision induced or activated dissociations (CID or CAD) and have been incorporated in advanced MS devices.
In ECD, low energy electrons (typically <3 eV) are captured by positive ions. Historically, ECD was performed in a Fourier transform ion cyclotron resonance mass spectrometer (FT-ICR) because FT-ICR generally utilizes a static electro-magnetic field for ion confinement that avoids the heating of free electrons. However, such devices required relatively long interaction times and involved large instruments that were expensive to build. Attempts to use ECD in smaller applications involving Radio Frequency (RF) ion traps have been found to cause acceleration of electrons due to the trapping RF field. As a result, the field generally turned to ETD, which used negatively charged reagent ions as the electron source, or implemented ECD in a linear RF ion trap with a magnetic field.
The usage of the term ECD in the present teachings hereinafter should be understood to encompass all forms of electron related dissociation techniques, and is not limited to the usage of ECD with electrons with kinetic energy of 0 to 3 eV. Rather, usage of the term ECD within the present teachings is representative of electron related dissociation techniques, and should be understood to include all forms of electron related dissociation phenomenon including hot ECD, EID, EDD, EIEIO, and negative ECD.
ECD and ETD conventionally require relatively long reaction times between the precursor ions and reagent ions to effect (“de-ionization” or ionization)/dissociation. Though devices have been described that perform ion reactions in a “flow through” mode in which precursor ions are continuously flowed through the reaction region, such devices typically suffer from poor reaction efficiency. For example, it was reported that ExD product ion signal/total precursor ion signal can be less than 1%. See Voinov, V. G.; Deinzer, M. L.; Barofsky, D. F. Anal. Chem. 2009, 81, 1238-1243. Accordingly, linear ion traps have been utilized to simultaneously trap precursor and reagent ions during the ion reaction events, for example, with the electron injection and precursor ion injection/extraction sharing the same ports (or the same end lens electrodes). Trapping operations, however, typically require multiple steps and have poor compatibility with conventional CID-based quadrupole Time-of-Flight mass spectrometers (qToF), which generally operate in a continuous flow through manner. Moreover, the duty cycle is decreased because when trapping one analyte ion population, the rest of the analytical ion beam goes unused.
Recently, a new ECD device was reported that utilizes a branched RF ion trap structure in which a low-energy electron beam can be injected orthogonally into the analytical ion beam with independent control of both the ion and electron beams. See PCT App. No. PCT/IB2014/00893, filed on May 29, 2014, which is incorporated herein by reference in its entirety. This device could operate in either “flow-through” mode or simultaneous trapping mode, though it was reported that a short ion trapping period at the region of precursor ion and electron beam intersection could increase ECD efficiency while still providing up to five ECD spectra per second when operating in an information-dependent acquisition workflow.
Accordingly, there remains a need for ECD devices and methods for operating in a pure “flow through” mode, with high ion reaction efficiency.
In accordance with some various aspects of the present teachings, ECD methods and systems are provided herein for interacting precursor ions with charged species for an increased duration and/or along a substantially longer path length relative to known ion reaction devices, without simultaneously trapping the precursor ions and charged species, thereby increasing efficiency of the ion reaction and/or improving continuous or “flow through” operability and compatibility with conventional CID based processes. In various aspects, the methods and systems transmit precursor ions from their injection axis and along the injection axis of the reagent species (e.g., charged species, ions, electrons, protons) before exiting the ion reaction apparatus. In some embodiments, continuous or “flow through” ion reactions can be performed so that an optimum duty cycle for ToF measurement is realized.
In accordance with various aspects of the present teachings, an ion reaction apparatus is provided, the ion reaction apparatus comprising a first plurality of electrodes arranged to define a first pathway therebetween, the first pathway comprising a first axial end configured to receive ions from an ion source and a second axial end disposed at a distance from the first axial end of the first pathway extending at least partially along a first central axis; a second plurality of electrodes arranged to define a second pathway extending along a second central axis, said second pathway intersecting the first pathway at a first intersection point, the second central axis being substantially orthogonal to the first central axis; and a third plurality of electrodes arranged to define a third pathway therebetween, the third pathway comprising a first axial end and a second axial end disposed at a distance from the first axial end of the third pathway to transmit at least one of ions and reaction products of said ions out of the ion reaction apparatus, said third pathway extending at least partially along a third central axis substantially orthogonal to the second central axis and intersecting the second pathway at a second intersection point spaced a distance apart from the first intersection point. The first, second, and third plurality of electrodes are configured to couple to an RF voltage source that provides an RF voltage to each of the electrodes of the first, second, and third plurality of electrodes. The apparatus can also include a charged species source for introducing a charged species into the second pathway along the second central axis extending between the first and second intersection points. In various aspects, the apparatus enables the ions to interact with the charged species substantially along the second pathway so as to cause electron capture dissociation, for example. By way of non-limiting example, the interaction length between the ions and the charged species can be increased relative to known ECD devices operating in a flow through mode, wherein the interaction length is at least about 10 mm.
In various aspects of the present teachings, the first central axis and the third central axis can be parallel. Additionally or alternatively, the first central axis and the second central axis can extend through the first intersection point, and the second central axis and the third central axis can extend through the second intersection point. In various aspects, the first axial end of the first pathway and the second axial end of the third pathway can be collinear.
The charged species source can have a variety of configurations in accordance with the present teachings. By way of example, the second pathway can extend between a first axial end and a second axial end disposed at a distance from the first axial end of the second pathway, with the charged species source being disposed at or proximate one of the first or second axial end of the second pathway. Alternatively, each of the axial ends of the second pathway can have a charged species source (the same or different from one another), wherein only one of said charged species sources is operational at a time. One of the charged species sources can be an electron emitter, for example, a filament (e.g., tungsten, thoriated tungsten, or others), or a Y2O3 cathode. In various aspects, the apparatus can further comprise a magnetic field generator that generates a magnetic field parallel to and along said second central axis. In various aspects, the second pathway can include lenses disposed at or proximate at least one of the axial ends of said second pathway for focusing the charged species emitted from the charged species source. In some embodiments, the charged species can be reagent anions.
In various aspects, a laser source can be disposed at or proximate to an axial end of the second pathway opposite the charged species source, the laser source for providing energy (e.g., ultraviolet or infrared light) to said ions or said charged species. In various embodiments, the injection of photons can provide complementary dissociation techniques, such as UV photo dissociation and infrared multiphoton dissociation (IRMPD), as well as a activation means for AI-ECD.
In various aspects, the apparatus can also include an ion source (e.g., a source of cations or anions) disposed at or proximate the first axial end of said first pathway for introducing the ions along the first central axis.
The first, second, and third plurality of electrodes can have a variety of configurations in accordance with the present teachings, and can comprise solid rod-type electrodes or substantially planar electrodes (e.g., formed from a surface of a printed circuit board (PCB)). By way of example, the first plurality of electrodes can comprise a set of quadrupole electrodes arranged in a quadrupole orientation around the first central axis for guiding ions along the first pathway, the second plurality of electrodes can comprise a set of quadrupole electrodes arranged in a quadrupole orientation around the second central axis for guiding ions along the second pathway, and the third plurality of electrodes can comprise a set of quadrupole electrodes arranged in a quadrupole orientation around said third central axis for guiding ions along the third pathway.
In accordance with various aspects of the present teachings, the apparatus can further include a voltage source for providing an RF voltage to said first, second, and third plurality of electrodes to generate an RF field (e.g., along one or more of the pathways defined by the electrodes) and a controller for controlling RF voltages applied to the electrodes. In related aspects, the apparatus can further comprise a fourth plurality of electrodes arranged around the first central axis and disposed on an opposed side of the second central axis from the first plurality of electrodes. As described in detail below, at least one of the first plurality of electrodes can also comprise one of the second plurality of electrodes and at least one of the fourth plurality of electrodes can also comprise one of the second plurality of electrodes. In some aspects, the controller can be configured to deliver voltage to the first and fourth plurality of electrodes such that: i) each electrode in the first plurality of electrodes is paired with another electrode in the first plurality of electrodes to form an electrode pair such that one electrode in each electrode pair of the first plurality of electrodes has the same polarity and is directly opposite across the first central axis of the other electrode in the electrode pair of said first plurality of electrodes, ii) each electrode in said fourth plurality of electrodes is paired with another electrode in said fourth plurality of electrodes to form an electrode pair such that one electrode in each electrode pair of said fourth plurality of electrodes has the same polarity and is directly opposite across the first central axis of the other electrode in the electrode pair of said fourth plurality of electrodes, and iii) each electrode in said first plurality of electrodes is paired with an electrode in said fourth plurality of electrodes to form an electrode pair such that each electrode in each electrode pair of said first and fourth plurality of electrodes has opposite polarity and is directly opposite across the first intersection point of the other electrode in the electrode pair of said first and fourth plurality of electrodes, and iv) wherein the RF fields generated between said first intersection point and said first plurality of electrodes is in reverse phase to the RF fields generated between said first intersection point and said fourth plurality of electrodes. In some aspects, the RF fields generated are at a frequency of between about 400 kHz to 1.2 MHz (e.g., about 800 kHz). In some aspects, the RF field can be 100-500V peak to peak, though a greater or lower amplitude RF signal can be utilized in accordance with the present teachings.
In related aspects, the apparatus can further comprise a fifth plurality of electrodes arranged around said third central axis and disposed on an opposed side of the third central axis from the third set of electrodes, and optionally, wherein at least one of the third plurality of electrodes also comprises one of the second plurality of electrodes and wherein at least one of the fifth plurality of electrodes also comprises one of the second plurality of electrodes. In a related aspect, the controller can be configured to deliver voltage to the third and fifth plurality of electrodes such that: i) each electrode in said third plurality of electrodes is paired with another electrode in said third plurality of electrodes to form an electrode pair such that one electrode in each electrode pair of said third plurality of electrodes has the same polarity and is directly opposite across the third central axis of the other electrode in the electrode pair of said third plurality of electrodes, ii) each electrode in said fifth plurality of electrodes is paired with another electrode in said fifth plurality of electrodes to form an electrode pair such that one electrode in each electrode pair of said fifth plurality of electrodes has the same polarity and is directly opposite across the third central axis of the other electrode in the electrode pair of said fifth plurality of electrodes, iii) each electrode in said third plurality of electrodes is paired with an electrode in said fifth plurality of electrodes to form an electrode pair such that each electrode in each electrode pair of said third and fifth plurality of electrodes has opposite polarity and is directly opposite across the second intersection point of the other electrode in the electrode pair of said third and fifth plurality of electrodes, and iv) the RF fields generated between said second intersection point and said third plurality of electrodes is in reverse phase to the RF fields generated between said second intersection point and said fifth plurality of electrodes.
In accordance with some aspects, the apparatus can further include a gate electrode disposed at the first axial end of the first pathway for controlling the introduction of said ions, an electrode disposed at said second axial end of the first pathway, said electrode having a DC potential applied thereto of the same polarity as said ions (e.g., so as to repel the introduced ions), a gate electrode disposed at the second axial end of the third pathway for controlling the removal of at least one of said ions and reaction products of said ions, and an electrode disposed at the first axial end of the third pathway, the gate having a DC potential applied thereto of the same polarity as said ions (e.g., so as to repel the ions or reaction products of the ions). In some embodiments, the gate electrode(s) can be switchable between open and closed positions, wherein when in an open position, ions or products of ion reactions are allowed to pass and when in a closed position, the ions or products of ion reactions are not allowed to pass. The controller can also control the amount of time when the gate is open and when the gate is closed. In some embodiments, for example, the gate(s) can be continuously open.
In accordance with various aspects of the present teachings, a method for performing an ion reaction is provided, the method comprising: introducing a plurality of ions into a first pathway extending at least partially along a first central axis and defined by a first plurality of electrodes, the first pathway comprising a first axial end configured to receive ions from an ion source and a second axial end disposed at a distance from the first axial end of the first pathway; transmitting the ions into a second pathway extending along a second central axis and defined by a second plurality of electrodes, said second pathway intersecting the first pathway at a first intersection point, the second central axis being substantially orthogonal to the first central axis; transmitting the ions into a third pathway extending along a third central axis and defined by a third plurality of electrodes, said third pathway intersecting the second pathway at a second intersection point spaced a distance apart from the first intersection point, the third central axis being substantially orthogonal to the second central axis; and, introducing a charged species into the second pathway along the second central axis extending between the first and second intersection points so as to allow the ions transmitted along the second pathway and the charged species to interact.
In various aspects, the method can also include providing a magnetic field parallel to said second central axis, for example, to control the path of electrons along the second pathway. In some aspects, the method can additionally include focusing the charged species with lenses disposed at or proximate one or more axial ends of said second pathway. By way of non-limiting example, electron capture dissociation can be performed by transmitting positively charged precursor ions along the first and second pathways, introducing electrons along the second pathway, and transmitting the precursor ions and/or the reaction products along the third pathway. In various aspects, the third plurality of electrodes can be configured to have RF voltages applied thereto so as to selectively filter the ions to be transmitted out of the ion reaction device (e.g., to a downstream detector or mass analyzer).
These and other features of the applicant's 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 applicant's teachings in any way.
It will be appreciated that for clarity, the following discussion will explicate various aspects of embodiments of the applicant's 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 applicant's 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 applicant's teachings in any manner.
Methods and systems for interacting precursor ions with charged species are provided herein. Whereas conventional ion reaction devices typically require the simultaneous trapping of the precursor ions and reagent ions for a duration sufficient to produce adequate ion reactions (e.g., ECD), the methods and systems described herein can enable the precursor and reagent ions to interact for an increased duration and/or along a substantially longer path length without trapping, thereby increasing efficiency of the ion reaction and/or improving continuous or “flow through” operability and compatibility with conventional CID-based processes. In various aspects, precursor ions, which initially enter the ion reaction device along an injection axis, are transmitted along the injection axis of the reagent species (e.g., charged species, ions, electrons, protons) before exiting the ion reaction apparatus. In some embodiments, continuous or “flow through” ion reactions can be performed so that an optimum duty cycle for ToF measurement is realized. In various aspects, the apparatus comprises first, second, and third pathways, each of which extends at least partially along a central axis, and wherein the second central axis is orthogonal to the first and third central axes. Precursor ions entering the ion reaction device along the first axis can then be introduced into the second pathway as reagent ions are transmitted therethrough, thereby increasing the possibility of ion reactions occurring within the ion reaction device without simultaneous trapping of the species.
With reference now to
Inside the ion reaction cell 100, the precursor ions are transmitted along a first pathway extending along a central axis (A), guided by the RF fields generated by the electrodes surrounding the first pathway and towards a first intersection point 112, upon which the precursor ions continue along the central axis (A) due to their momentum or are deflected to follow a second pathway extending along a second central axis (B) transverse or orthogonal to the first axis (A). As discussed otherwise herein, an electrode can be disposed at the axial end of the first pathway opposite the inlet 102 that can have a DC voltage applied thereto so as to repel (e.g., slow down the ions introduced into the reaction cell 100 along the first pathway). By way of example, if the precursor ions are cations, the electrode can be maintained at a positive DC voltage such that the precursor ions are repelled back toward the intersection point 112. Likewise, a gate electrode at the inlet 102 can be biased positive relative to the electrodes surrounding the central axis (A) of the first pathway such that ions that have already been injected are prevented from being ejected through the inlet 102.
As a result of the above-described forces acting on the precursor ions in the first pathway, precursor ions continuously introduced into the first pathway lose kinetic energy (e.g., through repulsion by the gate/blocking electrodes and interaction with the cooling gas), and are thus introduced (e.g., leak) into the second pathway along the second central axis (A), which is also surrounded by a plurality of electrodes that focus the precursor ions along the second central axis (B). By way of example, the precursor ions can be weakly trapped by the reagent ion beam or cloud that is injected into the second pathway by the charged species source 104 along the second central axis (B) disposed at an axial end of the second pathway. Accordingly, the precursor ions, charged species (and optionally the photons generated by the light source) interact while the precursor ions traverse the second pathway. Depending on the nature of reactants utilized, the interaction can cause a number of phenomenon to occur which result in the formation of product ions, which can then be extracted or ejected from the ion reaction cell 100 together with potentially other unreacted precursor ions through the outlet 108 of the third pathway. For example, at the second intersection point 123, (e.g., the intersection between the second central axis (B) and the third central axis (C) that is orthogonal thereto), the precursor or product ions can enter the third pathway under the influence of an electrode disposed at the axial end of the third pathway opposite the outlet 108. By way of example, the electrode can have a DC voltage applied thereto so as to repel the precursor ions toward the outlet, while a gate electrode at the outlet 108 can be biased relative to the electrodes surrounding the third pathway so as to promote the extraction of the precursor or product ions from the ion reaction cell 100. By way of example, if the precursor and/or product ions are cations, the electrode can be maintained at a positive DC voltage such that the precursor ions are repelled back toward the intersection point 123, while the gate electrode at the outlet 108 can be biased negative relative to the electrodes surrounding the central axis (C) of the third pathway such that ions at the second intersection point 123 tend to move toward the outlet 108. As will be appreciated by a person skilled in the art, the ions extracted from the ion reaction device 100 can then be subjected to further analysis or detection by a downstream element of a mass spectrometry system. Because of the increased path length and/or duration of the precursor ions with the charged species (e.g., electrons, reagent ions) along the second pathway (i.e., along central axis (B)), ions can be continuously introduced and extracted from the outlet 108 of the ion reaction cell 100, without requiring ions to be trapped within the ion reaction device 100. In various aspects, not only does the increased interaction length increase reaction efficiency (i.e., more precursor ions undergo an ion reaction), it should be appreciated that the lack of a trapping step avoids bunching the ions, thereby improving compatibility with conventional CID-based processes and/or relatively high-volume sample sources (e.g., liquid chromatography with relatively high volumetric flow rates).
Generally, the ion source (not shown) is configured to generate precursor ions, which can be received by the ion reaction device 100 for reaction with the charged species generated by the charged species source. It will be appreciated in light of the present teachings that the ion source can be any ion source known in the art or hereafter developed and modified in accordance with the present teachings, including for example, a continuous ion source, a pulsed ion source, an electrospray ionization (ESI) source, an atmospheric pressure chemical ionization (APCI), atmospheric pressure photo-ionization (APPI), direct analysis in real time (DART), desorption electrospray (DESI), 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. By way of non-limiting example, the sample can additionally be subjected to automated or in-line sample preparation including liquid chromatographic separation.
Generally, the precursor ions can be any ion that is positively charged (cations) or negatively charged (anions), and the charged species can be electrons or ions that are either positively or negatively charged and capable of reacting with the precursor ions. By way of example, when the ions are cations and the charged species are electrons, the cations may capture the electrons and undergo electron capture dissociation in which the interaction between ions and charged species results in the formation of product ions, or fragments of the original precursor ions. The stream of species ejected from the ion reaction cell can consist of one or more or a mixture of the precursor ions, the product ions, and in some cases, the charged species. In addition, it will be appreciated by a person skilled in the art that various electron associated fragmentation phenomena can be performed in methods and systems in accordance with the present teaching such as hot ECD, electron ionization dissociation (EID), activated ions ECD (AI-ECD), electron detachment dissociation (EDD), EIEIO, and negative ion ECD. For example, ECD and hot ECD can be implemented when the precursor ions are cations, while EID can be used if the precursor ions are anions, for example. Proton transfer reactions can also be implemented with the appropriate selection of a charged species, as understood by a person skilled in the art in light of the present teachings
When the charged species are electrons, for example, the electron source 104 can be a filament such as a tungsten or thoriated tungsten filament or other electron source such as a Y2O3 cathode. The filament electron source is typically used because it is inexpensive but it is not as robust on oxygen residual gas. Y2O3 cathodes on the other hand are expensive electron sources but are more robust on oxygen so it is useful for de novo sequencing using radical-oxygen reaction. In operation, an electric current of 1 to 3 A is typically applied to heat the electron source, which produces 1 to 10 W heat power. A heat sink system of the electron source can be installed to also keep the temperature of a utilized magnet, if present, lower than its Curie temperature, at which the magnetization of permanent magnet is lost. Other known methods of cooling the magnet can also be utilized.
With specific reference again to
The exemplary apparatus 100 comprises a first plurality of generally L-shaped electrodes 110a-d arranged around the first central axis (A) in a quadrupole type arrangement. While quadrupoles are specifically embodied here, any arrangements of multipoles could also be utilized, including hexapoles, octapoles, etc. In
With reference again to
Like the electrodes 110a-d, the fourth set of electrodes 140a-d can be connected to the RF voltage source and controller, which also serve to provide RF voltages to the electrodes 140a-d to generate an RF field therebetween to guide the ions towards the first central axis (A) (e.g., the midpoint of the quadrupoles). By way of example, each electrode in the fourth set of electrodes 140a-d can have an RF voltage applied thereto such that each electrode in the fourth set of electrodes 140a-d is directly opposite across the first central axis (A) of another electrode of the fourth set of electrodes having the same polarity. That is, as best shown in
As shown in
As noted above, the separation distance between the first set of electrodes 110a,d and the fourth set of electrodes 140a,d forms a small gap therebetween which also represents a portion of the second pathway extending along the second central axis (B). This second pathway provides a path for the transport of a charged species within the ion reaction device 100. As shown in
With reference again to
With reference again to
Like the electrodes 130a-d, the fifth set of electrodes 150a-d can be connected to the RF voltage source and controller, which serve to provide RF voltages to the electrodes 150a-d to generate an RF field therebetween to guide the ions towards the third central axis (C) (e.g., the midpoint of the quadrupoles). By way of example, each electrode in the fifth set of electrodes 150a-d can have an RF voltage applied thereto such that each electrode in the fifth set of electrodes 150a-d is directly opposite across the third central axis (C) of another electrode of the fifth set of electrodes having the same polarity. That is, as best shown in
Thus, as depicted in
With specific reference again to
As shown in
It will also be appreciated that to prevent ions from escaping from the axial ends of the second pathway, a blocking electrode (e.g., a plate electrode 105b) can be provided adjacent the axial ends of the second pathway, the blocking electrode being electrically connected to a suitable voltage source (e.g., a DC voltage source) such that a blocking potential of the same polarity as the ions to be analyzed/reacted can be applied thereto.
With reference now to
As shown in
As shown in
With reference now to
With reference now to
It should be appreciated that the schematically-depicted ion reaction device 1000 can additionally or alternatively include one or more other features described herein. By way of example, the ends of the pathways can comprise electrodes for controlling the axial motion of ions therein. Moreover, as described above with reference to
With reference now to
With reference now to
The ions initially injected along the first pathway are transmitted along the first pathway toward the first intersection point 1212 with the second pathway. Unlike the other ion reaction devices described herein, however, the ions can flow through the device (e.g., without being substantially diverted from the first pathway (e.g., for conventional MS/CID analysis, as shown in
The ions initially injected along the first pathway are transmitted along the first pathway toward the first intersection point 1212 with the second pathway, initially under the influence of the electrodes 1210a-d to which an RF signal is provided to substantially focus the ions along the central axis (A). By way of example, the inverted phase of the signal applied to electrodes 1210a and 1210b (which surround electrode 1260a) maintain the ions substantially along the central axis (A) as they enter the ion reaction device 1200. In a MS/CID mode of operation in which the ions merely flow through the reaction cell 1200 (e.g., without undergoing ECD), a repulsive potential DC potential (e.g., +1V) can also be applied to one or more of the lens electrode 1201, plate electrodes 1205a,b, and electrode 1260a, such that the trajectory of the ions is maintained substantially toward electrodes 1260c,d (maintained at an attractive potential (e.g. −1 V)), and electrode 1203 (maintained at an attractive potential to the ions (e.g., −2V)), as shown in
When it is desired for an ECD reaction to be performed, for example, a controller can activate a charged species source (which as discussed otherwise herein transmits a charged reagent species along the second pathway, as shown in
In various embodiments, electron control optics and ion control optics are completely separated, so independent operations on both charged particles are possible. For electrons, electron energy can be controlled by the potential difference between the electron source and the intersection point between the ion pathway and the charged species pathway. The charged species pathway can be controlled in an ON/OFF fashion by use of a gate electrode. Lens can be positioned at or proximate either axial end of the second pathway and when positively biased, cause the charged species, when such species are electrons, to focus. Ions which are introduced through the other pathway are stable near theses lens since they are biased positively.
It should be appreciated that numerous changes can be made to the disclosed embodiments without departing from the scope of the present teachings. While the foregoing figures and examples refer to specific elements, this is intended to be by way of example and illustration only and not by way of limitation. It should be appreciated by the person skilled in the art that various changes can be made in form and details to the disclosed embodiments without departing from the scope of the teachings encompassed by the appended claims.
This application claims priority to U.S. provisional application No. 62/098,019 filed on Dec. 30, 2014, entitled “Electron Induced Dissociation Devices and Methods,” which is incorporated herein by reference in its entirety and to U.S. provisional application No. 62/106,346 filed on Jan. 22, 2015, entitled “Electron Induced Dissociation Devices and Methods,” which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/059856 | 12/21/2015 | WO | 00 |
Number | Date | Country | |
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62106346 | Jan 2015 | US | |
62098019 | Dec 2014 | US |