1. Field of the Invention
The present invention relates to multi-dimensional liquid chromatography separation systems and methods. More particularly, it relates to those apparatus and methods that may be used to separate complex mixtures of molecules.
2. Prior Art
In a typical two-dimensional liquid chromatography system, the separation of the second dimension is carried out one fraction from the first dimension at a time, in a serial fashion. Although relatively simple to implement, this strategy limits the overall efficiency of the separation system. Even though the intrinsic separation speeds of the two dimensions are comparable, the first dimension separation has to slow down so that the next fraction of the first dimension is produced just when the second dimension separation for the current fraction is done. The number of fractions from the first dimension is often limited to a small number, due to the total time required to separate these fractions by the second dimension. It is thus desirable to have a second dimension separation throughput much higher than the first dimension, but the throughput, even after being optimized for speed, is still quite limited due to this serial separation process.
It is an object of this invention to provide a parallel separation apparatus and process where the total separation time is roughly the sum of that for each dimension rather than the product of respective dimensions.
It is another object of the invention to provide apparatus and methods having an advantage of at least five times the throughput speed for 2D separation, with the advantage becoming much more significant as one moves to higher and higher dimensions.
It is another object of the invention to achieve the improvement in separation speed without the use of too many parallel separation columns in latter dimensions, thus allowing for many more fractions from earlier dimensions to be further separated in latter dimensions cost-effectively.
It is another object of the invention to provide an easy means to add internal standards so that each latter column can be individually calibrated while online along with the detection system.
It is yet another object of the invention to provide a means to concentrate separated components prior to the detection and thus gain in detection sensitivity.
Compared to one-dimensional separation, detection mechanisms with higher sensitivity are desired, because the components being detected are spread over a two-dimensional plane instead of a one-dimensional line.
These objects and others are achieved in accordance with the invention by the use of at least two groups of traps where one group undergoes the next dimension of separation while others are continuously collecting fractions. The use of a novel trap and release scheme prior to the detection system allows for component concentrating and flexible management of trap-release-detection timing among traps and groups of traps. The invention also utilizes online introduction of internal standards through the release solvent. All of these features may be provided in a fully automated mode, resulting in an un-attended analytical system where many processes such as separation, sample handling, component concentrating, calibration, and detection are all occurring simultaneously in order to achieve high throughput.
The foregoing aspects and other features of the present invention are explained in the following description, taken in connection with the accompanying drawings, wherein:
The invention, an improved multi-dimensional liquid chromatography system, has multiple fraction traps to collect fractions from the first dimension. The traps are coupled with an array of second dimensional separation columns. These traps are divided into multiple groups, each group containing the same number of traps as the number of second dimensional separation columns. While one group of traps is in the process of collecting fractions, the other groups undergo the other processes, including the second dimensional separation. Fractions collected in a group of traps are separated by the second dimensional columns simultaneously in a parallel fashion. The processes undergone by the groups rotate until the whole separation task is completed. Because the second dimensional separation is now carried out in parallel, much higher overall separation efficiency can be achieved.
For simplicity and clarity, integrated and on-line two-dimensional systems are first used as examples in the following discussion. Then the ideas/concepts/designs are applied/expanded/extended to systems with a greater number of dimensions.
The detector 31 can be a multi-channel detector capable of monitoring effluent from C1 and C2 simultaneously. Alternatively, separate detectors can be used for C1 and C2.
The styles of traps include a segment of simple hollow tube, packed or open-tubular chromatography columns or solid phase extraction columns.
The rinse pump 25 is optional. The functions of the rinse pump 25 include pushing remaining effluent into the traps, and rinsing the traps before the second dimensional separation.
C1 and C2 can be integrated with the traps and thus can be optional as separate units.
The styles of traps can include packed or open-tubular chromatography or solid phase extraction columns. Other chemical, electrochemical, or physical mechanisms that can lead to desired trap-and-release processes can also be used with trap-and-release detection.
The traps should be installed as close to the detector as possible to minimize zone broadening.
The trap-and-release detection scheme is particularly suitable for multiplexing detectors which scan all the channels but actually only spend a fraction of the total detection time on each individual channel, such as the Micromass (now Waters) mass spectrometers equipped with MUX interface. With proper control, trapped components can be released at such an optimal time that, while one channel is scanned, the enriched zone for this channel reaches the detector, but the enriched zones from the other channels are queued closely behind. Consequently, not only are most of the components enriched and subjected to detection, but also the components of one channel are detected with minimized interference from the other channels, or with minimized cross-talk.
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Flow switching devices with low dead volume, minimum cross talk between channels, ability to handle large number of channels are critical in multidimensional liquid chromatography systems. Two designs with such characteristics are shown, with a first in
Parallel fraction collection can be a very useful in multidimensional liquid chromatography systems for coupling one dimension to the next dimension, parking fractions for further and/or future treatment and analysis.
The use of a parallel fraction collection device, however, allows for these fractions to be analyzed offline later on any mass spectrometer, for example, a mass spectrometer fitted with NanoMate ESI chip made by Advion Biosciences (Ithaca, N.Y.) where each fraction can be mass analyzed through direct introduction into a mass spectrometer without further separation.
Referring to
Analysis system 10 has a sample preparation portion 12, a mass spectrometer portion 14, a data analysis system 16, and a computer system 18. The sample preparation portion 12 may include a sample introduction unit 20, of the type that introduces a sample containing molecules of interest to system 10, such as Finnegan LCQ Deca XP Max, manufactured by Thermo Electron Corporation of Waltham, Mass., USA. The sample preparation portion 12 may also include an analyte separation unit 22, which is used to perform a preliminary separation of analytes, such as the proteins to be analyzed by system 10. Analyte separation unit 22 may contain any of the multidimensional chromatographic separation arrangements of FIGS. 1 to 10.
The mass separation portion 14 may be a conventional mass spectrometer and may be any one available, but is preferably one of MALDI-TOF, quadrupole MS, ion trap MS, or FTICR-MS, or some combinations such as a qTOF or triple-stage quadrupole (TSQ). If it has a MALDI or electrospray ionization ion source, such ion source may also provide for sample input to the mass spectrometer portion 14. In general, mass spectrometer portion 14 may include an ion source 24, a mass spectrum analyzer 26 for separating ions generated by ion source 24 by mass to charge ratio (or simply called mass), an ion detector portion 28 for detecting the ions from mass spectrum analyzer 26, and a vacuum system 30 for maintaining a sufficient vacuum for mass spectrometer portion 14 to operate efficiently. If mass spectrometer portion 14 is an ion mobility spectrometer, generally no vacuum system is needed.
The data analysis system 16 includes a data acquisition portion 32, which may include one or a series of analog to digital converters (not shown) for converting signals from ion detector portion 28 into digital data. This digital data is provided to a real time data processing portion 34, which process the digital data through operations such as summing and/or averaging. A post processing portion 36 may be used to do additional processing of the data from real time data processing portion 34, including library searches, data storage and data reporting.
Computer system 18 provides control of sample preparation portion 12, mass spectrometer portion 14, and data analysis system 16, in the manner described below. Computer system 18 may have a conventional computer monitor 40 to allow for the entry of data on appropriate screen displays, and for the display of the results of the analyses performed. Computer system 18 may be based on any appropriate personal computer, operating for example with a Windows® or UNIX® operating system, or any other appropriate operating system. Computer system 18 will typically have a hard drive 42, on which the operating system and the program for performing the data analysis described below is stored. A drive 44 for accepting a CD or floppy disk is used to load the program in accordance with the invention on to computer system 18. The program for controlling sample preparation portion 12 and mass spectrometer portion 14 will typically be downloaded as firmware for these portions of system 10. Data analysis system 16 may be a program written to implement the processing steps discussed below, in any of several programming languages such as C++, JAVA or Visual Basic.
Although the description above contains many specifics, these should not be construed as limiting the scope of the invention but as merely providing illustrations of some feasible embodiments of this invention. For example, there may be more than two groups with each group including more than two traps, requiring the valves to operate in a multi-state mode instead of a binary mode.
Thus the scope of the invention should be determined by the appended claims and their legal equivalents, rather than by the examples given. Although the present invention has been described with reference to the single embodiment shown in the drawings, it should be understood that the present invention can be embodied in many alternate forms of embodiments. In addition, any suitable size, shape or type of elements or materials could be used.
This application is a divisional of application Ser. No. 11/249,722 filed on Oct. 12, 2005, which claims priority, under 35 U.S.C. §119(e), from provisional patent application Ser. No. 60/618,199 filed on Oct. 12, 2004, both of which are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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60618199 | Oct 2004 | US |
Number | Date | Country | |
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Parent | 11249722 | Oct 2005 | US |
Child | 11760667 | Jun 2007 | US |