1. Field of Invention
The invention relates to devices and methods for performing electrospray from capillary or planar microfluidic systems. The invention further relates to devices and methods for interfacing microfluidic systems with mass spectrometry. The device includes at least a reservoir, an electrode, a microchannel possessing a first end and a second end, and a porous membrane attached to the second end of the microchannel.
2. Background of the Invention
Microfluidic and capillary systems offer the potential for performing liquid-phase biomolecular analyses with increased throughput and sensitivity while significantly reducing cost. Ultimately, high resolution molecular analysis requires the coupling of these systems with mass spectrometry (MS) for accurate mass identification. Electrospray ionization (ESI), which utilizes a strong local electric field to transfer ions from solution to the gas phase in a fine spray at atmospheric pressure, is a commonly used approach for coupling both microfluidic and capillary analytical systems to mass spectroscopy by direct ESI-MS interfacing.
Various approaches to fabricating ESI interfaces into microfluidic systems have been reported. External interfaces have been demonstrated by inserting a capillary spray tip into microchannel exits, or by using a liquid junction to couple the microfluidic device to capillary-based separation systems followed by capillary ESI-MS. Although these techniques have shown excellent electrospray performance, they are not fully integrated with the microfluidic channels and thus suffer from large dead volumes which can lead to broadening of separation bands, and difficulty with fabricating high density electrospray tip arrays. Another method uses the flat surface at the microchannel exit, defined by cutting the substrate to expose the channel opening, to create the electrospray emitter. While straightforward, this approach leads to difficulty in consistently establishing well defined, stable Taylor cones at the microchannel exit due to liquid spreading, even for hydrophobic surfaces such as glass. In addition to increasing Taylor cone volume, liquid spreading at the exit also limits the ability to realize tightly spaced arrays of multiple ESI tips, since crosstalk between adjacent channels poses a significant problem. A further need arises from a desire to achieve stable electrospray when very low bulk fluid flow rates are imposed on the electrospray channel.
Several approaches have been explored to improve the stability of the electrospray process while also reducing exit spreading for integrated microchip ESI devices. For example, shaped spray tips have been fabricated from the bulk substrate material at the channel exit, using silicon (e.g. G. A. Shultz, T. N. Corso, S. J. Prosser, S. Zhang, Anal. Chem. 2000, 72, 4058-4063) and various polymers (e.g. K. Tang, Y. Lin, D. W. Matson, T. Kim, R. D. Smith, Anal. Chem. 2001, 73, 1658-1663). Similarly, the addition of thin parylene tips bonded at the channel exit to form a wicking structure has also been demonstrated (J. Kameoka, R. Orth, B. Ilic, D. Czaplewski, T. Wachs, H. G. Craighead, Anal. Chem. 2002, 74, 5897-5901). In general, shaped tips have been shown to significantly reduce or eliminate liquid spreading and provide very good spray stability, but are relatively difficult to fabricate, requiring additional fabrication steps including mechanical machining of the substrate or the use of additional lithographically-patterned material layers in the microfluidic system.
A simpler method for improving the performance of integrated ESI tips involves increasing the hydrophobicity of the channel exit, either by application of a surface coating, or by using polymer substrates with high native hydrophobicity. The latter approach has been shown to limit liquid spreading and assist in maintaining relatively small Taylor cone volumes, but does not prevent drift in the position of the Taylor cone away from the channel exit (T. C. Rohner, J. S. Rossier, H. H. Girault, Anal. Chem. 2001, 73, 5353-5357). In addition, for the case of thin film hydrophobic coatings, damage to the coating during the electrospray process can occur. For example, using a monolayer of (n-octyl) covalently-attached to the exit surface of a glass microchip, stable electrospray was limited to under 5 min at a flow rate between 100-200 nL/min before the coating was damaged (Q. Xue, F. Foret, Y. M. Dunayevskiy, P. M. Zavracky, N. E. McGruer, B. L. Karger, Anal. Chem. 1997, 69, 426-430). Similarly, CF4 exposure in an RF plasma system has been shown to increase the hydrophobicity of laser-shaped polycarbonate (PC) ESI tips (K. Tang, Y. Lin, D. W. Matson, T. Kim, R. D. Smith, Anal. Chem. 2001, 73, 1658-1663) for reduced liquid spreading and improved ESI stability. However, the longevity of CF4 plasma surface modifications can be limited, and the processing costs are significant. An alternate approach incorporated by reference herein involves the use of a hydrophobic porous membrane bonded to the microchannel exit (Y. Wanǵ, J. Cooper, C. S. Lee, D. L. DeVoe, Lab On A Chip 2004, 4, 263-267).
A further need arises from a desire to interface multiplexed microfluidic systems with mass spectrometry. Despite the potential for ESI-MS analysis from microfluidic systems, there is often a need to decouple on-chip biomolecular separations from MS analysis. For example, the time scales for biomolecular separations and MS data acquisition are often incompatible. Another important demand for off-line analysis arises from the need for coupling multiple parallel (multiplexed) microchannels to mass spectrometry, in which simultaneous ESI-MS from each separation channel is not feasible due to physical constraints. Matrix assisted laser desorption ionization—mass spectrometry (MALDI-MS) and related methods including desorption ionization on silicon—mass spectrometry (DIOS-MS) are powerful analytical techniques commonly employed for off-line MS analysis following capillary separations (e.g. T. Rejtar, P. Hu, P. Juhasz, J. M. Campbell, M. L. Vestal, J. Preisler, B. L. Karger, Journal of Proteome Res. 2002, 1, 171-179). Although it is a serial process, the high duty cycle of MALDI-MS analysis enables high throughput for large numbers of samples deposited on a single target plate. Preparation of MALDI targets is often carried out by the dried-droplet method, in which spotting of an aliquot containing a mixture of sample and matrix solution is followed by air-drying of the deposited spot (M. Karas, F. Hillenkamp, Anal. Chem. 1988, 60, 2299-2301.). The quality of MALDI data is highly dependent on the way analyte is prepared on the target plate. Liquid-phase deposition methods including dried-droplet, fast solvent evaporation, sandwich, and two-layer preparation tend to suffer from poor homogeneity of crystallized sample, since matrix and analyte tend to partition during the solvent evaporation process, resulting in significant variations in mass resolution, intensity, and selectivity, and preventing meaningful quantitative analysis. As an alternative to mechanical pipetting or spotting, a number of studies have investigated the use of electrospray deposition of analytes from single capillaries onto MALDI targets, followed by MALDI-MS analysis. A number of studies have shown that electrospray deposition can markedly improve the homogeneity of sample on the MALDI target surface by reducing segregation of matrix/analyte components, leading to greatly enhanced repeatability (e.g. E. P. Go, Z. Shen, K. Harris, G. Siuzdak, Anal. Chem. 2003, 75, 5475-5479; S. D. Hanton, I. Z. Hyder, J. R. Stets, K. G. Owens, W. R. Blair, C. M. Guttman, A. A. Giuseppetti, J. Am. Soc. Mass Spectrom. 2004, 15, 168-179), thereby enabling improved quantitative analysis. Furthermore, electrospray deposition has been shown to significantly improve the precision of molecular mass measurements during MALDI-MS. There is a need to bring these benefits to microfluidic analytical systems, in particular for microfluidic systems containing two or more microchannels from which parallel analyses are desired. This concept is described by Wang et al. (Y. Wang, Y. Zhou, B. Balgley, J. Cooper, C. S. Lee, D. L. DeVoe, Electrophoresis 2005, 26, 3631-3640) and is incorporated by reference herein.
The present invention fulfills these and other needs.
In one aspect of the present invention, stable electrospray from the flat edge of a microfluidic chip is enabled through the addition of a porous hydrophobic membrane to the channel exit surface. The porous membrane provides a controllable and repeatable hydrophobic surface to constrain lateral dispersion of liquid from the tip exit. The base of the resulting Taylor cone formed during electrospray is thus constrained to remain positioned at the channel exit.
In another aspect of the invention, multiple electrospray tips may be formed in a single microfluidic substrate, with one or more microchannels used to deliver liquid to each of the tips. By using a hydrophobic porous polymer to constrain lateral dispersion of liquid at the exposed face of the membrane, spacing between adjacent tips may be as small as the diameter of the Taylor cones formed during the electrospray process, enabling dense arrays of electrospray tips to be formed with negligible contamination of analyte molecules between the tips.
In another aspect of the invention, an interface is provided between multiplexed microchannels and mass spectrometry through the simultaneous deposition of analyte molecules from a multiple channels within a microfluidic substrate onto a MALDI target by electrospray.
According to another aspect, the porous membrane can be made from a conductive material, such that the voltage required for electrospray can be delivered directly to the membrane rather than through liquid within the electrospray microchannel.
In another aspect, the porous exit surface of the membrane serves as a dense array of nanoscale electrospray tips, enabling the generation of stable electrospray at low bulk fluid flow rates.
According to another aspect, the highly porous membrane reduces the pressure required to achieve sufficient liquid flow for stable electrospray when compared to pulled-silica nanospray tips.
According to another aspect, the porous membrane reduces the pressure required to achieve sufficient liquid flow for stable electrospray when compared to pulled-silica nanospray tips.
Another aspect of the invention is the ability to selectively bind molecules to the membrane surface, for example through hydrophobic-hydrophobic interactions, thereby enabling controlled interactions between the bound molecules and analyte molecules passing through the membrane during the electrospray process. The high surface area of the membrane may serve to enhance the kinetics of the molecular interactions. For example, a proteolytic enzyme such as trypsin may be bound to the membrane through hydrophobic interactions, and used to digest proteins passing through the membrane in real-time, while electrospraying the resulting protein digest. Other molecular species chosen to interact with the analyte may similarly be bound to the membrane. For example, a phosphotase may be bound to the membrane to enable the removal of phosphorylated groups from analyte proteins during electrospray.
These and other features and advantages of the invention will be more fully appreciated from the detailed description of the preferred embodiments and the drawings attached hereto. It is also to be understood that both the foregoing general description and the following detailed description are exemplary and not restrictive of the scope of the invention.
I. Apparatus
A preferred embodiment of the apparatus is depicted in
The microchannels may be fabricated from a number of different materials, including glass, silica, or plastic. The use of the term “microchannel” in the present invention is not intended to limit the invention to planar microfluidic systems, but rather is used to refer to any fluid-carrying channel including but not limited to silica or plastic capillary tubing. The microchannels need not be circular in cross-section. For example, the channels may be ellipsoidal, rectangular, or trapezoidal in cross-section, depending on the method used for their fabrication. Microchannels possessing inner diameters on the order of 10 μm to 100 μm may be desirable for applications involving small sample volumes, but larger or smaller inner diameters may also be used depending on the application.
According to another embodiment, depicted in
According to one embodiment of the invention, as depicted in
In the various embodiments described herein, the porous membrane may be fabricated from a wide range of suitable materials. Either hydrophobic and hydrophilic materials may be desirable, depending on the application. According to a preferred embodiment, the porous membrane is fabricated from a hydrophobic material such as polytetrafluoroethylene (PTFE) or hydrophobic polyvinylidene fluoride (PVDF). Hydrophobic materials tend to prevent the wicking of aqueous solutions, thereby serving to constrain the lateral spreading of fluid at the exit surface during the electrospray process. Hydrophobic membrane materials also provide the benefit of enabling the bonding of many biomolecules such as peptides and proteins to the membrane surface by hydrophobic-hydrophobic interactions. Hydrophilic materials, such as polyethersulfone or hydrophilic polyvinylidene fluoride (PVDF), may be used to reduce the binding of hydrophobic molecules passing through the membrane. Non-polymer materials such as porous silica which offer high structural rigidity and strength may also be desirable to facilitate easier bonding to the microchannel substrate. In general, it is preferable to use materials which remain electrically, mechanically, and chemically stable when exposed to high temperatures and high electric fields. It may be preferable to use a membrane with a thickness between 5-100 microns, an average pore size between 0.1-1.0 microns, and a porosity of 85% or greater.
The substrate may be fabricated from glass, silicon, plastic, or other material as commonly employed in microchannel manufacturing. According to a preferred embodiment, the substrate is fabricated from a polymer material with a glass transition temperature substantially lower than the thermal deformation temperature of the porous membrane material. For example, if the porous membrane is fabricated from a PTFE formulation possessing a glass transition temperature over 200° C., the microfluidic substrate may be fabricated from polymethylmethacrylate (PMMA), polycarbonate (PC), or cyclic olefin polymer materials with glass transition temperatures under 150° C. The lower glass transition temperature ensures that the porous membrane may be thermally bonded to the microfluidic substrate without significantly deforming the membrane pores during the bonding process.
Specific molecules may be bound to the membrane surface, for example through hydrophobic-hydrophobic interactions or by binding to functional chemical groups on the membrane surface, thereby enabling controlled interactions between the bound molecules and analyte molecules passing through the membrane during the electrospray process. For example, a proteolytic enzyme such as trypsin may be bound to the membrane through hydrophobic interactions, and used to partially or fully digest proteins passing through the membrane in real-time while electrospraying the resulting protein digest. Furthermore, multiple molecular species with desired functionality may be bound to a single membrane. For example, a phosphotase with activity towards phosphorylated residues may be combined with a serine protease such as trypsin which cleaves lysine and arginine residues.
The apparatus may be useful for performing electrospray ionization, wherein fully desolvated ions are expelled from the electrospray tip. Alternately, the invention may be used for electrospray deposition, wherein the distance between the electrospray tip and target is sufficiently small to prevent complete desolvation of the sample stream exiting the electrospray apparatus before the sample molecules impinge upon the target. The use of electrospray deposition without fully desolvating the analyte may be desirable for certain applications. For example, incomplete desolvation may be desirable when depositing analyte onto a target for MALDI-MS analysis, since the residual solvent may enhance the ability for deposited molecules to interact effectively with a pre-deposited matrix solution for proper crystallization.
According to another embodiment of the invention, as depicted in
According to another aspect of the invention, depicted in
II. Methods
In one aspect of the invention, a method is provided for binding selected species of molecules to the electrospray membrane prior to performing electrospray of analyte molecules. Referring to
In another aspect, the invention includes a method for performing electrospray of analyte molecules from the exposed membrane surface. Referring to
In another aspect, a method for coupling electrospray with molecular separations is provided. Referring to
In another aspect, a method for depositing analyte molecules onto a MALDI target is provided. Referring to
This application claims priority from U.S. Provisional Patent Application Ser. No. 60/616,525, filed Oct. 7, 2004, which is incorporated herein by reference in its entirety.
This invention was made in part with government support under Grants No. R43 EB000453 and GM62738 from the National Institutes of Health, and Contract No. W911SR-04-C-0014 from the U.S. Army. Accordingly, the U.S. government may have certain rights to this invention.
Number | Date | Country | |
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60616525 | Oct 2004 | US |