Patent Grant
7220345
The present invention relates generally to a microfluidic system, and more particularly to a microfluidic system having an externally controllable nanofluidic interconnect.
Microfluidic devices are devices for controlling fluid flow having dimensions less than about one millimeter. These devices are becoming increasingly important in chemical and biochemical sensing, molecular separations, drug delivery and other emerging technologies. New microfluidic devices and methods for rapidly constructing these devices are being developed. However, most prior art devices are two-dimensional. To produce three-dimensional microfluidic devices, interconnects between two-dimensional structures often are made. However, creation of these interconnects has proved challenging. Many prior three-dimensional microfluidic devices use discrete channels to bridge, rather than connect, independent analysis modules. In other words, the channels passively connect the modules and do not have gates or valves for selectively permitting and preventing flow from one module to the next. Although a pressure activated valve has been developed, this interconnect has limited usefulness because it depends on a variation in pressure of the fluid for opening and closing the valve. Thus, there is a need for an externally controllable active interconnect to exploit the full three-dimensional capacity of microfluidic devices.
Briefly, the present invention includes a fluid circuit comprising a membrane having a first side, a second side opposite the first side, and a pore extending from the first side to the second side. The fluid circuit also includes a first channel containing fluid extending along the first side of the membrane and a second channel containing fluid extending along the second side of the membrane and crossing the first channel. Further, the circuit comprises an electrical source in electrical communication with at least one of the first fluid and second fluid for selectively developing an electrical potential between fluid in the first channel and fluid in the second channel thereby causing at least one component of fluid to pass through the pore in the membrane from one of the channels to the other.
In another aspect, the invention includes a fluid circuit comprising a membrane having a pore having a width less than about 250 nanometers, a first channel containing fluid extending along the first side of the membrane, and a second channel containing fluid extending along the second side of the membrane.
In yet another aspect, the invention includes a circuit comprising a membrane, a first channel containing a first fluid having a first Debye length in fluid communication with the first side of the membrane, and a second channel containing a second fluid having a second Debye length at least as long as the first Debye length in fluid communication with the second side of the membrane. The pore in the membrane has a width between about 0.01 and about 1000 times the first Debye length.
Apparatus of the present invention for constructing a fluid circuit comprises a membrane, a first channel for containing fluid in fluid communication with a first side of the membrane, and a second channel for containing fluid in fluid communication with the second side of the membrane. Further, the apparatus includes an electrical source in electrical communication with at least one of the first channel and the second channel for selectively developing an electrical potential between fluid in the first channel and fluid in the second channel thereby causing at least one component of fluid to pass through the pore in the membrane from one channel to the other.
A method of the present invention for isolating a particle having a selected electrophoretic velocity from a plurality of particles using the apparatus described above comprises filling the first channel with a fluid, positioning the plurality of particles in the fluid at a first end of the first channel, and developing an electrical potential between the first end of the first channel and a second end of the first channel opposite the first end so the plurality of particles migrate along the first channel from the first end to the second end in an order corresponding to their respective electrophoretic velocities. An electrical potential is developed between the first channel and the second channel when the particle having the selected electrophoretic velocity is adjacent the pore in the membrane so the particle passes through the pore from the first channel to the second channel.
In another method of the present invention, at least one component of fluid is transferred from a first channel to a second channel. Fluid is delivered to the first channel extending along a first side of a membrane and to the second channel extending along a second side of the membrane. An electrical potential is developed between the fluid in the first channel and the fluid in the second channel thereby causing at least one component of fluid to pass through the pore in the membrane.
In yet another method of the present invention, a selected component within a fluid comprising a plurality of components is tagged. A chemical reagent is passed through the pore so the reagent coats a surface of the pore. The pore is flushed to remove the reagent from a central portion of the pore so at least a portion of the reagent coating remains on the surface of the pores. At least one component of the fluid is passed through the pore so the selected component contacts the reagent.
Another apparatus of the present invention comprises a plurality of membranes, each having a first side, a second side opposite the first side, and a pore extending from the first side to the second side. The apparatus also includes a plurality of pairs of channels, each including a first channel adjacent at least one of the first sides of the membranes for containing fluid in fluid communication with the first side of the respective membrane and a second channel adjacent at least one of the second sides of the membranes for containing fluid in fluid communication with the second side of the respective membrane. In addition, the apparatus includes an electrical source in electrical communication with at least one of the channels for selectively developing an electrical potential between fluid in at least two of the channels thereby causing at least one component of fluid to pass through the pore in at least one of said membranes.
Other features of the present invention will be in part apparent and in part pointed out hereinafter.
a–5c are schematic cross sections of the apparatus illustrating a steps of a method of the present invention;
a–6d are fluorescence signature graphs for various experimental transfers;
a–7c are fluorescence signature graphs for various experimental transfers;
a is a perspective showing a fluid circuit formed by the second apparatus; and
b is a schematic showing an array of fluid circuits formed from an expansion of the second apparatus.
Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.
Referring now to the drawings and in particular to
As illustrated in
As illustrated in
As will be appreciated by those skilled in the art, an interior surface 60 defining each pore 42 may be coated with a coating 62 as illustrated in
As will be appreciated by those skilled in the art, the separations capacity factor, which is governed by the surface-to-volume ratio, can be quite large. For example, the separations capacity factor increases by about 120 times when a pore 42 having a width of about 200 nm is coated with a reagent having a thickness 64 of about 10 nm compared to a pore having a width of about 20 um coated with the same coating.
Although in one embodiment the fluid in the first and second channels 28, 30 have identical chemistries, the fluid in each channel may have different chemistries without departing from the scope of the present invention. As will be appreciated by those skilled in the art, each of the fluids contained by the channels 28, 30 has a Debye length which is a measure of the distance at which the Coulomb field of the charged particles in a plasma cease to interact. The properties of the flow through the pores 42 is affected by the relationship between the width 44 of the pores and the Debye length of the fluid in the channels 28, 30. In one embodiment, the first channel 28 is filled with a first fluid having a first Debye length and the second channel 30 is filled with a second fluid having a second Debye length at least as long as the first Debye length. Further, the pore 42 has a width 44 between about 0.01 and about 1000 times the first Debye length. If the pores have a small width (closer to 0.01 times the first Debye length), then flow in the pores is dominated by electroosmosis, whereas if the pores have a large width (greater than 1 first Debye length), then ion migration dominates the flow in the pores.
The previously described apparatus 20 can be used to selectively transfer one or more components of fluid from the first channel 28 to the second channel 30 as illustrated in
In addition, the apparatus 20 may be used to tag a selected component within a fluid. A chemical reagent (e.g., an antibody) is passed through the pore 42 so the reagent coats the interior surface 60 of the pore. Alternatively a sequence of chemical reagents can be passed through the pore 42 so that a multilayer structure is built up to coat the interior surface 60 of the pore. The pore 42 is flushed to remove the reagent from a central portion of the pore so the reagent coats the surface 60 of the pore. The fluid component to be tagged is drawn through the pore 42 using a method such as described above so the selected component contacts the reagent coating 62, and a tagging reaction results between the selected component and the immobilized chemical reagent. Although it is envisioned other methods may be used to attract the selected component to the pore in one embodiment, the electrical potential between the fluid in channel 28 and the fluid in channel 30 draws the selected component through the pores. It is further envisioned that the membrane 22 may be selected so the pore 42 has a width 44 equal to between about 0.5 and about 100 times the Debye length of the fluid plus between about 1 and about 1000 times a width of the selected component.
The previously described apparatus 20 also may be used to isolate a particle having a selected electrophoretic velocity from a plurality of particles. As illustrated in
As will be understood by those skilled in the art, fluidic communication can be established among any number of vertically stacked bodies and each body can be adapted to perform a specialized fluid handling, separation or sensing task. Interconnects as described above can be used to provide controllable transport of components between bodies. It is further envisioned that such systems could be used to perform complex sequences and arrays of fluidic manipulations as will be explained in further detail below.
Using nanofluidic structures to connect microfluidic channels allows a variety of flow control concepts to be implemented, leading to hybrid fluidic architectures of considerable power and versatility. The key characteristic feature of nanofluidic channels is that fluid flow occurs in structures of the same size as physical parameters that govern the flow. For example, the Debye length which characterizes the length scale of ionic interactions in solution spans the range between about 1 nm and about 50 nm when the ionic strength of the buffer solution lies in the high-to-low mM range. Because the solution Debye length is of the order of the channel dimensions in the nanopores, fluidic transfer may be controlled through applied bias, polarity and density of the immobile nanopore surface charge, and the impedance of the nanopore relative to the microfluidic channels. Transfer between microchannels may be operated to produce either two or three stable transfer rates, illustrating the digital character of the fluidic transfer. Furthermore, the separations capacity factor governed by the surface-to-volume ratio, can be quite large. For example, the separations capacity factor is about 120 times larger for a pore having a width of about 200 nm and a coating thickness of about 10 nm compared to a pore having a width of about 20 um and the same coating.
Because gateable transfer of selected solution components between vertically separated microfluidic channels opens the way to multilevel fluidic systems, the potential applications of this technology are far reaching. As one example, the presence of high salt concentrations degrades electrophoretic separations. With this technology, one can pre-separate analytes from high-salt biological fluids, collect and concentrate particular fractions of the separation into a different layer now under optimum conditions for a high resolution second-dimensional separation. Because the manipulations are displaced vertically one could readily imagine multi-dimensional separations, not limited by the two in-plane spatial directions. One can even envision placing derivatizing chemistry or immunochemical reagents in a particular channel layer and allow chemical reactions to take place on a selected analyte band. Given the large variety of single layer devices already optimized to perform cellular manipulations, chemical reactions and complex separations, the ability to combine these individual architectures into independent layers with external control of the transfer of individually selectable analytes between layers, will enable many applications.
As will be appreciated by those skilled in the art, the direction of particle travel in the apparatus 20 can be controlled by applied potential, surface charge density (pH controllable), ionic strength, and even by the impedance of the fluidic network in which the interconnect is placed relative to the impedance of the membrane 42.
The present invention has been demonstrated through the following examples:
The simple system described above was formed as a proof of concept. Microfluidic channels were formed in bodies of polydimethylsiloxane (PDMS) using standard rapid prototyping protocols for PDMS as explained in J. C. McDonald, et al., Electrophoresis 21, 27–40 (2000). A 5 um thick nanoporous membrane was sandwiched between the bodies. Assembly has been accomplished by centering a 10 mm×1 mm section of membrane on the lower body and placing the upper body on the membrane so its channel was perpendicular to the channel in the lower body.
More sophisticated embodiments of the hybrid microfluidic and nanofluidic system, such as a seven layer sandwiched structure, may be made using the following protocol:
(1) Etch microchannels and holes in a glass substrate.
(2) Mount a polycarbonate nanopore membrane having desired pore diameters on a carrier, such as a PDMS slab about 2 mm thick, without wrinkling or deforming and sufficiently to hold the membrane in place for subsequent handling, but not so tightly as to permanently bond the membrane to the carrier.
(3) Apply adhesive type B (as described below) to the substrate with imprinting, spraying, or screening techniques.
(4) Align the membrane and carrier to the etched glass substrate and tack them in place.
(5) Release the carrier from the membrane leaving it on the substrate to form a layered stack.
(6) Repeat step (2) to a solid polycarbonate membrane layer.
(7) Using conventional shadow mask, etch a desired pattern of channels and holes into the solid membrane using reactive oxygen ion etching, or similar etching techniques for polymers.
(8) Apply adhesive type H (as described below) to the solid membrane, with imprinting, spraying or screening techniques.
(9) Align the patterned solid membrane with the stack and tack the membrane in place.
(10) Repeat step (2) to the second nanopore PC membrane
(11) With shadow mask, etch desired holes and/or channels into membrane.
(12) Apply adhesive type H to the substrate.
(13) Repeat steps (4) & (5).
(14) Repeat steps (6) to (9) for a second solid PC membrane.
(15) Repeat steps (10) to (13) for a third nanopore PC membrane.
(16) Apply adhesive type B to a top glass layer having desired etched holes and channels.
(17) Apply pressure to the entire stack and heat to thermally cure and activate the adhesives, without degrading the polycarbonate.
A separated view of the resulting apparatus made by this protocol is shown in
One of the keys to achieving the desired bond is to use adhesives that can be dried of solvents after application, and that can be thermally cured without evolving sufficient vapors that produce undesired bubbles in the bond. For the glass/polycarbonate combination, adhesive B is a phenolic-based adhesive that is soluble in various non-aqueous solvents, such as ethanol. For the polycarbonate/polycarbonate combination, adhesive H is a low molecular weight polycarbonate dissolved in solution. For both adhesives, the adhesives are diluted to a low concentration, so that the bond thickness on cure is 1 to 2 micrometers thick. If too thick of an adhesive layer is applied, the adhesive on curing can reflow back into the microfluidic channels and potentially plug the channels and nanopores. The bonds are then created by applying pressure and heat, typically over 100 psi and under 150° C. The process steps are still under development to determine the optimum bond cycles.
The crossed microfluidic channels spatially define the transport region and eliminate the need for precise alignment of the nanofluidic membrane. Transport control was monitored with fluorescence spectroscopy and imaging of fluid streams containing small molecule fluorophores by interrogating the fluorescence signal on either the originating or the receiving channel side of the nanofluidic membrane.
In all of the above experiments the direction of transfer was controlled by the electroosmotic flow generated by the microfluidic channels. PDMS exhibits a negative surface charge at pH=8, so forward bias is expected when Vrec−Vsource<0, as observed. Interestingly, this is directly opposite to the flow direction based on the electroosmotic flow characteristics of the PCTE membrane alone. The surfaces of the PCTE membrane channels are coated with polyvinylpyrrolidone (PVP) to render them hydrophilic. The tertiary amine of the PVP is susceptible to protonation, making the surface net positive at pH 8, thus recruiting a population of negative solution counterions to the interior of the nanochannels. Under the low ionic strength conditions used here, the ionic population in the channel is predominantly H2PO4−/HPO42−, so forward bias is obtained with Vrec−Vsource>0, if the nanofluidic channels control the direction of transport. Instead, flow in the direction predicated on the (negative) charge state of the PDMS surfaces of the microfluidic channels controls transport.
This control can be reversed, as shown in
These control concepts have been used to effect preparative separations on the microscale by incorporating them into a microfabricated capillary electrophoresis arrangement with a molecular gate membrane placed between two channel layers just before the detection region. When the gate is off, the system acts as a standard electrophoresis system; when the gate is forward biased, the analyte is collected in the vertically displaced receiving channel, and the signal is reduced or eliminated at the detection region.
Among the advantages of the apparatus 20 of the present invention is the ability to selectively control flow by controlling the potential applied across the pores 42. Flow through the pores 42 can be started and stopped nearly instantaneously. Systems can be created in which the flow is normally on or off until a potential is applied between the fluids in the two channels. Further, direction of flow through the pores 42 can be instantaneously reversed. Still further, the apparatus 20 allows certain species to be selectively transported or blocked from passage through pores 42 and selected pores within the apparatus 20 can be controlled using the fluids themselves as the signal path.
Surface charge density is a critical property influencing electrokinetic flow in these structures, because the enhanced surface-to-volume ratio in these nanofluidic channels means that a significant fraction of the total charge is bound to the walls and is immobile. Because it determines the magnitude of the surface potential and the applicability of the Debye-Hückel approximation, surface charge density provides an experimental handle to adjust the microscopic processes that determine transport in the nanopore. Thus, the potential for facile control of nanofluidic flow by varying the bias, nanochannel wall charge density, charge polarity, and/or solution ionic strength offers the opportunity to effect intelligent transfer of fluid components with extreme ease and versatility.
When introducing elements of the present invention or the preferred embodiment(s) thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
This application claims priority from U.S. Provisional Patent Application No. 60/330,417 filed Oct. 18, 2001, which is hereby incorporated by reference.
This invention was made with government support under grants from the U.S. Department of Energy (DE FG02 88ER13949 and DE FG02 99ER62797), the U.S. Defense Advanced Research Projects Agency (F30602-00-2-0567) and the National Cancer Institute (CA82081). The U.S. government has certain rights in this invention.
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