DESCRIPTION MICROFLUIDIC APERTURE MIXERS
This application claims priority to two commonly assigned U.S. Patent Applications, Serial No. 10/046,071 , filed January 11 , 2002 and Serial No. 10/138,959, filed May 3, 2002. The present invention relates to manipulation, and more particularly, mixing, of fluids in microfluidic systems.
There has been a growing interest in the application of microfluidic systems to a variety of technical areas, including such diverse fields as biochemical analysis, medical diagnostics, chemical synthesis, and environmental monitoring. For example, use of microfluidic systems for acquiring chemical and biological information presents certain advantages. In particular, microfluidic systems permit complicated biochemical reactions and processes to be carried out using very small volumes of fluid. In addition to minimizing sample volume, microfluidic systems increase the response time of reactions and reduce reagent consumption. Furthermore, when conducted in microfluidic volumes, a large number of complicated biochemical reactions and/or processes may be carried out in a small area, such as in a single integrated device. Examples of desirable applications for microfluidic technology include analytical chemistry; chemical and biological synthesis, DNA amplification; and screening of chemical and biological agents for activity, among others. Traditional methods for constructing microfluidic devices have used surface micromachining techniques borrowed from the silicon fabrication industry. According to these techniques, microfluidic devices have been constructed in a planar fashion, typically covered with a glass or other cover material to enclose fluid channels. Representative devices are described, for example, in some early work by Manz, ef al. (Trends in Anal. Chem. (1990) 10(5): 144-149; Advances in Chromatography (1993) 33: 1 -66). These publications describe microfluidic devices constructed using photolithography to pattern channels on silicon or glass substrates, followed by application of surface etching techniques to remove material from a substrate to form channels. Thereafter, a cover plate is typically to the top of an etched substrate to enclose the channels and contain a flowing fluid. More recently, a number of methods have been developed that allow microfluidic devices to be constructed from plastic, silicone or other polymeric materials. Fabrication methods include micromolding of plastics or silicone using surface-etched silicon as the mold material (see, e.g., Duffy etal., Anal. Chem. (1998) 70: 4974-4984; McCormick etal., Anal. Chem. (1997) 69: 2626-2630); injection-molding; and micromolding using a LIGA technique (see, e.g., Schomburg etal., Journal of Micromechanical Microengineering (1994) 4: 186-191), as developed at the Karolsruhe Nuclear Research Center in Germany and
commercialized by MicroParts (Dortmund, Germany). LIGA and hot-embossing techniques have also been demonstrated by Jenoptik (Jena, Germany). Imprinting methods in polymethylmethacrylate (PMMA) have also been described (see, e.g., Martynova etal., Anal. Chem. (1997) 69: 4783-4789). These various techniques are typically used to fashion planar (i.e., two dimensional, or 2-D) structures that require some sort of cover to enclose microfluidic channels. Additionally, these techniques do not lend themselves to rapid prototyping and manufacturing flexibility. Moreover, the tool-up costs for such techniques are often quite high and can be cost-prohibitive
A more recent method for constructing microfluidic devices uses a KrF laser to perform bulk laser ablation in fluorocarbons that have been compounded with carbon black to cause the fluorocarbon to be absorptive of the KrF laser (see, e.g., McNeely etal., "Hydrophobic Microfluidics," SPIE Microfluidic Devices & Systems IV, Vol. 3877 (1999)). This method is reported to reduce prototyping time; however, the addition of carbon black renders the material optically impure and presents potential chemical compatibility issues. Additionally, the reference is directed only to planar structures.
When working with fluids in conventional macroscopic volumes, achieving effective mixing between two or more fluid streams is a relatively straightforward task. Various conventional strategies may be employed to induce turbulent regions that cause fluid streams to mix rapidly. For example, active stirring or mixing elements (e.g., mechanically or magnetically driven) may be employed. Alternatively, special geometries may be employed in flow channels to promote mixing without the use of moving elements. One common example of the use of special geometries includes the addition of baffles to deflect flowing fluid streams and thereby promote turbulence.
Applying conventional mixing strategies to microfluidic volumes is generally ineffective, impractical, or both. To begin with, microfluidic systems are characterized by extremely high surface-to-volume ratios and correspondingly low Reynolds numbers (less than 2000) for most achievable fluid flow rates. At such low Reynolds numbers, fluid flow within most microfluidic systems is squarely within the laminar regime, and mixing between fluid streams is motivated primarily by the phenomenon of diffusion - typically a relatively slow process. In the laminar regime, using conventional geometric modifications such as baffles is generally ineffective for promoting mixing. Moreover, the task of integrating moveable stirring elements and/or their drive means in microfluidic devices would be prohibitively difficult using conventional methods due to volumetric and/or cost constraints, in addition to concerns regarding their complexity and reliability. In light of these limitations, it would be desirable to provide a microfluidic mixer that could rapidly mix fluid streams without moving parts, in a minimal space, and at a very low construction cost. An ideal fluid mixer
would further be characterized by minimal dead volume to facilitate mixing of extremely small fluid volumes.
Passive microfluidic mixing devices have been constructed in substantially planar microfluidic systems where the fluids are allowed to mix through diffusion (e.g., Bokenkamp, et al., Analytical Chemistry (1998) 70( 2): 232-236. In these systems, fluid mixing occurs at the interface of the fluids, which is commonly small relative to the overall volume of the fluids. Thus, mixing occurs in such devices very slowly.
Another passive microfluidic mixer has been proposed by Erbacher and Manz in WIPO International Application Number PCT/EP96/02425 (Publication Number WO 97/00125), published January 3, 1997. There, a flow cell for mixing of at least two flowable substances includes multiple fluid distribution troughs (one for each substance) leading to a fan-like converging planar flow bed, all disposed between fluid inlets and an outlet. One limitation of the disclosed mixing apparatus is that its components (e.g., supply channels, distribution troughs, and flow bed) are fabricated by conventional surface micromachining techniques such as those used for structuring semiconductor materials and lithographic- galvanic LIGA process, with their attendant drawbacks mentioned above. A further limitation of the disclosed mixing apparatus are that its components consume a relatively large volume, thus limiting the ability to place many such mixers on a single device and providing a large potential dead volume. A so-called "microlaminar mixer" is provided in U.S. Patent 6,264,900 to Schubert, et al. There, an improved nozzle includes a microfabricated guide that supplies multiple distinct fluid layers to an external collecting tank or chamber. Various reactive fluid streams are kept spatially separated until they emerge from the guide, specifically to prevent the starting components from coming into contact with one another within the device. One limitation of the disclosed nozzle-type system is that its "guide" element is fabricated with conventional surface micromachining techniques. A further limitation of this nozzle-type system is that it would be highly impractical, if not impossible, to integrate its elements into a single microfluidic device for further manipulation of the resulting fluid following the mixing step. U.S. Patent No. 5,595,712 to Harbster et al. ("Harbster") discloses an integral laminated apparatus for mixing and reacting chemicals. A plurality of laminae - typically silicon (or glass or ceramic) wafers - are surface micro-machined to form horizontal channels or trenches in the top and/or bottom surfaces of the laminae that cooperate to form an array of mixers, each of which comprises a plurality of intersecting channels. The channels intersect with other channels in a shearing fashion at a predetermined angle of attack. Specifically, each turning section includes channel walls that are "beveled from the
vertical at a 57 degree angle." This is implemented by etching crystalline materials along beveling faceting planes, something that can only be achieved with crystalline materials such as silicon.
Knight et al. describe mixers comprising of channels etched in a silicon chip that include a nozzle. Knight et al., "Hydrodynamic Focusing on a Silicon chip: Mixing Nanoliters in Microseconds," Physical Review Letters, 80: 17, 27 April 1998, 3863-3866 ("Knight"). The nozzle acts to focus the flow, enhancing and accelerating mixing of two fluid streams in the channel. Both Harbster and Knight require the use of surface micro-machining or etching techniques with their attendant drawbacks mentioned above. Alternative mixing methods have been developed based on electrokinetic flow.
Devices utilizing such methods are complicated, requiring electrical contacts within the system. Additionally these systems only work with charged fluids, or fluids containing electrolytes. Finally, these systems require voltages that are sufficiently high to cause electrolysis of water, thus causing problems with bubble formation is a problem and collecting samples without destroying them.
In light of the limitations of conventional microfluidic mixers, there exists a need for robust mixers capable of rapidly and thoroughly mixing a wide variety of fluids within a minimal volume in a microfluidic environment. Such mixer designs would preferably be amenable to rapid, low cost fabrication in both low and high volumes, would be suitable for prototyping and large-scale manufacturing, and would permit further processing of fluids downstream of any mixing region(s).
In the following, preferred embodiments are discussed referring to the drawings:
FIG. 1 A is a top view photograph of a microfluidic device with traced channel borderlines according to a first prior art design that promotes interfacial contact between two side-by-side fluids in a straight channel, wherein only minimal mixing occurs between the two fluids before the aggregate is split into two separate streams. FIG. 1 B is a top view photograph of a microfluidic device with traced channel borderlines according to a second prior art design that promotes interfacial contact between two side-by-side fluids in a channel with several turns, wherein incomplete mixing occurs between the two fluids before the aggregate is split into two separate streams.
FIG. 2A is an exploded perspective view of a microfluidic mixing device constructed in five layers and capable of mixing two fluids, the device having two through-layer contraction / expansion regions disposed in-line with straight inlet and outlet channels. FIG. 2B is a top view of the assembled device of FIG.2A. FIG. 2C is a top view photograph of the microfluidic mixing device of FIGS. 2A-2B with trace channel borderlines, showing the
mixing pattern for mixing between two fluids at an aggregate flow rate of about 20 microliters per minute. FIG. 2D provides the same view as FIG. 2C, but shows the mixing pattern for mixing between the two fluids at an aggregate flow rate of about 400 microliters per minute. FIG. 3A is an exploded perspective view of a microfluidic mixing device constructed in five layers and capable of mixing two fluids, the device having ten through-layer contraction / expansion regions disposed in-line with straight inlet and outlet channels. FIG. 3B is a top view of the assembled device of FIG. 3A. FIGS 3C-3E are a top view photograph of the microfluidic mixing device of FIGS 2A-2B with traced channel borderlines, showing the mixing pattern for mixing between fluids at three different aggregate flow rates: 20, 200, and 400 microliters per minute, respectively.
FIG. 4A is an exploded perspective view of a microfluidic mixing device constructed in eleven layers and capable of mixing two fluids, the device having four stacked through- layer contraction / expansion regions with two flow reversals, the stacked regions disposed in line with straight inlet and outlet channels. FIG 4B is a top view of the assembled device of FIG.4A.
FIG. 5A is an exploded perspective view of a microfluidic mixing device constructed in five layers and capable of mixing two fluids, the device having eighteen through-layer contraction / expansion regions and sixteen 90-degree bends. FIG. 5B is a top view of the assembled device of FIG. 5A. FIGS. 5C-5E are top view photographs of the microfluidic mixing device of FIGS. 5A-5B with traced channel borderlines, showing the mixing pattern for mixing between two fluids at three different aggregate flow rates: 20, 200, and 400 microliters per minute, respectively.
Definitions The term "channel" as used herein is to be interpreted in a broad sense. Thus, the term "channel" is not intended to be restricted to elongated configurations where the transverse or longitudinal dimension greatly exceeds the diameter or cross-sectional dimension. Rather, the term is meant to include a conduit of any desired shape or configuration through which liquids may be directed. A channel may be filled with one or more materials.
The term "major dimension" as used herein refers to the largest of the length, width, or height of a particular shape or structure. For example, the major dimension of a circle is its radius, and the major dimension of a rectangle (having a length that is greater than its width or height) is its length. As applied to an aperture, the major dimension of a circular aperture is its radius, and the major dimension of a typical rectangular aperture is its length.
The term "microfluidic" as used herein is to be understood, without any restriction thereto, to refer to structures or devices through which fluid(s) are capable of being passed or directed, wherein one or more of the dimensions is less than five hundred (500) microns. The terms "passive" or "passive mixing" as used herein refer to mixing between fluid streams without the use of moving elements.
The term "stencil" as used herein refers to a material layer or sheet that is preferably substantially planar, through which one or more variously shaped and oriented channels have been cut or otherwise removed through the entire thickness of the layer, thus permitting substantial fluid movement within the layer (as opposed to simple through-holes for transmitting fluid through one layer to another layer). The outlines of the cut or otherwise removed portions form the lateral boundaries of microstructures that are completed when a stencil is sandwiched between other layers, such as substrates and/or other stencils. Stencil layers can be flexible, thus permitting one or more layers to be manipulated so as not to lie in a plane.
Fabrication of Microfluidic Structures
In an especially preferred embodiment, microfluidic devices may be constructed using stencil layers or sheets to define channels for transporting fluids. A stencil layer is preferably substantially planar and has one or more microstructures such as channels cut through the entire thickness of the layer. For example, a computer-controlled plotter modified to manipulate a cutting blade may be used. Such a blade may be used either to cut sections to be detached and removed from the stencil layer, or to fashion slits that separate regions in the stencil layer without removing any material. Alternatively, a computer- controlled laser cutter may be used to cut patterns through the entire thickness of a material layer. While laser cutting may be used to yield precisely-dimensioned microstructures, the use of a laser to cut a stencil layer inherently removes some material. Further examples of methods that may be employed to form stencil layers include conventional stamping or die- cutting technologies. Any of the above-mentioned methods for cutting through a stencil layer or sheet permits robust devices to be fabricated quickly and inexpensively compared to conventional surface micromachining or material deposition techniques used by others to produce fluidic microstructures.
After a portion of a stencil layer is cut or removed, the outlines of the cut or otherwise removed portions form the lateral boundaries of microstructures that are completed upon sandwiching a stencil between other device layers such as substrates and/or other stencils. Upon stacking or sandwiching the device layers together, the upper and lower boundaries of a microfluidic channel within a stencil layer are formed from the bottom and top, respectively,
of adjacent stencil or substrate layers. The thickness or height of microstructures such as channels can be varied by altering the thickness of a stencil layer, or by using multiple substantially identical stencil layers stacked on top of one another. When assembled in a microfluidic device, the top and bottom surfaces of stencil layers are intended to mate with one or more adjacent stencil or substrate layers to form a substantially sealed device, typically having one or more fluid inlet ports and one or more fluid outlet ports. A stencil layer and surrounding stencil or substrate layers may be bonded using any appropriate technique.
The wide variety of materials that may be used to fabricate microfluidic devices using sandwiched stencil layers include polymeric, metallic, and/or composite materials, to name a few. In especially preferred embodiments, however, polymeric materials are used due to their inertness and each of manufacture.
When assembled in a microfluidic device, the top and bottom surfaces of stencil layers may mate with one or more adjacent stencil or substrate layers to form a substantially sealed device. In one embodiment, one or more layers of a device may be fabricated from single- or double-sided adhesive tape, although other methods of adhering stencil layers may be used. A portion of the tape (of the desired shape and dimensions) can be cut and removed to form microstructures such as channels. A tape stencil can then be placed on a supporting substrate with an appropriate cover layer, between layers of tape, or between layers of other materials. In one embodiment, stencil layers can be stacked on each other. In this embodiment, the thickness or height of the channels within a particular stencil layer can be varied by varying the thickness of the stencil layer (e.g., the tape carrier and the adhesive material thereon) or by using multiple substantially identical stencil layers stacked on top of one another. Various types of tape may be used with such an embodiment. Suitable tape carrier materials include but are not limited to polyesters, polycarbonates, polytetrafluoroethlyenes, polypropylenes, and polyimides. Such tapes may have various methods of curing, including curing by pressure, temperature, or chemical or optical interaction. The thicknesses of these carrier materials and adhesives may be varied. As an alternative to using tape, an adhesive layer may be applied directly to a non-adhesive stencil or surrounding layer. Examples of adhesives that might be used, either in standalone form or incorporated into self-adhesive tape, include rubber-based adhesives, acrylic-based adhesives, gum-based adhesives, and various other types.
Notably, stencil-based fabrication methods enable very rapid fabrication of robust microfluidic devices, both for prototyping and for high-volume production. Rapid prototyping is invaluable for trying and optimizing new device designs, since designs may be quickly implemented, tested, and (if necessary) modified and further tested to achieve a desired
result. The ability to prototype devices quickly with stencil fabrication methods also permits many different variants of a particular design to be tested and evaluated concurrently. In another preferred embodiment, microfluidic devices may be fabricated from materials such as glass, silicon, silicon nitride, quartz, or similar materials. Various conventional surface machining or surface micromachining techniques such as those known in the semiconductor industry may be used to fashion channels, vias, and/or chambers in these materials. For example, techniques including wet or dry etching and laser ablation may be used. Using such techniques, channels may be made into one or more surfaces of a first substrate. A second set of channels may be etched or created in a second substrate. Still further embodiments may be fabricated from various materials using well-known techniques such as embossing, stamping, molding, and soft lithography. Additionally, in yet another embodiment, the layers are not discrete, but instead a layer describes a substantially planar section through such a device. Such a microfluidic device can be constructed using photopolymerization techniques such as those described in Cumpston, ef al. (1999) Nature 398:51 -54.
In addition to the use of adhesives or single- or double-sided tape discussed above, other techniques may be used to attach one or more of the various layers of microfluidic devices, as would be recognized by one of ordinary skill in attaching materials. For example, attachment techniques including thermal, chemical, or light-activated bonding; mechanical attachment (including the use of clamps or screws to apply pressure to the layers); or other equivalent coupling methods may be used.
Microfluidic Mixers
Certain embodiments of the present invention are directed to passive microfluidic mixing devices capable of rapidly mixing two or more fluid streams in a controlled manner without the use of stirrers or other moving parts. Typically, mixing is substantially completed within the novel microfluidic devices. In one embodiment, these devices contain microfluidic channels or channel segments that are formed in various layers of a three-dimensional structure. Mixing may be accomplished using various manipulations of fluid flow paths and/or contacts between fluid streams. For example, in various embodiments structures such as channel overlaps, converging/diverging regions, and turns may be designed into a mixing device to promote rapid and controlled mixing between two or more fluid streams. Certain parameters may be altered to have a controllable effect on the amount or rate of mixing, such as, but not limited to, the size and geometry of the microstructures, surface chemistry of the materials, the fluids used, and the flow rate of the fluids. Multiple structures to promote mixing may be used within the same device, such as to ensure more rapid or
complete mixing, or to provide sophisticated mixing utility such as mixing different fluid streams in various proportions.
Microfluidic channels have at least one dimension less than about 500 microns. Channels useful with the certain embodiments preferably also have an aspect ratio that maximizes surface-to-surface contact between fluid streams. A channel may have a depth from about 1 to about 500 microns, preferably from about 10 to about 100 microns, and a width of about 10 to about 10,000 microns such that the aspect ratio (width/depth) of the channel cross section is at least about 2, preferably at least about 10, at the overlap region where the channels meet. In various embodiments, a channel can be molded into a layer, etched into a layer, or can be cut through a layer. Where a channel is cut through the entire thickness of a layer, it is referred to as a stencil layer.
Various embodiments produce sufficient interfacial contact per cross-sectional area between the different fluid streams to effect rapid mixing. In this manner, diffusional mixing is achieved between two or more fluid streams that meet at the overlap region, and they can mix to a greater degree than is usual in a microfluidic device. The shape and the amount of overlap at those points can be controlled in order to alter the amount of mixing.
In various embodiments, a microfluidic device may contain one or several mixing regions. In certain embodiments, all of the mixing regions are substantially identical in type, size and/or geometry. In other embodiments, mixing regions of different types, sizes, or geometries may be provided within a single device in order to produce preferential mixing. In certain embodiments, mixers may be multiplexed within a device to perform various functions. For example, mixers may be multiplexed within a device to promote combinatorial synthesis of various types of materials.
Importantly, the nature of these microfluidic mixers may be tuned for particular applications. Some of the parameters that affect the design of these systems include the type of fluid to be used, flow rate, and material composition of the devices. The microfluidic mixers described herein may be constructed in a microfluidic device by controlling the geometry and chemistry of the regions where one fluid stream contacts another.
Prior two-dimensional microfluidic mixing devices typically have fluidic channels on a single substantially planar layer of a microfluidic device. Generally, the aspect (width to height) ratio of these channels is 10:1 or greater, with channels widths commonly being between 10 and 500 times greater than their height. This constraint is due in part to limitations of the silicon fabrication techniques typically used to produce such devices. In order to mix samples, two coplanar inlet channels are brought together into a common outlet channel. The fluids meet at the intersection and proceed down the outlet channel, typically in a side-by-side fashion. In microfluidic systems, fluid flow is practically always laminar (no
turbulent flow occurs); thus, any mixing in this outlet channel occurs through diffusional mixing at the interface between the inputted liquid streams. This mixing is extremely slow since the interface between the two intersecting fluids is along the smaller dimension of the perpendicular cross-sections of the fluid streams, and this dimension is very small compared to the overall volume of the fluids. Since in traditional two-dimensional microfluidic systems all of the fluidic channels are contained within the same substantially planar layer of the device, this problem is difficult to overcome. Microfluidic devices approximating prior art two- dimensional "mixing" structures were constructed. Typical results of attempts to mix two liquids (e.g., colored water) in such devices are shown in fairly dramatic fashion in FIGS. 1 A- 1B, showing the relative lack of diffusive mixing between two contacting, side-by-side streams.
Microfluidic devices according to the present embodiments are three-dimensional, having microfluidic channels defined on or located in different layers of a fluidic device. In certain embodiments, multiple fluid streams flow side-by-side within a first microfluidic channel until they reach a contraction / expansion region leading to a second microfluidic channel, with the first channel and the second channel being defined in different device layers. Multiple contraction expansion regions may be provided in series to promote more rapid or complete missing between the fluids.
In another preferred embodiment, changing the chemical nature of the device layers or specific regions may alter the mixing characteristics. This can be accomplished by forming a stencil layer from a different material, or by altering the surface chemistry of a stencil layer. Surface chemistry of a stencil layer can be altered in many ways, as would be recognized by one skilled in the art. Examples of methods for altering surface chemistry include chemical derivatization as well as surface modification techniques such as plasma cleaning or chemical etching. The above-described methods for altering the chemical nature of device layers or specific regions within a microfluidic device can be used independently or in conjunction with one another.
In a mixer embodiment having an intermediate spacer layer, the spacer layer defines an aperture that is substantially smaller in major dimension than the adjacent channels. Such an aperture may be configured in various convenient shapes, such as round, rectangular, or triangular, to name a few. Additionally, such an aperture is preferably disposed substantially centered along the width of each of the adjacent channels. In one embodiment, two microfluidic channels carrying different fluids meet at a junction region in one layer, which typically results in a combined stream of two distinct fluids flowing side-by- side. The combined stream then proceeds through an "upstream" channel to a channel overlap region with a small aperture that permits fluid communication between the upstream
channel and a downstream channel. Flow continues through the small aperture and into the downstream channel. The combination of the small aperture and downstream channel serves as a contraction / expansion region, since fluid flow area contracts through the aperture and then expands as fluid moves into the downstream channel. Multiple channel overlap contraction / expansion regions may be provided in a single device. When placed in series, multiple contraction / expansion regions may promote more rapid or complete mixing of multiple fluids.
Some examples of mixing devices having multiple channel overlap contraction / expansion regions are provided in FIGS. 2A-2B and 2A-2B. In further embodiments, fluid streams may be manipulated to undergo a substantial change in direction from one contraction / expansion region to another. Examples of such devices are provided in FIGS. 4A-4B and 5A-5B.
The following Examples describe certain aspects of several preferred embodiments of the present invention.
Example 1 In one embodiment, a microfluidic mixing device includes a spacer layer defining an aperture that is substantially smaller in diameter than the adjacent upstream and downstream channels, such that the aperture and downstream channel serve as a contraction / expansion region to promote mixing. One example of a microfluidic mixer embodying such a design is shown in FIGS. 2A-2B. A mixing device 250 is constructed in five device layers 251-255, including stencil layers 252, 254. Starting from the bottom, the first layer 251 defines two fluid inlet ports 256, 257 and two outlet ports 258, 259, each port being about eighty (80) mils in diameter. The second layer 252 defines two inlet channel sections 260, 261 meeting at a junction 262 that feeds an upstream channel section 263 having an outlet 263A. The second layer 252 defines another channel 264 having a splitting region 265 for dividing a mixed fluid stream into two substreams. The third layer 253 defines two small apertures 266, 267, each aperture 266, 267 being smaller in size than the adjacent channels 263, 268, 264. In this embodiment, each aperture 266, 267 is approximately six (6) mils in diameter. Preferably, these apertures 266, 267 are substantially centered along the width of each of the channels 263, 264, 268. The fourth layer 254 defines a channel 268 that slightly overlaps both channel section 263 and channel 264 defined in the second layer 252. The channel 268 is substantially downstream of the channel section 263 and first aperture 266, and simultaneously is substantially upstream of the second aperture 267 and channel 264. The fifth layer 255 may be fabricated from a bare substrate or film, thus serving to enclose the channel 268 from above and support the device 250 if necessary.
The channels 260, 261 , 263, 264, 265, 268 each have a nominal width of about forty (40) mils. As described previously, the stencil layers 252, 254 may be advantageously fabricated from double-sided self-adhesive tapes, while the non-stencil layers 251 , 253, 255 may be fabricated from non-adhesive materials. In operation, a first fluid stream is injected into the first inlet port 256 and a second fluid stream is injected into the second inlet port 257. The fluid streams travel through channel sections 260, 261 , respectively until they meet at the junction 262. From the junction 262, the components of the combined stream flow side-by-side through the channel section 263 until reaching a channel outlet 263A immediately upstream of the first aperture 266. The combined stream flows upward through the small aperture 266 and into channel 268, which together serve as a contraction-expansion region that promotes mixing. The combined stream proceeds through channel 268 and flows downward to the second aperture 267 and into the channel 264. The combination of the second aperture 267 and the channel 264 serves as another contraction-expansion region that promotes further mixing. In the illustrated embodiment, the first upstream channel section 263, the upstream/downstream channel section 268, and the downstream channel section 264 all direct the fluids in substantially the same direction without any significant directional change. From the second channel 264, the fluid is directed to a splitting region 265 where it is split into two streams to exit the mixing device 250 through outlet ports 258, 259. It has been observed that the microfluidic mixing device 250 promotes more rapid or complete mixing within a given distance of the contraction / expansion regions at higher fluid flow rates. For example, FIG. 2C shows a photograph of a combined fluid flow rate of about twenty (20) microliters per minute flowing through the device 250 (flowing from left to right). Notably, mixing does not appear complete downstream of the contraction / expansion regions, since a relatively clear demarcation between the first (blue) and second (yellow) fluid streams remains visible. In contrast, FIG. 2D shows a photograph of the same device subjected to a combined fluid flow rate of about four hundred (400) microliters per minute. In this case, mixing between the fluid streams appears to be much more complete.
Example 2
In the previous example, a microfluidic mixing device included two contraction / expansion regions. Similar mixing devices can be constructed with numerous contraction / expansion regions in series to promote more rapid or complete mixing. For example, a microfluidic mixing device 300 having ten (10) contraction / expansion regions is illustrated in FIGS. 3A-3B. The device 300 is constructed with five device layers 301-305, including stencil layers 302, 304. Starting from the bottom, the first layer 301 defines two fluid inlet
ports 308, 309 and two outlet ports 310, 311 , each port being about eighty (80) mils in diameter. The second layer 302 defines two inlet channel sections 312, 313 meeting at a junction 314 leading to a channel outlet 314A. The second layer 302 defines four channel sections 315 and another channel 316 having a splitting region for dividing a mixed fluid stream into two substreams. The third layer 303 defines ten (10) small apertures 318, each aperture 318 being about six (6) mils in diameter. As before, these apertures 318 are substantially centered along the width of each of the channels 315, 316, 320. The fourth layer 304 defines five channel sections 320, each of which has a channel inlet 320A and slightly overlaps two channels or channel sections defined in the second layer 302. Each of the channel sections 315, 320 is downstream of one aperture 318 and upstream of another, with the channel sections 315, 320 and upstream and downstream channels 314, 316 all serving to direct fluid in substantially the same direction. The fifth layer 305 may be fabricated from a bare substrate or film, thus serving to enclose the channel sections 320 from above and support the device 300 if necessary. Each of the above-described channels has a nominal width of about forty (40) mils. As described in connection with the previous two Examples, the stencil layers 302, 304 may be advantageously fabricated from double- sided self-adhesive tapes, while the sandwiching layers 301 , 303, 305 may be advantageously fabricated from non-adhesive materials.
The mixing device 300 operates in a substantially identical manner as the device 250 described previously, except that the device 300 has ten (10) contraction / expansion regions rather than two. It has been observed that the use of ten contraction / expansion regions promote more rapid or complete mixing than the use of two. As before, better mixing was observed at higher fluid flowrates, as shown in FIGS. 3C-3E. FIG. 3C shows a photograph of a combined fluid flow rate of about twenty (20) microliters per minute flowing through the mixing device 300 (flowing from left to right). Here, a relatively clear demarcation between the first (blue) and second (yellow) fluid streams remains visible even after passage through ten contraction/expansion regions , indicating less-than-optimal mixing. FIG. 3D shows a photograph of the same device 300 containing a combined fluid flow rate of about two hundred (200) microliters per minute. Mixing appears to be noticeably better in this case. FIG. 3E, however, shows the same mixing device 300 with better mixing results obtained at a combined fluid flow rate of about four hundred (400) microliters per minute. It thus appears that higher fluid flow rate and the presence of more contraction / expansion regions are factors that may be employed to improve mixing.
Example 3 In further embodiments, fluids may undergo substantial directional changes in addition to flowing through contraction / expansion regions. For example, a microfluidic mixing device 340 having four contraction / expansion regions and two flow reversal regions is illustrated in FIGS. 4A-4B. The device 340 is constructed with eleven device layers 341- 351 , including stencil layers 342, 344, 346, 348, 350. Starting from the bottom, the first layer 341 defines two fluid inlet ports 355, 356, each port being about one hundred twenty mils in diameter. The second layer 342 defines two inlet channel sections 357, 358 meeting at a junction channel 360 having a channel outlet 360A. The third, fifth, seventh, and ninth layers 343, 345, 347, 349 each define a small aperture 362, 364, 366, 368, respectively. Each of the apertures 362, 364, 366, 368 are about ten mils in diameter and are preferably substantially centered along the width of their surrounding channels. The fourth, sixth, and eighth layers 344, 346, 348 each define a channel 363, 365, 367, respectively, with each channel having a channel inlet, such as channel inlet 363A. The tenth layer 350 defines an outlet channel 370 that leads to the fluidic outlet port 372 defined in the eleventh layer 351. Each of the above-described channels has a nominal width of about one hundred twenty (120) mils. As described previously, the stencil layers 342, 344, 346, 348, 350 may be advantageously fabricated from double-sided self-adhesive tapes, while the sandwiching non-stencil layers 341, 343, 345, 347, 349, 351 may be advantageously fabricated from non- adhesive materials.
In operation, a first fluid stream is injected into the first inlet port 355 and a second fluid stream is injected into the second inlet port 356. The fluid streams travel through channel sections 357, 358, respectively until they meet at a junction channel 360 and flow to channel outlet 360A. From the channel outlet 360A, the components of the combined stream flow through the first aperture 362 into the inlet 363A of first short channel 363, the combination serving as a first contraction / expansion region. From the first short channel 363, the fluid combination flows through the second aperture 364 into the second short channel 365. Notably, the second short channel segment 365 reverses the direction of the fluid combination by approximately 180 degrees toward the third aperture 366. From the third aperture 366, the fluid enters the third short channel 367, where the fluid changes direction again toward the fourth aperture 368. Looking from the top down, the fluid would appear to move in a back-and-forth direction between the second short channel 365 and the third short channel 367. From the fourth aperture 368, the fluid flows into the outlet channel 370 and ultimately exits the device 340 through the outlet port 372. The resulting mixing device 340 utilizes many (eleven) layers but promotes mixing between two microfluidic streams within a small footprint, as shown in top view in FIG. 4B.
Example 4 Further microfluidic mixing device embodiments having multiple contraction / expansion regions and many fluid directional changes may be constructed. For example, a microfluidic mixing device 380 having eighteen contraction / expansion regions and sixteen roughly ninety-degree directional change regions is illustrated in FIGS. 5A-5B. The device 380 is constructed with five device layers 381-385, including stencil layers 382, 384. Starting from the bottom, the first layer 381 defines two fluid inlet ports 386, 387 and two outlet ports 388, 389, each port being about eighty mils in diameter. The second layer 382 defines two inlet channel sections 392, 393 meeting at a junction channel 395 leading to a channel outlet 395A. The second layer 382 defines eight parallel short channels 397 and another channel 398 having a splitting region for dividing a mixed fluid stream into two substreams. The third layer 383 defines eighteen small apertures 399, each aperture 399 being about six mils in diameter. These apertures 399 are substantially centered along the width of each of the surrounding channels 397, 400. The fourth layer 384 defines ten short channels 400, each of which has a channel inlet 400A and slightly overlaps two channels defined in the second layer 382. Each of channels 397, 400 is downstream of one aperture 399 and upstream of another aperture 399. The fifth layer 385 may be fabricated from a bare substrate or film, thus serving to enclose the channel sections 400 from above and support the device 380 if necessary. The fifth layer 305 may be fabricated from a bare substrate or film, thus serving to enclose the channel sections 320 from above and support the device 300 if necessary. Each of the above-described channels has a nominal width of about forty mils. As described in connection with the previous two Examples, the stencil layers 382, 384 may be advantageously fabricated from double-sided self-adhesive tapes, while the sandwiching layers 381 , 383, 385 may be advantageously fabricated from non- adhesive materials.
The mixing device 380 operates similarly to the mixers described in the preceding Examples. A first fluid stream is injected into the first inlet port 386 and a second fluid stream is injected into the second inlet port 387. The fluid streams travel through channel sections 393, 393, respectively until they meet at junction channel 395. From the channel outlet 395A, the combined stream flows through the eighteen expansion-contraction regions and changes direction sixteen times, each time by approximately ninety degrees before splitting into two substreams at channel 398 and exiting the device 380 through outlet ports 388, 389. Increased flowrate through the device 380 seems to promote better mixing, as shown in FIGS. 5C-5E. FIGS.5C-5E show mixing between two fluids at a combined flow rates of twenty, two hundred, and four hundred microliters per minute, respectively. As is
apparent from comparing the three figures, more rapid or complete mixing within a given length of device is yielded at higher fluid flow rates.