1. Field of the Invention
The present invention relates to microfluidic processing of biological samples and, more particularly, to methods and apparatuses for use in temperature controlled processing of biological samples in a microfluidic device.
2. Description of the Related Art
Microfluidics refers to a set of technologies involving the flow of fluids through channels having at least one linear interior dimension, such as depth or diameter, of less than 1 mm. It is possible to create microscopic equivalents of bench-top laboratory equipment such as beakers, pipettes, incubators, electrophoresis chambers, and analytical instruments within the channels of a microfluidic device. Since it is also possible to combine the functions of several pieces of equipment on a single microfluidic device, a single microfluidic device can perform a complete analysis that would ordinarily require the use of several pieces of laboratory equipment. A microfluidic device designed to carry out a complete chemical or biochemical analyses is commonly referred to as a micro-Total Analysis System (μ-TAS) or a “lab-on-a chip.”
A lab-on-a-chip type microfluidic device, which can simply be referred to as a “chip,” is typically used as a replaceable component, like a cartridge or cassette, within an instrument. The chip and the instrument form a complete microfluidic system. The instrument can be designed to interface with microfluidic devices designed to perform different assays, giving the system broad functionality. For example, the commercially available Agilent 2100 Bioanalyzer system can be configured to perform four different types of assays—DNA (deoxyribonucleic acid), RNA (ribonucleic acid), protein, and cell assays—by simply placing the appropriate type of chip into the instrument.
In a typical microfluidic system, the microfluidic channels are in the interior of the chip. The instrument interfacing with the chip performs a variety of different functions: supplying the driving forces that propel fluid through the channels in the chip, monitoring and controlling conditions (e.g., temperature) within the chip, collecting signals emanating from the chip, introducing fluids into and extracting fluids out of the chip, and possibly many others. The instruments are typically computer controlled so that they can be programmed to interface with different types of chips and to interface with a particular chip in such a way as to carry out a desired analysis.
Microfluidic devices designed to carry out complex analyses will often have complicated networks of intersecting channels. Performing the desired assay on such chips will often involve separately controlling the flows through certain channels, and selectively directing flows through channel intersections. Fluid flow through complex interconnected channel networks can be accomplished either by building microscopic pumps and valves into the chip or by applying a combination of externally-generated driving forces to the chip. Examples of microfluidic devices with pumps and valves are described in U.S. Pat. No. 6,408,878, which represents the work of Dr. Stephen Quake at the California Institute of Technology. Fluidigm Corporation of South San Francisco, Calif., is commercializing Dr. Quake's technology. The use of multiple electrical driving forces to control the flow through complicated networks of intersecting channels in a microfluidic device is described in U.S. Pat. No. 6,010,607, which represents the work Dr. J. Michael Ramsey performed while at Oak Ridge National Laboratories. The use of multiple pressure driving forces to control flow through complicated networks of intersecting channels in a microfluidic device is described in U.S. Pat. No. 6,915,679, which represents technology developed at Caliper Life Sciences, Inc. of Hopkinton, Mass.
Lab-on-a-chip type microfluidic devices offer a variety of inherent advantages over conventional laboratory processes such as reduced consumption of sample and reagents, ease of automation, large surface-to-volume ratios, and relatively fast reaction times. Thus, microfluidic devices have the potential to perform diagnostic assays more quickly, reproducibly, and at a lower cost than conventional devices. The advantages of applying microfluidic technology to diagnostic applications were recognized early on in development of microfluidics. In U.S. Pat. No. 5,587,128, Drs. Peter Wilding and Larry Kricka from the University of Pennsylvania describe a number of microfluidic systems capable of performing complex diagnostic assays. For example, Wilding and Kricka describe microfluidic systems in which the steps of sample preparation, PCR (polymerase chain reaction) amplification, and analyte detection are carried out on a single chip.
For the most part, the application of microfluidic technology to diagnostic applications has failed to reach its potential, so only a few such systems are currently on the market. Two of the major shortcomings of current microfluidic diagnostic devices relate to cost and to difficulties in sample preparation. Issues related to cost arise because materials that are inexpensive to process into chips, such as many common polymers, are not necessarily chemically inert, thermally stable, or optically transparent enough to be suitable for diagnostic applications. To address the cost issue, technology has been developed that allows microfluidic chips fabricated from more expensive materials to be reused, lowering the cost per use. See U.S. Published Application No. 2005/0019213. However, when chips are reused, issues of cross-contamination from previously processed samples could arise. The best solution may be to overcome the limitations of currently available polymer materials so that a chip can be manufactured inexpensively enough to be disposed of after a single use.
It is an object of the present invention to employ microfluidic devices for the performance of assays, such as PCR, that could be relevant to diagnostic applications. In particular, it is an object of the invention to provide methods and apparatuses based on microfluidic technology that allow PCR amplification and analyte detection to be performed in a cost-effective manner.
These and further objects will be more readily appreciated when considering the following disclosure and appended claims.
In various embodiments and aspects, the invention comprises a microfluidic device, instrumentation interfacing with that device, processes for fabricating that device, and methods of employing that device. Embodiments of the invention provide microfluidic devices capable of performing PCR amplification. Embodiments of the invention are also compatible with quantitative Polymerase Chain Reaction (“qPCR”) processes.
In an illustrative embodiment, the microfluidic device contains a plurality of parallel processing channels. Fully independent reactions can take place in each of the plurality of parallel processing channels. The availability of independent processing channels allows a microfluidic device in accordance with the invention to be used in a number of ways. For example, separate samples could be processed in each of the independent processing channels. Alternatively, different loci on a single sample could be processed in multiple processing channels.
Microfluidic devices in accordance with the invention may comprise wells configured to receive the reagents to be used and the samples to be processed in the device. In order to make the microfluidic device compatible with industry standard liquid handling equipment, the wells could be arranged in the same pattern and with the same spacing as the wells on industry standard multiwell plates. For example, the wells could be arranged in the same pattern as the wells on standard 96, 384, or 1536 well microtiter plates. Some of the reagents to be used in the device could be stored in the device in dry form, so that they can be reconstituted through the addition of liquid when the processing of a sample is to take place.
The invention may be understood by reference to the following description taken in conjunction with the accompanying drawings, in which like reference numerals identify like elements, and in which:
While the invention is susceptible to various modifications and alternative forms, the drawings illustrate specific embodiments herein described in detail by way of example. It should be understood, however, that the description herein of specific embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Illustrative embodiments of the invention are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort, even if complex and time-consuming, would be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.
For present purposes, however, note that the body structure 106b defines a plurality of ports 157 (only one indicated) into the microfluidic circuits (not yet shown) that align with the wells 103, which are formed in the caddy 106b. In general, the ports 157 will be relatively small, as is the case generally with microfluidic devices such as the device 100. To ease difficulties associated with that size, the wells 103 of the caddy 106a are usually significantly larger. Thus, the wells 103 are loaded with fluids 109 and the fluids 109 are then loaded into the microfluidic circuits within the body structure 106b through these ports 157. In such an embodiment, the ports into the microfluidic circuits can be formed as “funnels”, with a larger opening at the surface and a narrower opening into the microfluidic circuit. The structural interface between the caddy 106a and the body structure 106b may be, for example, the same as that disclosed in U.S. Pat. No. 6,488,897, entitled “Microfluidic Devices and Systems Incorporating Cover Layers”, issued Dec. 3, 2002, to Caliper Technologies Corp. as assignee of the inventors Robert S. Dubrow, et al., although others may be used.
In the illustrated embodiment of
The assembly 150 includes not only the microfluidic device 100, but also first and second, or “top” and “bottom,” covers 160, 163. The first cover 160 includes pneumatic access ports 165 and electrical access ports 168 through which a pressure (e.g. a vacuum) and electrical power respectively may be supplied to the pneumatic and electrical circuits 153, 156. The first cover 160 also includes a cutout 170, whose function will be discussed below. As will be apparent from the discussion below, the cutout 170 may be omitted in some embodiments. Note that the terms “top” and “bottom” as used in this paragraph are defined relative to the nominal orientation of the assembly 150 in
The microfluidic device 100, first cover 160, and second cover 163 may be assembled in any manner known to the art. Note that the first cover 160 does not provide access to the individual wells 103, and is therefore assembled after the fluids 109 are deposited into the wells 103. This may affect the techniques used in assembly in some embodiments. In general, the caddy 106a and body structure 106b of the plate 106, the top cover 160, and the bottom cover 163 may be, for example, adhered or fastened together. In the illustrated embodiment, the caddy 106a and body structure 106b are laminated together, as is the bottom cover 163. The structural interface between the caddy 106a and the body structure 106b can be that as described in previously cited U.S. Pat. No. 6,488,897. In disposable embodiments, the manner in which the top cover 160 is assembled is not material, but may be taken into account in embodiments in which the microfluidic device 100 might be reused.
A more detailed view of the ports and channels on body structure 106b is shown in
Techniques for the manufacture of microfluidic ports (e.g., the ports 120-126) and channels (e.g., the channels 128) are known to the art for embodiments in which the body structure 106b is fabricated from glass or plastic. These known techniques will be readily adaptable to the present invention by those in the art having the benefit of this disclosure. For embodiments in which the body structure 106b is fabricated from plastic, traditional manufacturing techniques employed in polymer processing may be used. For instance, body structure 106b, or a plurality of components that are assembled to form body structure 106b, may be molded and laminated, or cast and milled, or some combination of these techniques. This proposition also holds for the caddy 106a. Such manufacturing techniques are well known across a number of arts, and should also be readily adaptable to the present invention by those in the art having the benefit of this disclosure.
A variety of substrate materials may be employed to fabricate a microfluidic device such as device 100 in
Properties of the interior channel surfaces determine how these surfaces chemically interact with materials flowing through the channels, and those properties will also affect the amount of electroosmotic flow that will be generated if an electric field is applied across the length of the channel. Techniques have been developed to either chemically treat or coat the channel surfaces so that those surfaces have the desired properties. Examples of processes used to treat or coat the surfaces of microfluidic channels can be found in:
Materials normally associated with the semiconductor industry are often used as microfluidic substrates since microfabrication techniques for those materials are well established. Examples of those materials are glass, quartz, and silicon. In the case of semiconductive materials such as silicon, it will often be desirable to provide an insulating coating or layer, e.g., silicon oxide, over the substrate material, particularly in those applications where electric fields are to be applied to the device or its contents. The microfluidic devices employed in the Agilent Bioanalyzer 2100 system are fabricated from glass or quartz because of the ease of microfabricating those materials and because those materials are generally inert in relation to many biological compounds.
Microfluidic devices can also be fabricated from polymeric materials such as polymethylmethacrylate (“PMMA”), polycarbonate, polytetrafluoroethylene (e.g., TEFLON™), polyvinylchloride (“PVC”), polydimethylsiloxane (“PDMS”), polysulfone, polystyrene, polymethylpentene, polypropylene, polyethylene, polyvinylidine fluoride, acrylonitrile-butadiene-styrene copolymer (“ABS”), cyclic-olefin polymer (“COP”), and cyclic-olefin copolymer (“COC”). Such polymeric substrate materials are compatible with a number of the microfabrication techniques described above. Since microfluidic devices fabricated from polymeric substrates can be manufactured using low-cost, high-volume processes such as injection molding, polymer microfluidic devices could potentially be less expensive to manufacture than devices made using semiconductor fabrication technology. Nevertheless, there are some difficulties associated with the use of polymeric materials for microfluidic devices. For example, the surfaces of some polymers interact with biological materials, and some polymer materials are not completely transparent to the wavelengths of light used to excite or detect the fluorescent labels commonly used to monitor biochemical systems. So even though microfluidic devices may be fabricated from a variety of materials, there are tradeoffs associated with each material choice.
Similarly, techniques for preparing and loading microfluidic samples and other fluids are also well known to the art and readily adaptable. Any suitable technique known to the art for these tasks may be employed. For instance, sample preparation and loading can be performed manually, as it has been in the past. Alternatively, sample preparation and loading may be automated, since the illustrated embodiment is designed to meet standards employed in automated processing of microtiter plates. In other words, the wells 103 are arranged in the same manner as the wells on standard format microtiter plates. That allows industry standard fluid handling equipment to be use to add and remove fluids from the wells 103. Note that there is one manner in which the illustrated embodiment departs from those standards. In a standard microtiter plate, the area corresponding to the heating area 112 would be occupied by wells. In other words, while a standard microtiter plate comprises a full rectangular array of wells, a microfluidic device in accordance with the invention will be missing the wells in the array that would occupy heating region 112. Thus, the microfluidic device 100 will have fewer wells 103 than would a microtiter plate meeting the same standard and some accommodation for this departure will be made in automated handling systems.
The invention admits variation in the configuration of the microfluidic circuits in various alternative embodiments of the present invention.
Returning to
In this particular embodiment, the electrical circuit 156 is shown on the surface of the caddy 106a, but this is not necessary to the practice of this aspect of the invention. The electrodes 173a-173d may be at any layer of the microfluidic device 100. (Similarly, the pneumatic circuit 153 need not be fabricated on the surface in all embodiments.) Some embodiments may also find if desirable to employ separate electrodes to each well 103 rather than the four shown.
The electrodes 173a-173d may be fabricated using any suitable technique. Exemplary techniques include co-injection molding, insert molding, printing, or some form of flow of material followed by some sort of curing or hardening, or by lowering heat. However, other techniques may be employed.
Some alternative embodiments may fabricate the electrodes 173a-173d using a low melt point metal, a low melt point metal alloy, a stamped metal, a conductive ink, or a conductive gel. Still other alternative embodiments may employ still other materials. Note that fabrication techniques in these alternative embodiments will vary depending on the material from which the electrodes 173a-173d are fabricated.
The microfluidic device 100, shown in
The instrument 400 also includes an optical assembly 512 mounted to the top 515 of the landing 503. The optical assembly 512 is best shown in
Microfluidic devices such as the microfluidic device 100 may be used in a variety of applications, including, e.g., the performance of high throughput screening assays in drug discovery, immunoassays, diagnostics, genetic analysis, and the like. The wells 103 and the ports 157, shown in
Returning to
The instrument 400 further includes a thermocycler 530, constructed and operated in accordance with another aspect of the present invention, mounted to the underside 533 of the landing 503. In general, the thermocycler 530 operates by contacting the heating area 112 of the microfluidic device 100 with a series of thermal elements for a predetermined time to bring the temperature of the microfluidic samples 106 to some desired temperature and hold it there. The invention admits some variation in the manner in which this may be achieved.
Turning now to
Note that the bars 603 are not shown contacting the microfluidic device 100, but that such contact will be found in operation. One way to initiate such contact would be to lift the shaft 606, and thus the bars 603, using the drive 609. Alternatively, a lift (not shown) may be provided for the subassembly of the drive 609, shaft 606, and bars 603. The bars 603 may be mounted to the shaft 606 using any technique known to the art provided it suffices to overcome the forces imparted by rotation of the shaft 606. The magnitude of those forces will be a function of, for instance, the speed of the rotation.
More particularly, the bars 703 are placed securely in the tray 706. The lift 709 includes a shaft 715 that reciprocates, as indicated by the arrow 718. The shaft 715 operates either directly on the bars 703 extending through the tray 706, as shown in
Each of the thermocycler embodiments 530 disclosed above operate under the aegis of a controller that controls the positioning of the microfluidic device 100 and thermal elements relative to one another, and the temperatures of the thermal elements.
On power-on or reset, the processor 903, under the control of the OS 912, performs a self-test and then invokes the protocol application 915. Under the direction of the protocol application, the processor 903 implements the testing protocol of the process to which the microfluidic sample 109, shown in
Upon receiving the START signal, the processor 903 begins executing the protocol application 915. In general, on execution, the protocol application performs a method comprising cycling a microfluidic sample 109 through a plurality of thermal cycles. Each thermal cycle includes contacting a predetermined portion, i.e., the heating area 112, of a microfluidic device 100 holding the microfluidic sample 109 with a respective thermal element. The microfluidic sample 109 is then heated to a predetermined temperature for a predetermined period of time. The temperature and time data may be either hard-coded into the protocol application 915; or, retrieved by the protocol application 915 from, e.g., a data store 918; or, entered through a console.
To implement the protocol, the processor 903, in executing the protocol application, generates and transmits CONTROL signals to the various components of the instrument 400. The content of the CONTROL signals will be implementation specific. For instance, in embodiments employing the thermocycler 530a of
Turning now to
The illustrated embodiment is intended for use in performing a polymerase chain reaction (“PCR”). PCR is a common technique that is well known and well understood in the art. Although temperatures and durations may vary, PCR usually involves three thermal cycles—hence, the use of three thermal elements 1003a-1003c. Thus, in this particular embodiment, the microfluidic sample 109 comprises a solution of a target DNA sequence, a plurality of PCR primers, a polymerase, and a plurality of nucleotides, none of which are shown.
The process, according to the protocol implemented by the protocol application 915, shown in
However, the invention admits variation to help improve operational efficiency. Consider the embodiment 1100, in
Some embodiments may also provide fewer thermal elements 1003a-1003c than there are thermal cycles in the protocol. In the embodiments set forth illustrated herein, the implemented protocols call for a different temperature in each thermal cycle. However, some protocols may have multiple thermal cycles at the same temperature. In these embodiments, a single thermal element may be used in each thermal cycle calling for a particular temperature. It is there possible that the number of thermal elements may differ from the number of thermal cycles in some embodiments.
Microfluidic devices typically allow for increased automation of standard laboratory processes. This is why microfluidic devices are often referred to as “labs on a chip.” Thus performing PCR in a microfluidic device allows multiple steps of the work flow associated with the PCR process to be performed on a single microfluidic device.
As mentioned above, the enzyme 130 for the PCR is loaded in the well 120; the microfluidic sample 131 (or “lysate”) is loaded in the wells 121, 123; the dried SIE buffer 132 is loaded in the well 122; the LSR 134 are loaded in the wells 124, 125. Waste from the PCR reaction is deposited in the wells 126. If the SIE buffer 132 and the locus specific reagents 134 are dried in wells 122, 124 and 125 respectively, then they are reconstituted and the electrical and pneumatic circuits 153, 156 are activated. The nucleic acid extraction occurs in a portion 1200, shown better in
The electrokinetic principles employed by the invention are by now known in the art. Such principles are taught, for instance, in:
The invention also admits variation to accommodate modification and differences in protocols. For instance, DNA-based procedures like PCR routinely monitor the various aspects of the process by tagging elements of the solution with a fluorescent tag.
More particularly,
The optical elements 1314 are positioned and arranged such that the elliptical spot 1316 is focused to the detection region 1325 on the sample microfluidic device 100. Preferably, the source 1310 and/or optical elements 1314 are positioned such that the elliptical excitation beam 1316 impinges on the microfluidic device 100 at a non-normal angle of incidence φ. In a preferred embodiment, φ is approximately 45° relative to the plane defined by microfluidic device 100, although other non-normal angles of incidence may be used, e.g., from about 30° to about 100°. In one embodiment, source 1310 and optical elements 1314 are arranged such that the elliptical excitation beam 1316 is polarized with a polarization direction/vector 1318 that is substantially parallel to the major axis of the elliptical excitation beam 1316.
The optical elements 1314 are also preferably arranged such that the major axis of the resulting elliptical excitation beam 1316 is substantially perpendicular to the direction of the micro-channels 1322 in the detection region 1325 as shown. Alternatively, the major axis of the elliptical excitation beam spot 1316 is oriented along the length of one or more of the microchannels 1322 in the detection region 1325. This orientation excites and detects a longer region of each of the microchannels 1322, e.g., where a time dependent reaction is being monitored, or where detection sensitivity requires extended detection. In this manner, substances (not shown) in each of the microfluidic channels 1322 may be simultaneously excited by the elliptical excitation beam 1316.
Emissions emanating from the samples 109 in each of the plurality of the microchannels 1322 in the detection region 1325 are focused and/or directed by one or more optical elements 1334 (two elements shown) onto the detector array 1320. At least one optical element, e.g., element 1334′, such as an objective lens, is preferably positioned to direct emissions received from the detection region 1325 in a direction normal to the plane defined by the microfluidic device 100 as shown. One or more band-pass filter elements 1336 are provided to help prevent undesired wavelengths from reaching detector array 1320. The detector results then are processed over time to monitor the reaction. The light source may also be a light emitting diode (“LED”), which would typically have a larger illumination spot size. When detecting the reaction product in a dual rotor system, one or both rotors will move out of the optical path.
Although not shown, the radiation 1316 strikes the PCR reaction reservoirs 138, shown best in
As another example of a variation found in some embodiments, not all PCR protocols employ three thermal cycles. Some only employ two thermal cycles. In these PCR protocols, one cycles only between the denaturation and annealing temp and no dwell time is spent at those temperatures. The idea is that in an optimized assay, just reaching 95° C. is sufficient for denaturation and just touching the annealing temp, say 60° C., is enough for annealing. No time is spent at the extension step because the enzyme is active during the ramp from 60° C. to 95C. Even though no time is spent at the optimum temp for activity of 72° C.-74° C., there is enough activity during the ramp to yield a PCR. Thus, as few as two thermal elements may be used to implement certain PCR protocols.
Another alternative protocol calls for what is known as “thermal ramping.” One or more times while thermally cycling the microfluidic sample 109, or after completing thermal cycling, one of the heating elements can be ramped while thermally connected to the microfluidic sample 109. Thermal ramping is typically combined with fluorescent monitoring, which was discussed above and performed at the same time.
As was mentioned above, the invention admits wide variation in the implementation of the microfluidic device of the present invention.
The plate 1403 is fabricated, in the illustrated embodiment, from a plastic, such as COC. The plate 1403 comprises a first, or “top”, layer 1412 and a second, or “bottom” layer 1413. Note that the terms “top” and “bottom” are defined relative to their nominal orientations when the PCR device of the body structure 1400 is in use. In the illustrated embodiment, the first layer 1412 is approximately three times as thick as the first layer 1413—e.g., 300 μm to 100 μm thick. (The heating element 1609 is fabricated approximately 10 nm thick.) The term “approximately” is an accommodation to certain factors such as manufacturing tolerances, etc., the may interfere with some embodiments being able to achieve high degrees of precision. However, the relative thicknesses of the first and second layers 1412, 1413 is not material to the practice of the invention in this embodiment so long as the resultant device performs as intended by the invention.
The microfluidic PCR circuit 1406 generally includes a plurality 1415 of ports 1418, 1419 formed in the plate 1403 into which the PCR components may be loaded, e.g., the enzyme 1421 and the DNA and deoxyNucleotideTriPhosphate (“dNTP”) 1424. The microfluidic PCR circuit 1406 also includes a port 1427 formed in the plate 1403 by which an electrokinetic force may be imparted to the loaded PCR components 1421, 1424. The body structure 1400 imparts the electrokinetic force through, in the illustrated embodiment, a continuous flow vacuum. A plurality of microfluidic channels 1425, shown best in
More particularly, with respect to the microfluidic channels 1425, note that the microfluidic channels 1425 are actually fabricated in the interior of the body structure 1400. More particularly, as is best shown in
The microfluidic PCR circuit 1406 also includes a detection window 1430. This particular embodiment is intended for use with a fluorescent monitoring technique such as that disclosed above relative to
Note that this characteristic of the detection window 1430 impacts material selection at least for that part of the plate 1403. There is no requirement that the entire plate 1403 be fabricated from the same material. However, it will generally be convenient to fabricate at least each of the first and second layers 1412, 1412 from the same material throughout. Thus, the first layer 1412 will typically, in this particular embodiment, be fabricated of a material that is optically transmissive in the frequency range employed in the monitoring technique.
The footprint 1433 of the heating element 1409 is shown in
The heating element 1409 is formed on the plate 1403 and permits a portion of the microfluidic PCR circuit 1406 to be selectively heated. More particularly, in this embodiment, the heating element 1409 heats that portion of the microfluidic PCR circuit 1406 comprising the plurality 1436 of parallel, branching channels 1439. The heating element 1409 will typically employ a resistive heating. To this end, a voltage can be applied across the heating element 1409 to generate a current therethrough, which will generate heat therein that will conduct into the plate 1403. The heating element 1409 can be formed on the plate 1403 using any suitable technique known to the art. In the illustrated embodiment, the heating element 1409 is formed on the plate 1403 using a physical vapor deposition techniques such as is port known to those in the art. However, the heating element 1409 may alternatively be separately fabricating and adhered or fastened to the plate 1403. Any suitable technique known to the art may be used.
In operation, the enzyme 1421 and the DNA and dNTP 1424 are loaded into the ports 1418, 1419, respectively. A continuous flow vacuum is applied through the port 1427 to impart the electrokinetic force to the enzyme 1421 and the DNA and dNTP 1424. The heating element 1409 is heated to the proper temperature so that, when the enzyme 1421 and the DNA and dNTP 1424 mixture enters the plurality 1436 of parallel, branching channels 1439, it can begin the thermal cycling for the PCR reaction. Note that the level of the vacuum is selected so that the mixture remains in the reaction chamber while the PCR reaction occurs. When the PCR reaction is completed, the vacuum is applied once again and the result monitored through the detection window. Detection can be performed by either using continuous flow or just filling the microfluidic channels 1425 and monitoring for clouds of fluorescence. Note that quantitation is possible in this particular embodiment, as port.
The plate 1503 is fabricated in largely the same manner as is the plate 1403 in
The heating element 1509 is also fabricated and employed similarly to the heating element 1409 in
However, the microfluidic PCR circuit 1506 of the embodiment in
The microfluidic PCR circuit 1506 also differs in the number of ports it employs. In addition to the loading ports 1518, 1519 for the enzyme 1521 and the DNA and dNTP 1524, but also a loading port 1530 for a DNA ladder reference 1522 such as is commonly used in the art. In addition to the port 1527 through which a continuous flow vacuum may be applied, the microfluidic PCR circuit 1506 also includes ports 1542, 1543 by which positive and negative load voltages, respectively, may be applied and ports 1544, 1545 by which positive and negative separation voltages may be applied, respectively.
The microfluidic PCR circuit 1506 also differs in the number of ports it employs. In addition to the loading ports 1518, 1519 for the enzyme 1521 and the DNA and dNTP 1524, but also a loading port 1530 for a DNA ladder reference 1522 such as is commonly used in the art. In addition to the port 1527 through which a continuous flow vacuum may be applied, the microfluidic PCR circuit 1506 also includes ports 1542, 1543 by which positive and negative load voltages, respectively, may be applied and ports 1544, 1545 by which positive and negative separation voltages may be applied, respectively.
Turning now to
Once the PCR reaction is complete, a load voltage is imposed on the microfluidic circuit 1506 via the ports 1543, 1542 to impart an electrokinetic force to the mixture. More particularly, a negative load voltage is applied to the port 1543 and a positive load voltage is applied to the port 1542. This imparts an electro-osmotic force such that the mixture travels from the channels 1539 through the channel 1525b and the intersection 1553 to the detection window 1530a on the channel 1525c as indicated by the arrow 1556. (The channels 1525b-1525c are coated in a manner known to the art to help facilitate the electro-osmotic movement.) At this point, fluorescent monitoring can yield detection without separation.
Once the mixture reaches the detection window 1530a, the load voltages are lifted from the ports 1543, 1542 and a separation voltage is imposed on the ports 1545, 1544. More particularly, a positive negative separation voltage is imposed on the port 1545 and a positive separation voltage on the port 1544. (Note that the timing can be determined from the flow rate of the mixture.) This imparts an electrophoretic force on the mixture, causing it to reverser course in the channel 1525c back toward the intersection 1553, as represented by the arrow 1559.
At the intersection 1553, the electrophoretic force turns the mixture into the channel 1525d, as indicated by the arrow 1562, and approaches the intersection 1565. (The channel 1525d is coated in a manner known to the art to help inhibit electro-osmotic movement.) The electrophoretic force turns the mixture into the channel 1525e at the intersection 1565, as indicated by the arrow 1571. The electrophoretic force continues driving the mixture, as indicated by the arrow 1574, to the detection window 1530b. At this point, fluorescent monitoring will yield detection with separation.
The plate 1603 is fabricated in largely the same manner as is the plate 1403 in
The heating element 1609 is also fabricated and employed similarly to the heating element 1409 in
The heating element 1609 and the thermal element 1650 establish a temperature gradient through the first layer 1612. Isothermal lines 1652 (only one indicated), shown in broken lines, illustrate the conduction of heat generated by the heating element 1609 through the first layer 1612 in the presence of the temperature gradient. The material of the first layer 1612 and the temperature gradient dampen the conduction to produce the profile presented. Note that the isothermal lines 1652 are nearly flat at the microfluidic channels 1625, which is desirable so that the microfluidic channels 1652 can heat uniformly. This is one desirable consequence of fabricating the microfluidic channels 1625 toward the bottom of the body structure 1600. Note that, even in the presence of completely flat isothermal lines 1652, the microfluidic channels 1625 will experience 4 C temperature variations within due to Taylor-Ari-like behavior. These heating principles apply equally to those embodiments disclosed in
Note that the various aspects of the disclosed embodiment are but various means by which the associated functionalities may be implemented. For instance, in each of the embodiments shown in
Thus, that aspect of the invention presented in
This concludes the detailed description. The particular embodiments disclosed above are illustrative only, as the invention may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the invention. Accordingly, the protection sought herein is as set forth in the claims below.
This application is a continuation of U.S. patent application Ser. No. 11/398,489, filed Apr. 4, 2006, which claims the benefit of U.S. Provisional Patent Application Ser. No. 60/668,274, filed Apr. 4, 2005, each of which is hereby incorporated by reference for all purposes as if set forth herein verbatim.
Number | Date | Country | |
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60668274 | Apr 2005 | US |
Number | Date | Country | |
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Parent | 11398489 | Apr 2006 | US |
Child | 14691340 | US |