Patent Grant
7198759
The present invention relates to microfluidic devices, and methods and systems using such devices. The present invention relates to devices that manipulate, process, or otherwise alter micro-sized amounts of fluids and fluid samples.
Microfluidic devices are useful for manipulating fluid samples. There continues to exist a demand for microfluidic devices, methods of using them, and systems for processing them, that are fast, reliable, consumable, and that can process many samples simultaneously.
According to various embodiments, a fluid manipulation assembly is provided having two or more recesses separated by one or more intermediate walls. The intermediate wall can be a deformable material, for example, an elastically deformable material, that can be deformed to cause a fluid communication between two or more of the recesses. If the intermediate wall is elastically deformable, it can be made of a material that exhibits less elasticity, that is, is not as elastically deformable or is not as quickly elastically rebounding as the cover layer. According to various embodiments, an elastically deformable cover layer covers at least one of the recesses and contacts the immediate wall when the intermediate wall is in a non-deformed state. The elastically deformable cover layer can be designed not to contact the intermediate wall when the intermediate wall is in the deformed state.
According to various embodiments, a fluid manipulation assembly is provided that includes a recess with two or more recess portions where the recess is at least partially defined by an opposing wall surface portion that includes a deformable inelastic material. The recessed portions are in fluid communication with each other when the deformable inelastic material is in the non-deformed state. The opposing wall surface portion that includes the deformable inelastic material can be deformed to cause a barrier wall between the two recessed portions. The barrier wall can prevent fluid communication between the two recessed portions. An elastically deformable cover layer covers at least a portion of the recess and can cover at least an entire recess. The elastically deformable cover layer can contact the barrier wall when the barrier wall is formed. Various embodiments provide a system including such an assembly and various other components.
According to various embodiments, a deformer can be provided that contacts the elastically deformable cover layer of the assembly and deforms an intermediate wall. The deformer can then retract out of contact with the elastically deformable material layer whereby the layer rebounds to result in a fluid communication between the recesses separated by the intermediate wall. According to various embodiments, the deformer can deform a sidewall portion of a recess to form a barrier wall separating two portions of the recess.
Methods are also provided for deforming an intermediate wall to cause a fluid communication between two or more recesses in a covered substrate. The methods can include contacting an elastically deformable cover layer of an assembly and deforming an intermediate wall underneath the deformed cover layer.
According to various embodiments, methods are provided for forming a barrier wall to interrupt fluid communication between two recessed portions using an assembly and deformer described herein. Methods are provided whereby two or more recessed portions in an assembly as described herein having an opposing wall surface portion of a deformable inelastic material is deformed to form a barrier wall. An elastically deformable cover layer covers at least part of the recessed portion where the opposing wall surface made up of at least the deformable inelastic material is deformable to form a barrier wall. The barrier wall is preferably formed between at least two portions of the recess and interrupts fluid communication between the at least two portions of the recess when in a deformed state. The methods include contacting the elastically deformable cover layer with the deformer and inelastically deforming the deformable inelastic material to form a barrier wall, then allowing the cover layer to elastically rebound. The result can be a contact between the cover layer and the barrier wall after deformation.
According to various embodiments, a microfluidic manipulation system is provided having a fluid manipulating assembly, an assembly support platform, an assembly deformer, and a positioning unit, wherein the positioning unit is adapted to position the deformer relative to the fluid manipulating assembly. When the fluid manipulating assembly is on the assembly support platform, the deformer can be forced to deform the deformable inelastic material through the elastically deformable material layer, to form a fluid communication between the first and second recesses.
These and other embodiments can be more fully understood with reference to the accompanying drawing figures and the descriptions thereof. Modifications that would be recognized by those skilled in the art are considered a part of the present invention and within the scope of the appended claims.
a is a top view of a microfluidic device according to an embodiment wherein two recesses in a substrate are separated by an intermediate wall formed from a deformable inelastic material;
b is a cross-sectional side view of the assembly shown in
a is a top view of the assembly shown in
b is a cross-sectional side view of the assembly and deformer shown in
a is a top view of the assembly shown in
b is as cross-sectional side view of the assembly shown in
a is a top view with partial cutaway of a microfluidic assembly according to an embodiment wherein a substrate is comprised of a recess that can be divided into two recessed portions;
b is a cross-sectional side view of the assembly shown in
a is a top view of the assembly shown in
b is cross-sectional side view of the assembly and deformer shown in
a is a top view of the assembly shown in
b is a cross-sectional side view of the assembly shown in
a is a top view of a disk-shaped fluid manipulating assembly according to an embodiment showing a plurality of radially extending series of recesses in the substrate;
b is an enlarged view of a section of the disk-shaped fluid manipulating assembly shown in
a is a perspective view of a microfluidic manipulation system according to an embodiment wherein a disk-shaped fluid manipulating assembly is disposed on an assembly support platform beneath a deformer fixed to a positioning unit;
b is a side view of the microfluidic manipulation system shown in
a is an enlarged view of a section of the system shown in
b is an enlarged view of a section of the system shown in
Other various embodiments of the present invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention described herein, and the detailed description that follows. It is intended that the specification and examples be considered as exemplary only, and that the true scope and spirit of the invention includes those other various embodiments.
a is a top view of a microfluidic assembly 98 according to an embodiment wherein two recesses 106 and 107 are formed in a substrate layer 100 and are separated by an intermediate wall 108 formed from a deformable material. The material of the intermediate wall can be inelastically deformable or elastically deformable.
If the material of the intermediate wall is elastically deformable, it can be less elastically deformable (have less elasticity) than the material of the cover layer, or at least not as quickly elastically rebounding as the material of the cover layer, whereby the cover layer is able to recover or rebound from deformation, more quickly than the intermediate wall material. Thus, if both the cover layer and the intermediate wall are elastically deformable but to different degrees, the cover layer can rebound from deformation more quickly than the intermediate wall material and a gap can therefore be provided therebetween, that can function as an opening for a fluid communication. For the sake of example, but not to be limiting, the intermediate wall material will be described below as being inelastically deformable.
b is a cross-sectional side view of the assembly 98 shown in
a is a top view of the assembly 98 shown in
As can be seen in
According to various embodiments, the assembly can be disk-shaped, card-shaped, or have any other suitable or appropriate shape, the specific shape being suitably adaptable for specific applications. The device can be shaped to provide a series of generally linearly extending chambers that can be connected to one another according to embodiments of the present invention. For example, series of chambers can be provided in assemblies according to various embodiments whereby centripetal force can be applied to the assembly to move a fluid sample from one chamber of a series to a subsequent chamber in the series, by centripetal force. For example, disk-shaped devices having radially-extending series of chambers are provided according to various embodiments.
The assembly can be sized to be conveniently processed by a technician and can have a length, for example, of from about one inch to about ten inches. Depending upon the number of series of chambers or configuration desired, the assembly can have any appropriate size. Disk-shaped assemblies can have diameters from about one inch to about twelve inches, such as, from about four inches to about five inches. The assembly can have any suitable thickness. The thickness can be from about 0.5 millimeter (mm) to about 1 centimeter (cm) according to some embodiments. A card-shaped rectangular device having a length of from about two inches to about five inches and a width of from about one inch to about three inches, and a thickness of from about 1 mm to about 1 cm is exemplary.
The substrate layer of the assembly can include a single layer of material, a coated layer of material, a multi-layered material, and combinations thereof. An exemplary substrate is made up of a single-layer substrate of a hard plastic material, such as a polycarbonate compact disk.
Plastics that can be used for the assembly, particularly for the substrate, a base layer, a recess-containing layer, or any combination thereof, include polycarbonate, polycarbonate/ABS blends, ABS, polyvinyl chloride, polystyrene, polypropylene oxide, acrylics, polybutylene terephthalate and polyethylene terephthalate blends, nylons, blends of nylons, and combinations thereof. In particular, polycarbonate substrates can be used. The substrate can include a polyalkylene material, a fluoropolymer, a cyclo-olefin polymer, or a combination thereof, for example. One particularly useful material for the substrate is ZEONEX, a cyclo-olefin polymer available from ZEON Corporation Tokyo, Japan.
The entire substrate can include an inelastically deformable material, or at least the substrate includes an intermediate wall that is inelastically deformable. While some elasticity can be exhibited by the intermediate wall, the intermediate wall can preferably become deformed sufficiently to enable fluid communication between the two recesses that the intermediate wall separates. According to various embodiments, the assembly substrate can include a material, for example, glass or plastic, that can withstand thermal cycling at temperatures back-and-forth between 60° C. and 95° C., as for example, are used in polymerase chain reactions. Furthermore, the material should be sufficiently strong to withstand a force necessary to achieve manipulation of a fluid sample through the assembly, for example, centripetal force necessary to spin and manipulate a sample within the assembly.
The substrate layer can include one or more base layers that support and contact the recess-containing layer. The recess-containing layer can be a layer having holes formed therethrough, and a base layer can be included to contact the recess-containing layer and define bottom walls of through-hole recesses in the substrate. The substrate can have the same dimensions as the assembly and can make-up a major portion of the size of the assembly.
According to various embodiments, an assembly is provided with an elastically deformable cover layer, that at least covers portions of the recess-containing substrate layer in areas where a portion of the substrate layer is to be deformed. For example, the cover layer can cover any number of a plurality of chambers serially aligned, or all of the chambers. The cover layer can partially cover one or more chambers, inlet ports, ducts, and the like. The cover layer can have elastic properties that enable it to be temporarily deformed as a deformer contacts and deforms an intermediate wall, for example, underneath the cover layer. Once the deformer is removed from contact with the assembly, the inelastically deformed intermediate wall remains in a deformed state for at least an amount of time sufficient to enable fluid transfer between two or more recesses that are made to be in communication by deformation of the intermediate wall. The inelastically deformable material of the intermediate wall can be elastic to some extent, but if so should remain at least partially deformed after deformation for at least about 5 seconds, for example, for at least about 60 seconds. The intermediate wall can remain deformed for 10 minutes or more, or can be permanently deformable.
The elastically deformable cover layer, on the other hand, has greater elasticity than the intermediate wall and can return substantially to its original state after deformation to thereby result in the formation of a fluid communication between the two or more recesses. The elastically deformable cover layer can more or less return to an original orientation to an extent sufficient to achieve fluid communication between underlying recesses brought into communication by deformation of an intermediate wall. However, the elastically deformable cover layer does not necessarily have to be completely elastic, but should be sufficiently elastic to rebound a distance that is greater than about 25% of its deformed distance, for example, greater than about 50% of its deformed distance. For instance, if the elastically deformable cover layer has a surface that is originally in contact with an underlying intermediate wall, and is deformed at the contact area to be depressed a distance of 1.0 mm in a direction toward the intermediate wall, the elastically deformable cover layer can rebound, at the contact area after deformation, a distance of at least about 0.25 mm in a direction away from the deformed underlying intermediate wall. The elastically deformable cover layer can have an elasticity that enables it to rebound after deformation to about one hundred percent of its original orientation.
The elastically deformable cover layer can be chemically resistant and inert, as can be the substrate layer. The elastically deformable cover layer can be selected to be able to withstand thermal cycling, for example, back-and-forth between about 60° C. and about 95° C., as may be required for polymerase chain reactions. Any suitable elastically deformable film material can be used, for example, elastomeric materials. The thickness of the cover layer should be sufficient for the cover layer to be deformed by the deformer as required to re-shape an intermediate wall beneath the cover layer. Under such deforming, the elastically deformable cover layer should not puncture or break and should substantially return to its original orientation after deforming an underlying intermediate wall.
PCR tape materials can be used as or with the elastically deformable cover layer. Polyolefinic films, other polymeric films, copolymeric films, and combinations thereof can be used, for example, for the elastically deformable cover layer.
The cover layer can be a semi-rigid plate that bends over its entire width or length or that bends or deforms locally. The cover layer can be from about 50 micrometers (μm) to about 100 μm thick and a glue layer, if used, can be from about 50 μm to about 100 μm thick.
The glue or adhesive layer, for example, layer 102 or layer 122 depicted in
The adhesive layer can have any suitable thickness and preferably does not deleteriously affect any sample, desired reaction, or treatment of a sample processed through the assembly. The adhesive layer can be more adherent to the elastically deformable cover layer than to the underlying inelastically deformable material, and can rebound with the elastically deformable cover layer.
According to various embodiments, the intermediate wall can have a height that is about equal to the depth of the deepest recess it separates. The top of the intermediate wall can be flush with the top surface of the recess-containing layer of the assembly. The intermediate wall can be formed by forming recesses in a uniform thick substrate layer whereby an intermediate wall results between the two formed recesses. The intermediate wall can be of sufficient height in a non-deformed state to contact and form a fluid-tight seal with the elastically deformable cover layer, thereby preventing fluid communication between two recesses separated by the intermediate wall. The intermediate wall can entirely be made-up of, or include only a portion that is, a deformable material. According to various embodiments, only a portion of the intermediate wall is deformed to cause a fluid communication between two recesses that the intermediate wall separates.
Assemblies according to various embodiments can include two or more recesses or chambers separated by an intermediate wall, and inlet and/or outlet ports to access the recesses or chambers. Inlet and outlet ports can be provided through a top surface of the assembly, through a bottom surface of the assembly, through a side edge or end edge of the assembly, through the substrate, through the cover layer, or through a combination of these features. For example, the assembly can include an inlet port through an elastically deformable cover layer and in communication with a first chamber of the assembly. The assembly can include an outlet port through the elastically deformable cover layer and in communication with a second chamber of the assembly. The inlet port can be designed for loading sample into the second chamber by capillary action, by gravity, by force such as elevated pressure or centripetal force, and the like. The outlet port can be designed to enable venting of gas from the second chamber, that is displaced by sample that enters the second chamber. The outlet port can be designed to enable extraction of a sample from the second chamber, for example, as by capillary action, pipetting, gravity-induced drainage, force such as centripetal force, elevated pressure, or the like. Extraction can be useful, for example, for further analysis of the extracted sample or for re-use of the assembly.
According to various embodiments, an assembly is provided that instead includes, or further includes, a recess having an inelastically deformably wall portion that can be deformed to make a barrier blocking communication between two portions of the recess. The entire side wall of the recess, or only a portion of the sidewall, can include inelastically deformable material. Such an embodiment is exemplified in
a is a top view with partial cutaway of a microfluidic assembly according to an embodiment wherein a substrate is comprised of a recess that can be divided into two recessed portions.
b is a cross-sectional side view of the assembly shown in
a and 5b show the deformer positioned at the initiation of an opposing wall surface portion-deforming step, and the contact surface of the deformer advancing toward the deformable opposing wall surface portions.
a and 6b show the assembly shown in
In
Similar constructions materials, dimensions, and other properties described with reference to
As shown in
According to various embodiments, the assembly can be provided with series of chambers that can be made in communication with adjacent chambers or blocked from adjacent chambers, according to deforming methods. The assemblies can include linear series of multiple chambers, that can optionally include differently sized channels for connecting, and blocking communication between, adjacent chambers. The chambers, channels, or both, can each independently be empty, loaded with a reactant, agent, solution, or other material, or be provided with, for example, filtration media and/or frits. The assembly can be provided with an inlet or entrance port for each series of reaction chambers, and can include a plurality of reaction chambers. Exemplary assemblies can include 48 or 96 series of reaction chambers, with each series having an independent inlet port. One or more outlet ports for each series of chambers can be provided or formed in the assembly before or after a sequence of treatments or reactions occur through the series, for example, according to various embodiments. An exemplary configuration includes a splitter to divide a sample through a series of chambers whereby a portion of the sample continues along a first flowpath and involves a forward sequencing reaction, and the remainder of the sample follows a second flowpath and involves a reverse sequencing reaction. In such splitting configurations, two respective outlet ports can be provided in product collection wells for analysis of forward-sequenced and reverse-sequenced products. The various chambers of the series according to various assemblies can be of different sizes and capacities. For example, purification chambers can have longer lengths and larger capacities than sequencing reaction chambers and a polymerase chain reaction chamber can have double the capacity of the forward-sequencing and the reverse-sequencing chambers. A PCR chamber can be provided in a series according to various embodiments, wherein the PCR chamber is preloaded with PCR reactants sufficient to enable a desired amplification of a nucleic acid sequence.
The series of chambers can include one or more purification chambers, for example, a purification downstream of a PCR chamber and prior to one or more sequencing reaction chambers. An additional, or alternative embodiment provides an assembly whereby one or more purification chambers are provided downstream of one or more respective sequencing reaction chambers in a series of chambers. If sequencing reaction chambers are provided, they can be preloaded with sequencing reaction reactants that enable a desired forward, reverse, or both forward and reverse sequencing reaction or group of reactions. Other pre-loaded components can include buffers, marker compounds, primers, and other components as would be recognized as suitable by those skilled in the art.
Different levels and layers of channels and chambers can be included in assemblies according to various embodiments. For example, a tiered, multi-channel assembly can be provided that includes flow pathways that traverse different heights or levels in the substrate. An assembly including a tiered three-channel series is illustrated with reference to
According to various embodiments, a system is provided that includes a support for supporting an assembly according to various embodiments, and a deformer that contacts the supported assembly and deforms at least one intermediate wall, at least one deformable side wall, or any combination thereof, of the assembly. The system can be provided with a positioning unit for registering the area of the assembly to be deformed, with the deformer. Precision positioning drive systems can be used to enable the deformer and the assembly to be moved relative to one another such that the feature of the assembly to be deformed is aligned and registered with the deformer.
According to various embodiments, the deformer can have any of a variety of shapes, for example a shape that leaves an impression in the inelastically deformable material that results in a fluid communication or a barrier wall breaching communication, between two recesses or recessed portions of the assembly. The deformer can have an opening blade design that, when contacted with an assembly in a deforming step can form a communication between two recesses of the assembly by deforming an intermediate wall that separates the two recesses. A straight edge, chisel-edge, or pointed-blade design, for example, can be used to form a trough or other channel for providing a fluid communication between the two recesses.
According to embodiments wherein the deformer includes one or more features that deform an inelastically deformable sidewall of a recess into a barrier wall. For example, a deformer having two points that contact the assembly on opposite sides of a fluid communication channel, can be used to deform the sidewalls of the channel adjacent the deformer points and thereby cause the formation of a dam or barrier wall between the two portions of the recess resulting from the deformation.
The deformer can include, for example, both a closing feature and an opening feature that together can simultaneously interrupt a communication and form a new communication in a single deforming action.
The system according to various embodiments can include a variety of deformers, for example, one or more opening blade deformer and one or more closing blade deformer. Such systems can be used in connection with processing assemblies that include at least one series of chambers, one or more of which is in fluid communication with another, and one or more of which is separated from another by a barrier wall. More details about various systems are set forth below.
According to various embodiments, methods are provided for forming a fluid communication between two recesses of an assembly having at least two recesses separated by at least one intermediate wall. The method includes inelastically deforming the intermediate wall to form a fluid communication between the at least two recesses. More specifically, the method includes contacting the elastically deformable cover layer of the assembly with a deformer, and forcing the assembly and deformer into contact under sufficient force to deform the intermediate wall with the deformer, through the elastically deformable cover layer. After inelastic deformation of the intermediate wall, the deformer is removed from contact with the elastically deformable cover layer and the elastically deformable cover layer returns to its original, pre-deformed, shape. The resulting structure of the assembly thereby changes to cause a space between the elastically deformable cover layer and the underlying, deformed, intermediate wall. The intermediate wall can be in contact with the elastically deformable cover layer, to form a fluid-tight seal, when the intermediate wall is in a non-deformed state.
According to various embodiments, methods are provided for forming a barrier wall to interrupt fluid communication between two recessed portions of an assembly according to various embodiments. According to such methods, at least one of the two recessed portions is partially defined by or has a sidewall made of an inelastically deformable material that can be deformed into the shape of a barrier wall between the two recessed portions of the assembly. According to such embodiments, a closing blade configuration can be used with a deformer to effect the formation of the barrier wall. The barrier wall can be made by the deformation of opposing side walls of a recess or of at least one recessed portion of two communicating recessed portions.
According to various embodiments, after an assembly has been deformed to form a fluid communication or to form a barrier wall, the deformed assembly can then be treated or processed to achieve a product, for example, a reaction product or a purification product. Methods of manipulating the flow of fluids and other components within various chambers of a series of chambers can be effected by, for example, centripetal force, electrical forces such as are used in electrophoresis or in electroosmosis, pressure, vacuum, gravity, centripetal force, capillary action, or by any other suitable fluid manipulating technique, or combination thereof. As a result of a fluid manipulation step, the manipulated fluid can be reacted in a newly-entered chamber, for example, by polymerase chain reaction under thermal cycling conditions, by a sequencing reaction under specified thermal conditions, by purification, and/or by any combination of treatments.
According to various embodiments, a microfluidic manipulation system is provided having a fluid manipulation assembly, an assembly support, a deformer, and a positioning unit. The fluid manipulation assembly can be any of the assemblies desired herein, for example, an assembly that has a substrate layer, at least two recesses formed in the substrate layer, and at least one intermediate wall wherein the intermediate wall separates a first recess from a second recess, and the intermediate wall includes a deformable inelastic material. The deformer can contact a surface of the assembly, with the cover layer in between, that is more resistant to deformation than the deformable inelastic material of the intermediate wall. The positioning unit is adapted to position the deformer relative to the fluid manipulating assembly, when the fluid manipulating assembly is supported by the assembly support, such that the deformer can be forced to deform the deformable inelastic material to form a fluid communication between the first recess and the second recess.
A further feature is a microfluidic manipulation system having a fluid manipulating assembly, an assembly support platform, a deformer, and a positioning unit, where the fluid manipulating assembly has a substrate layer and at least one recess formed in the substrate layer and having a first portion and a second portion in fluid communication with one another in a non-deformed state of the assembly. The recess is at least partially defined by one or more recess wall surface that includes a deformable inelastic material.
The system can be configured to enable the deformer to deform the deformable inelastic material to form a barrier wall between the first recess portion and the second recess portion. A barrier can be produced that can, for example, prevent fluid communication between the portions when the barrier wall is in a deformed state.
The deformer can have one or more contact surface that is more resistant to deformation than the deformable inelastic material. The positioning unit of the system can be adapted to position the deformer relative to the fluid manipulating assembly, when the fluid manipulating assembly is on the assembly support platform. The deformer can include a closing blade and can be manipulated to be forced to deform the deformable inelastic material into a barrier wall. The barrier wall can be of sufficient dimensions to interrupt fluid communication between the two recessed portions of the assembly.
The systems can be provided with an appropriate control unit to control the relative positioning between the deformer and an assembly supported by the assembly support. The control unit can include programmable software, hardware, or both, that can control positioning, control the deforming action of the deformer, and control the application of fluid manipulating forces to an assembly supported by the assembly support. For example, the control unit can control rotation and the application of centripetal force to an assembly, including, starting rotation, ending rotation, and the rate of rotation during the actuation period. Suitable controls including registration systems are taught, for example, in PCT published Application No. WO 97/21090 and WO 99/34920, which are hereby incorporated in their entireties by reference. Such electronics can be housed in a singular unit and the unit can be housed in an assembly, for example, along with heating devices, centripetal force devices, supports, and other components as would be recognized by those skilled in the art.
The control unit can also be controllable to selectively decide between various pathways of fluid flow through assemblies according to various embodiments. All, or many, of the method steps used according to various embodiments can be controlled by the control unit. The control unit can be programmed, for example, to carry out a sequence of steps such as a spinning step, a deforming step, a heating step, a deforming step, a purification step, and a sample collection step, in sequence.
In the foregoing various embodiments, the deformer, positioning unit, and the assembly support platform, can be replaced by various other means for deforming, means for positioning, and means for supporting the assembly, respectively.
According to various embodiments, a system is provided that can include an apparatus that analyzes, sequences, detects, or otherwise further treats, processes, or manipulates a sample or reaction product in an assembly as described herein. Various analyzers, detectors, and processors that can be used include: separation devices, including electropheretic, electroosmotic, or chromatographic devices; analyzing devices, including nuclear magnetic resonance (NMR) or mass spectroscopy devices; visualizing devices, including autoradiographic or fluorescent devices; recording or digitizing devices, such as a camera, a personal computer, a charged coupled device, or x-ray film; or any combination of the above apparati.
According to exemplary method embodiments involving the use of a system as described herein, a sample can be treated as follows. First, a sample reagent, or wash solution, can be dispensed into an inlet port or inlet chamber of an assembly as described herein. Dispensing can be accomplished by a robot, or manually, at any suitable time during the process, for example, at the beginning of the process. A sample access hole can be provided. The assembly can be spun to move fluid sample from one chamber to an adjacent chamber through a fluid communication. Spinning can be used to force fluid through a purification medium. Fluid communications between various chambers can be selectively opened and closed through the deforming steps described herein to effect fluid transfer or fluid isolation. Mixing of fluid can be accomplished by a variety of means, for example, an external ultrasonic actuator or by oscillating a stepper motor. Time and temperature controls can be provided so that the assembly can be subjected to an incubation period. Heating elements and cooling elements can be provided as part of a temperature control unit.
The methods can also include detecting a product processed in an assembly as described herein using a method and system as described herein. Detection can be accomplished by a system described herein or by implementing any of various independent detection systems.
Processed fluids can be preserved in the assembly, stored, or removed from the assembly, for example, by pipetting or washing-out.
The opening blade 144 of
Due to the deformation of the substrate 160 upon deforming contact of the substrate with any of the closing blade configurations 158, 166, and 168 results in a bulging deformation that causes a barrier wall to form, interrupting communication between the two portions of communication 162 that become separated by the barrier wall. The closing blades 158, 166, and 168 can have a variety of sizes. For example, the cutting portions 159, 165, and 169 of the closing blades 158, 166, and 168, respectively, of
a is a top view of a disk-shaped fluid manipulating assembly according to an embodiment showing a plurality of radially extending series of recesses in the substrate.
According to various embodiments as shown in
The microfluidic assembly according to an embodiment as shown in
a is a perspective view of a microfluidic manipulation system according to an embodiment wherein a disk-shaped fluid manipulating assembly 220 is held by supports 229 and 256 and disposed on an assembly support platform 231 beneath a deformer 255 fixed to a positioning unit 230.
In
Referring to
As mentioned above, centripetal force is used to force the sample 303 from chamber 302 into PCR chamber 306. As shown in
After the assembly is subjected to sufficient thermal cycling for PCR in the PCR chamber 306, an initially blocked or closed PCR outlet channel 308 is opened as shown in
As shown in
After the assembly is subjected to conditions that cause the forward and reverse sequencing reactions, the sequencing reaction chamber outlet channels 318 and 319, which are initially blocked or closed, are opened, which occurs in region 525 shown in
b depict a system according to various embodiments. The system 410 includes an electronics unit 412, a rotating platen 414, a heating assembly 416, a cover 418, and an enclosure basin 420. The device 410 also includes an assembly processing unit 370 shown in
The assembly processing component 370 includes a tray loading door 372, the electronics 412, a valve actuator 376, and two heaters 377 and 378. The component 370 shown particularly in
In the methods depicted in
Further details regarding microfluidic devices, for example, devices having geometrically parallel processing pathways, and systems and apparatus including such devices or for processing such devices, are described in U.S. patent application Ser. No. 10/336,706 to Desmond et al., filed Jan. 3, 2003, entitled “Microfluidic Size-Exclusion Devices, Systems, and Methods”, and in U.S. patent application Ser. No. 10/336,330 to Desmond et al., filed Jan. 3, 2003, entitled “Micro-Channel Design Features That Facilitate Centripetal Fluid Transfer”, both of which are herein incorporated in their entireties by reference.
Those skilled in the art can appreciate from the foregoing description that the broad teachings of the present invention can be implemented in a variety of forms. Therefore, while this invention has been described in connection with particular embodiments and examples thereof, the true scope of the invention should not be so limited. Various changes and modification may be made without departing from the scope of the invention, as defined by the appended claims.
The present application claims the benefit of U.S. Provisional Patent Applications Nos.: 60/398,851 and 60/398,946, both filed Jul. 26, 2002, and both of which are incorporated herein in their entireties by reference. Cross-reference is also made to U.S. patent application Ser. Nos. 10/336,706 and 10/336,330, both filed Jan. 3, 2003, both of which are also herein incorporated in their entireties by reference.
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