APPARATUS AND METHODS FOR MICROFLUIDIC APPLICATIONS
Non-rigid tape apparatus and fabrication methods for microfluidic processing applications such as gel electrophoresis are provided, where microfluidic processing is performed on selected areas. Parts of the tape are formed by high pressure plastic film forming. Membranes and other structures are self sealing during and after penetration by pipettes and electrical probes. Rigid exoskeleton elements protect the non-rigid parts during processing and facilitate transport of the tape.
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This invention relates to fabrication and processing technology for microfluidic applications in chemical and biological processing and analysis, in particular fabrication and application of non-rigid apparatuses optionally in the form of a tape.
In the field known as “lab-on-a-chip”, electronic, microfluidic and bio processes are combined at chip scale to bring dramatic productivity and cost benefits to fields as diverse as high throughput screening, bio-molecular assays and point of care diagnostics.
Fabrication technologies are known that have been developed in the microelectronics industry and then applied to biotechnology and biomedical industries. However, compared to electronic based devices, biotechnology devices are much more diverse in order to enable the manipulation of a large variety of bio materials, fluids and chemicals. Improvements in performance, throughput and cost have been achieved by reducing the size and volume in miniaturised biosystems.
These “Lab-on-a-chip” solutions have increased the amount of functionality per apparatus by miniaturisation. The problem with increased miniaturisation is the complexity of smaller scale processing and the large cost of equipment for microfabrication. Furthermore, conventional lithographic and etching processes adopted from the microelectronics industry require rigid apparatuses.
Glass apparatuses for microfluidic applications are known, such as the LabCHIP from Caliper Technologies Corp (Mountain View, Calif.), U.S. Pat. No. 6,274,089. The glass apparatus is attached to a plastic moulded cartridge which incorporates wells for loading test samples, reagents and gel.
Rigid plastic apparatuses are known, such as the LabCard from Aclara Biosciences Inc (Mountain View, Calif.), U.S. Pat. No. 6,103,199. A tooling process involving patterning and electroplating is used to create embossed microchannels on the card surface.
“Lab-on-a-CD” devices such as from Gamera and Gyros use centrifugal force of a rotating disk as the microfluidic pumping mechanism, e.g., Gamera Bioscience Corporation (Medford, Mass.), U.S. Pat. No. 6,063,589.
The above are all discrete devices which require further handling steps for continuous operation. They are also inefficient for single test operation.
Silicon apparatuses are known, such as the Nanogen chip, which is a microfluidic microarray device, where the microarray is selectively doped with biological or chemical probes which can be polarised electrically to attract or repel molecules from the sample material under test.
For example, U.S. Pat. No. 5,858,195 to Lockheed Martin Energy Research. Corporation (Oak Ridge, Tenn.) describes a microchip laboratory system and method to provide fluid manipulations. The microchip is fabricated using standard photolithographic procedures and etching, incorporating an apparatus and rigid cover plate joined using die bonding. Capillary electrophoresis and electrochromatography are performed in channels formed in the apparatus. Analytes are loaded into a four-way intersection of channels by electrokinetically pumping the analyte through the intersection.
These approaches require time consuming additional steps of picking and placing discrete apparatuses which increases the overall processing cycle time in microfluidic applications.
“MicroTape™—A 384 Well Ultra High Throughput Screening System” Journal of the Association for Laboratory Automation, May 1999: Volume 4, Number 2, p. 31, Astle, T. W., teaches of a tape device designed for storage of liquid compounds in smaller volumes (typically 10 ul) than the industry standard 96 or 384 well micro-titer plate (MTP). Tape storage is in a pattern identical to a 384 well MTP. In effect, MicroTape™ is an alternative passive storage medium to the micro-titer plate.
The primary features of MicroTape™ are:
1) bulk compounds typically stored in 96 or 384 well micro-titer plates can be transferred into a smaller volume storage medium, i.e. the MicroTape™, and then stored within the medium for future use at low temperature. When this array of compounds is required for test, only one section of tape (i.e. a 384 well section) need be retrieved and defrosted, rather than the whole of the bulk compound medium.
2) the MicroTape™ incorporates a separate sealing membrane to protect the compound during storage. This membrane is capable of being de-sealed and re-sealed.
3) use of MicroTape™ for Polymerase Chain Reaction (PCR) processing. The concept takes a reel/roll of MicroTape™ and uses alternate immersion in hot and cold water tanks to perform thermal cycling for the PCR process.
The limitations of this approach are:
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- It's well capacity is 10 ul which is much larger scale than lab-on-a-chip.
- It is not patterned microfluidic channels.
- It is not analytical, i.e. does not incorporate gels or analytes through which molecular separation or purification can be accomplished.
- It is not electrically active, i.e. incorporating electrical elements or interfacing with electrical elements i.e. it is simply a carrier.
- The PCR processing is performed on the whole reel rather than on selectable areas or segments of the tape.
In the contemporary art of gel electrophoresis, including the emerging field of miniaturised systems, a common means of detection is to capture an image of these layers using electro-optical means. A convenient method is to use a 2 dimensional CCD (Charged Coupled Device) detector array (an area array) to capture the appearance of the permeation layer area in a single “snapshot” image. Another convenient method is to use a 1 dimensional CCD array (a line array) and move it relative to the permeation layer such that the full image is built up from many adjacent line images.
It would be advantageous to provide an apparatus for microfluidic applications that allowed an increased area for microfluidic processing, without requiring an increase in miniaturisation and the associated complexity of processing.
It would be further advantageous to provide an apparatus for microfluidic applications that facilitated loading and transport of analytes and reagents both during and after apparatus fabrication.
It would be further advantageous to provide an apparatus that allowed continuous processing of a moving apparatus.
It would be further advantageous to provide an apparatus that allowed a variable area on one apparatus, while using a fixed size of apparatus handling mechanism.
It would further be advantageous to integrate information storage and management systems within or on the apparatus for use with simple detection methods.
It is an object of at least one aspect of the present invention to provide an apparatus for microfluidic applications.
It is a further object of at least one aspect of the present invention to allow an increased area for microfluidic processing and novel dynamic processing steps both within and of the apparatus, while using simple fabrication processes and apparatus handling techniques.
In this document, a probe is defined as including mechanical probes, electrical probes and pipettes for fluidic manipulation.
In this document, indexing patterns are defined as including patterns for facilitation mechanical movement, detection of position, detection of movement, and display and recording of information.
In this document, mass transport is defined as transport of mass relative to the apparatus.
According to a first aspect of the present invention, there is provided an apparatus for microfluidic processing applications, wherein said microfluidic processing is performed on a selected area of a plurality of areas each individually selectable on said apparatus, characterised in that the apparatus is non-rigid.
According to a second aspect of the present invention, there is provided an apparatus for mass transport microfluidic processing applications, characterised in that the apparatus is non-rigid.
According to a third aspect of the present invention, there is provided an apparatus for microfluidic processing applications, characterised in that the apparatus comprises at least one rigid member and at least one non-rigid member.
Preferably the apparatus comprises at least two non-rigid members.
Preferably said non-rigid member is a tape.
Preferably there are a plurality of rigid members each associated with one of a plurality of areas each individually selectable on said apparatus.
Preferably said rigid member comprises access ports.
According to a fourth aspect of the present invention, there is provided a method of fabrication of an apparatus for microfluidic processing applications, comprising the step of attaching at least one rigid member to at least one non-rigid member.
Preferably said method of fabrication further comprises the step of forming at least one non-rigid member.
Preferably said step of forming said at least one non-rigid member comprises the step of high pressure plastic film forming with said high pressure acting on said apparatus.
Alternatively said step of high pressure plastic film forming is arranged with the high pressure acting on a compliant membrane, which is part of a forming tool in contact with said apparatus.
Preferably said rigid member has a maximum dimension perpendicular to its plane greater than the maximum dimension perpendicular to the plane of said at least one non-rigid member.
According to a fifth aspect of the present invention, there is provided a method of mounting an apparatus for microfludic processing applications, comprising the step of attaching said apparatus to a non-rigid carrier that is in the form of a tape.
Preferably said carrier has a maximum dimension perpendicular to its plane greater than the maximum dimension perpendicular to the plane of said apparatus.
Preferably said apparatus is attached to said non-rigid carrier by snap fitting into apertures in said carrier.
Alternatively said apparatus is attached to said non-rigid carrier by ultrasonic welding, heat sealing, adhesive, chemical or molecular bonding.
Preferably said apparatus is a tape.
Preferably said apparatus comprises a polymer film.
Preferably said apparatus comprises processing elements for microfluidic processing.
Typically said processing elements comprise indents of said apparatus.
Optionally said processing elements comprise cavities embedded within said apparatus.
Optionally said processing elements comprise processing materials in intimate contact with the surface of said apparatus.
Optionally said processing elements comprise processing materials embedded within said apparatus.
Optionally said processing elements comprise opaque, translucent or coloured materials for providing optical isolation between elements or providing indexing marks.
Preferably an element of said apparatus is transparent.
Preferably a member of said apparatus is transparent.
Preferably said apparatus is penetrable.
Preferably said apparatus is self sealing during penetration.
More preferably said apparatus is self sealing after penetration.
Preferably said apparatus further comprises an impermeable membrane.
Preferably said impermeable membrane is affixed in intimate contact with parts of the surface of said apparatus.
Alternatively said impermeable membrane is arranged as discrete areas of impermeable membrane in intimate contact with parts of the surface of said apparatus.
Preferably said impermeable membrane is penetrable.
Preferably said impermeable membrane is self sealing during penetration.
More preferably said impermeable membrane is self sealing after penetration.
Optionally said impermeable membrane is re-sealed by a capping element after penetration.
Preferably said impermeable membrane is supported by support structures.
Preferably said apparatus further comprises a non-rigid member.
Preferably said non-rigid member is affixed in intimate contact with parts of the surface of said apparatus.
Alternatively said non-rigid member is arranged as discrete areas of non-rigid member in intimate contact with parts of the surface of said apparatus.
Preferably said non-rigid member is penetrable.
Preferably said non-rigid member is self sealing during penetration.
More preferably said non-rigid member is self sealing after penetration.
Optionally said non-rigid member is re-sealed by a capping element after penetration.
Preferably said non-rigid member is supported by support structures.
According to a sixth aspect of the present invention, there is provided a method of fabrication of an apparatus for mass transport microfluidic processing applications comprising the step of forming an apparatus that is non-rigid.
According to a seventh aspect of the present invention, there is provided a method of fabrication of an apparatus for mass transport microfluidic processing applications comprising the step of fabricating a tape.
Preferably said step of forming said apparatus comprises the step of high pressure plastic film forming with said high pressure acting on said apparatus.
Alternatively said step of high pressure plastic film forming is arranged with the high pressure acting on a compliant membrane, which is part of the forming tool in contact with said apparatus.
Optionally said step of fabricating said apparatus further comprises the step of preloading processing materials onto said apparatus before fabrication.
Optionally said step of fabricating said apparatus further comprises the step of loading processing materials onto said apparatus during fabrication.
Typically said step of preloading or loading during fabrication of said apparatus comprises the step of depositing processing materials onto a carrier.
Typically said step of preloading or loading during fabrication of said apparatus comprises the step of depositing processing material onto a non-rigid member.
Preferably said deposited processing material comprises permeation layers.
Alternatively said deposited processing material comprises conductive material.
Alternatively said deposited processing material comprises chemically or biologically active material.
Alternatively said deposited processing material comprises marks for identity purposes.
Alternatively said deposited processing material comprises magnetisable material.
Preferably said step of depositing comprises printing.
Alternatively said step of preloading or loading during fabrication of said apparatus is performed by a preloading or loading process selected from a list of processes comprising: deposition and etching, injection into a cavity and injection into an indentation.
Preferably said method of fabrication of said apparatus further comprises the steps of depositing patterns on an apparatus and forming said apparatus, wherein the localised formation of said processing elements is responsive to the distortion by said forming of said deposited pattern.
Preferably said method of fabrication of said apparatus further comprises the steps of depositing patterns on an apparatus and localised formation of said apparatus is responsive to the topography of said deposited pattern, resulting in the formation of said processing elements.
Preferably said step of depositing comprises pre-printing.
According to an eighth aspect of the present invention, there is provided a method of fabrication of an apparatus for mass transport microfluidic processing applications, comprising the step of including an impermeable membrane as part of said apparatus.
Preferably said step of including an impermeable membrane comprises the step of affixing an impermeable membrane to a substrate.
Optionally, said step of including an impermeable membrane comprises the step of depositing, overlaying or affixing discrete areas of impermeable membrane in intimate contact with parts of the surface of said apparatus.
Optionally, said step of including an impermeable membrane comprises the step of depositing, overlaying or affixing an impermeable membrane on said apparatus and selectively removing areas of said impermeable membrane.
Optionally, said selected removal of said impermeable membrane is performed by the step of cropping.
According to a ninth aspect of the present invention, there is provided a method of fabrication of an apparatus for mass transport microfluidic processing applications, comprising the step of including a non-rigid member as part of said apparatus.
Preferably said step of including a non-rigid member comprises the step of affixing a non-rigid member to a substrate.
Optionally, said step of including a non-rigid member comprises the step of depositing, overlaying or affixing discrete areas of non-rigid member in intimate contact with parts of the surface of said apparatus.
Optionally, said step of including a non-rigid member comprises the step of depositing, overlaying or affixing a non-rigid member on said apparatus and selectively removing areas of said non-rigid member.
Optionally, said selected removal of said non-rigid member is performed by the step of cropping.
According to a tenth aspect of the present invention, there is provided a method of microfluidic processing, comprising the steps of selecting an area of a plurality of areas of an apparatus and performing microfluidic processing at said selected area, characterised in that said apparatus is non-rigid.
Optionally said step of performing microfluidic processing comprises contacting at least one conducting element that connects the exterior of said apparatus to the interior of said apparatus.
Preferably said method further comprises the step of providing an electrical potential to at least one conducting element.
Preferably said method further comprises the step of enabling an electrical current to pass through said least one conducting element.
Preferably said apparatus is a tape.
Preferably said microfluidic processing is mass transport microfluidic processing.
Preferably said microfluidic processing is responsive to the deformation of said apparatus.
Preferably said deformation comprises deformation by a step selected from a list of steps comprising: bending, flexing, folding, twisting, conforming to a rigid surface, mechanical deformation, deformation by applying a sound pressure, deformation by applying a liquid pressure, and deformation by applying a gas pressure.
Typically said gas pressure is a negative pressure.
Optionally said deformation may further comprise the step of bringing part of said apparatus back into contact with another part of itself.
Alternatively, said step of deformation further comprises the step of bringing a part of said apparatus into contact with another apparatus.
Optionally said deformation of said apparatus comprises the step of moving part of said apparatus into a position for processing of said part of said apparatus.
Typically said position for processing is a position with said apparatus in contact with a processing tool.
Preferably said microfluidic processing is responsive to said deformation of said apparatus, said microfluidic processing being selected from a list comprising pumping, filling, pouring, pressurising, mixing, dispensing, aspirating, separating, combining, heating and cooling.
According to an eleventh aspect of the present invention, there is provided a method of processing for microfludic processing applications, characterised in that the processing comprises the step of piercing an impermeable membrane.
Preferably said step of piercing an impermeable membrane is performed with at least one probe.
Optionally said at least one probe comprises at least one pipette.
More preferably said method of processing further comprises the step of providing an electrical potential to at least one conducting probe that has pierced said membrane.
Alternatively said step of processing further comprises the step of enabling an electrical current to pass through at least one conducting probe that has pierced said membrane.
According to a twelfth aspect of the present invention, there is provided a method of processing for microfludic processing applications, characterised in that the processing comprises the step of piercing an apparatus.
Preferably said apparatus is self sealing during said step of piercing.
Preferably said apparatus is self sealing after said step of piercing.
Optionally said apparatus is re-sealed by a capping element after penetration.
Preferably said step of piercing the apparatus is performed with at least one probe.
Optionally said at least one probe comprises at least one pipette.
More preferably said method of processing further comprises the step of providing an electrical potential to at least one conducting probe that has pierced said apparatus.
Alternatively said step of processing further comprises the step of enabling an electrical current to pass through a conducting probe that has pierced said apparatus.
According to a thirteenth aspect of the present invention, there is provided an apparatus for microfluidic processing applications, characterised in that the apparatus is a non-rigid tape comprising a plurality of indexing patterns.
Preferably said indexing patterns are rigid members.
Preferably said indexing patterns are repeated.
Preferably said indexing patterns are arranged to facilitate detection of position.
Typically said indexing patterns are arranged to facilitate detection of position using optical detection.
According to a fourteenth aspect of the present invention, there is provided a method of transporting a tape apparatus for microfluidic applications comprising the step of moving said apparatus by interaction of a moving object with at least one rigid member attached to said apparatus.
In order to provide a better understanding of the present invention, an embodiment will now be described by way of example only and with reference to the accompanying figures in which:
The invention is a non-rigid apparatus for microfluidic processing applications, which may be in the form of a tape. The use of a non-rigid apparatus allows novel dynamic processing methods. The incorporation of re-sealable impermeable layers allows further novel dynamic processing steps.
The apparatus includes a supporting layer 251, a formed pattern layer 265 with a machine readable index mark 254. The pattern layer has formed cavities 266 and a connecting channel 267 filled with gel. The exoskeleton 2915 supports plugs 3124 that are used for re-sealable access to the cavities.
A DC voltage in the range 5 to 500 Volts (typically 100V/cm has been found to be suitable) will be applied across negative terminal 252 and positive terminal 253. This will cause the negatively charged DNA sample 3430 to migrate into the gel column 267 and its constituent molecules will then separate into bands in accordance with their molecular weight. An image of the band pattern will be captured by a commercial CCD camera and the image processed and presented to the user on a computer screen.
The electrical terminal pads 252 and 253 are conveniently presented for perpendicular access by external contact pins whose engagement will be controlled by the tape processing instrument. The exoskeleton 2915 may be conveniently employed as the tape transport means, and be driven by, for example, a toothed belt or a drive pinion having the same tooth pitch as the test segments on the tape.
The CCD image capture system can also conveniently capture the test segment ID mark, thus avoiding the need for a separate device such as a bar code reader.
The processing elements may comprise geometries which have sloping, curved or stepped surfaces. The processing materials may be conformal layers in intimate contact with surfaces of the apparatus. The processing elements may be opaque, translucent or coloured in order to provide optical isolation between elements or, alternatively, to provide indexing marks for allowing detection of movement and position of the apparatus.
Several of the processing elements shown in
The processing materials can be gases, liquids, solids or semi-solids, e.g. biomolecular samples, fragments of DNA, biochemical polymers, chemical polymers, biomolecular modifiers, catalysts, antibodies, polypeptide molecules, protein molecules, biological organisms such as cells and viruses and permeation layers. The permeation layers may be solid, semi-solid, liquid, viscous, gelatinous or gaseous layers. The permeation layers may be biomolecular gates which are activated by electrical probes. The function of the biomolecular gates is defined by their particular depth, shape, volume and composition.
The apparatus contains another processing element 33, where the membrane is configured as a flap 34, such that the cavity is sealed when the unattached end of the membrane is in contact with the apparatus 35.
Another processing element 44 shows the impermeable membrane 45 in intimate contact and attached to the apparatus at the left hand side 46 and configured as a flap in a sealing contact with the right hand side 47 of an indent in the apparatus 48. This flap may be opened by deforming the apparatus in the same way as described as above with reference to processing element 36.
In another processing element 49, the impermeable membrane 410 is deposited as a plug in an indent resulting in a cavity 411, the membrane again providing an hermetic seal.
Alternatively, the impermeable membrane is continuous with the tape (i.e. not discrete). This continuous configuration can also embody local flaps in the membrane and still be one continuous membrane.
Large areas of membrane would tend to bend on attempted insertion of a probe.
Another useful structure is a circular indent but still connected to adjacent processing elements and an externally configured loop or coil of wire (or other conducting element) around that circular indent. The electrical/magnetic field created can be used to attract or trap or process the liquid in the circular indent.
A “U” shaped pillar 66 is shown and a probe that enters in the centre of the “U” at point 67, marked with a plus, may be connected to a probe penetrating the impermeable membrane at the second penetration point 68 by an electrical, liquid or permeation path that is greater in length than the direct distance between the two penetration points.
Turning
With reference to
With reference to
With reference to
Firstly, raw material preparation is provided, 141, the primary material will be a flexible substrate, preferably in the form of a continuous tape but other substrates, membranes, films, mouldings, skeletal structures or pre-assembled microfluidic devices may be part of the fabrication “kit”.
Patterns can be pre-printed 142, preferably on a flat plastic non-rigid substrate. These patterns may be conductive elements, chemically or biologically active zones, magnetisable zones, or printed marks for identity purposes.
The apparatus, 143, is formed using high pressure thermo-forming with the high pressure acting on the apparatus or the high pressure acting on a compliant membrane which is part of the forming tool that is in contact with the apparatus. The high pressure may be delivered by a gas or a fluid. During forming, the pre-printed patterns on the tape surface may be distorted in response to the topography of the formed processing elements. The final position of the pre-printed pattern material may be predicted by calibration test runs or simulation in order to design pre-printed patterns that distort to create processing elements that comprise the processing material that has been pre-printed. Alternatively, the forming of an apparatus may be performed by stereolithography or selective laser sintering. While forming the apparatus by stereolithography or selective laser sintering, processing elements may be included in the apparatus either by direct patterning or in response to the topography of the pre-printed patterns on the carrier.
The fabrication of the apparatus can further comprise the step of preloading processing materials 144. These processing materials may be preloaded by processes such as printing, film deposition and etching, stereo-lithography, injecting into a cavity and also injection into an indentation. Alternatively, the preloading may be achieved by tilting the apparatus with respect to gravity in order to open flaps of impermeable membrane so as to introduce processing materials through the open flaps into underlying structures. Alternatively these flaps may be opened by the distortion of the apparatus, such as conforming it to a rigid roller or corner.
A cropping operation 145 can be incorporated (optionally before the preloading step) to insert apertures in a substrate or finish a substrate to a defined external profile.
Apparatus assembly can continue, 146, by attachment or assembly of other layers, for example, a sealing layer or sealing layers, or sealing plugs, or additional supporting layers to improve the robustness of the apparatus, or other pre-assembled devices. The attachment methods may include a mechanical snap-fit, a mechanical interference fit, ultrasonic welding, heat sealing, molecular, chemical or adhesive bonding. Typically the final layer of apparatus that is affixed results in one or more impermeable membranes as part of the apparatus. Alternatively, the membranes may be formed by depositing, overlaying or affixing discrete areas of impermeable membrane in intimate contact with parts of the surface of the apparatus. Alternatively the formation of the impermeable membrane may be performed by depositing a film of impermeable membrane across the apparatus and selectively removing areas of the impermeable membrane. This selective removal may be performed using cropping/blanking or by lithography, such as photolithography, for patterning combined with wet or dry etching. These membranes are optionally formed of homogeneous apparatus material in the case of formation using stereo-lithography or selective laser sintering.
The apparatus can incorporate a further loading sequence, 147, of chemical or biological agents such as solvents, electrolytes, gels, stainers, dyes, affinity tags or bio-sensors. This loading may be achieved by pipette probe through the apparatus membrane or through an access port or access ports in the apparatus.
These steps 141 to 147 have many possible permutations and
In each of
With reference to
Additionally, with reference to
Additionally, where the substrate is configured to have more than one discrete permeation layer in a transverse line across the substrate, each of these more than one discrete permeation layers can be imaged simultaneously.
In the emerging field of biological micro-arrays, the processing substrates are typically comprised of a rigid transparent material (e.g. a glass slide) and whereby bio-material is deposited locally on a rectangular grid whose pitch may be in the range of 50 um to 2 mm. The present invention provides the advantage that it is equally suitable as a substrate for micro-array fabrication but offers the benefit of having low fabrication cost and a capability for continuous processing due to the flexible nature of the apparatus in its form as a continuous tape.
With reference to
The apparatus is thus configured to provide an improved degree of containment for any reaction process which is specified to take place on that micro-array element and that this improved degree of containment can allow operations of mixing, stirring or agitation which would not be achievable with planar micro-arrays.
The apparatus is configured such that this shallow well has a thin wall section 174 (e.g. 0.1 mm, compared to a glass slide of typically 1 to 3 mm) that enables the efficient coupling of a conductive heating element 175 (for example a peltier device or similar) to the well for the purpose of, for example, hybridisation of a DNA sample at a temperature in the range of, for example, 60 to 80 degrees centigrade.
This thin wall section can readily be transparent and that this enables the efficient coupling of an optical system 175 to detect the bio-reaction state of any element on the micro-array.
The apparatus can also have different regions functionalised for the attachment of chemical or biological moieties such as affinity tags or biological probes. Within a microfluidic channel, there can be micro-zones incorporating reactive groups for highly specific functions, e.g. an affinity tag such as a streptavidin coated zone.
With reference to
The apparatus is non-rigid in that it is pliant, unlike rigid apparatuses known in the prior art that are made of at least one layer of hard plastic or glass or silicon, or where the composite apparatus is rigid. On deformation of the apparatus according to the present invention, the apparatus can return to its original shape (i.e. flat) after deformation. The apparatus may have a bend radius approaching zero.
The apparatus is a tape in that it is substantially longer than it is wide in its larger two dimensions. Hence it is a substantially continuous, narrow, flexible strip. The tape 13 may be arranged in a reel-to-reel arrangement between reels or rollers 14 and 15.
With extreme deformation, the apparatus may be folded and remain folded. This may be facilitated by using perforations or indentations to weaken the fold line. Thus the apparatus may be folded into a fanfold arrangement 16 for storage, dispensing and processing.
The tape can also be separated into short discrete sections 17. The separation may be performed by guillotining or tearing across perforations or indentations in the tape.
A continuous strip of tape 18 may be arranged around rollers 19 into a conveyor belt arrangement. A twist in the tape would provide a Moebius strip arrangement.
The apparatus may be formed from a polymer film, that is a thermoplastic polymer film, thermosettable polymer film, elastomeric polymer film or hybrid compositions of each of these films.
In another embodiment, the tape comprises three primary construction elements as illustrated with reference to
The substrate and its chemical contents may be protected by the attachment of a cover seal 192 membrane. The combined substrate and cover seal will be attached to a carrier layer 193 whose function is to protect the substrate from mechanical stress or damage during handling, shipment, storage or end user processing. The tape may be a one time use consumable item.
The tape assembly employs construction materials, fabrication techniques and packaging methods that ensure that the tape will function reliably at its final point of use. The tape will therefore be unaffected by:
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- Automated and manual handling processes prior to shipment packaging (factory);
- Automated and manual handling processes at the point of use (end user);
- Shipment transport (protected by secondary packaging);
- Transport temperatures of −40 C to +70 C (up to 24 hours);
- Storage temperatures of 0 C to +40 C (up to 12 months);
- Relative humidity in range 10% to 90% (transport and storage); and
- Atmospheric pressure (air cargo).
The substrate comprises a thin polymer membrane with a thickness of 50 um preferred, but 125 um for some applications. The thickness may be selected to match available commercial film grades.
The substrate has:
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- Forming radius equal to thickness without stress cracking;
- Feature width to depth ratio, typically in range 2:1 to 1:1;
- Uniform (consistent) draw during forming.
Thermal assist during (or prior to) forming is desirable. Forming may be:
-
- 1) high pressure in range 1 bar to 200 bar
- 2) Vacuum
- 3) high pressure with vacuum assistance
All of these may benefit from a pre-heating cycle.
Desirable features of the substrate include:
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- stable after forming (having no shape memory effects
- Flexible, non rigid, non brittle;
- Abrasion Resistant;
- Punchable, to create optional holes for mechanical indexing;
- Penetratable by probe (e.g. for liquid delivery or for electrical probing);
- High optical clarity;
- Adaptable via suitable surface modification to minimise static charge or to locally influence hydrophilic/hydrophobic surface characteristics;
- Chemical Resistance to Aqueous solutions
- Analyte material loaded in the substrate channels typically comprised of Agarose or Polyacrylamide;
- Provide bio-compatible surface (e.g. DNA, proteins, cells, bacteria etc);
- Avoid leeching of metals, anti-oxidants and stabilisers;
- Capable of receiving a heat sealable cover layer e.g. polyester/polyethylene cover layer; and
- Printable with ink, stroke widths down to 0.1 mm.
Auxiliary coatings, or deposited layers on the substrate include:
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- Local conductive tracking;
- Local hydrophobic coatings (e.g. PTFE);
- Local hydrophilic coatings (eg titanium oxide); and
- Bio-compatible coatings (e.g. parylene).
The seal 192 may be a single or composite layer but a dual composite construction may be beneficial in that the outer layer can be specified to resist the thermal affects of the heat sealing tool whereas the inner layer is able to melt and create a seal without putting the integrity of the membrane at risk. Properties of the seal layer include:
It is preferred that the seal be suitable for penetration by a probe (typically 0.5-1 mm diameter) e.g. for liquid delivery or for electrical probing. A self healing or re-sealable penetration hole is preferred.
Pre-forming of the seal (schematically as in
The carrier layer 193 can comply with EIA-481-B (Electronic Industries Alliance), the standard for “Embossed carrier Taping” for automated component handling in the electronic industries. A preferred material is either black or translucent polystyrene, preferred thickness is in the range 100 um to 300 um. This layer will be formed prior to assembly of the substrate/cover such that the substrate/cover will be contained within a recessed channel in the carrier tape and thereby avoid contact with any other surfaces during manufacture or distribution (e.g., in a reel), or at point of use.
The primary functions of the carrier layer are a) to provide a mechanically robust carrier for the more fragile substrate/cover layers b) incorporate punched holes which provide a means of transport drive for the tape c) incorporate registration features which align the substrate/cover layer with the punched drive holes d) incorporate apertures which allow the channels in the substrate to be visible from underneath the tape.
With reference to
With reference to
With reference to
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For the preferred embodiment, a single segment of tape will be described below, comprising the means of processing one discrete test sample of bio-material such as DNA.
High pressure thermoforming is preferably used to create formed cavities 266, connecting channels 267, optional side channels 268, primary access ports 269 and secondary optional access ports 2610. Shallow channels 2611 provide entry slots for the conductive tracks 252, 253. Typical relative depths of these formed features is illustrated in typical section
The exoskeleton material is preferably a rigid polymer such as polycarbonate, ABS, polyester, polystyrene, polyethylene, polymethyl methacrylate, polypropylene or other co-polymers of these materials. This exoskeleton will be typically 1.0 mm thick but other thicknesses in the range 0.5 mm to 3 mm may be used.
The test segment has now been pre-loaded ready for use, and will be shipped in this condition to the point of use. The only “wet chemistry” at the point of use is to load the test sample for analysis.
The exoskeleton incorporates access ports which can be oriented longitudinally (e.g. port no. 3431) or perpendicularly (e.g. port no. 3432). Optionally port 3432 can be used to vent any unwanted build up of gas in the lower cavity.
These fabrication methods can create features which provide a wide range of processing options at the point of use.
With reference to
During these steps the fabricated apparatus with its optional preloaded processing materials may be deformed in order to cause dynamic processing. The apparatus may be deformed by bending, flexing, folding, twisting, conforming to a rigid surface, mechanical deformation, deformation by applying a sound pressure, deformation by applying a liquid pressure, and deformation by applying a gas pressure. Optionally the deformation can result in the bringing of a part of the apparatus back into contact with another part of itself or with another apparatus. The deformation may move part of the apparatus into a position for processing, including being in contact with a processing tool. The deformation of the apparatus results in dynamic processing that includes pumping, filling, pouring, pressurising, mixing, dispensing, aspirating, separating, combining, heating and cooling.
Apparatuses that include impermeable membranes facilitate further novel processing methods that involve the impermeable membrane. The membrane may be pierced by one or more probes. These probes may be pipettes.
Conducting probes that have pierced the membrane may provide an electrical potential, and used for passing an electric current through the conducting probe into a conducting medium.
Optionally a grid of probes are mounted on a discrete carrier or a continuous carrier that can be indexed or replaced, such that another set of probes can be used after the first set has worn out.
The grid of probes may be configured such that each probe is separately addressable and each probe may have a separate voltage applied in order to progressively move the processing material through processing elements, such as indented troughs and permeation layers in the apparatus, after the grid of probes has penetrated or contacted a corresponding grid of impermeable membranes. This arrangement can be used to move process materials through permeation layers for molecular separation. The controlled and progressive switching of voltages on the grid of probes can be used to split processing material into more than one separate processing path through more than one separate processing elements. These split process materials may be further combined or different process materials may be combined at the junctions of paths through the apparatus. In this way, the grid of electrical probes can be configured to apply voltages that cause a multi-dimensional separation of molecules, e.g. polypeptide or protein molecules.
If the probes are pipettes, processing materials may be introduced into the apparatus through the impermeable membranes that have been penetrated or processing materials removed from within the apparatus. An array of pipettes compatible with 96, 192, 384, 1536 or 3456 well assay plates can be matched to an array of commensurately spaced impermeable membranes for penetration by the array of pipettes. Probes that penetrate or touch the surface of a membrane can cause processing to be performed, such as pumping, filling, pouring, pressurising, mixing, B dispensing, aspirating, separating, combining, heating, cooling, movement by electrokinesis, movement by electrokinesis, movement by the molecular entrapment method of molecular tweezers, acoustic tweezers and bio-molecular motor principles.
An apparatus in the form of a tape may be transported through processing equipment and handling equipment by friction of, for example, rollers in contact with the apparatus or by pinions inserted into indents or perforations in the apparatus in a similar manner to the handling of photographic or cine film. Alternative methods of moving the tape include sliding drawers and walking beams. Moving the apparatus with electromagnetic fields and induction within the apparatus or moving using air or fluid pressure applied to the apparatus are also possible.
The position of the apparatus in response to movement is detected by measurement of indexing patterns. After movement dynamic processing can be performed and then further repeated movement and dynamic processing steps can be performed in a continuous fashion as the continuous tape is indexed through the processing equipment.
In conclusion, we present the advantages of the present invention.
A significant and long-established traditional art for some of the kinds of bio-molecular separation described herein is commonly referred to as “slab gel electrophoresis”. The demands in material usage, process time, operator time and workspace for this process are recognised by those with even minor experience of this art. The procedure commonly employs manual preparation of gels involving mixing, heating and casting steps. Although the method can now employ pre-cast gels to provide some degree of improvement, the overall process remains manually intensive and inefficient.
In contrast, the present invention offers significant advantages, by miniaturising all the elements of this traditional process and eliminating many of the material preparation and manual processing tasks.
While the traditional processes remain in common use, new art is emerging which includes miniaturised bio-analysis systems employing chip-scale technology, micro-fluidics, and semiconductor fabrication techniques.
The present invention provides advantages over both traditional and emerging techniques.
The present invention provides very significant savings in materials, time and workspace over traditional gel electrophoresis methods.
The present invention provides an adaptable platform for a very wide range of bio-analysis processes (not just gel electrophoresis) and employs geometric patterning, tooling methods and fabrication methods which are much less complex than other emerging micro-fluidic or chip scale techniques. This allows rapid and cost effective production of multiple versions of tape to match the range of applications anticipated.
The present invention allows bio-sample processing in a range from one single simple test up to highly parallel and multiple complex tests in an uninterrupted continuous serial or parallel mode. The former is attractive to small research laboratories, many quality control laboratories, and point of care clinics. The latter is attractive to high throughput processing laboratories. A combination of these processing methods is attractive to public health hospitals and clinics whose demand can fluctuate significantly. This range of capability is provided in one single effective and efficient platform regardless of usage patterns.
The present invention configures processing elements on a highly flexible substrate and enables a versatile range of substrate indexing patterns and transport methods to be utilised as described.
Additionally, these transport methods provide the advantage of allowing the use of non complex, compact, low cost optical scanning means by the embodiment of a fixed position transverse optical line-scanning system whose focal plane is along a line across the width of the substrate. The scanning function is provided by the (already provided) indexing motion of the substrate.
This highly flexible substrate also enables the other described features and advantages which result from bending, folding, twisting, flexing and deforming its geometry.
The substrate flexibility also allows it to be penetrable by probes for the purposes of processing material delivery or removal, electrical connection and process tooling introduction.
Additionally this flexible substrate is suitable for affixing a secondary impermeable membrane which is also readily penetrable by suitable probes for the purposes of processing material delivery or removal, electrical connection, process tooling introduction.
The penetrable substrate and penetrable membrane provides a processing system which can be fully enclosed and which can provide some processing materials pre-loaded within the system. This minimises preparation, avoids spillage, avoids the need for cleaning or flushing procedures and simplifies waste disposal.
Alternatively, a stereo-lithographic method is described to fabricate the substrate and the impermeable membrane in one homogenous material with the advantage that this simplifies the means of construction.
Alternatively, a selective laser sintering method is described to fabricate the substrate and the impermeable membrane in a single fabrication process again with the advantage that this simplifies the means of construction.
The present invention employs one generic material type in its construction (polymer) and avoids the significant use of glass, silicon or metal in its fabrication. This simplifies the waste disposal methods after bio-processing is complete.
The fabrication techniques described provide a wide range of substrate geometries. These features can be created by rapid and simple methods of tooling, thus avoiding the long lead times and complexity of other miniaturised bio-processing systems.
The present invention has the advantage that these rapid and simple fabrication techniques correspond to processing elements whose dimensional accuracy is less critical than those of chip scale devices. A corresponding advantage is that this is achieved without sacrifice to the overall device size because the device size, in the current state of the art, is determined by the practicalities of the size of the sample loading wells and not by the processing element sizes.
The present invention can be enhanced by pre-printing processing materials onto a planar plastic film substrate using commercially available printing methods and then by deforming that substrate in a non planar fashion such that the pre-printed material deforms into a desired shape or position and such that, for example, a pre-printed permeation layer can subsequently (after forming of the substrate) be hydrated into its gelatinous phase.
Related printing and forming methods are already established in the field of foil manufacture for “in-mould decoration” of plastic injection moulded products (used for cosmetic effect mainly on consumer electronic products), but the present invention provides the scope for adapting these methods into this unconnected field of application.
The flexible substrate is readily available in a range of polymer materials whose optical properties can be matched to available commercial optical systems for detection or imaging of the bio-processing events during system operation.
Further modifications and improvements may be added without departing from the scope of the invention herein described.
Claims
1-73. (canceled)
74. A microfluidic processing apparatus comprising a non-rigid member provided with at least one microfluidic processing area and a support member adapted to extend across the at least one microfluidic processing area, the support member being provided with at least one access zone for loading and/or unloading the microfluidic processing area of the non-rigid member, wherein the support member provides local rigidity proximate to the microfluidic processing area of the non-rigid member.
75. The microfluidic processing apparatus of claim 74 wherein the access zone is penetrable.
76. The microfluidic processing apparatus of claim 74 wherein the access zone is sized to be penetrable by a sample loading probe.
77. The microfluidic processing apparatus of claim 76 wherein the sample loading probe comprises a pipette tip.
78. The microfluidic processing apparatus of claim 74 wherein the at least one access zone is provided with at least one access port.
79. The microfluidic processing apparatus of claim 74 wherein the non-rigid member is formed from a single thin polymer film and provided with shallow channels and deep cavities on the non-rigid member so as to provide microfluidic and macro fluidic capabilities.
80. The microfluidic processing apparatus of claim 74 wherein microfluidic processing can be enabled by incorporating conductive layers directly on to the non-rigid member.
81. The microfluidic processing apparatus of claim 80 wherein the conductive layers are configured to act from one side of the apparatus only, thus allowing the other side of the apparatus to be available for other means of detecting microfluidic reaction processes.
82. The microfluidic processing apparatus of claim 74 wherein the at least one access zone is positioned to provide access to an end of the microfluidic processing area.
83. The microfluidic processing apparatus of claim 74 wherein the at least one access zone is positioned to provide access to an end edge of the microfluidic processing area at one or more positions along its length.
84. The microfluidic processing apparatus of claim 74 wherein the support member is affixed to the non-rigid member by means of a snap-fit connection.
85. The microfluidic processing apparatus of claim 74 wherein the support member is affixed to the non-rigid member by an adhesive.
86. The microfluidic processing apparatus of claim 78 wherein the access port is provided with a replaceable seal.
87. The microfluidic processing apparatus of claim 86 wherein the replaceable seal is a plug.
88. The microfluidic processing apparatus of claim 74 wherein the support member is made from a polymer film.
89. The microfluidic processing apparatus of claim 74 wherein the support member has a thickness between 0.5 mm and 3 mm.
90. The microfluidic processing apparatus of claim 74 comprising a plurality of support members and a plurality of microfluidic processing areas contained on the non-rigid member, wherein one support member extends across one microfluidic processing area.
91. The microfluidic processing apparatus of claim 74 wherein the support member is further provided with coupling means to allow attachment of the support member to a drive means.
92. The microfluidic processing apparatus of claim 91 wherein the coupling means comprises a plurality of apertures adapted for engagement with the drive means.
93. The microfluidic processing apparatus of claim 74 wherein the non-rigid member consists of a layer of deformable tape, the microfluidic processing area thereon being formed by deformation of the layer of deformable tape.
94. The microfluidic processing apparatus of claim 93 wherein the deformable tape is constructed from a polymer film.
Type: Application
Filed: Sep 30, 2008
Publication Date: Jan 22, 2009
Applicant:
Inventors: Stuart Polwart (Stirlingshire), Joel Fearnley (Peeblesshire), Douglas Roy (Edinburgh), Peter Ghazal (Edinburgh)
Application Number: 12/242,547
International Classification: G01N 27/00 (20060101); B01J 19/00 (20060101);