1. Field of the Invention
The invention relates to assay equipment. More particularly, the invention relates to a system having a liquid transport structure for use with assay equipment.
2. Background of the Invention
A variety of assays have been developed for detecting the presence of one or more target agents in a liquid. This liquid is often prepared from a sample that is believed to have the target agent. The sample must often be transported from a site where the sample is obtained to a laboratory where the assay is performed. An undesirable amount of time is often associated with transporting the sample to the laboratory. As a result, there is a need for an assay system that can be performed in the field.
The invention relates to an apparatus for use with assay equipment. The apparatus includes a liquid transport structure having a reservoir configured to hold a liquid within the liquid transport structure. The apparatus includes an outlet channel configured to transport a liquid held in the reservoir to a chamber within the liquid transport structure.
Another embodiment of the apparatus includes a liquid transport structure configured to hold a sensor for detecting one or more components in a liquid. The liquid transport structure includes a reservoir configured to hold a liquid within the liquid transport structure and a channel configured to transport a liquid held in the reservoir to a sensor held by the liquid transport structure. The liquid transport structure can also include an inlet channel extending from an external side of the liquid transport structure to the reservoir.
In some instances, the liquid transport structure includes a first member positioned over the sensor and a second member positioned under the sensor. The first member and/or the second member can include a base and a cover. The base and the cover can each define a portion of the reservoir.
The liquid transport structure can be removably coupled with an interface system that provides liquid communication between the reservoir and one or more tubes. In some instances, the liquid transport structure is configured to be clamped between two or more members of the interface system.
The liquid transport structure can hold a sensor structure that includes the sensor positioned on a sensor support. In some instances, the sensor structure is configured to be removed from the liquid transport structure. The sensor structure can include a plurality of sensors positioned on the sensor support. Further, the liquid transport structure can define a plurality of reservoirs that are each configured to hold a liquid within the liquid transport structure. The liquid transport structure can also include a plurality of channels that are each configured to transport a liquid from a reservoir to a sensor on the sensor structure.
The sensor can include a plurality of electrodes positioned on the sensor support. The electrodes can include a reference electrode and a counter electrode that are each spaced apart from a working electrode.
The invention also relates to a sensor having an electrode support with a first support region spaced apart from a second support region. One or more electrodes are positioned on the first support region and one or more of the electrodes positioned on the second support region. In some instances, a working electrode is positioned on the second support region, a reference electrode is positioned on the first support region and a counter electrode is positioned on the first support region.
The invention also relates to a method for performing an assay. The method includes changing the pressure on a liquid stored in a reservoir of a liquid transport structure. The pressure is changed such that at least a portion of the liquid flows from the reservoir onto a sensor held by the liquid transport structure. The pressure can be changed by increasing pressure in an inlet channel extending from an external side of the liquid transport structure to the reservoir and/or by reducing pressure in an outlet channel extending from the reservoir to a chamber formed over the sensor.
Another embodiment of the method includes applying one or more liquids to a sensor such that a target agent bonds to the sensor along with one or more non-target agents. The sensor is configured to detect a component in a liquid and includes two or more electrodes positioned on a sensor support. The method also includes removing non-target agents from the sensor. Removing the non-target agents can include flowing a liquid across the sensor. The liquid can be flowed across the sensor so as to generate a shear flow pattern on the sensor. In some instances, a liquid transport structure defines a chamber over the sensor and flowing the liquid across the sensor includes flowing the liquid through the chamber.
The invention relates to a liquid transport structure for use with an assay. The liquid transport structure holds one or more sensors for the detection of a component in a liquid. A suitable sensor is an electrochemical sensor including a plurality of electrodes formed on a sensor support. These sensors can have a compact size that is suitable for use with small volumes of liquid.
The liquid transport structure can include inlet channels that each extend from an outside surface of the liquid transport structure to a reservoir located inside of the holder. The liquid transport structure can also include a plurality of outlet channels that are each configured to carry a liquid from a reservoir to a sensor held within the liquid transport structure. Liquids that are to be employed during an assay can be stored in each of the reservoirs or delivered into the reservoirs from an outside source. Each liquid can be transported onto the sensor at the desired time. The ability to store these solutions in the reservoir allows the liquid transport structure to be used in the field.
The liquid transport structure can be interfaced with assay equipment such as pumps, vacuums and valves for controlling the flow of liquid from the reservoirs. The liquid transport structure can be constructed so as to be easily coupled with the assay equipment and easily removed from the assay equipment. As a result, different liquid transport structures can be used with the assay equipment. Accordingly, the liquid transport system provides a wide range of flexibility.
The sensor 10 includes a plurality of electrodes 12 positioned on an electrode support 14. The electrode support 14 includes a first support region 16 spaced apart from a second support region 18. One or more tether members 20 immobilize the position of the first support region 16 relative to the second support region 18. Although the first support region 16 is shown as surrounding the second support region 18, the first support region 16 need not surround the entire second support region 18.
A reference electrode 22 and a counter electrode 24 are spaced apart from one another on the first support region 16. A working electrode 26 is formed on the second support region 18. A portion of the working electrode 26 extends from the second support region 18 across a tether member 20 to the first support region 16. As will be illustrated below, the portion of the working electrode 26 positioned on the first support region 16 can serve as a contact pad.
The sensor 10 can be constructed such that the largest dimension of the working electrode 26 is less than 1 μm, 10 μm, 50 μm, 100 μm, 1 mm or 10 mm. Suitable widths for the counter electrode 24 and the reference electrode 22 include, but are not limited to, widths less than 1 μm, 10 μm, 100 μm, 500 μm, 0.1 mm, 1 mm or 5 mm. Suitable dimensions for the gap between the working electrode 26 and the reference electrode 22 and/or between the working electrode 26 and the counter electrode 24 include, but are not limited to, gaps less than 0.1 μm, 10 μm, 50 μm, 200 μm, 0.5 mm or 2 mm. These dimensions can provide for a sensor 10 having a compact size that is suitable for use in on site assay equipment.
Suitable materials for the sensor 10 support include, but are not limited to, plastics, polymers, glass, silicon substrates and metals. Suitable material for the working electrode 26 include, but are not limited to, gold, silver, copper, platinum, chromium, aluminum, titanium, nickel and conducting polymers. Suitable methods for forming the electrodes 12 on the electrode support 14 include, but are not limited to, lift-off processes with photolithography, thin film deposition with shadow mask and thin film foil pressing.
The sensor structure 28 includes the sensor 10 illustrated in
The electrodes 12 of a sensor 10 are formed directly on the sensor support 30. Accordingly, the sensor support 30 serves as the electrode support 14 disclosed with respect to
Although
Although the working electrode 26 is shown above as having a round shape, the working electrode 26 can have a variety of other shapes including, but not limited to, rectangular shapes, triangular shapes and wedge shapes as illustrated in
During operation of a sensor 10, one or more liquids are transported onto the sensor 10. In some instances, a liquid positioned on the sensor structure 28 is washed off the sensor structure 28 and replaced with a different liquid. A liquid transported onto the sensor structure 28 can be confined to the working electrode 26 in the shape of a drop 36 as shown in
The sensors 10 described above can be operated as electrochemical sensors 10. For instance, the one or more liquids transported onto a sensor 10 are selected so as to bond a target agent to the sensor 10 and/or to the sensor support 30. Examples of target agents include, but are not limited to, DNA strands, proteins, small molecules and cells. A target DNA strand can be bonded to the sensor 10 by bonding a DNA strands with a complementary region to the sensor 10 and then transporting onto the sensor 10 a liquid containing the target DNA strand. Further, bonding to the sensor 10 antibodies that specifically bind to the target cell and then transporting onto the sensor 10 a liquid containing the target cell can serve to bond a target cell to the sensor 10. As noted above, one or more liquids are transported onto the sensor 10 so as to bond the target agent to the sensor 10 and/or to the sensor support 30. Examples of methods for bonding various components to the sensor 10 and/or the sensor support 30 are described in U.S. patent application Ser. No. 09/848,727, filed on May 3, 2001, entitled “Biological Identification System with Integrated Sensor Chip” and incorporated herein in its entirety.
Once the target agent has been bonded to the sensor 10, a sample to be tested for the presence of the target agent is prepared by transporting onto the sensor 10 a liquid contains one or more first components that interact with the target agent so as to produce a second component in the sample. In some cases, the target agent can be modified by a signal agent to react with the first component. The sample is tested by applying a potential between the working electrode 26 and the reference electrode 22 while monitoring current passing through a circuit that includes the working electrode 26, the sample and the counter electrode 24. The potential applied between the working electrode 26 and the reference electrode 22 is raised to a level sufficient to cause electron transfer between the working electrode 26 and second component that diffuses from the target agent to the working electrode 26. In some case, the electron transfer between the target agent and the working electrode 26 can be monitored. The electron transfer allows current to flow through the circuit. A current flowing through the working electrode 26 and the counter electrode 24 indicates that the target agent is present in the sample while the lack of current indicates that the component is not present in the sample. Because the first component interacts with the target agent to produce the second component in the sample, the presence of the second component in the liquid indicates the presence of the target agent. In some instances, the direct electron transfer between the target agent and the working electrode 26 is monitored instead of monitoring the secondary components.
Because the sensors 10 illustrated above can be operated as electrochemical sensors 10, coulometric, amperometric and/or voltametric methods can be employed to quantify the concentration of the target agent in the sample.
The sensor 10 described above can be operated using other methods. For instance, the target agent can also be the component that diffuses to the sensor 10 and transfers electrons with the working electrode 26.
A variety of mechanisms are available for constraining a liquid to the working electrode 26 or over each of the electrodes 12. For instance, when the surface of working electrode 26 is elevated relative to the sensor support 30 as shown in
Elevating one or more electrodes 12 relative to a sensor support 30 can be achieved by selecting an electrode support 14 with the desired thickness. Alternatively, a trench can be etched between the working electrode 26 and the reference electrode 22, between the working electrode and the counter electrode 24, around the outside of the reference electrode 22 and/or around the outside of the counter electrode 24. When the sensor structure 28 is constructed as shown in
Other mechanisms are available for constraining a liquid to a sensor 10. For instance, all or a portion of the upper surface of the sensor support 30 can be hydrophobic. In some instances, the portion of the upper surface between the reference electrode 22 and the working electrode 26 and between the counter electrode 24 and the working electrode 26 is hydrophobic. An aqueous liquid transported onto the working electrode 26 will remain constrained on the working electrode 26 until enough liquid is transported onto the working electrode 26 to overcome the hydrophobic nature of the upper surface and cross over the gap between the working electrode 26 and the reference electrode 22 and/or the gap between the working electrode and the counter electrode 24. Accordingly, the hydrophobic nature of the upper surface can serve to constrain a drop of the liquid to the working electrode 26.
When the portion of the upper surface located outside of the counter electrode 24 and the reference electrode 22 is also hydrophobic, an aqueous liquid transported onto the sensor structure 28 is driven onto the reference electrode 22, the counter electrode 24 and the working electrode 26. Accordingly, the hydrophobic nature of the upper surface can serve to constrain a drop of the liquid to the reference electrode 22 and the counter electrode 24.
A variety of techniques can be employed to create a hydrophobic sensor support 30. For instance, the sensor support 30 can be constructed of a hydrophobic medium such as most plastics and polymers. Alternatively, the sensor support 30 can be constructed of a medium having a hydrophobic coating or treatment. Glass and silicon are examples of media that are suitable for use with hydrophobic coating.
In some instances, the exposed surfaces of the working electrode 26, the reference electrode 22 and/or the counter electrode 24 are hydrophilic. The hydrophilic nature of the electrodes 12 serves to draw the liquid onto the electrodes 12. Accordingly, the hydrophilic nature of the electrodes 12 can serve to constrain liquid to the working electrode 26, the reference electrode 22 and/or the counter electrode 24.
A variety of techniques can be employed to create one or more hydrophilic electrodes 12. For instance, an electrode 12 can be coated with a hydrophilic medium. As an example, a working electrode 26 constructed of gold can have a protein coating.
The sensor support 30 can include a well as shown in
A sensor structure 28 can be included in a liquid transport structure 50 for use in transporting a liquid to one or more sensors 10 included on the sensor structure 28.
The liquid transport structure 50 includes a first member 52 and a second member 54 configured to hold the sensor structure 28. The first member 52 and the second member 54 each include a base 56 and a cover 58. A suitable material for the first member 52 and the second member 54 includes, but is not limited to, acrylic plastics and polymers. In some instances, the liquid transport structure 50 has a compact size that is suitable for use in the field. For instance, the liquid transport structure 50 can have a volume less than 26 cubic inches, less than 16 cubic inches, 4 cubic inches or 1 cubic inch. Examples of suitable dimensions include, but are not limited to, a block that is about 2 inch by 1 inch by 0.5 inch, 2 inch by 2 inch by 1 inch or 4 inch by 4 inch by 1 inch.
The liquid transport structure 50 can employ a variety of mechanisms for immobilizing the components of the liquid transport structure 50 relative to one another. For instance, registration or alignment pins (not shown) can extend through the liquid transport structure 50 to keep the various components immobilized relative to one another. Each pin can extend through first member 52, the sensor structure 28 and the second member 54. The use of pins allows the liquid transport structure 50 components to be separated from one another although other mechanisms may permanently immobilize the various components of the liquid transport structure 50. Additionally or alternatively, the components of the liquid transport structure 50 can be immobilized using techniques such as ultrasonic bonding, welding and gluing with registration and alignment geometry on each component. Although the liquid transport structure 50 is shown as having a substantially block shape structure, the liquid transport structure 50 can have a variety of different shapes.
The portion of the sensor structure 28 having the pads 34 extends from the liquid transport structure 50. As a result, the sensor structure 28 can be interfaced with a coupler that connects the sensor structure 28 to electronics configured to operate each sensor 10 so as to detect a component in the liquid.
The first member 52 can include one or more reservoirs 60. Each reservoir 60 is configured to hold a liquid to be transported to one or more sensors 10 located on the sensor structure 28. The cross section shown in
The sensor structure 28 and the first member 52 define an assay chamber 64 over the sensor 10. An outlet channel 62 extends from the reservoir 60 to the assay chamber 64 through the first member 52. In some instances, the outlet channel 62 is sized so the surface tension of a liquid in the reservoir 60 prevents the liquid from flowing out of the reservoir 60 under the action of gravity. A vent channel 68 extends through the first member 52 to the assay chamber 64. The vent channel 68 can be employed to vent the assay chamber 64 when liquid flows into and/or out of the assay chamber 64. Additionally, a waste channel 70 extends from the assay chamber 64 through the sensor structure 28 and through the second member 54. The waste channel 70 can be employed as an outlet for excess liquid or as an outlet for wash fluids when a liquid is washed off a sensor 10.
During operation of the liquid transport structure 50, a positive pressure is applied to a liquid in the reservoir 60 so as to transport the liquid through the outlet channel 62 into the assay chamber 64. The pressure can be sufficient to transport the liquid through the outlet channel 62, into the assay chamber 64 and onto the sensor 10. The positive pressure can be generated by increasing the pressure in the inlet channel 66 and/or by sealing the waste channel 70 while decreasing the pressure in the vent channel 68.
The reservoir 60 can be positioned below the sensor structure 28 as shown in
Each reservoir 60 can include more than one outlet channel 62 extending to an assay chamber 64. Increasing the number of outlet channels 66 can reduce the amount of pressure that is require to drive a liquid out of a reservoir 60 an into that assay chamber 64. In some instances, different outlet channels can extend from the same reservoir to different assay chambers.
The liquid transport structures 50 illustrated above can be combined to provide a liquid transport structure 50 having a reservoir 60 positioned over the sensor structure 28 and a reservoir 60 positioned under the sensor structure 28 as illustrated in
The first member 52 and/or the second member 54 can include a plurality of reservoirs 60 configured to transport a liquid to a single sensor 10. For instance,
Although
An inlet channel 66 extends from each reservoir 60. Before operation of the liquid transport structure 50, each inlet channel 66 can be maintained at a same pressure that is less than or equal to the pressure in the vent channel 68 to prevent flow of a liquid from a reservoir 60 into the assay chamber 64. During operation of the liquid transport structure 50, a liquid from a particular reservoir 60 can be transported onto a particular sensor 10 by increasing the pressure in the inlet channel 66 of that reservoir 60 above the pressure in the vent channel 68. The relative pressure can be increased by increasing the pressure in an inlet channel 66 and/or by reducing the pressure in the vent channel 68.
In some instances, the first member 52 and/or the second member 54 are not constructed with a base 56 and a cover 58. For instance, the first member 52 and/or the second member 54 can have a one-piece construction.
In some instances, the sensor structure 28 is not independent of the liquid transport structure 50. For instance, the second member 54 can serve as the sensor support 30 or the sensor support 30 can be constructed to serve as the second member 54.
In some instances, the liquid transport structure 50 does not include a second member 54.
Many of the liquid transport structures 50 above are shown as having both a vent channel 68 and a waste channel 70. In some instances, the vent channel 68 also serves as a waste channel 70 and the liquid transport structure 50 does not include a waste channel 70. In some instances, the waste channel 70 also serves as a vent channel 68 and the liquid transport structure 50 does not include a vent channel 68.
As noted above, the liquid transports structures can be operated by controlling the pressure of one or more inlet channels 62 and one or more vent channels 68.
A suitable sealing mechanism 72 is illustrated in
Although
As shown in
Although the principle of sealing and unsealing the inlet channels 62 are taught in the context of a liquid transport structure 50 having reservoirs 60 positioned under the sensors 10, the same principles can be applied to a liquid transport structure 50 having reservoirs 60 positioned over a sensor 10 as shown in
The liquid transport structures shown above can include a diaphragm 74 obstructing an inlet channel 66. For instance,
In some instances, a diaphragm is flexible. A flexible diaphragm 74 can be operated so as to control pressure on liquids within a liquid transport structure 50. For instance, an instrument 76 can be employed to drive the diaphragm 74 further into the inlet channel as shown in
Although the diaphragm 74 of
The diaphragm 74 can include one or more openings through which the fluid can flow. Example openings include, but are not limited to, pores, slits, holes, apertures. The size and number of the one or more openings can control the pressure required to drive a fluid through the diaphragm. For instance, reducing the size and/or number of the one or more openings can increase the pressure required to drive the fluid through the diaphragm. Suitable diaphragms having openings include, but are not limited to, passive valves, pinch holes, septa, filters and membranes.
A diaphragm 74 having one or more openings through which a fluid can flow can be employed to control pressure in the assay chamber 64. For instance,
Although the above diaphragms are portrayed as being flexible, the diaphragm can be rigid.
The liquid transport structure can include a plurality of diaphragms 74. Different diaphragms 74 can obstruct different channels. Different diaphragms 74 can be positioned on different sides of the liquid transport structure 50. A single diaphragm 74 can obstruct more than one channel as illustrated in
In some instances, a diaphragm 74 can be positioned so as to cover a reservoir 60. For instance,
One or more outlet channels 62 of a liquid transport structure can include an obstruction 78 as illustrated in
The obstruction 78 can serve to constrain a liquid in a reservoir 60 by increasing the pressure required to drive a liquid from the reservoir 60 into the assay chamber 64. For instance, the obstruction 78 can include one or more openings through which the liquid can flow. Example openings include, but are not limited to, pores, slits, holes, apertures. The size and number of the one or more openings can control the pressure required to drive a liquid from the reservoir into the assay chamber. For instance, reducing the size and/or number of the one or more openings can increase the pressure required to drive the liquid into the assay chamber 64. A suitable obstruction 78 includes, but is not limited to, passive valves, pinch holes, septa, filters and membranes.
The liquid transport structure 50 can include one or more channels 86 configured to flow a liquid across one or more sensors 10 held in a liquid transport structure 50.
Although
One of more of the channels 86 can be constructed to have a port positioned on the upper side of the liquid transport structure 50 and/or on the lower side of the liquid transport structure 50. For instance,
One of more of the channels 86 can be constructed without a port positioned in the upper side of the assay chamber. For instance,
The flow of a liquid across a sensor can reduce noise associated with operation of the liquid transport structure 50. As noted above, a target agent is generally bonded to the surface of the sensor 10 or to the sensor support 30 during operation of a sensor 10. Non-specific binding of other agents to the sensor 10 and/or the sensor support 30 can act as a source of noise. Non-target agents are generally bound with less affinity or weaker bond than the target agent. As a result, the flow of a liquid across the sensors can cause the non-target agents to detach while the target agents remain intact. The ability to detach these non-target agents from the sensor 10 and/or from the sensor support 30 can serve to reduce the noise associated with operation of the sensors 10.
A channel 86 can be configured to act as a nozzle.
Although
The outlet channels 66 of the liquid transport structures 50 shown above can be constructed so as to provide a particular flow of liquid onto a sensor 10. For instance, when a reservoir 60 is positioned below a sensor 10, the outlet of an outlet channel 62 can be angled toward the working electrode 26 as shown in
When a reservoir 60 is positioned under the sensors 10, the above illustrations show the outlet of the outlet channel 62 positioned between the working electrode 26 and the reference electrode 22 or between the working electrode 26 and the counter electrode 24. However, the outlet of the outlet channel 62 can be positioned elsewhere relative to the sensor 10. For instance, the outlet can be positioned between the reference electrode 22 and the counter electrode 24. Alternatively, the outlet can be positioned such that the outlet and the working electrode 26 are on opposite sides of the reference electrode 22. Further, the outlet can be positioned such that the outlet and the working electrode 26 are on opposite sides of the reference electrode 22.
The liquid transport structures illustrated above need not include sensors. For instance, the liquid transport structures illustrated above can be assembled without a sensor structure. As a specific example,
The liquid transport structure 50 can include one or more assay chambers 64 that serve as a mixing chamber and one or more assay chambers 64 having one or more sensors. For instance,
As noted above, a liquid is transported from a reservoir 60 into an assay chamber by generating a pressure differential across a reservoir 60. The pressure in a channel can be controlled with the use of pressure sources such as pumps and vacuums.
The liquid transport structure 50 can be interfaced with assay equipment by clamping the liquid transport structure 50 between interface members as shown in
The interface members also include recesses 108 configured to seat a gasket mechanism 106 around the opening of a lumen 96. A suitable gasket mechanism 106 includes, but is not limited to, an O-ring. As is evident in
The connectors 104 can each be coupled with a tube 110 as illustrated in
The interface system 90 can be employed with a liquid transport structure 50 constructed according to
The second interface member 94 includes a plurality of guide lumens 114. The guide lumens 114 are positioned such that each of the guide lumens 114 is aligned with an inlet channel 66 when the second interface member 94 is positioned adjacent to the liquid transport structure 50. The sealing mechanisms can be moved within the guide lumens 114 as illustrate by the arrow labeled A. Each guide lumen 114 guides the movement of the sealing mechanism relative to the liquid transport structure 50. For instance, when a sealing mechanism is employed to seal an inlet channel 66, the guide lumen 114 guides the movement of the sealing mechanism into contact with the liquid transport structure 50.
The interface system 90 of
In some instances an interface member will not include any lumens. For instance, when a member of the liquid transport structure 50 does not include any channels, the adjacent interface member need not include any lumens. As a result, the adjacent interface member can be a slab.
In some instances, the liquid transport structure 50 serves as a cartridge that can be easily incorporated into and removed from assay equipment including equipment such as the pumps, vacuums, valves and/or electronics discussed above.
The illustrated assay equipment includes a frame 116 with a base 118 and an upper body 120. The upper body 120 can be moved relative to the base 118 as illustrated by the arrow labeled A. The base 118 holds the second interface member 94 while the upper body 120 holds the first interface member 92. The liquid transport structure 50 is configured to be coupled with the frame 116 during operation of the assay system and can be removed from the frame 116. The liquid transport structure 50 can be coupled with the frame 116 by positioning the liquid transport structure 50 on the second interface member 94 and lowering the upper body 120 toward the base 118 until the liquid transport structure 50 is clamped between the first interface member 92 and the second interface member 94 as shown in
When the liquid transport structure 50 is coupled with the frame 116, the sensors 10 can be in electrical communication with electronics (not shown) for operating the sensors 10. This electrical communication can be achieved by inserting the pads 34 of the chip into a port that provides electrical communication between the sensors 10 and the electronics before or after the liquid transport structure 50 is coupled with the assay equipment.
The upper body 120 of the frame 116 and/or the lower body of the frame 116 can include a chamber 122 where various equipment is positioned. For instance, a chamber 122 can hold the pumps, vacuums, valves and/or electronics discussed above. Alternatively, the pumps, vacuums, valves and/or electronics can be located outside of the frame 116. The electronics can operate the pumps, vacuums and valves so as to create the desired pressure in the channels of the liquid transport structure 50. Accordingly, the electronics can control the transport of the liquid from a reservoir into the assay chamber.
The sealing mechanisms shown in
Although the first interface member and the second interface member are shown as being independent of the frame, the first interface member and/or the second interface member can be integrated into the frame.
Although the liquid transport structure is illustrated above as being constructed from a first member and a second member, the first member and the second member can be formed into a single piece. As a result, the liquid transport structure can have a one-piece construction or a multi-piece construction.
Although the liquid transport structure is disclosed in the context of a particular sensor embodiment, the liquid transport structure can be employed other sensor types and constructions. For instance, the liquid transport structure can be employed with sensors other than electrochemical sensors. Further, the sensor need not be limited to detection of biological agents and can be a sensor for the detection of other agents such as chemicals and particulates, electrolytes and molecules.
Other embodiments, combinations and modifications of this invention will occur readily to those of ordinary skill in the art in view of these teachings. Therefore, this invention is to be limited only by the following claims, which include all such embodiments and modifications when viewed in conjunction with the above specification and accompanying drawings.
This application claims priority to provisional patent application Ser. No. 60/339,766 filed on Nov. 2, 2001, entitled “Integrated Sample Preparation Unit” and incorporated herein in its entirety. This application is related to patent application Ser. No. 60/399,058 filed on Jul. 26, 2002, entitled “Assay System Employing a Cartridge” and incorporated herein in its entirety.
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