The present invention relates to systems for processing an analyte.
Conventional systems that detect analytes have limited flexibility and are unable to accurately and repeatably analyze a variety of analytes in a range of volumes and under a range of flow rates. Some inflexible analyte detection systems enable sample addition at only a single point in time and/or location in the analysis process. Thus, conventional analyte detection systems are limited to use in certain applications. Further, systems that detect analytes (e.g., biological agents) are generally large in size, precluding system use in certain applications, for example, in the field. In addition, systems that detect analytes are limited, because analyte sample contamination requires the entire system to be sterilized by, for example, autoclaving after each detection cycle.
Systems of the invention address challenges to systems for processing an analyte. The system enables consistent conditions at the point when the analyte (i.e., a sample) is exposed to the processing device (e.g., a sensor such as a flexural plate wave device). The system can be employed in a large range of volumetric flow rates (e.g., a flow rate within the range of from about 3 microliters/minute to about 1,000 microliters/minute or from about 6 microliters/minute to about 500 microliters/minute per channel). The system can be used to process a variety of analytes such as, for example, body fluid samples containing communicable diseases such as, for example, HIV and other pathogens. For example, one or more portions of the system can be disposable, which enables the system to be cleaned such that contamination risk is removed between different samples. A first analyte sample is prevented from contaminating a second analyte sample, for example. In some embodiments, sterilizing the system between each detection cycle (by, for example, autoclaving) is avoided.
During the analysis of a given sample by the system, e.g., sample “A”, processing of the sample “A” is repeatable such that the analyte sample is consistently transported to a surface of the processing device (e.g., a sensor surface). The number of streams of the samples and/or types of samples that are transported through the system is flexible. In addition, the different parts of the analysis system are preferably sized to enable portability for use in the field. The system prevents disruption of the processor during sample processing. The compact system repeatably makes fluid, mechanical, and electrical contact enabling consistent and reliable analyte analysis and/or processing. In one embodiment, the analyte sample volumetric flow rate is maintained substantially consistent throughout the analysis. In another embodiment, the analyte sample volumetric flow rate varies throughout the analysis.
In one aspect, the invention relates to a system for processing a sample. The system includes a fluid reservoir, a plurality of sample reservoirs, a plurality of channels, and a pump. The pump has an input side and an output side. A segment of each of the plurality of channels is disposed between the input side and the output side, the pump synchronously draws from the fluid reservoir and the plurality of sample reservoirs to provide a plurality of samples through the plurality of channels. A flexural plate wave device processes the plurality of samples in the plurality of channels. In one embodiment, the plurality of channels contact the flexural plate wave device. The flexural plate wave device contacts, for example, the plurality of samples being drawn through the plurality of channels. The system can include a fluid output for disposal of the sample.
In one embodiment, the pump rotates about an axis substantially perpendicular to the segment. The pump can have a plurality of rollers that rotate about the axis substantially perpendicular to the segment of each of the plurality of channels and the plurality of rollers rotate when the pump rotates.
In another embodiment, the input side has a plurality of pump input grooves, the output side has a plurality of pump output grooves, and the segment of one of the plurality of channels is disposed between a first pump input groove and a first pump output groove. The first pump input groove and the first pump output groove tension fit the segment of one of the plurality of channels over a surface of the pump. In still another embodiment, the input side has a plurality of pump input grooves, the output side has a plurality of pump output grooves, and the segment of each of the plurality of channels is disposed between the plurality of pump input grooves and the plurality of pump output grooves. The plurality of pump input grooves and the plurality of pump output grooves tension fit the segment of each of the plurality of channels over a surface of the pump.
The segment of each of the plurality of channels can be disposed between a cover and the pump, optionally, the pump is disposed in a housing and the cover is fastened to the housing. In one embodiment, the pump is disposed in a housing and a portion of the pump is exposed above a surface of the housing.
The system can include a tubing grip that interlocks with a housing and, for example, the pump is disposed in the housing. The tubing grip can have a plurality of pump grooves and a portion of each of the plurality of channels is disposed in a pump groove. The segment of each of the plurality of channels can be a segment of a flexible tube that is disposed between the input side and the output side.
Each of the plurality of channels can have a volumetric flow rate within the range of from about 1 microliters/minute to about 1,000 microliters/minute or from about 6 microliters/minute to about 500 microliters/minute. In one embodiment, each of the plurality of samples has a synchronized flow rate. In another embodiment, the input side of the segment of each of the plurality of channels is less than about 3.3 inches from the flexural plate wave device. The input side of the segment of each of the plurality of channels is, for example, disposed in the pump cover and the input side is less than about 3.3 inches from the flexural plate wave device.
In another aspect, the invention relates to a valve for a sample processing system. The valve includes an enclosure having a first side and a second side adjacent to and substantially parallel to the first side. A first end is disposed between and is substantially perpendicular to the first side and the second side. A second end is disposed between and is substantially perpendicular to the first side and the second side. The first side has a plurality of valve input grooves and the second side has a plurality of valve output grooves. A segment of a tube is disposed between a first valve input groove and a first valve output groove. A pin is disposed beneath a dowel within the enclosure. The first end of the dowel fastens to the first end of the enclosure and the second end of the dowel fastens to the second end of the enclosure. A pusher pushes the pin toward a fastened dowel.
In one embodiment, a segment of a tube is pinched between the pin and the fastened dowel. The tube is, for example, a portion of a channel. In one embodiment, a portion of the tube is disposed in the first valve input groove and another portion of the tube is disposed in the first valve output groove. Optionally, a second valve input groove is disposed adjacent the first valve input groove and a second valve output groove is disposed adjacent the first valve output groove. In one embodiment, a portion of the second tube is disposed in the second valve input groove and another portion of the second tube is disposed in the second valve output groove.
In another aspect, the invention relates to a system for processing a sample. The system includes a fluid reservoir and a sample reservoir. A channel draws from the fluid reservoir and the sample reservoir to provide a sample. A valve includes an enclosure. The enclosure has a first side and a second side adjacent to and substantially parallel to the first side, a first end is disposed between and substantially perpendicular to the first side and the second side, and a second end is disposed between and substantially perpendicular to the first side and the second side. The first side has a plurality of valve input grooves and the second side has a plurality of valve output grooves. A portion of the channel is disposed in the first valve input groove and another portion of the channel is disposed in the first valve output groove. A pin is disposed beneath a dowel within the enclosure. The dowel has a first end fastened to the first end of the enclosure and a second end fastened to the second end of the enclosure. A pusher pushes the pin toward a fastened dowel. A processing device processes the sample in the channel.
In one embodiment, the system has a pump having an input side and an output side. A segment of the channel is disposed between the input side and the output side. The pump rotates about an axis substantially perpendicular to the segment of the channel and the pump for pulls the sample through the channel. Optionally, the segment of the channel is disposed between a cover and the pump. The system can also have a fluid output for disposal of the sample.
In another aspect, the invention relates to a system for processing a sample. The system has a fluid reservoir and a plurality of sample reservoirs. A plurality of channels draw from the fluid reservoir and the plurality of sample reservoirs to provide a sample. A processing device processes the sample. The processing device has a plurality of electrical contact pads. A segment of the plurality of channels, and the processing device are disposed on a top surface of a supporting surface, for example, a plate. The plate can have registration features such as positioning pins or positioning apertures to position the processing device. The plate can be disposed on a supporting surface, for example, the housing. A socket has a plurality of magnets and a plurality of electrical contact points are disposed about a surface of the socket. The electrical contact points are complementary to the plurality of contact pads on the processing device. The socket is disposed in a position substantially parallel to the top surface of the supporting surface (e.g., the plate and/or the housing) and the socket moves in a substantially vertical direction toward the processing device. The plurality of electrical contact points contact the complementary plurality of electrical contact pads. The plurality of magnets actuate to align with the processing device. The plurality of magnets are centered substantially over the sensor surface of the processing device.
In one embodiment, alignment of the plurality of magnets with the processing device is ensured when registration features on the socket (e.g., positioning pins) engage with registration features on the supporting surface (e.g., positioning apertures). The plurality of magnets are, for example, disposed on the socket.
In one embodiment, the system also has a fluid output for disposal of the sample. In another embodiment, the system also has a cartridge for processing the sample. The processing device can be disposed on the cartridge, for example, on a top surface of the cartridge. Optionally, the cartridge has a plurality of positioning members and the cover has a plurality of complementary positioning members that mate with the plurality of positioning members thereby aligning the socket with the processing device. In one embodiment, a pneumatic or electromechanical device actuates the plurality of magnets to align with a processing device disposed on the cartridge. In one embodiment, each of the plurality of channels align with one of the plurality of magnets.
The system can include a cover enclosing a frame. The frame has a first foot and an adjacent second foot. A first end is substantially perpendicular to the first foot and a second end is substantially parallel to and is spaced from the first end. The first end has a rotation axis and the second end has a locking member. The socket is disposed in the frame and the cover rotates about the rotation axis. The first foot and the second foot contact the top surface. The locking member releasably secures the socket in a position substantially parallel to the top surface of the housing.
In another aspect, the invention relates to a method of actuating a processing device. The method includes rotating a socket into a position substantially parallel to a top surface of a housing. The socket is moved in a substantially vertical direction toward a processing device disposed on a supporting surface, for example, the top surface of the housing. A plurality of electrical contact pads disposed on the processing device are contacted with a plurality of electrical contact points disposed on a surface of the socket. A plurality of magnets disposed relative to the socket are actuated to align with the processing device. The method can optionally include aligning a positioning member defined by a cartridge with a complementary positioning member defined by the socket. The method can also include aligning the plurality of magnets with a plurality of channels defined by a cartridge.
In another embodiment, the invention provides a system for processing a sample that includes, a fluid reservoir, a plurality of sample reservoirs, a plurality of channels that draw from the fluid reservoir and the plurality of sample reservoirs to provide a sample. The system also includes a processing device for processing the sample and a thermal conditioning interface that contacts at least a portion of the plurality of channels to control the temperature of the sample. In one embodiment, the thermal conditioning interface controls the temperature of the sample as the sample is drawn through the plurality of channels and processed by the processing device. In another embodiment, the thermal conditioning interface controls the temperature of the sample as the sample is processed by the processing device. The processing device can be, for example, a flexural plate wave device. The temperature of the sample can control one or more of viscosity, density, and speed of sound of the sample processed by the processing device.
In one aspect, the invention relates to a cartridge for processing a sample. The cartridge includes a processing device for processing a sample and a body. The body has a surface and is bounded by at least one edge. A plurality of positioning members are defined by the surface. The plurality of positioning members are for aligning the processing device relative to a conduit defined by the body between a cartridge input and a cartridge output.
The cartridge can have a sample input disposed relative to the conduit. For example, a sample reservoir can be disposed on the body with a sample input at an end of the sample reservoir with the sample input disposed relative to the conduit. The cartridge input and the sample input can both be disposed on a top surface of the body. Optionally, the cartridge input and the sample input are the same input.
In one embodiment, the plurality of positioning members are apertures defined by the surface of the body. In another embodiment, the plurality of positioning members are pins disposed on the surface of the body. In another embodiment, one or more of the plurality of positioning members align the body with one or more of a plurality of complementary positioning members disposed relative to a plate. In still another embodiment, one or more of the plurality of positioning members align the body with one or more of a plurality of complementary positioning members disposed relative to a socket.
The processing device can be a sensor for sensing a sample in the conduit. The sample can be, for example, a blood sample taken from a patient. The processing device can be, for example, a flexural plate wave device and/or a silicon containing chip. A electrode cover can act as a cap that seals a surface of the processing device. The processing device can have a plurality of electrical contact pads. In one embodiment, one or more of the plurality of positioning members is adjacent the processing device. In one embodiment, the processing device processes a plurality of samples. The processing device processes the plurality of samples simultaneously or sequentially, for example.
In another embodiment, a second conduit is defined between a second cartridge input and a second cartridge output. The conduit and the second conduit can be sized to provide at least substantially the same length and/or at least substantially the same flow velocity. At least a portion of a conduit is, for example, adjacent the processing device. The conduit can include a discontinuity with, for example, the processing device adjacent the discontinuity. In one embodiment, a first portion of the conduit is upstream of the discontinuity and a second portion of the conduit downstream of the discontinuity and each portion (e.g., upstream and downstream) is sized to be smaller than the remaining portions of the conduit.
In one embodiment, the cartridge has a plurality of conduits defined between a plurality of cartridge inputs and a plurality of cartridge outputs. The conduit and the plurality of conduits are each sized to provide at least substantially the same length and/or at least substantially the same flow velocity.
A thermal transfer layer can be disposed on a portion of the surface. The thermal transfer layer can be a thin layer that allows for the transfer of thermal energy such that when the thermal transfer layer is in contact with a thermally controlled surface the thermal conditions of the thermally controlled surface condition a sample in a conduit. In this way, a sample within a conduit can be thermally conditioned prior to and/or after being processed by the processing device. Alternatively, or in addition, the thermal transfer layer can be hydrophilic layer. In one embodiment, the thermal transfer layer functions as a sealing layer.
In another aspect, the invention relates to a method for aligning a cartridge that includes providing a processing device disposed on a body, the body having a surface and being bounded by at least one edge. The surface defines a plurality of positioning members for aligning the processing device relative to a conduit. The conduit is defined by the body between a cartridge input and a cartridge output. One or more of the plurality of positioning members is placed in contact with a plurality of complementary positioning members defined by a plate. The method for aligning also includes placing one or more of the plurality of positioning members in contact with a plurality of complementary positioning members defined by a surface of a socket.
The foregoing and other objects, feature and advantages of the invention, as well as the invention itself, will be more fully understood from the following illustrative description, when read together with the accompanying drawings which are not necessarily to scale.
The invention relates to a compact system that repeatably makes fluid, mechanical, and electrical contact enabling reliable sample analysis.
A portion of each channel 110 is a tube 210. In one embodiment, each channel 110 includes one or more input tubes 210. In this embodiment, there are nine input tubes 210a-210i that pull fluid 150 from the fluid input 120 through each input tube 210a-210i. The fluid from each input tube 210 enters a cartridge input 401 (e.g., 401a-401i) (see, for example,
The system 10 includes one or more fluid control devices for changing at least one fluid property, such as flow, pressure, trajectory, and temperature for example, within the system 10. Fluid control devices can include a valve 300 and a pump 800 that direct and control the flows of various fluids, sample specimens, and samples through the system 10 and over the sensor surface located within the processing device 450. Other fluid control devices include a temperature control device that changes the temperature of the liquid flowing through the system 10. The temperature of the liquid influences and/or controls, for example, the viscosity, fluid density, and speed of sound at which the flows. In general, a fluid control device changes at least one fluid property in the vicinity of at least one surface within the system 10. Generally, this is done to distribute, for example, the magnetic particles along at least a portion of the sensor surface within the processing device 450.
In one embodiment, a valve 300 for the analyte processing system is located between the fluid input 120 and the cartridge 400. Referring now to
In one embodiment, referring now to
In another embodiment, referring still to
The valve input tubes 210 have an outer diameter that ranges in size depending on, for example, the requirements of a particular assay. The outer diameter of the valve input tube 210 has a value within a range that measures from about 0.05 inches to about 0.15 inches, from about 0.08 inches to about 0.11 inches, or about 0.09 inches. The outer diameter of the valve input tube 210 can also have a value within a range that measures from about 0.088 inches to about 0.1 inches. The valve input tubes have an inner diameter, through which fluid can flow, that have a value within a range that measures from about 0.015 inches to about 0.06 inches, from about 0.020 inches to about 0.035 inches, or about 0.0275 inches.
The valve 300 includes a dowel 330. In one embodiment, the first end 331 of the dowel 330 fastens to the first end 303 of the enclosure 399 and the second end 332 of the dowel 330 fastens to the second end 304 of the enclosure 399. In another embodiment, referring to
A handle 340 is disposed at the second end 332 of the dowel 330. At the second end 304 of the enclosure 399, at the end of the sides 301 and 302 opposite the rod 324, is a locking member 345. In one embodiment, the handle 340 is moved in the direction 360 (i.e., pushed and/or pulled such that it rotates together with the dowel 330 about the rod 324 toward the locking member 345) and the handle 340 engages within the locking member 345. In another embodiment, the handle 340 is moved in the direction 360 and the dowel 330 engages with the locking member 345. Optionally, the dowel 330 does not have a handle 340.
In one embodiment, referring to
The handle 340 has an internal spring that exerts a force against locking member 345 when the dowel 330 is in the locked position. The dowel 330 is designed to release from locking member 345 when, for example, the handle 340 is pulled in direction 343. Once free, the dowel is rotated in direction 365. The force in direction 365 can be a pulling force and/or a pushing force. The handle 340 and/or the dowel 330 rotates in the direction opposite the locking member 345 (e.g., the handle is pushed and/or pulled such that the handle rotates together with the dowel 330 about the rod 324 in a direction opposite the locking member 345).
In another embodiment, referring to
The handle 340 has an internal spring that exerts a force between the locking teeth 382, 384 and the two notches 392, 394 of the locking member 345 when the dowel 330 is in the locked position. The dowel 330 is designed to release the locking teeth 382, 384 from the notches 392, 394 of the locking member 345 when, for example, the handle 340 is pulled in direction 343. Once free, the dowel 330 is rotated in direction 365.
A pin 320 is disposed within the enclosure 399 beneath the dowel 330. Specifically, the pin 320 is disposed in between the first row of grooves 310a-310i and the second row of grooves 314a-314i. The pin 320 is also disposed between the first end 303 and the second end 304. The valve 300 includes a pusher to push the pin 320 toward a fastened dowel 330. The pusher can be, for example, a piston 311 disposed adjacent the pin 320. In one embodiment, at least two pistons 311a, 311b are disposed adjacent the pin 320. In one embodiment, the pin 320 is surrounded by the first side 301, the second side 302, the first end 303, and the second end 304 of the enclosure 399.
The valve 300 and its various components including, for example, the pin 320, the dowel 330, the handle 340, the sides 301, 302, the ends 303, 304, and the locking member 345, for example, made be made from any of a variety of materials. Non limiting examples of suitable materials include metals, polymers, elastomers, and combinations and composites thereof.
Referring now to
Referring now to
Referring now to
A single edge can surround the body 404 in the shape of, for example, a circle. Alternatively, multiple edges 407 surround the body 404 to form a square, a triangle or a rectangle, for example.
The cartridge 400 can feature a plurality of positioning members, which are defined by one or more surfaces of the body 404. The positioning members can include, for example, apertures defined by the body 404 of the cartridge 400 and/or pins disposed on the body 404 of the cartridge 400. In one embodiment, a positioning aperture mates with a positioning pin. The positioning aperture can extend throughout the surface of the body 404 to provide an opening that goes through the body 404 or, alternatively, can be a cavity that is open from one of the top surface 405 or the bottom surface 406 of the body 404. For example, the cartridge 400 has one or more positioning apertures 431, 432, 433, 434. The positioning apertures (e.g., 431) are apertures defined by the surface of the body 404 that mate with a complementary positioning pin. In another embodiment, the cartridge 400 has one or more positioning pins disposed on a surface of the body 404, for example, on the top surface 405 of the body 404. Positioning pins mate with complementary positioning apertures.
The positioning members align the processing device 450 relative to the body 404 and/or the conduit(s) 410 defined by the body 450. For example, the positioning members ensure that the processing device 450 is positioned in a desired location relative to the body 404 of the cartridge 400 and/or the conduits 410 defined by the body 404. In one embodiment, the processing device 450 is disposed on the top surface 405 of the body 404 of the cartridge 400 and the positioning members align the body 404 and the processing device 450 in a position where the information available in the processing device 450 can be processed.
Referring to
Fluid and/or sample specimen provide a sample 425 that travels through one or more conduits 410a-410i within the cartridge 400. Each conduit 410 is located between the cartridge input 401 and the cartridge output 402. Fluid enters a cartridge input 401a-401i, flows through the conduit 410a-410i, and exits the cartridge output 402a-402i.
The conduits 410 can have a diameter range of from about 0.05 mm to about 1 mm, or about 0.5 mm. Referring also to
Referring also to
In one embodiment, a fluid 150 is pulled via a pump into the cartridge input 401a-401i, enters the conduit 410a-410i and is pulled into the conduit 410a-410i. A sample specimen (e.g., 420a-420i) in a sample reservoir 415a-415i is pulled into the conduit 410a-410i through an end (e.g., 416a-416i) of the sample reservoir 415a-415i. Optionally, one or more sample reservoir 415a-415i is covered by a reservoir cover 417. The reservoir cover 417 can cover the sample specimen 420 disposed in the sample reservoir 415 to avoid, for example, contamination of the sample specimen 420 by, for example, individuals who interface with the cartridge 400 and/or the system 10 (see
The sample input 411 can be at the end 416 of the sample reservoir 415, for example. In one embodiment, the end 416 of the sample reservoir 415 through which the sample specimen 420 enters the conduit 410 is shaped and/or sized to consistently provide the sample specimen 420 to the conduit 410. For example, the end 416 of the sample reservoir 416 has a funnel shape and an opening, through which the sample specimen 420 enters the conduit 410, is disposed at the bottom of the funnel.
The cartridge 400 can feature a plurality of positioning members, which are defined by one or more surface of the body 404. The positioning members can include, for example, positioning apertures (e.g., 431, 432, 433, 434) defined by the body 404 of the cartridge 400 and/or pins disposed on the body 404 of the cartridge 400. The cartridge input 401 and the sample input 411 can be a single input. The fluid and/or the sample specimen can be provided to the conduit 410 via this single input.
In one embodiment, the fluid 150 mixes with the sample specimen 420 to provide a sample 425. In another embodiment, the fluid 150 provides one layer within the conduit 410 and the sample specimen 420 provides another layer within the conduit 410 and the flow through the conduit 410 after the point in the conduit 410 where the cartridge input 401 and the sample input 411 have been provided is referred to as the sample 425. In still another embodiment, the fluid 150 is physically separate from the sample specimen 420, however, after the point in the conduit 410 where the cartridge input 401 and the sample input 411 have been provided though physically separate they are referred to as the sample 425. In still another embodiment, after the point in the conduit 410 where the cartridge input 401 and the sample input 411 are provided the sample 425 includes, for example, a section of fluid (e.g., 150) and then a section of sample specimen (e.g., 420) or where there is no sample specimen in the sample input 411 the sample 425 is composed only of the fluid (e.g., 150). While traveling through the conduit 410, the sample 425 is processed by the processing device 450 and thereafter the sample 425 exits the cartridge 400 via the cartridge output 402.
A processing device 450 for processing the sample 425 is disposed on the cartridge 400. For example, in one embodiment, the processing device 450 is disposed on a surface of the body 404. In one embodiment, at least a portion of the processing device 450 is surrounded by a raised surface 409 that is part of and/or disposed on the top surface 405 of the body 404. The raised surface 409 is raised above the top surface 405 and has a measurement above the top surface 405 of the body in the Z direction has a value within the range of from about 0.5 mm to about 0.7 mm, or from about 0.55 mm to about 0.65 mm, or about 0.63 mm higher than the top surface 405 of the body 404. The raised surface 409 also has a measurement along the top surface 405 of the body in the X direction that has a value within the range of from about 7 mm to about 25 mm, or from about 20 mm to about 22 mm, or about 21 mm of the top surface 405 of the body 404. The raised surface 409 aids in positioning the processing device 450 for contact (e.g., electrical and/or mechanical contact) with the socket 630 and the cover 600 (discussed in detail together with
In one embodiment of the cartridge 400, a fluid 150 is pulled into the first cartridge input 401a and enters the conduit 410a, a sample specimen 420a, in a sample reservoir 415a, is pulled into the conduit 410a through an end 416a of the sample reservoir 415a. Thereafter the conduit 410a contains a sample 425a that includes a section of fluid 150 followed by a section of sample specimen 420a followed by a section of fluid 150. A processing device 450 for processing the sample 425a is disposed on the cartridge 400. After being processed by the processing device 450, the sample 425a exits the cartridge output 402a. In still another embodiment, the cartridge 400 has a second cartridge input 401b a second sample reservoir 415b and a second conduit 410b between the second cartridge input 401b and a second cartridge output 402b. The fluid 150 is pulled into the second cartridge input 401b and enters the second conduit 410b. A second sample specimen 420b in the second sample reservoir 415b is pulled into the second conduit 410b through an end 416b of the second sample reservoir 415b. Thereafter the conduit 410a contains a second sample 425b that includes a section of fluid 150 followed by a section of second sample specimen 420b followed by a section of fluid 150. The processing device 450 processes the second sample 425b and the second sample 425b exits the second cartridge output 402b.
Referring now to
In order to assemble the cartridge 400, the body 404 is submerged in an ethanol solution containing from about 5% to about 100% ethanol for a time within the range of from about 2 minutes to about 30 minutes. In one embodiment, the conduit 410 is not a tunnel defined through the body 404, but rather is a extended cavity cut through one surface of the body. A surface of the body 404 through which the conduits 410 are disposed and/or cut, for example, the bottom surface 406 of the body 404 is positioned to enable the ethanol solution to drain from the conduit 410. For example, the bottom surface 406 of the body 404 is positioned on a surface, for example, on a non-abrasive tissue (e.g., a Kimwipe®). Optionally, any particles are removed from the bottom surface 406 of the body 404 by cleaning the bottom surface 406 by, for example, blowing an inert gas, such as nitrogen, over the bottom surface 406. A sealing layer 408 is disposed on at least a portion of a surface of the body 404. For example, the sealing layer 408 is disposed on the bottom layer 406 of the body 404. The sealing layer 408 can be a thermal transfer layer. The sealing layer 408 can be a thin layer that measures from about 0.0001 inches to about 0.01 inches, or from about 0.001 inches to about 0.005 inches, for example. The sealing layer 408 allows for fluid thermal conditioning of, for example, wash buffers, the fluid 150, the sample specimen 420 and/or the sample 425, prior to processing by the processing device 450. More specifically, when the sealing layer 408 contacts a thermally controlled surface (e.g., a top surface 504 of a plate 500 that has a temperature control device 520, see
In one embodiment, the sealing layer 408 has one or more portions that align with the positioning members defined by the body 404. For example, where the positioning members are positioning apertures (e.g., 431, 432) a portion of the sealing layer 408 that aligns with the positioning apertures also features apertures. In this way, when the sealing layer 408 is disposed on the body 404 a positioning pin will fit into the complementary positioning aperture without resistance. In one embodiment, the sealing layer 408 is a hydrophilic layer. Suitable materials that may be employed as a sealing layer 408 include a hydrophilic tape or a plastic film such as polyester, polycarbonate, polymide, or polyetheridmade with a hydrophilic seal, for example. In one embodiment, the sealing layer 408 provides a wetted surface that is disposed on a surface of the body 404. The sealing layer 408 can be, for example, a hydrophilic tape. In another embodiment, a surface of the body 404 is modified, for example, chemically and/or by introducing a charge to the surface of the body 404. For example, the surface of the body 404 can be treated with a fluid to effect hydrophobic or hydrophilic characteristics on the surface of the body 404.
In one embodiment, the sealing layer 408 is a hydrophilic tape that includes an adhesive. A backing is removed from the hydrophilic tape and is discarded. A region of the hydrophilic tape is aligned with the positioning members defined by the body 404, for example, a plurality of apertures within the hydrophilic tape are aligned with a plurality of positioning apertures (e.g., 431, 432) defined by the body. The adhesive side of the hydrophilic tape (e.g., the sealing layer 408) is pressed onto the bottom surface 406 of the body 404. In one embodiment, the sealing layer 408 is rubbed with a block, for example, a plastic block to ensure that there are no bubbles between the sealing layer 408 and the bottom surface 406 of the body 404. In one embodiment, the body 404 and sealing layer 408 are placed onto a heated surface to ensure that the sealing layer 408 is sealed onto the bottom surface 406 of the body 404. The heated surface can be a hot plate at a temperature within the range of from about 50° C. to about 160° C., from about 80° C. to about 120° C., or about 100° C. The sealing layer 408 and body 404 can be held on the heated surface for a time having a value within the range of from about 20 seconds to about ten minutes, from about 40 seconds to about five minutes, or for about one minute. Optionally, a weight is placed on the body 404 and sealing layer 408 assembly for the time that the assembly is on the heated surface. The assembly is removed from the heated surface and, while still hot, any air pockets located between the sealing layer 408 and the body 404 are removed by, for example, pressing or rubbing the sealing layer 408, for example, with a block that is rubbed over the sealing layer. In one embodiment, any air pockets located between the sealing layer 408 and the bottom surface 406 of the body 404 are removed. Prior to adding the sealing layer 408 to the bottom surface 406 of the body 404, the conduit 410a-410i has a cross section shaped substantially like the letter “C”. Upon adhering the sealing layer to the bottom surface 406 of the body 404 the cross section of the conduit 410a-410i is shaped substantially like the letter “D”.
The processing device 450 is disposed on the body 404. For example, the processing device 450 is disposed on a surface, for example, the top surface 405 of the body 404. The processing device 450 can be flush with the top surface 405 of the body 404. Alternatively, the processing device 450 can be raised above the top surface 405 of the body 404 or located below the top surface 405 of the body 404. In one embodiment, the processing device 450 is a micro-electro mechanical system (MEMS) chip disposed on the body 404. In one embodiment, the processing device 450 is a sensor for sensing the sample 425 in the conduit 410. In another embodiment, the processing device 450 includes a flexural plate wave device (FPW device). In another embodiment, the processing device 450 is a silicon containing chip. In still another embodiment, the processing device 450 is an acoustic device.
The processing device 450 is disposed on a surface of the body 404. Referring now to
In one embodiment, the first portion upstream of the discontinuity 413i is sized to be smaller than the remaining portions of the conduit 410i, for example, it has a cross-sectional area that tapers and is reduced relative to the remaining portions of the conduit 410i. Likewise, the second portion downstream of the discontinuity 414i is sized to be smaller than the remaining portions of the conduit 410i, for example. The second portion 414i tapers relative to the remaining portions of the conduit 410i and has a cross-sectional area that is reduced relative to the remaining portions of the conduit 410i. For example, at the most narrow point, the cross-sectional area of the first portion 413i is within a range of from about 0.00007 in2 to about 0.0009 in2, from about 0.00005 in2 to about 0.0004 in2, or about 0.0001 in2. Likewise, at the most narrow point, the cross-sectional area of the second portion 414i is within the range of from about 0.00007 in2 to about 0.0009 in2, from about 0.00005 in2 to about 0.0004 in2, or about 0.0001 in2. The size of the first portion 413i and the second portion 414i can be the same or, alternatively, can differ. The first portion 413i and the second portion 414i narrows relative to the remaining portions of the conduit 410i. The first portion 413i and the second portion 414i and, for example, the angles relative to the remaining portions of the conduit 410i and/or the region of the taper are sized and shaped to ensure flow therethrough. For example, in one embodiment, where the conduit 410i is at an angle, the edges of the angle by which the sample 425 passes are smoothed out or chamfered to avoid disturbing the flow of sample 425i therethrough.
The mounting surface 442 is cleaned with, for example, liquid ethanol and/or gaseous nitrogen and is dried. A gasket 446 has a plurality of holes or slotted apertures that are sized to complement the processing device inputs 443 and processing device outputs 444 defined by the mounting surface 442. The gasket 446 is a double sided pressure sensitive adhesive film. A release liner is removed from one side of the gasket 446 to reveal a side of the pressure sensitive adhesive film. The gasket 446 is aligned with the mounting surface 442 to ensure that the holes in the gasket 446 align with and do not block the processing device inputs 443 and processing device outputs 444 defined by the mounting surface 442. The gasket 446 is sealed onto the mounting surface 442 on the top surface 405 of the body 404. A seal is formed between the gasket 446 and the mounting surface 442 when there are no visible air pockets therebetween. The other release liner is removed from the gasket 446. The processing device 450 is cleaned and dried with, for example, liquid ethanol, and/or gaseous nitrogen. The processing device 450 is held by at least two edges using duck billed tweezers. Holding the processing device 450 at the edges ensures that the membranes 455 (e.g., membranes including fragile gold portions that are in a FPW device, see,
In one embodiment, referring still to
Referring now to
The analyte-particle complex is localized onto a surface of the processing device 450, for example, the membrane 455 (e.g., 455a-455i) by applying a gradient magnetic field. The magnetic field induces a polarization in the magnetic material of the particle that is aligned with the local magnetic field lines. The particle experiences a net force in the direction of the gradient, causing the particle to migrate toward regions of higher field strength. The magnetic field distribution is tailored to draw analyte-particle complexes from the sample flow and distribute them across the membrane 455 of the processing device 450. Extraneous background components of the sample (e.g., cells, proteins) generally have a much lower magnetic susceptibility as compared to the magnetic particles, and so the magnetic field does not significantly influence them. As a result, only a very small fraction of this background material interacts with the sensor surface.
Where the processing device 450 is a flexural plate wave (FPW) device the FPW device functions particularly well with the magnetic particles for two reasons. First, the presence of the magnetic particles on membrane 455 of the processing device 450 results in an amplified FPW signal response. The larger combined size and density of the analyte-particle complex yields a larger FPW signal response than the sample 425 alone. Second, the membrane 455 of the sensor in the FPW device is a thin membrane that is typically only a few micrometers thick, which allows larger magnetic fields and field gradients to be created at the membrane surface 455, because the field source can be positioned closer to the sample 425 flow. This results in higher fractional capture of the sample 425. With this higher capture rate and efficiency, it is possible to process larger sample volumes in shorter times than would be otherwise possible. The processing device 450 can include a monitoring device that monitors at least one signal output by the flexural plate wave device.
In one embodiment, the sample 425 is not bound to magnetic particles. For example, in an embodiment where the FPW device has a level of sensitivity that avoids the need for amplification of the FPW signal. In another embodiment, the sample 425 that is being evaluated is of adequate size that amplification of the sample is unnecessary to enable FPW signal detection. In such embodiments, the sample 435 is not bound to magnetic particles.
In one embodiment, the cartridge 400 is designed to cause the sample 425 to flow through the cartridge 400 such that it passes close to (and/or contacts) the membrane 455 of the processing device 450. The magnetic particles may be initially located in one or more of the sample specimen 420, in the sample reservoir 415, the fluid 150, the fluid input 120, and in the cartridge input 401. In one embodiment, the fluid 150 contains magnetic particles that mix with the sample specimen 420 in the conduit 410 of the cartridge. The magnetic particles may be combined with the sample specimen 420 and/or the sample 425 by a device (e.g., by the action of a pump or a magnetic agitator). Further, in some embodiments, one or more sources of magnetic flux are part of the cartridge.
In one embodiment, the processing device 450 is an FPW device, which is shown in more detail in
In general, the FPW device 450 is constructed from a silicon wafer 1300, using micro-fabrication techniques known in the art. In the described embodiment, a cavity 1320 is etched into the wafer 1300 to produce a thin, suspended membrane 455 that is approximately 1.6 mm long, from about 0.3 mm to about 0.5 mm wide, and from about 2 to about 3 μm thick. The overall wafer 1300 thickness is approximately 500 μm, so the depth of the cavity 1320 is just slightly less than the wafer 1300 thickness. A 0.5 μm layer 1360 of aluminum nitride (AlN) is deposited on the outer surface (i.e., the surface opposite the cavity 1320) of the membrane 455, as shown in
In operation, instrument/control electronics apply a time-varying electrical signal to at least one set of the inter-digitated metal electrodes to generate vibrations in the suspended membrane 455. The instrument/control electronics also monitor the vibrational characteristics of the membrane 455 by receiving a sensor signal from at least a second set of electrodes. When liquid is in contact with the cavity side 1320 of the membrane 455, the maximal response of the plate structure is around 15-25 MHz. The instrument/control electronics compare a reference signal to the sensor signal from the second set of electrodes to determine the changes in the relative magnitude and phase angle of the sensor signal as a function of frequency. The instrument/control electronics interpret these changes to detect the presence of the targeted analyte. In some embodiments, the instrument/control electronics also determines, for example, the concentration of the targeted analyte on the inner surface of the membrane 455.
Capture agents targeting the analyte of interest are immobilized on the thin layer of gold 1400 covering the inner surface of the membrane 455. In one embodiment, thiol-terminated alkyl chains are linked to the gold surface forming a self-assembled monolayer (SAM). A fraction of the SAM chains are terminated with reactive groups (e.g., carboxyl) to allow covalent linking of capture agents to the SAM chains using biochemical process steps known in the art. The remainder of the SAM chains are terminated with non-reactive groups, preferably ones that have a hydrophilic character to resist nonspecific binding (e.g., oligomers of ethylene glycol). In another embodiment, disulfides with biotinylated oligoethylene glycol chains (i.e., n of EG unit is typically 8˜9) are linked to the gold surface via disulfide-gold interaction and form a monolayer. The oligoethylene glycol chains in this molecule provide a high-resistance toward non-specific binding of unwanted biological molecules. The terminal group of this monolayer (i.e., biotin) allows a biotin-binding protein (i.e., neutravidin) to be immobilized on them, and the resulting neutravidin layers serve to further link capture agents (i.e., antibodies).
In another embodiment, the sensing surface of the membrane 455 is functionalized with capture agent. Gold coated sensors are cleaned using an oxygen plasma source. Typical processing conditions are 50 W for 2 minutes. The FPW device 450 is subsequently incubated in ethanol for 30 minutes. Next, the FPW device 450 is transferred to a 0.5 mM solution of biotin PEG disulfide solution (Polypure, Cat No. 41151-0895) in ethanol and allowed to incubate overnight. The FPW device is transferred back into a pure ethanol solution for 30 minutes. The chips receive a brief, final ethanol rinse and are blown dry using a nitrogen stream. Variations on preparation conditions can be made with similar results achieved. The resultant biotinylated surface is coated with Neutravidin (Pierce PN 31000) by flowing a 10 ug/ml solution of neutravidin over the biotinylated surface for 1 hour. Antibody is biotinylated according to the manufacturer's instructions (Invitrogen/Molecular Probes PN F-6347) and then coupled to the neutravidinated surface, by flowing, for example, 5 ug/ml solution of the biotinylated antibody (diluted into 1× PBS 0.1% BSA buffer), over the neutravidin coated surface for 1 hour. Other surface chemistries are described in the literature and can be used to produce a capture surface.
The FPW device 450 is packaged to allow electrical connections to the intergiditated electrodes 460 on the outer surface of the membrane 455. The interdigitated electrodes 460 are electrically connected to contact pads 461 disposed around the periphery of surface 1360 of device 450. Additionally, the FPW device 450 is mechanically supported by conduit 410, to allow for the inner surface of the membrane 455 to contact the samples 425 and an interface (e.g., the mounting surface 442 and processing device inputs 443, 444) is provided for contacting the sensor surface 1430 with the sample 425.
The conduit 410 is a path through which the sample 425 flows past the inner surface of the membrane 455. In one embodiment, a seal 1440 is formed between the FPW device 450 and the conduit 410 to prevent analyte test solutions from escaping from the conduits 410 formed within cartridge 400 on which the FPW device 450 is disposed. In another embodiment, the conduit 410 is a fluid chamber and the FPW device 450 is at least in part one of the interior walls of the conduit 410. The delicate membranes 455 in the processing device 450 are fragile (e.g., glass-like) and disposal of the processing device 450 on the cartridge 400, formed of plastic, should be approached carefully to avoid stressing the fragile membranes 455. In addition, the tolerance differences of the materials employed in making the processing device 450 as compared to the cartridge body 404 should be considered during material selection in order to ensure cartridge 400 accuracy.
As previously discussed, the cartridge 400 features a plurality of positioning members. Positioning members can include, for example, positioning apertures disposed on the cartridge 400 and/or pins disposed on the cartridge 400. In one embodiment, a positioning aperture mates with a positioning pin. For example, the cartridge 400 has one or more positioning apertures 431, 432, 433, 434. Positioning apertures (e.g., 431) are apertures within the cartridge 400 that mate with a positioning pin. Referring also to
Referring now to
In one embodiment, where the processing device 450 is a FPW device, the electronic configuration is a single set of drive and sense electronics that is multiplexed to each individual membrane 455a-455i (generally 455). Where the electronic configuration is a single set of drive and sense electronics that is multiplexed to each individual membrane 455, the device and its configuration can be referred to as bipolar (i.e., there is a set of electronics at the device input and output, that drives and senses the same differentially, and there is an independent ground through the substrate plane). Suitable multiplex chips that may be employed include, for example, MAX4565 (available from Maxim Integrated Products, Inc. Sunnyvale, Calif.), SW90-0004A (available from MIA-Com, Lowell, Mass.), ADG707 and ADG726 (available from Analog Devices, Norwood, Mass.).
In another embodiment, one of the input (i.e., common-drive) and the output (i.e., common-sense) are multiplexed. Where either the input or the output are multiplexed, there is no measurable cross-talk between the membranes 455a-455i (i.e., there less than 1% cross talk for either a multiplexed input or a multiplexed output). Where only the input (i.e., common-drive) is multiplexed there is a drop in frequency response magnitude of about 1 dB. Where only the output (i.e., common-sense) is multiplexed there is a drop in frequency response magnitude of about 6 dB. Thus, the drop in frequency response magnitude is greater where the output is multiplexed versus where the input is multiplexed.
Where one or more of the membranes 455 are ganged (e.g., the membranes 455h and 455i are tied or grouped together) the drop in frequency response magnitude drops in a manner proportionate to the number of ganged membranes 455. Both the drive (i.e., input) and the sense (i.e., output) signals can be ganged together so that when one membrane 455 is driven, so are the others, or when one membrane 455 is sensed, so are the others. In one embodiment, a FPW device is designed to have passbands that are separated in frequency. Where the passbands are sufficiently isolated (e.g., at sufficiently different frequencies) cross-talk between membranes (e.g., between membrane 455h and membrane 455i) is less than 1%.
In another embodiment, the input (i.e., drive) and/or the output (i.e., sense) of an FPW device is with a single electrode (rather than differentially) this is referred to as single ended drive/sense. For example, standard FPW devices are employed with one of the electrodes connected to ground. Where single-ended drive is used, the magnitude response drops by a magnitude of about 6 dB. In effect, the signal to the FPW device is effectively cut in half while the reference is left the same. When using single-ended sense, the background overwhelms the signal to such an extent that it is not possible to track any accumulation. Ganging one of the input (i.e., drive) and the output (i.e., sense) does not result in cross talk that would affect current measurements; however, ganging both input (i.e., drive) and output (i.e., sense) does result in cross talk that would affect current measurements.
Ganging can reduce the number of electrical connections to an array of devices, however, it results in a drop in the frequency response function magnitude. The desire for reduced connections is balanced with the desired signal to noise ratio for a given application. Where optimal signal to noise ratio is desired a bioplar (non-ganged) configuration is employed, however, the disadvantage is that more connections are required.
The various electronic configurations employed in the system 10 generally involve connecting the FPW 450 to the circuit with complementary electrical contact points 660 disposed on the surface of the socket 630. In one embodiment, the complementary electrical contact point 660 is the a spring pogo socket assembly available from Aries Electronics (Frenchtown, N.J.). Each FPW electrode contacts an complementary electrical contact point 660 that features a spring-loaded pin with a pointed tip. The pointed tip is able to contact the surface. For example, the pointed tip can penetrate through debris on the surface of the chip at the contact pads 461. The spring-loaded pin is mounted in a socket that is screwed to a printed circuit board. The printed circuit board has gold coated pads that contact the spring side of the pogo. Other pogo pins connect chip, ground, RTD traces, and other electrical features. Alternative methods for contact of the complementary electrical contact point 660 include, for example, wire-bonding to a flex cable, a rubberized polymer embedded with gold threads referred to as Z-Strip, and other sockets available from Gryphics (Plymouth, Minn.) and Johnstech International (Minneapolis, Minn.).
Where the contact between the complementary electrical points 660 and the FPW device 450 is poor the result is similar to the result of single ended drive or singled ended sense, there is a magnitude response drop and/or a presence of background that overwhelms the signal to such an extent that it is not possible to track accumulation. Where a drive pin is not contacted, the magnitude response drops slightly and the background rises slightly. This is often not obvious and can still provide reliable data. However, if a sense pin is not contacted, the background rises enough to make the sensor unusable.
One cause of poor contact is dirty contact pads 461 on the FPW device 450. This can arise from natural oxidation or insufficient cleaning of any surface chemistry to which the FPW device is exposed. The oxidation can be cleaned by suitable methods including, for example, plasma ashing. Where surface chemistry remains on the contact pads 461 of the FPW device 450, cleaning the surface chemistry involves exposing the FPW device 450 to ethanol by, for example, rubbing a cotton swab or a Kimwipe® soaked in ethanol on the contact pads 461.
Due to the small signals at high frequencies, the type and distance of the connection between the FPW device 450 and the network analyzer circuit is important. In one embodiment, the socket 630 containing the complementary electrical contact points 660 is on the same Printed Circuit Board as the analyzer circuitry. In another embodiment, due to constraints including, for example, size and placement, the FPW device 450 is separated from the analyzer circuit.
In one embodiment, a 2 inch long header was employed at a 0.1 inch spacing. In another embodiment one or more of: flex cable, ribbon cable, HDMI cables, CAT5e network cable, and coaxial cable are employed to connect the FPW device and the network analyzer circuit. Because each membrane 455, any contact pads 461, and/or any material (e.g., electroding material) on the contact pad 461 on the FPW device 450 measures only a few picofarads, it is important to minimize any capacitive loading in the connection between the electrode device and the analyzer circuit. Capacitive loading introduces a background noise that increases with frequency and eventually overwhelms the signal. The acceptable distance between the membrane 455 and the network analyzer circuit depends on the type of connection used. Typically, the distance between the FPW device 450 membrane 455 and the network analyzer circuit is only a few inches. Where amplifiers are placed close to the FPW device 450 membranes 455 the distance (i.e., the signal length) can be extended. For example, in one embodiment, amplifiers were placed in close proximity to the membranes 455 of the FPW device and a coaxial cable measuring 6 feet long was employed to connect the FPW device 450 to the network analyzer circuit.
Referring now to
The sealing layer 408 on the cartridge 400 allows for fluid thermal conditioning of, for example, wash buffers, the fluid 150, the sample specimen 420 and/or the sample 425, prior to and/or during processing by the processing device 450. When the sealing layer 408 contacts a thermally controlled surface (e.g., the top surface 504 of the temperature controlled plate 500) the liquid flowing through the cartridge 400 is thermally conditioned. Thermal conditioning of liquids (e.g., wash buffers, the fluid 150, the sample specimen 420 and/or the sample 425) impacts and/or controls the viscosity, density, and/or speed of sound of the liquid flowing through the cartridge 400. The speed of sound of the liquid flowing through the cartridge 400 strongly influences the FPW processing device, because the FPW processing device strongly interacts with the acoustic properties of liquids.
The plate 500 can be made from any of a variety of materials including, for example, polymers, copolymers, metal, glass, and combinations and composites of these. In one embodiment, plate 500, including the top surface 504 and the positioning pins 531, 532, is a formed aluminum plate. Optionally the formed aluminum plate 500 is anodized to improve its ruggedness (e.g., corrosion and abrasion resistance).
Referring also to
Referring again to
Referring also to
Referring now to
Referring to
The shell portion 603 features a pin 601. In one embodiment, the pin 601 is disposed within the inside surface of the shell portion 603. In another embodiment, one or more pins 601 are disposed through the shell portion 603. Once the cover 600 is moved in the direction 691 past the point at which locating member 610 comes into contact with complementary locating member 510, thereby substantially compressing the placement springs 615, the pin 601 aligns with a carriage 652. In one embodiment, after the pin 601 aligns with the carriage 652, the shell portion 603 of the cover 600 forces the pin 601 into the carriage 652 and pushes the carriage 652 in the direction 616. The direction 616 is substantially vertical and is substantially perpendicular to the surface of the housing 100. Being perpendicular is important, for example, for positioning pins 633 and 634, into complementary apertures disposed in cartridge 400. Referring also to
Referring still to
In one embodiment, the locating member 610, the complementary locating member 510, and/or the lock 627 secure the cover 600 and/or the surface of the socket 630 in a position substantially parallel with the top of the housing 100. The cover 600 includes one or more locks 627. In one embodiment, referring to
In one embodiment, referring to
Alternative locks 627 may be employed to releasably secure the cover 600 over the cartridge 400. For example, referring also to
In another embodiment, referring now to
Referring still to
Referring now to
Referring now to
In one embodiment, a portion of a channel 110a is held by a groove 708a and another portion of the channel 110a is held by a groove 714a. For example, a portion of the output tube 710a is held by a groove 708a and another portion of the output tube 710a is held by a groove 714a. Likewise, a portion of each of the output tubes 710b-710i is held by the grooves 708b-708i and another portion of each of the output tubes 710b-710i is held by the grooves 714b-714i. In one embodiment, the grooves (i.e., 708 and 714) are sized to hold the outer diameter of the output tubes without compressing the tubes thereby avoiding occlusion of the fluid flowing through the output tubes 710. The output tubes 710 have an outer diameter that ranges in size depending on, for example, the requirements of a particular assay. The outer diameter of the output tubes 710 have a value within a range that measures from about 0.05 inches to about 0.15 inches, from about 0.08 inches to about 0.11 inches, or about 0.09 inches. The outer diameter of the output tubes 710 can also have a value within a range that measures from about 0.088 inches to about 0.1 inches. The output tubes have an inner diameter, through which fluid can flow, that have a value within a range that measures from about 0.015 inches to about 0.06 inches, from about 0.020 inches to about 0.035 inches, or about 0.020 inches.
Optionally, a portion of one or more output tube 710 is held in the groove of a grip 774, 775 by, for example, an adhesive. In one embodiment, a segment of each output tube 710 is held between a first grip 774 and a second grip 775. The segment of the output tube 710 that is between the first grip 774 and the second grip 775 can be pulled to a desired level or amount of tension and secured to a portion of the system 10 (see,
Referring also to
Referring now to
The pump 800 pulls the sample 425 through the channel 110. The processing device 450 processes the sample 425 in the channel 110 (see,
Referring still to
Referring also to
In one embodiment, the cover 840 is fastened to the housing 100. In another embodiment, the cover 840 is fastened to the pump 800. The cover 840 can be fastened to the pump 800 and/or the housing 100 by any suitable fastener. In one embodiment, the cover 840 is fastened to the housing by one or more screws that mate with a complementary opening (e.g., an aperture sized to mate with the threaded end of the screw or a bolt sized to mate with the threaded end of the screw, for example) disposed on the pump 800 and/or the housing 100. In one embodiment, the pump 800 is a peristaltic pump and a segment of each channel 110 (e.g., the output tubes 710) is located adjacent the rollers 820 that compress the segment of the channels 110 (e.g., the output tubes 710). As the pump 800 rotates about the axis 811 the segment of each channel 110 (e.g., the segment of each output tube 710) disposed between the input side 801 and the output side 802 is compressed thereby forcing the sample 425 to be pumped (i.e., pulled) thorough the channel 110. The cover 840 is positioned and/or fastened in a manner relative to the rollers 820 on the pump 800 that enables the pump 800 to pull the sample 425 through each channel 110. Optionally, one or more shims may be employed between the cover 840 and the rollers 820 to ensure suitable compression that enables the pump 800 to pull sample 425 through the output tube 710 as required by the system 10. The number of rollers 820 can be a value within the range of from 6 to 18, of from 8 to 14, or 10. The rollers are sized to have a diameter with a value within the range of from about 0.02 inches to about 0.5 inches, from about 0.05 inches to about 0.375 inches, or about 0.1875 inches. The volumetric flow of the pump 800 has a value within the range of from about 1 microliter/minute to about 2,000 microliters/minute, from about 3 microliters/minute to about 1,000 microliters/minute, or from about 6 microliters/minute to about 500 microliters/minute. The pump 800 produces a coefficient of variation (CV) that is better than 5%. In one embodiment, the pump 800 has a CV that is better than 3%.
In one embodiment, the segment of the each of the channels 110 disposed between the input side 801 and the output side 802 of the pump 800 comprises a flexible tube. The input side of this flexible segment of each of the channels 110 disposed in the pump cover 840 is less than 3.3 inches downstream from the processing device 450 (e.g., the flexural plate wave device). (see, FIGS. 1 and 8A-8C).
In one embodiment, the pump 800 synchronously draws from the fluid input 120, e.g., a fluid reservoir, and the plurality of sample reservoirs 415 to provide a plurality of samples 425 through the plurality of channels 110. (see,
In one embodiment, the pump input groove 708 and the pump output groove 714 tension fit a segment of each channel 110 over a surface of the pump 800. The surface can be, for example, the exterior surface of the rollers 820. A segment of one of the plurality of channels 110 (e.g., 110a) that contacts the plurality of rollers 820 has a contact area of less than 0.35 square inches. For example, a portion of the tube 710a is disposed in the first pump input groove (e.g., 708a) and another portion of the tube is disposed in the first pump output groove (e.g., 714a). A second pump input groove (e.g., 708b) is disposed adjacent the first pump input groove (e.g., 708a) and a second pump output groove (e.g., 714b) is disposed adjacent the first pump output groove (e.g., 714a). A portion of the second channel 110b comprises a second tube 710b, a portion of the second tube 710b is disposed in the second pump input groove (e.g., 708b) and another portion of the second tube 710b is disposed in the second pump output groove (e.g., 714b). The input grooves 708 and the output grooves 714 can be located in grips 774, 775 that hold a portion of the tubes 710 with, for example, adhesive.
In one embodiment, a grip 774 has a first pump groove (e.g., 708a) and a second pump groove (e.g., 708b). The first pump groove (e.g., 708a) holds a portion of a first tube 710a and the second pump groove (e.g., 708b) holds a portion of a second tube 710b and the tubing grip 774 interlocks with the housing 100. The pump 800 is disposed in the housing 100. The tubing grips can include, for example, grips 774, 775, that hold a segment of the tubes 710 over the surface of the pump 800 with tension. The tension imposed by the trips 774, 775 on the tubes 710 can be a value within the range of from about 1 lb to about 6 lbs, from about 2 lbs to about 5 lbs, or from about 3 lbs to about 4 lbs.
In another embodiment, the tension fit segments of the channels 110 (e.g., output tubes 710) are disposed over the pump 800 and at their highest point, the tension fit segments of the channels 110, are less than 0.4 inches above the plane of the supporting surface, for example, the housing. Thus, the distance in which the segments of the channels 110 bend over the pump 800 is impacted by, for example, the amount of the pump 800 that is above the plane of the supporting surface. Where the pump 800 exposure above the support surface is limited (e.g., where the pump has a low profile) the bending of the channels 110 is limited.
The pump 800 is capable of simultaneously running multiple channels. The pump 800 has the capacity to run multiple channels 110a-110i (e.g., output tubes 710a-710i) simultaneously. In one embodiment, the pump 800 provides a substantially consistent volumetric flow rate of sample 425 through the channels 110a-110i which flow in synch. Optionally, the pump 800 self primes and primes the system 10 when, for example, it pulls sample 425 through the system 10 (see,
Referring also to
The systems for processing an analyte and components of the system including the pump, the valve, the socket, the cartridge, and the methods for aligning and actuating and other aspects of what is described herein can be implemented in analyte processing, for example and other suitable systems known to those of ordinary skill in the art. Variations, modifications, and other implementations of what is described herein will occur to those of ordinary skill without departing from the spirit and the scope of the invention. Accordingly, the invention is not to be defined only by the illustrative description.