This disclosure relates generally to chemical assay devices and, more particularly to chemical assay devices that are formed from hydrophilic substrates with embedded hydrophobic structures that control fluid flow through the hydrophilic substrates.
Paper-based chemical assay devices include portable biomedical devices, chemical sensors, diagnostic devices, and other chemical testing devices made of a hydrophilic substrate, such as paper, hydrophobic materials, such as wax or phase-change ink, and one or more chemical reagents that can detect chemical assays in test fluids. A common example of such devices includes biochemical testing devices that test fluids such as blood, urine and saliva. The devices are small, lightweight and low cost and have potential applications as diagnostic devices in healthcare, military and homeland security to mention a few. To control the flow of liquids through a porous substrate such as paper, the devices include barriers formed from wax, phase-change ink, or another suitable hydrophobic material that penetrates the paper to form fluid channels and other structures that guide the fluid to one or more sites that contain reagents in the chemical assay device.
The current state of the art paper chemical assay devices is limited on fluidic feature resolution and manufacturing compatibility due to uncontrolled reflow of the wax channel after the wax is printed on the paper. The paper and wax are placed in a reflow oven where the wax melts and penetrates into the paper.
In one embodiment, a chemical assay device has been developed. The chemical assay device includes a first hydrophilic substrate, the first hydrophilic substrate having a first side and a second side, a predetermined length and width, and a thickness of not more than 1 millimeter, and a first hydrophobic structure formed in the first hydrophilic substrate from a hydrophobic material and penetrating through substantially the thickness of the first hydrophilic substrate from the first side to the second side, the first hydrophobic structure forming a fluid barrier wall in the first hydrophilic substrate with a surface of the fluid barrier wall extending through the thickness of the first hydrophilic substrate with a deviation from perpendicular of less than 20° from the first side and second side of the first hydrophilic substrate.
In another embodiment, a chemical assay device has been developed. The chemical assay device includes a first hydrophilic substrate having a first side and a second side, a predetermined length and width, and a thickness of not more than 1 millimeter, and a plurality of hydrophobic structures formed in the first hydrophilic substrate from a hydrophobic material, each hydrophobic structure in the plurality of hydrophobic structures including the hydrophobic material extending from one arrangement in a plurality of arrangements of the hydrophobic material through substantially the thickness of the first hydrophilic substrate from the first side to the second side, each arrangement of the hydrophobic material being formed on only the first side of the first hydrophilic substrate prior to penetration of the hydrophobic material into the first hydrophilic substrate with a single shape and size, and a ratio of a maximum area for a largest hydrophobic structure in the plurality of hydrophobic structures to a minimum area for a smallest hydrophobic structure in the plurality of hydrophobic structures being less than 1.25.
In another embodiment, a chemical assay device has been developed. The chemical assay device includes a first hydrophilic substrate, the first hydrophilic substrate having a first side and a second side, a predetermined length and width, and a thickness of not more than 1 millimeter and a first hydrophobic structure formed in the first hydrophilic substrate from a hydrophobic material. The hydrophobic material is selected from a group including a wax and a phase change ink, and the first hydrophobic structure penetrates through substantially the thickness of the first hydrophilic substrate from the first side to the second side. The first hydrophobic structure forms a fluid barrier wall in the first hydrophilic substrate with a surface of the fluid barrier wall extending through the thickness of the first hydrophilic substrate with a deviation from perpendicular of less than 20° from the first side and second side of the first hydrophilic substrate.
In another embodiment, a chemical assay device has been developed. The chemical assay device includes a first hydrophilic substrate having a first side and a second side, a predetermined length and width, and a thickness of not more than 1 millimeter and a plurality of hydrophobic structures formed in the first hydrophilic substrate from a hydrophobic material. The hydrophobic material is selected from a group including a wax and a phase change ink, each hydrophobic structure in the plurality of hydrophobic structures includes the hydrophobic material extending from one arrangement in a plurality of arrangements of the hydrophobic material through substantially the thickness of the first hydrophilic substrate from the first side to the second side. Each arrangement of the hydrophobic material is formed on only the first side of the first hydrophilic substrate prior to penetration of the hydrophobic material into the first hydrophilic substrate with a single shape and size, and a ratio of a maximum area for a largest hydrophobic structure in the plurality of hydrophobic structures to a minimum area for a smallest hydrophobic structure in the plurality of hydrophobic structures is less than 1.25.
The foregoing aspects and other features of a chemical assay device are explained in the following description, taken in connection with the accompanying drawings.
For a general understanding of the environment for the system and method disclosed herein as well as the details for the system and method, reference is made to the drawings. In the drawings, like reference numerals have been used throughout to designate like elements. As used herein, the word “printer” encompasses any apparatus that produces images with resins or colorants on media, such as digital copiers, bookmaking machines, facsimile machines, multi-function machines, or the like. In the description below, a printer is further configured to deposit a melted wax, phase-change ink, or other hydrophobic material onto a porous substrate, such as paper. The printer is optionally configured to apply a temperature gradient and pressure to the substrate that spreads the hydrophobic material and enables the hydrophobic material to penetrate into the porous substrate to form channels and barriers that control the capillary flow of liquids, including water, through the substrate.
As used herein, the terms “hydrophilic material” and “hydrophilic substrate” refer to materials that absorb water and enable diffusion of the water through the material via capillary action. One common example of a hydrophilic substrate is paper and, in one specific embodiment, a filter paper, such as a cellulose filter paper, or chromatography paper forms the hydrophilic substrate. The hydrophilic substrates are formed from porous materials that enable water and other biological fluids that include water, such as blood, urine, saliva, and other biological fluids, to diffuse into the substrate. As described below, a hydrophobic material is embedded in the hydrophilic substrate to form fluid channels and other hydrophobic structures that control the diffusion of the fluid through the hydrophilic substrate.
As used herein, the term “hydrophobic material” refers to any material that resists adhesion to water and is substantially impermeable to a flow of water through capillary motion. When embedded in a porous substrate, such as paper, the hydrophobic material acts as a barrier to prevent the diffusion of water through portions of the substrate that include the hydrophobic material. The hydrophobic material also acts as a barrier to many fluids that include water, such as blood, urine, saliva, and other biological fluids. As described below, the hydrophobic material is embedded in a porous substrate to form channels and other hydrophobic structures that control the capillary diffusion of the liquid through the substrate. In one embodiment, the substrate also includes biochemical reagents that are used to test various properties of a fluid sample. The hydrophobic material forms channels to direct the fluid to different locations in the substrate that have deposits of the chemical reagents. The hydrophobic material is also substantially chemically inert with respect to the fluids in the channel to reduce or eliminate chemical reactions between the hydrophobic material and the fluids. A single sample of the fluid diffuses through the channels in the substrate to react with different reagents in different locations of the substrate to provide a simple and low-cost device for performing multiple biochemical tests on a single fluid sample.
As used herein, the term “phase change ink” refers to a type of ink that is substantially solid at room temperature but softens and liquefies at elevated temperatures. Some inkjet printers eject liquefied drops of phase change ink onto indirect image receiving members, such as a rotating drum or endless belt, to form a latent ink image. The latent ink image is transferred to a substrate, such as a paper sheet. Other inkjet printers eject the ink drops directly onto a print medium, such as a paper sheet or an elongated roll of paper. Phase-change ink is one example of a phase change material that is also a hydrophobic material. Examples of phase-change inks that are suitable for use in forming fluid channels and other hydrophobic structures in hydrophilic substrates include solid inks that are sold commercially by the Xerox Corporation of Norwalk, Conn. Because the phase change ink forms a solid phase after being formed into a printed image on the substrate, the phase change ink is one example of a hydrophobic material that can be formed into channels and other hydrophobic structures on a hydrophilic substrate to control the capillary diffusion of fluids in the hydrophilic substrate.
As used herein, the term “hydrophobic structure” refers to an arrangement of hydrophobic material that extends partially or completely through a thickness of a hydrophilic substrate to control a flow of fluids through the hydrophilic substrate. Examples of hydrophobic structures include, but are not limited to, fluid barriers, fluid channel walls, wells, protective barriers, and any other suitable structure formed from a hydrophobic material that penetrates the hydrophilic substrate. The term “well” refers to a type of hydrophobic structure that forms a circular or other enclosed region in the hydrophilic substrate to receive a fluid sample and contains the fluid sample within the well. As described below, an apparatus applies a temperature gradient and pressure to melt a layer of a hydrophobic phase-change material formed on a surface of a hydrophilic substrate to form different hydrophobic structures in the hydrophilic substrate in a controlled manner. In some embodiments, the hydrophobic structures are formed in multiple hydrophilic substrates and the hydrophobic material bonds the substrates together and forms fluid paths through multiple hydrophilic substrates. In a chemical assay device, the hydrophobic structures are arranged in predetermined patterns that form hydrophobic structures including fluid channels, deposit sites, and reaction sites around bare portions of a hydrophilic substrate, to bond two or more hydrophilic substrates together in multi-layer devices, and to form protective layers that prevent contamination of the chemical assay devices.
Illustrative embodiments of apparatuses are described below that apply a temperature gradient and pressure using two members, such as rotating cylindrical rollers or plates, to form hydrophobic structures in hydrophilic substrates with improved structural shape and robustness, reduced variation in structure size and shape, and to bond substrates together without requiring intermediate adhesive layers. As used herein, the term “engage” when referencing the members in an apparatus that applies heat and pressure between two members to form hydrophobic structures in a hydrophilic substrate refers to either direct contact between a member and one surface of a hydrophilic substrate or stack of substrates, or indirect contact through an intermediate layer.
As used herein, the term “plate” refers to a member with a surface that is configured to engage one side of substrate where at least the portion of the surface of the plate that engages the substrate is substantially smooth and planar. In some embodiments, the surface of the plate engages an entire side of the substrate. As described below, in some embodiments of a structure formation unit, the two members are plates. The two plates apply a temperature gradient and pressure to two sides of one substrate or either end of a stack of substrates. When one plate is heated to have a uniform surface temperature that is sufficiently high to melt one or more layers of a hydrophobic phase-change material, the hydrophobic material penetrates one or more layers of the substrate to form hydrophobic structures in the substrate. When one plate is heated to an elevated temperature while the other plate remains at a lower temperature, the melted hydrophobic material flows towards the higher-temperature plate to a greater degree than the lower temperature plate.
As used herein, the term “dwell time” refers to an amount of time that a given portion of one or more substrates spend between members in a structure formation unit. In an embodiment where the members in the structure formation unit are rollers, the amount of dwell time is related to the surface areas of the rollers that form the nip and the linear velocity of the substrate through the nip. The dwell time is selected to enable the phase-change material to penetrate the substrates and to bind the substrates together. The selected dwell time can vary based on the thickness and porosity of the substrates, the temperature gradient in the nip, the pressure in the nip, and the viscosity characteristics of the phase-change material that binds the substrates together. Larger rollers typically form a nip with a larger surface area. Thus, embodiments of bonding apparatuses with larger roller diameters operate with a higher linear velocity to achieve the same dwell time as other embodiments with smaller diameter rollers.
In a traditional inkjet printer, the phase change ink is transferred to one side of a substrate, with an option to transfer different phase change ink images to two sides of a substrate in a duplex printing operation. The printer spreads the phase change ink drops on the surface of the substrate, and the phase change ink image cools and solidifies on the surface of the print medium to form a printed image. The embodiments described below, however, apply heat and pressure to phase-change ink or another hydrophobic material on the surface of the substrate to enable the hydrophobic material to penetrate through the porous material in the substrate to form a three-dimensional barrier through the thickness of the substrate that controls the diffusion of fluids through the substrate.
As depicted in
The hydrophobic structures in the chemical assay device 104 are formed from one or more arrangements of hydrophobic material that are deposited on one side of the substrate 104 and subsequently penetrate the substrate 104 to form the hydrophobic structures that extend through the thickness 142 of the substrate 104. In
In the chemical assay device 100, the fluid channel barriers 108 and 112 are formed from the arrangements of hydrophobic material 172 and 176, respectively, that penetrate the substrate 104. In the finished chemical assay device 100, most or all of the hydrophobic material that is originally formed in the hydrophobic arrangements 172 and 176 is urged into the substrate 104 to form the hydrophobic structures 108 and 112. As the hydrophobic material penetrates the substrate 104, the hydrophobic material spreads laterally along the length 140 and width 142 of the substrate 104 to some degree, but the degree of lateral spread is substantially reduced from prior art devices. Instead, a much larger portion of the hydrophobic material that forms each hydrophobic structure penetrates through the thickness of the substrate 104 from the first side 132 toward the second side 136 to form fluid barrier walls and other hydrophobic structures with more sharply defined features and with more effective penetration of the substrate 104 than in prior art devices.
Using
The spread factor S is determined empirically from the following equation:
where l1 is the width of the arrangement of hydrophobic material prior to penetrating the hydrophilic substrate (width 186 in
In the illustrative embodiment of
which is less than two to one. In contrast, the prior art sensors exhibit a much greater degree of spread
For any given substrate thickness, the chemical assay sensor device of
As described below, the width of the hydrophobic structures tapers somewhat toward the second side, but the degree of taper and deviation of the hydrophobic structure walls from perpendicular relative to the first and second sides of the substrate. Apparatuses that enable arrangements of hydrophobic material to penetrate a hydrophilic substrate to form hydrophobic structures with the properties described above are described in more detail below.
The width ratios that are depicted in
The ability to form wider arrangements of the hydrophobic material while still forming narrower and more well-defined hydrophobic structures is advantageous because the wider hydrophobic material arrangements include a larger volume of the hydrophobic material that subsequently forms the hydrophobic structures with a denser configuration than the prior art. A first fraction of the volume within a hydrophilic substrate is occupied by the fibrous material (e.g. cellulose in many forms of paper) that forms the substrate. As used herein, the term “void volume fraction” refers to a fraction of the volume of the hydrophilic substrate that includes open pores and other voids that can be filled by another fluid such as air, water, or a liquefied hydrophobic material. The liquefied hydrophobic material subsequently returns to a solid phase to form a hydrophobic structure that occupies the voids. The void volume fraction varies for different types of hydrophilic material, such as different grades of paper, with some grades of high porosity filter paper having a void volume fraction of 20-25% of the total volume of the paper. The void volume fraction in a particular hydrophilic substrate forms an upper bound for the density of the hydrophobic structures since the hydrophobic material in the hydrophobic structure only occupies the voids in the hydrophilic substrate.
The chemical assay devices 100 and 450 include hydrophobic structures that occupy a high proportion of the maximum available void volume fraction in the hydrophilic substrate. For example, in the hydrophobic structure 108 the ratio between the initial volume for a given length for the hydrophobic material arrangement 172 and the corresponding volume ratio for the given length of the hydrophobic structure 108 is
where wa and ha the width and height, respectively, of the arrangement of hydrophobic material, and ws and hs are the width and height, respectively, of the hydrophobic structure that is formed from the hydrophobic material in the arrangement. In a hydrophilic substrate with a 20% void volume fraction, the parameter Ø of 0.17 (17%) corresponds to a large fraction of the available void volume being occupied by the hydrophobic material. The, hydrophobic structure occupies 85% (17%/20%) of the 20% void volume fraction in the hydrophilic substrate that is available to accept the hydrophobic material. By contrast, the hydrophobic material in prior art chemical assay devices experiences a much greater degree of spread that does not fill the available voids in the hydrophilic substrate efficiently, with a volume ratio of, for example,
where the hydrophobic material only occupies 41.5% (8.3%/20%) of the available void volume fraction. The prior art hydrophobic structure leaves a much larger portion of the void volume fraction in the substrate unoccupied (e.g. less than 50% occupied), which increases the likelihood that voids in the prior art hydrophobic structures would enable fluid to escape from a fluid channel or otherwise penetrate the hydrophobic structure. However, the hydrophobic structures in the chemical assay devices 100 and 450 fill a higher proportion of the void volume fraction that exceeds 50% of the available void volume, which produces more robust hydrophobic structures that are less likely to include gaps or other defects that would enable fluid to diffuse through fluid barrier walls or other hydrophobic structures compared to the prior art chemical assay devices.
In the illustrative embodiment of
The angle θ can vary based on different hydrophilic substrate and hydrophobic material compositions and thicknesses, but the angles of deviation are typically less than 20°. The angles of deviation in the embodiments described herein are substantially less than the prior art hydrophobic layers that have angles of deviation of approximately 45° due to the much larger degree of spread of hydrophobic material through the substrate in prior art devices.
While
Referring again to
The chemical assay device 100 of
In the chemical assay device 450, each of the substrates includes fluid channels that are formed from hydrophobic material, and the substrates are bonded together to form the device 450. In the illustrative example of the chemical assay device 450, the layer 454 is an inlet layer with a region 455 that is formed from the hydrophobic material and a deposit site 456 that is formed from the bare paper substrate and receives drops of the fluid sample. The hydrophobic material in the region 455 seals the chemical assay device 450 from one side and controls the diffusion of biomedical fluids that are placed on the deposit site 456. The layers 458 and 462 each include patterns of the hydrophobic material forming intermediate fluid channels that direct the fluid from the inlet layer 454 to different test sites in the layer 466. For example, the test site 468 includes a chemical reagent that tests for protein levels in a blood sample and the test site 470 includes a chemical reagent that tests for glucose levels in the blood sample. The pattern of the hydrophobic material on the substrate layer 466 forms barriers to prevent diffusion of the fluid between the test sites and enables the substrate layer 466 to be bonded to the substrate layer 462.
As described above, the multi-substrate chemical assay device 450 includes multiple substrates that are bonded together using the same hydrophobic material that forms fluid channels and other hydrophobic structures in the individual hydrophilic substrates. The multi-substrate chemical assay device 450 does not require special adhesive material or additional intermediate adhesive layers between the hydrophilic substrates, which are required to bond substrates in prior-art multi-substrate devices.
A first portion of the hydrophobic material in the structures 482 and 488 penetrates the substrate 458 to form fluid barrier walls and other hydrophobic structures as depicted in regions 486 and 492, respectively. A second portion of the hydrophobic material in the structures 482 and 488 penetrates into the substrate 454, as depicted in the regions 484 and 490, respectively. The portion of the hydrophobic material from the substrate 548 that penetrates the substrate 454 bonds the two substrates together. As depicted in
Ideally, each of the well structures in the respective arrays 1000 and 1100 should have the same size and shape, although practical embodiments experience variations in the sizes and surface areas of the well structures. The level of variation between the surface areas for the well structures 1000 in
The narrower range in variation between the wells in the array 1100 of
The single substrate and multi-substrate chemical assay devices that are depicted above with improved hydrophobic structural characteristics are not formed using the prior art reflow oven of
During operation, the rollers 554 and 558 rotate as indicated to move the substrate 552 in a process direction 534. The heat and pressure in the nip 566 melts the hydrophobic material 544 and enables the hydrophobic material to penetrate the substrate 552 to from hydrophobic structures, such as the hydrophobic structure 528. The higher temperature of the first roller 554 and lower temperature of the second roller 558 produces a temperature gradient in the nip 566. The rollers 554 and 558 apply the predetermined temperature and pressure to the substrate in a much more controlled manner than the prior art reflow ovens. Additionally, the rollers 554 and 558 rotate at a controlled velocity to enable each portion of the substrate 552 to remain in the nip 566 for a predetermined dwell time, which typically ranges from 0.1 second to 10 seconds in different operating configurations.
In
where γ is the surface tension of the melted hydrophobic material 544, D is the pore diameter of pores in the substrate 552, t is the dwell time of the substrate in the nip during which the temperature gradient and pressure in the nip reduce the viscosity of the hydrophobic material 544, and η is the viscosity of the melted hydrophobic liquid. The surface tension γ and viscosity η terms are empirically determined from the properties of the hydrophobic material 544. The pore diameter D is empirically determined from the type of paper or other hydrophilic material that forms the substrate 552. The apparatus 580 has direct or indirect control over viscosity η of the hydrophobic material and time t as the hydrophobic material and substrate move through the temperature gradient that is produced in the nip 566. Hydrophobic materials such as wax or phase-change inks transition into a liquid state with varying levels of viscosity based on the temperature of the material and pressure applied to the hydrophobic material. The viscosity of the liquefied hydrophobic material is inversely related to the temperature of the material. The temperature gradient in the nip reduces the viscosity of the hydrophobic material in the higher-temperature region near the side 560 and the first roller 554 to a greater degree than on the cooler side 556 and cooler roller 558. Thus, the temperature gradient enables the ink in the higher temperature regions of the temperature gradient to penetrate a longer distance compared to the ink in the cooler regions due to the reduced viscosity at increased temperature.
As is known in the art, the pressure applied in the nip 566 also reduces the effective melting temperature of the hydrophobic material 544 so that the temperature levels required to melt and reduce the viscosity level of the hydrophobic material 544 in the nip 566 are lower than the melting temperature at standard atmospheric pressure. Once a portion of the substrate 552 exits the nip 566, the pressure and temperature levels drops rapidly, which enables the hydrophobic material 544 to return to a solidified state in a more rapid and controlled manner than in the prior art reflow oven depicted in
In the nip 566, the temperature gradient produces anisotropic heating of the melted hydrophobic material 544. The higher temperature of the first roller 554 on the side 560 reduces the viscosity η of the hydrophobic material 544 to a greater degree than on the cooler side 556. Thus, the temperature gradient enables the hydrophobic material 544 to flow into the porous material of the substrate 552 toward the second side 560 for a longer distance than the horizontal flow of the hydrophobic material 544 along the length of the substrate 552. In
The apparatus 580 generates the anisotropic temperature gradient and liquid flow patterns for the hydrophobic material 544 to form fluid channel barriers and other structures with the hydrophobic material 544 that exhibit less spread along the length of the substrate 552 and improved penetration through the substrate 552 from the printed side 556 to the blank side 560 and produce hydrophobic structures with higher density and lower variance than the prior art devices. Furthermore, the anisotropic temperature gradient in the apparatus 180 enables the hydrophobic material 144 to penetrate into the substrate 152 to a greater degree than the prior art reflow oven with the isotropic temperature distribution depicted in
During operation, the first roller 554 and second roller 558 engage the stacked substrates 114 and 210 and move the stacked substrates in the process direction 534. The temperature and pressure in the nip between the rollers 554 and 558 melts the layer of hydrophobic material 618. The temperature gradient between the rollers 554 and 558 enables the hydrophobic material in the layer 618 to melt and penetrate the substrate 610. As depicted in
The portion of the hydrophobic material in the layer 618 that penetrates the substrate 610 forms another hydrophobic structure 630, such as a fluid barrier or fluid channel wall. A smaller portion of the melted hydrophobic material in the layer 618 penetrates the substrate 552, as indicated by arrow 628, which bonds the two substrates 552 and 610 together. Some of the hydrophobic material remains between the substrates 552 and 610 to maintain the bond. A portion of the hydrophobic material 618 merges with the hydrophobic material in the barrier 528 in the region 632, which increases the strength of the bond between the substrates 552 and 610. The hydrophobic barrier 528 in the substrate 552 remains substantially intact during the fluid structure formation in the substrate 610 and bonding process between the substrates 552 and 610. In the illustrative example of
In
During operation of the apparatus 780, the actuator 768 moves the plates 754 and 758 together to engage the stacked substrates 752 and 756. As depicted in
The portion of the hydrophobic material in the layer 744 that penetrates the substrate 752 forms another hydrophobic structure 748, such as a fluid barrier or fluid channel wall. A smaller portion of the melted hydrophobic material in the layer 744 penetrates the substrate 762, which bonds the two substrates 752 and 762 together. In
It will be appreciated that various of the above-disclosed and other features, and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations, or improvements therein may be subsequently made by those skilled in the art, which are also intended to be encompassed by the following claims.
This application is a continuation of and claims priority to U.S. application Ser. No. 15/098,671, which is entitled “Paper-Based Chemical Assay Devices With Improved Fluidic Structures,” and was filed on Apr. 14, 2016. U.S. application Ser. No. 15/098,671 is a continuation of U.S. application Ser. No. 14/312,128, which is entitled “Paper-Based Chemical Assay Devices With Improved Fluidic Structures,” and was filed on Jun. 23, 2014, and this application also claims priority to U.S. application Ser. No. 14/312,128.
Number | Date | Country | |
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Parent | 15098671 | Apr 2016 | US |
Child | 15244479 | US | |
Parent | 14312128 | Jun 2014 | US |
Child | 15098671 | US |