Patent Description:
It is known the use of multiple indicators for a single analyte for paper-based microfluidic devices (<NPL>). The principle of the devices is based on an oxidation of indicators by hydrogen peroxide produced by oxidase enzymes specific for each analyte. Each indicator reacts at different peroxide concentrations and therefore analyte concentrations, giving an extended range of operation. Mixtures of <NUM>-aminoantipyrine and <NUM>,<NUM>-dichloro-<NUM>-hydroxy-benzenesulfonic acid, o-dianisidine dihydrochloride, potassium iodide, acid black, and acid yellow were chosen as indicators for simultaneous semi-quantitative measurement of glucose, lactate and uric acid on the µPAD.

<CIT> discloses a diagnostic for determining the presence and amount of a target analyte. It comprises a sample addition reservoir, a reaction chamber containing reagent(s) and a diagnostic element. A time gate delays the flow of the reaction mixture from the reaction chamber into the diagnostic element. The time gate is a capillary having a hydrophobic surface. The hydrophobic surface can bind components contained in the reaction mixture so as to render it more hydrophilic. This allows the fluid to flow.

The article of <NPL>" describes two quantitative assays that operate by measuring flow-through time or by counting the number of colored bars at a fixed assay time. A paper disk provided in a paper-based microfluidic device contains <NUM>-(<NUM>-hydroxyethyl)-<NUM>-piperazineethanesufonic acid buffer (HEPES) that was pre-deposited and dried on the paper disk prior to assembling the device.

Low cost, robust, and sensitive diagnostic tests are needed for resource limited settings. However, most point of care diagnostic tests currently on the market require a reader, a power source, and an electronic display to output the results, all of which significantly add to the cost of performing the test. Although some colorimetric test strips can be operated without the use of auxiliary electronics, user interpretation is still required and the results may vary from patient to patient. Accordingly, diagnostic devices that are inexpensive, equipment-free, portable, sensitive, with easy-to-read results would be desirable.

Aspects of the present invention are directed to easy-to-produce and customizable diagnostic devices, as claimed in claim <NUM>. The devices may be utilized for health-related diagnostic tests for the detection of glucose, lactose, urea, creatinine, and the like in a biological sample, for example. Advantageously, the devices may be quickly manufactured and do not require equipment to provide at least qualitative or semi-quantitative results. Thus, the devices described herein may be utilized where resources are limited. Further, the devices described herein may be inexpensively constructed from low cost materials, are simple to manufacture, are highly flexible (in terms of assay expansion), require only small sample sizes, and provide fast results.

In accordance with one aspect, there is provided a diagnostic device which utilizes a conversion component to provide at least a qualitative or semi-quantitative result for a target analyte or property in the sample. In certain aspects, the conversion component comprises a target analyte in a sample which directly reacts with a hydrophobic material associated with the device to convert the hydrophobic material to a hydrophilic material.

In accordance with another aspect of the present invention, the conversion component may comprise a compound which is derived from a target analyte in the sample. For example, the conversion component may comprise or be derived from a product of a reaction with a target analyte in a sample, wherein the produced conversion component from the reaction with the target analyte is effective to convert a hydrophobic material associated with the device to a hydrophilic material. In exemplary embodiments, the conversion component may comprise H2O2, CO2, or another component produced via an enzymatic reaction with a target analyte in a sample such as glucose, lactose, urea, and creatinine. Via a number of different structures and arrangements described herein, the presence of the target analyte may be quickly and inexpensively determined qualitatively, semi-quantitatively, or even quantitatively.

In accordance with another aspect, there is provided a device including a plurality of reaction channels, each of which may include a hydrophobic material associated therewith. The hydrophobic material is selected such that upon contact with a conversion component (e.g., a target analyte or a product from a reaction with a target analyte in a sample), the hydrophobic material is converted from the hydrophobic material to a hydrophilic material. The device may be structured so as to provide an indication of the extent of the hydrophobic to hydrophilic conversion caused by the conversion component, which may correspond to the amount of a target analyte in the sample.

The hydrophobic material may be converted to the hydrophilic material by the conversion component so as to allow a hydrophilic or aqueous sample to move up the reaction channel as the conversion takes place. In certain embodiments, one or more enzymes may also be provided along with the hydrophobic material within one or more reaction channels to produce a conversion component, e.g., H2O2 or CO2, which may convert the hydrophobic material to a hydrophilic material.

In accordance with another aspect, as the concentration of the target analyte increases in a sample, a greater amount of hydrophobic to hydrophilic conversion takes place. The extent of conversion may be utilized to quickly determine at least qualitatively or semi-quantitatively (e.g., provide a range for a target analyte or whether a predetermined threshold value has been reached or not) an amount of a target analyte in a sample. For example, reaction channels having differing concentrations of the hydrophobic material may be provided in a device. In other embodiments, a plurality of channels may be provided, each with a different length to determine an amount of an analyte in a sample. The device may comprise a plurality of channels, each with a different concentration of one or more compounds, such as one or more enzymes, which will react with a target analyte in a sample to at least quantitatively or semi-quantitatively provide an indication of an amount of the target analyte in the sample.

The device further includes a dye that directly or indirectly provides an indication of an amount of the target analyte in the sample. The dye is placed along a path of the reaction channel or at an end thereof. The dye is placed at an end of a reaction channel and provides an indication that hydrophobic to hydrophilic conversion has taken place to a degree sufficient for the sample to reach the dye. In other embodiments, the dye may be distributed entirely or at intervals along a length of each reaction channel. The dye may be selected such that upon contact with a conversion component such as hydrogen peroxide the dye undergoes a reaction and provides visible or readable color change. In other embodiments, the dye is selected such that it provides an indication that an aqueous sample has come into contact therewith.

Below are described exemplary embodiments of the devices that may be produced in accordance with aspects of the present invention.

The invention is explained in the following description in view of the drawings that show:.

There is provided a diagnostic device comprising a substrate (in the following also designated as "base member") and a hydrophobic material disposed on the substrate. The hydrophobic material is a material that will be converted from the hydrophobic material to a hydrophilic material upon contact with a conversion component within or derived from a sample introduced to the device. The substrate comprises a plurality of reaction channels, at least some of them comprising an amount of the hydrophobic material therein. The hydrophobic material is converted into a hydrophilic material upon contact with a conversion component within or derived from a sample introduced to the reaction channels. Each of the plurality of reaction channels comprises a dye at an end of the respective channel, wherein the dye is selected to provide a visible or readable indication that a sample introduced to the device has traveled along a length of the reaction channel to the dye. The conversion of the hydrophobic material into the hydrophilic material is stimulated via a reaction with hydrogen peroxide, carbon dioxide, compounds with thiol terminated groups, or another component produced via an enzymatic reaction with a target analyte in the sample, or via a change in pH. In an embodiment, the conversion component comprises a compound such as hydrogen peroxide produced from one or more enzymatic reactions starting with a target analyte in a sample introduced into the device.

In accordance with another (not claimed) aspect of the present invention, there is provided a diagnostic device comprising a substrate; a plurality of reaction channels defined on the substrate; a hydrophobic material disposed within at least one of the reaction channels; and one or more enzymes disposed within at least one of the reaction channels along with the hydrophobic material. The one or more enzymes are selected to provide a conversion component upon contact of the one or more enzymes with a target analyte in a sample introduced to the device. The hydrophobic material is selected to be converted from the hydrophobic material to a hydrophilic material on the substrate upon contact with the conversion component.

In accordance with another (not claimed) aspect of the present invention, there is provided a diagnostic device comprising a substrate; a plurality of reaction channels defined on the substrate; one or more enzymes disposed within selected ones of the reaction channels; and a dye associated with selected ones of the reaction channels. The dye may be disposed at ends of the selected reaction channels, at intervals along selected reaction channels, or throughout selected ones of the reaction channels, for example. "Selected ones" may refer to any one or more of the reaction channels. The one or more enzymes are selected to provide a conversion component upon contact of the one or more enzymes with a target analyte in a sample introduced to the device. In an embodiment, the dye provides a visible or readable change in a property thereof upon reaction with the conversion component, which may be a color or fluorescence change, for example. In other embodiments, the dye may produce a visible or readable change upon mere contact with the conversion component. To provide at least a qualitative or semi-quantitative result, the device may comprise a plurality of reaction channels, each with a different amount of the one or more enzymes therein. In another embodiment, the device may comprise a plurality of reaction channels with equivalent concentrations of the one or more enzymes, but with different concentrations of the dye material.

As used herein, the term "conversion component" may refer to any compound which is effective to convert an amount of a hydrophobic material to an amount of the hydrophilic material and/or produce a change in a dye material as described herein.

As used herein, by the phrase "effective amount," it is meant an amount of material suitable for bringing about an intended result.

As used herein, the term "sample" refers to any material that contains a target for which a target assay is desired. The sample can be but is not limited to a biological sample, such as a biological fluid or a biological tissue.

As used herein, the term "subject" refers to any human and non-human mammal.

Referring now to the figures, <FIG> illustrate a diagnostic device10 in accordance with an aspect of the present invention. The device <NUM> comprises a base member <NUM> and at least one reaction channel <NUM> defined on the base member <NUM> in a predetermined pattern <NUM>. For purposes of illustration, a plurality of reaction channels <NUM> may be provided on a single device as shown in <FIG>. It is contemplated that a device may comprise a single reaction channel <NUM> and may be in the form of a strip. When a plurality of reaction channels <NUM> are provided, the reaction channels <NUM> may be separated from one another by providing a boundary for each reaction channel. In certain embodiments, for example, at least a portion of the periphery of each reaction channel <NUM> is defined by a barrier defining material <NUM> (hereinafter "barrier material <NUM>"). An effective amount of a hydrophobic material <NUM> may be disposed within at least a portion of each reaction channel <NUM> defined by the barrier material <NUM>.

Critically, the hydrophobic material <NUM> is selected to have a structure such that upon contact with a conversion component, the hydrophobic material <NUM> is converted from the hydrophobic material <NUM> as shown in <FIG> to a hydrophilic material <NUM> as shown in <FIG>. It is understood that by "conversion from hydrophobic material to hydrophilic material" or the like it is meant that upon reaction with the conversion component, the hydrophobic material becomes more hydrophilic than prior to contact with the conversion component.

In an embodiment, the conversion component may comprise a target analyte in the sample introduced into the device <NUM>. In another embodiment, the conversion component may comprise a product derived from the target analyte. For example, the conversion component may be produced from a reaction with a target analyte in the sample introduced into the device <NUM>. In still another embodiment, the conversion component may comprise a product of a reaction with a compound derived from the target analyte such as with an intermediate product from a reaction starting with the target analyte. It is understood that it may not be known whether the target analyte is present in an unknown sample. As the hydrophobic material <NUM> is converted to the hydrophilic material <NUM> by the conversion component along a length of a respective reaction channel <NUM>, an aqueous sample may travel along a longitudinal length of the reaction channel <NUM> by capillary action in the direction shown by arrow <NUM>.

In certain embodiments, if the sample does not include or provide a sufficient amount of the target analyte to directly or indirectly convert the hydrophobic material <NUM> in the reaction channel <NUM> to the hydrophilic material <NUM>, the sample will not travel from a sample port <NUM>, for example, to an end <NUM> of the reaction channel <NUM> as shown in <FIG>, for example. To the contrary, if the sample comprises a sufficient amount of the target analyte, the hydrophobic material <NUM> will be converted to the hydrophilic material <NUM> along an entire length of the respective reaction channel <NUM> and reach the end <NUM>.

It is appreciated that the sample to be introduced into the device <NUM> may comprise any one or more of urine, saliva, and blood, or a sample derived therefrom, from a subject. Further, the sample to be introduced into the device <NUM> may undergo any pre-treatment or filtration process as is known in the art in preparation for analysis prior to introduction to the device <NUM>.

The base member <NUM> may be any suitable porous or non-porous material. In certain embodiments, the base member <NUM> comprises a porous material. The porous material may comprise a cellulosic material, a glass fiber material, a porous polymeric material, or combinations thereof, for example. With a porous material, it is generally understood that the barrier material <NUM>, hydrophobic material <NUM>, and any other desired components for the device <NUM> may be disposed on a surface of the base member <NUM> and/or within pores of the base member <NUM>.

While not shown in the Figs. , a cover layer may be used to cover the device <NUM> (and any of the other devices discussed below) thereby enclosing one or more, up to all, of reaction channels <NUM> from above. State differently, the cover layer may position opposite the base member <NUM> with the reaction channel disposed in between. Thus individual reaction channels <NUM> can be defined by base member <NUM>, the barrier material <NUM>, and the cover layer. Any such cover layer would have an opening aligned with the sample port <NUM> to allow for sample entry. The cover layer could be made from any of a variety of transparent materials known to a person of ordinary skill in the art such that the reaction channel <NUM> remains visible below. Such a cover layer may help protect a user from coming into contact with the sample.

In the embodiment shown in <FIG>, there are shown three reaction channels <NUM> which define the pattern <NUM>. However, it is understood that any number of reaction channels <NUM> may be defined on the base member <NUM>. For example, the device <NUM> may be patterned so as to provide a device with one, four, six, eight, ten or any other number of reaction channels <NUM>. In addition, the channels <NUM> may be of any suitable length and width to accomplish the objectives of the assay to be performed within each reaction channel <NUM>. In an embodiment, selected ones of the reaction channels <NUM> comprise a predetermined amount of the hydrophobic material <NUM> therein, although it is contemplated the devices described herein are not so limited. In certain embodiments, it may be desirable to provide a control reaction channel <NUM> having no hydrophobic material <NUM> therein, for example.

Advantageously, the simple construction of the devices described herein enable easy assay expansion. For example, if one wished to expand the device <NUM> to accommodate three additional concentrations of the hydrophobic material <NUM> in the reaction channels <NUM>, one could do so by defining adding additional reaction channels <NUM> to the pattern <NUM> in <FIG> and disposing a predetermined amount of hydrophobic material <NUM> (and any other suitable components) within the additional channels. It is appreciated that device <NUM> may be tailored so as to accommodate two or more distinct hydrophobic materials and/or other components, each of which may be directly or indirectly useful in testing for one or more target analytes in a sample introduced to the device <NUM>.

When multiple reaction channels <NUM> are present, the reaction channels <NUM> may be defined on the base member <NUM> by any suitable method, such as by drawing, spraying, brushing, and/or printing the barrier material <NUM> in the desired pattern <NUM> on the base member <NUM>. In an embodiment, the reaction channels <NUM> may be defined by disposing the barrier material <NUM> on a single side of the device <NUM> in the pattern <NUM>. In other embodiments, the reaction channels <NUM> may be defined by disposing the barrier material <NUM> on both sides of the base member <NUM>. In certain embodiments, the reaction channels <NUM> may be disposed on opposed sides in substantially the same pattern <NUM>. It is appreciated that a non-porous material may be placed between the two opposed sides at least where penetration of the sample from one side to other is not desired. In an embodiment, a sample introduction site is located or provided on the base member <NUM> for the introduction of the sample to the device <NUM> to provide sufficient sample for one or both sides of the device <NUM>. For example, the device <NUM> may comprise a single, common sample introduction site <NUM> for the device <NUM> such that a sample introduced to the site <NUM> is sufficient to provide sample for each of the reaction channels <NUM> on the device <NUM> as shown in the FIGS.

The barrier material <NUM> may be any suitable material effective to form a barrier to a sample introduced into the device <NUM> and define a path (e.g., a reaction channel <NUM>) for the sample when the hydrophobic material <NUM> is converted to the hydrophilic material <NUM>. In an embodiment, the barrier material <NUM> has a lower porosity and/or a higher degree of hydrophobicity than the base member <NUM> and/or the hydrophilic material <NUM> (when present and converted from the hydrophobic material <NUM>). In this way, a sample may continue to be maintained within a boundary defined by the barrier material <NUM>. Thus also, the barrier material <NUM> is typically a hydrophobic material that is not converted to the hydrophilic material <NUM> by contact with the sample or components in the reaction channel <NUM>. In certain embodiments, the barrier material <NUM> may comprise one or more components selected from the group consisting of hydrophobic polymers, permanent inks, waxes, or any other suitable hydrophobic material.

The hydrophobic material <NUM> may be any suitable material that is converted to a hydrophilic material <NUM> by contact with a conversion component as described herein. In an embodiment, the hydrophobic material <NUM> may be provided in an amount effective to indicate the presence of a target analyte in a sample. In an embodiment, upon conversion of the hydrophobic material <NUM> to hydrophilic material <NUM> within a respective reaction channel <NUM>, a sample introduced at a leading edge of the reaction channel <NUM> will be able to flow by capillary action along a longitudinal length of the reaction channel <NUM> to a degree commensurate with the extent of hydrophobic material conversion. In other words, if there is a sufficient amount of the target analyte, the hydrophobic to hydrophilic conversion may take place over the entire length of the respective channel <NUM>. As noted above, in certain embodiments, the conversion component may comprise the target analyte in the sample which is introduced onto the device. In other embodiments, the conversion component is formed from a reaction with a target analyte or a reaction with a product of another reaction stemming from the target analyte.

By way of example, the hydrophobic to hydrophilic conversion may be stimulated via reactions with H<NUM>O<NUM>, CO<NUM>, compounds with thiol-terminated groups such as glutathione (GSH), or a change in pH, for example. The following are exemplary starting materials and reaction schemes for the hydrophobic to hydrophilic material conversion in accordance with an aspect of the present invention.

In an embodiment, the hydrophobic material <NUM> is selected so as to be one that may be converted to a hydrophilic material <NUM> through contact with hydrogen peroxide as shown below, for example. As such, the conversion of the hydrophobic material <NUM> to the hydrophilic material <NUM> may be done via an oxidation-triggered reaction. In the exemplary reaction below, the hydrophobic material <NUM> is shown on the left side of the reaction scheme and the hydrophilic material <NUM> is shown on the right of the reaction arrow.

According to the present invention, an alkyl ketene dimer may be added to the reaction channels <NUM> to modify a hydrophilic surface of the base member <NUM> to a hydrophobic surface. Introduction of a sample that includes or directly or indirectly produces an amount of a conversion component such as H<NUM>O<NUM> via reaction could thereafter reverse the wettability of the modified surface to a hydrophilic surface. The now hydrophilic surface allows the sample to travel up the reaction channel <NUM> to a degree commensurate with the amount of the target analyze that produces the conversion component (e.g., H<NUM>O<NUM>).

The hydrophobic material <NUM> may comprise a composition which is converted to the hydrophilic material <NUM> via reaction with at least CO<NUM>. For example, the hydrophobic material <NUM> may comprise a compound comprising amidine functional groups. For example, the hydrophobic material <NUM> comprises an amidine-terminated self-assembled monolayer coated on a surface that may be converted to a hydrophilic material <NUM> in the presence of CO<NUM> and water as shown below.

The hydrophobic material <NUM> may comprise a compound having one or more pH-sensitive functional groups such that the device <NUM> may be utilized to determine a pH of a sample, such as a blood or urine sample
<CHM>.

The hydrophobic material <NUM> may comprise an acid-base catalyzed acetal compound ((g) below), which may undergo the following reaction to provide an indication of a pH or a pH range of a sample. As can be seen, the lower the pH of a sample, the greater the amount of hydrogen ions available for conversion to a more hydrophilic compound. In the following example, R<NUM> and R<NUM> may be any suitable hydrophobic group. R<NUM> and R<NUM> may be independently an unsubstituted or substituted straight-chained or branched alkyl group or an aryl group, for example.

The hydrophobic material <NUM> may comprise a compound which converted to the hydrophobic material <NUM> by reaction with a thiol compound. In certain embodiments, the hydrophobic material <NUM> may be converted to the hydrophilic material <NUM> via cleavage of a disulfide bond. For example, the conversion component may comprise glutathione (GSH), which may be found in a blood sample, which will cleave the disulfide bond of the hydrophobic material <NUM>. Thus, the hydrophobic material <NUM> may be a compound, which when contacted by GSH, is converted into the hydrophilic material <NUM>. The glutathione is targeted directly to determine a qualitative, semi-quantitative or quantitative amount of GSH in a sampleThe hydrophobic material <NUM> may be selected so as to react with a thiol compound in the sample merely to allow the sample to move up the length of the reaction channel where another qualitative, semi-quantitative, or quantitative assay may take place. The hydrophobic compound <NUM> may be converted to a hydrophilic material <NUM> by reaction with a thiol such as RSH as follows:
<CHM>.

In accordance with an aspect of the present invention, the plurality of channels <NUM> may comprise channels <NUM> having different concentrations of the hydrophobic material <NUM> therein. For example, a device <NUM> having a six channel configuration is shown in <FIG> (numbered <NUM>-<NUM> in a clockwise direction). Selected ones of the reaction channels <NUM> may be provided with different concentrations of the hydrophobic material <NUM>. A control reaction channel <NUM> with no hydrophobic material may also be provided. In certain embodiments, the channels <NUM> may have an increasing concentration of the hydrophobic material <NUM>, for example, from channels <NUM>-<NUM> with one channel (e.g., channel <NUM>) serving as a control. In operation, there may be a sufficient amount of the hydrophobic material <NUM> in the sample to cause an entire length of one reaction channel <NUM> (e.g., a channel having <NUM> of the hydrophobic material) to be converted from the hydrophobic material <NUM> to the hydrophilic material <NUM> by the conversion component, but not the next greater "level" or concentration of hydrophobic material (e.g., <NUM>). With these results, it would be understood that there is an amount of the conversion component sufficient to convert from <NUM> ≥ to < <NUM> of hydrophobic material <NUM>. The amount of the target analyte may be determined therefrom as would be readily understood by one skilled in the art.

The conversion of hydrophobic material <NUM> to hydrophilic material <NUM> may itself provide a colorimetric result which can be visually inspected or read by suitable apparatus to determine an amount of hydrophobic to hydrophilic conversion. The extent of hydrophobic to hydrophilic conversion may then be correlated with the amount of a target analyte in a sample. In certain embodiments, the conversion of hydrophobic to hydrophilic conversion does not itself provide a measurable indication. Therefore, in any of the embodiments described herein, an effective amount of a dye <NUM> may be disposed at an end of the one or more reaction channels <NUM> to indicate when an entire length of the reaction channel <NUM> has been converted from the hydrophobic material <NUM> to the hydrophilic material <NUM> as is exemplified by <FIG>. In this way, the sample will have traveled up an entire longitudinal length of the respective reaction channel <NUM>. Upon contact of the aqueous sample material with the dye <NUM>, the dye <NUM> will provide an indication of the presence of a sufficient amount of the predetermined compound to convert the hydrophobic material <NUM> to the hydrophilic material <NUM> within the corresponding reaction channel <NUM>.

The dye <NUM> may be any suitable material capable of providing a readable or visible indication upon contact with the sample. In an embodiment, the dye <NUM> does not react with any component associated with the sample, but is capable of providing a visible or readable indication that the sample has come in contact therewith. In other embodiments, the dye <NUM> may be selected so as to also react with a conversion component (e.g., hydrogen peroxide, nitric oxide, or a compound having a thiol-terminated group) to provide a qualitative, semi-quantitative, or quantitative indication that the conversion component has come into contact therewith. Thus, in another aspect, the conversion component may be a component which reacts with the dye to produce a measurable change in the dye <NUM>. The change may be visible based on a hue, or may be a readable change such as a change in fluorescence of the dye upon contact with the conversion component. Exemplary dyes <NUM> that can be triggered by reaction with hydrogen peroxide, for example, and result in fluorescence increase are shown (h)-(k). Exemplary dyes <NUM> that can be triggered by reaction with thiol-terminated groups and result in fluorescence increase are shown (I)-(o).

The following compounds contain the same carbamate group that can be removed by thiol, such as glutathione (GSH). They share the same reaction mechanism.

The following compounds involve NO-induced diamine cyclization process, and fluorophores attached to phenylenediamine become fluorescent when reacting with NO. They share the same reaction mechanism.

Now referring to <FIG>, there is shown a device <NUM> comprising a plurality of channels <NUM> having the same concentration of hydrophobic material <NUM> therein, but have differing lengths <NUM>. By way to comparison of known standards of a predetermined compound, a qualitative or semi-qualitative analysis may be provided for the predetermined compound. For example, a known amount of analyte may be sufficient to cause the sample to travel an entire length of one reaction channel <NUM>, but not another reaction channel <NUM>. By comparison to known standards, a qualitative, semi-quantitative, or quantitative analysis may be provided for an unknown sample. As described above, a dye <NUM> may be disposed at an end <NUM> of the channel <NUM> if necessary to provide an indication that a sample has traveled from sample port <NUM> to the end <NUM>.

Any or more of the devices described herein may comprise reaction channels <NUM> comprising one or more enzymes which are specific for one or more target analytes (or products derived therefrom) in a sample to thereby directly or indirectly produce a conversion component which may react with a hydrophobic material <NUM> and/or dye to provide an indication of the presence of the target analyte in the sample.

The devices described may not include a hydrophobic material <NUM> which is converted to a hydrophilic material, but instead include a substrate having one or more reaction channels with one or more enzymes disposed within a selected reaction channel or channels and a dye to provide an indication of the amount of conversion.

By way of example, the one or more enzymes may include enzymes for the breakdown of creatinine, glucose, lactose, urea, and the like in the sample. As such, the conversion component may be a product of an enzymatic reaction, such as hydrogen peroxide or carbon dioxide, which can react with the hydrophobic material <NUM>. For example, in one embodiment, the enzymes may comprise enzymes, e.g., creatininase, creatinase, and sarcosine oxidase, for the breakdown of creatinine in the sample. The enzymes work according to the reaction:
<CHM>.

The enzymes may comprise one or more enzymes, e.g., glucose oxidase, for the breakdown of glucose in the sample according to the reaction:
<CHM>.

The enzymes may comprise one or more enzymes, e.g., lactate oxidase, for the breakdown of lactate in the sample according to the reaction:
<CHM>.

The enzymes may comprise one or more enzymes, e.g., lactase and glucose oxidase, for the breakdown of lactose in the sample according to the reactions:
<CHM>
<CHM>.

The enzymes may comprise one or more enzymes, e.g., urease, for the breakdown of urea in the sample according to the reaction:
<CHM>.

As mentioned, the enzymes produce a conversion component from a target analyte in the sample and the hydrophobic material <NUM> may be selected to be one that is converted from the hydrophobic material <NUM> to the hydrophilic material <NUM> as described herein via the conversion component. In certain embodiments, the conversion component such as the produced hydrogen peroxide may also or instead react with a dye <NUM> at an end <NUM> of a respective reaction channel <NUM> as was shown in <FIG>. The dye <NUM> may provide a visible or readable indication that the enzymatic reaction (with the target analyte or a downstream product from a reaction with the target analyte) has taken place and that hydrogen peroxide has been produced throughout a length of the reaction channel <NUM>.

Referring now to <FIG>, there is shown another embodiment of a device <NUM> having two reaction channels 14A and 14B. Reaction channel 14A comprises one or more enzymes <NUM> for the breakdown of a target analyte in a sample introduced into the device <NUM>. In the embodiment shown, a sample may be introduced at sample inlet <NUM>. If the sample includes the desired target analyte, the one or more enzymes <NUM> facilitate the breakdown of the target analyte to the conversion component through one or more steps in the reaction channel 14A, wherein the conversion component will react with a dye <NUM> which is disposed within the channel (along the length) or at an end thereof as shown to provide a change in a property of the dye indicative of a presence of the target analyte.

For example, the conversion component may react with the dye <NUM> to provide a readable or visible indication if and when the sample has reached the dye <NUM> at the end of the reaction channel <NUM>. Alternatively, the dye may be additionally distributed along a longitudinal length of each channel 14A, 14B from sample inlet <NUM> to end <NUM>. In the embodiment shown in <FIG>, reaction channel 14B does not comprise enzyme(s) and thus may serve as a control to correct for any unspecific reactions that may induce any color change in the sample. In certain embodiments, the dye <NUM> may comprise a hydrophobic material.

Referring now to <FIG>, there is shown another embodiment of a device <NUM> in accordance with an aspect of the present invention having a plurality of reaction channels <NUM>, each with differing concentrations of the one or more enzymes <NUM>. For example, as shown, the device <NUM> in each of <FIG> has five arms having <NUM>, <NUM>, <NUM>, <NUM>, and <NUM> of one or more enzymes <NUM>. In the case of multiple enzymes, each reaction channel <NUM> may have the same concentration of enzymes or a differing amount. In addition, each channel 14includes a dye <NUM> as described herein disposed uniformly within the reaction channel <NUM> bounded at least in part by the barrier material <NUM>.

Once the sample is introduced onto sample introduction site <NUM>, a readable or visible indication that the sample has contacted the dye <NUM> within a respective reaction channel <NUM> will only be produced if a target analyte in the sample, e.g., creatinine, fully reacts with the enzymes <NUM> in the reaction channel <NUM> to produce a conversion component that will react with the dye <NUM> to produce a color change, e.g., hydrogen peroxide. If the creatinine (in this case) is below the enzyme concentration, it is contemplated that no color change of the dye <NUM> will take place along the entire length of the reaction channel. Thus, with reference to <FIG>, it can be seen that the test results in <FIG> indicate that there was sufficient creatinine in the sample to produce an amount of hydrogen peroxide sufficient to provide a positive indication for the <NUM>, <NUM>, and <NUM> channels, but not <NUM> or <NUM>. Thus, it can be deduced that the unknown sample has creatinine content sufficient to react with between <NUM> to <NUM> of the enzyme(s) disposed in the channel <NUM>.

In alternate embodiment, referring again to <FIG>, the reaction channels <NUM> may comprise the same concentration of the one or more enzymes <NUM>, but selected ones of the reaction channels <NUM> may be provided with a different concentration of the dye <NUM> at an end thereof or along a longitudinal length of the channels <NUM>. If the sample has a sufficient amount of a target analyte to produce a sufficient amount of the conversion component (via one or more enzymes) to react with the dye <NUM> in the channel, it may be determined from the dye <NUM> that the sample has at least a concentration of the target analyte which corresponds to the amount of dye <NUM> undergoing a color change in the respective channel. For example, all of the dye <NUM> at an end of the channel <NUM> or throughout a channel <NUM> may undergo a color change indicative of a presence of a corresponding amount of the target analyte.

In certain embodiments, the base member <NUM> shown in <FIG>, for example, is entirely self-supporting. In other embodiments, the devices described herein may be mounted on a backing. The backing may be formed from a liquid impermeable material, such as a polymeric material, for example. The base member <NUM> may be secured to the backing by any suitable structure such as tabs, clips, an adhesive, or the like. In still another embodiment, the base member <NUM> may be disposed (sandwiched) between a first backing and a second backing and secured thereto by any suitable structure or process, such as by laminating and/or the use of tabs, clips, an adhesive, or the like.

If a laminate structure is used to house the base member <NUM> between a first backing and a second backing, the laminate structure may comprise a commercially available laminate pouch made from a polymeric material and a suitable heat melt adhesive as is known in the art. In this embodiment, the base member <NUM> may be positioned between the first backing and the second backing and the backings, base member, and reagent(s) may be collectively laminated under pressure and/or heat to form an enclosed device. In addition, in this embodiment, one or more first apertures may be provided in the backings to serve as a respective sample port for receiving a sample to be distributed to the reaction channels in fluid communication with the sample port. In addition, the device may comprise one or more second apertures disposed over any one or more of the reaction channels <NUM> to serve as respective vents in the device for allowing a sample to move up the reaction channels.

Once the sample has been introduced into a device as described herein and the desired duration has expired for the subject assay has been completed, the results may be determined by visual inspection or alternatively by other suitable methods and equipment known in the art. In certain embodiments, the assay result(s) may be readily determined as set forth above by having different concentrations in different reaction channels, for example. The results may then be compared to those of known standards as is known in the art that are determined concurrently or otherwise.

In certain embodiments, the assay results are colorimetric in nature and provide for example, a deeper or darker color with an increasing amount of the target analyte. In such cases, the assay results may be recorded by taking an image of the device after completion of the assay(s) thereon. The images can be recorded and stored on smart phones, scanners, cameras, and the like. In certain embodiments, an image is taken of the relevant portion of the device before and after the testing for comparison utilizing a suitable software program, such as the Eyedropper tool from Adobe Systems, Inc. Specific properties, such as intensity, can be measured from the recorded images and compared to values of a calibration curve created from known standards. In another embodiment, the samples may be read by fluorescence detection as is known in the art. In an embodiment, the recorded images may be transmitted and/or stored on a computer comprising a microprocessor comprising hardware or software configured for processing and analysis of the imaging data. In certain embodiments, the data and/or results may be transmitted remote site over a network.

Claim 1:
A diagnostic device (<NUM>) comprising:
a substrate (<NUM>) comprising a plurality of reaction channels (<NUM>) defined by a barrier material (<NUM>) and form a predetermined pattern (<NUM>), wherein at least some of the reaction channels (<NUM>) comprise an amount of a hydrophobic material (<NUM>) disposed on the substrate;
wherein the hydrophobic material is selected to be converted from the hydrophobic material (<NUM>) to a hydrophilic material (<NUM>) upon contact with a conversion component within or derived from a sample introduced to the reaction channels (<NUM>),
wherein each of the plurality of reaction channels (<NUM>) comprises a dye (<NUM>) at an end (<NUM>) of the respective channels, wherein the dye (<NUM>) is selected to provide a visible or readable indication that a sample introduced to the device has traveled along a length of the reaction channel to the dye, and
wherein the conversion of the hydrophobic material (<NUM>) into the hydrophilic material (<NUM>) is stimulated via an oxidation-triggered reaction with hydrogen peroxide,
wherein the conversion from hydrophobic material (<NUM>) to hydrophilic material (<NUM>) means that upon reaction with the conversion component, the hydrophobic material (<NUM>) becomes more hydrophilic than prior to contact with the conversion component,
wherein the substrate (<NUM>) comprises a surface within the reaction channels (<NUM>) modified with an alkyl ketene dimer as follows:
<CHM>