Tests have been developed to detect the presence of analytes in bodily samples, including in point-of-care formats that allow health care professions to quickly determine a patient's condition. These tests typically involve antigen-antibody reactions or some other ligand-ligand receptor binding event, and may involve radioactive, enzymatic, fluorescent, or other detectable labels. Many such tests are designed to make a qualitative determination by detecting the presence or absence of the analyte in the sample at or above a specified level or concentration.
However, a binary test result indicating that an analyte is present or absent in a sample at or above a detectable concentration does not necessarily provide the most useful information to the clinician, the patient, or the person administering the test. For example, the presence of cardiac troponins (e.g., cTnI), which are markers of myocardial damage, in patient serum can be indicative of, or associated with, numerous conditions, including myocardial infarction as well as secondary ischemic and non-ischemic injuries such as coronary intervention, myopericarditis, septicemia, cardiac trauma, chemotherapy, and renal failure. See Sharma et al., Cardiac Troponins, J. Clin. Pathol. 57:1025-1026 (2004). Thus, the presence of cardiac troponins in serum does not necessarily indicate that a patient is experiencing an acute cardiac event (e.g., myocardial infarction or MI). Further, the absence of such levels does not necessarily exclude an acute cardiac event (such as MI), since troponin levels increase in serum over the course of about 4 to 12 hours after such an event. It is instead important to determine whether troponin levels are rising over time in a manner consistent with an acute cardiac event.
A point-of-care test that has the ability to provide accurate, semi-quantitative, convenient, and cost effective information concerning the level of analytes in samples, including markers of myocardial injury, would fill a great need.
The present invention provides methods and devices for detecting the presence of two or more threshold levels of an analyte in a sample. In various embodiments, the invention provides convenient point-of-care tests for determining the condition of a patient, so as to guide cost effective health care.
In one aspect, the present invention provides a device for the detection of at least two threshold levels of a marker of myocardial damage or injury in a patient sample. Rising levels of such markers of myocardial injury or damage, which include cardiac troponins (e.g., cTnT or cTnI), myoglobin and CK-MB, can be indicative of myocardial infarction and other acute cardiac events described herein. The device may be suitable for a point-of-care determination, and may be administered by a health care professional or by an untrained person, to determine the need for hospitalization or emergency care.
In accordance with this aspect, the device involves a lateral flow membrane and binding reagents to form a detectable complex in the presence of a marker of myocardial injury or damage (“biomarker”). The device comprises a sample application zone, and one or more fluid flow paths in fluid communication with the sample application zone. The fluid flow paths comprise a first biomarker capture zone and a second biomarker capture zone, which may be in series on a single flow path or may be in separate flow paths. The first capture zone is configured to detectably capture the biomarker when present in the sample at or above a first threshold level, and the second capture zone is configured to detectably capture the biomarker when present in the sample at or above a second threshold level. Thus, the device provides semi-quantitative information for determining or tracking the biomarker levels in a patient, and provides versatile information for determining the condition of the patient in a point-of-care format.
For example, the device may contain binding reagents for the detection of at least two threshold levels of a cardiac troponin, such as cTnI. In such embodiments, the first threshold level may be indicative of the presence of cTnI in blood circulation, and may correspond to about 0.04 ng/mL and provide for more specific clinical evaluation. For example, a level of cTnI above this threshold indicates that the patient should be monitored for rising cTnI levels, which is indicative of a potential cardiac event. The second threshold level may be indicative of an acute cardiac event, and may correspond to about 0.1 ng/mL of cTnI in the circulation. A level of cTnI above the second threshold level is indicative of an acute cardiac event, such as MI. The device may also provide for a determination of three or more threshold levels of cTnI in certain embodiments, to enhance the sensitivity and/or specificity and/or range of the test, and/or to provide for an even further specific clinical evaluation.
The fluid flow path(s) are generally formed by one or more bibulous, absorbent, and/or porous membranes, and each flow path may include a control zone that produces a detectable signal as an indication of successful sample flow. In some embodiments, the fluid flow path may further include membranes or pads of various porosity to filter cells and/or debris, which are generally located in proximity to the sample application zone. In these or other embodiments, the fluid flow path may comprise one or more reagent pads housing binding reagents, and/or may include an absorbent pad at the terminal end to help drive sample flow.
The biomarker (e.g., cTnI) is detectable, for example, in the sample by formation of a capturable and detectable complex, formed with a first binding member and a second binding member that are included in the device (e.g., in the reagent pad) or added to the sample (e.g., in a preincubation step). The first binding member and the second binding member can be immunoreagents as described in detail herein. The first binding member has an attached or bound detectable label which can be visualized or detected upon immobilization of the complex at a capture zone. Various suitable labels are described herein. The device may include one or a plurality of second binding members to allow capture or immobilization of the complex at the specific capture zones. Particularly, each second binding member is immobilized at a capture zone or is capable of being immobilized at a particular capture zone during sample flow. For example, at least one second binding member may be capturable at a capture zone by a streptavidin-biotin interaction, an antibody-antigen interaction, or by hybridization of complementary or substantially complementary oligonucleotides. The first and/or second binding members may be diffusively bound in the flow path(s) upstream of the cTnI capture zone(s), such that the biomarker in the sample forms capturable and detectable complexes with the first and second binding members during sample flow.
In some embodiments, the first capture zone and the second capture zone are in different, parallel or bidirectional, flow paths in fluid communication with the sample application zone. For example, the device may comprise two, three, or more flow paths, each configured to determine a different threshold level of the biomarker in the sample. In some embodiments, the device may comprise at least a second sample application zone, and corresponding flow path or flow paths, for repeating the test within a period of time to detect rising analyte levels.
The device is generally configured for the detection of the biomarker at a plurality of threshold levels. In some embodiments, the first capture zone has a first amount of immobilized capture agent, and the second capture zone has a second amount of said immobilized capture agent, and so on for additional capture zones, so as to detectably capture different threshold levels of the marker at each capture zone. The immobilized capture agent may be, for example, streptavidin, biotin, an antibody, or a natural or artificial polynucleotide, with the opposing binding member being conjugated to an analyte-specific binding reagent (“the second binding member”). In other embodiments, the first capture zone comprises an antibody with a first affinity for the biomarker, and the second capture zone comprises an antibody with a second affinity for the biomarker, so as to detectably capture the biomarker at different threshold levels. Low and high affinity antibodies may be non-diffusively bound to respective capture zones, or may be directed to particular capture zones through the use of specific capture agents, such as streptavidin or polynucleotide capture agent(s), among others. For example, polynucleotide capture agents having different sequences may be used to direct low and/or high affinity antibodies to particular capture zones.
In still other embodiments, the capture zones are continuous, with threshold or relative levels being identified by the relative length of the detectable immunocomplex captured along the flow path.
In another aspect, the invention provides a semi-quantitative method for evaluating the level of a marker of myocardial injury or damage in a patient sample, such as a cardiac troponin (e.g., cTnI). The method comprises applying a test sample to a device of the present invention, and detecting the presence or absence of a specific detectable signal in the capture zones. The patient may have one or more symptoms of an acute cardiac event, and/or may have a chronic heart condition, making a rapid troponin (e.g., cTnI) determination potentially critical for determining the need for emergency intervention. Further, the patient may have a chronic medical condition associated with specific circulating levels of cTnI, such as renal disease, previous cardiac trauma or surgical intervention, or septicemia, such that a method for quickly and accurately detecting rising levels of cTnI over potential background levels would be desirable to avoid the expense of unnecessary emergency care. Where the patient sample shows a level of the marker at the first threshold level, but below the second threshold level, the test is repeated within about one to about ten hours to detect rising levels of the marker.
For example, a detectable signal indicating a first threshold level of cTnI is suggestive that the patient be monitored for signs and symptoms of a myocardial infarction, and in some embodiments, the test is repeated after a period of time to detect rising levels of cTnI. A detectable signal indicating a second threshold level of cTnI is suggestive that the patient be treated for a potential acute cardiac event, such as an MI. Where the patient does not have a level of cTnI detectable with the test device, the patient is determined to not be experiencing an acute cardiac event, or has a low risk of an adverse outcome.
In another aspect, the present invention provides a device and method for the detection of at least two threshold levels of an analyte in a test sample. In this aspect, the analyte need not be a marker of myocardial injury, but may be any marker whose level in a sample can suggest more than one medical treatment decision point. Such markers may be indicative of stroke or brain trauma, an allergic response to a therapeutic agent (e.g., IgE antibodies to a therapeutic agent), or a measure of a particular disease activity, including autoimmune disease by detection of autoantibodies or determination of cytokine profiles.
In this aspect, the device generally comprises a sample application zone, and one or more fluid flow paths in fluid communication with the sample application zone. The fluid flow path(s) include a first analyte capture zone and a second analyte capture zone. The first and second capture zones are in series on a single flow path or are in separate flow paths. The first analyte capture zone comprises a first amount of an immobilized capture agent to detectably capture, directly or indirectly, the analyte (e.g., as present in a detectable complex) when present in the sample at or above a first threshold level. The second analyte capture zone comprises a second amount of the immobilized capture agent configured to detectably capture, directly or indirectly, the analyte (e.g., as present in a detectable complex) when present in the sample at or above a second threshold level. Binding reagents for forming detectable complexes (e.g., immunocomplexes) with the analyte may be present in the device in the fluid flow path, or combined with the sample in a preincubation step.
In various embodiments, the immobilized capture agent is one member of a binding pair selected from streptavidin-biotin, antibody-antigen, or complementary or substantially complementary natural or artificial oligonucleotides, with the opposing binding member being conjugated to one of the binding reagents for forming the complex (e.g., the second binding member).
The present invention provides methods and devices for detecting the presence of two or more threshold levels of an analyte in a sample. In various embodiments, the invention provides convenient point-of-care tests for determining the condition of a patient, so as to guide cost effective health care.
Analyte concentrations in bodily fluid samples are useful indicators for diagnosis or prognosis of disease and other clinical conditions. As described herein, multiple threshold (i.e., cutoff) levels on a single test device enhances the information delivered by the test, and provides the opportunity to quickly evaluate medical treatment options. Furthermore, measurement of an analyte or analytes at multiple threshold levels may be useful to monitor progression of a disease state or medical condition, or to determine the presence or absence of a medical condition, by measuring the evolution of the analyte level through serial measurements over a period of time.
Measurement of an analyte concentration against multiple threshold levels using a semi-quantitative test, such as a lateral flow test, may be particularly useful, since more than one clinical decision point (and therefore, the resultant course of action) can be addressed in a single evaluation at the point of care, and may be conducted by an untrained person.
In various embodiments, the device and methods of the invention avoid the requirement for cumbersome or inconvenient instrumentation often required for quantitative analysis, making the invention ideal for the home, rural areas, ambulances, airplanes, and underdeveloped locales, for example. The invention provides an easily interpretable test sufficient to signal to an inexperienced user the need for emergency health care.
The device in certain embodiments detects analytes associated with myocardial injury or damage, whose presence in serum are indicative of acute myocardial events, such as myocardial infarction. Such analytes include cardiac troponins (e.g., cTnT, cTnI, and cTnC), myoglobin, and CK-MB. Other markers of myocardial injury are described in U.S. Pat. No. 6,461,828, which is hereby incorporated by reference in its entirety. The device may be configured to detect a plurality of threshold levels of at least one, two, or three markers of myocardial injury.
The analyte may be at least one cardiac troponin (e.g., cTnI, cTnC, cTnT). The level of circulating cardiac troponins is specific for myocardial damage. Further, the level of the cardiac troponins in serum changes over time in the progressive development of MI. For example, if a patient presents with MI-like symptoms such as unstable chest pain and non-specific changes on ECG but has a blood concentration of cTnI lower than 99th percentile of normal when symptoms first appear, then the subject should be tested again in six to nine hours. An increase in cTnI over time provides more accurate risk assessment and specificity for myocardial necrosis, and rules out non-specific causes of elevated troponin such as renal damage. An increase in cTnI of 20% to 30% on successive tests is considered significant.
In certain embodiments, the device determines the presence of cTnI in a patient sample above a plurality of threshold levels. Cardiac troponin I (cTnI) increases for the first 4 to 12 hours after a myocardial infarction (MI). For example, if a subject's circulating troponin I level is greater than about 0.04 ng/mL but is less than about 0.1 ng/mL, there is a suspicion of myocardial infarction or acute cardiac event, but such a level of troponin I could be due to causes other than myocardial infarction such as renal disease. Thus, a single measurement reporting a blood cTnI amount that is greater than 0.04 ng/mL, but less than 0.1 ng/mL, may not be definitive. If, however, several hours after the first measurement (e.g., from two to eight hours later), a second measurement shows that the subject's cTnI level is greater than about 0.1 ng/mL, this indicates that the subject's troponin I level has increased over time, and that an MI is significantly more likely.
Therefore, in particular embodiments related to cTnI, the device is configured to detect a low threshold level of cTnI in patient blood or serum, the low threshold level being indicative of the presence of cTnI. This threshold may be from about 0.01 ng/mL to about 0.06 ng/mL, or in certain embodiments, is about 0.04 ng/mL. In these embodiments, the device is also configured to simultaneously detect a higher threshold of cTnI that is indicative of an acute cardiac event, such as MI. The higher threshold of cTnI may correlate to about 0.08 ng/mL to about 0.2 ng/mL in patient blood or serum, or about 0.1 ng/mL in particular embodiments. If the initial measurement with the test device shows cTnI levels greater than about 0.1 ng/mL, then the risk of an adverse event such as MI or death is about 2.2- to 3.0-fold higher as compared to if cTnI were less than 0.1 ng/mL. If the initial measurement shows cTnI levels in blood or serum are less than about 0.04 ng/mL, then an MI would be highly unlikely, unless the test was performed very early in the development of MI.
In some embodiments, the device is configured to determine the presence of a third threshold level of circulating cTnI. The third threshold level may be from about 0.2 ng/mL to about 0.7 ng/mL (e.g., about 0.5 ng/mL). A level of cTnI of approximately 0.5 ng/mL or more has a high specificity for MI. A subject whose blood or serum cTnI levels is about 0.5 ng/mL or more would likely be experiencing myocardial damage. This system of three threshold levels may be particularly meaningful for the individual performing the test at home following the onset of acute chest pain or other symptoms of MI, including for patients that have a history of acute and/or chronic heart conditions, and/or who experience other ailments for which cTnI may be present in the circulation, such as renal disease or prior cardiac trauma or intervention, or carditis (pericarditis or endocarditis). In the absence of other symptoms or indications, the test result may provide information regarding the need to seek immediate medical care.
In some embodiments, at least two analytes are detected by a single test device. The two analytes may be specific markers for MI. For example, in one embodiment, the test device comprises at least one capture zone, specific for troponin I, and at least a second capture zone, specific for troponin T. The detectable thresholds for each troponin are such that one is selected to “rule in” MI (a low threshold indicating the presence of a circulating troponin), while the other is selected to “rule out” MI (a high threshold that is indicative of MI or an acute cardiac event). Since both troponin I and troponin T are specific for MI, but are genetically coded for by different genes, depletion of one molecule by its specific capture zone on a lateral flow device would not affect the levels of the other molecule for detection by its specific capture zone on that device.
The device may be configured to determine at least one, or a plurality of threshold levels for a second marker of myocardial injury or status, such as myoglobin or CK-MB. Such markers are described in U.S. Pat. No. 5,290,678, which is hereby incorporated by reference in its entirety.
In these and other embodiments, the device can provide for a semi-quantitative determination of an additional marker of cardiac status, such as NT-proBNP, BNP, proBNP, ANP, or pro-ANP, as also described in U.S. Pat. No. 6,461,828, which is hereby incorporated by reference.
In other embodiments, the device determines a plurality of threshold levels for one or more markers of brain injury or trauma, as a determination of stroke or other brain trauma. For example, in some embodiments, the markers include one or more of myelin basic protein (MBP), the beta isoform of S 100 protein (S 100), neuronal specific enolase (NSE), Thrombomodulin, Glucose Transporter I in the dimeric or tetrameric form, Neurothelin, Gamma Glutamyl Transpeptidase, and P-glycoprotein. These and other markers are described in U.S. Pat. No. 6,780,606, which is hereby incorporated by reference in its entirety. Thus, the invention provides devices and methods for tracking the circulating levels over time, as described and exemplified herein for cardiac markers.
In still other embodiments, the device determines the presence of inflammatory or immune response markers, which may be monitored upon exposure to a drug or potential antigen, or other stimulus. Such markers may be antibodies against a therapeutic agent to monitor efficacy of, or reaction to, a therapeutic intervention, or the marker may be an autoantibody indicative of an autoimmune disease to monitor disease activity over time, including in response to therapy.
Generally, the analyte may be a toxin, an organic compound, a protein (including an immunoglobulin), peptide (e.g., peptide hormone), microorganism or component thereof, vitamin, metabolite, drug (including those administered for therapeutic purposes as well as those taken for illicit purposes), pollutant, pesticide, or antibodies to any of the foregoing.
Generally, the sample may be any material to be tested for the presence and/or concentration of an analyte, including a biological or environmental sample. In various embodiments, the sample is a body fluid sample such as whole blood, serum, plasma, urine, sweat, saliva, cerebrospinal fluid, nasal secretions, or the like. Where the device is configured to detect one or more markers of myocardial injury, the sample may be blood, serum, or plasma in some embodiments.
The device and methods of the invention employ a lateral flow test. Lateral flow tests are well known, and are described for example in U.S. Pat. Nos. 6,461,828, 6,177,281, 7,390,674, and U.S. Pat. No. 7,491,551, which are hereby incorporated by reference in their entireties. The lateral flow test generally comprises a sample application zone (e.g., for applying fluid sample for testing), and one or more fluid flow paths in fluid communication with the sample application zone. The fluid flow paths comprise a first biomarker capture zone and a second biomarker capture zone, which may be in series on a single flow path or may be in separate flow paths. The term “fluid communication” means that the sample can flow from a first component to a second component of the flow path, or vice versa. A first component is in fluid communication with a second component, even if there is an intervening component. For example, a sample application zone, a reagent zone (e.g., that houses the assay immunoreagents), and lateral flow membrane that includes one or more capture zones, may be situated serially on a test device, and will be in fluid communication. The device may further comprise one or more components for the separation of blood cells or large debris, including filters of appropriate porosity.
The lateral flow test involves a lateral flow membrane and binding reagents to form a detectable complex in the presence of the marker or analyte of interest. The complex (e.g., immunocomplex) comprises a first reagent specific for the analyte, and having an attached or bound label, and the second reagent is immobilized or capturable, and is also specific for the analyte of interest. The binding reagent may be an immunoreagent, which is generally an antibody or portion thereof. In various embodiments, the immunoreagent is a monoclonal antibody, a polyclonal antibody, multispecific or bispecific antibody, chimeric antibody, or antibody portion or fragment that binds to the analyte of interest. The antibody may be of any isotype, including IgA, IgD, IgE, IgG, and IgM, and subtype thereof.
The immunoreagent may further be an antigen-binding antibody portion or fragment, such as a Fab, Fab′, F(ab′)2, Fv fragment, a single-chain antibody molecule, a multispecific antibody formed from any fragment of an immunoglobulin molecule comprising one or more antigen-binding domains.
In embodiments where the binding reagents are immunoreagents, at least one immunoreagent (e.g., “the first immunoreagent” or “the first binding member”) contains an attached or bound label detectable by visual or instrumental means. One or more labels can be used in the devices and methods of the invention, e.g., in order to visually distinguish capture zones in different flow paths, or to distinguish control zones. In other embodiments, two distinct labels are used to visually differentiate different analytes. Various labels suitable for use in the present invention include labels which produce signals through either chemical or physical means. Such labels include enzymatic labels (e.g., that produce a detectable signal in the presence of substrate), chromogens, dyes, catalysts, fluorescent or fluorescent-like compounds and/or particles, magnetic compounds and/or particles, chemiluminescent compounds and or particles, and radioactive labels. The label may be covalently or non-covalently bound, directly or indirectly, to the first immunoreagent, which is specific for the target analyte. In certain embodiments, the label remains detectable for at least 2, at least 4, at least 6, or at least 8 hours after conducting the test, such that a repeat test several hours later can be directly compared to the first result.
At least one immunoreagent (e.g., “the second immunoreagent” or “second binding member”) is immobilized at a capture zone, or is capturable at said capture zone through a specific binding pair interaction. Exemplary binding pair members include complementary or substantially complementary oligonucleotides, ligand-receptor, antibody-antigen, or streptavidin-biotin. This second binding member may provide the basis for detecting a plurality of threshold levels of the analyte. For example, as discussed in greater detail below, the capture zones may employ different amounts or concentrations of the same binding pair member so as to immobilize or capture the second immunoreagent at different levels. Alternatively, the capture zones may employ different immunoreagent capture schemes, so as to distinguish between second immunoreagents having different affinities for the analyte of interest. Particularly, low affinity and high affinity antibodies can be recognized by the identity of the conjugated capture reagent.
Each flow path may further include one or more control zones downstream of the one or more capture/detection zones as an indication of successful sample flow. The control zone, in one embodiment, may have a means for capturing or detecting the presence of unbound labeled binding reagent at the terminal end of the flow path. For example, the control zone may comprise immobilized anti-mouse IgG, where the first binding reagent (e.g., the labeled immunoreagent) is a mouse monoclonal antibody. Other sample flow controls are known in the art, and may be used in accordance with the invention.
The test device may further comprise an absorbent pad downstream of, and in fluid communication with, the lateral flow membrane to help drive sample flow. Such components for lateral flow assays are also well known.
Further still, additional components may be employed to premix sample and binding agent prior to application to the device. Exemplary components for this purpose are described in WO 2007/098184, WO 2009/014787, and WO 2010/132453, each of which are hereby incorporated by reference in their entireties.
The lateral flow substrates are generally porous, absorbent, and/or bibulous substrates or membranes that allow transport of fluid samples, e.g., by capillary action. A variety of materials can be used as the lateral flow substrate, and such materials include organic or inorganic polymers, and natural and synthetic polymers, including but not limited to, agarose, cellulose, nitrocellulose, cellulose acetate, other cellulose derivatives, dextran, dextran-derivatives and dextran co-polymers, other polysaccharides, glass, silica gels, gelatin, polyvinyl pyrrolidone (PVP), rayon, nylon, polyethylene, polypropylene, polybutylene, polycarbonate, polyesters, polyamides, vinyl polymers, polyvinylalcohols, polystyrene and polystyrene copolymers, polystyrene cross-linked with divinylbenzene or the like, acrylic resins, acrylates and acrylic acids, acrylamides, polyacrylamide, polyacrylamide blends, co-polymers of vinyl and acrylamide, methacrylates, methacrylate derivatives and co-polymers thereof.
In one embodiment, the lateral flow substrate comprises nitrocellulose, e.g., any nitric acid ester of cellulose. In certain embodiments, the lateral flow substrate comprises nitrocellulose in combination with carboxylic acid esters of cellulose.
The pore size of the substrate (e.g., nitrocellulose substrate) may vary. For example, the pore size may be from about 1 μm to about 20 μm, or from about 8 μm to about 15 μm, or from about 10 μm to about 12 μm.
Various components of the flow path may employ different substrate materials, and/or different pore sizes to control the fluid flow, control the ability of reagents to diffusively bind to the substrate material, and/or control the filtration of debris.
Components of the flow path may in some embodiments be treated with blocking agents such as bovine serum albumin, whole animal serum, casein, or non-fat dry milk.
The lateral flow substrate defining the at least one fluid flow path may be backed by, or laminated upon, a generally water impervious layer, e.g., Mylar®. However, in some embodiments the lateral flow substrate may be self-supporting. When employed, the backing is generally fastened to the matrix by an adhesive. A water impervious backing is generally used for substrates of low thickness.
Generally, the fluid flow paths are defined by at least one sample application zone, and at least one lateral flow substrate. Where multiple lateral flow substrates are employed, the multiple lateral flow substrates may be in fluid communication with the same or different sample application zones. Reagent zones or pads are optional.
In one embodiment, the test device includes one lateral flow membrane in fluid communication with a single sample application zone (
In another embodiment, the test device includes two lateral flow membranes, as shown in
At least two separate sample application zones may also be employed, each in fluid communication with a separate, independent, lateral flow substrate, where each lateral flow substrate defines a separate fluid flow path. The separate fluid flow paths may further include separate reagent zones or pads. The test device may have additional sample application zones (e.g., three, four or five sample application zones), each corresponding to separate fluid flow paths on separate lateral flow substrates, or corresponding to separate fluid flow paths on the same lateral flow substrate (e.g., a lateral flow membrane divided into a plurality of subsections by one or more impermeable barriers). During use, a measured volume of fluid sample is applied to each sample application zone.
Parallel, independent lateral flow substrates may also be employed in a single test device by positioning a sample application zone as shown in
In another embodiment, the test device includes one sample application zone for multiple lateral flow substrates. In this embodiment, the sample is applied to the test device once, and the sample application zone is in fluid communication with each of the lateral flow substrates or fluid flow paths (
In certain embodiments, the device has a design that enables two or three tests, such that tests may be conducted over the course of from 2 to 10 hours, to monitor increasing analyte concentrations.
The device and methods described herein employ at least two capture zones for discriminating two threshold levels of analyte. The at least two capture zones may be arranged serially on a single flow path, or may be in separate flow paths, each designed to capture a different detectable threshold concentration of the analyte.
One multiple capture zone embodiment is presented in
The capture zone with the high affinity antibodies captures and retains a larger amount of analyte, and therefore shows a visible signal at a lower analyte concentration, than the capture zone with the low affinity capture antibodies. In this design, the number of capture zones can be readily extended to more than two, through the use of more than two antibody affinities. Antibodies can be deposited either directly or through a binding agent such as BSA or IgG or amino dextran or other protein molecule to which the antibody has been conjugated. Such binding agents can help amplify a signal because of increased density of antibody on the binding agent, or because the binding agent may have a stronger interaction for the matrix material, or because the linkage forms a “tether” allowing greater avidity or binding capacity of the antibody by the reduction in steric hindrance.
In other embodiments, at least one of the second immunoreagents is not immobilized at its capture zone, but is conjugated to a binding moiety that directs it to a particular capture zone. Such binding interactions act to “sort” high affinity and low affinity immunoreagents during sample flow, and such binding moieties include biotin/streptavidin or complementary oligonucleotides (or derivatives thereof).
For example, as illustrated in
The capture zones may employ a variety of specific binding interactions to capture or immobilize the detectable immunocomplexes containing analyte, and these interactions include antigen/antibody, biotin/avidin, carbohydrate/lectin, complementary oligonucleotides (including pyranosyl RNA or DNA, or other oligonucleotide derivatives), receptor/ligand molecules including hormone/hormone receptor, enzyme/cofactor, or specific protein interaction, and metal/chelator.
In certain embodiments, an oligonucleotide is bound directly or indirectly (e.g., through a chemical linker) to the surface of the lateral flow substrate at the capture zone(s), with the complementary oligonucleotide conjugated to an immunoreagent for capturing the immunocomplex (see
In some embodiments, the oligonucleotide is selected from DNA, RNA, DNA-RNA hybrids, oligonucleotides comprising locked nucleic acids, pyranosyl-RNA (pRNA), pyranosyl-DNA (pDNA), 2′-O-methyl oligonucleotides, and 5′-5′ inverted oligonucleotides. The use of oligonucleotide agents to capture oligonucleotide conjugates is described in U.S. Patent Application Publication 2005/0208576, which is hereby incorporated by reference.
The complementary oligonucleotides may have the same or similar hybridization efficiencies, and conjugated or linked to high and low affinity antibodies, to thereby provide the basis for discriminating different threshold levels of analyte. See
Alternatively, the concentration of the same specific binding pair member can be varied (e.g., immobilized) in each capture zone to allow for the capture of different levels of a target analyte. The zones with a relatively higher concentrations of immobilization reagent thus capture more analyte and produce a positive signal at lower analyte concentrations. For example, streptavidin may be applied to the capture zones at concentrations of from 0.1 mg/mL to about 10 mg/mL, or from 0.1 to 5 mg/mL, thereby forming different capture zones with different detectable thresholds of a biotin conjugated and labeled immunocomplex formed in the presence of analyte.
In one embodiment, a test device includes a single lateral flow membrane with a single fluid flow path, which comprises serial capture zones (see, e.g.,
Similarly, for NT-proBNP, multiple cutoffs on a single test device would be useful since the clinical decision points are about 125 pg/mL and about 450 pg/mL (which are recommended CHF decision threshold values for individuals under 75 years of age and 75 years and older, respectively). These concentrations correspond to 1.5×10−15 and 5.4×10−15 mole of analyte, respectively, in a 100 μL sample. The analyte in a sample would be affected by a capture zone that retains on the order of 10−12 moles of analyte molecules. Therefore, for this analyte, serial capture zones that do not account for depletion of analyte on a lateral flow device would not be practical.
In certain embodiments, the device architecture exploits the analyte depletion phenomenon. A lateral flow test device, in one embodiment, is formed by layering multiple capture zones as sequential lines or regions, or by layering a capture zone as a continuous area formed of deposited capture moieties, on the test membrane. As analyte and reagent react and migrate along the device and are bound to the capture molecules, the analyte is removed from the migrating solution. Then, the number of detectable capture regions or length of the capture region is directly related to the quantity of analyte molecules originally present in the sample, and these embodiments are thereby able to extend the quantitative range of the device. The device according to this embodiment acts like a gauge to detect analyte levels, and is particularly useful for expanding the range of the assay.
In the case of a continuous capture area, the portion of the capture zone having visible label will be directly related to the quantity of analyte originally present in the sample. In this manner the amount of analyte could be measured in a semi-quantitative, thermometer-like fashion (see
At least one immunoreagent or binding member has a detectable moiety (e.g., a label). Exemplary labels include particulate labels such as colloidal metallic particles such as gold, colloidal non-metallic particles such as selenium or tellurium, dyed or colored particles such as a dyed plastic, dyed impregnated latex particles, organic polymer latex particles and liposomes, nanospheres, colored beads, polymer microcapsules, or other vesicles containing directly visible substances, and the like.
As for assays that do not directly detect label (e.g., with the naked eye), a fluorescent label such as fluorescein, europium, cyanine, or alexa dyes, a chemiluminescent label, a fluorescent-energy transfer label, a fluorescent quantum dot, a paramagnetic label, an electrochemical label using amperometric (either with direct or oscillating applied voltage) or carbon nanotube detection methods, can be used.
For example, detectable molecules include but are not limited to fluorophores as well as others known in the art as described, for example, in Principles of Fluorescence Spectroscopy, Joseph R. Lakowicz (Editor), Plenum Pub Corp, 2nd edition (July 1999) and the 6th Edition of the Molecular Probes Handbook by Richard P. Hoagland, each incorporated herein by reference in their entireties.
Directly visible labels include incorporation of dye-impregnated latex or other particles which have more functional groups than gold particles for conjugating to antibody, or are more visible than gold. In certain embodiments, silver-coated gold particles are employed, which can enhance the signal by one or two orders of magnitude. The use of quantum dots or nanospheres as colorimetric labels might also enhance signal. The use of larger gold particles (e.g., greater than the standard 40 nm diameter particle) may also provide enhanced sensitivity.
The label-bearing specific binding pair members may be diffusively bound to the lateral flow membrane upstream of the capture/detection zone. In these embodiments, when the sample migrates along a fluid flow path on the lateral flow membrane, it encounters the labeled specific binding pair member(s), and the analyte, if present in the sample, binds the label-bearing specific binding pair member. The analyte-specific binding pair member-label complex further migrates to the capture zone, and binds the capture binding pair member. Excess label can then be washed away.
The present invention provides devices, as described above, for the detection of multiple levels of one analyte, multiple analytes, or multiple levels of multiple analytes. In order to detect the presence of the test analyte, the analyte must be labeled, so that it can be visualized. Visualization can occur with or without the use of an external reader instrument.
In certain embodiments, the device uses an external reader to provide an objective result. The reader may provide a displayed, printable, or downloadable result in various embodiments. Use of an external reader may be advantageous such that labels of greater sensitivity may be employed, such as fluorescent labels.
The reader further provides the option of communication capabilities (e.g., via internet, cable, wireless, or GSM etc.) to automatically notify a healthcare or emergency healthcare professional upon a particular result requiring emergency action, or may be connected to an institution's health records, to store records of tests. The reader further provides various memory options, to acquire (for example, through alphanumeric input or through automatic barcode reading) the operator ID and patient ID, as well as date and time of test results, for detailed patient histories.
The present invention is further illustrated by reference to the following illustrative Examples.
In a lateral flow test device with four serial capture zones, sample comprising 10 ng/mL cTnI was applied. Over half the analyte was depleted by the first line (see
The purpose of the following study was to demonstrate the ability of an exemplary device to distinguish two concentrations of cardiac troponin I (cTnI) in a qualitative/semi-quantitative manner.
Mouse monoclonal anti-cTnI antibody attached to colored microspheres, ˜0.02%.
Rabbit polyclonal anti-cTnI antibody conjugated to biotin, ˜10 μg/mL.
Lateral flow membrane with immobilized streptavidin-carrier complex (SA). The low-sensitivity strips were prepared by applying SA to the membrane at ˜0.5 mg/mL and the high-sensitivity strips were prepared with SA at ˜2 mg/mL.
The samples tested by the assay were (1) Li-heparin human plasma, pooled, normal (NHP), and (2) NHP with recombinant cTnI diluted in it at fixed concentrations (concentrations confirmed by commercial cTnI immunoassay).
The test device comprises one high sensitivity lateral flow membrane (“strip”) and one low-sensitivity lateral flow membrane. The membranes are positioned parallel to one another, similar to the device shown in
Three sets of samples were tested, each in triplicate—(1) blank NHP (i.e., no recombinant cTnI), (2) NHP with recombinant cTnI at ˜50 pg/mL and (3) NHP with recombinant cTnI at ˜500 pg/mL.
Samples were applied at ˜240 μL per test device, incubated for approximately 15 minutes at ambient conditions. Each test device was then read visually and on a portable reflectometer at ˜550 nm (e.g., 520 to 550 nm).
Example of the collected data is given in the table 2 and
Analysis of the signal distributions within three standard deviation (SD) range of its average value on low-sensitivity strips indicated absence of analyte detection at low concentration.
Patents, patent applications, publications, product descriptions, and protocols which are cited throughout this application are incorporated herein by reference in their entireties.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US2012/054425 | 9/10/2012 | WO | 00 | 8/15/2014 |
Number | Date | Country | |
---|---|---|---|
61532433 | Sep 2011 | US |