The present invention relates to an immunoassay for detecting cardiac markers during early stages of a cardiac event, such as myocardial infarction. Particularly, the invention provides a device for detecting diagnostically relevant combination of two blood markers as early as half an hour upon an acute myocardial infarction symptoms onset.
About one million people have an acute myocardial infarction (AMI) each year in the United States alone, of whom 10% may die within one year, depending on the severity of the event and the quality of intervention. In any case, medical assistance, including primary percutaneous coronary intervention and/or thrombolytic therapy if needed, should be provided as promptly as possible. Shortening the duration between chest pain onset and reperfusion to less than about four hours was shown to be critical in reducing myocardial necrosis and improving heart function lowering 30-day mortality. [Ho Y. C. et al.: Crit. Care Med. 42 (2014) 1788-96]. Early diagnosis of the AMI is important, but the sensitivity of the classic ECG for diagnosing AMI in the patients presenting with ischemic-type chest pain is not much more than 50% [The Merck Manual, 17th Ed. (1999), p. 1673]. Blood cardiac markers are therefore of immense importance. Various proteins that leak out of injured myocardial cells into the bloodstream have served for assessing cardiac injury, including myoglobin or the enzymes like aspartate transaminase, lactate dehydrogenase, or creatine phosphokinase. Nowadays, it is mainly troponins which have been acknowledged as being enough specific for detecting myocardial damage. Unfortunately, cardiac troponins, although remaining elevated for up to 2 weeks after the AMI event, do not appear immediately and are well measurable only several hours after the AMI event, so that the first moments, when the correct diagnosis is most critical, are not well covered. It is therefore an object of this invention to provide a method for diagnosing acute myocardial infarction by detecting suitable blood markers. It has been found that heart-type fatty acid binding protein (HFBP) is another AMI marker, and conveniently the protein appears in the blood within about one hour and peaks within about five hours within the AMI event [Tanaka T. et al.: Clinical Biochemistry 24 (1991) 195-201; Van Nieuwenhoven F. A. et al.: Circulation 92 (1995) 2848-54], but the diagnostic accuracy of HFBP as a sole marker was found to be not sufficient in the clinical setting [Park S. Y. et al.: Clin. Neurol. Neurosurg. 115 (2013) 405-10]. It is another object of this invention to provide a method for diagnosing acute myocardial infarction by detecting more than one blood marker.
It is still another object of this invention to provide a device for diagnosing AMI which employs more than one blood marker of myocardial infarction.
It is a further object of this invention to provide a device for assisting in diagnosing AMI within the period of several hours after the AMI event.
Other objects and advantages of present invention will appear as description proceeds.
The present invention provides a device for detecting acute myocardial infarction (AMI) markers in a human blood sample, the device comprising a mixture of at least two antibodies or antibody conjugates which reacts with at least cardiac troponin (CT) and with heart-type fatty acids binding protein (HFBP). Said markers preferably comprise CT and HFBP, wherein said antibody conjugates simultaneously react with said markers present in said blood sample, thereby providing a visible signal if the concentration of each of said markers is higher than a certain predetermined threshold. The antibodies, or antibody conjugates, react with said blood markers only after separating the blood plasma from the blood cells; the blood cells do not contact said antibodies as is known to an expert, as the blood cells are first removed on a prefilter; usually the plasma migrates toward the antibody or the antibody conjugate to form a marker-antibody complex or a marker-antibody conjugate complex, which provides a visible signal either by itself or after reacting with additional reagents. The threshold for each marker is derived from the distribution of its blood concentration in healthy population. In one embodiment of the invention, said threshold is higher than the 95th percentile in said distribution for each of the markers. In another embodiment of the invention, said threshold is higher than the 99th percentile in said distribution for each of the markers. In a preferred embodiment of the invention, said threshold for each marker is lower than the maximal concentration of the marker in the blood which does not provide a visible signal during the reaction with said antibodies or antibody conjugates, if said marker is alone in the sample. In one embodiment, said threshold for CT is 0.5 ng/ml and said threshold for HFBP is 5 ng/ml in the device according to the invention. In another embodiment, said threshold for CT is about 1 ng/ml and said threshold for HFBP is about 10 ng/ml. In one embodiment, the device of the invention provides a visible signal if the concentration of CT in said blood sample is at least 0.5 ng/ml and simultaneously the concentration of HFBP in said blood sample is at least 5 ng/ml. In other embodiment, the device of the invention provides a visible signal if the concentrations of CT and HFBP in said blood sample are at least 1 ng/ml and 5 ng/ml, respectively. In a still other embodiment, the device of the invention provides a visible signal if the concentrations of CT and HFBP in said blood sample are at least 1 ng/ml and 10 ng/ml, respectively. Said troponin may comprise proteins selected from troponin-C, troponin-I, troponin-T, a complex of said troponins, or a mixture comprising at least two of said troponins. Preferably, troponin-I or troponin-T is employed as a cardiac marker. Said mixture of antibodies or antibody conjugates is usually immobilized in an immunoassay strip, in the device of the invention. Said strip may be a part of an immunoassay device, for example of a lateral flow immunoassay kit. In one embodiment, said immunoassay device comprises ELISA. Said mixture of antibodies or antibody conjugates is immobilized in an immunoassay strip as one narrow band, which is configured to change color in the presence of the antigens, namely of said AMI blood markers. Said visible signal is thus color-changing of said band, caused by a color forming reaction of the marker with an antibody conjugate. In another aspect of the invention, said mixture of antibodies or antibody conjugates may be immobilized in said strip as several narrow bands differing in said predetermined threshold and providing visible signals at different concentrations of said markers (differing in sensitivity). The device of the invention may advantageously comprise reference bands, exhibiting a comparative color intensity either before or after contacting with said blood sample. The comparative bands may comprise antibodies or antibody conjugates reacting with typical blood proteins (albumins, immunoglobulins, etc.), the antibodies or antibody conjugates being conjugated in such a way and immobilized in such an amount so as to provide a color signal of the desired intensity in contact with said blood sample. The comparative bands may comprise a color of the desired intensity present in the device before contacting said sample and stable also after contacting said sample. Said color of the desired intensity may correspond to the expected color signal provided by relevant markers concentrations in the blood sample. A set of comparative bands enables to assess the concentration of the cardiac markers in the blood sample, when comparing a visible signal provided by a blood cardiac marker or a combination of markers with the set of comparative bands.
In a preferred embodiment of the invention, provided is a device for detecting an AMI event which comprises one or more antibody mixtures simultaneously specific both to CT and HFBP, the antibodies or antibody conjugates being immobilized in an immunoassay strip as one or several narrow bands and reacting with cardiac markers CT and HFBP in at least one blood sample to provide visible signal(s) if the concentration of each of said markers is higher than a certain predetermined threshold, said strip further comprising reference bands exhibiting a comparative color intensities either before or after contacting with said blood sample, wherein said several narrow bands optionally react with said markers in said blood sample with different sensitivities and provide said visible signals at different marker concentrations. The device of the invention provides an assessment of the CT and/or HFBP concentration in said sample, based either on comparing the intensities of said signal(s) with said comparative intensities or based on comparing two signals corresponding to two different marker concentrations. In one aspect of the invention, the assessment of the CT and/or HFBP concentration in said sample provides an assessment of the time elapsed is between taking the sample and the AMI event. In one example of the device according to the invention, said predetermined threshold is 0.5 ng/ml for CT and 10 ng/ml for HFBP for one of said several narrow bands, wherein a positive signal indicates that an AMI event occurred in the donor of said sample at last one hour ago. In another example of the device according to the invention, said predetermined threshold is 1 ng/ml for CT and 20 ng/ml for HFBP for one of said several narrow bands, wherein a positive signal indicates that an AMI event occurred in the donor of said sample at last three hours ago. In other example of the device according to the invention, said predetermined threshold is 4 ng/ml for CT and 80 ng/ml for HFBP for one of said several narrow bands, wherein a positive signal indicates that an AMI event occurred in the donor of said sample at last nine hours ago. Combined signals of several “well-tuned” bands enables more accurate assessments. For example, a device according to the invention may comprise a band with a threshold of 0.5 ng/ml for CT and 10 ng/ml for HFBP, and another band with a threshold of 1 ng/ml for CT and 20 ng/ml for HFBP, wherein a positive signal in the former band together with a negative signal in the latter band indicate that an AMI event occurred in the donor of said sample at a time between about 3 and about 6 hours ago.
The invention provides a method of diagnosing cardiac event, particularly an AMI, comprising taking a blood sample of a subject suspected of such event, for example a subject suffering from ischemic-type chest pain, and applying the sample on an immunoassay device comprising a mixture of at least two antibodies or antibody conjugates which reacts with at least CT and HFBP. In another aspect of the invention, at least two samples are taken at two different times, wherein concentration assessments of the CT and/or HFBP in said two sample improves the accuracy in assessing the time of the AMI event.
The inventors found that simultaneous detection of two cardiac blood markers by employing a mixture of antibodies or antibody conjugates may obviate drawbacks of the previous methods aiming at early confirmation of a cardiac event in case of, for example, ischemic-type chest pain or other symptoms. The invention provides a one-step cardiac test device which enables a rapid diagnostic assessment in a subject suspected of a cardiac event, particularly an acute myocardial infarction (AMI), within the most critical period of several hours from the event. In one aspect, the invention provides a qualitative lateral flow immune chromatographic assay comprising a mixture of two antibodies or antibody conjugates, each of them specific to one cardiac marker, aiming at simultaneous detection of both markers at low concentrations characteristic for the early stages of the cardiac event, while the combined immunoassay signal provided by both markers, surpassing certain threshold level, indicates the event. In the preferred embodiment of the invention, one of the markers is a cardiac troponin (CT) and the other is heart-type fatty acid binding protein (HFBP). In one embodiment, HFBP is detected about half an hour upon symptoms onset while, of which levels at that time is about 5 ng/ml (basal levels in 95% of the healthy population are in the range of 0.5-3.5), whereas troponin-I becames detectable at about three hours after the symptoms, when its levels are above 1 ng/ml. For example, clinical results showed the additive effect of two markers, wherein each one alone was undetectable below specific concentration (usually 1 ng/ml for troponin and 5 ng/ml for HFBP), but both of them together in the same concentrations provided true positive results; in one example, 0.14 ng/ml troponin or 4.92 ng/ml FABP was undetectable, but a sample containing 0.14 ng/ml troponin with 4.92 ng/ml HFBP became detectable.
When relating to “antibody” in the description of the invention, the relation may be to antibody, as well as to antibody derivative or antibody conjugate, the relevant aspect being the ability of the agent to react with the antigen, namely with the cardiac marker. The mixture of antibodies in a device or method according to the invention may comprise more than one antibody against one marker; the mixture may comprise antibodies against several forms of the marker, such as against several forms of troponin, or against several epitopes on the same marker. Of course, that the device and method according to the invention employs reactions known in the art, such as reactions of antibody-antigen complex with another antibody or antibody conjugate, the aim being as strong visible signal as needed. In one embodiment of the invention, for example, the device comprises two antibodies for the reaction with CT and one antibody for the reaction with HFBP, and furher two antibody conjugates for reacting with the CT complexes and one antibody conjugate for reacting with the HFBP complexes.
A device according In one aspect, the assay aims at qualitative determination of HFBP and troponin I in a sample of the whole blood of a diagnosed subject, said markers usually detectable in blood within 1 hour and within 4 hours, respectively, after the myocardial damage, when checked separately, wherein it should be noted that current practice does not rely on the detection of HFBP alone.
Means for separately detecting HFBP and troponin I have been described; however the invention combines two separate reactions into one effect resulting in one indicative signal. In an important aspect of the invention, a device comprising a mixture of antibodies or antibody conjugates specific to two cardiac markers simultaneously detects combined minimal levels of cardiac troponin I and/or HFBP; in one embodiment of the invention, said minimal levels may be hardly detectable when measured separately. Advantageously, the device of the invention provides results in few minutes, for example 10 to 15 minutes; very importantly, the results may be obtained within the first several most critical hours from an cardiac event, such as within four hours, for example within three hours or within two hours. The fact is that a positive result in detecting increased levels of any one of HFBP and CT after a suspected cardiac event in a subject indicates an emergency situation and directs the subject to the hospital; the novel attitude of combining both markers to a single line simplifies the interpretation of the actionable results. Moreover, the common test line for two cardiac markers improves the sensitivity of the test, in which the complexes of more antibodies or antibody conjugates, such as anti-HFBP and anti-troponin I, contribute to the intensity of the same band. Thanks to this accumulation effect, lower markers amounts are detectable in one band comprising an antibody mixture than in two separate bands comprising separate antibodies or antibody conjugates. However, the main advantage of the new device and method is an averaging effect of the signals combination in the critical period of between 1 and 4 hours from an AMI event, which provides rapid and reliable results nearly online.
The invention will be further described and illustrated in the following examples.
Antibody conjugates providing color reaction with CT, HFBP, or human serum albumin were obtained, particularly anti-troponin I, anti-HFBP, and anti-HSA. The antibody conjugates were employed for immobilization, in narrow bands, on strips of capillary beds configured to immobilize antibody conjugates. The strips were employed in preparing lateral flow immunoassay devices (LFID). By immobilizing a series of conjugate quantities/concentrations (volumes of certain concentrations to be applied onto the strip for the conjugate immobilization corresponding to different total amounts of color-forming reagents in the band), and by reacting the bands with a series of samples containing different antigen concentrations, the needed reagent quantities for desired signal intensities were determined for all antigens. The following threshold quantities/concentrations were determined: the quantity of anti-troponin I for detecting 1 ng/ml troponin I in the sample, and the quantity of anti-FABP-3 for detecting 5 ng/ml HFBP in the sample, the threshold quantities corresponding to the maximal quantity providing an imperceptible color signal. Samples comprising either 3 ng/ml troponin-I or 15 mg/ml HFBP provided under the same conditions quite clear color bands. Anti-HAS was employed in such a quantity, so as to provide a strong signal (about 10 times stronger than 3 ng/ml troponin-I with the troponin band) and serve as a control that the LFID principally works. A mixture of antibody conjugates was prepared by mixing said threshold quantity of anti-troponin I and said threshold quantity of FABP-3.
Nine LFIDs were prepared, all comprising a control HAS band; three comprised threshold quantity for detecting 1 ng/ml troponin-I, three comprised threshold quantity for detecting 5 ng/ml HFBP, and three comprising the band with mixed antibody conjugates comprising said threshold quantities of both anti-troponin-I and anti-HFBP. A sample of human blood from a healthy donor (very low levels of the cardiac markers) was divided to three portions: troponin-I was added to the first portion to a concentration of 1 ng/ml, HFBP was added to the second portion to a concentration of 5 ng/ml, and both markers were added in concentrations of 1 and 5 ng/ml, respectively, in the third portion. Each portion was applied on the LFIDs comprising relevant antibody. Perceptible signals appeared (+) or did not appear (−) in the devices as shown in Table 1.
The table shows consistent results provided by the devices (triplicate). The concentrations of 1 and 5 ng/ml of the two markers, respectively, correspond to a very early stage of the cardiac event. The table shows that a device according to the invention can provide relevant information contributing to early diagnosing an AMI.
While this invention has been described in terms of some specific examples, many modifications and variations are possible. It is therefore understood that within the scope of the appended claims, the invention may be realized otherwise than as specifically described.
Number | Date | Country | Kind |
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245091 | Apr 2016 | IL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IL2017/050359 | 3/22/2017 | WO | 00 |