EP1305629A2 - Device for testing in vivo samples of small volumes (1 to 100 microlitres) - Google Patents

Abstract

The invention concerns a test device and the method for making same, for analysing small volumes, optionally predetermined and controlled, optionally in vivo, by chromatographic immunoassay processes. The use of a volumetric control and the reduced size of some of the components of said device enable to perform non-invasive in vivo analyses, for example on tear drops, secretions, perspiration and any naturally or spontaneously accessible liquid. The inventive testing device enables to analyse samples having a volume less than 100 mu l. It also enables to control the analysed volume for quantitative analysis of the results. Said testing device is useful, for example but not exclusively, for detecting in vivo various specific elements in a biological sample. The invention also concerns the use of said testing device in analysis kits.

Description

 IN VIVO TEST DEVICE FOR SAMPLES FROM 1 TO 100 UL FIELDS OF APPLICATION

This invention relates to immunoassay, immunochromatography analysis, assay devices using reagents for immunoassays, and one-step methods for performing analyzes of liquid samples suspected of containing ligands. In particular, this invention relates to analysis devices which are suitable for unitary use, at home, in a hospital environment or in a doctor's office, and which are intended to give a rapid analytical result and requiring the minimum of skill and practicality. , and presenting the minimum of difficulties for an inexperienced user. This is to protect an original test device allowing the use of immunochromatographic methods with very small sample volumes without reducing the sensitivity of the analysis. This invention makes it possible to obtain results with samples whose volume is very small, of the order of μl to a few tens of μl, by using immunochromatography or lateral migration, while calibrating the volume of sample analyzed.

It also allows the sample to be taken in vivo and brought into contact with the analysis device.

It also makes it possible to determine and control the volume of sample analyzed.

STATE OF THE ART Analyzes using the specific affinity of reagents have shown their great utility in recent years, both in the field of biological analysis and for other applications. Several techniques, called immuno-analysis, thus use the specific affinity existing between two or more reagents: this is the 'sandwich' technique, and competition. These methods use one or both members of couple (s) of specific affinity for the detection and the determination of one or more elements).

All of these techniques have the characteristic of using a reagent fixed on a support and a free development reagent. Depending on the nature of the test, the reagent attached to the support can be an antibody, an antigen or any substance member of a specific affinity couple. Similarly for the developing reagent, which has further the feature of not being attached to a support but to be composed at least partially ^of a reporter molecule or which resulted in an indicator reaction. The most commonly used markers are dyes, radioactive substances, enzymes, colloidal ^gold and latex beads. Many forms of solid supports on which one of the members of an affinity couple is fixed, have been described. Currently, the most common supports for R1A and ELISA are polystyrene tubes, plates or beads. But paper filters, glass and various plastics have been used for a long time. Radioimmunological (RIA) and enzymatic (EIA) tests are known and used worldwide. More recently developed, immunochromatographic tests have taken and continue to take an increasingly important place in the field of diagnosis. These tests mainly use membranes of various natures and compositions as a solid support.

The development of non-radioactive and non-enzymatic markers has facilitated the use of immunological diagnostic procedures outside specialized laboratories, up to the doctor's office and even in patients' homes. These procedures should be quick and simple, providing diagnostic assistance almost instantly. The development of such tests has therefore focused, in addition to the need for appropriate sensitivity and specificity, on the improvement of three main characteristics: speed, stability (at room temperature), and ease of job and reading the results. In Immunochemistry - Practical applications in pathology and biology (eds Polak J.M and Van Noorden S., 1986), the preparation and use of gold as a colored marker is described. The absorption of a reactive substance on gold colloids is described by Geoghegan W. and Ackerman G. in J. Histochem. Cytochem. (1977), 25, 1187. The use of gold colloids for the visualization of antigen-antibody reactions in analyzes using the deposition of immunological reagents on membranes is described by Moeremans M. et al. in J. Immunol. Meth. (1984), 74, 353.

The immunochromatographic analysis methods use an immunochromatography support through which the sample will diffuse, either laterally and we speak of migration, or transversely and we speak then of filtration. In the case of immunochromatography tests by migration, gold colloids and latex beads are generally used for the optical (colored) development of the result, as components of the development or coloring reagent. However, enzymes are also used, the reaction of which with a substrate directly or indirectly produces a coloration associated with an insoluble colored product. According to the sandwich technique which uses two ligands of the molecule sought, one of the ligands is fixed and the other coupled with an indicator allowing the visualization of the result, by direct coloration when it is a colored substance or by the color formation after an enzymological reaction when ^it is an enzyme. According to the competition technique, a single ligand is used as well as the desired substance or its analog; the ligand is then fixed or free and coupled with the colored or enzymatic indicator, the desired substance or its analog being inversely fixed or coupled. Immunochromatography has been the subject of numerous patent applications including EP 0 306 772 and EP 0 262 323 from Abbott (registered trademark), EP 0 286 371 and EP 0 183 442 from Syntex (registered trademark), EP 0 276 152 of Synbiotics Corporation (registered trademark), EP 0 296 724 of Quidel (registered trademark) and WO 88/00322 of Uniiever (registered trademark). One can also quote US Patents 4,366,241 from Tom et al., US No. 4,632,901 from Valkirs et al., US 4,522,923 from Deutsch A. and Platt HA, WO 8606488 from Barnett B., EP 0 022 669 from Graham HA et al., US 4,094,647, 4,235,601 and 4,361,537 from Deutsch ME and Mead LW, FR 2,537,724 from Friedenberg RM, EP 0206779 from Lipp V. and Buck RL, EP 0189925 from Deutsch A. and coll., WO 84/02397 from Friedenberg, US 3,893,808 from Campbell, and US 3,895,914 from Alberty et al.

Hochstrasser (U.S. Patent 4,059,407) discloses a test strip device which can be immersed in a biological fluid for the semi-quantification of an analyte in the fluid. Also in the field of strip assay, are the U.S. patents 3,802,842, 3,915,639 and 4,689,309.

In migration type analyzes, a membrane is soaked with the reagents required to perform the analysis. The labeled analyte is captured in a detection zone included in the membrane and where the result of the analysis is read. See, for example, Tom et al., US Patent 4,366,241, and Zuk, EP-A 0 143 574. The use of reagent-soaked test strips for specific catch analyzes, such as immunoassays , has been proposed in patents EP 0225054, EP 0183442, EP 0186799, and GB 1589234. In such procedures, a sample is applied to part of the test strip and impregnates the strip, usually using an elution solution such as water. In doing so, the sample progresses through a detection zone in the strip, where a capture reagent specific to the analyte suspected of being in the sample is immobilized. The analyte present in the sample can therefore be captured in the detection zone. The way in which the analyte is captured can be determined using labeled reagents which can also be incorporated into the strip or applied to it later.

Korom et al., EP 0 299359, describe a modification of a test device in which the labeled antibody is incorporated into a membrane which acts as a system delivering the reagent. Grubb et al, U.S. Patent 4,168,146) describe the use of porous test strip material to which is covalently bound an antibody specific for an antigen.

Weng et al. in US Patent 4,740,468 describe a test strip chromatographic device comprising an absorbent strip having a terminal portion to come into contact with the sample. An analysis region is remote from the terminal part and contains an immobilized antibody deposit specific for the analyte. The strip also includes an unbound marker capture area including an immobilized analog of the analyte. In use, an analysis solution is prepared by mixing the patient's sample with a first member of a pair of • specific igdiids, for example, a specific anti-pseudo-pseudo-conjugate for the analyte.

^The immunochromatographic dipstick containing immunoreactive conjugate particuiaire is described in the patent EP 284 232 Rosenstein Becton Dickinson (indicates filed).

In the strip analysis method, the analysis device is a strip on which an immunological ligand is fixed. The bandeieue is immersed in or otherwise contacted with ^the sample, then successively contacting one or more difféientes solutions which may contain an anti - maïqué ligand, a substrate of enzymes (for enzyme labels) and / or solutions wash to remove any uncaught marker. A filtration step can also be carried out to facilitate complete washing (see, for example, US Pat. No. 4,623,461). Other researchers have suggested using a second analysis control to verify the results. See, for example, US Patent 4,200,690: method given for the analysis of faecal samples, using two washes and incubation steps.

The immunochromatograph (strip) in a plastic case with two windows: sample well and reading window, is described in patent EP 291,194 to Unilever (registered trademark).

Other patents relate to the revealing reagent used, such as the Leuvering patents from Akzona EP 7654 (US 4,313,734), EP 398,913 (WO 89/06801) from Nycomed (registered trademark), EP 0 250 137 and 0 258 963 from Ortho Diagnostic System (registered trademark), EP 0 158 746 and 0 293 947 from Janssen Phar aceutica (registered trademark), and EP 0 310 872 from Hygeia Sciences, for the use of gold colloids, the patents for the use of latex beads being also numerous (US N ° 4.434.150, N ° 31.712, N ° 4.478.914, N ° 4.141.965, N ° 4.210.622, N ° 4.331.649, N ° 4.582 .810). U.S. Patents may also be mentioned N ° 4,803,154, N .446.232, No. 4,752,572 for the enzymatic detection and use ^of a ligand coupled to an enzyme.

These patents relate to devices, methods and applications to carry out the detection ^of an element, and thus leading to obtaining a result indicating the presence or absence of said element in a sample.

Immunochromatographic methods are mainly used in unit tests allowing rapid analysis of a single sample. These tests exhibit the result of ^the analysis in the form of a spot or a line visible or invisible depending on the result after a time generally less than 20 minutes. The validity of the result is generally ensured by an internal operating control.

On the same test, we obtain the results of ^the analysis and the result of the control operation. These results, generally qualitative and reading mostly visual, are in the form of lines, dots and colorful characters, eg color red for tests using colloidal ^gold. Generally these tests use the direct capture of the development reagent (complex composed of an affine substance and a colored indicator or an enzyme) for controlling the functioning of the test. In order to assure the user of the correct functioning of the test, the signal is generally intended to have a maximum intensity, and therefore optimal visibility.

These devices often require a sample volume of around 200 μl. Sometimes, they use only a smaller volume of sample taken, but it is then diluted so as to obtain a final volume greater than 100 μl. It is obvious that this latter case results in a loss of sensitivity linked to dilution. However, it is sometimes useful or necessary to carry out analyzes on samples whose volume is very small, whose sampling can be delicate and whose dilution prevents having sufficient sensitivity.

The sensitivity of such tests is in fact limited by the volume of sample diffusing into the strip. These devices, with the exception of unit tests provided with a wick described in some of the previously cited patents, are intended for in vitro analyzes. The sample collection must be carried out beforehand and independently of these devices.

The sample, possibly extracted and treated, is then brought into contact, pure or diluted, with the test device by the filter or the wick. However, small volumes are difficult to handle, and their manipulation leads to a loss of their volume and a risk of contamination of the sample but especially of the manipulator. In addition, in certain cases, the taking of the sample can prove to be delicate, either by the place of taking which can be a delicate tissue or for example a sensitive mucosa, or by its very small volume. It is in these two cases: delicate sampling and low volume, preferable to carry out an in vivo analysis, that is to say to put the test device directly in contact with the tissue which one wants to analyze, which allows '' avoid any sample collection and manipulation.

INTRODUCTION The present invention is an original test device which makes it possible to detect one or more analytes in very small volumes, of the order of a millionth of a liter (μl), with a sensitivity equal to or close to that obtained for usual volumes. It can also allow direct sampling to be carried out in vivo. The analysis is then made in vivo. The invention also describes a device and a method for calibrating the sample volume used for the analysis, and indicating that the minimum necessary volume of sample has indeed been taken by the device. The immunochromatographic methods to which the present invention applies are characterized by the fact that their object is the detection and possibly the determination of an analyte in a sample. They may or may not include at least one internal operation control or operation indicator, which can be used in the present invention for the calibration of the sample volume.

In particular, the purpose of this original test device is to allow the detection of analyte (s) in low-volume samples with immunochromatography tests by membrane migration, using a colored visual indicator, which may be colloidal gold, latex beads, any particulate substance or not, or the product of one or more enzymological reactions, and giving a coloration for the indication of the result.

The test device, using a precise methodology and the aforementioned techniques, allows firstly the direct contact of samples of small volumes with an immuno-chromatographic analysis device, secondly to reduce the volume of sample necessary for thirdly, to indicate to the performer of these tests that this minimum volume necessary for the analysis has indeed been taken by said tests. By low volumes is meant volumes between 0 and 100 μl.

DESCRIPTION The test device of the present invention calls upon the concepts used in immunoassays in heterogeneous phase, and on the principles of fluid mechanics, material physics, chromatography, and immunofixation. In particular, it uses the concept of dead volume of materials. The volume of solution which the device can contain, excluding the parts downstream from the analysis and control system, mainly the absorbent, is called dead volume.

In the context of the present invention, the dead volume of analysis will be defined as the minimum sample volume necessary for obtaining valid analysis results. The object of the present invention is to reduce the dead analysis volume, to take a sample volume equal to or greater than this and less than or equal to 100 μl and to bring it into contact with the analysis device ^. , its use for the desired analysis, as well as the calibration of the sample volume used in any analysis in order to obtain good reproducibility of the results.

This test device is in particular characterized by the fact that its dead volume can be less than 100 μl and even 10 μl. Lateral immunochromatography tests are made up of 4 distinct parts:

1. A wick accompanied optionally ^a filter allows contacting the strip with the sample while the filter. The wicks and filters are generally composed of membranes, the material of which may be cellulosic, or nylon, or one or several polymers or fibers. The purpose of the wick is to bring the sample into contact with the analysis device, the filter has the function of preventing the passage of materials or particles which may interfere with the analysis.

2. A first reactive zone, called reservoir, composed of a membrane intended to receive a sample of fluid to be tested and containing half a pair of specific affinity of the ligand sought and coupled to a reagent allowing the demonstration of the presence of the ligand sought. This membrane is composed of a material which can act as a container (for example cellulose or cellulose derivatives, nylon, fibrous or microporous polymers of high density polyester type for example, fibers of plant, animal, mineral or synthetic origin, under in the form of powder, tablets or multiple layers) and having, with or without treatment, properties of low adsorption of biological molecules.

3. A second reactive zone, called the reaction support, composed of an activated membrane having properties of selective adsorption of molecules (for example by ionic interactions, by hydrophobic interactions, by affinity, by immunoaffinity) and migration properties and capillarity allowing the sample to be tested to move and thus to drive the element to be assayed through the reactive zones. This membrane may or may not be composed of two distinct and contiguous parts having or not the properties set out above. This membrane can be composed of one or more materials having the properties set out above (for example cellulose or cellulose derivatives, nylon, fibrous or microporous polymers of high density polyester type for example, fibers of plant, animal or mineral origin. or synthetic, in the form of powder, tablets or multiple layers). Found in this part a test area, where the results for the detection of one analyte to be read, an operation control zone, and in the context of ^the present invention, a volumetric control.

The purpose of the operation indicator is to indicate that the analysis has been carried out correctly and that the analysis device was functional when it was used. It is generally constituted by a ligand of the development reagent, this ligand being fixed on the support.

The capture of the development reagent in the operation control zone gives a signal which therefore validates the result of the analysis.

^The appearance of the volumetric control signal indicates that the volume of sample required and sufficient for the analysis has been taken by the device. This volumetric indicator may or may not be the operation control, then used for these two functions.

4. A last part, called absorbent, whose role is to cause and / or promote the flow through the two previous parts. This element can be composed of a material having hygroscopic properties (for example cellulose wadding or cellulose derivatives, nylon, fibrous or microporous polymers of high density polyester type for example, fibers of vegetable, animal, mineral or synthetic origin, in the form of powder, tablets or multiple layers).

These four parts are placed contiguously and without discontinuity, often in a plastic module revealing two sectors of the reactive membrane through a window:

. the first sector includes the test showing the result of the analysis. . the second includes the control indicating that the test has been carried out in good conditions: operation indicator. In the context of the present invention, it can also include the volumetric indicator.

The first three parts are generally made up of membranes of various kinds (cellulose, nitrocellulose, nylon, glass fibers, etc.). In the test device of the present invention, each of these first three parts is subject to modifications whose aim is to reduce their dead volume with the constraints of retaining the specificity and sensitivity of the desired results.

For these three parts, it is advisable to use preferably and as far as possible, the membranes having the thinnest thickness, therefore having a lower dead volume. In addition, the reading of the results, by optical nature, whether visual or carried out using a device, is therefore done on the surface of the reaction support. So that the results are visible to the maximum, it is therefore necessary to privilege the surface to the thickness.

First part: filter and / or wick.

When a filter is required, it can also act as a wick to remove additional dead volume. The length of the filter or wick will be set at the minimum necessary for the sampling of the sample, less than 5 millimeters when the analysis is done in vitro, and the length necessary for the sampling for an in vivo analysis, generally less than 10 millimeters.

The width of the filter or the wick can possibly intervene for its filtration function when it is vital and made a significant contribution, but this is generally not the case. In addition, it is obvious that the smaller the sample volume, the smaller the filter can be. As for its contacting function, the reduction in its width will eventually only result in a minimal slowing down of the analysis. The width of the filter or wick can then be reduced to a minimum. For an in vivo test device, the wick must be composed of a material devoid of any toxicity and non-allergenic, of a width or diameter less than 5 millimeters, of a length less than 10 millimeters.

The wick of an in vivo test device must therefore have an area of less than 50 mm ² , priority must be given to its length which must be sufficient for good contacting in vivo. Second part: the reservoir or first reactive zone.

The part called reservoir only has the function of bringing the sample into contact with a sufficient quantity of development reagent, for a given width of the second reactive zone. It is therefore generally sufficient to maintain the proportionality of the width of the first three zones to preserve the characteristics of the analysis.

The length of the reservoir is reduced to the minimum necessary for the deposition of the development reagent which must be of a minimum volume therefore as concentrated as possible. In a preferred version of the invention, the filter or the wick also acts as a reservoir, the development reagent being deposited downstream, according to the direction of diffusion, of the part brought into contact with the sample. This ensures that the development reagent does not come into contact with the patient during an in vivo analysis. For additional safety, it can also be checked beforehand that the development reagent does not present any toxicity in vivo. Third part: second reactive zone or support of the reaction. This zone is that of the reading of the result (s), the functional check and the volumetric check.

During the development work of the present invention, it was found that when the sample volume is in large excess relative to the dead volume of the analysis device, the sensitivity of the lateral immunochromatography tests is independent of the width of the second hotspot. On the other hand, when the sample volume is not in excess, the sensitivity is directly dependent on the ratio between the width of this part and the sample volume with which the analysis is carried out. The consequence is that the smaller the sample volume, the more the width of this reactive zone must be reduced to maintain the same sensitivity. The third part includes the test and possibly the operation indicator. These two indicators generally call for affinity reactions, between the analyte sought (A) and a ligand fixed (La) for the test, and between the development reagent and a ligand fixed for the control of functioning. The rate of these reactions is generally expressed by a formula of the type: Vr = k x IAIE ILale IAIE which is the effective concentration of ^the analyte, and ILale is the effective concentration of the bound ligand. The effective concentrations are dependent on the rate of diffusion in the support.

The membrane used for the third part, supporting the reaction, must have a lateral diffusion speed which is just sufficient for carrying out the analysis in the fixed time, but as slow as possible in order to allow the maximum reduction in the length of this part. , without loss of sensitivity.

The other factor to take into account for the reduction of the length of this part is the variation of the migration speed of the diffusion front of the sample as a function of the distance traveled by it. The more this distance increases, the more the speed decreases, the more the effective concentration increases, the more the reaction rate increases, the more the reaction product is important for a time and a quantity of analyte fixed, and therefore the higher the sensitivity, it is therefore necessary to keep a sufficient distance between the start of this part and the location of the attached ligands. In addition, this distance must allow the formation as complete as possible of the analyte - reagent reagent complexes.

The third part is in fact the most delicate part to modify, due on the one hand to the fact that it contains the result reading and operation control zones, on the other hand that it must also contain the volumetric control of the analyzed sample. The methodology for defining its characteristics, in particular its length and the location of the different result areas, is therefore the subject of a particular chapter which will be found below.

Ultimately, we realize that the width of the first three parts must be reduced identically, which is very simple during the industrial production of these strips.

For a sample volume of less than 20 μl, the width of these different parts must be less than 2 mm, a width between 1 and 2 mm being sufficient for easy reading of the results.

For a sample volume of less than 100 μl, the width of these different parts must be less than 5 millimeters.

METHODOLOGY FOR THE THIRD PART.

It is first necessary to determine the membrane serving as support for this part, as well as the ligands used, for the development reagent as for the fixed reagents, also called capture reagents, their method of fixing and the order of their location by relation to the direction of diffusion of the sample. These elements are indifferently defined either with the usual methodology and the corresponding sample volumes, or during a first approach of low sample volumes. It is of course preferable to give preference to the conditions allowing the best sensitivity to the analysis to be obtained, even in the presence of an excess volume of sample. When these various elements are determined, the methodology for determining the exact distance between the start of this part and the location of the attached ligands is as follows: Samples containing the limit concentration of analyte which it is desired to be able to detect are analyzed with devices in which this distance has been varied, the sample volume being in excess. The minimum distance for obtaining an analyte detection signal is thus determined. ! 1 there are then two options concerning the sample volume and its calibration or control:

1. adapt the test to a determined sample volume,

2. Accurately determine the minimum sample volume necessary to obtain satisfactory analysis results, and adjust the volumetric control appropriately.

In these two cases, it is necessary to place the control or volumetric control of the sample after, or downstream, in relation to the direction of diffusion, of the analysis area. Depending on the arrangement of the volumetric control in the test, the volume of sample used for the analysis can be adjusted. 1. To adapt the test device to a determined sample volume, the volumetric control is placed a few millimeters downstream of the test area.

The width of the first three parts is then reduced so as to obtain a positive signal in the test zone with the minimum volume of sample for which the analysis device is intended, this sample containing the limit concentration of analyte which is wants power detected. This width is less than 5 millimeters for sample volumes less than 100 μl and less than 2 millimeters for sample volumes less than 20 μl.

Once this width has been determined, the distance separating the test zone from the volumetric indicator is then increased until the latter gives a signal with the fixed sample volume, without giving it with a volume just below. It should moreover be specified that an accuracy greater than 90% can commonly be obtained when the sample volume thus checked. The length of the analytical part must be less than 70 millimeters for samples of volume less than 100 μl, its width less than 5 millimeters and its surface less than 450 mm ² .

We have determined that for a membrane composed of one or more commonly used materials (for example cellulose or cellulose derivatives, nylon, fibrous or microporous polymers of high density polyester type), the analytical part, defined as the part including the zone d analysis and the volumetric control zone, should have a maximum surface of 4.5 mm ² per μl of sample, ie 45 mm ² for 10 μl, or even 450 mm ² for 100 μl.

2. To determine the minimum sample volume for the test, once the different lengths and widths of the first three parts have been reduced to the minimum necessary, the length of the analytical part reduced to less than 70 millimeters, its width to less than 5 millimeters and its surface less than 450 mm ² for sample volumes less than 100 μl, various analyzes are carried out with sample volumes variables, containing the limit analyte concentration that we want to be able to detect. The minimum volume for obtaining the signal is then determined.

It only remains to carry out various tests with this minimum volume of sample, by varying the location of the volumetric indicator to find the maximum distance where that gives a signal.

Once the volumetric indicator is placed at this distance, the appearance of its signal will indicate that the minimum sample volume has indeed diffused into the test device. The last part, called absorbent, is then placed as close as possible to the strip of the operating indicator, this in order to reduce the duration of the analysis and allow obtaining the results as quickly as possible.

In a first version, the volumetric indicator is also the indicator that the test is working properly. The latter is generally constituted by the capture of the development reagent by a ligand fixed on the membrane. In a second version, preferable in certain cases, the volumetric control can in fact be constituted by the capture of an analyte present in the sample, the so-called reference analyte. A revelation reagent, identical or different from that allowing the visualization of the results of the analysis, will allow its visualization.

This control, which does not directly depend on the sample volume, is useful in the case where it is desired to control the sample volume by the detection of another analyte than that for which the analysis is intended, an analyte present constantly in the samples. It can also be useful if it is necessary to reference the result of the analysis not in relation to a sample volume, but in relation to a determined quantity of a reference analyte. Mention may be made, for example, of serum albumin or that present in tears, various types of immunoglobulins or any other analyte to which the results concerning the analyte sought are generally referred. It can also be a precursor, metabolite or a competitive compound for the metabolism of the analyte sought.

This second version has the particularity that the volumetric control calibrates not the sample volume but a determined quantity of an analyte present in the sample. This version can be useful when the aim of the analysis is not to simply determine the presence or the level of an analyte, but an abnormal ratio of the concentration of an analyte compared to a so-called reference analyte. These include for example, but not limited nor exhaustive, albumin, various proteins in the blood or ^other tissues, the different classes of immunoglobulins. For example, it may be to compare or measure the ratio of specific antibody levels to an antigen with the rate ^of antibodies specific for another antigen.

In the two versions described above, it should be noted that a simple modification of the location of the volumetric indicator or of the dimensions of the first parts of the device makes it possible to modify the calibrated volume or the quantity of reference analyte. In versions derived from these first two, one can seek to control the volume and the quantity of one reference analyte or of several, one can also consider controlling the quantity of several reference analytes.

It is also possible to use a volumetric control to determine a flow rate of fluid or sample in vivo, as well as its viscosity by temporal analysis.

Here is a mode of application of the invention to which the latter is not limited in any way.

Example 1:

This example relates to a rapid lateral immunochromatography test for the detection of total IgE in human tears, according to the sandwich method.

Detection of total IgE in tears presents certain difficulties. For example, the volume of tears is almost always very low, as well as their flow, and their collection a difficult operation, little appreciated by practitioners.

In order to collect the sample as simply as possible, to perform an analysis with a small volume of tears in a reasonable time, while avoiding stimulating the tear flow with irritants, a test device was developed according to the present invention.

The device comprises a wick filter also serving as a reservoir for the development reagent, a membrane on which the IgE detection zone is situated and an operating indicator which also serves for the calibration of the sample volume, operating by capturing the reagent. of revelation. The test device has a width of

1.75 millimeters and a total length of 55 millimeters, with part of the filter-wick used for the in vivo collection of the sample with a length of 7 mm. The analysis device was adjusted to operate with a sample volume of 10 μl. Its analytical part therefore has an area of less than 45 mm ² .

The practitioner does not have to collect tears to perform, he just has to set up the test, at the corner of the eye in the conjunctival sac. The size and composition of the device were thus optimized for a minimum volume of tears. For most patients, the contact time of the test device with the eye is less than 3 minutes. The volume of tears collected is calibrated using the operating indicator, which therefore also acts as a volumetric indicator. A signal appears when a sufficient volume

(10 μl) was collected, which allows good reproducibility of the collection and therefore of the results.

When the volumetric indicator gives a visible signal, 10 μl of tears were collected by the device. This is then removed from the eye and brought into contact with a solution allowing the sample taken to diffuse throughout the analysis device. For this specific application, it is 30 μl of demineralized water, but other solutions can be used, their composition then being defined for optimal functioning of the analysis.

This device was thus able to be validated on different samples, with the obtaining of a satisfactory agreement between the interpretation of the results (reading) and the values of the IgE levels determined by a recognized quantitative method.

The same test device also makes it possible to detect total IgE in the discharge from the nose, in the case of suspected allergic rhinitis. One can also consider modifying this test device for the detection of total IgE in saliva or any other body fluid. SCOPE

The test device of the present invention is applicable to any analysis using an affine or non-affine reaction, comprising an internal operating control, and characterized by the presence of a reagent fixed on a support, which can be, without limitation, a membrane. , and the use of a development reagent. The development reagent may comprise particulate components giving a coloration or reactive molecules, for example and without limitation, enzymes, the reaction of which makes it possible to obtain a coloration, or an absence of coloration, indicative of the nature of the result . This device can be used for any detection of an element liable to intervene in an affinity reaction with a counter-element.

“Element” is understood to mean, within the framework of this presentation, any substance, composition, particle capable of intervening in a ligand-refining system, in particular in an affine reaction with a “counter-element”. The generality given to the word “element” therefore also extends to the expression “counter-element”. In a nonlimiting manner, “element” and “counter-element” can consist of a mutually complementary, affine antigen and antibody, or vice versa.

The element sought by this test device may be of a biological nature, an antibody or an antigen, of a chemical or biochemical nature. This test device and this method is applicable to the detection of any biological marker of one or more infectious pathologies, for example and in a non-exhaustive manner serology tests, and antigen detection tests. This test device and this method are also applicable when the element sought is a single type of antibody or several types, classes or subclasses. A specific example to which the claims of this patent is not limited in any way is the serology HIV or Chlamydia, and for which this device and this method make it possible to determine or evaluate the level of antibodies directed against a specific antigen, in the serum or other samples, by calibrating it against the level of antibodies against another antigen. This test device and this method are also applicable when the element sought is one or more antigens specific for one or more pathologies. This test device and this method are also applicable in the context of therapeutic monitoring. This test device and this method are also applicable for any type of sample, whether human, animal or plant tissue, whether solid or liquid. It is applicable with any type of sample, for example and without limitation: bodily secretions, mucus, sweat, tears, lacrimal and nasal fluids, saliva, mood, pus. For example and in a nonlimiting manner, this test device can allow the characterization of microorganisms in the liquids of abscesses, panaris, and oozing from wounds.

This test device is also applicable to any in vitro analysis on samples of small volume, for example taken from children and infants. It can also make it possible to carry out analyzes on meat samples, whether for the purpose of researching microorganisms, or of putrefaction marker or any other biological, biochemical or chemical marker.

The test device therefore allows the detection of any analyte, for example for diagnosis in human health, in samples of small volume which can also be difficult to take.

The present invention is applicable to research in biology and in the field of medical diagnosis, as well as in all fields of diagnostic and analytical sciences, such as veterinary, agricultural, agro-food, food and expertise sciences. , where it is necessary to detect an element, compound or substance, or to determine its rate. It is also applicable in industry, and to any qualitative detection process used industrially.

This test device can be used either with a visual reading, carried out by a human operator, or with a reading device coupled or not with a data processing device.

Claims

1) Test device for analysis by an immunochromatographic technique in which the visualization of the results is associated with a coloration, characterized in that it includes at least one volumetric control giving a signal whose color or intensity is a function of the volume of sample which has diffused in the test device, making it possible to determine the volume of sample analyzed, or to verify that the volume of sample necessary for the analysis has actually diffused in said device.

2) Test device according to one of the preceding claims, characterized in that it contains at least one volumetric indicator and that the test is working properly. 3) Test device according to one of claims 1 or 2, for the analysis of samples of volume less than 100 μl, characterized in that its analytical part has an area less than or equal to 4.5 mm ² per μl of sample, for example less than 45 mm ² for 10 μl, or else 450 mm ² for 100 μl, its length being equal to or less than 70 millimeters and its width less than 5 millimeters. 4) Test device according to one of the preceding claims, characterized in that it includes a non-toxic wick intended for in vivo sampling and allowing the contact of an organic tissue with an immunochromatographic test device, the width or diameter is less than 5 millimeters.

5) Analysis device according to one of claims 1 to 4, characterized in that it includes an element allowing the direct contact of the sample with its analytical part, and on which is deposited a development reagent downstream of the contact area.

6) A test device according to any preceding claim characterized in that it includes at least an enzyme and a substrate whose reaction leads to ^the appearance of a coloration, allowing the visualization of the result. 7) Test device according to any one of the preceding claims, characterized in that the signal or signals are obtained using one or more colored reagents comprising a colored particulate substance which may be a complex of colloidal gold or metal salts or latex beads.

8) A method of producing a test device according to any one of claims 1 to 7, characterized in that the location and the composition of at least one volumetric indicator included in the device are fixed so that that the intensity or color of its signal is dependent on the volume of sample analyzed.

9) Method for producing a test device according to claim 8, characterized in that the location and the composition of at least one volumetric indicator are adjusted to obtain a correspondence between the intensity or the color of its signal and known values or ranges of known values of the level of one or more reference substances, this correspondence between the signal and one or more values of one or more reference elements being used for the analysis and interpretation of the results.

10) assembly or analysis kit characterized in that it contains a test device according to any one of the preceding claims, the results of which are read by an apparatus.