WO1991002979A1 - Method and device for rapidly assaying a plurality of samples containing an immunologically reactive substance - Google Patents

Abstract

The process described involves: choosing an assaying reagent the microparticles of which have at least one μ max substantially corresponding to a reading wavelength made possible by the reading apparatus; mixing the assaying reagent with the plurality of samples in a series of micro-cupulas housed in a micro-plate. Simultaneously incubating all said mixtures shaking said plate. Reading the plurality of results by placing the micro-plate in an automatic spectro-photometric micro-plate reader programmed on a reading wavelength adjacent to the μ max typical of the microparticles chosen. Applications: rapid assays of antigens or antibodies in a plurality of samples.

Description

METHOD AND APPARATUS FOR QUICK ASSAY OF A PLURALITY OF SAMPLES CONTAINING A SUBSTANCE OF IMMUNOLOGICALLY REACTIVE CLINICAL INTEREST

TECHNICAL AREA :

The present invention relates to the general technical field of methods and devices for dosing a chemical, biological or biochemical substance contained in any natural or artificial medium.

The present invention applies, more particularly but not exclusively, to assay methods and devices which aim to assay immunologically reactive substances of clinical interest, such as the assay of an antigen by an antibody and vice versa.

The present invention is part of a development and improvement of the method and of the metering device described in patent application FR-A-2604526.

Thus, by "immunologically reactive substance" is meant mainly all the antigens (including haptens) and the monoclonal or polyclonal antibodies obtained by cell fusion and natural or induced immunization.

In the same way, by "substance of clinical interest which is immunologically reactive" is meant mainly all the antigenic molecules or antibodies whose assay, in a biological sample of human or animal origin, may be of interest in medical diagnosis, The clinical research or Monitoring of a pathological process, or of a therapy implemented.

PRIOR ART

The prior application FR-A-2604526 describes a method for assaying, in particular for assaying an antigen with an antibody, in which particular phases of agitation and result reading. Synthetic or natural micro-particles or micro-spheres are thus used which, during a stirring phase of determined amplitude and frequency, lead to the immunological and specific agglutination of the antibodies and antigens. The microparticles or microspheres chosen have the particularity of offering, for a determined wavelength, visible ultraviolet light, a maximum absorption called λ max. This particular property of true absorption is then used in practice to determine, by conventional spectrophotometry, the concentration of samples to be assayed, since only the microspheres or microparticles not agglutinated in a sample to be assayed, by spectro-photometric reading in the vicinity of the λ max characteristic of said micro-particles or micro-spheres, maximum absorption.

By comparison with a standard curve obtained by reading at the same characteristic wavelength λ max, it is thus possible, by simple reading of a sample crossed by a radius of wavelength λ max, the concentration of said sample after the implementation of appropriate dilutions, and The use of blocking solutions. The process thus described requires, beforehand, only the knowledge or the verification of the wavelength λ max characteristic of the maximum absorption of the micro-spheres or micro-particles used. The method and its implementation device have proven to be of practical use, since they are capable of being used by any type of laboratory possessing a conventional spectrophotometric reading apparatus. This technique is comparable to traditional spectrophotometric readings used in other fields and is therefore easy to use, quick to perform and relatively low final cost of analysis.

However, such a method suffers from a major drawback relating to the need to carry out the individual and successive reading of each of the tubes to be read, since these these must be introduced into the Reading device, then read and finally removed by the user. The number of manipulations is, therefore, directly proportional to the number of tubes to be assayed, while the reading process itself is instantaneous, which leads to making the overall assay technique of a length unrelated to the technique. even reading. This situation is all the more detrimental since, in practice, the user is confronted with the need to proceed with the determination of a large number of samples, namely one or several hundreds for example.

US Pat. No. 4,240,751 discloses a method for reading samples having some automation and using a reading device, of the coloπ ^' meter type with optical fiber and double beams, provided with a reading head. which is moved manually by the operator above each of the samples to be assayed, which are contained in micro-wells of a micro-plate. The method of Reading revealed teaches to use a wide reading band, the upper limits of wavelength of which are less than the average diameter of the microparticles likely to be used. It is therefore not mentioned to have recourse to a specific Reading wavelength, such an approach being even discouraged. The dosing method described operates on a principle unrelated to that of FR-A-2604526 and requires numerous manipulations in addition to the manual displacement of the read head leading to a relatively long dosing.

In addition, reading devices are already known which are capable of performing automatic reading, in particular by spectrophotometry, of a large number of samples to be assayed. These reading devices, generally using the principle of optical fibers, are for example used in the field of immunoenzymology and make it possible to read the result of the assay specific to each sample, by means of a micro-plate comprising a series of micro-cups in which the series of samples to be assayed is inserted • and held vertically. These may be, for example, micro-plates of the ELISA type, the usual function of which is to allow the reading of a series of metric coloπ ^' reactions. These micro-plates are usually provided to allow the automatic reading of 96 sample tubes. The appropriate reading devices, more commonly designated under the term "automatic microplate readers" ensure, once the microplate provided with the plurality of tubes to be read is placed in the apparatus, the automatic processing Individualized reading of the sample tubes, by emission of a set of optical beams generally passing vertically through each of the tubes. In most cases, a printer is connected to the reading device to allow immediate printing of the reading results. This automatic reading technique is, of course, perfectly suited to the rapid reading of a large series of samples, but its use is currently limited to reading colorimetric reactions. In fact, the optical possibilities of the commonly used automatic reading devices are reduced to a limited number of reading wavelengths characteristic of the reading head or crown of each type of device. These characteristics are in finite number and the discontinuous wavelengths, namely for example 340 nanometers, 405 nanometers, 414 nanometers, 450 nanometers, etc. This characteristic does not make the reading process, described in the patent application FR -A-2604526, directly adaptable to Reading by these automatic devices, insofar as i L is necessary that the wavelength λ max of the micro-particles or micro-spheres used in the process according to the above-mentioned request has a maximum absorption corresponding to the reading wavelength of the device.

In addition, the reading methods known up to now and using micro-plates consist of resorting, in a conventional manner, to sample tubes placed on the micro-plate, or to successive uses for the same dosage of several micro-plates including washes. The reading methods known to date therefore do not allow a rapid reading of a large number of samples, insofar as there remains a series of manipulation operations which lead to the reckless lengthening of the dosing phases and reading, due in particular to the washing phases. In addition, the difficulty of washing the micro-cups leads to an impaired reliability of the Reading results.

STATEMENT OF THE INVENTION

The object of the invention is to propose an improvement to the method and to the device for assaying substances of clinical interest which are immunologically reactive according to the request FR-A-2604526 which makes it possible to ensure the automatic reading of the assay of a plurality of 'samples.

Another object of the invention is to propose a method and an implementation device allowing the adaptation of the method and the device according to the request FR-A-2604526 to the automatic reading techniques allowed by automatic microplate readers. .

A secondary object of the invention is to propose a method and its implementation device in which the set of operations for preparing and handling the samples to be assayed and for determining the standard range is reduced and simplified, with a view to reduce the total dosing time.

The object of the invention is achieved by means of a method for assaying a substance of clinical interest which is immunologically reactive with other substances of the same type, of the type assaying of an antigen by an antibody and vice versa, of the type in which :

- an immunologically active substance, acting as a metering agent, is grafted beforehand onto natural or synthetic micro-particles to form a metering reagent,

- determining the maximum absorption of visible ultraviolet light, ie of a suspension in Liquid medium of said non-agglutinated micro-particles, either of the dosing reagent in liquid suspension, the determination being carried out by making the ultraviolet absorption spectrum visible from one or the other of said suspension, the wavelength corresponding to the maximum of absorption being called λ max,

the dosing reagent is mixed with the substance to be measured diluted in an appropriate manner and in a known manner,

- Said mixture is incubated, by shaking, in order to carry out the unoLogical agglutination of said micro-particles in the incubation medium,

- the result is then read in a spectrophotometer type reading device, by visible ultraviolet absorption spectrophotometry, by placing itself in the vicinity of said wavelength λ max, - the concentrations are calculated of The substance to be dosed in

The sample, by comparison with the visible ultra-violet absorption results measured at the same wavelength λ max obtained, under the same conditions, on a standard range, characterized in that, with a view to carrying out the assay a plurality of samples in a single pass in the Reading device:

to choose all of the dosing operations, a dosing reagent is chosen beforehand, the microparticles of which have at least one λ max corresponding substantially to at least one reading wavelength authorized by the reading apparatus,

mixtures of the dosing reagent are carried out with the plurality of samples to be assayed diluted in a known manner in a series of individual volumes, consisting of a series of micro-wells formed in a micro-plate,

- All of said mixtures are incubated simultaneously by subjecting said microplate to stirring.

- The plurality of results is read by inserting the micro-plate into a reader spectro-photometric and automatic micro-plate programmed on a Reading wavelength close to the λ max characteristic of the micro-particles chosen. The object of the invention is also achieved thanks to a device for implementing the method comprising:

- at least one micro-plate in which a plurality of micro-cups is provided,

- a dosing reagent comprising micro-particles grafted on an immunologically active substance and capable of exhibiting at least an absorption maximum (λ max) for at least one reading wavelength authorized by an automatic reading device, of the type spectrophotometer,

- a solution for blocking the agglutination reaction, - a standard range of the immunoLogically active substance. Various other characteristics will emerge from the description given below with reference to the appended drawings which show, by way of nonlimiting examples, embodiments of the subject of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS:

Fig. 1 shows a general schematic and perspective view of a micro-plate used in the method and the device according to the invention.

Fig. 2 shows a top view of a micro-plate and FIG. 2_a shows a partial view of a specific form of distribution of the standard range. Fig. 3 shows a general top view of a box according to the invention.

BEST WAY TO IMPLEMENT THE INVENTION:

In the description which follows, it will only be done succinctly refer to the step relating to the grafting of the immunologically active substance on micro-particles or micro-spheres or to the step of determining the maximum absorption λ max of a suspension in liquid medium of said non-agglutinated micro-particles or the dosing reagent itself. For more details on the practical realization, one will usefully refer to the request FR-A-2604526.

Most of the automatic microplate reading devices currently on the market are fitted with a network of interferential reading filters mounted on a rotating crown allowing the selection, by rotation of the crown, of a specific reading wavelength. to each of the filters. In practice, the main Reading wavelengths that can be displayed are: 340 nanometers, 405 nanometers, 414 nanometers, 450 nanometers, 492 nanometers, 540 nanometers, 620 nanometers, 690 nanometers.

In order to be able to ensure, in a significant manner, the measurement of the absorption of an aqueous suspension containing non-aggregated micro-particles or micro-spheres, by absorption spectrophotometry at the wavelengths authorized by conventional devices for reading microplates corresponding to the values mentioned above, it has proved necessary to use dosing reagents whose microparticles or microspheres have an absorption λ max for at least one of these same values of reading and more generally have a λ max between 340 and 690 nanometers. In practice, taking into account the available devices, we will limit ourselves, most of the time, to the range between 340 and 450 nanometers. In fact, patent application FR-A-2604526 has shown that if by visible ultraviolet absorption spectrophotometry by placing itself at a wavelength which corresponds to the absorption max λ of the non-aggregated microspheres , a solution containing a mixture of non-agglutinated microspheres and microparticles and a mixture of agglutinates is read. these, the measurement carried out only concerns, and therefore detects, only the non-agglutinated particles, because the latter are the only ones to absorb at this maximum.

The maximum absorption λ max is therefore a characteristic of the disaggregated microspheres, and this characteristic is directly related either to the size of the particles, or to their constituent material, or to their color.

The investigations carried out on currently available natural or synthetic micro-particles or micro-spheres, and in particular for polystyrene micro-particles, have made it possible to demonstrate that, for commonly used reading wavelengths, the size of the micro-particles or micro-spheres, likely to have a max λ at the Reading wavelengths of micro-plate Reading devices, should be between 0.4 and 0.7 micrometers on the one hand, and between 0 , 8 and 1, 2 micrometers on the other hand, for Reading respectively, for example, in the vicinity of 340 nanometers and 405 nanometers. Micro-particles or micro-spheres with a diameter of 1 micrometer having, for example, maximum absorption at a Reading wavelength of exactly 405 nanometers.

For Reading wavelengths of 340 nanometers, microparticles or microspheres with a diameter of 0.5 to 0.6 micrometers in polystyrene, or 0.6 micrometer in vinyl butadiene are also suitable. For shorter wavelengths, sizes between 0.1 and 0.5 micrometers are also suitable.

For another reading wavelength, for example 405 nanometers, a diameter of 0.9 to 1.2 micrometers is also suitable. The adjustment of the max λ of a given microsphere over a wavelength imposed by the reading device does however have a certain tolerance, insofar as i L has been noted that the microparticles or microspheres of a given size could have a λ max varying by plus or minus 5 nanometers around the displayed reading value without harming significantly to the result.

In summary, it was noted that non-colored synthetic polystyrene microspheres or microparticles, with a diameter substantially equal to 0.1, 0.3, 0.3 to 0.7, 0.8 to 0 , 85, 1, 1.4 micrometers respectively allowed the readings in the vicinity of 300, 310, 320 to 350, 380, 405, 414, 420 and 450 nanometers. Preferably, whatever the material of the microparticles, the ratio λ. max of the maximum absorption of d micro-particles on The average diameter of the micro-particles will be between 0.4 and 0.8 and advantageously substantially equal to 0.65. These data being experimental, the ratio \ max can, in some cases and for certain types of particles, be between 0.3 and 1. As is also well described in patent application FR-A-2604526, it is possible to select micro-spheres or micro-particles on their color characteristic and, in this case, The blue color has been found to give good results in the vicinity of 340 nanometers. Advantageously, micro-particles or micro-spheres of blue polystyrene, with a diameter of between 0.4 and 0.7 micrometers, allow a reading between 320 and 360 nanometers.

It has also been found that advantageously the microparticles must have a spherical shape, must be synthetic, and chosen from the group consisting of synthetic polymers of vinyl toluene, acrylo-nitri Le, styrene butadiene, acrylo-nitrile derivatives- acrylic acid, acrylic esters, silicones, vinyl butadiene and, preferably, polystyrene. Among these materials, micro-particles made up of polymers of vinyl toluene, styrene butadiene, vinyl butadiene and polystyrene are preferred.

The selection of the sizes or colors of microparticles or microspheres that can be used being carried out, an immunologically active substance is grafted, in known manner, playing the role of dosing agent, onto said microparticles or microspheres, in view of constituting a dosing reagent.

The method according to the invention then consists in using a standard microplate for cell cultures or, for example of the ELISA type, an exemplary embodiment of which is shown diagrammatically in FIGS. 1 and 2. These micro-plates 1 are generally in the form of a volume defined in the shape of a rectangular parallelepiped comprising a series of micro-cups 2, preferably of cylindrical shape distributed regularly in the mass of the micro-plate 1. The volumes defined by the micro-cups are also preferably constant and equal with respect to each other and have an opening, for example circular, opening at the level of the upper face 3 of the micro-plate 1. It It is obvious that other forms of micro-cups 2 are possible. These plates are generally made of a transparent plastic material of the polystyrene type. Commonly, the micro-plates 1 comprise a series of eight rows numbered from A to H, distributed over twelve columns, which leads to micro-plates 1 comprising 96 micro-wells. The method according to the invention has the particularity of carrying out the mixing of the dosing reagent, therefore containing grafted synthetic microspheres, with the plurality of samples to be assayed (previously diluted in known manner) directly in each of the individualized volumes defined by the micro-wells 2 of the micro-plate 1. Each micro-well 2 is thus capable of containing a mixture of a known amount of dosing reagent, with an also known amount of samples to be assayed, without using tubes of reading.

Preferably, certain micro-cups are reserved, advantageously three rows distributed over nine columns, to constitute the standard reading range.

In a particularly advantageous embodiment of the invention, the points of the standard range 4 are present at the bottom of the micro-cups 2 which are reserved for them, in freeze-dried form and in quantity also pre-calibrated. The The user task CONSI ^'ste simply reconstitute the standard range of microplate by simply rehydrating the micro-wells 2 containing the points of the standard range 4. Surprisingly, it was indeed found that the points of standard ranges 4 Lyophilized deposited at the bottom of a micro-cup had the particularity, first of all to be distributed naturally in the form of circular rings (fig. 2a) at the bottom of the hydrophilic micro-cups, then in the event of mechanical shock or any movement imparted to the micro-plate, had a natural tendency to remain naturally linked and fixed to the bottom of said micro-cup. Conversely, the standard range points are naturally distributed in the form of a crescent (fig. 2) in hydrophobic micro-cups. Even in the event of a major shock or untimely manipulation of the microplate 1, including its inversion, the quantities of points of the standard range thus deposited constantly maintain their position at the bottom of the microplate 2 and their crescent or circular, even if minimal quantities of standard range points are freeze-dried. Likewise, it may be envisaged to preferably provide for depositing, at the bottom of all or part of the remaining micro-cups not occupied by the points of Standard range 4, pre-calibrated quantities of the dosing reagent under dehydrated or even freeze-dried form distributed in a ring or crescent. The user then only has to deposit at the bottom of said micro-wells the required quantities of each of the samples to be assayed.

Advantageously, provision is made for a system for closing the microplate 1 which may, for example, consist of a cover 5 held by any means known to those skilled in the art and, for example, by bonding to the upper face 3 from The micro-plate. By simply detaching this cover 5, the user obtains a ready-to-use micro-plate.

Once completed The mixing of the dosing reagent with the substance to be measured, which has been diluted in an appropriate manner and in a known manner directly in the micro-wells, and therefore that the points of the standard range have been reconstituted by rehydration in the micro-cups reserved for this purpose within the micro-plate, one proceeds to the incubation of said mixtures by simultaneous agitation of the plurality of mixtures by subjecting to agitation La micro-plate itself.

Advantageously, the microplate 1 is subjected to a periodic movement of frequency between 4 and 40 Hertz, preferably between 5 and 25 Hertz and advantageously close to 16 or 20 Hertz, and of amplitude varying from a few millimeters to a few centimeters , preferably of the order of 4 millimeters. The purpose of this periodic agitation movement is to carry out the specific immunological agglutination of said micro-particles or micro-spheres contained in each of the incubation media present in each of the micro-wells. To achieve this agitation, recourse is had to conventional agitation apparatus well known to those skilled in the art. After the stirring phase, the blocking of each of the solutions is carried out using a blocking solution which is introduced directly into each of the micro-wells. After a rest time of the order of, for example, 10 minutes, the user can then read directly the plurality of concentration results relating to the plurality of samples by direct introduction of the microplate 1 into a reader. spectro-photométπ ^'and that automatic microplate. However, the user must first select

The reading wavelength of the device on a reading wavelength close to the λ max characteristic of the microparticles or microspheres chosen as dosing reagents.

The spectrophotometric reading apparatus then ensures, by itself automatically and in a single pass of the microplate 1, the individualized reading of each of the samples by emission of vertical optical rays through each of the micros -cupules 2 of the micro-plate.

The device for implementing the method according to the invention must therefore consist of at least one microplate 1 wherein ^is provided a plurality of micro-wells 2, and comprise a reagent doser containing micro-particles or micro-spheres grafted onto an immunologically active substance, able to act as dosing agent and capable of present at least an absorption maximum (λ max) for at least one reading wavelength authorized by an automatic reading device, of the spectro-photometer type. These micro-particles or micro-spheres are, of course, chosen according to the possibilities of reading the device to be used, and their characteristics of constituent material, size and colors correspond to those mentioned above. A solution for blocking the agglutination reaction, as well as a standard range of the immunologically active substance, must complete the device. Advantageously, the implementation device is in the form of a box 6 (fig. 3) containing at least one and, preferably, three micro-plates 1, each of the micro-plates having a standard range 4 which is originally deposited in lyophilized form and pre-calibrated at the bottom of 27 micro-cups. The box 6 also preferably presents bottles of a lyophilized buffer solution 7 for the final dilution of the sample. The buffer solution is reconstituted by simple rehydration. The box 6 can, in addition, include bottles of a blocking solution 8, as well as tubes of control serum 9, for example two, and, finally, tubes of reagents 10 ready for use for the mixing of samples.

In the case where the points of the standard range 4 are not distributed at the bottom of a series of micro-cups, it is obviously necessary to provide, in the box 6, bottles or tubes containing the points of the range standard. Likewise, if the reagent intended for the samples is originally distributed in the micro-wells, the kit will not include reagent tubes 10. As a variant, it is also possible, if the liquid channel is chosen, to ^' distribute the original ready-to-use reagent at the bottom of the micro-wells, the closure cap 5 then ensuring the tightness of the assembly. The method and the implementation device which have been described thus allow the user to have a dosing and reading technique which makes it possible to considerably reduce the preparation and handling times, since the microplate is ready. ready to use and is capable of containing the points of the standard range and, if necessary, even the dosing reagent. In addition, since the mixing of the dosing reagent and the samples to be assayed takes place directly within the microplates of the microplate, it is no longer necessary to have to resort to additional series of tubes, which, a new times, reduces handling time. The dosing reagent can finally, of course, be in dehydrated or lyophilized form and be presented in box 6 in tubes or vials.

The technique used is, moreover, considerably simplified, insofar as the microplate itself is used as a support element for agitation leading to agglutination.

Finally, the automatic reading of the concentration of each of the samples in an automatic reading device allows the user to obtain, almost simultaneously, the concentration results for a large number of samples.

Example of execution n_ ° _ 1 - General case: The box intended for the simultaneous dosing of a plurality of samples is delivered with three micro-plates, each micro-plate comprising 27 micro-cups reserved for the standard range points distributed over three rows, that is to say 9 points of standard range in triple pre-lyophilized. The other 69 micro-wells on each plate, totaling 207 micro-wells, are blank and available for incubation of diluted biological samples. All fluid or liquid distributions can be do this very quickly using multichannel pipettes (8 channels).

1) Distribution:

- the user simply rehydrates the micro-wells of the standard range, - the user proceeds to the distribution of the biological samples, diluted beforehand, in the virgin micro-wells, at the rate for example of 10 microliters per micro-wells.

2) The user then distributes the ready-to-use reagent in the micro-cups by pipettes eight channels, for example at the rate of 20 microliters of reagent.

3) The user then proceeds to the incubation and shaking phase for, for example, 6 minutes at room temperature and at the frequency and amplitude mentioned previously in the description.

4) After the incubation phase, the user distributes, by an eight-channel pipette, the blocking liquid in each of the micro-wells, for example at the rate of 100 microliters.

5) The user then only has to proceed to the simultaneous reading of the 96 wells corresponding to each of the micro-wells by introducing the micro-plate into a micro-plate reader, of the type for example FL0W MCC 340.

Previously, the user has, of course, selected the reading filter of the device on the wavelength corresponding to the maximum absorption characteristic of the microparticles of the reagent used.

It should also be noted that since the vibration device used for the incubation and shaking phase can shake four microplates simultaneously, it becomes possible to dose a large number of samples very quickly.

Example of realization n ° _2 - Determination of human albumin: 1) Distribution of the biological samples: One distributes, in duplicate, in the virgin cups, 10 μl of the diluted biological samples. For the distribution of 10 μl of the diluted samples, we use a precision micropipette (capillary pipettes recommended).

Care should be taken not to distribute any sample in column 12 of the microplate. 2) Rehydration of the standard range:

Using a precision multichannel pipette, the 3 columns of the micropLaque range are successively rehydrated with 10 μl of water for injection. Protocol: a) The 10 μl of water is injected against the wall of the micro-cup, just above the freeze-dried ring, b) For complete dissolution, the plate is agitated on the rotary agitator for 30 seconds at 1,400 rpm. 3) Distribution of the B2 SPHEROTEST reagent:

The B2 M SPHEROTEST reagent is vigorously vortexed (1 min).

The vortexed reagent is placed in a gutter. Using a precision multichannel pipette, 30 μl of reagent are distributed, column by column, in all of the columns, except for column 12.

4) Incubation:

To carry out the immunological reaction, the microplate is stirred (rotary shaker) immediately after dispensing the reagent:

- duration: exactly 15 seconds

- Rotation speed: 1,000 rpm.

5) Blocking of the reaction:

The following two manipulations are carried out successively:

. 1) Removal of the micro-plate from the rotary agitator, then, using a precision multichannel pipette, 100 μl of blocking solution are distributed, column by column, in all the columns (including the column 12). . 2) Agitation (rotary agitator) of the microplate having received the blocking solution:

- Duration: exactly 30 seconds

- Rotation speed: 600 rpm. 6) Reading the result:

The micro-plate is read at a Reading wavelength of 340 nanometers for example. NB: stability of the micro-plate (crimped with the adhesive film ⁾ : 5 hours (4-8 ° C) a reading made after 5 hours (up to 8 hours) requires rehomogenization of the micro-plate ( stirring 600 rpm - 1 minute).

Realization example n_ ° _3: Determination of human microglobular B2: We proceed exactly as for example n ° 1, making sure to dispense 20 μl of the reagent (step 3), to incubate for 2 minutes at 1,000 rpm (step 4) and shake the microplate for 2 minutes at 600 rpm (step 5).

Realization example n ° _ 4: Assay of native anti DNA: We proceed as for example n ° 3 taking care, to distribute 20 μl of biological samples (step 1), and to rehydrate ⁽ step 2) with 20 μl of water.

Realization example n ° _ 5: Assay of mouse onoclonal IgG: Manipulations are carried out identical to examples 2 to

4 by distributing 20 μl of biological samples (step 1) and by rehydrating (step 2) The micro-wells with 20 μl of water. The incubation time (step 4) is exactly 15 seconds at 1,000 rpm, the shaking time of the blocking phase (step 5) being exactly 4 minutes at 600 rpm.

The invention is not limited to the examples described and shown, since various modifications can be made without departing from its scope. POSSIBILITY OF INDUSTRIAL APPLICATION:

The invention applies to the assay of antibodies by antigens and vice versa.

Claims

1 - Method for assaying a substance of clinical interest which is immunologically reactive with other substances of the same type, of the type assaying of an antigen by an antibody and vice versa, of the type in which:

- an immunologically active substance, acting as a dosing agent, is grafted beforehand onto natural or synthetic micro-particles to constitute a dosing reagent,

- the maximum absorption of visible ultraviolet light is determined, either from a suspension in a liquid medium of said non-agglutinated micro-particles, or from the dosing reagent in liquid suspension, the determination being carried out by making the absorption spectrum ultraviolet visible from one or the other of said suspension, the wavelength corresponding to the maximum absorption being called λ max,

the dosing reagent is mixed with the substance to be measured diluted in an appropriate manner and in a known manner,

said mixture is incubated, by shaking, in order to carry out immunological agglutination of said micro-particles in the incubation medium,

- The reading of the result is then carried out in a reading device of the spectro-photometer type, by visible ultra-violet absorption spectrophotometry, by placing it at the vpisinage of the said wavelength λ max, - the concentrations are calculated of the substance to be dosed in

The sample, by comparison with the visible ultraviolet absorption results measured at the same wavelength λ max obtained, under the same conditions, on a standard range, characterized in that, with a view to carrying out the assay a plurality of samples in a single pass in the reading device:

to choose all of the dosing operations, a dosing reagent whose micro-particles have at least one λ max corresponding substantially to at least one length is chosen beforehand Reading wave authorized by the reading device,

- the dosing reagent is mixed with the plurality of samples to be assayed diluted in a known manner, in a series of individualized volumes, consisting of a series of micro-wells formed in a micro-plate,

- All of said mixtures are incubated simultaneously by subjecting said microplate to stirring.

the reading of the plurality of results is carried out by introducing the micro-plate into a spectrophotometric and automatic micro-plate reader programmed on a reading wavelength close to the λ max characteristic of the chosen micro-particles,

2 - Method according to claim 1, characterized in that it consists in distributing the dilutions of the samples to be assayed in a series of micro-wells belonging to the same micro-plate as the micro-wells containing the standard range points.

3 - Method according to claim 1, characterized in that it consists in reconstituting the standard range of a micro-plate by simple rehydration of micro-cups containing the standard range points (4) lyophilized in the micro-cup.

4 - Process according to claim 1, characterized in that the dosing reagent is dehydrated or lyophilized in the micro-cups (2) of the micro-plate (1). 5 - Process according to claim 1, characterized in that the natural or synthetic micro-particles used have a maximum visible ultraviolet absorption (λ max) between 300 and 690 nanometers and, preferably, between 300 and 450 nanometers, in the vicinity of the following wavelengths: 340 nm - 405 nm - 414 nm - 450 nm.

6 - Method according to claim 1, characterized in that the micro-plate (1) used is either a standardized micro-plate of the ELISA type whose usual function is to allow the reading of a series of colorimetric reactions, or a cell culture microplate. 7 - Process according to claim 1, characterized in that the micro-particles are synthetic and chosen from the group consisting of synthetic acrylonitrile polymers, by acrylo-nitri derivatives of acrylic acid, by acrylic esters, by silicones and preferably from polymers consisting of polystyrene, vinyl toluene, styrene butadiene and vinyl butadiene, said particles being chosen from those having an average diameter between 0.1 and 1.4 micrometers to read between 300 and 450 nanometers . 8 - Process according to claim 7, characterized in that the micro-particles are chosen so that the ratio λ_ max d of the maximum absorption of the micro-particles on The average diameter of the micro-particles is between 0.4 and 0 , 8 and is, advantageously, substantially equal to 0.65.

9 - Process according to claim 7, characterized in that the synthetic micro-particles are micro-particles of polystyrene with a diameter between 0.4 and 0.7 micrometers and between 0.8 and 1.2 micrometers to read respectively at in the vicinity of 340 nm and 405 nm, or of a diameter of approximately 0.1., 0.3, 0.8, 1 and 1.4 micrometers to read respectively in the vicinity of 300, 310, 380, 405 and 420 nanometers.

10 - Process according to claim 1, characterized in that, during the incubation, the micro-plate is subjected to a stirring frequency between 5 and 25 Hertz and, preferably, close to 16 to 20 Hertz.

11 - Device for implementing the method according to one of claims 1 to 10, comprising: - at least one micro-plate (1) in which is formed a plurality of micro-wells (2): - a dosing reagent comprising micro-particles grafted onto an immunologically active substance and capable of exhibiting at least maximum absorption (λ max) for at least one Reading wavelength authorized by an automatic reading device, of the spectro-photometer type,

- a solution for blocking the agglutination reaction,

- a standard range (4) of the active substance i munologically.

12 - Device according to claim 11, characterized in that the standard range (4) consists of a series of lyophilized range points pre-deposited in origin at the bottom of the micro-cups ⁽ 2) in pre-calibrated quantity, The range points are ready for use after rehydration.

13 - Device according to claim 11, characterized in that the dosing reagent and the standard range are liquid or lyophilized and stored in bottles (7, 8).

14 - Device according to claim 11, characterized in that the dosing reagent is liquid and pre-deposited in the micro-cups, which are covered with a closure cap (5). 15 - Device according to claim 11, characterized in that the dosing reagent is dehydrated or lyophilized and pre-deposited at the origin in constant quantity and ready for use by rehydration at the bottom of a series of micro-cups.

16 - Device according to Claims 12 and 15, characterized in that the standard range points (4) and the dosing reagent are distributed in a ring or increasing at the bottom of the micro-particles (2).

17 - Device according to claim 11, characterized in that the micro-plate (1) is provided with a sealing cap (5) sealed and tearable capable of closing the micro-cups.

18 - Device according to claim 11, characterized in that the dosing reagent contains micro-particles which have at least an absorption maximum (λ max) between 300 and 690 nanometers and, preferably, in the vicinity of the wavelengths following: 340, 405, 414, 450, 492, 540 nanometers. 19 - Box (6) intended for the simultaneous dosing of a plurality of samples comprising a device according to claims 10 to 18.