FR2673292A1 - Method for immunofixing or for immunoelectrophoresis with the aid of an assembly of at least two different immune sera or two different immunoglobulin solutions, and kit for implementing such a method - Google Patents

Abstract

The subject of the invention is a method for immunofixing or for immunoelectrophoresis using immunological reactions with the aid of an assembly of immune sera or of solutions of immunoglobulins, which are all different from one another, characterised in that each immune serum or each solution of immunoglobulins used is coloured with the aid of a dye or of a mixture of dyes, the dye or the mixture having, in particular, the following properties: - it does not affect the quality of the immune serum or of the solution of immunoglobins, - it does not affect the immunological reaction, and - preferably, it does not affect the preservation of the immune serum or of the solution of immunoglobins, the assembly of immune sera or of the solutions of immunoglobulins being coloured by at least two dyes of different colour or by at least two mixtures of dyes of different colour. The invention also relates to the kits in which these immune sera or solutions of immunoglobulins are combined for implementing the abovementioned method.

Description

INMUNOFIXATION OR IZMUNOELECTROPHORESIS PROCESS
HELP FROM A SET OF BLACKS TWO INNUNSERUNS
DIFFERENT OR TWO 80LUTIONS OF INXUNOGLOBULINS
DIFFERENT AND KIT FOR IMPLEMENTING SUCH
PROCESS
The subject of the invention is a method of immunofixation or immunoelectrophoresis using immunological reactions, using a set of at least two different immune sera or two different immunoglobulin solutions and a kit (or kit). ) in which these immunsera or immunoglobulin solutions are combined, for the implementation of such a method.

 Immunofixation is a process intended to demonstrate and characterize, for example, paraproteins (proteins secreted abnormally during any benign or malignant gammopathy) of the immunoglobulin family, and this process can be carried out, for example, as follows - several aligned deposits (for example 6) of the same sample are made on an electrophoresis plate, - an electrophoretic migration is carried out to separate the different molecular species of the sample according to the six tracks, - once the migration finished, parallel deposition of the different antisera is carried out along these tracks, each antiserum covering an entire track, these antisera being for example of specific anti-IgG, anti-IgA, anti-IgM, anti-kappa and anti-lambda, one of the tracks being fixed by a protein fixer which insolubilizes all of the proteins in the zone which it covers to serve as witness.

 After incubation, washing and staining, we can determine according to the areas precipitated by the specific antisera which are located at the level of the paraprotein visualized on the proteinogram, the type of heavy chain (gamma, alpha and mu) and light chain (kappa or lambda) of the paraprotein concerned.

 The object of the invention is to provide a method of immunofixation or immunoelectrophoresis implementing immunological reactions, using a set of different sera or different immunoglobulin solutions having the advantage of making it possible to check that the right immune system (or the right immunoglobulin solution) is used, and in particular that the same immune serum (or the same immunoglobulin solution) is not used several times, when he (she) should not to be only once.

 The object of the invention is also to propose an immunofixation or immunoelectrophoresis method using a set of different sera or different immunoglobulin solutions, having the advantage of controlling the deposition and the quality of the distribution of immunsera on the immunofixation or immunoelectrophoresis plate.

 Another object of the invention is to propose a method of immunofixation or immunoelectrophoresis using a set of different sera or solutions of different immunoglobulins, having the advantage of controlling, after the immunological reaction has taken place. , that the correct immune serum or immunoglobulin solution has been used.

 The invention relates to an immunofixation or immunoelectrophoresis method implementing immunological reactions, using a set of immunsera or immunoglobulin solutions, all different from each other, this method being characterized in that each immuniserum or each immunoglobulin solution used is colored using a dye or a mixture of dyes, the dye or the mixture having the following properties - it retains an appropriate coloration in the immuniser or immunoglobulin solution, - it does not affect the quality of the immuniserum or the immunoglobulin solution, - it does not affect the immunological reaction and, - preferably, it does not affect the conservation of the immunoglobulin or immunoglobulin solution, all the immunoglobulin or immunoglobulin solutions being colored by at least two dyes of different color or of different color intensity or by at least ins two mixtures of dyes of different color or different color intensity.

 The expression "the immuniserum, or the immunoglobulin solution, retains an appropriate coloration in the immuniserum or the immunoglobulin solution" means on the one hand that the intensity of coloration evaluated by measuring the optical density at the wavelength corresponding to the maximum absorption does not change over time and on the other hand that the visible spectrum of this immuniser or of this colored immunoglobulin solution remains unchanged over time.

 The expression "the immuniserum, or the immunoglobulin solution, does not affect the quality of the immuniserum or the immunoglobulin solution" implies that it does not modify the structure of the protein fractions of the immuniserum or the immunoglobulin solution and in particular that it does not cause precipitation of these protein fractions which could result in the appearance of a disorder.

 The expression "the immuniserum, or the immunoglobulin solution, does not affect the immunological reaction" means that the immuniser or the colored immunoglobulin solution has the same title as the immuniser or immunoglobulin solution before staining at the same dilution.

 The expression "the immuniserum, or the immunoglobulin solution, does not affect the storage of the immuniserum or the immunoglobulin solution" means that the title of the immuniserum or the immunoglobulin solution has the same stability over time as the non-stained immunoglobulin or immunoglobulin solution stored under the same conditions.

 Two immune sera or two immunoglobulin solutions have a different intensity of color, when their color is the same (same adsorption spectrum in the visible), but they have a different intensity of staining, one of the immune sera or immunoglobulin solutions being more colored than the other, which results in the fact that the ratio between the optical density (corresponding to the maximum of adsorption) of the immuniser or the most colored immunoglobulin solution and the optical density (corresponding to the maximum adsorption) of the less colored immuniserum or immunoglobulin solution is greater than or equal to 2.

 The dye (or mixture of dyes) used is chosen from water-soluble dyes, of ionic or nonionic nature, insofar as it has the properties stated above.

 The dye or mixture of dyes must be such that it retains an appropriate coloration, that is to say sufficient to make it possible to identify its presence in the immune serum or in the immunoglobulin solution in which it is put.

 The dye must also be such that it does not affect the quality of the immuniserum or the immunoglobulin solution, that is to say that the antibodies of the immuniserum or of the immunoglobulin solution do not lose nothing of their property to participate in an immunological reaction.

 The dye should not affect the immunological reaction.

 Preferably, the dye should not affect the storage of the immuniserum or the immunoglobulin solution, which should be able to be stored for at least about 1 year and advantageously about 3 years.

 In the event that the dye could affect the storage of the immuniserum or the immunoglobulin solution, it should not be introduced into the immuniserum or the immunoglobulin solution until the use of the said immuniserum. or said immunoglobulin solution on the immunofixation or immunoelectrophoresis plate.

 When all of the immunosera or immunoglobulin solutions are stained with two dyes or two mixtures of dyes of different color, a two-color set of immunsera or immunoglobulin solutions is obtained.

 According to an advantageous embodiment of the method of the invention, each immune serum or each immunoglobulin solution is colored by a dye or by a mixture of dyes such that all the immunsera or all the immunoglobulin solutions are of different color or d different color intensity.

 According to another method of the invention at least two immune sera or solutions of immunoglobulins are colored by the same dye or the same mixture of dyes such that at least two immune sera or solutions of immunoglobulins are of the same color (same adsorption spectrum in the visible), but have a different intensity of coloration, one of the immunsera or immunoglobulin solutions being more colored than the other, which results in the fact that the ratio between the optical density (corresponding to the maximum adsorption) of the most colored immunoglobulin or immunoglobulin solution and the optical density (corresponding to the maximum adsorption) of the least colored immuniser or immunoglobulin solution is greater than or equal to 2 .

According to another embodiment of the method of the invention, five different colored immunums or five different colored immunoglobulin solutions are used, these five different immunums or these five different immunoglobulin solutions having a different color or color intensity, for example: - pink with a maximum absorption at 555 nm - night blue """" 625 nm - khaki """" 480 nm - green """" 427 nm - light blue """625 nm or for example five different sera or solutions of different immunoglobulins each having a different color, for example: - purple with a maximum absorption at 555 nm - green """" 427 nm - light blue """" 625 nm - orange """"480 nm - red""""520 nm
According to another embodiment of the process of the invention, the amount of dye intended to color each immuniserum or immunoglobulin solution varies from approximately 0.1 mg / 100 ml to approximately 1 g / 100 ml, advantageously approximately 0.5 mg / 100 ml to approximately 100 mg / 100 ml.

 According to another embodiment of the method of the invention, the amount of dye intended to color each immuniserum, or each immunoglobulin solution, is such that a visible coloration of a drop of immuniserum or solution is obtained. immunoglobulins of approximately 80 Al distributed over an area of approximately 3.6 cm2.

 This means that the colored serum or immunoglobulin solution distributed over this gel surface has, at the maximum absorption of the colored solution, an optical density greater than or equal to 0.015.

 The invention also relates to a kit (or kit) for implementing an immunofixation or immunoelectrophoresis method, comprising - a set of immunsera or immunoglobulin solutions, - and at least two color dyes different or two mixtures of dyes of different color, to stain the immune sera or immunoglobulin solutions in such a way that all of the immune sera or immunoglobulin solutions are stained with at least two dyes of different color or intensity different color or by at least two mixtures of dyes of different color or different color intensity, the dye or mixture of dyes being such that - it retains an appropriate coloration in the immuniserum or the immunoglobulin solution, - it does not affect the quality of the immune serum or immunoglobulin solution, - it does not affect the immunological reaction, - preferably it does not affect the c onservation of immunsera or immunoglobulin solutions, or - a set of immunsera or immunoglobulin solutions colored by at least two dyes of different color or by at least two mixtures of dyes of different color, the dye or the mixture of dyes being such that - it retains an appropriate coloration in the immuniserum or the immunoglobulin solution, - it does not affect the quality of the immuniserum or the immunoglobulin solution, - it does not affect the immunological reaction , and - preferably, it does not affect the preservation of the sera or of the immunoglobulin solutions.

 An advantageous kit is such that each immune serum or each immunoglobulin solution is colored by a dye or by a mixture of dyes such that all of the immune sera or immunoglobulin solutions are of different color.

 In an advantageous kit of the invention, at least two immune sera or immunoglobulin solutions are stained with the same dye or the same mixture of dyes such that at least two immune sera or immunoglobulin solutions are of the same color (same spectrum of adsorption in the visible), but have a different intensity of coloring, as indicated above.

Another advantageous kit contains five different immune sera or five different immunoglobulin solutions, each of these immunoglobulin solutions or solutions having a different color or color intensity, for example - pink with maximum absorption at 555 nm - night blue """" 625 nm - khaki """" 480 nm - green """" 427 nm - light blue """625 nm or for example five different sera or different immunoglobulin solutions each having a different color, for example - purple with a maximum absorption at 555 nm - green ""'I 11 427 nm - light blue """IF 625 nm - orange""""480 nm - red """" 520 nm
Another advantageous kit is such that the quantity of dye intended to color each immuniserum or each immunoglobulin solution varies from approximately 0.1 mg / 100 ml to approximately 1 g / 100 ml, advantageously approximately 0.5 mg / 100 ml at approximately 100 mg / 100 ml.

 Another advantageous kit is such that the quantity of dye intended to color each immune serum or each immunoglobulin solution is such that a visible coloration of a drop of immune serum or immunoglobulin solution is obtained of approximately 80 μl. spread over an area of approximately 3.6 cm2.

 According to an advantageous embodiment, the kit of the invention is such that the colored immune sera or the colored immunoglobulin solutions are packaged in bottles bearing labels of the same color as that of the immuniser or the immunoglobulin solution. that they contain respectively.

EXAMPLES
Example 1
An immunofixation kit has been prepared intended for the identification of gammopathies of human serum in which - the anti-IgG immune serum or anti-IgG immunoglobulin solution is colored in pink with a conventional dye known to man of the art and has a maximum absorption at about 555 nm and an optical density at this wavelength of about 2.0; - the anti-IgA immune serum or anti-IgA immunoglobulin solution is colored in dark blue with a conventional dye known to those skilled in the art and has a maximum absorption at around 625 nm and an optical density at this wavelength of about 7.0 ;; - the anti-IgM immune serum or anti-IgM immunoglobulin solution is colored in khaki with a mixture of two conventional dyes known to those skilled in the art and has a maximum absorption at around 480 nm and an optical density at this wavelength of about 6.8; - the anti-kappa immune serum in anti-kappa immunoglobulin solution is colored green by a mixture of two conventional dyes known to those skilled in the art and has a maximum absorption at around 427 nm and an optical density at this wavelength of about 2.0; - the anti-lambda immune serum or anti-lambda immunoglobulin solution is colored in light blue by a conventional dye known to those skilled in the art and has a maximum absorption at approximately 625 nm and an optical density at this wavelength of about 1.5.

Example 2
An immunofixation kit has been prepared for the identification of Bence Jones proteins in which - the anti-IgG trispecific immune serum, -IgA, -IgM, or anti-IgG immunoglobulin solution, -IgA, -IgM, is colored purple by a conventional dye known to a person skilled in the art and has a maximum absorption at around 555 nm and an optical density at this wavelength of around 2.0; - the anti-kappa immune serum or anti-kappa immunoglobulin solution is colored green by a mixture of two conventional dyes known to those skilled in the art and has a maximum absorption at around 427 nm and an optical density at this wavelength of about 2.0 ;; - the anti-lambda immune serum or anti-lambda immunoglobulin solution is colored in light blue by a conventional dye known to those skilled in the art and has a maximum absorption at around 625 nm and an optical density at this wavelength of about 1.5; - the free anti-kappa immune serum or free anti-kappa immunoglobulin solution is colored orange by a conventional dye known to those skilled in the art and has a maximum absorption at approximately 480 nm and an optical density at this wavelength of about 10.8; - the free anti-lambda immune serum or free anti-lambda immunoglobulin solution is colored red with a conventional dye known to those skilled in the art and has a maximum absorption at approximately 520 mii and an optical density at this wavelength of about 20.5.

Example 3
a kit intended for immunoelectrophoresis was prepared with the same colored sera or the same colored immunoglobulin solutions as those described in Example 1.

Claims (13)

 1. Method of immunofixation or immunoelectrophoresis implementing immunological reactions using a set of immunsera or immunoglobulin solutions, all different from each other, this method being characterized in that each immuniser or each immunoglobulin solution used is colored using a dye or a mixture of dyes, the dye or the mixture having the following properties - it retains an appropriate coloration in the immuniserum or the immunoglobulin solution , - it does not affect the quality of the immuniserum or the immunoglobulin solution, - it does not affect the immunological reaction and, - preferably, it does not affect the preservation of the immuniserum or the immunoglobulin solution, all of the immunsera or immunoglobulin solutions being colored by at least two dyes of different color or of different color intensity or by at least two mixtures of co lorants of different color or of different color intensity.  2. Method according to claim 1, in which each immune serum or each immunoglobulin solution is colored by a dye or by a mixture of dyes such that all the immune sera or all the immunoglobulin solutions are of different color or intensity of different color.  3. Method according to any one of claims 1 or 2, wherein each immuniserum, or each immunoglobulin solution, is colored at the time of use in order to determine the possible formation of an immunological reaction.  4. Method according to any one of claims 1 to 3, in which at least two immune sera or immunoglobulin solutions are stained with the same dye or the same mixture of dyes such that at least two immune sera or immunoglobulin solutions are same color (same adsorption spectrum in the visible), but have a different intensity of coloration, one of the immunsera or immunoglobulin solutions being more colorful than the other, which results in the fact that the ratio between the optical density (corresponding to the maximum adsorption) of the most colorful immunoglobulin or immunoglobulin solution and the optical density (corresponding to the maximum adsorption) of the immunoglobulin or the most immunoglobulin solution less colored is greater than or equal to 2.  5. Method according to any one of claims 1 to 4, in which five different colored immunums or five different colored immunoglobulin solutions are used, these five different immunums or these five different immunoglobulin solutions having a color or an intensity of different color, for example: - pink with maximum absorption at 555 nm - night blue "" "" 625 nm - khaki "" "" 480 nm - green "" "" 427 nm - light blue "" "625 nm or for example five different sera or solutions of different immunoglobulins each having a different color, for example: - purple with a maximum absorption at 555 nm - green "" "" 427 nm - light blue "" "" 625 nm - orange "" "" 480 nm - red "" "" 520 nm  6. Method according to any one of claims 1 to 5, in which the quantity of dye intended to color each immune serum or immunoglobulin solution varies from approximately 0.1 mg / 100 ml to approximately 1 g / 100 ml, advantageously from about 0.5 mg / 100 ml to about 100 mg / 100 ml.  7. Method according to any one of claims 1 to 5, in which the amount of dye intended to color each immuniserum or each immunoglobulin solution is such that a visible coloration of a drop of immuniserum or immunoglobulin solution of approximately 80 μl distributed over an area of approximately 3.6 cm2.  8. Kit (or kit) for implementing an immunofixation or immunoelectrophoresis process, comprising: - a set of immunsera or immunoglobulin solutions, - and at least two dyes of different color or two mixtures of dyes of different color, to stain the immune sera or immunoglobulin solutions in such a way that all of the immunsera or immunoglobulin solutions are stained with at least two dyes of different color or of different color intensity or by at least two mixtures of dyes of different color or of different color intensity, the dye or mixture of dyes being such that - it retains an appropriate coloration in the immune serum or the immunoglobulin solution, - it does not affect not the quality of the immuniserum or the immunoglobulin solution, - it does not affect the immunological reaction, - preferably it does not affect the preservation of the immune sera or immunoglobulin solutions, or - a set of immune sera or immunoglobulin solutions colored by at least two dyes of different color or by at least two mixtures of dyes of different color, the dye or mixture of dyes being such that - it retains an appropriate coloration in the immuniserum or the immunoglobulin solution, - it does not affect the quality of the immuniserum or the immunoglobulin solution, - it does not affect the immunological reaction, and - preferably , it does not affect the storage of immune sera or immunoglobulin solutions.  9. Kit according to claim 8, in which each immune serum or each immunoglobulin solution is colored by a dye or by a mixture of dyes such that all the immunsera or immunoglobulin solutions are of different color.  10. Kit according to any one of claims 8 or 9, in which at least two immune sera or immunoglobulin solutions are stained with the same dye or the same mixture of dyes such that at least two immune sera or immunoglobulin solutions are same color (same adsorption spectrum in the visible), but have a different intensity of coloration, one of the immunsera or immunoglobulin solutions being more colored than the other, which results in the fact that the ratio between the optical density (corresponding to the maximum adsorption) of the most colorful immunoglobulin or immunoglobulin solution and the optical density (corresponding to the maximum adsorption) of the immunoglobulin or the most immunoglobulin solution less colored is greater than or equal to 2.  11. Kit according to any one of claims 8 to 10, containing five different immune sera or five different immunoglobulin solutions, each of these immune sera or these immunoglobulin solutions having a different color or color intensity, for example - pink with maximum absorption at 555 nm - night blue "" "" 625 nm - khaki "" "" 480 nm - green "" "" 427 nm - light blue "" "625 nm or by example five different sera or solutions of different immunoglobulins each having a different color, for example: - purple with a maximum absorption at 555 nm - green "" "" IF 427 nm - light blue "" "" 625 nm - orange "" "" 480 nm - red "" "" 520 nm  12. Kit according to any one of claims 8 to 11, in which the quantity of dye intended to color each immune serum or each immunoglobulin solution varies from approximately 0.1 mg / 100 ml to approximately 1 g / 100 ml, preferably from about 0.5 mg / 100 ml to about 100 mg / 100 ml.  13. Kit according to any one of claims 8 to 11, in which the amount of dye intended to color each immuniserum or each immunoglobulin solution is such that a visible coloration of a drop of immuniserum or immunoglobulin solution of approximately 80 l distributed over an area of approximately 3.6 cm.