EP1121588A1

EP1121588A1 - Multi-array microsystem for chemical or biological analysis

Info

Publication number: EP1121588A1
Application number: EP99947540A
Authority: EP
Inventors: Jean-Frédéric Clerc; Patrice Caillat; Gérard Bidan; Marc Cuzin
Original assignee: Commissariat a lEnergie Atomique CEA
Current assignee: Commissariat a lEnergie Atomique et aux Energies Alternatives CEA
Priority date: 1998-10-13
Filing date: 1999-10-12
Publication date: 2001-08-08
Also published as: FR2784466B1; JP2002527747A; FR2784466A1; WO2000022425A1

Abstract

The invention concerns a method for producing a multi-array microsystem for chemical or biological analysis comprising the following steps which consist in: designing a structure provided with microwells (21), each microwell being designed to receive a reagent and provided with fixing means (24) for maintaining said reagent; placing a first organic compound (30) on the fixing means (24) of the microwells, the first organic compound comprising a binding function with the second organic compound (51) and a binding function with the fixing means (24); placing, in each microwell (21), the second organic compound (51), the second organic compound having a corresponding binding function of the first organic compound (30) and comprising said reagent, to obtain in each microwell chemical or biological probes formed by the reagent bound to the fixing means (24) by the mutual coupling of the binding functions of the first (30) and second (51) organic compounds.

Description

MULTIPLE POINT CHEMICAL ANALYSIS MICROSYSTEM OR

ORGANIC

Technical area

The present invention relates to a micro-system with multiple points of chemical or biological analysis implementing a coupling between the probes and a substrate.

Conventional microelectronics is increasingly called upon to be a link in much more complex systems in which several functions are integrated. These systems or micro-systems range from physical sensor applications to the latest development of so-called "biological" chips.

In the first case, a sensitive cell capable of measuring a physical phenomenon is associated with an integrated circuit capable of ensuring the processing of information and its exploitation. This is the case with pneumatic safety cushions for the automotive industry (known as an "air bag" in English terminology). In the second case, an integrated circuit undergoes a finishing allowing it to be used in a biological medium. This is the case, for example, with an integrated glucose meter or blood pressure probes. In all cases, the interface between the medium of conventional microelectronics and that of sensors or biologists is the key element of these micro-systems.

Chemical or biological analysis is undergoing the revolution of linked miniaturization the use of microtechnologies. When multiple tests can be grouped on a support of a few mm ² , costs are reduced and a once exceptional analysis can be used routinely.

The demand for systems allowing chemical or biological analysis at a very large number of points is emerging at the present time with the appearance of screening in pharmacology and DNA tests in biology.

In the first case, it is necessary to determine on a support comprising a large number of cuvettes filled with the same reagent, the effect of different molecules which are selectively deposited in each cuvette in a sequential manner. In the second case, each cuvette is filled with a different DNA probe and the analyte whose genomic sequence is to be known is brought into contact at the time of analysis with all of the cuvettes. In analytical chemistry also the demand is strong towards the miniaturization of the cuvettes of chemical reactions _t

From both the point of view of making the bowls, depositing the liquids in these bowls and the system for reading and acquiring results, research and development efforts are significant.

State of the art

In the field of biological analysis or more generally tests in pharmacology of new molecules, the reduction in the size of the test tool is extremely attractive from an economic point of view. More precisely, we can assimilate an analysis micro-system to a structure associating a support on which different reagents are all first fixed then placed in the presence of the solution to be analyzed, and a method for measuring the reactivity obtained. Optionally, processing in the micro-system itself of the information obtained can be provided.

There are different techniques for attaching different reagents to a substrate.

A first technique consists in activating sites where the reagents will then be deposited and fixed by various chemical molecules. It is a technique mainly used on glass substrates. The reagents are deposited by micro-pipetting or by a technique of the inkjet type. On the chemical side, to ensure the interface between the substrate and the reagent, mention may be made of silanes, lysines, thioles when the substrate is previously coated with gold. This chemistry is complex, especially when it comes to controlling its reproducibility on a substrate that may have a few thousand different sites. Mention may be made, as representative of this technique, of US Pat. No. 5,474,796 which relates to surface structuring: the reagents are fixed to a substrate having hydrophilic zones and hydrophobic zones. The matrixing obtained is therefore very regular.

According to a second technique applied to the field of DNA chips (the reagent is a DNA probe, in particular an oligonucleotide of around twenty bases), it has been proposed to construct the probe base after base on each site. It is known to use successive masks to make this synthesis in situ: each site is covered with a photoprotected base. The photomasking then makes it possible to remove the protection from the sites and to chemically attach an additional photoprotected base. The operation is repeated until the desired probe is obtained at each site. It is currently possible to build tens of thousands of different probes on a substrate. This technique is excellent but it does not make it possible to obtain probes with a large number of bases (the limit is approximately 20). It is also possible to fix at the start a base protected no longer by a photosensitive radical but by a chemically sensitive radical. It is then necessary, by pipetting or by a technique of the inkjet type, to come locally to the sites chosen to remove the protection of the existing base and hang an additional base there.

A third technique relates to electrodeposition on site electrically polarized of a conductive polymer carrying the selected reactive species. We can refer to this subject in the article "Electropolymerization of pyrrole and immobilization of glucose oxidase in a flow System: influence of the operating conditions on analytical performance" by Juan-C. VIDAL et al., Published in Biosensors &

Bioelectronics, vol. 13, No. 3-4, pages 371-382, 1998. The substrate is electrically connected to the outside and soaked in a tank containing the chemical species to be deposited. The site chosen is polarized and the copolymerization is carried out (in less than a minute at a voltage below I V). We pass to another solution carrying another reagent, another site is polarized on the surface of the substrate and so on. By this means, different reagents were fixed on different areas of the substrate, thus allowing a multipoint analysis.

An interesting improvement of this last technique consists in integrating the addressing electronics of the sites in the substrate itself. The conductive polymers used for this process are the polyanilines, polypyrroles. We can refer to this subject in documents WO 94/22 889, FR-A-2 741 475 and FR-A-2 741 476. This way of doing is interesting because the fixation of the probe on its site is strong, reproducible and well controlled. It is a sequential technique: each site is successively polarized and the substrate is completely covered or soaked in the solution carrying the reagent at each pass. However, when the number of sites becomes large, the processing time of each site support becomes prohibitive: as many times the time of copolymerization plus the time of rinsing and introduction of the new electrolyte.

The use of these biological probe devices can call on a very wide range of methods: electrical measurement by impedance-metry, microbalance, optical measurement by change of refractive index, radioactive labeling, fluorescence. The latter method is used more and more because it is relatively easy to implement and it has good sensitivity. Schematically, it consists in coupling the analyte to be tested with a fluophore. The analyte is brought into contact with the reagent fixed locally on the micro-system. If there is reaction / pairing of any kind whatsoever, the analyte carrying the fluophore will remain on the test zone. After washing, a reading of the fluorescence will make it possible to determine whether there has been pairing at the carrier site.

Statement of the invention

To remedy the problems of the prior art, the present invention proposes the use of a structure where each site is provided with a compound organic offering a biotin function. Each site can then receive a chemical or biological probe constituted by a determined reagent (a small piece of a DNA strand for example) associated for example with an avidin or streptavidin function. In this case, the coupling which takes place between the avidin and biotin functions ensures the fixation of the probes on their respective sites.

The subject of the invention is therefore a process for producing a micro-system with multiple points of chemical or biological analysis, comprising the steps consisting in:

- design a structure provided with micro-cuvettes, each micro-cuvette being intended to receive a reagent and being provided with fixing means making it possible to attach said reagent to it,

obtaining a first organic compound comprising a hooking function with said fixing means and a hooking function with a second organic compound, these two hooking functions being separated by a spacer,

- obtain a second organic compound comprising an attachment function with the corresponding attachment function of the first organic compound and comprising a reagent,

fix the first organic compound on the means for fixing the micro-cuvettes by means of its corresponding attachment function,

- place, in each microcuvette, a second organic compound to obtain in each microcuvette chemical or biological analysis probes constituted by the reagent attached to the fixing means by coupling the corresponding attachment functions of the first and second organic compounds. According to a first variant, the step consisting in fixing the first organic compound on the means for fixing the micro-cuvettes is carried out by electro-polymerization, the fixing means being electrically accessible conductive means, the hooking function of the first organic compound with the fixing means consisting of a conductive monomer, a counter-electrode being used to carry out the electro-polymerization. The conductive means can comprise an electrode common to all the micro-cuvettes. The structure can be designed from a substrate, one face of which has said common electrode, a layer of insulating material being deposited on said common electrode, the layer of insulating material being hollowed out up to said common electrode to form the micro-cuvettes whose bottom is constituted by the common electrode. The structure can also be designed from an active substrate having a plurality of electrodes on one of its faces, this plurality of electrodes constituting the fixing means, a layer of insulating material being deposited on said face, the layer of insulating material being hollowed out to the electrodes to form the micro-cuvettes, multiplexing means being provided for electrically connecting the plurality of electrodes in order to carry out the electro-polymerization. The counter-electrode may be an electrode integral with the structure or be placed opposite the fixing means during the electro-polymerization operation. Advantageously, the conductive monomer of the first organic compound is pyrrole.

According to a second variant, the step consisting in fixing the first organic compound on the means for fixing the micro-cuvettes consists in putting using a covalent bond between the attachment function of the first organic compound with the fixing means and the fixing means. This covalent bond is for example of silanization type (silane-biotin) or a self-assembly using a thiol-biotin bond.

According to a third variant, the step consisting in fixing the first organic compound to the means for fixing the micro-cuvettes is carried out chemically, by adding a reagent capable of causing polymerization on the means for fixing the first compound organic. This first organic compound can be pyrrole and the reagent capable of causing the polymerization of a ferric salt. According to a particularly advantageous aspect, the hooking function of the first organic compound with the second organic compound is a biotin function, the hooking function of the second organic compound with the first organic compound being an avidin or streptavidin function. The first organic compound can be a biotinilated pyrrole. The second organic compound can consist of said reagent directly attached to the avidin or streptavidin function. In this case, the step consisting in placing, in each microcuvette, the second organic compound can comprise the deposition of a solution containing the second organic compound in each microcuvette then the elimination of this solution so as to keep only the probes obtained by selective attachment of the first and second organic compounds, for example by binding between biotin and streptavidin / avidin.

The second organic compound can also consist of said reagent attached to the avidin or streptavidin function via a biotin function. In this case, the step consisting in placing, in each microcuvette, the second organic compound can comprise the deposition of a first solution of avidin or of streptavidin in each microcuvette, then the elimination of this first solution to reveal the first organic compound with the biotin function complexed by said avidin or said streptavidin, then the deposition of a second solution containing said reagent in biotinilated form, then the elimination of this second solution to keep only the probes obtained.

The invention also relates to a micro-system with multiple chemical or biological analysis points constituted by a structure provided with micro-cuvettes, each micro-cuvette being intended to receive a reagent and being provided with fixing means allowing attaching said reagent thereto via a first organic compound, the reagent being part of a second organic compound, the first organic compound comprising a bonding function with the second organic compound and a bonding function with the means fixing, these two attachment functions being separated by a spacer, the second organic compound comprising an attachment function with the corresponding attachment function of the first organic compound.

According to a first variant, the fixing means are electrodes and the attachment function with the fixing means of the first organic compound is a conductive polymer. The fixing means can form a common electrode. The micro-cuvettes can be formed in an insulating layer of said structure, the fixing means forming the bottom of the micro-cuvettes. The structure may include a counter-electrode arranged in opposition with respect to the bottom of the micro-cuvettes in order to be able to establish an electric field between the counter-electrode and the fixing means. Advantageously, said conductive polymer is a polypyrrole.

According to a second variant, the fixing means and the attachment function of the first organic compound with the fixing means are such that they form a covalent bond. This covalent bond is for example of the silanization (silane-biotin) or self-assembly type using a thiol-biotin bond.

According to a third variant, the attachment function of the first organic compound with the fixing means comprises a polymerization reagent, by chemical means, on the fixing means. This reagent can be a ferric salt.

According to a particularly advantageous aspect, the first organic compound comprises a biotin function for its attachment with an avidin or streptavidin function of the second organic compound. The first organic compound can be a biotinilated polypyrrole. The second organic compound can consist of said reagent directly attached to the avidin or streptavidin function. The second organic compound can also consist of said reagent attached to the avidin or steptavidin function via a biotin function.

Brief description of the drawings.

The invention will be better understood and other advantages and features will appear on reading the description which follows, given by way of non-limiting example, accompanied by the appended drawings in which:

- Figures 1A to 1E show different stages in the production of a structure for a micro-system with multiple points of chemical or biological analysis according to the present invention;

- Figure 2 illustrates a step of electropolymerization carried out in the micro-cuvettes of a structure intended for a micro-system with multiple points of chemical or biological analysis according to the present invention;

- Figure 3 shows a micro-bowl of the structure shown in Figure 2 and at the bottom of which is fixed a first organic compound, according to the method of producing a micro-system according to one invention, -

FIG. 4 represents another structure intended for a micro-system with multiple chemical or biological analysis points according to the present invention,

- Figure 5 illustrates a step of electropolymerization carried out in the micro-cuvettes of the structure shown in Figure 4; - Figures 6 to 8 illustrate the step of placing in a microcuvette the second organic compound to obtain a chemical or biological analysis probe according to the present invention; - Figure 9 illustrates the method of manufacturing a first organic compound usable for the present invention.

Detailed description of embodiment of the invention. Figures 1 to 8 illustrate the alternative embodiment for which the means for fixing the first organic compound are electrodes and for which the placement of this first organic compound is by electro-polymerization, these electrodes allowing the application of a potential electric.

For this alternative embodiment, two cases are to be considered. The structure may include a passive substrate, that is to say that it does not include integrated electronics. In this case, the substrate may be coated with a conductive plane (for example metallic) itself covered with a layer of a material ensuring the function of electrical insulation and in which the micro-cavities are formed. These lead locally to the driver plane. The exposed areas of the conductive plane then constitute the reception electrodes.

The substrate can also be active, in which case the electronics integrated into it can serve various functions: localized heating of sites, local pH measurement, reading of a fluorescence signal, etc. In most cases, it is not possible to short-circuit the sites for the subsequent functions which must remain addressable on each site independently of the others. The multiplexing necessary for these functions can then be used during the process of producing the micro-system. It is indeed possible to address all the sites collectively to carry out the operation of fixing the reagents. Each site may subsequently be addressed individually.

Figures 1A to 1E are cross-sectional and partial views. They illustrate a first embodiment of a micro-system according to the invention for which the counter-electrode is situated on the surface and for which the substrate is passive.

FIG. 1A represents a substrate 1 constituted by a wafer which can be made of a material such as glass, silicon, plastic. On a main face of this wafer, a metallic layer 3, for example in chromium, gold or platinum, with a thickness of between 0.1 and 10 μm, has been deposited. As shown in FIG. 1B, a photosensitive polymer film 5, for example a polyimide film with a thickness of between 1 and 50 μm, is deposited on the metal layer 3.

Micro-cuvettes 7 are then formed by exposure and development of the polyimide film (see FIG. 1C). They are advantageously formed with sloping sides. The micro-cuvettes formed locally reveal the metal layer 3. A new metal layer 9 is then uniformly deposited on the polyimide film including the interior of the micro-cuvettes 7. The metal layer 9 can be made of chromium, gold or platinum and be 0.1 to 10 μm thick.

As shown in FIG. 1D, a layer of masking resin 11 is deposited on the metal layer 9 and areas to be etched in this metal layer 9 are defined.

The metal layer 9 is then etched in accessible places and the resin 11 is removed. The structure shown in FIG. 1E is obtained. Each micro-bowl 7 has at its bottom an electrode 9a, all the electrodes 9a being electrically connected by means of the metal layer 3. A common electrode 9b covers the upper face of the polymer film 5. This structure is ready for the next step consisting in placing the first organic compound at the bottom of the micro-cuvettes.

Figure 2 illustrates the electropolymerization step. There is shown a structure 20 provided with micro-cuvettes 21 and which, unlike the case described above, is formed from an active substrate 22. The micro-cuvettes 21 have been formed in an insulating layer 23 deposited on the substrate 22 The bottom of the micro-cuvettes 21 is constituted by the electrodes 24 which can be, by multiplexing, electrically connected. As in the case described above, a common counter electrode 25 has been deposited on the upper part of the insulating layer 23. A potential difference can therefore be applied between the counter electrode 25 and the electrodes 24 electrically connected by multiplexing.

A layer 26 containing suitable monomers, for example a mixture of pyrrole and biotinylated pyrrole like that described below, is deposited on the face of the substrate 20 having the micro-cuvettes. An appropriate potential difference is applied between the counter electrode 25 and the electrodes 24. When the electro-polymerization is complete, the micro-cuvettes are rinsed and dried. An organic compound 30 is then obtained, as shown in FIG. 3, consisting of biotinilated polypyrrole, fixed on the electrodes 24. This organic compound adheres to the electrodes 24 by the pyrrole cycles and presents biotin molecules 31 attached to pyrrole cycles by spacers 32.

The structure intended to constitute the microsystem according to the invention may not include a counter electrode directly deposited on itself. Such a structure is shown in Figure 4. In this case, the structure 40 comprises for example a passive substrate 41, one face of which is covered with a metal layer 42 forming an electrode. An insulating layer 43 has been deposited on the metal layer 42 and etched to form micro-cuvettes 44. The electro-polymerization is then carried out, as shown in FIG. 5, in a tank 45 filled with an appropriate solution 46 containing a mixture of pyrrole and biotinilated pyrrole monomers. A DC voltage generator 47 is connected between the electrode 42 and a counter-electrode 48 arranged opposite the bottom of the micro-cuvettes 44. The electropolymerization causes the deposition of biotinilated polypyrrole on the visible areas of the electrode 42 as for FIG. 3. FIGS. 6, 7 and 8 illustrate the fixing of the second organic compound. The electropolymerization tank 45 may include an additional electrode serving as a reference.

The next step in the process is represented in FIG. 6. It consists in placing, in each microcuvette, a solution 50 comprising the second organic compound 51. This second organic compound comprises for example an avidin or streptavidin function if the first compound organic is biotinilated. A DNA probe can thus be constituted by choosing as the second organic compound DNA streptavidin which is marketed. Biotin / streptavidin recognition is widely used industrially because of the high recognition rate, insensitivity to temperature variations, a large choice of buffer, pH, etc.

FIG. 7 shows the attachment carried out between the biotin function of the organic compound 30 and the avidin or streptavidin function of the organic compound 51. After rinsing and drying, a micro-system is obtained, an analysis point of which is shown in FIG. 8. The micro-cuvette 21 is provided with probes formed by the association of organic compounds 30 and 51.

DNA, RNA, oligonucleotides, enzymes, nucleic or amino acids, proteins, antigens or any product which can be linked to 1 ′ can be attached to the biotinilated polypyrrole at the bottom of the microcuvettes. avidin (or streptavidin) or biotin. Indeed, one can form not only the association: polypyrrole-biotin / (strept) avidin-reactive, but also the association: polypyrrole-biotin / (strept) avidin / biotin-reactive.

It is then possible to use biotinilated DNA which is a commercial product. Biotin / streptavidin / biotin double recognition has the same qualities as the biotin / streptavidin recognition reaction.

It should be noted that the invention allows collective placement of the first organic compound on the bottom of the microwells.

The biotinilated polypyrrole which clings to the bottom of the microcuvettes is advantageously a copolymer synthesized from pyrrole and biotinilated pyrrole for which the biotin is attached to the nitrogen atom of a pyrrole cycle by a hydrophilic spacer. The choice of this spacer can be crucial. It must be long enough to ensure unrestricted recognition of biotin by avidin. A length of at least eleven atoms is particularly suitable.

Figure 9 is a diagram showing the synthesis of a biotinilated pyrrole. This summary is obtained by coupling an aminoalkylpyrrole and a biotin entity. The synthesis of the aminoalkylpyrrole was carried out using a reaction as described by JIRKOWSKY and BAUDY in Synthesis, 1981, page 481. The reagents used and the conditions of the reactions are as follows: i) 4,7,10-trioxa- 1.13-tridecanediamine (3 eq.), acetic acid / dioxane at reflux, for 5 h, yield 32%; ii) 10% KOH at reflux for 5 h, yield

65%; iii) ester of d-biotin N-hydroxysuccinimide (1 eq.) in dimethylformamide at room temperature for 16 h, yield 54%.

Claims

1. Method for producing a micro-system with multiple points of chemical or biological analysis, comprising the steps consisting in:

- design a structure (20, 40) provided with micro-cuvettes (21, 44), each micro-cuvette being intended to receive a reagent and being provided with fixing means making it possible to attach said reagent thereto,

obtaining a first organic compound (30) comprising a hooking function with said fixing means and a hooking function with a second organic compound, these two hooking functions being separated by a spacer,

- obtaining a second organic compound (51) comprising an attachment function with the corresponding attachment function of the first organic compound (30) and comprising a reagent, - fixing the first organic compound (30) on the fixing means (24 ) micro-bowls (21) by means of its corresponding hooking function,

- Place, in each micro-cuvette (21), a second organic compound (51) to obtain in each micro-cuvette (21) chemical or biological analysis probes constituted by the reagent attached to the fixing means by the coupling of corresponding attachment functions of the first and second organic compounds.

2. Method according to claim 1, characterized in that the step consisting in fixing the first organic compound (30) on the fixing means (24) of the micro-cuvettes (21) is carried out by electro-polymerization, the means fixing means being electrically accessible conductive means, the attachment function of the first organic compound (30) with the fixing means being constituted by a conductive monomer, a counter-electrode (25) being used to carry out the electro-polymerization.

3. Method according to claim 2, characterized in that the conductive means comprise an electrode (42) common to all the micro-cuvettes.

4. Method according to claim 2, characterized in that said structure (40) is designed from a substrate (41) one face of which has said common electrode (42), a layer of insulating material (43) being deposited on said common electrode, the layer of insulating material being hollowed up to said common electrode (42) to form the micro-cuvettes (44) whose bottom is constituted by the common electrode.

5. Method according to claim 2, characterized in that said structure (20) is designed from an active substrate (22) having a plurality of electrodes (24) on one of its faces, this plurality of electrodes constituting the fixing means, a layer of insulating material (23) being deposited on said face, the layer of insulating material (23) being hollowed out as far as the electrodes (24) to form the micro-cuvettes, multiplexing means being provided for electrically connecting the plurality of electrodes (24) to effect electropolymerization.

6. Method according to any one of claims 2 to 5, characterized in that the counter electrode (9b, 25) is an electrode integral with said structure.

7. Method according to any one of claims 2 to 5, characterized in that the counter electrode is an electrode (48) placed opposite the fixing means during the electropolymerization operation.

8. Method according to any one of claims 2 to 7, characterized in that the conductive monomer of the first organic compound (30) is pyrrole.

9. Method according to claim 1, characterized in that the step consisting in fixing the first organic compound (30) on the fixing means (24) of the micro-cuvettes (21) consists in implementing a covalent bond between the attachment function of the first organic compound with the fixing means and the fixing means.

10. Method according to claim 1, characterized in that the step consisting in fixing the first organic compound on the means for fixing the micro-cuvettes is carried out chemically, by addition of a reagent capable of causing polymerization on the means for fixing the first organic compound.

11. Method according to claim 10, characterized in that the first organic compound is pyrrole and in that the reagent capable of causing the polymerization is a ferric salt.

12. Method according to any one of claims 1 to 11, characterized in that the attachment function of the first organic compound (30) with the second organic compound (51) is a biotin function, the attachment function of the second organic compound (51) with the first organic compound (30) being an avidin or streptavidin function.

13. Method according to claim 12, characterized in that the first organic compound (30) is a biotinilated pyrrole.

14. Method according to one of claims 12 or 13, characterized in that the second organic compound (51) consists of said reagent directly attached to the avidin or streptavidin function.

15. The method of claim 14, characterized in that the step of placing, in each microcuvette (21), the second organic compound (51) comprises depositing a solution (50) containing the second organic compound (51) in each microcuvette (21) then the elimination of this solution to keep only the probes obtained.

16. Method according to one of claims

12 or 13, characterized in that the second organic compound (51) consists of said reagent attached to the avidin or streptavidin function via a biotin function.

17. The method of claim 16, characterized in that the step of placing, in each microcuvette (21), the second organic compound (51) comprises depositing a first solution of avidin or streptavidin in each micro-cuvette, then the elimination of this first solution to reveal the first organic compound (30) with the biotin function complexed by said avidin or said streptavidin, then the deposition of a second solution containing said reagent in biotinilated form, then the elimination of this second solution to keep only the probes obtained.

18. Micro-system with multiple chemical or biological analysis points constituted by a structure (20, 40) provided with micro-cuvettes (21, 44), each micro-cuvette being intended to receive a reagent and being provided with fixing means (24) enabling said reagent to be attached thereto via a first organic compound (30), the reagent being part of a second organic compound (51), the first organic compound (30) comprising an attachment function with the second organic compound (51) and an attachment function with the fixing means (24), these two attachment functions being separated by a spacer, the second organic compound (51 ) comprising an attachment function with the corresponding attachment function of the first organic compound (30).

19. Micro-system according to claim

18, characterized in that the fixing means are electrodes (9a, 24) and in that the attachment function with the fixing means of the first organic compound is a conductive polymer.

20. Microsystem according to claim

19, characterized in that the fixing means form a common electrode (42).

21. Micro-system according to one of claims 19 or 20, characterized in that the micro-cuvettes (21) are formed in an insulating layer (23) of said structure (20), the fixing means (24) forming the bottom of the micro-bowls.

22. Micro-system according to any one of claims 19 to 21, characterized in that said structure (20) comprises a counter-electrode (25) disposed in opposition relative to the bottom of the micro-cuvettes in order to be able to establish a field electric between the counter-electrode and the fixing means (24).

23. Micro-system according to any one of claims 19 to 21, characterized in that said conductive polymer is a polypyrrole.

24. Micro-system according to claim 18, characterized in that the fixing means and the attachment function of the first organic compound with the fixing means are such that they form a covalent bond.

25. Micro-system according to claim 18, characterized in that the attachment function of the first organic compound with the fixing means comprises a polymerization reagent, chemically, on the fixing means.

26. Micro-system according to claim 25, characterized in that said reagent is a ferric salt.

27. Micro-system according to any one of claims 18 to 26, characterized in that the first organic compound (30) comprises a biotin function for its attachment with an avidin or streptavidin function of the second organic compound (51).

28. Micro-system according to claim 27, characterized in that the first organic compound

(30) is a biotinilated polypyrrole.

29. Micro-system according to one of claims 27 or 28, characterized in that the second organic compound (51) consists of said reagent directly attached to the avidin or streptavidin function.

30. Micro-system according to one of claims 27 or 28, characterized in that the second organic compound (51) consists of said reagent attached to the avidin or streptavidin function via a biotin function.