WO2005052368A1

WO2005052368A1 - Microsystem for fluid displacement

Info

Publication number: WO2005052368A1
Application number: PCT/FR2004/050617
Authority: WO
Inventors: Alain Gliere; Dominique Masse; Jean-Luc Achard
Original assignee: Commissariat A L'energie Atomique; Centre National De La Recherche Scientifique
Priority date: 2003-11-28
Filing date: 2004-11-25
Publication date: 2005-06-09
Also published as: FR2863117A1; FR2863117B1

Abstract

The invention relates to a microsystem for the displacement of fluids, said microsystem comprising a microconduit (1) containing at least one fluid, and means for establishing a primary displacement of the fluid between an inlet (En) and an outlet (So) of the microconduit (1). The inventive microsystem is characterised in that it comprises magnetohydrodynamic means (5) for establishing at least one secondary displacement of the fluid. The invention can be applied to the field of microfluidics, inter alia, for mixing fluids and for scanning particles at the surface of reactors.

Description

MICROSYSTEM FOR MOVING FLUID

DESCRIPTION

TECHNICAL FIELD AND PRIOR ART The present invention relates to a microsystem for moving fluid. The invention applies to the field of microfluidics. The purpose of microfluidics is to ensure numerous functions in the management of small volumes of liquid: introduction and mixing of fluids in microsystems, displacement or immobilization of fluids in microreactors, mixing or segregation of several phases, scanning the surface of biochips by particles or molecules. The objectives of the various microsystems concerned (microreactors, biochips, biochips, etc.) differ depending on whether the applications relate to fine chemicals, health, diagnostics, etc. However, common concerns arise to varying degrees, such as, for example, miniaturization, maximization of the number of operations to be performed, portability, advanced automation to reduce human intervention, acceleration of processes. analysis to get quick answers, etc. Among the various functions provided by microfluidics, two appear to be essential: the mixing of fluids and the sweeping of active surfaces. The mixture of fluids and / or species molecules involved in chemical or biological reactions facilitate these reactions. Such a mixture proves necessary despite the very small size of the microsystems (typical length of 100 μm). There are at least two reasons for this: (i) Brownian diffusion alone does not allow sufficiently rapid mixing, in particular for large molecules, (ii) the flows which occur in microsystems are characterized by very Reynolds numbers low, preventing turbulence from appearing. The scanning of an active surface, for example the surface formed by the studs of a biochip, by particles or molecules is also an essential function. The biochips, whose objective is to detect different species of analytes (DNA strands, proteins, bacteria, enzymes) comprise a network of specific zones, commonly called studs, produced on a solid surface. A type of probe is grafted onto each of these areas. The surface is then called "active". These probes

“Interrogate”, by various methods, the target analytes contained in the fluid brought into contact with the surface. The fluid is generally pressed against the active surface by another solid surface which is parallel and very close (the order of magnitude varies between 10 μm and 1 mm), so that the geometry of the fluid can be considered as two-dimensional (fluid blade) with dimensions which may be large parallel to the walls (an order of magnitude is cm). In one given a given time interval, any active plot of a biochip can only capture, thanks to the Brownian movement, the specific analytes contained in a region surrounding the plot. The dimensions of this region are generally small (commensurable with the thickness of the fluid blade covering the biochip) with respect to the maximum dimensions of the biochip. In other words, many target analytes cannot be detected. So that the active plot can capture the maximum of analytes, it is desirable that each plot of fluid, of size, for example, comparable to the thickness, is brought to cover this plot for a predetermined time during an analysis. . The process by which a particle or molecule introduced into the system is made to pass close to a maximum number of pads is called "scanning". The devices for mixing fluids in a microsystem must meet the following two criteria: they must be easily miniaturizable and can be integrated into possibly composite structures (glass, silicon, plastic), and they must not include moving parts, in particular to avoid dead volumes which are sources of cross contamination (mechanical devices are therefore to be avoided). At least three techniques make it possible to design mixers meeting at least the second criterion. A first technique consists in using baffles or twisted channels to modify the geometry of the flow structures, which then leads to disturbing the flow of the fluid. However, it has been shown that this technique is only effective for Reynolds numbers of the order of 10. According to a second technique, it is different types of emitters of sound waves or ultrasound which are used to disturb flow. Again, however, the Reynolds numbers must be on the order of 10 for this second technique to be effective. Furthermore, parasitic vibrations may appear, which makes this second technique very difficult to implement. A third technique is Magneto-Hydro-Dynamics (MHD) which allows, thanks to the Lorentz force, to pump liquids into microconduits (cf. US Patent 6,146,103 Lee et al.). Magneto-Hydro-dynamics currently offers good prospects. The Lorentz force is a volume force which manifests itself at any point where an electric current and a magnetic field coexist. The Lorentz force is oriented perpendicular to the direction of each of these two quantities. In the case where the circulation of the fluid is ensured along the axis of the microconduit, the directions of the electric current and of the magnetic field must then be perpendicular to the walls of the microconduit. To allow the appearance of an electric current, the liquid must therefore be conductive, at least weakly, as are, for example, biological liquids. Figure 1 shows a diagram of principle of the MHD micropump according to the prior art as disclosed in US Patent No. 6,146,103. The micropump comprises a microconduit 1 and two permanent magnets 2 and 3. The microconduit 1, of width L, has a rectangular section. The magnets 2 and 3 are placed opposite one another, on either side of the microconduit, so as to produce a uniform magnetic field Ha in the microconduit. Electrodes Gl, G2 are placed on the side walls of the microconduit 1. A potential difference is applied between the electrodes Gl and G2 so that a current I flows from the electrode Gl towards the electrode G2 (l ' power supply to which the electrodes G1 and G2 are connected is not shown in the figure). The electric current I and - the magnetic field Ha are perpendicular to each other. A conductive fluid placed in the microconduit 1 undergoes a force F whose direction is perpendicular to the direction of the electric current I and to the direction of the magnetic field Ha. The force F, commonly called the Lorentz force, causes the movement of the fluid. The intensity of the force F is written: F = kx I x Ha x L, where k is a proportionality factor. In steady state, the force F is balanced by the viscosity forces of the fluid and this results in a flow rate Q. FIG. 2A represents a principle diagram of an MHD mixer according to the prior art as it appears in American patent N ° 6 146 103. The mixer ^• MHD includes all of the constituent elements of the micropump described above with reference to Figure 1. The mixer differs from the micropump by the only offset of the two electrodes G1 and G2 along the axis of the microconduit. FIG. 2B represents a top view of the velocity field of the particles of a fluid which moves in the MHD mixer described with reference to FIG. 2A. The density j of the current which is established between the electrode G1 and the electrode G2 undergoes two successive turns in opposite directions. The magnetic field Ha is uniform and directed in a direction perpendicular to the plane of the figure. The volume Lorentz force Fv (Fv being proportional to jxHa) consequently undergoes two successive and opposite rotations. These two rotations deform the current lines 4 and can, optionally, lead to two alternating vortices, 5a and 5b. Conductive fluids flowing in the microconduit 1 can thus be mixed and, therefore, a distribution of analytes can be homogenized in a conductive fluid. The MHD mixer according to the prior art has several drawbacks. First of all, the electrodes G1 and G2 which are used for the creation of the current are located near the zones where the mixing of the fluids takes place, that is to say near the reactive zones. However, an electrolysis phenomenon is triggered very early on the electrodes. Bubbles form, polluting the flow. The problem is all the more annoying as the temperature is high as has been observed by West and collaborators on a microsystem MHD dedicated to DNA chain duplication by PCR (cf. West et al., Lab Chip 2 (2002), p. 224-230). The phenomenon of electrolysis also has the drawback of damaging the electrodes, even in the absence of bubbles (cf. Zong JH et al., Sensors Actuators A 96 (2002), p.59-66), and of modifying the pH middle. Since pH is a parameter to which biological substances are very sensitive, this results in a deterioration in performance. The use of alternating current instead of direct current has been proposed as a remedy against electrolysis (cf. Lemoff and Lee, Sensors Actuators B 63 (2000), p. 178-185). The frequency of the alternating current is then of the order of kHz. A synchronous magnetic field, coming from an electromagnet must then be produced so that the Lorentz force points in the same direction during a whole cycle. It is clear that this remedy weighs down the implementation of the device. Furthermore, if such a system seems to give satisfactory results as regards the transport of liquids, no result is given as regards the mixing of liquids. United States patent application US 2003/0169637 A1 discloses another mixing system by the MHD technique. The system includes two channels in which drops to be mixed move and a mixing zone located at the intersection of the channels. The drops move along the axis of the channels due to the presence of MHD pumps regularly distributed along the channels. The mixing of the drops takes place in the mixing zone, by the simple fact that the mixture is found at the intersection of the two channels. Such a mixing system is bulky (perpendicular arms), or even complex (mixing zone in the form of a spiral) because of the need to carry it out according to a geometry which allows mixing at the intersection of the channels. Furthermore, in principle, MHD excludes dielectric liquids from its scope, which represents yet another drawback. The invention does not have the drawbacks mentioned above.

PRESENTATION OF THE INVENTION In fact, the invention relates to a microsystem for the displacement of fluid, the microsystem comprising a microconduit containing at least one fluid and means for establishing a primary displacement of the fluid between an inlet and an outlet of the microconduit, characterized in that it comprises magneto-hydro-dynamic means for establishing at least a secondary displacement of the fluid. According to a first variant of the invention, the means for establishing a primary displacement of the fluid establish a drop in driving pressure between the inlet and the outlet of the microconduit. According to a second variant of the invention, the means for establishing a primary displacement of the fluid comprise a supply for establishing a potential difference between the input and the output of the microconduit. According to an additional characteristic of the second variant, the fluid being dielectric, the means for establishing a primary displacement of the fluid further comprise means for injecting charges into the microconduit. According to another additional characteristic of the second variant, the fluid being conductive, the means for establishing a primary displacement of the fluid comprise: - at least one electrolyte contained in the microconduit, and a material which covers at least one wall of the microconduit or whose at less a wall of the microconduit is formed and which, in contact with the electrolyte, develops charges. According to an additional characteristic of the invention, the magneto-hydro-dynamic means for establishing at least one secondary movement of the fluid comprise at least one magnetic micro-element placed near a wall of the microconduit so that a magnetic field is created in the microconduit. According to another additional characteristic of the invention, the magneto-hydro-dynamic means for establishing at least one secondary movement of the fluid comprise a set of magnetic microelements placed one next to the other near a wall of the microconduit, each microelement magnetic creating a magnetic field in the microconduit, two magnetic fields created by two neighboring magnetic micro-elements being oriented in two opposite directions. According to another additional characteristic of the invention, a magnetic micro-element is a permanent micro-magnet. According to another additional characteristic of the invention, a magnetic microelement is a microbool. According to another additional characteristic of the invention, the magneto-hydro-dynamic means for establishing at least one secondary movement comprise a micro-magnet having a north pole and a south pole, the micro-magnet being placed near a wall of the microconduit and creating a magnetic field inside the microconduit, the axis defined by the north and south poles being substantially parallel to the axis of the microconduit. According to another additional characteristic of the invention, the magneto-hydro-dynamic means are placed outside the microconduit. According to another additional characteristic of the invention, the magneto-hydro-dynamic means are placed inside the microconduit. The invention also relates to a microsystem for mixing fluids, characterized in that it comprises a microsystem for moving fluid according to the invention, the microsystem for moving fluid comprising at least two inputs and one output, at least a first fluid entering the microsystem through a first inlet and at least one second fluid entering the microsystem through a second inlet. The invention also relates to a microsystem for scanning the surface fluid of a microreactor, characterized in that it comprises: a microconduit having a wall partially made up of the microreactor, the microconduit containing at least one fluid, means for establishing a primary displacement of the fluid along the axis of the microconduit between at least one inlet and one outlet of the microconduit, and magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid, the scanning of the fluid resulting from the combination of the primary displacements and secondary of the fluid. According to an additional characteristic of the scanning microsystem according to the invention, the magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid comprise at least one set of N aligned magnetic micro-elements placed next to each other in the vicinity of the microconduit, the N magnetic micro-elements creating, in the microconduit, N magnetic fields substantially perpendicular to the surface of the microreactor, the N magnetic fields being in successive directions opposite along the axis of the microconduit and creating N + l vortex cells distributed by on either side of the microreactor. According to another additional characteristic of the scanning microsystem according to the invention, the magneto-hydro-dynamic means for establish at least one secondary displacement of the fluid comprise at least one set of N aligned magnetic micro-elements placed one next to the other near the microconduit, the N magnetic micro-elements creating, in the microconduit, N magnetic fields substantially perpendicular to the surface of the microreactor, the N magnetic fields being in successive directions opposite along the axis of the microconduit, the walls of the microconduit situated on either side of the microreactor being covered with solid studs capable of suppressing recirculation of the fluid in the microconduit. According to yet another characteristic of the scanning microsystem according to the invention, the micro-elements are permanent micro-magnets. According to yet another characteristic of the scanning microsystem according to the invention, the micro-elements are microbrobes. According to yet another characteristic of the scanning microsystem according to the invention, the means for establishing a primary displacement of the fluid establish a drop in driving pressure between the inlet and the outlet of the microcontuit. According to yet another characteristic of the scanning microsystem according to the invention, the means for establishing a primary displacement of the fluid comprise a supply for establishing a potential difference between the input and the output of the microconduit. According to yet another characteristic of the scanning microsystem according to the invention, the fluid being dielectric, the means for establishing a primary displacement of the fluid further comprise means for injecting charges into the microconduit. According to yet another characteristic of the scanning microsystem according to the invention, the fluid being conductive, the means for establishing a primary movement of the fluid comprise: at least one electrolyte in the microconduit, and a material which covers at least one wall of the microconduit or of which at least one wall of the microconduit is made up and which, in contact with the electrolyte, develops charges. According to yet another characteristic of the scanning microsystem according to the invention, the microreactor is a biochip. According to yet another characteristic of the scanning microsystem according to the invention, the magneto-hydro-dynamic means for establishing at least a secondary displacement of the fluid are placed outside the microconduit. According to yet another characteristic of the scanning microsystem according to the invention, the magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid are placed inside the microconduit. According to a particular embodiment of the invention, the magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid comprises means for establishing a potential difference between the input and the output of a microconduit. These means for establishing a potential difference between the input and the output of a microconduit can then comprise at least a first electrode placed at the input of the microconduit and at least a second electrode placed at the output of the microconduit. In the case where the means for establishing a primary displacement of the fluid comprise at least a third electrode at the inlet of the microconduit and at least a fourth electrode at the outlet of the microconduit, the first electrode may then or may not be confused with the third electrode and the second electrode may or may not be confused with the fourth electrode. According to certain variants of the invention, the primary displacement of the fluid is carried out by electro-osmosis (case of conductive liquids) or by injection of ions (case of dielectric liquids). Electroosmosis and ion injection are electrokinetic and have in common the use of a permanent electric field imposed on the liquid, from the outside, between the entry and exit of the microsystem. They also have in common to generate a mass movement of the fluid from a displacement of excess ions under the effect of the Coulomb force. The origin of the excess ions is different in the two cases: in the case of conductive liquids, the ions are born in the double layer electric parietal of conductive liquids and in the case of dielectric liquids, the ions are injected by peak effect in the liquids. According to the invention, the electric field is parallel to the main axis of the primary flow. According to the invention, the secondary flows of the fluid are obtained by means of particular spatial implantations of magnetic micro-elements which create more or less complex figures of the magnetic field in an active area. The magnetic elements, for example permanent or non-permanent magnets, can either be integrated into the microsystem, or left outside of it. A microsystem for moving fluid according to the invention does not have any of the drawbacks mentioned above for exclusively MHD systems. The electrodes which create an electric field between the input and the output are placed outside the microsystem and, therefore, have no negative consequences on the reactive zone. They can be easily replaced and the bubbles which could be emitted in the case of a conductive fluid can be eliminated before entering the microconduit. It is therefore advantageously possible to use a continuous supply. In the case where the magnetic micro-elements are external, it is advantageously very easy to modify their number and / or their position. These modifications are reversible and strong magnets, even relatively large, can be used. Old microsystems can also be used by simply adding an external power-up and a set of micro-magnets adapted to the type of mixing that one wishes to carry out. Primary movement and secondary movement are in the invention partially or totally decoupled. Indeed, the magnetic field only plays on the secondary movement, while the electric field plays on both movements. It is thus possible to design systems where primary movement and secondary movement (s) are almost decoupled, in intensity and / or over time. Indeed, for a given magnetic field of sufficient intensity, the secondary movements start as soon as an electric field, even a weak one, is applied. The secondary movements can then be controlled by this electric field, over a range of intensities which induce only a negligible primary movement of the liquid. A mixture can then occur, at low value of the external electric field, without significant primary movement. If one limits oneself to the range of intensities of the electric field mentioned above (range proper to each microsystem), one can then choose to create the primary movement by another means than electric, such as a thermal means, a acoustic means, a micropipette, a magneto-hydro-dynamic means, etc. In these systems, the primary and secondary movements are then completely decoupled.

BRIEF DESCRIPTION OF THE FIGURES Other advantages and characteristics of the invention will appear on reading the description which follows, made with reference to the appended figures in which: FIG. 1, already described, represents a block diagram of an MHD micropump according to the prior art; FIG. 2A, already described, represents a block diagram of an MHD mixer according to the prior art; FIG. 2B, already described, represents a top view of the velocity field of the particles of a fluid which moves in the MHD mixer of FIG. 2A; FIG. 3A represents a block diagram of a mixer according to a first embodiment of the invention; - Figure 3B shows a top view of the velocity field of the particles of a fluid which moves, without primary flow, in the mixer of Figure 3A; FIG. 3C represents a top view of the velocity field of the particles of a fluid which moves, with primary flow, in the mixer of FIG. 3A; FIG. 4A represents a schematic diagram of a mixer according to a second embodiment of the invention; FIG. 4B represents a top view of the velocity field of the particles of a fluid which moves, without primary flow, in the mixer of FIG. 4A; FIG. 5A represents a schematic diagram of a mixer according to a third embodiment of the invention; FIG. 5B represents a top view of the velocity field of the particles of a fluid which moves, in the absence of primary flow, in the mixer of FIG. 5A. FIG. 6A represents a sectional view of a scanning device according to the invention; Figure 6B shows a top view of the scanning device of Figure 6A; - Figure 6C shows a top view of the velocity field of the particles of a fluid which moves in a scanning device according to Figure 6A; FIG. 7 represents an example of a fluid microsystem making it possible to mix two fluids according to the invention; 8 shows a variant of the scanning device shown in Figures 6A-6B. In all the figures, the same references designate the same elements.

DETAILED DESCRIPTION OF MODES FOR IMPLEMENTING THE INVENTION

FIG. 3A represents a schematic diagram of a mixer according to a first embodiment of the invention. The mixer comprises a microconductor 1 and a magnetic micro-element 5. The magnetic micro-element 5 is, for example, a permanent micro-magnet. It could also be, for example, a microbobin. The micro-magnet 5 is placed at proximity of the microconduit 1 so as to immerse the latter in a magnetic field Hb. The lines of the magnetic field Hb which come from the north pole N of the micro-magnet 5 then pass through the microconduit 1 while expanding to close on the south pole S of the micro-magnet. An electrical supply 6 is connected between an inlet tank En and an outlet tank So. FIG. 3B represents a top view of the velocity field of the particles of a fluid which moves, without primary flow (Q = 0), in the mixer of FIG. 3A. Two vortex cells 7a and 7b, symmetrical with respect to the axis of the magnetic field Hb, are established in the microchannel 1. FIG. 3C represents a top view of the speed field obtained by the previous mixer with primary flow (Q ≠ 0). Two vortices 8a and 8b, rotating in opposite directions, are established, between which the fluid flows along current lines 9a and 9b. The vortices 8a and 8b are zones in which the lines of current of the fluid loop on themselves. For reasons of convenience, in the following description, a fluid zone in which the current lines of the fluid loop on themselves will be called “recirculation zone” as opposed to a circulation zone in which the fluid moves (ie flows) from a first point to a second point different from the first. Each of the recirculation 8a, 8b is located near a different side wall of the microconduit. The primary flow flows between these zones. The larger the primary flow, the smaller the recirculation zones. FIG. 4A represents a block diagram of a mixer according to a second embodiment of the invention. The mixer comprises a microconduit 1, a power supply 6 and three micro-magnets 10, 11, 12 which have an alternating orientation, two micro-magnets 10, 12 of the same orientation surrounding the micro-magnet 11 of opposite orientation. The three micro-magnets 10, 11, 12 are placed near the microconduit 1 so that the respective magnetic fields Hc, Hd, He which they create penetrate the microconduit 1. The primary displacement is here carried out by electro-osmosis. A potential difference is then applied to at least one electrolyte contained in the microconduit 1. At least one internal wall of the microconduit 1 is covered with a material or made of a material which, brought into contact with the electrolyte, develops charges , for example negative charges. The electro-osmosis phenomenon is then triggered. FIG. 4B represents a top view of the velocity field of the particles of a fluid which moves, without primary flow (Q = 0), in a mixer according to FIG. 4A. Four vortex cells with alternating orientations 13b, 13bc, 13cd and 13c are present in the microconductor 1. In FIG. 4B, the projections of the micro-magnets 10, 11, 12 on the microconduit 1 are respectively represented by the neighboring zones 10p, llp, and 12p. FIG. 5A represents a schematic diagram of a mixer according to a third embodiment of the invention. The mixer comprises a microconduit 1, a micro-magnet 14 and a power supply 6. The North-South axis of the micro-magnet 14 is here parallel to the axis of the microconduit 1. The lines of the magnetic field created by the micro-magnet 14 close between the North and South poles of the micro-magnet. The micro-magnet 14 is placed near the microconduit 1 so that the magnetic field Hf that it creates penetrates the microconduit 1. An electrical supply 6 connected between an inlet reservoir En and an outlet reservoir So applies a potential difference to the minus one electrolyte contained in the microconduit 1. A primary flow is then produced by electroosmosis. FIG. 5B represents a top view of the velocity field of the particles of a fluid which moves, in the absence of primary flow (Q = 0), in the mixer of FIG. 5A. A single vortex cell 15, elongated along the axis of the microconduit 1, extends between the two zones which adjoin the North N and South S poles of the micro-magnet, these two zones then constituting the only motor zones of the mixer since the force de Lorentz sucks everywhere else. FIGS. 6A and 6B represent, respectively, a sectional view and a top view of a scanning device according to the invention and the FIG. 6C represents a top view of the velocity field of the particles of a fluid which moves in a scanning device as shown in FIGS. 6A and 6B. The scanning device is, for example, a scanning device for a biochip. The scanning device comprises a microcontuit 1 equipped with a heterogeneous phase microreactor R such as, for example, a biochip and a set 16 of N aligned magnetic microelements. The microcontuit 1 is provided with an input En and an output So. The fluid is put into primary movement between the input En and the output So using, for example, a micropump or a micropipette placed on the input En. The microreactor R is integrated into a wall of the microconduit 1. The microreactor R occupies only part of the total surface of the wall in which it is integrated. The wall in which the microreactor is integrated then comprises two lateral zones Z1, Z2, located on either side of the microreactor R, in which no reaction can take place. The N magnetic elements, for example N permanent magnets placed side by side and with alternating orientations, create N magnetic fields in the microconduit 1 and, consequently, at the level of the microreactor R. The N magnetic elements can be placed under the microconduit, as shown in FIG. 6A, or above the microconduit, or even inside the microconduit. The N magnetic fields are such that the induction lines cross the microconductor 1 only once, in a first direction then in another opposite to the first, when one progresses along the axis of the microconduit. The looping of the field lines towards the opposite poles is rejected relatively far outside of the microconduit 1 due to the use of magnets whose distance between the North and South poles is relatively large. The thickness of the magnets is on the other hand relatively small in order to favor the fineness of the scanning. In the absence of a drop in driving pressure (Q = 0), N + l vortex cells CT having alternating directions of circulation appear between En and So. The N + 1 vortex cells then occupy the entire width of the microcontuit 1. If a driving pressure is applied between the input En and the output So, a primary flow makes its way between the cells, as described above with reference to the Figures 3A-3C. The more the flow Q increases, the more the width of the vortex cells in the microconduit 1 is reduced, leaving the microreactor R free from any recirculation zone. The N + 1 CT vortex cells are then distributed in m cells in the zone Z1 and m + 1 cells in the zone Z2 located opposite Zl (with 2m + l = N + l). This results in a zigzag flow of the fluid, as illustrated in FIG. 6C. The fluid then performs a sweep of the surface of the microreactor R. This sweep promotes heterogeneous chemical or biological reactions. In particular, such a scanning makes it possible to expose, for an optimal duration, all of the studs of a biochip to a target analyte injected at the input En. Recirculation zones, even rejected at the outside of the surface of the microreactor R, can nevertheless be troublesome, because they are capable of trapping part of the analytes. Two remedies are possible depending on whether the circuit is closed or open. In a closed circuit, a back and forth movement is applied to the primary flow. The recirculation zones which are created in a first direction of circulation are destroyed and then reappear together in the opposite direction, offset by a thickness of magnet. In the open circuit, the lateral walls of the microconduit are equipped, at the location where the vortex cells CT must appear, with solid studs PT similar in shape to the shape of the vortex cells, as shown in FIG. 8. The primary flow , by winding in the microconduit 1, then no longer creates any recirculation zone. FIG. 7 represents a fluid microsystem according to the invention making it possible to mix two fluids. The device comprises a microconduit 1 and a set 17 of magnetic microelements. The input of the microconduit 1 is connected to two input microcircuits C1, C2 connected to the respective input reservoirs Enl, En2. The outlet of the microconduit 1 is connected to the outlet tank So. According to the embodiment of FIG. 7, the set 17 of micro-elements consists of a linear structure of N (N = 12) permanent micro-magnets of alternating orientation creating successive magnetic fields of opposite directions. More complex structures of micro-magnets or microbobins can also be envisaged such as, for example, matrix structures. A first fluid is introduced into the microcircuit 1 through the input microcircuit C1 and a second fluid through the input microcircuit C2. An electrical circuit (not shown in the figure) applies a voltage VI to the input Enl and a voltage V2 to the input En2, the output So being grounded. The fluids then flow from Enl to So and from En2 to So. The fluids are mixed in the microconduit 1.

Claims

1. Microsystem for the displacement of fluid, the microsystem comprising a microconduit (1) containing at least one fluid and means for establishing a primary displacement of the fluid between an inlet (En) and an outlet (So) of the microconduit (1), characterized in that it comprises magneto-hydro-dynamic means (5, 10, 11, 12, 14) for establishing at least one secondary displacement of the fluid.

2. Microsystem according to claim 1, characterized in that the magneto-hydro-dynamic means (5, 10, 11, 12, 14) comprise means for establishing a potential difference between the input (En) and the output ( So).

3. Microsystem according to claim 2, characterized in that the means for establishing a potential difference between the input (En) and the output (So) comprise at least a first electrode placed at the input (En) and at least a second electrode placed at output (So).

4. Microsystem according to one of claims 1 to 3, characterized in that the means for establishing a primary displacement of the fluid establish a drop in driving pressure between the inlet (En) and the outlet (So) of the microconduit (1) .

5. Microsystem according to one of claims 1 to 3, characterized in that the means for establishing a primary displacement of the fluid comprise a supply (6) for establishing a potential difference between the input (En) and the output (So ) of the microconduit (1).

6. Microsystem according to claim 5, characterized in that the means for establishing a primary displacement of the fluid comprise at least a third electrode at the input (En) and at least a fourth electrode at the output (So).

7. Microsystem according to claims 3 and 6, characterized in that the first electrode is merged with the third electrode and in that the second electrode is merged with the fourth electrode.

8. Microsystem according to one of claims 5, 6 or 7, characterized in that, the fluid being dielectric, the means for establishing a primary displacement of the fluid further comprise means for injecting charges into the microconduit.

9. Microsystem according to one of claims 5, 6 or 7, characterized in that, the fluid being conductive, the means for establishing a primary displacement of the fluid comprise: - at least one electrolyte in the microconduit (1), a material which covers at least one wall of the microconduit or of which at least one wall of the microconduit is made up and which, in contact with the electrolyte, develops charges.

10. Microsystem according to any one of the preceding claims, characterized in that the magneto-hydro-dynamic means for establishing at least one secondary movement of the fluid comprise at least one magnetic micro-element (5) placed near a wall of the microconduit so that a magnetic field (Hb) is created in the microconduit (1).

11. Microsystem according to any one of claims 1 to 9, characterized in that the magneto-hydro-dynamic means for establishing at least one secondary movement of the fluid comprise a set of magnetic micro-elements (10, 11, 12) placed one next to the other near a wall of the microconduit, each magnetic micro-element creating a magnetic field in the microconduit, two magnetic fields created by two neighboring magnetic micro-elements being oriented in two opposite directions.

12. Microsystem according to any one of claims 10 or 11, characterized in that the magnetic micro-element is a permanent micro-magnet.

13. Microsystem according to any one of claims 10 or 11, characterized in that the magnetic micro-element is a microbool.

14. Microsystem according to any one of claims 1 to 9, characterized in that the magneto-hydro-dynamic means for establishing at least one secondary movement comprise a micro-magnet (14) having a north pole (N) and a pole south (S), the micro magnet being placed near a wall of the microconduit and creating a magnetic field (Hf) inside the microconduit, the axis defined by the north and south poles being substantially parallel to the axis of the microconduit.

15. Microsystem according to any one of the preceding claims, characterized in that the magneto-hydro-dynamic means are placed outside the microconduit (1).

16. Microsystem according to any one of claims 1 to 14, characterized in that the magneto-hydro-dynamic means are placed inside the microconduit (1).

17. Microsystem for mixing fluids, characterized in that it comprises a microsystem for moving fluid according to any one of claims 1 to 16, the microsystem for moving fluid comprising at least two inlets (Enl, En2 ) and an outlet (So), at least a first fluid entering the microsystem through a first inlet (Enl) and at least a second fluid entering the microsystem through a second entry (En2).

18. Microsystem for sweeping the surface fluid of a microreactor (R), characterized in that it comprises: a microconduit (1) having a wall partially made up of the microreactor (R), the microconduit (1) containing at least a fluid, - means for establishing a primary displacement of the fluid along the axis of the microconduit (1) between at least one inlet (En) and an outlet (So) of the microconduit (1), and magneto-hydro-dynamic means to establish at least one secondary displacement of the fluid, the scanning of the fluid resulting from the combination of the primary and secondary displacements of the fluid.

19. Microsystem according to claim 18, characterized in that the magneto-hydro-dynamic means for establishing at least a secondary displacement of the fluid comprise at least one set of N aligned magnetic micro-elements placed one next to the other near the microconduit (1), the N magnetic micro-elements creating, in the microconduit, N magnetic fields substantially perpendicular to the surface of the microreactor (R), the N magnetic fields being of successive opposite directions along the axis of the microconduit (1) and creating N + 1 vortex cells distributed on either side of the microreactor (R).

20. Microsystem according to claim 18, characterized in that the magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid comprise at least one set of N aligned magnetic micro-elements placed one beside the other near the microconduit (1), the N magnetic micro-elements creating, in the microconduit, N magnetic fields substantially perpendicular to the surface of the microreactor (R), the N magnetic fields being of successive directions opposite along the axis of the microconduit (1), the walls of the microconduit located on either side of the microreactor (R) being covered with solid studs capable of suppressing recirculation of the fluid in the microconduit.

21. Microsystem according to any one of claims 19 or 20, characterized in that the micro-elements are permanent micro-magnets.

22. Microsystem according to any one of claims 19 or 20, characterized in that the micro-elements are microbrobes.

23. Microsystem according to any one of claims 18 to 22, characterized in that the magneto-hydro-dynamic means comprise means for establishing a potential difference between the input and the output.

24. Microsystem according to claim 23, characterized in that the means for establishing a potential difference between the input and the output comprise at least a first electrode placed at the input and at least a second electrode placed at the output.

25. Microsystem according to any one of claims 18 to 24, characterized in that the means for establishing a primary displacement of the fluid establish a drop in driving pressure between the inlet (En) and the outlet (So) of the microconduit (1 ).

26. Microsystem according to any one of claims 18 to 24, characterized in that the means for establishing a primary displacement of the fluid comprise a supply for establishing a potential difference between the input (En) and the output (Sn) of the microconduit (1).

27. Microsystem according to claim 26, characterized in that the means for establishing a primary displacement of the fluid comprise at least a third electrode at the input and at least a fourth electrode at the output.

28. Microsystem according to claims 24 and 27, characterized in that the first electrode is merged with the third electrode and in that the second electrode is merged with the fourth electrode.

29. Microsystem according to one of claims 26, 27 or 28, characterized in that, the fluid being dielectric, the means for establishing a primary displacement of the fluid further comprise means for injecting charges into the microconduit.

30. Microsystem according to one of claims 26, 27 or 28, characterized in that, the fluid being conductive, the means for establishing a primary displacement of the fluid comprise: at least one electrolyte in the microconduit (1), a material which covers at least one wall of the microconduit or of which at least one wall of the microconduit is made up and which, in contact with the electrolyte, develops charges.

31. Microsystem according to any one of claims 18 to 30, characterized in that the microreactor (R) is a biochip.

32. Microsystem according to any one of claims 18 to 31, characterized in that the magneto-hydro-dynamic means for establishing at least one secondary displacement of the fluid are placed outside the microconduit.

33. Microsystem for sweeping fluid according to any one of claims 18 to 31, characterized in that the magneto-hydro-dynamic means for establishing at least one displacement secondary of the fluid are placed inside the microconduit.