EP3162441A1 - Microfluidic device coupling two flow zones - Google Patents

Abstract

The invention relates to a microfluidic device comprising a first upstream microfluidic circuit (11) and a second downstream microfluidic circuit (13), the upstream and downstream microfluidic circuits (11, 13) being connected to a microfluidic chamber (3). extending between an inlet channel (51), forming an end of the upstream microfluidic circuit (11) and an evacuation channel (71), forming an end of the downstream microfluidic circuit (13), and in that: the microfluidic chamber (3) has a volume adapted to form a retention of a liquid flowing between the upstream microfluidic circuit (11) and the downstream microfluidic circuit (13), the evacuation channel has a section, in a plane perpendicular to the direction of flow of the liquid, sized to allow evacuation of the liquid from the microfluidic chamber (3) through said spontaneous capillary flow evacuation channel, and - The microfluidic chamber (3) comprises a vent (9) configured to evacuate the air contained in the liquid flowing in said microfluidic chamber (3) from the upstream microfluidic circuit (11).

Description

TECHNICAL AREA

The present invention relates to microfluidic devices and, more particularly, to a microfluidic device for coupling a first flow zone to a second flow zone.

The invention has applications in many fields, such as among others the fields of medical research, chemistry, biology and pharmaceuticals.

STATE OF THE PRIOR ART

In many fields, one seeks to manipulate and control the flow of a liquid to analyze small volume samples in a microfluidic device. This may be the case, for example, for establishing biological and / or chemical interactions between two solutions for a chemical analysis, a biological or medical diagnosis, or in the field of genetic engineering or agro-food.

However, handling a liquid, for example, when filling a microfluidic chamber to perform chemical or biological analyzes may inadvertently or uncontrollably introduce air bubbles into the chamber that can affect performance and the results of the analysis. It is therefore important to eliminate or prevent the formation of unwanted bubbles.

There are several works mentioning techniques of elimination of air bubbles. For example, the article of Chang and Jiang titled "A debubbler for microfluidics utilizing air-liquid interfaces," Applied Physics Letters, (Vol 95, No. 21, p.214103, Nov 2009 ) describes a device forming air pillars between a support and a cover comprising holes. The air pillars allow the bursting of the bubbles and the escape of the air through the holes on the hood. Another technique is to remove the bubbles a posteriori using a porous material. However, these two techniques are conducive to the evaporation of the liquid.

Another technique consists in controlling the filling front of a chamber by a rather complex modification of the structure of the chamber accommodating the liquid.

The documents FR2978437 and US2015 / 251181 describe techniques for removing air bubbles in a microfluidic device. However, the microfluidic device connects two flow zones under pressure and is not adapted to transfer a liquid from a first microfluidic circuit having a first mode of displacement to a second microfluidic circuit having a second mode of displacement. This type of device is not suitable for certain microfluidic applications that require linking two microfluidic flow zones of different natures.

The object of the present invention is therefore to overcome the aforementioned drawbacks by providing a microfluidic device for making an effective link between two microfluidic flow zones that can be of different natures while eliminating air bubbles.

STATEMENT OF THE INVENTION

• la chambre microfluidique présente un volume adapté à former une rétention d'un liquide s'écoulant entre le circuit microfluidique amont et le circuit microfluidique aval,
• le canal d'évacuation présente une section, dans un plan perpendiculaire à la direction d'écoulement du liquide, dimensionnée pour permettre une évacuation du liquide de la chambre microfluidique à travers ledit canal d'évacuation par écoulement capillaire spontané, et
• la chambre microfluidique comporte un évent configuré pour évacuer l'air contenu dans le liquide s'écoulant dans ladite chambre microfluidique depuis le circuit microfluidique amont.

The subject of the invention is a microfluidic device comprising a first microfluidic circuit called said upstream and a second downstream microfluidic circuit, the upstream and downstream microfluidic circuits being connected to a microfluidic chamber extending between an inlet channel, forming an end of the an upstream microfluidic circuit and an evacuation channel, forming an end of the downstream microfluidic circuit, and in that:

• the microfluidic chamber has a volume adapted to form a retention of a liquid flowing between the upstream microfluidic circuit and the downstream microfluidic circuit,
• the evacuation channel has a section, in a plane perpendicular to the direction of flow of the liquid, dimensioned to allow evacuation of the liquid from the microfluidic chamber through said spontaneous capillary flow evacuation channel, and
• the microfluidic chamber comprises a vent configured to evacuate the air contained in the liquid flowing in said microfluidic chamber from the upstream microfluidic circuit.

Thus, the microfluidic device makes it easy and effective to transfer a liquid from a first flow zone to a second spontaneous capillary flow zone of different nature than that of the first flow zone while preventing the injection of air bubbles into the second zone. The device then makes it possible to couple two microfluidic circuits having two different functions and having flow modes that are a priori incompatible. In addition, the microfluidic adapter makes it possible to fill the capillary circuit with the total volume of the injected liquid while minimizing waste (ie, without the need to prepare a surplus of a liquid that will not be used in the capillary circuit).

According to one embodiment of the invention, the upstream microfluidic circuit is a pressurized flow circuit.

Thus, by eliminating air bubbles, the microfluidic device allows the transfer of the liquid from an area in which the liquid moves under pressure to another area in which the liquid moves by capillary action avoiding the blockage of the capillary flow. to the second zone while filtering or eliminating air bubbles.

Advantageously, said microfluidic chamber is configured to be connected to the upstream and downstream microfluidic circuits in a predetermined orientation with the ends of the upstream and downstream microfluidic circuits at a level lower than that of the vent, the notions of lower and upper being related. in the field of gravity.

Thus, the gravitational field facilitates the drainage of the liquid by the exit of the microfluidic chamber while the buoyancy impeded the bubbles to approach this exit by raising them to the surface of the liquid where they burst, giving off air escaping through the vent.

Advantageously, the admission channel opens into the microfluidic chamber at a level greater than or equal to that of the evacuation channel.

This makes it possible to create a step tending to drain the liquid towards the upstream circuit while the air bubbles rise to the surface.

Advantageously, the evacuation channel comprises hydrophilic walls. The hydrophilic wall (s) of the evacuation channel efficiently (e) produce a spontaneous capillary action which facilitates the flow of the liquid to the downstream circuit.

Advantageously, the liquid is selected from the following liquids: water, aqueous buffers, body fluids (blood, plasma, serum, urine) and ethanol liquids. In addition, the contact angle of said liquid on at least one wall of the discharge channel is less than 60 ° and preferably less than 30 °.

Advantageously, the vent comprises an exhaust channel adapted to evacuate the air.

Advantageously, the device comprises at least one valve installed in at least one of the intake, exhaust, and exhaust channels.

This makes it possible to stop or modify the flow rate of the liquid admitted into the microfluidic chamber from the upstream microfluidic circuit, and / or to stop or modify the flow rate of the liquid transported from the microfluidic chamber to the downstream microfluidic circuit, and / or to stop or control the evacuation of air to the atmosphere.

Advantageously, the volume of the microfluidic chamber is greater than the total volume of liquid admitted into said microfluidic chamber.

Advantageously, the vent has a diameter of about 300 .mu.m to 1 mm; the exhaust channel has a section of about 300μm x 300μm to 1mm x 1mm; the microfluidic intake channel has a section of approximately 500 μm × 300 μm; the microfluidic evacuation channel has a section of approximately 300 .mu.m and 300 .mu.m and the volume of the microfluidic chamber is approximately 20 .mu.l to 30 .mu.l.

Advantageously, the predetermined volume of the microfluidic chamber is greater than a critical volume defined as a function of a total volume of the liquid injected into the microfluidic chamber and / or flow rates of entry and exit of the liquid.

This ensures that the filling of the microfluidic chamber is not faster than the emptying.

Advantageously, the microfluidic chamber has an internal volume having a concave configuration.

Advantageously, the microfluidic adapter comprises a plurality of vents, and / or a plurality of microfluidic outputs, and / or a plurality of microfluidic inputs.

Advantageously, the microfluidic chamber has hydrophilic inner walls with a divergent section on the microfluidic admission side and a convergent section on the microfluidic evacuation side.

Thus, the diverging section increases the volume of the microfluidic chamber while the converging section reduces the section to better drain the liquid to the outlet. It should be noted that the realization of the hydrophilic inner walls on all the internal surfaces of the chamber is simpler in practice than an embodiment on only a part of the internal surfaces.

Advantageously, the upstream and downstream microfluidic circuits, the microfluidic chamber, and the inlet and outlet channels are formed in one piece.

Advantageously, the downstream microfluidic circuit comprises channels supplying a network of reaction cells.

• configurer la chambre microfluidique de manière en ce que son volume soit adapté à former une rétention d'un liquide s'écoulant entre le circuit microfluidique amont et le circuit microfluidique aval,
• dimensionner le canal d'évacuation selon une section, dans un plan perpendiculaire à la direction d'écoulement du liquide, pour permettre une évacuation du liquide de la chambre microfluidique à travers ledit canal d'évacuation par écoulement capillaire spontané, et
• aménager un évent dans la chambre microfluidique pour évacuer l'air s'échappant de bulles d'air contenues dans le liquide s'écoulant dans ladite chambre microfluidique depuis le circuit microfluidique amont.

The invention also relates to a microfluidic flow process between a first microfluidic circuit said upstream and a second downstream microfluidic circuit, the upstream and downstream microfluidic circuits being connected to a microfluidic chamber extending between an inlet channel, forming a end of the upstream microfluidic circuit and an evacuation channel, forming an end of the downstream microfluidic circuit, the method comprising the following steps:

• configuring the microfluidic chamber so that its volume is adapted to form a retention of a liquid flowing between the upstream microfluidic circuit and the downstream microfluidic circuit,
• dimensioning the discharge channel in a section, in a plane perpendicular to the flow direction of the liquid, to allow evacuation of the liquid from the microfluidic chamber through said spontaneous capillary flow evacuation channel, and
• providing a vent in the microfluidic chamber to evacuate air escaping from air bubbles contained in the liquid flowing into said microfluidic chamber from the upstream microfluidic circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

• La Fig. 1 illustre de manière très schématique un dispositif microfluidique entre deux zones d'écoulement, selon un mode de réalisation de l'invention ;
• La Fig. 2 illustre de manière schématique un dispositif microfluidique reliant deux circuits d'écoulement, selon un autre mode de réalisation de l'invention ;
• La Fig. 3 illustre de manière schématique, différentes formes de chambres microfluidiques, selon différents modes de réalisation de l'invention ;
• Les Figs. 4A et 4B illustrent de manière schématique un dispositif microfluidique comportant un circuit amont adapté pour un écoulement par pression à un circuit aval adapté pour un écoulement capillaire, selon un mode préféré de réalisation de l'invention ; et
• La Fig. 5 illustre de manière schématique un dispositif microfluidique, selon un autre mode de réalisation préféré de l'invention.

Embodiments of the invention will now be described, by way of nonlimiting examples, with reference to the accompanying drawings, in which:

• The Fig. 1 very schematically illustrates a microfluidic device between two flow zones, according to one embodiment of the invention;
• The Fig. 2 schematically illustrates a microfluidic device connecting two flow circuits, according to another embodiment of the invention;
• The Fig. 3 schematically illustrates different forms of microfluidic chambers, according to different embodiments of the invention;
• The Figs. 4A and 4B schematically illustrate a microfluidic device comprising an upstream circuit adapted for a pressure flow to a downstream circuit adapted for a capillary flow, according to a preferred embodiment of the invention; and
• The Fig. 5 schematically illustrates a microfluidic device, according to another preferred embodiment of the invention.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

The concept underlying the invention consists in adapting the flow of a liquid between two upstream and downstream zones having different flow modes while preventing air bubbles from entering the downstream zone.

The Fig. 1 illustrates very schematically a microfluidic device between two flow zones, according to one embodiment of the invention.

According to the invention, the microfluidic device 1 comprises a microfluidic chamber 3, a first upstream microfluidic circuit 11 and a second downstream microfluidic circuit 13.

The microfluidic chamber 3 includes a microfluidic inlet 5 and a microfluidic outlet 7. The microfluidic inlet 5 is configured to be connected to the upstream microfluidic circuit 11 via an inlet channel 51 (or microfluidic inlet channel). The microfluidic output 7 is configured to be connected to the downstream microfluidic circuit 11 via an evacuation channel 71 (or microfluidic output channel). By way of example, the sections of the microfluidic inlet 51 and evacuation channels 71 are rectangular.

The microfluidic chamber 3 thus extends between the inlet channel 51, forming an end of the upstream microfluidic circuit 11 and the evacuation channel 71, forming an end of the downstream microfluidic circuit 13. The microfluidic chamber 3 has a volume adapted to forming a retention of a liquid flowing between the upstream microfluidic circuit 11 and the downstream microfluidic circuit 13.

More particularly, the microfluidic chamber 3 has a predetermined volume and is delimited by a side wall 31 and by first and second walls 33, 35 at two ends of the chamber 3. The first wall 33 with a connected portion of the side wall 31 form a first portion 37 of the microfluidic chamber 3 defining a reserve portion for containing the liquid. In contrast, the second wall 35 with the other portion of the side wall 31 form a second portion 39 of the microfluidic chamber 3 defining an air exhaust portion.

It will be noted that throughout the following description, by convention, a direct orthonormal coordinate system is used in Cartesian coordinates (X, Y, Z). The plane (X, Y) is parallel to the first and second walls 33, 35 and the direction Z is oriented from the first wall 33 to the second wall 35.

The microfluidic chamber 3 comprises a vent 9 disposed in the second portion 39 of the microfluidic chamber 3. The vent 9 is configured to evacuate the air that is in the microfluidic chamber 3 before filling or the air escaping from the air bubbles contained in the liquid flowing in the microfluidic chamber 3 from the upstream microfluidic circuit 11.

The excess air escaping from the vent 9 makes it possible to avoid the rise of an overpressure in the microfluidic chamber 3, which can possibly push air bubbles into the evacuation channel 71. air is also meant the case where the liquid intermittently arrives intermittently possibly intersected by air inlets. For example, a first volume of 5μL of liquid is admitted into the microfluidic chamber 3 followed by the arrival of 10μL of air and then followed by the admission of a second volume of 8μL of liquid, etc.

Advantageously, the vent 9 is disposed at the top of the microfluidic chamber 3 (ie at the level of the second wall 35) and comprises an exhaust channel 91 adapted to evacuate the air. In this case, the first portion 37 of the microfluidic chamber 3 occupies almost the entire predetermined volume of the chamber 3 and the second portion 39 of the chamber 3 is substantially limited to the second wall 35 of this chamber 3.

Thus, the microfluidic chamber is connected to the upstream microfluidic circuits 11 and downstream 13 in a predetermined orientation with the ends of the microfluidic circuits upstream 11 and downstream 13 to a level lower than that of the vent 9. The notions of lower (or lower) ) and higher (or high) are related to the field of gravity. In other words, and as represented on the Fig. 1 the first wall 33 and lower than the second wall 35 and the direction of the Z axis is oriented in the opposite direction of gravity.

In addition, the discharge channel 71 has a section, in a plane perpendicular to the direction of flow of the liquid, sized to allow evacuation of the liquid from the microfluidic chamber 3 through the evacuation channel 71 by spontaneous capillary flow. .

où γ est la tension de surface du liquide, θ est l'angle de contact entre le liquide et la surface du canal d'évacuation et α est une dimension caractéristique du canal d'évacuation 71 qui correspond à la plus petite dimension pour un canal à section rectangulaire et au rayon pour un canal à section circulaire.It should be noted that for a given liquid and for a given surface material of the discharge channel, the distinctive parameter for a spontaneous capillary flow is the dimensioning of the section of the evacuation channel. Indeed, capillary flow generated by a spontaneous Δ P pressure difference can be expressed by the equation of Young-Laplace $$\mathrm{\Delta }\mathit{P}=\frac{2\gamma \cos \theta }{\mathrm{at}}$$

where γ is the surface tension of the liquid, θ is the contact angle between the liquid and the surface of the discharge channel and α is a characteristic dimension of the exhaust channel 71 which corresponds to the smallest dimension for a channel rectangular section and radius for a circular section channel.

Advantageously, in order to further increase the capillary flow, the evacuation channel 71 comprises one or more hydrophilic walls.

More particularly, for a liquid selected from the following liquids: water, aqueous buffers (water + salt or water + surfactant), body fluids (blood, plasma, serum, urine, etc.), liquids ethanol type, and mixtures of two or more of said liquids, the hydrophilic wall (s) of the exhaust channel 71 is (are) configured so that the contact angle of the liquid on at least one wall of the exhaust channel 71 is less than 60 ° and preferably less than 30 °. Thus, the spontaneous capillary flow in the downstream microfluidic circuit 13 is advantageously enhanced.

It will be noted that the upstream microfluidic circuit 11 may be a pressurized flow circuit. Thus, the microfluidic device 3 adapts the flow of a liquid from an upstream microfluidic circuit 11 under pressure to a downstream microfluidic circuit 13 with spontaneous capillary flow while preventing air bubbles from entering this downstream circuit 13.

More particularly, the displacement of the liquid can be done in three modes operated by three different forces. The forces can be applied independently or in combination. A first force is a pressure force exerted for example via a pump which pushes the liquid coming from the first circuit 11 into the microfluidic chamber 3. A second force is a so-called capillarity force which depends inter alia on the dimensioning of the section of the channel This second force makes it possible to move the liquid by capillary drainage from the microfluidic chamber 3 to the downstream circuit 13. A third force is the force of gravity. The latter can act in combination with the capillary force to move the liquid to the downstream circuit 13. Note that according to the embodiments of the present invention, the capillary force is much greater than the force of gravity.

Thus, the liquid coming from the upstream microfluidic circuit 11 is admitted via the admission channel 51 into the first part 37 of the microfluidic chamber 3 by the action of the pressure. In addition, the capillary force and / or the gravitational force allows the liquid to be drained through the evacuation channel 71 to the downstream microfluidic circuit 13.

In addition, the action of buoyancy prevents the bubbles from approaching the outlet 7 by causing them to rise to the surface of the liquid where they burst, giving off air which then escapes through the vent 9. In addition, the separation of the bubbles is done in addition to the Archimedes thrust by the action of the capillary force because the latter acts exclusively on the liquid and has no action on the air bubbles.

Thus, the filling of the chamber 3 is done by pressure, the separation of the air bubbles is done by the combination of the action of an Archimedes surge on the bubbles and of the capillary action on the liquid, and the drainage of the liquid to the downstream microfluidic circuit 13 is done by the combination of capillary force and gravity. The weight of each of the forces may depend on the volume of the liquid (ie its mass), the geometry of the microfluidic chamber 3, the section of the microfluidic channels and the materials of the device.

In particular, according to the example of Fig. 1 , the microfluidic chamber 3 is represented in a cylindrical shape but may have any other shape (see the examples of FIG. Fig. 3 ).

Furthermore, it will be noted that the microfluidic chamber 3 may comprise a plurality of vents 9, and / or a plurality of microfluidic outputs 7, and / or a plurality of microfluidic inputs 5.

For example, the microfluidic output 7 is disposed at the bottom of the microfluidic chamber 3 (i.e. at the first wall 33). Advantageously, the microfluidic inlet 5 opens into the microfluidic chamber 3 at a level greater than or equal to that of the microfluidic outlet 7. In other words, the admission channel 51 opens into the microfluidic chamber 3 at a level greater than or equal to that of the evacuation channel 71 thus creating a step promoting the movement of the liquid by gravity towards the evacuation channel 71.

The Fig. 2 schematically illustrates a microfluidic device connecting two flow circuits, according to another embodiment of the invention.

The microfluidic device 1 of the Fig. 2 is identical to that of the Fig. 1 except that each of the intake 51 and exhaust 91 channels has a valve.

Indeed, the inlet microfluidic channel 51 comprises an inlet valve 53 adapted to stop or modify the flow rate of the liquid admitted into the microfluidic chamber 3 from the upstream microfluidic circuit 11. The exhaust channel 91 comprises a valve exhaust 93 adapted to stop or control the evacuation of air to the atmosphere. It will be noted that the microfluidic evacuation channel 71 may also comprise an outlet valve (not shown) adapted to stop or modify the flow rate of the liquid transported from the microfluidic chamber 3 to the downstream microfluidic circuit 13.

Alternatively, the microfluidic device may comprise a single valve installed in any of the intake 51, exhaust 91 and exhaust 71 channels.

The Fig. 3 schematically illustrates different forms of microfluidic chambers, according to different embodiments of the invention.

More particularly, Fig. 3 represents bottom views showing the first walls 133-1133 of the various microfluidic chambers 103-1103 in a plane (X, Y). According to these various examples, the discharge channels 71 and admission 51 are not necessarily arranged in the same plane. Indeed, the outlet channel 71 is advantageously arranged lower (in the Z direction) than the inlet channel 51.

More particularly, the first example shows a microfluidic chamber 103 having a triangular section (in a plane (X, Y)) on the side of the evacuation channel 71 and a circular section on the inlet channel 51 side. evacuation 71 emerges at a vertex of the triangular section while the inlet channel 51 opens at the circular section.

The second example shows a microfluidic chamber 203 having a triangular section. The evacuation channel 71 emerges from a vertex of the triangular section and the inlet channel 51 opens out in the middle of the side opposite this vertex.

The third example shows a microfluidic chamber 303 having a circular section thus forming a cylindrical chamber such as that shown in the drawings. Figs. 1 and 2 .

The fourth example shows a microfluidic chamber 403 having a pointed oval section on one side of the major axis of the oval and rounded on the opposite side. The exhaust channel 71 appears at the sharp side and the inlet channel 51 terminates at the rounded side.

The other examples show microfluidic chambers 533-1133 having other configurations or geometric shapes.

It should be noted that the majority of the examples (with the exception of the last three microfluidic chambers 933, 1033, 1133) show that the internal volume of each microfluidic chamber has a concave configuration (ie, any segment connecting two points of the internal volume is inscribed in the internal volume).

Moreover, each of the microfluidic chambers 133, 233, 433 and 831 has a convergent shape in the vicinity of the evacuation channel 71 and diverging in the vicinity of the inlet channel 51. The divergent part makes it possible to increase the volume of the microfluidic chamber while the convergent part makes it possible to better drain the liquid towards the outlet.

To further facilitate the evacuation of liquid via the outlet, the inner walls of the convergent portion of each microfluidic chambers 133, 233, 433 are covered with a hydrophilic layer while the inner walls of the diverging portion are covered with a hydrophobic layer. Alternatively, for practical manufacturing reasons, the entire inner surface of each of the microfluidic chambers is hydrophilic.

Advantageously, the majority of the microfluidic chambers (with the exception of the chambers 233 and 1133) do not have sharp angles, which favors a good drainage of the liquid towards the outlet 7. Indeed, sharp angles at the outlet 7 can prevent good capillary drainage to the outlet. Likewise, sharp angles within a hydrophilic microfluidic chamber 3 can retain the liquid by capillary forces thus preventing the proper drainage of the liquid towards the outlet 7.

The Fig. 4A schematically illustrates a microfluidic device comprising a microfluidic chamber 3 connected to an upstream circuit adapted for a flow by pressure and to a downstream circuit adapted for a capillary flow in a plane (X, Y), according to a preferred embodiment of the invention. 'invention.

By way of example, the upstream circuit 11 may comprise filters which may require a flow of the pressurized liquid by means of pumps 12. The downstream circuit corresponds, for example, to a network of microfluidic cells 14 comprising reagents for carrying out chemical reactions or where a capillary filling has certain advantages. In fact, the filling by capillarity promotes a complete filling of all the cells of the network, which is difficult to achieve in flow under pressure.

The predetermined volume of the microfluidic chamber 3 is chosen to be greater than a critical volume defined as a function of the total volume of the liquid to be injected into the chamber. chamber 3 and / or flow rates of entry and exit of the liquid. This critical volume makes it possible to ensure that the filling of the microfluidic chamber 3 by a flow under pressure is not faster than its emptying by a capillary flow. This is ensured either when the volume of the microfluidic chamber 3 is greater than or equal to the total volume of the liquid injected into the chamber 3 or when the inlet flow rate of the liquid is less than or equal to the output flow rate. The critical volume can also be defined by a clever combination of these two constraints.

For example, for a total volume of the injected liquid of 30 .mu.l at an input flow rate of the order of 100 .mu.l / min, the microfluidic chamber 3 may have a predetermined volume between 20 .mu.l and 30 .mu.l. In particular, the volume of the microfluidic chamber 3 may be of the order of 25 .mu.l with an output rate of the order of 120 .mu.l / min. For example, the area of the first wall may be of the order of 7 mm and the height of the microfluidic chamber 3 may be of the order of 3.5 mm.

Moreover, the microfluidic evacuation channel 71 is advantageously arranged at the lower end of the microfluidic chamber 3 and preferably on the first wall. According to this example, the inlet microfluidic channel 51 is also arranged at the lower end of the microfluidic chamber 3, but it can of course be arranged on the side wall of this chamber 3.

The microfluidic inlet channel 51 is adapted for pressurized flow and the microfluidic exhaust channel 71 is adapted for spontaneous capillary flow.

Indeed, the microfluidic evacuation channel 71 has a smaller section than that of the inlet microfluidic channel 51. By way of example, for a microfluidic chamber 3 having a volume of the order of 25 μl, the microfluidic channel discharge 71 has a section of about 300μm x 300μm and the inlet microfluidic channel 51 has a section of about 500μm x 300μm. This allows the microfluidic intake channel 51 to be more suitable for pressurized flow and allows the microfluidic evacuation channel 71 to be more suitable for capillary flow.

In addition, in order to guarantee a good spontaneous capillary flow and taking into account the liquids of interest likely to be used in this device (as for example the biological fluids), the microfluidic drainage channel 71 is advantageously made with hydrophilic walls for generating small contact angles of less than 60 °.

For example, the Fig. 4B shows a microfluidic evacuation channel 71 having an upper wall 73 and side walls 74, 75 covered with a hydrophilic layer having a contact angle of the order of 10 °. The hydrophilic layer may be a glass or silica layer, a silane layer with a hydrophilic end (of the "-COOH" type), or a "-OH" group layer formed on the surface of the polymer by a plasma treatment. . The bottom wall 76 may consist of a thin, untreated adhesive paper having a contact angle of the order of 60 ° (ie, less hydrophilic than the other three walls).

Advantageously, the vent 9 has an opening of greater width than the size of the air bubbles in order to prevent the latter from obstructing the vent 9 and thus to prevent the rise of an overpressure which may eventually cause bubbles In the microfluidic evacuation channel 71, for example, the vent may have a diameter of approximately 300 μm to 1 mm. For some applications, the microfluidic chamber 3 can even be completely open on its upper part (ie, not having a second wall) and in this case, the diameter of the vent is the same as that of the microfluidic chamber 3. In furthermore, the vent 9 may advantageously comprise an edge adapted to prevent the liquid or the air bubbles from blocking the opening of the vent 9.

According to this embodiment, the exhaust channel 91 is advantageously disposed at the upper end of the microfluidic chamber 3 and more precisely on the ceiling (ie the second wall) of this chamber 3. The exhaust channel 91 can present a section of about 300μm x 300μm to 1mm x 1mm.

Thus, when a liquid (inadvertently or uncontrollably containing air bubbles) enters via the microfluidic inlet channel 51 into the microfluidic chamber 3, the air bubbles due to their low density, rise to the surface . The excess air escaping from the bursting of the air bubbles on the surface is discharged through the vent 9 thus preventing the formation of an overpressure which would otherwise have pushed the air bubbles with the liquid into the air. microfluidic evacuation channel 71.

On the other hand, when the liquid reaches the microfluidic outlet 7, the capillary action of the microfluidic evacuation channel 7 transports the liquid towards the upstream circuit 13. On the other hand, the air bubbles do not enter the microfluidic evacuation channel. 71 because they remain on the surface of the liquid in the microfluidic chamber 3 and moreover, the capillary action does not act on them.

The Fig. 5 schematically illustrates a microfluidic device, according to a preferred embodiment of the invention.

The microfluidic device 111 comprises an upstream microfluidic circuit 11, a downstream microfluidic circuit 13 and a microfluidic chamber 3. The upstream circuit 11 is adapted for a flow under pressure while the downstream circuit 13 is adapted for a spontaneous capillary flow.

The microfluidic chamber 3 is similar to any one of the embodiments described above and thus corresponds to an interface between a first zone 11 of flow under pressure and a second zone 13 of spontaneous capillary flow. This interface makes it possible to transfer a liquid from the first flow zone 11 to the second flow zone 13 while preventing the transfer of air bubbles into the second zone 13.

Advantageously, the upstream microfluidic circuit 11, the downstream microfluidic circuit 13, the microfluidic chamber 3, the microfluidic inlet 51 and exhaust 71 channels and the exhaust channel 91 are formed in one piece.

The fact that the microfluidic device 111 is formed integrally or in one piece eliminates the technological constraints related to connection problems. Indeed, no connection is required between the microfluidic chamber 3 comprising the microfluidic intake channels 51 and exhaust 71, and secondly each of the upstream circuits 11 and downstream 13.

In addition, a microfluidic device 111 formed in one piece optimizes the transfer quality of the liquid from the upstream circuit 11 to the downstream circuit 13 without the introduction of air bubbles in this circuit 13.

The microfluidic device 111 may for example consist of a first substrate 112 disposed below a second substrate 114 and enclosing the circuits Upstream microfluidic 11 and downstream 13, the microfluidic intake 51 and discharge 71 channels as well as the microfluidic chamber 3. The inlet 51 and discharge 71 channels and the cavity of the microfluidic chamber 3 can be formed in the first substrate 112 while the vent 9 and the exhaust channel 91 can be formed in the second substrate 114. Moreover, the microfluidic networks of the upstream circuits 11 and downstream 13 can be formed on one or the other first and second substrates 112, 114.

Thus, the same substrates 112, 114 are used to form in one piece the upstream microfluidic circuits 11 and downstream 13 the inlet microfluidic channels 51 and discharge 71 as well as the microfluidic chamber 3. The material of the first substrate 112 and / or the second substrate 114 may be selected from a wide range of materials such as, for example, polycarbonate polymer, PMMA, COC, silicon, paper, etc.

The orifices, cavities, and microfluidic channels may be machined according to methods known by the plastics industry such as mechanical machining with a numerically controlled machine, by 3D printing, or preferably by injection.

In addition, the first substrate 112 and the second substrate 114 are assembled so as to ensure a sealed contact while providing a flow space at the cavities and different microfluidic channels. The assembly can be carried out by gluing, by plasma, by thermal sealing or by mechanical plating.

By way of example, the upstream circuit 11 is used to prepare a liquid and to inject it under pressure. The downstream circuit 13 corresponds to a capillary flow zone comprising channels feeding a network of reaction cells 14. The microfluidic chamber 3 provides an interface between the two fluid flow modes while preventing the transfer into the capillary zone of air bubbles present in the incoming liquid. In addition, the microfluidic device 111 makes it possible to fill the capillary circuit 13 with the total volume of the injected liquid while minimizing waste. It also makes it possible to perform a sequential and multi-fluid injection in the capillary circuit 13. In addition, the microfluidic device 1 can be used to mix different liquids before transfer of the mixture without bubbles into the capillary circuit 13.

Claims (13)

Microfluidic device comprising a first microfluidic circuit said upstream (11) and a second microfluidic circuit said downstream (13), the microfluidic circuits upstream and downstream (11, 13) being connected to a microfluidic chamber (3) extending between a channel d inlet (51) forming an end of the upstream microfluidic circuit (11) and a discharge channel (71) forming an end of the downstream microfluidic circuit (13), the device being characterized in that : the microfluidic chamber (3) has a volume adapted to form a retention of a liquid flowing between the upstream microfluidic circuit (11) and the downstream microfluidic circuit (13), the evacuation channel has a section, in a plane perpendicular to the direction of flow of the liquid, sized to allow evacuation of the liquid from the microfluidic chamber (3) through said spontaneous capillary flow evacuation channel, and - The microfluidic chamber (3) comprises a vent (9) configured to evacuate the air contained in the liquid flowing in said microfluidic chamber (3) from the upstream microfluidic circuit (11). Device according to Claim 1, characterized in that the upstream microfluidic circuit (11) is a pressurized flow circuit. Device according to claim 1 or 2, characterized in that said microfluidic chamber is configured to be connected to the upstream and downstream microfluidic circuits (11, 13) in a predetermined orientation with the ends of the upstream and downstream microfluidic circuits (11, 13) at a level lower than that of the vent (9), the notions of inferior and superior being related to the field of gravity. Device according to any one of the preceding claims, characterized in that the admission channel (51) opens into the microfluidic chamber (3) at a level greater than or equal to that of the evacuation channel (71). Device according to any one of the preceding claims, characterized in that the evacuation channel (71) comprises hydrophilic walls. Device according to any one of the preceding claims, characterized in that the liquid is selected from the following liquids: water, aqueous buffers and body fluids, and in that the contact angle of the liquid on at least one wall of the duct discharge (71) is less than 60 ° and preferably less than 30 °. Device according to any one of the preceding claims, characterized in that the vent (9) comprises an exhaust channel (91) adapted to evacuate the air. Device according to Claim 7, characterized in that it comprises at least one valve (53, 93) installed in at least one of the intake (51), exhaust (71) and exhaust ( 91). Device according to any one of the preceding claims, characterized in that the predetermined volume of the microfluidic chamber is greater than a critical volume defined as a function of a total volume of the liquid injected into the microfluidic chamber and / or inlet flow rates. and leaving the liquid. Device according to any one of the preceding claims, characterized in that the microfluidic chamber (3) has hydrophilic inner walls with a divergent section on the microfluidic admission side and a convergent section on the microfluidic evacuation side. Device according to any one of the preceding claims, characterized in that it comprises a plurality of vents, and / or a plurality of admissions microfluidics, and / or a plurality of microfluidic evacuations. Microfluidic device according to one of the preceding claims, characterized in that the upstream and downstream microfluidic circuits (11, 13), the microfluidic chamber (3), and the inlet and outlet channels are formed integrally. . Microfluidic flow process between a first upstream microfluidic circuit (11) and a second downstream microfluidic circuit (13), the upstream and downstream microfluidic circuits (11, 13) being connected to a microfluidic chamber (3) extending between an inlet channel (51) forming an end of the upstream microfluidic circuit (11) and a discharge channel (71) forming an end of the downstream microfluidic circuit (13), the method being characterized in that it comprises the following steps: configuring the microfluidic chamber (3) so that its volume is adapted to form a retention of a liquid flowing between the upstream microfluidic circuit (11) and the downstream microfluidic circuit (13), - dimensioning the discharge channel in a section, in a plane perpendicular to the direction of flow of the liquid, to allow evacuation of the liquid from the microfluidic chamber (3) through said spontaneous capillary flow evacuation channel, and - Fit a vent (9) in the microfluidic chamber (3) to evacuate air escaping air bubbles contained in the liquid flowing in said microfluidic chamber (3) from the upstream microfluidic circuit (11).

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