EP1860060A1 - Method and apparatus for mixing microdroplets - Google Patents

Abstract

The method for mixing of micro-droplets (2a, 2b), comprises supplying two carriers (3a, 3b), each of whose surfaces (4a, 4b) is structured in such a manner that a hydrophilic surface area is surrounded by a hydrophobic surface area. On a hydrophilic surface area of a first carrier, a first micro-droplet is arranged and on a hydrophilic surface area of a second carrier, a second micro-droplet is arranged. The surface of a first carrier is structured in such a manner that closely-lying hydrophilic surface areas are separated by the hydrophobic surface area. The method for mixing of micro-droplets (2a, 2b), comprises supplying two carriers (3a, 3b), each of whose surfaces (4a, 4b) is structured in such a manner that a hydrophilic surface area is surrounded by a hydrophobic surface area. On a hydrophilic surface area of a first carrier, a first micro-droplet is arranged and on a hydrophilic surface area of a second carrier, a second micro-droplet is arranged. The surface of a first carrier is structured in such a manner that closely-lying hydrophilic surface areas are separated by the hydrophobic surface area. The surface of a first carrier is provided with a matrix-shaped surface structure, which has many hydrophilic surface areas that are separated from one another by a hydrophobic surface area. The carriers with the first and the second hydrophilic surfaces are placed so closely adjacent to one another by moving them towards one another in such a manner that the micro-droplets are contacted with one another. The surface of a second carrier is provided with a surface structure that is suitable to the surface structure of the first carrier, that a micro-droplet is applied on each of the individual hydrophilic surface areas. The carriers with the surface structures placed adjacent to one another by moving them towards one another in such a manner that the micro-droplets of the hydrophilic surface areas that correspond to one another. Each of the hydrophilic surface areas is brought in contact with a micro-droplet. A second carrier is positioned relative to the hydrophilic surface areas in such a manner that the micro-droplets are contacted with one another as well as with the second carrier. The second hydrophilic surface area covers a region of the first hydrophobic surface area that is present between the first hydrophilic surface areas, and the three micro-droplets are contacted with one another. For the purpose of application of the micro-droplets on the hydrophilic surface area(s), one of the carriers is dipped into the liquid and then removed out of the liquid preferably at a speed in the range of 0.1-10 mm/s. A first micro-droplet contains enzymes and a second micro-droplet contains a DNA molecule, a primer and a nucleoside triphosphate at a concentration that is sufficient for a polymerase chain reaction. A carrier is provided as a metal oxide or semi metal oxide substrate, and that the substrate is coated at the sites meant for the hydrophilic surface areas with a polymer having a reactive group. The first micro-droplet contains hydrogen peroxide and a second micro-droplet contains luminol. An independent claim is included for a device for mixing of micro-droplets.

Description

The invention relates to a method and apparatus for mixing microdroplets.

From practice it is known to dose amounts of liquid in the range of less than 1 .mu.l using so-called nanopipettes. For mixing microdroplets, a first liquid is stored in a reservoir of a first nanopipette. A nozzle of the nanopipette connected via a channel to the reservoir is positioned on a substrate for ejecting a microdroplet of the liquid onto the substrate by means of an actuator. Thereafter, a second nanopipette is positioned on the substrate to correspondingly form a second microdroplet of a second liquid to apply to the substrate, for example, to start a chemical reaction between the liquids. Once the microdroplets come into contact with each other, they mix. However, because of the small size of the microdroplets, it is difficult to apply the second microdroplet to the substrate at exactly the same location as the first microdroplet. This is particularly problematic for liquids with low viscosity, since in these liquids, the microdroplets can easily split after exiting the nozzle. If several microdroplets are successively applied to the substrate, there is also a risk that the microdroplets evaporate before they come into contact with each other. In addition, the liquids are dispensed depending on their surface energy. Thus, e.g. Liquids with high surface energy larger microdroplets than liquids with low surface energy.

It is therefore an object to provide a method and a device which make it possible in a simple manner to mix at least two microdroplets together.

This object is achieved with respect to the method in that at least two carriers are provided whose surfaces are each patterned such that at least one hydrophilic surface area of at least A hydrophobic surface region is bounded by disposing a first microdroplet on a hydrophilic surface region of a first carrier and a second microdroplet on a hydrophilic surface region of a second carrier, and positioning the carriers with the first and second surfaces facing each other by moving toward each other in such close proximity in that the microdroplets come into contact with each other.

By structuring the carrier surfaces into hydrophilic and hydrophobic regions in aqueous liquids, an independent adjustment of the liquids on the hydrophilic regions is advantageously achieved. The microdroplets can be applied to the carrier with great positioning accuracy and precision. By positioning the carriers in the correct position, the microdroplets are brought into contact with one another and mixed.

In a preferred embodiment, it is provided that the surface of a first carrier is provided with a preferably matrix-shaped surface structure having a plurality of hydrophilic surface regions separated from each other by the at least one hydrophobic surface region such that the surface of a second carrier having a surface texture of the first carrier suitable surface structure is provided, that on the individual individual hydrophilic surface areas in each case a microdroplet is applied, and that the carrier with the surface structures facing each other by moving towards each other are positioned together so that the microdroplets of each corresponding hydrophilic surface areas in each case come into contact with each other. Thus, a plurality of pairwise associated microdroplets may be mixed together as the carriers are positioned one another.

The abovementioned object is also achieved with regard to the method in that at least two carriers are provided such that the surface of a first carrier is structured so that closely adjacent hydrophilic surface regions are separated from each other by at least one hydrophobic surface region, that the hydrophilic surface regions each with be brought into contact with a microdroplet, and that one second support is positioned relative to the hydrophilic surface areas such that the microdroplets are in contact with the second support and each other.

In this case, the hydrophobic surface area of the first carrier located between the adjacent hydrophilic surface areas is bridged by the second carrier so that the microdroplets come into contact with each other and mix, for example because the microdroplets are displaced laterally when positioning the carrier and / or in the diffuse each other microdroplets. The surface of the second support is preferably hydrophilic. The method is particularly simple and inexpensive to carry out, since only one of the two carriers must be structured.

The above object is also achieved with respect to the method in that at least two carriers are provided such that the surface of a first carrier is structured such that closely adjacent first hydrophilic surface regions are separated from each other by at least one first hydrophobic surface region second support is patterned such that at least a second hydrophilic surface region is bounded by at least a second hydrophobic surface region, the first hydrophilic surface regions and the at least one second hydrophilic surface region are each contacted with a microdroplet, and the supports are bonded to the first hydrophilic surface regions Surface areas and the at least one second hydrophilic surface area facing each other by moving towards each other are positioned so close to each other that the second hydrophilic O. The surface region covers a region of the first hydrophobic surface region situated between the first hydrophilic surface regions and the at least three microdroplets come into contact with one another.

In this solution, therefore, at least three microdroplets arranged on the carrier surfaces are mixed together in a simple manner virtually simultaneously.

It is advantageous if at least one of the carriers for applying the microdroplet (s) to the hydrophilic surface area (s) is immersed in a liquid and then preferably at a speed in the range of 0.1 to 10 mm / s the liquid is withdrawn. The at least one hydrophilic surface region can thereby be easily loaded with the microdroplet. As the carrier is withdrawn from the liquid, it will bead from the hydrophobic surface areas while adhering to the hydrophilic surface areas in the form of the microdroplet.

In an advantageous embodiment of the invention, it is provided that a first microdroplet contains an enzyme and a second microdroplet at least one DNA molecule, primer and nucleoside triphosphate in a sufficient for a polymerase chain reaction concentration. By bringing the microdroplets into contact, a polymerase chain reaction can then be started in a simple manner in order to amplify the DNA molecule. The process even makes it possible to start a large number of polymerase chain reactions simultaneously, with the individual reactions starting immediately after the microdroplets have been brought into contact. Compared to conventional methods, a so-called hot-start, in which the enzyme is inactivated by a thermolabile group under the action of heat, can be omitted.

In another advantageous embodiment of the invention, a first microdroplet of hydrogen peroxide and a second microdroplet of luminol. The method may then be used for the optical detection of receptor-ligand complexes which are directly or indirectly labeled with an enzyme which, when present, decomposes the luminol upon contact with the hydrogen peroxide with the emission of chemiluminescent radiation. The method can be used in particular in the ELISA or sandwich ELISA method.

It is advantageous if at least one support is provided as a metal oxide or semimetal oxide substrate, and if the substrate is coated with a polymer having at least one reactive group at the locations where the hydrophilic surface regions are to be. The substrate can then be patterned with great precision using methods known per se for semiconductor production become. The reactive group may, for example, have an OH, SH and / or NH ₂ group. The polymer may be a gel and in particular contain a polysaccharide and / or poly (2-hydroxyethyl) methacrylate (pHEMA).

The above object is achieved with respect to the device of the type mentioned above in that it has at least two carriers whose surfaces are each structured such that at least one hydrophilic surface area is bounded by at least one hydrophobic surface area, that the device has a positioning device by means of the carriers with the structured surfaces facing one another are positionable in such close proximity to one another that microdroplets which can be applied to the hydrophilic surface areas come into contact with one another.

By structuring the carrier surfaces into hydrophilic and hydrophobic regions, an independent adjustment of microdroplets on the hydrophilic regions is made possible upon contact of the carrier surface with an aqueous liquid. Thereafter, the carriers can be easily positioned together with the hydrophilic surface regions by means of the positioning device in such a way that the microdroplets come into contact with each other and mix.

The above-mentioned object is also achieved with respect to the device of the type mentioned above in that the device has at least two carriers such that the surface of a first carrier is structured so that closely adjacent hydrophilic surface regions are separated from one another by at least one hydrophobic surface region, and the device has a positioning device by means of which the carriers can be positioned so close to one another that microdroplets which can be applied to the hydrophilic surface regions of the first carrier come into contact with the second carrier and with one another.

In this device as well, the self-alignment of the microdroplets is made possible by structuring the carrier surfaces into hydrophilic and hydrophobic regions. Since only one of the two carriers must have a surface structuring, the device can be produced inexpensively.

The above object is also achieved with respect to the device of the type mentioned above in that the device has at least two carriers such that the surface of a first carrier is structured so that closely adjacent first hydrophilic surface regions are separated from each other by at least one first hydrophobic surface region, in that the surface of a second carrier is structured in such a way that at least one second hydrophilic surface region is bounded by at least one second hydrophobic surface region, and in that the device has a positioning device by means of which the carriers with the structured surfaces can be positioned so close to each other that they are so close together the second hydrophilic surface region covers a first hydrophobic surface region located between the first hydrophilic surface regions and the first hydrophilic surface In this case, microdroplets which can be applied can be brought into contact with microdroplets which can be applied to the second hydrophilic surface regions.

By means of the device it is thus possible to easily bring three microdroplets into contact and mix with one another almost simultaneously.

It is advantageous if the device has at least three of the carrier, and if these carriers by means of the positioning optionally or alternately positioned to each other. This makes it possible, in particular, to mix a plurality of microdroplets in succession, for example to mix first two microdroplets A and B into a microdroplet AB and then this with a microdroplet C to form a microdroplet ABC.

It is advantageous if at least one carrier has a metal oxide or semimetal oxide substrate which is coated on the hydrophilic surface regions with a polymer having at least one reactive group. The substrate can then be mass produced with high precision by methods of semiconductor manufacturing.

In an expedient embodiment of the invention, the positioning device cooperates with one another on the carriers to be positioned against each other Centering on, in particular centering bevels. The carriers can then be easily positioned with their surface structuring in a predetermined position relative to each other. As a centering can be provided on one carrier a projection and on the other carrier a matching recess. The centering elements can also be optical markings, such as crosshairs, which are brought to coincide when the carriers are positioned one against the other.

It is advantageous if at least one carrier preferably has a moisture and / or conductivity sensor on a hydrophilic surface area. With the sensor can be easily controlled whether the microdroplets are in contact with each other, for example, if the fluids of the microdroplets have different electrical conductivities.

In a preferred embodiment of the invention, at least one carrier has a cooling and / or heating element, in particular a Peltier element. The device can then be used to perform a polymerase chain reaction (PCR).

Fig. 1

eine Aufsicht auf einen ersten Träger eines ersten Ausführungsbeispiels einer Vorrichtung zum Mischen von Mikrotröpfchen,

Fig. 2

einen Querschnitt durch die mit Mikrotröpfchen beschichteten Träger des ersten Ausführungsbeispiels der Vorrichtung, wobei die Träger in einer Ausgangslage angeordnet sind,

Fig. 3

eine Darstellung ähnlich Fig. 2, wobei jedoch die Träger aus der Ausgangslage aufeinander zu bewegt wurden,

Fig. 4

einen Querschnitt durch die Träger eines zweiten Ausführungsbeispiels der Vorrichtung,

Fig. 5

eine Aufsicht auf einen ersten Träger eines dritten Ausführungsbeispiels der Vorrichtung,

Fig. 6

eine Aufsicht auf einen zweiten Träger des dritten Ausführungsbeispiels der Vorrichtung,

Fig. 7

einen Querschnitt durch die Träger des dritten Ausführungsbeispiels der Vorrichtung, wobei die Träger in einer Ausgangslage angeordnet sind,

Fig. 8

eine Darstellung ähnlich Fig. 7, wobei jedoch die Träger aus der Ausgangslage aufeinander zu bewegt wurden,

Fig.9

einen Querschnitt durch die mit Mikrotröpfchen beschichteten Träger eines vierten Ausführungsbeispiels der Vorrichtung, wobei die Träger in einer Ausgangslage angeordnet sind, und

Fig. 10

eine Darstellung ähnlich Fig. 9, wobei jedoch die Träger aus der Ausgangslage aufeinander zu bewegt wurden.

Embodiments of the invention are explained in more detail below. Show it:

Fig. 1

a top view of a first carrier of a first embodiment of a device for mixing microdroplets,

Fig. 2

a cross section through the microdroplet coated carrier of the first embodiment of the device, wherein the carriers are arranged in a starting position,

Fig. 3

a representation similar to Figure 2, but with the carriers were moved from the starting position toward each other,

Fig. 4

a cross-section through the carrier of a second embodiment of the device,

Fig. 5

a plan view of a first carrier of a third embodiment of the device,

Fig. 6

a plan view of a second carrier of the third embodiment of the device,

Fig. 7

a cross section through the carrier of the third embodiment of the device, wherein the carriers are arranged in a starting position,

Fig. 8

a representation similar to Figure 7, but with the carriers were moved from the starting position toward each other,

Figure 9

a cross section through the microdroplet coated carrier of a fourth embodiment of the device, wherein the carriers are arranged in a starting position, and

Fig. 10

a representation similar to Fig. 9, but with the carrier from the starting position were moved towards each other.

A device 1 for mixing microdroplets 2a, 2b, shown in FIGS. 1 to 3, has two approximately plate-shaped carriers 3a, 3b whose surfaces 4a, 4b are each structured such that a plurality of hydrophilic surface regions 5a, 5b are defined by a hydrophobic surface region 6a bordering them , 6b are laterally spaced from each other. The hydrophilic surface regions 5a, 5b are arranged in a matrix-like manner in a plurality of rows and columns. The matrices of the two carriers 3a, 3b are configured in such a way that the hydrophobic surface regions 6a, 6b of a first carrier 3a can be used with those of a second carrier 3b to cover when the carriers 3a, 3b with their hydrophilic surface regions 5a, 5b face each other be positioned together.

In Fig. 1 it can be seen that the carrier has formed as crosshairs optical position marks, which are arranged in a predetermined position relative to the hydrophilic surface regions 5a, 5b.

The supports 3a, 3b each consist of a semiconductor material, e.g. Silicon, which has on its surface a not shown in the drawing fluoropolymer layer which forms the hydrophobic surface region 6a, 6b. On the fluoropolymer layer in each case in the hydrophilic surface regions 5a, 5b, a polymer hydrogel is applied, which may have reactive groups.

First microdroplets 2a are applied to the hydrophilic surface regions 5a of the first carrier 3a. For this purpose, the carrier 3a may be immersed in, for example, a liquid and then withdrawn therefrom at a rate chosen to adhere the liquid only to the hydrophilic surface regions 5a. However, the microdroplets 2a can also be applied in any other way to the hydrophilic surface regions 5a, e.g. with the help of a needle, a pipette or by printing, in particular by means of a jet printer. In this case, the different surface regions 5a, 6a cause the microdroplets 2a to align themselves in such a way that they are arranged only on the hydrophilic surface regions 5a.

Second microdroplets 2b are applied in a corresponding manner to the hydrophilic surface regions 5a, 5b of the second carrier 3b. Then, the carriers 3a, 3b are positioned with their extension planes parallel to each other such that the hydrophilic surface regions 5a of the first carrier 3a are mirror images of the hydrophilic surface regions 5b of the second carrier 3b. For the correct alignment of the carriers 3a, 3b, the position marks 7 of the one carrier 3a are brought into coincidence with the position marks 7 of the other carrier 3b.

As can be seen in FIG. 2, the carriers 3a, 3b are initially spaced so far apart that the microdroplets 2a, 2b do not touch each other. In the arrangement shown in FIG. 2, the microdroplets 2a of the upper side of the first carrier 3a and the microdroplets 2b are arranged on the underside of the second carrier 3b. The last-mentioned microdroplets adhere to the hydrophilic surface regions 5b against the force of gravity. Of course, it is also possible that the plate assembly formed from the carriers 3a, 3b in a positioned elsewhere in the room, for example, rotated by 90 ° about an axis normal to the plane in Fig. 2 and 3 extending axis.

In a further method step, the carriers 3a, 3b are moved by means of a positioning device not shown in detail in the drawing, e.g. a robot, as long as normal moves to their extension planes until the located on the surface of the first carrier 3a microdroplets 2a each touch a corresponding thereto microdroplet 2b of the second carrier 3b and mix each with this, for example, a chemical reaction between the different Liquids of the microdroplets 2a, 2b and / or substances dissolved therein to start. In Fig. 3 it can be seen that the carriers 3a, 3b after the mixing of the microdroplets 2a, 2b to a new microdroplet 2 by a narrow gap are spaced apart from each other such that the microdroplets 2 by the hydrophobic surface regions 6a, 6b are spaced from each other. Microdroplets 2a, 2b, which were arranged on the same carrier 3a, 3b, therefore do not mix.

In the exemplary embodiment shown in FIG. 4, the positioning device has a first housing part 8a connected to the first support 3a and a second housing part 8b connected to the second support 3b. The first housing part 8a has a receiving recess and the second housing part 8b has a matching one Head Start. On the housing parts 8a, 8b inclined surfaces 9 are arranged, which act together in inserted into the first housing part 8a second housing part, that the housing parts 8a, 8b are centered in a predetermined position relative to each other. The housing parts 8a, 8b are preferably made of an inert plastic, with which the carrier parts 3a, 3b are partially encapsulated.

In the exemplary embodiment shown in FIGS. 5 to 8, hydrophilic surface regions 5 a are provided only on the surface of the first carrier part 3 a, which are separated from one another by a hydrophobic surface region 6 a. The hydrophilic surface regions 5a are arranged in a matrix-like manner in a plurality of rows and columns. In FIG. 5 it can be clearly seen that in each case two surface regions 5a are associated in pairs with one another and have a smaller distance from one another than to the remaining hydrophilic surface regions 5a.

The surface of the second, serving as a stamp carrier part 3b is completely hydrophilic.

A first microdroplet 2a and a second microdroplet 2b on the other surface area 5b are used up on a respective surface area 5a of the paired surface regions 5a. The application of the microdroplets 2a, 2b can be effected for example by printing.

As can be seen in FIG. 7, the carriers 3a, 3b are arranged with their extension planes parallel to one another, wherein the carriers 3a, 3b are initially spaced from one another so far that the second carrier 3b does not comprise the microdroplets 2a, 2b located on the first carrier 3a touched. Then the carriers are moved towards each other approximately normal to their planes of extent until the second carrier 3b touches the pairwise associated microdroplets 2a, 2b and these come into contact with each other.

In Fig. 8 it can be seen that the carriers 3a, 3b after mixing the microdroplets 2a, 2b to a new microdroplet 2 by a narrow gap are spaced apart from each other such that the microdroplets 2 are spaced apart by the hydrophobic surface portion 6a. Thus, only the pairwise associated microdroplets 2a, 2b are mixed together.

In the embodiment shown in Figs. 9 and 10, the arrangement of the surface portions 5a, 6a corresponds to that in Fig. 5. In addition, however, second hydrophilic surface portions 5b are provided on the second support, which are spaced apart from each other by a second hydrophobic surface portion 6b. The first hydrophilic surface regions 5a are coated with first and second microdroplets 2a, 2b as in the embodiment in FIG. Third microdroplets 2c are applied to the second hydrophilic surface regions 5b.

In FIG. 9 it can be seen that the carriers 3a, 3b are arranged with their extension planes parallel to one another such that the second hydrophilic surface regions 5b each have one between the first hydrophilic surface regions 5a overlap region of the first hydrophobic surface region 6a. It can clearly be seen that the third microdroplet 2 c is arranged in the plan view of the extension planes of the carriers 3 a, 3 b between a first microdroplet 5 a assigned to it and a second microdroplet 5 b. In this case, the carriers 3a, 3b are initially spaced apart from one another such that the microdroplets 2a, 2b, 2c do not touch each other. Then, the carriers are moved toward each other approximately normal to their planes of extent until the third microdroplets 2c touch and mix with the first and second microdroplets 2a, 2b.

In Fig. 10 it can be seen that the carriers 3a, 3b after the mixing of the microdroplets 2a, 2b, 2c to a new microdroplet 2 by a narrow gap are spaced apart such that the microdroplets 2 by the hydrophobic surface region 6a, 6b spaced from each other are. Thus, only three mutually associated microdroplets 2a, 2b, 2c are mixed together.

The first microdroplet 2a may contain hydrogen peroxide, the second microdroplet 2b luminol, and the third microdroplet a serum to be assayed, in which ligands are reacted with an enzymatic marker, e.g. Horseradish peroxidase (HRP) are labeled.

Claims (16)

Method for mixing microdroplets (2a, 2b, 2c), wherein at least two carriers (3a, 3b) are provided whose surfaces (4a, 4b) are each structured such that at least one hydrophilic surface region (5a, 5b) of at least one hydrophobic surface region (6a, 6b) is delimited, wherein on a hydrophilic surface region (5a) of a first carrier (3a) a first microdroplet (2a, 2b, 2c) and on a hydrophilic surface region (5b) of a second carrier (3b) a second Microdroplets (2a, 2b, 2c) are arranged, and wherein the carriers (3a, 3b) with the first and second hydrophilic surfaces (4a, 4b) facing each other by moving towards each other are positioned so close together that the microdroplets (2a, 2b, 2c) come into contact with each other. Method according to claim 1, characterized in that the surface (4a) of a first carrier (3a) is provided with a preferably matrix-shaped surface structure comprising a plurality of hydrophilic surface regions (6a, 6b) separated from each other by the at least one hydrophobic surface region (5a, 5b) in that the surface (4b) of a second carrier (3b) is provided with a surface structure matching the surface structure of the first carrier (3a), in each case a microdroplet (2a, 2b, 2c) being applied to the individual hydrophilic surface regions, and in that the carriers (3a, 3b) with the surface structures facing one another are moved toward one another by moving toward one another such that the microdroplets (2a, 2b, 2c) in each case come into contact with one another by hydrophilic surface regions which correspond to one another. Method for mixing microdroplets (2a, 2b, 2c), wherein at least two carriers (3a, 3b) are provided, wherein the surface (4a) of a first carrier (3a) is structured such that hydrophilic surface regions (5a) which are closely adjacent to one another by at least one hydrophobic surface region (6a) are separated from each other, wherein the hydrophilic surface regions (5a) each with a microdroplet (2a, 2b, 2c), and wherein a second support (3b) is positioned relative to the hydrophilic surface regions (5a) such that the microdroplets (2a, 2b, 2c) contact the second support (3b) and each other devices. Method for mixing microdroplets (2a, 2b, 2c), wherein at least two carriers (3a, 3b) are provided, wherein the surface (4a) of a first carrier (3a) is structured in such a way that first hydrophilic surface regions (5a ) are separated from one another by at least one first hydrophobic surface region (6a), the surface (4b) of a second carrier (3b) being structured in such a way that at least one second hydrophilic surface region (5b) is delimited by at least one second hydrophobic surface region (6b) in which the first hydrophilic surface regions (5a) and the at least one second hydrophilic surface region (5b) are each brought into contact with a microdroplet (2a, 2b, 2c), and wherein the supports (3a, 3b) are in contact with the first hydrophilic surface regions (5a). 5a) and the at least one second hydrophilic surface region (5b) face each other by moving toward each other in such a way are positioned close to each other so that the second hydrophilic surface region (5b) covers a region of the first hydrophobic surface region (6a) located between the first hydrophilic surface regions (5a) and the at least three microdroplets (2a, 2b, 2c) come into contact with one another. Method according to one of Claims 1 to 4, characterized in that at least one of the carriers (3a, 3b) for applying the microdroplet (s) (2a, 2b, 2c) to the hydrophilic surface region (s) ( 5a, 5b) is immersed in a liquid and then preferably withdrawn from the liquid at a rate in the range of 0.1 to 10 mm / sec. Method according to one of claims 1 to 5, characterized in that a first microdroplet (2a, 2b, 2c) enzymes and a second microdroplet (2a, 2b, 2c) at least one DNA molecule, primer and nucleoside triphosphate in a sufficient for a polymerase chain reaction concentration. Method according to one of Claims 1 to 6, characterized in that a first microdroplet (2a, 2b, 2c) contains hydrogen peroxide and a second microdroplet (2a, 2b, 2c) contains luminol. Method according to one of claims 1 to 7, characterized in that at least one carrier (3a, 3b) is provided as a metal oxide or semimetal oxide substrate, and that the substrate at the locations where the hydrophilic surface regions (5a, 5b) be coated with a polymer having at least one reactive group. Device (1) for mixing microdroplets (2a, 2b, 2c), with at least two carriers (3a, 3b) whose surfaces (4a, 4b) are each structured such that at least one hydrophilic surface region (5a, 5b) of at least a hydrophobic surface region (6a, 6b) is delimited, and with a positioning device, by means of which the supports (3a, 3b) with the structured surfaces (4a, 4b) facing each other are positioned so close to each other that the hydrophilic surface regions (5a, 5b) attachable microdroplets (2a, 2b, 2c) come into contact with each other. Device (1) for mixing microdroplets (2a, 2b, 2c) with at least two carriers (3a, 3b), wherein the surface (4a) of a first carrier (3a) is structured in such a way that hydrophilic surface regions (5a ) are separated from one another by at least one hydrophobic surface region (6a), and with a positioning device by means of which the carriers (3a, 3b) can be positioned so close to each other that microdroplets (2a.) can be applied to the hydrophilic surface regions (5a) of the first carrier (3a) , 2b, 2c) with the second carrier (3b) and come into contact with each other. Device (1) for mixing microdroplets (2a, 2b, 2c) with at least two carriers (3a, 3b), wherein the surface (4a) of a first carrier (3a) is structured in such a way that first hydrophilic Surface regions (5a) are separated from each other by at least one first hydrophobic surface region (6a), wherein the surface (4b) of a second carrier (3b) is structured such that at least one second hydrophilic surface region (5b) of at least one second hydrophobic surface region (6b ), and with a positioning device, by means of which the carriers (3a, 3b) with the structured surfaces (4a, 4b) facing each other are positioned so close to each other that the second hydrophilic surface region (5b) separates between the first hydrophilic surface regions (5b). 5a) located on the first hydrophilic surface regions (5a) attachable microdroplets (2a, 2b, 2c) with the second hydrophilic surface regions (5b) can be applied microdroplets (2a, 2b, 2c) come into contact , Device (1) according to claim 9 or 11, characterized in that it comprises at least three of the carriers (3a, 3b), and that these carriers (3a, 3b) by means of the positioning means are selectively or alternately positionable to each other. Device (1) according to one of claims 9 to 12, characterized in that at least one carrier (3a, 3b) comprises a metal oxide or semimetal oxide substrate which is coated at the hydrophilic surface regions with a polymer having at least one reactive group. Device (1) according to any one of claims 9 to 13, characterized in that the positioning means on the carriers (3a, 3b) to be positioned against one another has cooperating centering elements, in particular centering bevels. Device (1) according to one of claims 9 to 14, characterized in that at least one support (3a, 3b) preferably has a moisture and / or conductivity sensor on a hydrophilic surface area. Device (1) according to one of claims 9 to 15, characterized in that at least one carrier (3a, 3b) has a cooling and or heating element, in particular a Peltier element.

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