EP3917672A1 - Method and device for controlling the temperature of reaction mixtures in an agitation operation - Google Patents

Abstract

The invention relates to a method for controlling the temperature of reaction mixtures (2) in an agitation operation, wherein at least two reaction mixtures (2) in at least two reaction vessels (1) are individually temperature-controlled, said reaction mixtures (2) in said reaction vessels (1) being subjected to a common agitation movement (3), the individual temperature control of at least two reaction mixtures (2) being carried out by means of a separate heat transfer (6) between at least one reaction mixture (2) and at least one temperature control zone (4) associated with said reaction mixture (2).

Description

Process and device for temperature control of reaction mixtures in shaking mode

description

Technical field

The invention relates to a method for temperature control of reaction mixtures in shaking mode and to an apparatus for performing the method. It is particularly applicable for the individual temperature control of reaction mixtures that are shaken by the same shaker. The method and the device are advantageously used in particular, but not exclusively, in the cultivation of cells and in carrying out chemical reactions in shaken reaction vessels such as shake flasks, microtiter plates, reaction tubes, T-flasks or shaking bags.

The temperature is an essential process parameter of every biological, chemical or physical process. Such processes take place in reaction mixtures and are carried out in reaction vessels which are frequently shaken in the reaction vessel for the purpose of mixing the reaction mixture.

The setting and maintenance of a certain temperature in the reaction mixture is critical for the success of each reaction process, since the temperature influences, for example, the speed or equilibrium of reactions, mass transfer processes or cultivation processes. Each cell or cell line has an optimal cultivation temperature. The yield and quality of the expression of proteins can be regulated via the temperature, for example to enable slower translation and thus better protein folding by reducing the temperature. Chemical reactions or biochemical assays can also be controlled in terms of yield, stereosymmetry, purity, specificity, etc. by setting a suitable temperature.

State of the art

In order to achieve a high experimental throughput, particularly in development and screening processes, shaken processes are often carried out in parallel in or on shaking machines, with several reaction vessels filled with reaction mixtures being fastened together on a shaking platform and shaken by this. The skilled person is familiar with shaking machines in which the shaking platform is located in an incubator.To temper the reaction mixtures in shaking mode, the gas phase in the incubator, which also surrounds the reaction vessels, is tempered, so that all reaction vessels and the reaction mixtures in them are in equilibrium with the temperature of the Have gas phase in the incubator. Embodiments of this are typical incubation shakers for shake flasks, reaction tubes or microtiter plates. The temperature of the reaction mixtures is controlled by means of heat conduction between the incubator gas phase and the reaction mixture via the respective reaction vessel. Shaking machines are also known, the temperature control method of which comprises a temperature control liquid and which are often designed as water bath shakers. In this process, the temperature of all the reaction vessels and reaction mixtures on a shaking platform corresponds in equilibrium to the temperature of the heat transfer liquid. Here too, the temperature of the reaction mixtures is controlled by means of heat conduction between the incubator heat transfer liquid and the reaction mixture via the respective reaction vessel.

A disadvantage with regard to the temperature control processes of reaction mixtures in shaking operation described above is that the process-related setting of the same temperature in all the reaction mixtures shaken together is disadvantageous. This is particularly disadvantageous because full and optimal utilization of the shaking capacity available is only possible if all processes running in parallel have the same optimal temperature requirements at all times. In the case of development and screening processes, however, this is usually not the case. A further disadvantage is that the temperature of a particular reaction mixture cannot be set individually in feedback on the respective progress of the process running in it, without negatively influencing the other reaction mixtures shaken with their processes.

This is disadvantageous in particular against the background of increasingly available process-characterizing online sensor technology, which only allows a fundamentally advantageous individualized process control that is matched to recorded measurement data EP 1 393 797 A2 discloses a device of the type mentioned, in which a plurality of reaction mixtures are held in vessels. The vessels are at least separated from one another by air. The reaction mixtures are all heated by a single, common heating device (paragraph [0037]).

Task

It is therefore an object of the present invention to provide a method by means of which the temperature of jointly shaken reaction mixtures can be controlled individually and with the avoidance of negative influences on processes in other shaken reaction mixtures, in order to set process-specific optimal temperature conditions in each reaction mixture. The object on which the invention is based is achieved by a method according to claim 1 and an apparatus for carrying out the method according to claim 8; preferred embodiments result from the subclaims and the description.

Definitions

To ensure the clarity of some of the terms used in the description, these are defined and explained below and in the course of the description

For the purposes of the invention, reaction vessels are all devices and vessels which are suitable for receiving and storing reaction mixtures. They can be open or closed. Reaction vessels in the sense of the invention are, in particular, but not exclusively, shake flasks, reaction tubes, falcons, T-flasks, microtiter plates, shaking bags and shake barrels of any geometry, material composition and filling quantity.

Reaction mixtures in the sense of the invention are mixtures of at least two components and are particularly but not exclusively in the form of liquids, solutions, emulsions, dispersions, slurries, suspensions, foams, gas mixtures or powder mixtures. Biological, chemical or physical processes or reactions take place in reaction mixtures. Reaction mixtures within the meaning of the invention therefore particularly, but not exclusively, comprise mixtures of nutrient media and cells, of starting materials, catalysts and products, of various aggregate states, etc. Shaking movements in the sense of the invention are movements which are suitable for moving or mixing the reaction mixtures contained in them by moving reaction vessels. Shaking movements in the sense of the invention are in particular but not exclusively orbital shaking, rocking shaking and tumbling shaking. Shaking movements in the sense of the invention can be carried out continuously or discontinuously, depending on the process requirements.

Temperature control of a reaction mixture in the sense of the invention is the setting of a specific temperature in the reaction mixture via heat transfer into or out of the reaction mixture. The heat transfer can take place directly into or out of the reaction mixture or indirectly via the reaction vessel, in particular but not exclusively via convection, heat conduction or heat radiation.

Tempering zones in the sense of the invention are all zones, areas, areas or volumes which are involved in the targeted heat transfer between the reaction mixture and the tempering element.

Temperature control elements in the sense of the invention are all devices which are suitable for generating heat from other forms of energy or for generating temperature gradients by heat transport, which can be used for temperature control of reaction mixtures. Temperature control elements in the sense of the invention are in particular but not exclusively electrical heating elements, heating foils, Peltier elements, heat radiators, IR LEDs, heat engines, heat pumps, blowers and pumps.

Isolation zones in the sense of the invention are all zones, areas, areas or volumes which limit or prevent the heat transfer between different reaction mixtures or temperature zones.

According to the invention, the maximum achievable heat transfer denotes the amount of heat that can be exchanged under given conditions (for example heating or cooling output, temperature difference) between at least two components of the invention, areas, zones, areas or volumes per time, regardless of the mechanism of the heat transfer. solution

According to the invention, the object is achieved by a process for the temperature control of reaction mixtures in shaking mode, in which at least two reaction mixtures are individually temperature-controlled in at least two reaction vessels and are subjected to a common shaking movement, the individual temperature control of the at least two reaction mixtures each using separate heat transfer between at least one Reaction mixture and at least one tempering zone assigned to this reaction mixture takes place

The process according to the invention thus advantageously enables individual process control at optimal temperature conditions in each reaction mixture by using reaction mixture-specific temperature zones, the heat transfer to each individual reaction mixture taking place and being regulated separately. In an advantageous embodiment of the invention, at least two reaction mixtures, each in their reaction vessels with one another by at least separated an insulation zone, so that the maximum achievable heat transfer between at least two reaction mixtures is smaller than the maximum achievable heat transfer between at least one temperature control zone and an associated reaction mixture.

In some embodiments of the invention, each reaction vessel with reaction mixture is surrounded by an isolation zone everywhere, apart from the interaction area with at least one temperature control zone.

In an advantageous embodiment of the invention, at least two temperature control zones are separated from one another by at least one insulation zone, so that the maximum achievable heat transfer between the at least two temperature control zones is smaller than the maximum achievable heat transfer between each of the temperature control zones and at least one of their respectively assigned reaction mixtures.

In an advantageous embodiment of the invention, at least one temperature control zone is assigned to each reaction mixture with a reaction vessel. In some embodiments of the invention, several reaction mixtures are temperature-controlled via at least one common temperature control zone In an advantageous embodiment of the invention, the temperature control of at least one reaction mixture takes place over several, but at least two temperature control zones.

In an advantageous embodiment of the invention, the interaction areas between the tempering zones and the tempered reaction mixture are significantly smaller than the total surface of the reaction mixture, in particular> 2 times smaller,> 5 times smaller or> 10 times smaller. In some embodiments of the invention, this permits a process-related adaptation of the overall temperature control zone as an array of small temperature control zones to the shape and size of the reaction mixture to be temperature-controlled or of the associated reaction vessel.

In some embodiments of the invention, there is at least one temperature control zone along or as the vicinity of the contact surface between at least one temperature control element and at least one reaction vessel which contains the reaction mixture to be temperature controlled. Temperature control elements according to the invention with contact surface are, in particular but not exclusively, electrical heating plates and foils, Peltier elements, Heat pumps, heat exchangers or chillers. In an advantageous embodiment of the invention, temperature control elements with a contact surface with at least one reaction vessel have high thermal conductivities and thus allow a high maximum heat transfer compared to insulation zones.

In some embodiments of the invention, there is at least one temperature zone along or as the vicinity of the contact area between a fluid stream caused by at least one temperature element and a reaction mixture or a reaction vessel which contains the reaction mixture to be temperature-controlled. According to the invention, such fluid streams are especially but not exclusively air or other Gas flows as well as flows of liquid coolants or heat conductors. Temperature control elements according to the invention are thus also all fans, turbines or pumps which are operated in combination with devices which enable the fluid flow to be temperature controlled.

In some embodiments of the invention, there is at least one temperature zone along or as the environment of the interaction surface or the interaction volume of thermal radiation (in particular infrared radiation) with at least one reaction mixture or at least one reaction vessel which contains the reaction mixture to be temperature-controlled Temperature control elements according to the invention are therefore also all emitters of thermal radiation, in particular, but not exclusively, heat lamps, infrared LEDs, heating rods and coils or other heat radiators.

According to the invention, various temperature control elements for temperature control of at least one reaction mixture can be combined (for example cooling via Peltier elements, heating by means of infrared emitters).

According to the invention, temperature control elements can be integrated in the shaking platform in order to be continuously shaken with the reaction mixtures. In some configurations of the invention, the temperature control elements are not integrated in the shaking platform, which is particularly advantageous for radiation-based temperature control elements

According to the invention, depending on the heat transfer process used, temperature zones can lie both inside and outside the reaction mixture or the reaction vessel. In the case of outside temperature control zones, the reaction vessel acts as a thermal bridge for the heat transfer between the temperature control zone and the reaction mixture. According to the invention, the heat transfer between the temperature control zone and the reaction mixture can take place both unidirectionally and bidirectionally.

In some embodiments of the invention, cooling and heating of at least one reaction mixture take place via the same at least one temperature control zone or via the same at least one temperature control element. In other embodiments of the invention, temperature control zones or temperature control elements are used, which are each only suitable for cooling or only for heating and for complete temperature control of the reaction mixture can be combined.

In an advantageous embodiment of the invention, only one reaction mixture is assigned to each temperature control zone or each temperature control element

According to the invention, a large temperature control zone can be composed of several individual smaller temperature control zones. According to the invention, a large temperature control element can also be composed of several individual smaller temperature control elements. In an advantageous embodiment of the invention, all temperature zones or Temperature control elements can be regulated independently of one another.

In an advantageous embodiment of the invention, the temperature is controlled in the effective range of at least one tempering zone by measuring the temperature of the respective reaction mixture or reaction vessel. According to the invention, the temperature of the temperature control zone or of the temperature control element itself or of the space between at least two temperature control zones or temperature control elements can also be used for regulation.

In an advantageous embodiment of the invention, each temperature zone or each reaction mixture or reaction vessel is assigned at least one temperature sensor.Temperature sensors in the sense of the invention are all devices which are suitable for generating a signal suitable for controlling at least one temperature zone or at least one temperature element, but in particular not exclusively electrical temperature sensors (shunt, thermocouple, thermopile, temperature-dependent resistors, etc.), radiation sensors, flow sensors, thermometers, bimetallic strips or other stretch marks as well as soft sensors.

According to the invention, the temperature of the reaction mixture, the reaction vessel, the temperature control zones or the temperature control elements is regulated by hardware or software controllers both according to predetermined and time-based or event-based defined setpoints or profiles, and also in feedback on process parameters (e.g. optical density, fluorescence intensity, exhaust air composition) , Viscosity, pH, oxygen concentration, etc.), in particular to those which were recorded in, on or in the vicinity of the reaction mixture to be tempered.

According to the invention, an insulation zone is characterized by a comparatively low maximum achievable heat transfer, so that it can be used advantageously to prevent or limit the heat transfer between at least two reaction mixtures. In the sense of the invention, isolation zones are produced by thermal insulators, in particular, but not exclusively, by air, vacuum, hollow chamber constructions, plastic or ceramic foams, diffusion, convection and radiation barriers, and porous, lightly packed fiber materials. In some embodiments of the invention, the ambient air of the reaction mixtures and reaction vessels acts as an isolation zone. In some configurations of the inventions, temperature control elements or temperature control zones that are switched off or actively counter-regulated are used as insulation zones

In some embodiments of the invention, the heat flows in and around each reaction mixture are recorded and balanced in order to obtain information about the processes taking place in the reaction mixture.

The present invention is explained in more detail with reference to the figures and exemplary embodiments. Reference symbols in the figures, which denote components of the invention that have already been used in the same figure or in another figure under the same circumstances or with the same representation, are partially dispensed with in order to avoid the To maintain clarity and clarity of the figures. Graphic elements without reference numerals are therefore to be interpreted taking into account the list of reference symbols, the other figures, the depicted representations within the same figure, the patterning or structuring of graphical elements that have already been designated, and the entire description and the claims.

Execution examples and figures

FIG. 1 shows a schematic illustration of the process according to the invention with two reaction vessels 1, which are charged with two reaction mixtures 2 to be individually tempered and are separated by an isolation zone 5.

FIG. 2 shows a schematic representation of an embodiment of the device according to the invention for carrying out the method according to the invention for shake flasks and reaction tubes as reaction vessels 1 on an orbital shaker with individually combined arrays of small temperature control elements 9 and temperature control zones 4.

FIG. 3 shows a schematic illustration of an embodiment of the device according to the invention for carrying out the method according to the invention for microtiter plates using infrared lighting for the individual temperature control of each well.

Figure 1 shows a schematic representation of the method according to the invention. Two reaction vessels 1 which are exposed to the same shaking movement 3 are each with different ones Reaction mixtures 2 are charged and are individually temperature-controlled by means of the method according to the invention. For this purpose, each reaction vessel 1 with the reaction mixture 2 contained therein is in the effective range of a separate temperature zone 4, which carries out the temperature control of the assigned reaction mixture 2 individually via a heat transfer 6 between temperature zone 4 and reaction mixture 2

The reaction mixtures 2 in their reaction vessels 1 are at least partially separated by at least one isolation zone 5 in such a way that the maximum achievable heat transfer 7 between the reaction mixtures 2 is lower than the maximum achievable heat transfer 6 between the respectively assigned temperature zone 4 and reaction mixture 2. Also advantageous the tempering zones 4 are separated from one another by at least one insulation zone in such a way that the maximum achievable heat transfer 8 between the tempering zones 4 is lower than the maximum achievable heat transfer 6 between the respectively assigned tempering zone 4 and the reaction mixture 2. According to the invention, this allows an individual and process-optimal tempering of each Reaction mixture 2, without a negative influence on the individual reaction processes by the temperature or temperature of neighboring reaction mixtures 2.

FIG. 2 shows a schematic illustration of an embodiment of the device according to the invention for carrying out the method according to the invention for shake flasks and reaction tubes as reaction vessels 1 on an orbital shaker, which comprises at least one shaking drive 11 and one shaking platform 10; FIG. 2A shows a top view of the shaking platform 10, whereas FIG 2B shows a side view of the embodiment. FIG. 2 contains some schematic simplifications which serve to clarify and better illustrate the features according to the invention. In particular, FIG. 2A omits the representation of the non-existing reaction mixtures 2 in the reaction vessels 1 and the holder for the reaction tubes 14 in order to emphasize the arrangement of the temperature zones 4 and temperature elements 9. Furthermore, for the sake of clarity of illustration in FIG. 2B, the illustration of a complete side view of the arrangement in FIG. 2A is dispensed with and instead only its first row of reaction vessels 1 is shown. The attachment of the reaction vessels 1, in particular the shaking flask, to the shaking platform 10 is also for reasons of FIG Figure clarity is not shown in Figure 2 On a shaking platform 10, which is driven by a shaking drive 11, a plurality of reaction mixtures 2 to be individually temperature-controlled are positioned in different reaction vessels 1. The reaction vessels 1 shown comprise shaking flasks of different sizes and culture tubes. The reaction mixtures 2 in their reaction vessels 1 are all subjected to a common shaking movement 3 via the shaking platform 10. According to the invention, a plurality of temperature control elements 9 are integrated in the shaking platform 10, each of which generates temperature zones 4 which can be regulated separately in their environment, or are used as isolation zones 5 by switching off.

FIG. 2A shows the combination according to the invention of a plurality of temperature control elements 9 or temperature control zones 4 to combined arrays of small temperature control zones 4 and temperature control elements 9. According to the invention, this combination takes place as a function of the size of the reaction vessels 1, as shown in FIG. 2A using the cross sections of the reaction vessels 1 between each Reaction vessel-specific combined temperature zones 4 are further temperature elements 9, which are used as isolation zones 5 by switching off or active counter regulation. According to the invention, the temperature control elements 9 on the shaking platform 10 can be combined with one another to form combined temperature control zones 4 or isolation zones 5, depending on the loading and positioning of reaction vessels 1 with reaction mixtures 2.

The tempering zones can be combined by synchronous control of neighboring tempering elements. If a group of individual temperature control elements is controlled identically, a larger temperature control zone can be formed. An insulation zone can be formed by deactivating individual temperature control elements; the gas phase above is then not heated and thus isolates the adjacent tempering zone.

The reaction vessels 1 with the reaction mixtures 2 contained in them are surrounded by a gaseous phase as the isolation zone 5, which is either designed as ambient air or as an atmosphere regulated with regard to composition, pressure, temperature and humidity. In some embodiments of the invention, this gas phase also functions as Isolation zone 5 and as a weak tempering zone 4, which performs a heat transfer-limited basic tempering of all reaction mixtures 2, which is then individually adapted locally by the tempering elements 9 on the shaking platform 10. FIG. 2B furthermore shows a holder for reaction tubes 14, which in turn has regions with high thermal conductivity as temperature zones 4 and regions with low thermal conductivity as insulation zones 5. In an advantageous embodiment of the invention, the temperature control elements 9 under the holder for reaction tubes 14 are in the position of their temperature zones 4 and isolation zones 5 adjusted

The attachment of the shaking flasks as reaction vessels 1 on the shaking platform 10 is not shown in FIG. 2 for reasons of clarity of the illustration. According to the invention, reaction vessels 1 are attached to the shaking platform 10 with the devices customary for them, so that in an advantageous embodiment of the invention the heat transfer 6 between the temperature zone 4 and the reaction mixture 2 is larger than the heat transfer 7 between at least two reaction mixtures 2. In some embodiments of the invention, the fastening device itself can be used as the temperature zone 4 in order to ensure a suitable heat transfer between at least one temperature element 9 and the reaction mixture 2 via its reaction vessel 1 enable. This applies, for example, to clamps and adhesive mats with which shake flasks are attached to shaking platforms 10. Metallic clips or thermally conductive adhesive mats thus function according to the invention as temperature zones 4, which enable heat transfer between one or more Peltier elements as temperature element 9 and the reaction mixture 2 via their contact surface with the reaction vessel 1. The same applies according to the invention to other devices which are suitable for fastening at least one reaction vessel 1 on the shaking platform 10.

According to the invention, the shaking platform 10 comprises not only the temperature control elements 9 but also temperature sensors 12. In an advantageous embodiment of the invention, the temperature sensors 12 directly record the temperature of the reaction mixture 2 assigned to them, in particular, but not exclusively, by its emitted infrared radiation. In further refinements of the invention, the temperature sensors 12 record the temperature of the reaction vessel 1 assigned to them and thus indirectly the equilibrium the temperature of the reaction mixture 2. In some refinements of the invention, the temperature sensors also record the temperature of the tempering zones 4 or insulation zones 5 or tempering elements 9.

According to the invention, the temperatures detected by temperature sensors 12 become individual control of the temperature control of individual reaction mixtures 2 used in their reaction vessels 1. According to the invention, the detection of temperature gradients between reaction vessels 1, reaction mixtures 2, temperature zones 4, insulation zones 5 or temperature elements 9 enables a particularly precise temperature control. According to the invention, temperature sensors 12 can be attached in a wide variety of levels and positions in order to be able to detect such temperature gradients.

FIG. 3 shows a side view of a schematic representation of an embodiment of the device according to the invention for carrying out the method according to the invention for microtiter plates using infrared lighting for the individual temperature control of each well. According to the invention, a microtiter plate is an array of interconnected reaction vessels 1, each well corresponding to a reaction vessel 1 and filled with a reaction mixture 2 to be heated individually. The microtiter plate is fastened to a shaken shaking platform 10, which is moved by a shaking drive 11, so that all Reaction vessels 1 of the microtiter plate are exposed to a common shaking movement 3.

In order to be able to temper each well separately, the walls of the microtiter plate and thus the walls of the reaction vessels 1 are designed here as insulation zones 5. The temperature of the individual reaction mixtures 2 is therefore not carried out via contact areas, but rather directly by means of radiation-based heat transfer 6 between the temperature control element 9 and reaction mixture 2. FIG. 3 shows a device according to the invention in which infrared radiators (in particular as IR LEDs) are arranged as temperature control elements 9 in a holder 13 with at least a partial field of view of their assigned reaction mixture 2, with at least one infrared radiator individually providing heat as infrared radiation in an assigned reaction mixture 2 transferred.

Analogously to FIG. 2, the reaction vessels 1 with the reaction mixtures 2 contained in them are surrounded by a gaseous phase as an isolation zone 5, which is either designed as ambient air or as an atmosphere which is regulated with regard to composition, pressure, temperature and humidity. In some embodiments of the invention this gas phase simultaneously as an insulation zone 5 and as a weak tempering zone 4, which carries out a heat transfer-limited basic tempering or cooling of all reaction mixtures 2, which is then individually adapted locally by the infrared radiators as tempering elements 9. In some embodiments of the invention, the walls of at least one reaction vessel 1 are partially or completely capable of strongly reflecting or absorbing infrared radiation in order to intensify the heat transfer into the reaction mixture 2 either in the mixture itself or on the heated walls of the reaction vessel 1. According to the invention, this is achieved through the selection of suitable reaction vessel materials, coloring or coatings.

FIG. 3 shows temperature sensors 12 both in the shaking platform 10 and in an additional holder 13. The temperature sensors 12 in the shaking platform 10 primarily determine the temperature of the reaction vessels 1, whereas the temperature sensors 12 in the holder directly determine the temperature of the reaction mixtures 2 assigned to them via their IR - determine emissions. In an advantageous embodiment of the invention, these IR temperature sensors 12 are either optically clearly separated from the temperature control elements 9 or are operated in a modulated manner and matched to the temperature control elements 9. In some embodiments of the invention, these IR temperature sensors 12 are also used to measure and adapt the radiation power of the temperature control elements 9.

In some embodiments of the invention, the holder 13 is also shaken so that there is no relative movement between the reaction vessels 1 and the holder 13. In other embodiments, the holder 13 is fixed externally, so that a relative movement occurs between the reaction vessels 1 and the holder 13 in some embodiments of the invention changes the assignment of the temperature control elements 9 and the temperature sensors 12 to at least one reaction mixture 2 as a result of the relative movement, so that with suitable control, several reaction mixtures 2 can be individually temperature controlled by means of a single combination of temperature control element 9 and temperature sensor 12.

Reference list

1 reaction tube

2 reaction mixture

3 shaking motion

4 tempering zone

5 isolation zone

6 heat transfer between temperature control zone 4 or temperature control element 9 and reaction mixture 2

7 heat transfer between at least two reaction mixtures 2

8 Heat transfer between at least two tempering zones 4

9 temperature control element

10 shaking platform

11 shaker drive

12 temperature sensor

13 holder

14 holders for reaction tubes

Claims

Expectations

1. Process for tempering reaction mixtures (2) in shaking mode,

wherein at least two reaction mixtures (2) are individually tempered in at least two reaction vessels (1),

the same reaction mixtures (2) in the same reaction vessels (1) are subjected to a common shaking movement (3),

characterized,

that the individual temperature control of at least two reaction mixtures (2) via a separate heat transfer (6) between at least one

Reaction mixture (2) and at least one tempering zone (4) assigned to this reaction mixture (2)

2. The method according to the preceding claim,

characterized,

that a plurality of temperature control elements (9) is provided, the

Temperature control elements can be controlled individually.

3. The method according to any one of the preceding claims,

characterized,

that by individually controlling the temperature control elements (9)

Reaction mixtures (2) and / or the tempering zones (4) can be tempered individually.

4. The method according to any one of the preceding claims,

characterized,

that at least two reaction mixtures (2) are separated from one another by at least one insulation zone (5), so that the maximum achievable heat transfer (7) between the at least two reaction mixtures (2) is smaller than the maximum achievable heat transfer (6) between the tempering zone (4) and at least one reaction mixture (2) assigned to it.

5. The method according to any one of the preceding claims,

characterized,

that at least two tempering zones (4) with one another by at least one Isolation zone (5) are separated so that the maximum achievable heat transfer (8) between the at least two temperature control zones (4) is smaller than the maximum achievable heat transfer (6) between each temperature control zone (4) and at least one reaction mixture (2) assigned to it.

6. The method according to any one of the preceding claims,

characterized,

that at least two temperature control zones (4) are combined to form a larger temperature control zone (4) or that at least two temperature control elements (9) are combined to form a larger temperature control element (9).

7. The method according to any one of the preceding claims,

characterized,

that for the combination of temperature zones (4) a first number of, in particular adjacent, temperature elements (9) are controlled identically, while a second number of temperature elements (9) are controlled differently.

8. The method according to any one of the preceding claims,

characterized,

that in order to form an insulation zone (5) one of the insulation zone (5) locally assigned temperature control element (9) is switched inactive.

9. The method according to any one of claims 6 to 8,

characterized,

that, in particular through targeted control of the temperature control elements, the

Combination of tempering zones (4) or tempering elements (9) is adapted to the positioning or shape of reaction vessels (1).

10. The method according to any one of the preceding claims,

characterized,

that the control of at least one temperature control zone (4) or at least one temperature control element (9) takes place on the basis of measurement data collected by at least one temperature sensor (12).

11. The method according to any one of the preceding claims,

characterized, that the control of at least one temperature control zone (4) or at least one temperature control element (9) takes place on the basis of measurement data or information that accompanies the process in, on or in the environment of the temperature control

Reaction mixture (2) were recorded.

12. Device for carrying out the method according to one of the preceding claims, comprising at least two reaction mixtures (2) to be individually tempered in at least two reaction vessels (1),

comprising at least one driven by a shaking drive (11)

Shaking platform (10) on which these reaction mixtures (2) are located

Reaction vessels (1) are exposed to a common shaking movement (3),

that the device has at least two temperature control elements (9) or

Tempering zones (4), each one of the at least two

Reaction mixtures (2) are each assigned to one of the at least two reaction vessels (1) and via which the individual temperature control of at least two

Reaction mixtures (2) takes place

13. Device according to the preceding claim,

characterized,

that the device comprises at least one isolation zone (5) which separates at least two reaction mixtures (2) in such a way that the maximum achievable heat transfer (7) between at least two reaction mixtures (2) is smaller than that of the maximum achievable heat transfer (6) between at least one Temperature control zone (4) and at least one assigned reaction mixture (2).

14. Device according to one of claims 12 and 13,

characterized,

that the device comprises a large number of freely combinable temperature zones (4) or temperature elements (9)