EP1732692A1

EP1732692A1 - Tempering methods and tempering device for the thermal treatment of small amounts of liquid

Info

Publication number: EP1732692A1
Application number: EP05747692A
Authority: EP
Inventors: Andreas Geisbauer
Original assignee: Advalytix AG
Current assignee: Beckman Coulter Inc
Priority date: 2004-05-25
Filing date: 2005-05-24
Publication date: 2006-12-20
Also published as: US20070295705A1; WO2005115624A1; DE102004025538A1

Abstract

The invention relates to tempering methods for performing a defined, particularly a cyclical thermal treatment of small amounts of liquid on substrates. According to the invention, one or several amounts of liquid are applied to a substrate, the substrate is brought in thermal contact with a heating apparatus that is started during heating phases of the thermal treatment, a thermally conductive element whose thermal capacity is greater than or equal to the sum of the thermal capacities of the amounts of liquid, the substrate, and at least the part of the heating apparatus which is in thermal contact with the substrate is brought in thermal contact with the substrate or the heating apparatus during cooling phases of the thermal treatment, and the thermal contact between the thermally conductive element and the substrate is interrupted and the heating apparatus is started during heating phases of the thermal treatment. The invention further relates to a tempering method in which substrates comprising an integrated heating apparatus are used as well as tempering devices that are suitable for carrying out the inventive methods.

Description

Temperature control method and device for the temperature treatment of small amounts of liquid

The invention relates to temperature control processes for carrying out a defined, in particular cyclical, temperature treatment of small amounts of liquid on substrates, temperature control devices and substrates for carrying out the method.

In particular in the case of PCR (polymerase chain reaction) for the duplication of specific DNA sequences, reagents must be subjected to a very defined and special temperature profile. As a rule, it is necessary to heat up and cool the reagents cyclically. It is of great importance for the reproducibility of the course of the reaction that the temperature ramps can be carried out quickly, precisely and reproducibly. For PCR procedures that are carried out in glass capillaries, z. B. used a Röche Light Cycler, in which the glass capillaries are cooled or heated with the help of a temperature-controlled air flow. A corresponding technology is e.g. B. described in US 5,455,175 or US 6,174,670. Other conventional so-called thermal cyclers have metallic recording blocks in which plastic caps or micro-titer plates are recorded with the PCR reagents. The metal block is heated using conventional resistance heating or Peltier elements, which can also be used for cooling. In order to be able to cool the reagent vessels effectively, the metallic receptacle blocks must have a sufficiently large thermal capacity and therefore sufficient thermal mass to be able to dissipate the heat quickly. The cooling of the metallic receiving block is, for. B. with the aid of a strong blower or a Peltier element (US 5,038,852, US 5,333,675). The high thermal mass of the receiving block can lead to temperature gradients which lead to locally different temperature conditions. Another approach to heating / cooling is the use of tempered liquids which are passed through the receiving block (US 5,038,852). Corresponding switching valves and equipment configurations are to be provided.

Recently, microbiological experiments have increasingly been carried out using so-called lab-on-the-chip elements. The reagents are processed on essentially planar substrates of the order of magnitude, as are known from microelectronics, in small amounts of liquid of the order of a few 10 nl to several 100 μl. Reaction vessels can z. B. generated by etched structures on the substrate. A special embodiment provides that the reagents are applied to a planar substrate in the form of drops, which are held together by their surface tension and thus do not require any etched structures. A localization of the drops held together by the surface tension can e.g. B. can be achieved by areas on the substrate surface which are preferably wetted by the reagent liquid and in this respect represent anchor points. Such completely planar substrates have e.g. B. the size of a few mm ² to a few cm ² .

To such planar substrates such. B. in the form of a slide a corresponding temperature cycle, for. B. to carry out PCR reactions pulling, starting from the conventional thermocyclers, adapter blocks are necessary, which make the metallic mounting blocks of the conventional cyclers planar. These adapter blocks increase the thermal mass of the metal receiving blocks. The resulting thermal offset must be determined using a calibration factor to correct the PCR parameters.

The high thermal load of conventional thermal cyclers limits the possible sample throughput due to long cycle times.

The object of the present invention is to specify temperature control methods and temperature control devices with the aid of which a defined, in particular cyclical, temperature treatment of small amounts of liquid on essentially planar substrates is made possible, which enables a precise and reproducible temperature profile with a simple construction.

This object is achieved with temperature control processes with the features of claim 1 or claim 3 and temperature control devices with the features of claim 13 or claim 17. Subclaims are directed to preferred embodiments.

In a first temperature control method according to the invention, one or more quantities of liquid are applied to a preferably essentially planar substrate. The amounts of liquid are on the substrate z. B. held together by their surface tension or are in etched receptacle contours or separate containers and generally each comprise a few 10 nl to a few 10 μl. The substrate is preferably planar on the underside and likewise essentially planar on the upper side, with the exception of the possibly etched receiving contours. The substrate can e.g. B. be a glass slide or from other substrate material such. B. Lithium niobate exist. The amounts of liquid can e.g. B. applied in etched receiving structures or small containers on the substrate. It is particularly simple if the individual amounts of liquid are applied to the surface of the substrate in the form of drops, which generally comprise a few 10 nl to a few 10 μl.

The substrate is brought into thermal contact with a heating device which is put into operation during the heating-up phases of the temperature treatment. The substrate with the amounts of liquid is therefore in constant thermal contact with the heating device, which, however, is only in operation during the heating phases.

During the cooling phases of the temperature treatment, a heat-conductive element is brought into thermal contact with the substrate and / or the heating device, the heat capacity of which is greater than or equal to the sum of the heat capacities of the quantities of liquid, the substrate and at least that part of the heating device which is in thermal contact with the substrate.

To cool the amounts of liquid, both the substrate and the heating device are cooled. This is done by thermal contact with a thermally conductive element, which due to its heat capacity can effectively dissipate the heat of the heating device and the substrate. This thermally conductive element is only in thermal contact during the cooling phases and therefore does not have to be heated during the heating phases. Due to the simple design of the carrier element for the small amounts of liquid, that is, the substrate, the heat capacity of the elements to be cooled is small due to the low thermal mass. The thermally conductive element for cooling during the cooling phases can therefore also have a lower thermal mass, so that it can also be cooled again quickly and easily.

During the heating-up phases of the temperature treatment, the thermal contact between the thermally conductive element and the substrate is interrupted and the heating device is put into operation. With the method according to the invention, it is not necessary to cool the heating device and / or the substrate directly with a blower, which would require high flow rates. The thermally conductive element acts like a heat sink and acts as an effective mediator for releasing the heat to the environment. The contact between the thermally conductive element and the heating device or the substrate can take place at definable time intervals, so that a defined amount of heat can flow away from the substrate and the heating device. The defined heat transfer is guaranteed by the special selection of the heat capacity.

With the tempering process according to the invention, for. B. PCR in small volumes with high heating and cooling rates possible, with the advantage of minimizing non-specific reactions during the heating and cooling phases and the process time. The planar approach to PCR enables very specific reactions by rapidly breaking down temperature gradients by convection.

The inventive method allows the use of e.g. B. transparent substrates that allow an optical examination during or after the reaction in a simple manner. The use of planar substrates increases the compatibility of the temperature control process with lab-on-the-chip applications.

The temperature control process according to the invention can be carried out particularly easily if the substrate is simply placed on a heating device, for. B. on a hot plate, so as to make the thermal contact, and the thermally conductive element during the cooling phase with the heating device, for. B. the heating plate is brought into thermal contact.

Another embodiment of the method according to the invention uses a substrate which comprises an integrated heating device. In such an embodiment of the method according to the invention, the one or more amounts of liquid are applied to the substrate with the integrated heating device. During the cooling phases of the temperature treatment, a thermally conductive higes element brought into thermal contact with the substrate, the heat capacity is greater than or equal to the sum of the heat capacities of the amounts of liquid and the substrate. During the heating phase of the temperature treatment, the thermal contact between the thermally conductive element and the substrate is interrupted and the heating device is put into operation.

The heater integrated on the substrate can e.g. B. a resistance heater, which preferably comprises a vapor-deposited metal conductor of high resistance. The heating energy is coupled into this resistance heater with the aid of a power source. Another embodiment provides an induction heater into which energy is injected with the help of induction.

While a temperature control process using a substrate without an integrated heating device enables the use of simple and inexpensive substrates, the use of substrates with an integrated heating device ensures the optimal thermal coupling of the heating device to the amount of liquid.

While the thermally conductive element is not in thermal contact with the substrate or the heating device, it absorbs the heat absorbed. This can e.g. B. with the help of cooling liquids, an air flow or a Peltier element. It is particularly simple and advantageous if the thermally conductive element is in thermal contact with a heat sink when it is not connected to the heating device or the substrate. The amount of heat absorbed by the thermally conductive element during the cooling phase can then emit the absorbed heat to the heat sink during this contact phase. In particular, this can happen while the substrate is being heated by the heating device during a heating phase. The thermally conductive element therefore gives off the heat it has absorbed during the cooling phase to the cooling body until the start of the next cooling phase. The heat sink itself can in turn z. B. by a cooling liquid, by an air flow or by a Peltier element, the simplest and most advantageous z. B. cooled by cooling fins. The heat transfer between the substrate or the heating device and the thermally conductive element on the one hand and between the thermally conductive element and the heat sink on the other hand can be achieved by using coupling media, e.g. As glycerin, can be further improved.

The amounts of liquid, preferably drops, can on the planar substrate z. B. applied in flat etched receiving structures. A process in which the amounts of liquid in the form of drops are held together only by their surface tension is particularly simple and easy to process. For this purpose, the wetting properties of the surface of the substrate are selected such that the drops do not flow apart due to their small volume and their surface tension properties. In order to localize the drops at desired locations, areas can also be provided on the substrate which are preferably wetted by the liquid and in this respect represent anchor points for the liquid drops. Wetting-modulated surfaces of this type can be produced in a simple manner using lithographic processes. For processing aqueous solutions z. B. the surface areas outside the anchor points have been made hydrophobic by a silanization process.

To protect against evaporation during heating, the drops in the amount of liquid can be covered with oil.

In particular, the temperature control method according to the invention is suitable for temperature cycles above room temperature, since it is here that the amount of heat absorbed can be released directly from the thermally conductive element or from the heat sink. The temperatures to be set are higher than room temperature, particularly for the advantageous application of the temperature control method according to the invention for PCR products. A first temperature control device according to the invention has a heating device and a holding device for a preferably essentially planar substrate, which enable the substrate to be stored in thermal contact with the heating device. Furthermore, a thermally conductive element is provided which can be brought into thermal contact with a substrate held by the holding device or with the heating device, the heat capacity of the thermally conductive element being greater than the sum of the heat capacities of the substrate and the heating device. Furthermore, the temperature control device according to the invention has a movement device which is designed such that it can bring the thermally conductive element into thermal contact with the substrate or the heating device.

The temperature control device according to the invention is particularly suitable for carrying out the temperature control method according to the invention. The movement device enables the thermally conductive element to be brought into contact with the substrate and / or the heating device. The selection of heat capacities according to the invention enables the removal of defined amounts of heat. The advantages of the temperature control device according to the invention also result in particular from the advantages of the temperature control method to be carried out with it.

In a particularly advantageous development of the temperature control device according to the invention, the holding device is formed directly by the heating device, in particular by a heating plate. The heating device can then serve directly as a support for the substrate, so that the thermal contact between the substrate and the heating device has already been established. Separate holding devices in addition to the heating device are then not necessary. The design with a hot plate, for. B. a silicon heating plate. Silicon offers itself because of its good and inexpensive availability. It has a high thermal conductivity, which enables a high heat dissipation or supply from or to the substrate. In other embodiments, a transparent material such as e.g. B. lithium niobate used as a hot plate with the z. B. an optical detection of the course of the reaction from below is possible.

Another temperature control device according to the invention has a holding device for a substrate, which has an integrated heating device. The temperature control device also has an energy supply device, with the aid of which energy can be coupled into the heating device of the substrate in order to heat it. A thermally conductive element is provided which can be brought into thermal contact with a substrate held by the holding device and whose heat capacity is greater than the heat capacity of the substrate. Finally, this temperature control device according to the invention also has a movement device which is designed such that it can bring the thermally conductive element into thermal contact with the substrate.

Such a temperature control device according to the invention can be used similarly to the temperature control device already described. It can e.g. B. substrates are used in which a metallic resistance heater is preferably vapor-deposited on the underside. A temperature control device provided for the use of such substrates has contact devices which come into contact with the resistance heater when the substrate is placed on it. The energy supply device of the temperature control device is in this case, for. B. a current source, with the help of which current can be sent through the resistance heater through the contact devices. Other temperature control devices have devices by means of which energy can be inductively coupled into an induction heater applied to the substrate. The function and advantages of the thermally conductive element and the movement device of the temperature control device have already been explained above.

A movement device that includes an electromagnet is simple and precise to control. As a thermally conductive element for removing the heat from the substrate or the heating device, a block of thermally conductive material, for. B. made of metal, in particular aluminum or copper. According to a particular embodiment, a heat sink is provided with which the thermally conductive element can be brought into thermal contact in order to dissipate the amount of heat absorbed by the substrate or the heating device. A metal block, in particular made of aluminum or copper, is suitable as the heat sink, which advantageously has a heat capacity that is greater than the heat capacity of the thermally conductive element. Either alternatively or additionally, the heat sink can comprise cooling fins that ensure effective heat dissipation to the environment. The heat flow can be calibrated in preliminary tests. In a preferred embodiment, a temperature measuring element is provided which can optionally be used to regulate the temperature control processes.

A controller, in particular a microprocessor controller, can be provided for this purpose.

Because of the precise temperature cycles possible with the temperature control device according to the invention or the temperature control method according to the invention, the method according to the invention and the device according to the invention are particularly suitable for PCR applications.

Independent protection is claimed for substrates with integrated heating devices for use with a temperature control device according to the invention, in particular a substrate with a, preferably vapor-deposited resistance heating device and a substrate with a, preferably vapor-deposited induction heating.

The invention is explained in detail with reference to the accompanying figures. It shows: FIG. 1: a schematic side sectional view of an embodiment according to the invention in a first process state when carrying out a method according to the invention,

Figure 2: the device of Figure 1 in a second process state, and

FIG. 3: a temperature cycle that can be carried out with the method according to the invention.

In Figure 1, the substrate is designated 1. There are drops 3 of a reaction liquid in which, for. B. a PCR reaction is to take place. The drops 3 are covered with an oil film 5 and are held together by their surface tension. If appropriate, there are hydrophilic anchor points on the substrate 1 in relation to their surroundings, which cause the drops 3 to be localized. The entire arrangement lies on the heating plate 7.

As substrate materials such. B. polished silicon, especially when used for PCR. It has a high thermal conductivity, which can effectively conduct the heat generated with the heating plate 7 to the drops 3. Other possible substrates are e.g. B. coated with silicon dioxide lithium niobate, glass or glass coated with silicon dioxide.

The heating plate consists, for. B. made of silicon. Not shown is a temperature sensor, e.g. B. a platinum resistance thermometer. On the silicon hot plate, for. B. a thin-film heater made of nickel. The temperature sensor can e.g. B. with the help of thin-film technology also be integrated on the heating plate 7. The heating plate then carries a passivation, which is intended to prevent the sensor material from oxidizing during operation and thus moving away from the original calibration data.

13 shows a schematic representation of a lifting magnet for lifting a plunger 15 together with the thermally conductive element 9. B. a copper block. For example, when using a silicon substrate of size 20 x 20 x 0.5 mm ³ , a copper stamp with a mass of 12 g can be used. 11 denotes a copper storage block with an exemplary mass of 800 g. The lifting magnet 13 is designed such that movement of the copper block

9 from the position shown in FIG. 1 to the position shown in FIG. 2 is possible. While in FIG. 1 the copper block 9 is in thermal contact with the heating plate 7 and there is an air gap between the copper block 9 and the copper storage block 11

10, the copper block 9 is in thermal contact with the storage block 11 in FIG. 2 and there is an air gap 8 between the copper block 9 and the heating plate 7. FIG. 17 shows cooling fins which serve to cool the storage block 11.

The embodiment can be used as follows. First, the liquid drops are applied to the substrate, in which, for. B. the PCR reaction is to take place. To protect against evaporation, an oil film 5 is placed over the liquid drops 3. The substrate prepared in this way is placed on the heating plate 7. In order to heat the substrate, the silicon heating plate 7 is heated with the resistance heating (not shown).

After a corresponding heating step, the heating plate 7 is switched off for cooling and thermal contact of the heating plate 7 with the copper block 9 is generated. For this purpose, the copper block 9 is brought up into the position of FIG. 1 with the aid of the lifting magnet 13 and the stamp 15. Due to the greater heat capacity, the copper block 9 absorbs heat from the heating plate 7 and the substrate 1 and thus leads to their cooling. After the heat has been absorbed, the copper block 9 is moved back into the position of FIG. 2, in which it is in thermal contact with the copper storage block 11. For this, z. B. the winding of the electromagnet 13 de-energized. In the position of FIG. 2, the copper block 9 can effectively transfer the absorbed heat to the copper storage block 11. This is effectively cooled with the help of the cooling fins 17 and thus enables the heat from the copper block 9 to be dissipated quickly. While the heat is transferred from the copper block 9 to the copper storage block 11, the next heating process of the substrate 1 with the liquid drops 3 can already take place by the Heating plate 7 is heated. In the position of FIG. 2, the air gap 8 prevents heat transfer from the heating plate 7 to the copper block 9. In this way, a sharp and defined temperature profile can be generated, as z. B. is visible in Figure 3 and can be used to carry out PCR reactions.

The movement of the copper block 9 with the aid of the electromagnet 13 and the operation of the heating plate 7 can be controlled by control electronics which use the signal from the temperature sensor (not shown in the figures) on the heating plate 7. The necessary heating power of the heating plate 7 or the time that the copper block must remain in contact with the heating plate in order to generate the desired temperature profiles can be determined in preliminary tests or estimated from the thermodynamic parameters.

The described embodiment has the advantage that the heating plate can be easily loaded with substrates and the reagents on them. The substrates can be loaded with reagents outside the device. After the temperature treatment, they are easily accessible for analysis. The substrates can be used as disposable.

An embodiment, not shown, enables the use of substrates with an integrated heating device. In this case, no heating device is provided on the temperature control device, but a simple holder for the substrate. The substrate itself has e.g. B. a vapor-deposited resistance heater, which comes into contact with contact devices when the substrate is placed in the temperature control device, which are connected to a power source. To heat the substrate in the position according to FIG. 2, current is then conducted through the resistance heating of the substrate with the aid of this current source through the contact devices in order to heat the latter. Alternatively, an induction heater can be provided on the substrate, which can be heated by inductive coupling of energy. The operation of such embodiments is otherwise analogous to the mode of operation explained with reference to FIGS. 1 and 2.

Claims

claims

1. temperature control process for carrying out a defined, in particular cyclical temperature treatment of small amounts of liquid, in which one or more amounts of liquid are applied to a substrate (1), the substrate (1) is brought into thermal contact with a heating device (7), which during heating phases of the Heat treatment is put into operation, while cooling phases of the temperature treatment are brought into thermal contact with the substrate or the heating device (7), the heat capacity of which is greater than or equal to the sum of the heat capacities of the liquid quantities (3), of the substrate (1) and at least that part of the heating device (7) which is in thermal contact with the substrate, and during the heating phases of the temperature treatment the thermal contact between the thermally conductive element (9) and the substrate (1) is interrupted and the heating device (7) is put into operation.

> Temperature control method according to Claim 1, in which the substrate is placed on the heating device (7) and the thermally conductive element (9) is brought into thermal contact with the heating device (7) during the cooling phases.

5.Tempering process for carrying out a defined, in particular cyclical, temperature treatment of small amounts of liquid, in which one or more amounts of liquid are applied to a substrate, the substrate having a heating device, while cooling phases of the temperature treatment bring a thermally conductive element into thermal contact with the substrate, the Heat capacity is greater than or equal to the sum of the heat capacities of the quantities of liquid and the substrate, and during the heating-up phases of the temperature treatment the thermal contact between the thermally conductive element and the substrate is interrupted and the heating device is put into operation.

! •. Temperature control method according to claim 3, in which a substrate is used which has an integrated resistance heating device, preferably a vapor-deposited resistance heating device.

5. Temperature control method according to claim 4, in which the substrate is brought into contact with contact devices, with the aid of which a current can be passed through the resistance heating device.

6. Temperature control method according to claim 3, in which a substrate is used which has an inductive heating device.

7. Temperature control method according to one of claims 1 to 6, in which an essentially planar substrate (1) is used.

8. Temperature control method according to one of claims 1 to 7, in which the one or more liquid quantity (s) in the form of drops (3) are applied to the substrate (1).

9. Temperature control method according to claim 8, in which the drops (3) are dimensioned and the wetting properties of the surface of the substrate (1) are selected such that the drops (3) on the surface of the substrate (1) are held together by their surface tension.

10. Temperature control method according to one of claims 8 or 9, wherein the one or more amounts of liquid, which are applied in the form of drops (3) on the substrate (1), are each coated with an oil film (5) in order to evaporate the one or several amounts of liquid (3) to prevent.

11. Temperature control method according to one of claims 1 to 10, in which the one or more amounts of liquid (3) on the substrate (1) are applied to anchor points which, in comparison to their surroundings on the substrate (1), have a surface texture which is suitable for preferred wetting leads through the one or more amounts of liquid (3).

12. Temperature control method according to one of claims 1 to 11, wherein the heat absorbed by the thermally conductive element (9) during a cooling phase is given off to a heat sink (11, 17) when the thermally conductive element (9) is not in thermal contact with the Substrate (1) is.

13. Temperature control device for carrying out a defined, in particular cyclical, temperature treatment of small amounts of liquid on substrates, which has the following: a heating device (7), a holding device for a substrate (1), which supports the substrate (1) in thermal contact with the heating device ( 7) enables a thermally conductive element (9) which can be brought into thermal contact with a substrate (1) held by the holding device or with the heating device (7) and whose heat capacity is greater than the sum of the heat capacities of the substrate (1) and Is heating device (7), and a movement device (13, 15) which is designed such that it can bring the thermally conductive element (9) with the substrate (1) or the heating device (7) into thermal contact.

14. Temperature control device according to claim 13, wherein the holding device is formed by the heating device (7).

15. Temperature control device according to one of claims 13 or 14, wherein the heating device comprises a heating plate (7).

16. Temperature control device according to claim 15, wherein the heating device comprises a silicon heating plate (7).

17. Temperature control device for carrying out a defined, in particular cyclical, temperature treatment of small amounts of liquid on substrates, which has the following: a holding device for a substrate which has an integrated heating device, an energy supply device, with the aid of which energy can be coupled into the heating device of the substrate for heating it , a thermally conductive element which can be brought into thermal contact with a substrate held by the holding device and whose heat capacity is greater than the heat capacity of the substrate, and a movement device which is designed such that they bring the thermally conductive element into thermal contact with the substrate can.

18. Temperature control device according to claim 17, in which the holding device is designed such that it can store a substrate with a preferably vapor-deposited electrical resistance heater, and the energy supply device comprises a power source and contacts connected thereto, which with the storage of the substrate in the holding device Resistance heating are in contact.

19. Temperature control device according to claim 17, in which a substrate with an induction heater can be used and the energy supply device comprises a device for coupling energy into the induction heater.

20. Temperature control device according to one of claims 13 to 19, wherein the holding device is designed to hold an essentially planar substrate (1).

21. Temperature control device according to one of claims 13 to 20, wherein the movement device comprises an electromagnet (13).

22. Temperature control device according to one of claims 13 to 21, wherein the thermally conductive element comprises a block (9) made of thermally conductive material, in particular aluminum or copper.

23. Temperature control device according to one of claims 13 to 22 with at least one heat sink (11, 17), wherein the movement device (13, 15) is designed such that it thermally conductive element (9) with the heat sink (11, 17) Can bring in contact.

24. Temperature control device according to claim 23, wherein the heat sink comprises a block (11) made of thermally conductive material, in particular aluminum or copper with a greater heat capacity than that of the thermally conductive element (9).

25. Temperature control device according to one of claims 23 or 24, wherein the cooling body comprises cooling fins (17).

26. Temperature control device according to one of claims 13 to 25 with a Peltier cooling element, a liquid cooling or an air flow cooling.

27. Temperature control device according to one of claims 13 to 26 with a temperature measuring device.

28. Temperature control device according to one of claims 13 to 27 with a control, preferably a microprocessor control for the automatic control of the heating device (7) and the movement device (13, 15).

29. Temperature control device according to claims 27 and 28, in which the control is designed such that it uses the signal of the temperature measuring device as a control variable for controlling the heating device (7) and the movement device (13, 15) to generate a desired temperature profile.

30. A substrate with a preferably vapor-deposited resistance heating device for use in a temperature control device according to claim 18.

31. A substrate with a preferably vapor-deposited induction heater for use in a temperature control device according to claim 19.

32. Use of a temperature control method according to one of claims 1 to 12 or a temperature control device according to one of claims 13 to 29 for PCR (polymerase chain reactions) applications.