WO2000029115A1 - Dispositifs et procedes de temperage d'echantillons - Google Patents

Dispositifs et procedes de temperage d'echantillons Download PDF

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Publication number
WO2000029115A1
WO2000029115A1 PCT/EP1999/008550 EP9908550W WO0029115A1 WO 2000029115 A1 WO2000029115 A1 WO 2000029115A1 EP 9908550 W EP9908550 W EP 9908550W WO 0029115 A1 WO0029115 A1 WO 0029115A1
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WO
WIPO (PCT)
Prior art keywords
temperature
heating
cooling
heat exchanger
circuit
Prior art date
Application number
PCT/EP1999/008550
Other languages
German (de)
English (en)
Inventor
Thomas Altmann
Dietmar Kropp
Ulrich Schneider
Heinrich SPÖNTJES
Toralf Eifrig
Original Assignee
MAX-PLANCK-Gesellschaft zur Förderung der Wissenschaften e.V.
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Publication date
Application filed by MAX-PLANCK-Gesellschaft zur Förderung der Wissenschaften e.V. filed Critical MAX-PLANCK-Gesellschaft zur Förderung der Wissenschaften e.V.
Priority to AU13813/00A priority Critical patent/AU1381300A/en
Publication of WO2000029115A1 publication Critical patent/WO2000029115A1/fr

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L7/00Heating or cooling apparatus; Heat insulating devices
    • B01L7/52Heating or cooling apparatus; Heat insulating devices with provision for submitting samples to a predetermined sequence of different temperatures, e.g. for treating nucleic acid samples
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D23/00Control of temperature
    • G05D23/01Control of temperature without auxiliary power
    • G05D23/13Control of temperature without auxiliary power by varying the mixing ratio of two fluids having different temperatures
    • G05D23/1393Control of temperature without auxiliary power by varying the mixing ratio of two fluids having different temperatures characterised by the use of electric means

Definitions

  • the invention relates to devices for tempering a liquid bath, in particular for tempering a large number of samples within a reaction container and tempering method.
  • thermostats It is generally known to use temperature control devices in the form of controllable thermostats to set the temperature of samples or materials or to regulate them according to a certain time pattern or to set certain thermal reaction conditions in a sample room.
  • a thermostat usually includes an aquarium bath that is in thermal contact with a heating and cooling device and has a temperature sensor. Depending on the deviation of the temperature value measured with the temperature sensor from a target value, the heating or cooling devices are actuated to heat or cool the water bath.
  • the specific structure of a thermostat depends on the desired application. Recently there have been new requirements for the temperature control of samples or the like in medicine, biochemistry and genetic engineering. m related to the speed, accuracy and reproducibility of the temperature setting, which can no longer be achieved with conventional thermostats.
  • thermostable reactions examples include the polymerase or ligase chain reaction (PCR or LCR processes) for the multiplication of a nuclear acid sequence using certain thermostable enzymes.
  • PCR processes in particular require the cyclical setting of certain sample temperatures for certain reaction or tempering times.
  • immersion PCR It is generally known to carry out PCR processes in an immersion bath (immersion PCR).
  • immersion PCR has the disadvantage that temperature gradients occur in the water bath, by means of which the PCR conditions cannot be reproduced sufficiently and can be set precisely.
  • a temperature control device has a structure with a reaction vessel, a heating element, a cooling coil and a large number of temperature sensors, as is known, for example, from WO 90/05329.
  • a programmable control system enables rapid heating and cooling and the cyclical setting of a temperature profile.
  • the basic disadvantages of conventional thermostats are not overcome. These disadvantages manifest themselves in particular in the fact that, in the case of a large volume (approximately 1 to 2 liters) of the reaction vessel, the temperature setting is too slow and too imprecise for numerous biochemical applications and is associated with the setting of a temperature gradient (inhomogeneous temperature control).
  • the reaction vessels are characterized by a high water consumption.
  • the new devices are intended in particular to provide fast, enable accurate, reproducible and energy-saving temperature settings.
  • the object of the invention is also to provide an improved temperature control method with which the temperature grading can be improved and / or the sample throughput can be increased.
  • a nozzle heat exchanger which simultaneously forms a flow for a temperature control medium and a sample holder.
  • the reaction vessel comprises a trough and the nozzle heat exchanger and is provided with a flow and a return for connection to a circulating media circulation (for example to the media circuits mentioned above) and is set up inside for a media circulation with reversal of the flow direction.
  • a circulating media circulation for example to the media circuits mentioned above
  • the medium is first directed past the samples in a first direction, then deflected in a deflection area and finally directed past the samples in the opposite direction.
  • the medium that enters the flow with a certain deviation from the target temperature and exits with an opposite deviation at the return after thermal contact with the samples will exert an essentially balanced and homogeneous temperature control effect on the samples.
  • the sample temperature is too low, medium with an elevated temperature is supplied.
  • the samples near the lead are heated more strongly than the samples at a distance from the lead (e.g. at the steering area), however, when flowing back to the return, the samples are warmed more strongly than the samples at the feed, due to the then still higher media temperature.
  • the balancing effect of the flow principle according to the invention is thus achieved.
  • a temperature control method is created in particular, in which the energy-transporting medium is directly connected to two media circuits which are set up to set different temperatures and represent, for example, a heating and a cooling circuit, the temperature in a reaction vessel or a bath or at a sample location by means of optionally operable locking devices and heating or cooling devices in the media circuits.
  • a reaction vessel is an arrangement that can be tempered with the medium and is set up to hold at least one sample. With the locking devices and heating or cooling devices, the medium at the sample location can be adjusted from the circuits as a precisely metered mixture of certain amounts of media with certain temperatures.
  • the invention also provides a new type of regulation for a temperature control process.
  • the control is aimed at setting a medium, the temperature of which can be adjusted with a heating and a cooling circuit, to a specific target temperature.
  • a total of four controllers are provided for this purpose, which are actuated as a function of the deviation of the sample temperature from the target temperature. They include a main controller that is set up to operate the heating or cooling circuit, a cooling controller that is set up to reduce the sample temperature during the control, a heating control set up to increase the sample temperature during the control, and a pump controller , with which the amount of media passing through a reaction container or a bath or a sample location is set.
  • a temperature control device consists, according to the above-mentioned principle of metering the energy-transporting medium, of adjustable proportions from media circuits of different temperatures, in particular from the reaction vessel mentioned, which is equipped with a flow and a return as part of one of the two media circuits with locking devices and a heating or cooling device, the flow and the return are each connected to the second media circuit via further locking devices.
  • the first media circuit is preferably a heating circuit, which thus leads from the flow via the reaction tank, the return, a pump device, a blocking device and a heating device back to the flow.
  • the second media circuit is then a cooling circuit, which contains a pumping device and a cooling device and can be connected to the forward or return flow via blocking devices.
  • the invention is not limited to this design. Rather, a design is also possible in which the first media circuit is the cooling circuit and the second media circuit is the heating circuit.
  • the temperature control device for implementing such a flow control is preferably designed as a nozzle-type heat exchanger in the reaction vessel, the line system of which simultaneously serves to guide the medium and to hold the sample.
  • the invention has the following advantages. For the first time, a reaction container with a significantly increased volume (up to 8 1) is created, which temperature-regulates samples in accordance with the requirements in biochemistry, medicine and genetic engineering in terms of accuracy, reproducibility decorability and speed of temperature adjustment met. A high level of energy efficiency, flexibility and speed are achieved when approaching certain temperature holding points.
  • the reaction vessel or heat exchanger according to the invention does not require a lead time due to the device.
  • the tempering process can be started directly without pre-tempering the temperature circuits. Due to the speed of the temperature setting, the temperature of the sample is particularly gentle, since the time during which the sample is close to the desired reaction temperature and the first reactions may already be unreproducible or undesirable is shortened.
  • the samples can remain in the reaction container. Flooding in the temperature setting is avoided.
  • the invention is not restricted to specific applications. It is possible to adapt different types of samples or to use them in other technical areas (e.g. material testing) where rapid temperature changes are important.
  • the device according to the invention can be easily operated and maintained.
  • the invention can be implemented with a wide variety of temperature control media (eg water, 01).
  • the reaction container according to the invention has an expanded area of application, to which materials adapted to the desired application are used as temperature control media. High temperatures can also be reached without the need for a pressure vessel.
  • 1 shows a schematic overview of a temperature control device according to the invention
  • 2 shows a block diagram to illustrate the control according to the invention
  • Fig. 4 is a graph to illustrate the
  • Fig. 5 is a schematic perspective view of an inventive nozzle heat exchanger.
  • a temperature control device consists of a reaction container 10 which is part of a heating circuit 20 and is connected to a cooling circuit 30.
  • the reaction container 10 comprises a trough 11, in which a heat exchanger 12 (for details see FIG. 5) with sample receptacles 13 is arranged and which is connected to a fullness measurement 19.
  • the inlet-side connection of the heat exchanger 12 and the outlet-side connection of the trough 11 form the flow 14 and the return 15 of the reaction container 10.
  • Several temperature sensors are provided on the reaction container 10. These include the flow sensor 16, the sample sensor 17 and the return sensor 18.
  • the sensors are, for example, resistance temperature sensors (eg PT 100), but can also be thermocouples or based on other measuring principles.
  • the flow and return sensors record the media temperature in the flow or return with a distance of approx. 3 to 5 cm from the reaction container 10.
  • the invention is not restricted to the form of the reaction container 10 described here with the heat exchanger 12 inserted, but can also be used with differently designed reaction containers, for example in the form of a flow trough or a closed heat exchanger. exchangers in which the samples do not come into contact with the energy-transmitting medium.
  • the heating circuit 20 (circulation in the direction of the arrow) comprises the reaction container 10, a dynamic pump 21, a locking device which is formed by the first solenoid valve 22 (MV 2), and a heating device in the form of a continuous-flow heater 23 with a heating temperature limiter 24.
  • the dynamic pump 21 is a circulation pump which is used for the stepless speed setting, eg in the range from 0 to 3000 U / mm.
  • the instantaneous water heater 23 and the first solenoid valve 22 there are em pump regulators 54, heating regulators 55 and cooling regulators 56 (enabling the first solenoid valve 22), the functions of which will be explained with reference to FIG. 2.
  • the cooling circuit 30 simultaneously has the function of cooling and a buffer reservoir and comprises a static pump 31 which is set up for the permanent circulation of the medium in the cooling circuit 30, a filter 32 (particle filter), at least one buffer store 37 and two refrigeration machines 33a, 33b that act as cooling directions.
  • the cooling circuit 30 also has a branching point between the static pump 31 and the first cooling device 33a, from which there is a connection via the second solenoid valve 35 (MV 1) to a branching point between the instantaneous heater 23 and the flow 14 in the heating circuit.
  • a further branching point is provided between the second cooling device 33b and the static pump 31 in the cooling circuit 30, from which a connection via a third solenoid valve 36 (MV 2) to the heating circuit 20 at a branching point between the dynamic pump 21 and the first solenoid valve 22 consists.
  • the cow devices 33a, 33b (refrigeration machines) are each equipped with a thermostat 34a, 34b.
  • the thermostats 34a, 34b sense the temperature of the circulating medium with sensors and actuate the cooling devices 33a, 33b to set a predetermined, fixed temperature.
  • the entire system shown in FIG. 1 is filled with an energy-transporting medium.
  • This medium is preferably water, but can also be formed depending on the application by a suitable salt solution (reduction of lime deposits, improvement of the heat conduction) or by a light oil or a transformer oil.
  • the system is filled z. B. by external filling of the tub 11 with the third solenoid valve 36 open, pumps 21, 31 running and the first and second solenoid valves 22, 35 closed until the buffer tank 37 leaks water at the vent connection, or via a separate feed connection (not shown) .
  • the performance parameters of the heating and cooling circuits are selected depending on the application.
  • the cooling devices 33a, 33b can also be replaced by a single cooling device with a correspondingly higher cooling capacity, which, however, can be disadvantageous in terms of energy consumption and operational safety.
  • Fig. 1 also shows an additional ventilation cooler 40, which is provided for the immediate cooling of the instantaneous water heater 23 by taking up surface heat. Any suitable ventilator with sufficient power (for example a control cabinet ventilator) can be used as ventilation device 40.
  • FIG. 1 also schematically shows a control device 50 with a sequence control 51, a protection control 52, a main controller 53 (so-called ECO controller), the pump controller 54, the heating controller 55, the cooling controller 56, actuating elements 57 and a display 58.
  • the elements of the control device 50 are explained below with reference to FIG. 2.
  • the sequence controller 51 provides the control signals which represent the specific sequence of a temperature control process. Accordingly, the sequence control 51 has an input 51 ⁇ , via the process parameters, such as a sequence of target temperatures T s , n , which are to be repeatedly set for N temperature cycles for certain temperature control times t n , and the sample temperature T P from the sample probe 17 (see FIG 1) can be entered. At the output 51o, the sequence controller 51 accordingly sends set values x s to the controller and an off signal to the protective controller 52.
  • the protection control 52 receives at the input 52 ⁇ a series of operationally relevant switching signals, which relate to the state of the unit, the system filling, an emergency shutdown and the like, and the off signal of the sequence control 51.
  • a series of operationally relevant switching signals which relate to the state of the unit, the system filling, an emergency shutdown and the like, and the off signal of the sequence control 51.
  • the output 52o of the protection control 52 are the stationary pump 31 of the cooling circuit 30 (see FIG. 1) and second to Receiving an Em signal, the controller main controller 53 and pump controller 54 connected.
  • the main controller 53 receives the on signal from the protection controller 52 as a release, and the current setpoint x s and the current sample temperature T P at the input 53 ⁇ .
  • the main controller 53 is set up to switch on the heating or cooling controllers 55, 56 or to assume a zero position as a function of the value of the sample temperature T P in relation to the target temperature T s via the output 53o m.
  • the pump controller 54 receives the on signal from the protection control 52 as a release, and the current setpoint x s and the current return temperature T RL at the input 54 ⁇ .
  • the pump controller 54 provides a voltage signal (for example in the range from 0 to 10 volts) at the output 54o, which is applied as an input signal to a frequency converter 54a with which the dynamic pump 21 (see FIG. 1) is controlled. If the setpoints and actual values on the pump controller 54 match, the frequency converter 54a sets a predetermined fixed speed on the dynamic pump 21 em depending on the application.
  • the heating control 55 receives the Em signal from the protection controller 52 as a release, and at the input 55 ⁇ em release signal from the main controller 53, the current target size x s and the current flow temperature T VL - if in the operating state (protection control 52: Em) with the main controller 53 is actuated by the release signal of the heating controller 55, this gives at the output 55o em voltage signal to a pulse-modulated thyristor controller 55a, with which the water heater 23 (see FIG. 1) is actuated.
  • the output signal of the heating controller 55 can be, for example, a voltage signal in the range from 0 to 10 volts.
  • heating controller 55 interrupts its own output signal via an internal switch (opener).
  • the cooling controller 56 receives the Em signal from the protection controller 52 as a release, and at the input 56 ⁇ the release signal from the main controller 53, the current target size x s and the return sensor 18 (see FIG. 1) the current return temperature T RL .
  • the ventilation device 40 see FIG. 1
  • the solenoid valves 22, 35 and 36 are actuated at higher temperature differences between the setpoint and actual values, as will be explained in detail below.
  • FIG. 2 also shows the display device 58, which is set up to display the number of cycles N, the current setpoint value Xs and / or the current sample temperature T P and for this purpose with the sequence control 51 and the sample sensor 17 (or the corresponding input of the main controller 53) connected is.
  • the actuating elements 57 of the control device 50 are correspondingly represented in FIG. 2 by the circuit 57 and illustrate conventional switches as are provided on the temperature control device and in particular a main switch “Em / Aus” and an emergency stop switch include. When the actuating elements 57 are released, the cooling mechanisms 33a, 33b are also switched on.
  • the device is first brought into an operational state by filling the reaction container 10 and the circuits 20, 30 and specifying the temperature setpoints T s , n , the tempering times t n and the number of cycles N on the sequence controller 51.
  • the pump 31 is activated so that the water circulates in the cooling circuit 30.
  • the water temperature in the cooling circuit 30 is initially set to 20 ° C.
  • the actual temperature control process is started and the pump 21 is started.
  • the temperature in the water bath of the reaction vessel in which the samples are located is set according to a specific, application-dependent, time-based temperature program (example see below). After the end of the program, the device is switched back to a state ready for operation.
  • controllers work together as follows to control the temperature during the program run. All controllers are designed as proportional controllers and are set up to process the same current setpoint x s , which corresponds to one of the setpoint temperatures T S n .
  • the current setpoint is compared at the main controller 53 with the sample temperature from the sample sensor 17, at the pump controller 54 with the return temperature from the return sensor 18, at the heating controller 55 with the flow temperature from the forward sensor 16 and finally at the cooling controller 56 again with the return temperature.
  • the main controller 53 which is the first in the controller hierarchy, issues the release signal to the heating controller 55.
  • the cooling controller not released remains in the state of
  • the output signal (for example in the range from 0 to 10 volts DC voltage) of the heating controller 55 is now applied to the pulse-modulated thyristor controller 55a, which accordingly controls the water heater 23. If the setpoint / actual value deviation (x w ) increases, a high pulse rate and thus a high heating output is set, and if the deviation x decreases, a small pulse rate or a small heating output is set. If x disappears, the output signal of heating controller 55 is switched off internally.
  • the release signal is sent from the main controller 53 to the cooling controller 56, the heating controller 55 now remaining in the ready-for-operation state (continuous setpoint / actual value comparison).
  • the cooling controller 56 switches the ventilation device 40 em with a small deviation x w ( ⁇ 0.5 to 1 ° C.).
  • the second and third solenoid valves 35, 36 are released and the first solenoid valve 22 is closed.
  • the release of the second and third solenoid valves 35, 36 is in turn dependent on the magnitude of the deviation x by means of corresponding release or cycle times, which advantageously ensures that the controller is particularly continuous.
  • the flow temperature is the same as the return temperature, the temperature of the samples has stabilized.
  • a signal for the temperature control can be derived.
  • the pump controller 54 runs independently in parallel.
  • the speed of the dynamic pump 21 (see FIG. 1) is set according to the following scheme. in the In the case of heating, small deviations x (example: 0.5 ° C) become a high speed and with large deviations x w (example: 5 ° C) a low speed and in cooling cases with small deviations x w a low speed and with large deviations x w a high speed of the pump 21 set. If the deviation x w disappears, the dynamic pump 21 runs at a predetermined fixed speed (for example 3000 U / mm). At this fixed speed, the flow rate through the pump is z. B. 25 1 / mm.
  • the device according to the invention is continuously monitored via a safety control chain with regard to excess media temperature, lack of water and the cover locking. If critical operating states occur, the device switches off automatically. A new start only takes place after the start button has been pressed manually.
  • the level in the reaction container 10 is regulated according to the following principle.
  • the fill level in the reaction container 10 is measured with a fill level measuring device 19 (see FIG. 1), which comprises a float switch device (eg with two switches).
  • the float switch device is connected to the solenoid valves 22, 35 and 36.
  • an impermissibly high fill level is reduced by temporarily opening the third solenoid valve 36 with the second solenoid valve 35 and the first solenoid valve 22 closed. Feeding takes place by temporarily opening the second solenoid valve 35 with the third solenoid valve 36 closed and the first solenoid valve 22 open.
  • the full-level measuring device 19 is preferably designed as a vessel communicating with the reaction container 10.
  • the float switch is located in the additional vessel, which is separated from the actual reaction container by a connection line or a partition with an opening (shown).
  • the control according to FIG. 2 can be equipped with electrical filters for the temperature sensors to smooth the control behavior.
  • the electrical filters are set up to round off or cut off the 1/100 degree position of the temperature signals from the sensors.
  • the aim of temperature control is to cyclically repeat three different temperature setpoints. After reaching the respective target value, the temperature should be kept constant for a predetermined time t. The setting of the three temperatures forms a cycle. This cycle should be repeated as often as required, depending on the application.
  • the tempering times t should each be, for example, 1 minute, with the tempering time ti of the first target temperature Ts, ⁇ being 4 minutes in the first heating cycle in order to achieve the greatest possible DNA denaturation at the initially low DNA concentration.
  • the parting times should be in the minute range (approx. 2 to 3 minutes).
  • the cycle number is queried (step 304) in order to set the sequencer 51 a timer circuit according to the example above to 4 mm (for the first cycle) or to 1 mm (for each subsequent cycle).
  • the time ti set in the timer circuit is queried and, as long as the time is running, the target / actual comparison 303 is repeated continuously.
  • the following steps target-actual comparison (307) and query of the timer circuit (308) take place analogously to the regulation of the first target temperature, whereby the cycle number is not differentiated here.
  • T Sr2 the DNA denatured in the first step is increased.
  • T s , 3 the amplified DNA is assembled into a new strand. For this purpose, steps 309 to 311 with steps 306 to 308 essentially become repeated.
  • the third tempering period the
  • Number of cycles N is decremented and queried whether the current number of cycles N * is equal to zero (step 312). If N * is not equal to zero, there is a return to step 302 (input of the first target temperature). Otherwise, the program is stopped (step 313).
  • Each setting process m in relation to a target temperature comprises a setting time for setting the target temperature (according to steps 303, 307 and 310 in FIG. 3) and the actual tempering time t.
  • the exposure time is particularly dependent on the medium, the media volumes for heating or cooling and the thermal load (sample quantity).
  • Curves A and B accordingly show the water temperature and the sample temperature, the course of which compared to the water temperature is delayed due to the delay in establishing the thermal equilibrium. 4 shows a decisive advantage of the invention in relation to the speed and consistency of the setting of the media temperature.
  • reaction container 10 Details of the reaction container 10 (see FIG. 1) are explained below with reference to FIG. 5. It is emphasized that the design of the heat exchanger as a sample holder is an independent aspect of the invention, which is preferably implemented in combination with the control principle explained above, but can also be used independently thereof for sample temperature setting using conventional thermostats. 5 shows the reaction container 10 with the trough 11 and the sample holder functioning as a heat exchanger 12, the front wall of the trough 11 not being shown for reasons of clarity.
  • the trough 11 has the shape of a vessel known per se from laboratory applications, the inner shape of which is preferably adapted to the outer shape of the heat exchanger 12. If the heat exchanger 12 is arranged in the trough 11 with as little play as possible, this has an advantageous effect on the speed and accuracy of the temperature setting.
  • the water flowing back from the nozzles (see below) to the outlet is forced into the immediate vicinity of the samples to be tempered.
  • the tub 11 has a rectangular plan.
  • the return 15 is provided as a connecting attachment between the tub interior and the pipe connection to the heating circuit 20 (see FIG. 1).
  • a peripheral support 111 is attached as a support for a lid (not shown).
  • the resting or locking of the lid can be detected by a sensor and taken into account in the protective control 52 (see FIG. 2).
  • the heat exchanger 12 is surrounded by a sheathing 112, which provides electrical engineering support and thermal insulation from the environment and consists, for example, of neoprene.
  • the tub volume is in the range of 5 to 8 1 (e.g. 7.5 1) with a floor area of approx. 135 mm • 460 mm at a height of 120 mm. The invention is not limited to realizing these large proportions.
  • the heat exchanger 12 (nozzle heat exchanger) serves simultaneously as a sample holder or support frame for the samples to be tempered. Accordingly, the design of the heat exchanger 12 is adapted to the sample format, depending on the application. an adaptation to the format of microtiter plates is preferred for biochemical and genetic engineering applications (here a microtiter plate is referred to as a sample).
  • the heat exchanger 12 consists of the frame 121, a distributor 122, an inlet connection 123 and outlet nozzles 124.
  • the frame 121 consists at least partially of components, the inner media lines in the form of channels, cavities, shafts or the like. contain.
  • the components are arranged in such a way that receptacles 13 for the samples (eg microtiter plates) are formed, the internal media lines being guided in such a way that good thermal contact between the medium penetrating the components and the samples in the receptacles is ensured.
  • the frame 121 is in the form of a shelf with horizontally aligned in the operating state the bottom 125 and to vertically aligned supporting elements 126.
  • a matrix array of 7 • 5 receptacles for the samples corresponding to m seven levels and five stacks (IV) is provided. With a 16 • 24 format of the microtiter plates used, a total of 13 440 individual samples can be subjected to a temperature control process simultaneously.
  • the sample temperature sensor 17 (see FIG. 1) or generally at least one temperature sensor of a sample holder is arranged in a shape that corresponds as closely as possible to the sample shape. It is envisaged, for example, to use a Fuhler microtiter plate in one of the receptacles, which contains no substances, but only the temperature sensor. In this case, 34 samples are taken from the reaction container 10. This attachment of the sample probe is not a mandatory feature of the invention. It can also be placed elsewhere in the sample container or even omitted entirely (see below).
  • the bottoms 125 are hollow elements which form at least one shaft-shaped, flat media line from the distributor 122 to the discharge nozzles 124 on each level.
  • each floor 125 which run in the plane of the respective floor over the entire width from the distributor 122 to the outlet nozzles 124.
  • the structure according to the invention is implemented, for example, with six waveguide strips, but fewer strips can also be provided.
  • Each waveguide strip has a rectangular cross section with typical dimensions of, for example, 10 • 3 mm 2 .
  • the broad side of the waveguide strips lies in the plane of the bottom 125.
  • the coupling element 127 is preferably a detachable quick coupling which enables the heat exchanger 12 to be removed from the trough 11 without further changes to the overall system.
  • the inlet connection 123 consists of a flexible hose.
  • the medium used for temperature control eg water
  • the outlet nozzles 124 are provided at the ends of the bottom which the medium flows through the tub 11. Since the shape of the heat exchanger 12 is adapted to the shape of the trough 11, the outlet nozzles 124 are located in the immediate vicinity of a side wall of the trough 11. The medium emerging at the end of the heat exchanger 12 opposite the distributor 122 can be freely m the tub 11 flows, but experiences essentially a reversal of the flow direction due to the adjacent tub wall. The outlet nozzles 124 thus form a deflection area with the adjoining tub wall, from which the medium flows back through the tub 11 through the frame 121 over its surface and the samples along the stacks V to I hm to the return 15. The backflow therefore does not take place inside the hollow components of the frame 121, but rather outside of them, so that the samples are wound directly by the medium in the sample receptacles.
  • the regular structure of the sample holder ensures a homogeneous and uniform flow through the sample container 10 corresponding to two flow sections.
  • first flow section there is an essentially laminar flow through the floor from the distributor 122 hm to the outlet nozzles 124.
  • second flow section there is also a homogeneous, almost laminar backflow from the deflection area (outlet nozzles 124) hm to the return 15.
  • a particular advantage of the invention is that that the lambda of the flow enables an extremely even heat distribution from the medium to the samples.
  • the medium first flows from the inlet connection 123, heating the samples lying in the receptacles on the bottom 125 with a continuously falling temperature through the bottom to the outlet nozzles 124.
  • the backflow under the action of the dynamic pump 21 essentially takes place above the samples m the recordings.
  • Heat exchange is again effected, with the samples (stack I) heated more strongly in the first flow section being heated relatively less and the samples heated less in the first flow section (eg stack V) being heated more strongly.
  • the first samples on the outlet side are subjected to the highest temperature from their underside and the lowest temperature from their top, whereas samples in the vicinity of the outlet nozzles 124 are exposed from the top and bottom be subjected to substantially similar temperatures.
  • all samples are supplied with the same total energy.
  • the described reaction container according to FIG. 5 is used in such a way that first the frame 121 is loaded with the samples (microtiter plates). Subsequently, on the coupling element 127, the connection of the flow 14, the insertion of the heat exchanger 12 m, the tub 11 and the covering and filling of the system (see above). With the dynamic pump 21, the medium, after it has filled the distributor 122, is pressed into the bottom 125 and through the outlet nozzles 124 into the trough, and is sucked out of the trough into the rest of the media circuit due to the differential pressure between supply and return via the return 15 .
  • the sample holder heat exchanger 12
  • the coupling element After carrying out the temperature control process, as described above, for example, the sample holder (heat exchanger 12) is removed from the tub, and after the coupling element has been released, all of the samples can be transported as a block to the site for further processing.
  • Parts of the level measurement device 19 are not shown in FIG. 5.
  • the invention is not limited to the described embodiments of the control method or the temperature control device, but rather can be modified depending on the application. For example, it is possible to reduce the number of temperature sensors on the reaction vessel. If the temperature control takes place under reduced accuracy requirements, the sample probe can be omitted and the regulation principle can be adapted in such a way that heating or cooling is effected until the temperatures at the flow and return are equal. This condition corresponds to that desired equilibrium, in which the sample temperature inevitably corresponds to the flow and return temperatures. Furthermore, the valves shown can be replaced by other locking devices, for example by three-way valves, in particular if there are reduced demands on the speed of the temperature setting. Other possible modifications relate to the number and type of heater or cooler, the size of the heat exchanger, the shape of the reaction vessel, the type of level measurement and the use of the ventilation device.

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  • Biochemistry (AREA)
  • General Health & Medical Sciences (AREA)
  • Molecular Biology (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Automation & Control Theory (AREA)
  • Automatic Analysis And Handling Materials Therefor (AREA)

Abstract

L'invention concerne le tempérage d'un bain liquide dans un récipient réactionnel (10) par un agent dont la température peut être réglée par un circuit de chauffage (20) et un circuit de refroidissement (30) présentant respectivement des équipements de chauffage ou de refroidissement (23, 33a, 33b). A cet effet, l'agent traverse un échangeur de chaleur (12) logé dans le récipient réactionnel (10) d'un élément d'admission (14) et à un élément de reflux (15) et de l'élément de reflux (15) à l'élément d'admission (14) en passant par le circuit de chauffage et/ou le dispositif de refroidissement (20, 30) en fonction de l'actionnement de dispositifs de blocage (22, 35, 36). Les équipements de chauffage ou de refroidissement (23, 33a, 33b) et les dispositifs de blocage (22, 35, 36) sont commandés de telle façon que l'agent ait une certaine température théorique dans le récipient réactionnel.
PCT/EP1999/008550 1998-11-16 1999-11-08 Dispositifs et procedes de temperage d'echantillons WO2000029115A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU13813/00A AU1381300A (en) 1998-11-16 1999-11-08 Devices and method for regulating the temperature of samples

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE1998152733 DE19852733A1 (de) 1998-11-16 1998-11-16 Verfahren und Vorrichtung zur Temperierung eines Flüssigkeitsbades
DE19852733.0 1998-11-16

Publications (1)

Publication Number Publication Date
WO2000029115A1 true WO2000029115A1 (fr) 2000-05-25

Family

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Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/EP1999/008550 WO2000029115A1 (fr) 1998-11-16 1999-11-08 Dispositifs et procedes de temperage d'echantillons

Country Status (3)

Country Link
AU (1) AU1381300A (fr)
DE (1) DE19852733A1 (fr)
WO (1) WO2000029115A1 (fr)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102004027161B3 (de) * 2004-06-03 2005-08-25 Siemens Ag Ventileinrichtung
CN114870926A (zh) * 2022-05-11 2022-08-09 何光亮 可自动增强固定效果的恒温箱

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102004062804B3 (de) * 2004-12-27 2006-05-24 Bernhard Harter Kombitemperierungsgerät
CN113201454A (zh) * 2021-05-25 2021-08-03 江南大学 一种运用液体交换法的小型核酸快速退火装置

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1990005329A1 (fr) * 1988-11-10 1990-05-17 Grant Instruments (Cambridge) Limited Appareil de reglage de la temperature et ses applications
US5656493A (en) * 1985-03-28 1997-08-12 The Perkin-Elmer Corporation System for automated performance of the polymerase chain reaction
WO1998009728A1 (fr) * 1996-09-06 1998-03-12 Central Research Laboratories Limited Appareil et procede de cyclage thermique d'un echantillon
WO1999017881A1 (fr) * 1997-10-07 1999-04-15 The Perkin-Elmer Corporation Appareil pour cycleur thermique a impact de fluide

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3360032A (en) * 1965-09-20 1967-12-26 Globe Union Inc Temperature controlling system
DE2038814A1 (de) * 1970-08-05 1972-02-17 Johann Hoffmann Vorrichtung zum Temperieren von Reagenzglaesern und Kuevetten
DE2908685C2 (de) * 1979-03-06 1982-05-27 Frhr. von Hardo Dr.med. 7400 Tübingen Gise Inkubator für histologische Präparate
DE29622848U1 (de) * 1996-07-02 1997-07-03 Barkey, Volker, 33619 Bielefeld Vorrichtung zum Temperieren von Probengefäßen

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5656493A (en) * 1985-03-28 1997-08-12 The Perkin-Elmer Corporation System for automated performance of the polymerase chain reaction
WO1990005329A1 (fr) * 1988-11-10 1990-05-17 Grant Instruments (Cambridge) Limited Appareil de reglage de la temperature et ses applications
WO1998009728A1 (fr) * 1996-09-06 1998-03-12 Central Research Laboratories Limited Appareil et procede de cyclage thermique d'un echantillon
WO1999017881A1 (fr) * 1997-10-07 1999-04-15 The Perkin-Elmer Corporation Appareil pour cycleur thermique a impact de fluide

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102004027161B3 (de) * 2004-06-03 2005-08-25 Siemens Ag Ventileinrichtung
CN114870926A (zh) * 2022-05-11 2022-08-09 何光亮 可自动增强固定效果的恒温箱

Also Published As

Publication number Publication date
AU1381300A (en) 2000-06-05
DE19852733A1 (de) 2000-05-25

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