DE102004034827A1 - Cooling device for biological samples - Google Patents

Abstract

The invention relates to a cooling device ( 1 ) for cooling an item to be cooled, especially for use in the examination, handling and processing of cryogenic samples. The device includes a cooling compartment ( 3 ) for receiving the item to be cooled, an inner wall defining the cooling compartment ( 3 ), an outer wall, a space between the outer wall and the inner wall, and a coolant feed line ( 11 ) for feeding a coolant. According to the invention, the coolant feed line ( 11 ) leads into the space between the inner wall and the outer wall and feeds the coolant into the space, the inner wall being permeable for the coolant.

Description

The The invention relates to a cooling device for biological Samples, in particular for the investigation, manipulation and processing of cryoprobes, according to the generic term of claim 1.

It is in the field of biology, pharmacology, medicine and known in biotechnology, samples of biological material under Maintaining vitality freeze the sample material at liquid nitrogen temperatures. Such samples are also referred to as cryoprobes, wherein the vitality sustaining Storage of such cryoprobes takes place in so-called cryotanks, in which are more fluid Nitrogen is located. For manipulation, editing or examination the cryoprobes are removed from the cryogenic tank and into a cooling device introduced, for example, may consist of a tub at the bottom more fluid Nitrogen, which is also referred to as nitrogen lake and slowly evaporates, leaving the cryoprobe in the tub still sufficiently cooled becomes. To avoid outgassing of the liquid nitrogen in the ambient air can Here, a transparent protective bell placed on the tub become, whereby in the wall of the protective bell glove cuffs can be located over the an operator can manipulate the cryoprobe in the tub.

adversely on the previously described known cooling device for manipulation, Processing or examination of cryoprobes is the unsatisfactory Temperature constancy and distribution within the tub.

One Another disadvantage of the known cooling device is the fact that the protective bell due to outgassing from the nitrogen lake Nitrogen can fog up, which makes the visual inspection much more difficult.

Furthermore you can see the temperature within the tub in the known cooling device not or only with difficulty by a change of the introduced into the tub Amount of liquid nitrogen to adjust.

Of the The invention is therefore based on the object described above Cooling device accordingly to improve.

A Another goal may be to maintain the temperature in the cooling device to improve the temperature setting, to optimize the temperature distribution within the cooling device, To avoid fogging of the protective bell and moisture in the fridge to minimize.

The mentioned above Task is by a cooling device according to claim 1 solved.

The Invention is based on the technical knowledge that the unsatisfactory Temperature constancy and distribution within the cooling trough in the known cooling device caused by the outgassing nitrogen from the nitrogen lake within the cooling device undefined spread, so that the desired working temperature only difficult to reach and hardly regulate. The uncontrolled outgassing of Nitrogen from the nitrogen lake also leads to fogging the attached protective bell.

The The invention therefore comprises the general technical teaching, a Nitrogen lake in the cooler to avoid and controlled instead gaseous nitrogen in the fridge initiate.

The Cooling device according to the invention therefore indicates the inclusion of refrigerated goods a fridge, which is bounded by an inner wall and an outer wall, wherein there is a gap between the inner wall and the outer wall located in the a coolant supply line empties. The coolant (e.g., more liquid Nitrogen) is thus not introduced directly into the cold room, but instead in the space between the inner wall and the outer wall the refrigerator, where the inner wall for the coolant permeable is, so the coolant from the space between the outer wall and the inner wall enters the refrigerator through the inner wall.

Preferably is in the space between the inner wall and the outer wall of the cooling chamber a buffer material arranged, which introduced into the space coolant temporarily receives and continuously through the inner wall into the refrigerator emits.

The Buffer material is therefore preferably porous, for example liquid nitrogen to be able to cache.

The outer wall of the cooling space is preferably impermeable to the coolant, in contrast to the inner wall of the cooling space, in order to prevent leakage of the coolant to the outside into the environment. In addition, the outside wan tion preferably thermally insulating to prevent cooling of the environment or heating of the cooling device.

The Inner wall of the refrigerator on the other hand preferably consists of a thermally conductive material, such as metal, for the heat transfer from the inside refrigerator to improve the coolant in the gap. Furthermore It is advantageous if the material of the inner wall not only a good thermal conductivity but also has a high specific heat capacity, so that the inner wall with their heat capacity as thermal Buffer unwanted Counteracts temperature fluctuations.

In a preferred embodiment of Invention, the inner wall is substantially grid-shaped, so that the coolant located in the intermediate space is largely unhindered in the fridge can outgas.

Farther is the fridge in a preferred embodiment trough the invention and has on its upper side a peripheral edge, wherein the coolant supply line preferably a coolant distributor extending along the peripheral edge of the refrigerator compartment extends and the coolant over his Length distributed in the space between the inner wall and the outer wall of the refrigerator initiates. The coolant is thus evenly in the Interspace between the inner wall and the outer wall of the refrigerator initiated, which is advantageous for a uniform temperature distribution in the fridge leads, there the fridge Is cooled evenly from all sides.

Furthermore exists within the scope of the invention, the possibility that in the refrigerator, a heating element is arranged to the refrigerator to warm up or in the fridge refrigerated goods to thaw. Preferably, this heating element is under or in a heating plate, wherein the heating plate preferably a plurality Having passages, which allow a gas circulation.

As in the known cooling device described above also exists in the cooling device according to the invention the possibility, on the fridge a detachable protective bell to prevent the ingress of Moisture in the fridge to avoid. Preferably, this protective bell is at least partially transparent, to provide a visual inspection of the refrigerated goods in the refrigerator enable.

In a preferred embodiment of Invention, the protective bell on a sample lock, by the refrigerated goods introduced into the refrigerator or from the fridge can be removed, the sample lock a heat exchange largely prevented with the environment.

Further can be at the bottom of the protective bell and / or at the top of the refrigerator a cold gas outlet may be arranged over the coolant or cold gas from the refrigerator can escape. This cold gas outlet causes a large temperature gradient in height the cold gas outlet, wherein the temperature above the cold gas outlet significantly higher is as below the cold gas outlet. This will be beneficial prevents fogging of the protective bell.

Farther is carried out in the context of the invention preferably a control of the temperature in the fridge. For this purpose, the cooling device according to the invention preferably one in the refrigerator arranged temperature sensor to the temperature in the refrigerator too measure or regulate. As an actuator for temperature adjustment Is then preferably a controllable coolant valve provided, that the amount of the supplied refrigerant or, the coolant flow established. The actual temperature control then takes place a temperature controller, the input side connected to the temperature sensor is and the output side, the coolant valve activates according to a predetermined temperature setpoint.

The Control of the coolant valve through the temperature controller can be done via a clock, the coolant valve alternately opens and close, the opening and closing times of the coolant valve set by the clock and set by the temperature controller. The coolant supply takes place here so discontinuously by the coolant valve alternately opens and close.

Preferably is the temperature sensor for detecting the temperature in the refrigerator here the processing position of the refrigerator arranged to the optimum processing temperature in the refrigerator too measure or regulate.

Of the Temperature controller therefore preferably regulates the temperature in the refrigerator so that is at the bottom of the refrigerator no coolant lake forms.

Further is to mention that it is the coolant preferably liquid Nitrogen is, but the invention is not limited to nitrogen as coolant limited is, but also with other liquid or gaseous coolants is feasible, the rule in the space between the inner wall and the outer wall the refrigerator introduced can be.

The Cooling device according to the invention can for different temperature ranges are used, such as at temperatures of about -150 ° C, -130 ° C, -80 ° C, -40 ° C, + 4 ° C or + 37 ° C, wherein the aforementioned Temperature ranges include, for example, a range of ± 10 ° C, ± 5 ° C or ± 2 ° C can. A temperature of 37 ° C is beneficial because the growth temperature of biological cells then it is optimal. A temperature of + 4 ° C, on the other hand, offers the advantage that the physiological processes in the cells are slowed down. at a manipulation of cells at a temperature of less than 4 ° C is the cell damage lower (e.g., with Tropsia and DMSO).

Finally includes the invention not only the above-described cooling device as a device, but also the use of such a cooling device for examination, Processing and / or manipulation of a cryoprobe.

Other advantageous developments of the invention are characterized in the subclaims or will be discussed below together with the description of the preferred Embodiment of Invention with reference to the figures explained. Show it:

1 a perspective view of a preferred embodiment of the cooling device according to the invention with an attached protective bell,

2 a perspective view of the protective bell 1 in the removed condition,

3 a cross-sectional view of the wall structure of the cooling space in the cooling device 1 .

4 a simplified perspective view of the coolant supply in the cooling device 1 such as

5 a control engineering equivalent circuit diagram of the cooling device 1 ,

The illustrated in the drawings embodiment of a cooling device according to the invention 1 is used for tempering a cold room for receiving cryoprobes in an investigation, manipulation and / or processing.

For this purpose, the cooling device 1 a cryo-tub 2 with a trough-shaped, open-topped refrigerator 3 on, taking on the cryo-tub 2 a removable protective bell 4 is attached, which prevents the ingress of moisture from the environment into the refrigerator and detailed in 2 is shown.

The protective bell 4 points to the introduction of the cryoprobes in the refrigerator 3 and for removing the cryoprobes from the refrigerator 3 a sample lock 5 on, the side of the protective bell 4 is mounted and during insertion of the cryoprobe or when removing the cryoprobes largely prevents heat exchange with the environment and the moisture in the refrigerator 3 minimized.

Furthermore, the protective bell 4 a lamp on top 6 on to the fridge 3 to illuminate and manipulate the in the refrigerator 3 thereby facilitate cryoprobes.

The protective bell 4 itself consists of a transparent material, which allows a simple visual inspection by an operator.

At the bevelled front of the protective bell 4 There are two conventional glove cuffs 7 . 8th through which an operator enters the refrigerator 3 can manipulate cryoprobes located without gas exchange.

Furthermore, located on the back of the protective bell 4 below two openings 9 , about the cold gas from the protective bell 4 can escape. The two openings 9 have the consequence that in the height of the two openings 9 a large temperature gradient sets, since cold gas from the two openings 9 escapes to the outside. The atmosphere in the protective bell 4 above the openings 9 is therefore much warmer than below the openings 9 , causing a fogging of the inner walls of the protective bell 4 counteracts.

At the top of the cryo-pan 2 is located on the front of an operating and display panel 10 at which the temperature in the refrigerator 3 can be displayed and set.

The cooling of the refrigerator 3 takes place here by liquid nitrogen from a nitrogen tank (eg an Apollo tank) via a nitrogen line 11 is fed, the nitrogen line 11 not directly in the refrigerator 3 leads to the formation of a nitrogen lake at the bottom of the refrigerator 3 to avoid. Instead, the nitrogen line opens 11 via an electrically controllable coolant valve 12 in a coolant supply line 13 , where the coolant supply line 13 along the peripheral edge of the tub-shaped refrigerator 3 extends and releases the liquid nitrogen distributed over the length.

The fridge 3 is here of a metal, lattice-shaped inner wall 14 bounded by an outer wall 15 is enclosed, with the inner wall 14 and the outer wall 15 include a gap in which a buffer material 16 is arranged. The coolant supply line 13 is in the lateral direction between the inner wall 14 and the outer wall 15 above the buffer material 16 arranged and has downwardly directed outlet openings, through the liquid nitrogen from the interior of the coolant supply line 13 in the buffer material 16 is delivered. The buffer material 16 absorbs the liquid nitrogen and gives it continuously through the lattice-shaped inner wall 14 through into the fridge 3 from.

The coolant valve 12 works here discontinuously by the coolant valve 12 either closes or opens.

The activation of the coolant valve 12 takes place here by a clock 17 , wherein the opening time T _AUF and the closing time T _ZU for the coolant valve 12 from a regulator 18 can be specified to dose the coolant.

The regulation takes place here in dependence on the temperature in the cold room 3 by a temperature sensor 19 is measured, the temperature sensor 19 at the processing position of the refrigerator 3 is arranged.

The temperature sensor 19 therefore measures a temperature T _IST and delivers it to a subtractor 20 Further, as a further input variable, a target value T _SOLL for the temperature in the refrigerator 3 receives and calculates a target-actual deviation .DELTA.T.

The regulator 18 sets the opening time T _OP and the closing time T _ZU for the coolant valve 12 then so that the desired temperature (eg -130 ° C) in the refrigerator 3 prevails without being at the bottom of the refrigerator 3 forms a nitrogen lake.

Furthermore, on the floor of the refrigerator 3 a heating plate 21 arranged, which is a heating of the cryoprobe and the refrigerator 3 allows.

In the hot plate 21 Here are numerous vertically continuous passages 22 arranged, which allow a gas circulation.

The Invention is not on the embodiment described above limited. Rather, a variety of variants and modifications is possible, the also make use of the idea of the invention and therefore fall into the scope.

1

cooling device

2

Cryogenic bath

3

refrigerator

4

protective bell

5

sample port

6

lamp

7, 8th

Glove cuffs

9

openings

10

operator and display field

11

nitrogen line

12

Coolant valve

13

Coolant supply

14

inner wall

15

outer wall

16

buffer material

17

clock

18

regulator

19

temperature sensor

20

subtractor

21

heating plate

22

passages

Claims (20)

Cooling device ( 1 ) for cooling a chilled goods, in particular for the investigation, manipulation and / or processing of cryoprobes, having - a cold room ( 3 ) for holding the goods to be cooled, - a cooling space ( 3 ) delimiting inner wall ( 14 ), - an outer wall ( 15 ), - a gap between the outer wall ( 15 ) and the inner wall ( 14 ) and - a coolant supply line ( 11 . 13 ) for introducing a coolant, characterized in that the coolant supply line ( 11 . 13 ) in the space between the inner wall ( 14 ) and the outer wall ( 15 ) and introduces the coolant into the intermediate space, wherein the inner wall ( 14 ) is permeable to the coolant. Cooling device ( 1 ) according to claim 1, characterized in that in the intermediate space a buffer material ( 16 ) is arranged, which temporarily receives the introduced into the intermediate space coolant and continuously through the inner wall ( 14 ) through into the cold room ( 3 ). Cooling device ( 1 ) according to claim 2, characterized in that the buffer material ( 16 ) is porous. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the inner wall ( 14 ) is substantially grid-shaped. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the inner wall ( 14 ) consists of a thermally conductive material. Cooling device ( 1 ) according to claim 5, characterized in that the inner wall ( 14 ) consists essentially of metal. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the cooling space ( 3 ) is trough-shaped and has on its upper side a peripheral edge. Cooling device ( 1 ) according to claim 7, characterized in that the coolant supply line ( 11 . 13 ) a coolant distributor ( 13 ), which extends along the peripheral edge of the cooling space ( 3 ) extends and the coolant distributed over its length into the intermediate space initiates. Cooling device ( 1 ) according to one of the preceding claims, characterized in that in the cold room ( 3 ) a heating element ( 21 ) is arranged. Cooling device ( 1 ) according to claim 9, characterized in that the heating element under a heating plate ( 21 ), wherein the heating plate ( 21 ) several passages ( 22 ), which allow gas circulation. Cooling device ( 1 ) according to one of the preceding claims, characterized in that on the cold room ( 3 ) a removable protective bell ( 4 ) is attached. Cooling device ( 1 ) according to claim 11, characterized in that the protective bell ( 4 ) is at least partially transparent. Cooling device ( 1 ) according to claim 11 or 12, characterized in that the protective bell ( 4 ) a sample lock ( 5 ) having. Cooling device ( 1 ) according to one of the preceding claims, characterized in that on the underside of the protective bell ( 4 ) and / or at the top of the refrigerator ( 3 ) a cold gas outlet ( 9 ) is arranged, via the coolant and / or cold gas from the refrigerator ( 3 ) can escape. Cooling device ( 1 ) according to one of the preceding claims, characterized by - one in the cold room ( 3 ) arranged temperature sensor ( 19 ) for measuring the temperature in the cold room ( 3 ), - a controllable coolant valve ( 12 ) for adjusting the amount of coolant supplied, - a temperature controller ( 18 ) for controlling the temperature in the cold room ( 3 ), the temperature controller ( 18 ) on the input side with the temperature sensor ( 19 ) and the output side with the coolant valve ( 12 ) connected is. Cooling device ( 1 ) according to claim 15, characterized in that the temperature controller ( 18 ) via a clock ( 17 ) with the coolant valve ( 12 ), the clock ( 17 ) the coolant valve ( 12 ) alternately opens and closes. Cooling device ( 1 ) according to claim 15 or 16, characterized in that the temperature sensor ( 19 ) at a processing position in the cold room ( 3 ) is arranged. Cooling device ( 1 ) according to claim 15 to 17, characterized in that the temperature controller ( 18 ) and / or the clock ( 17 ) adjusts the coolant supply so that at the bottom of the refrigerator ( 3 ) does not form a coolant lake. Cooling device ( 1 ) according to one of the preceding claims, characterized in that the coolant is liquid nitrogen. Use of a cooling device ( 1 ) according to one of the preceding claims for the examination, processing and / or manipulation of a cryoprobe.