WO2015078767A1 - Device for monitoring a temperature parameter with a view to detecting a break in a cold chain - Google Patents

Abstract

The invention relates to a temperature parameter monitoring device (100) which includes a container (101) and a monitoring element (102) located in the container (101). Said monitoring element (102) is configured such as to adopt a first position relative to the container (101), as long as the temperature to which the monitoring device (100) is subjected remains lower than a predetermined threshold, and to adopt a fixed second position relative to the container (101) if the temperature of the monitoring device surpasses said predetermined threshold.

Description

 Device for controlling a temperature parameter for detecting a break in a cold chain

Technical field of the invention

The invention relates to the field of preservation of sample (s) by freezing, or more particularly by cryogenics.

The subject of the invention is more particularly a device for controlling a temperature parameter.

STATE OF THE ART In the field of the preservation of a sample at low temperature, such as for example a biological tissue, it is important that its temperature remains rather low throughout the preservation. In fact, an increase in temperature could have the consequence of damaging the sample, which would then no longer be suitable for use.

There is therefore a need to develop a robust device for easily determining whether a sample has not seen its temperature exceed a predetermined temperature. Object of the invention

The aim of the present invention is to propose a solution allowing an unambiguous reading of a failure within a low-temperature storage.

This object is attained by means of a device for controlling a temperature parameter comprising a container and a control element disposed in the container, said control element being configured to adopt a first position relative to the container as long as the temperature at which the control device is subjected remains below a predetermined threshold, and so to adopt a second final position relative to the container if the temperature of the control device passes above said predetermined threshold. In particular, the predetermined threshold is chosen in a range between -135 ° C and-150 ° C and preferably equal to -136 ° C.

Advantageously, the device comprises a holding element of the control element in the second position when the latter has reached said second position.

For example, the control element comprises at least one ferromagnetic element and the holding element comprises a magnet, or in that the control element comprises a magnet, and the holding element comprises at least one ferromagnetic element. According to a particular implementation, the container is filled with a material having a solid phase below the predetermined threshold so as to maintain the control element in its first position, and a liquid phase above the predetermined threshold so as to allow the passage of the control element from the first position to the second position, in particular by gravity and / or by magnetic attraction.

Preferably, the container is filled with a material comprising a first density below the predetermined threshold so as to maintain the control element in its first position, and a second density above the predetermined threshold so as to allow the passage of the control element from the first position to the second position.

The material may be chosen from: Ethylcyclopentane, 2-methyl-2-butene, 2-Methyl-1-butene, Dibromodifluoromethane, Diclhorofluoromethane, or Trichlorofluoromethane.

Preferably, the device comprises an initialization configuration before being subjected to a temperature below the predetermined threshold in which a force is applied so as to maintain the control element in its first position regardless of the orientation of said device. control.

The invention also relates to a system comprising at least first and second devices as described above, the first and second devices being oriented in different directions or directions. The invention also relates to a method of using a control device as described, said method comprising:

a cooling step of the control device at a temperature below the predetermined threshold, a step of applying a force, in particular a magnetic field on the control element, so as to maintain the control element voluntarily in its first position during the cooling step, a step of stopping the application of said force when the temperature of the control device is below the predetermined threshold.

The invention also relates to a cryogenic method of a sample, in particular a biological tissue, said cryogenic process comprises the following steps:

an association of the sample with at least one control device as described,

a cryogeny of the sample associated with the at least one control device from which it follows that the control element is in its first position.

Preferably, the cryogenic process comprises a step of implementing the method of using the control device whose cooling step allows the cryogeny of said sample.

For example, the association step comprises a step of introducing the sample into the container.

According to one embodiment, the cryogenics process may comprise, after the cryogenesis step of the sample, at least one control step of the state of the control device, such that a sample is classified as faulty if the control step detects the control element in its second position.

Brief description of the drawings

Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention given as non-restrictive examples and shown in the accompanying drawings, in which:

 FIG. 1 is a perspective view of an embodiment of a control device according to the invention, the control element of which is arranged at its first position;

 FIG. 2 is a perspective view of the embodiment of FIG. 1 for which the control element is arranged at its second position;

 FIGS. 3 to 5 illustrate how a control device can be manufactured,

 FIG. 6 illustrates a control device in a use situation in which the control element is in its second position,

FIGS. 7 and 8 illustrate two other implementations of the control device,

 FIG. 9 schematically illustrates steps of a method of using the control device,

 FIG. 10 schematically illustrates steps of a cryogenic method of a sample.

Description of preferred modes of the invention As illustrated in FIGS. 1 and 2, a device 100 for controlling a temperature parameter may comprise a container 101 and a control element 102 placed in the container 101. The control element 102 is configured to adopt a first position relative to the container 101 as long as the temperature at which the control device 100 is subjected is below a predetermined threshold (and in particular remains within a range whose upper bound is the predetermined threshold) and so to adopt a second definitive position relative to the container 101 if the temperature of the verification device 100 passes above said predetermined threshold.

The container 101 will preferably be a tube formed of polypropylene which has the advantage of not expanding when it is subjected to temperature variations. More particularly, in a configuration of use of the control device 100, while the control element is in its first position, said control device 100 is subjected to a conservation temperature below the predetermined threshold (or included in said range this has the consequence that the control element 102 is held in its first position. Still in this configuration of use, if the temperature of the control device 100 passes above the predetermined threshold while the control element 102 is in its first position (for example in the event of failure of the cooling of the control device) , the latter leaves its first position towards its second position that it will adopt permanently, regardless of future temperature variations of the control device. The first position of the control element 102 is illustrated in FIG. 1 and the second position of the control element 102 is illustrated in FIG.

Preferably, the control device 100 will be intended to be associated with at least one sample of biological tissue (s) conserved by cryogenics. In general, the temperature range at which a sample is subjected to such storage is -150 ° C to -180 ° C. In this sense, the upper bound of the given range is relatively close to -150 ° C. More particularly, it has been observed that a sample of biological tissue (s) was able to evolve above -136 ° C. In this sense, the upper limit of the range will preferably be equal to -136 ° C for a conservation application of a sample comprising at least one biological tissue. In other words, the predetermined threshold can be chosen in a range between -135 ° C and-150 ° C and preferably equal to -136 ° C.

"Final position" means that the change of position from the first position to the second position must be irreversible. In other words, once the control element is in its second position, the transition from the second position to the first position is inhibited. In this sense, the device 100 preferably comprises a holding element 103 of the control element 102 in the second position when the latter has reached said second position. This holding element 103 allows in particular to ensure the irreversible nature referred to above. According to a particular example, the control element 102 comprises at least one ferromagnetic element and the holding element 103 has a magnet It is then understood that in second position, the control element 102 is attracted and held by the holding element 103. Alternatively, the control element 102 comprises a magnet and the holding element 103 comprises at least one element ferromagnetic. The use of the magnetic properties makes it possible to obtain a control device at low costs. It is also possible to extrude magnets (ferrites, etc.) into a mass of polypropylene (thus preferably into the mass of the tube), the other advantage being that the magnet (for example inside the container) can be covered with polypropylene or a polymer (sterilizable) that will prevent any contact with biological products to protect. This would not be the case with a glue or other point.

In a general manner and applicable to all that has been said above, the passage of the control element from the first position to the second position, in particular in the configuration of use, is made possible by magnetic attraction between the control element 102 and the holding element 103 and / or by gravity. It is then understood because of the use of gravity that the skilled person will position the control device in a suitable manner to achieve the desired effect. By gravity, here is meant by the fall of the control element 102 in the container 101 according to earth's gravity, or by raising of the control element 102 in a material 104 filling the container 101.

According to one embodiment, in its first position the control element can be glued to an inner wall of the container by an adhesive point capable of melting when the temperature of the control device passes above the predetermined threshold. Once this glue point melts, the control element moves to its second position. According to another embodiment, the container 101 is filled with a material 104 having a solid phase below the predetermined threshold so as to maintain the control element 102 in its first position, and a liquid phase above the threshold predetermined so as to allow the passage of the control element from the first position to the second position, in particular by gravity and / or magnetic attraction.

For example, the material 104 may be chosen from: Ethylcyclopentane (melting point at -138 ° C.), 2-methyl-2-butene (melting point at -134 ° C.), 2-Methyl-1 -butene (melting point at -138 ° C) Dibromodifluoromethane (melting point at -141 ° C), Diclhorofluoromethane (melting point at -135 ° C), or Trichlorofluoromethane (melting point -1 -1 1 ° C). A mixture of at least two of these materials is also possible.

As the material 104, all the halogenated compounds more particularly fluorohalogenés are candidates of choice because they are very low viscosity at low temperature and they are absolutely harmless for the biological products. In addition, because of the presence of heavy element in their formula, they all have a density much greater than 1, which is an advantage for a device operating by gravity. However, this type of material belongs to the class of freons and should therefore be regulated as to their use because of the damage to the ozone layer caused by their possible photo decomposition. Other products are more toxic and flammable, but they do not generate legislative risks. In addition, their boiling points are relatively high and thus facilitate the steps of filling and packaging. Mixtures can therefore be chosen. The material or materials chosen to fill the container 101 will preferably have a low melting point and a boiling point as high as possible. For environmental reasons, a non-toxic solvent is preferably chosen, for example a material of the CFC, HCFC or other refrigerant type. A mixture of materials and / or an association with glycols can be envisaged. The glycols, because of the hydrogen functions, will make it possible to adjust the rheology. It has been described above the use of a solid phase and a liquid phase of a material. However, it is also possible to generalize by using a container 101 filled with a material 104 having a first density below the predetermined threshold so as to maintain the control element 102 in its first position, and a second density above the predetermined threshold. predetermined threshold so as to allow the passage of the control element 102 from the first position to the second position, in particular by gravity and / or magnetic attraction.

In the case where the passage from the first position to the second position is accompanied by a fall of the control element 102 according to gravity, the first density is greater than the second density, and the control element 102 presents a lower density at first density but higher than the second density.

In the case where the passage from the first position to the second position is accompanied by a rise of the control element 102 in the material 104 of the container 101, the control element 102 has a density lower than the second density. . In addition, the density of the control element 102 is in this case greater than the first density.

It is understood from what has been said above that before being placed at a temperature below the predetermined threshold, that is to say before putting in the configuration of use of the control device 100, the control element 102 can move in the container 101 since it is not "frozen" by the material 104. Thus, to avoid this displacement, it is preferable to use a member applying a force to said control element 102 of so as to maintain the latter in its first position regardless of the position of the container 101. This may, for example, be implemented by a temporary element of magnetic attraction when the control element 102 comprises a ferromagnetic element. This temporary element can be kept as long as the control device is not used, that is to say as long as it is not subjected to a temperature below the predetermined threshold. In other words, the control device 100 may comprise an initialization configuration before being subjected to a temperature below the predetermined threshold in which a force is applied so as to maintain the control element 102 in its first position whatever the orientation of said control device 100. This force may be of the magnetic type as mentioned above in the context of the holding element 103.

To facilitate the detection of the control element 102 in its second position, the control device 100 may advantageously comprise a marker element 105. In FIGS. 1 and 2, this reference element 105 is formed by the holding element 103. for example in the form of a ring. Of course, any other type of cue element for dissociating the first position of the second position, particularly visual, can be used by the skilled person. According to one particular embodiment illustrated in FIGS. 3 to 8, the control element 102 is placed in the container 101 (FIG. 3). The control element 102 may comprise a label 102a provided with a pellet 102b comprising a magnet or a ferromagnetic element.

The container 101 is then filled with the material 104 referred to above (Figure 4 to 8). It follows from the filling that the control element 102, thus immersed, starts to rise upwards (that is to say to move in a direction opposite to the direction of gravity), or if necessary remains in the bottom of the container. To facilitate detection, the marker element 105, here in the form of a mask, is glued to the container 101 (FIG. 5). Furthermore, a label 106 provided with a magnet, or possibly a ferromagnetic element, and removably mounted on the control device so as to temporarily hold the control element 102 in its first position under the marker element 105.

In this example, the control device 100 will be disposed, when subjected to a temperature below the predetermined threshold so that the marker 105 is proximal to the ground S (Figure 6), the portion of the container 101 not covered by the reference element 105 then being distal from the ground S. When the temperature is below the predetermined threshold, the label 106 will be removed. It is then understood that if the temperature to which the control device 100 is subjected passes above the predetermined threshold, the initially hidden control element 102 (shown in dashed lines in FIG. 6) will go upwards in the container 101 of so as to be visible (Figure 6) because of its difference in density with respect to the material 104 in its liquid phase. The holding element 103 visible in FIG. 6 will then inhibit the return of the control element 102 in the first position and will force the maintenance of the latter in its second position.

Preferably, two devices as described above are associated with the same sample and are arranged head to tail. This allows in particular not to worry about the direction in which the sample associated with the control device will be stored. Thus, the invention may also relate to a system comprising two control devices, preferably identical, and oriented in different directions or directions. According to an improvement applicable to all that has been said above, the container 101 has an elongate shape provided with two opposite longitudinal ends E1, E2 (Figure 7). In this case, the second position of the control element 102 corresponds to the location of the control element 102 at any of the ends E1, E2 of the container 101. It is then understood that the first position of the control element corresponds to its location in a median zone of the container 101 disposed between the ends E1 and E2. This avoids putting two identical devices head to tail. In this case, the presence of a cover 105 arranged to hide the control element 102 in its first position, although recommended (shown in dotted lines), is not necessary.

According to another alternative illustrated in FIG. 8, the control element 102 is in the form of a pellet placed, in the first position of the control element 102, in the center of a cylindrical container 101 in the form of a tube. Any decentering of the control element 102 being representative of a passage of the control device 100 at a temperature above the predetermined threshold. The invention also relates to a method of using a control device as described. Such a method comprises a cooling step E1 of the control device at a temperature below the predetermined threshold, and a step E2 application of a force, including a magnetic field on the control element 102, so as to maintain the control element deliberately in its first position during the cooling step. The method further comprises a stopping step E3 of the application of said force when the temperature of the control device 100 is below the predetermined threshold.

Furthermore, the invention also relates to a cryogenic method of a sample, in particular a biological tissue, comprising the following steps: the association E100 of the sample with at least one control device 100 as described above, and a cryogenic step E101 of the sample associated with said at least one control device 100 from which it follows that the control element 102 is in its first position. In particular, the cryogenic process may comprise a step of implementing the method of using the control device whose cooling step allows the implementation of the cryogenic step E101 of said sample.

The association step E100 may comprise a step of fixing the control device 100 on an envelope comprising the sample or a step of introducing the sample into the container 101. Preferably, the sample will be disposed in the container 101 so as to save space.

The cryogenics process comprises, after the cryogenesis step of the sample, at least one control step E103 of the device state 100, so that a sample is classified as defective if the control step E103 detects the control element 102 in its second position. This control step E103 is generally carried out before thawing of the sample for use.

The invention described above will advantageously be implemented in the field of storage of cryobanks which must ensure long-term storage of organic tissues or embryos.

In addition, the control device as described has the advantage of being handled and stored at room temperature before use.

Claims

1. A temperature parameter control device (100) comprising a container (101) and a control element (102) disposed in the container (101), said control element (102) being configured to assume a first position relative to the container (101) as long as the temperature at which the control device (100) is subjected remains below a predetermined threshold, and so as to adopt a second definitive position with respect to the container (101) if the temperature of the device control passes above said predetermined threshold, characterized in that the predetermined threshold is chosen in a range between -135 ° C and -150 ° C and preferably equal to -136 ° C.

2. Device according to claim 1, characterized in that it comprises a holding member (103) of the control element (102) in the second position when the latter has reached said second position.

3. Device according to the preceding claim, characterized in that the control element (102) comprises at least one ferromagnetic element and the holding element (103) comprises a magnet, or in that the control element (102) ) comprises a magnet, and the holding element (103) comprises at least one ferromagnetic element.

4. Device according to any one of the preceding claims, characterized in that the container (101) is filled with a material (104) having a solid phase below the predetermined threshold so as to maintain the control element (102). ) in its first position, and a liquid phase above the predetermined threshold so as to allow the passage of the control element (102) from the first position to the second position, in particular by gravity and / or magnetic attraction.

5. Device according to any one of claims 1 to 4, characterized in that the container (101) is filled with a material (104) comprising a first density below the predetermined threshold so as to maintain the control element (102) in its first position, and a second density above the predetermined threshold so as to allow the passage of the control element from the first position to the second position.

6. Device according to one of claims 5 or 6, characterized in that the material (104) is selected from: Ethylcyclopentane, 2-methyl-2-butene, 2-Methyl-1-butene, Dibromodifluoromethane , Diclhorofluoromethane, or Trichlorofluoromethane.

7. Device according to any one of the preceding claims, characterized in that it comprises an initialization configuration before being subjected to a temperature below the predetermined threshold in which a force is applied so as to maintain the element of control (102) in its first position regardless of the orientation of said control device (100).

8. System comprising at least a first and a second device according to one of the preceding claims, the first and the second devices being oriented in different directions or directions.

9. A method of using a control device according to any one of claims 1 to 7, characterized in that it comprises:

a cooling step (E1) of the control device at a temperature below the predetermined threshold,

an application step (E2) of a force, in particular a magnetic field on the control element (102), so as to maintain the control element (102) deliberately in its first position during the cooling step (E1),

- A stop step (E3) of the application of said force when the temperature of the control device (100) is below the predetermined threshold.

10. A method of cryogenizing a sample, in particular a biological tissue, characterized in that it comprises the following steps:

an association (E100) of the sample with at least one control device (100) according to any one of claims 1 to 7,

- A cryogenics (E101) of the sample associated with said at least one control device from which it follows that the control element is in its first position.

1 1. Method according to the preceding claim, characterized in that it comprises a step of implementing the method (E101) of use of the control device (100) according to claim 9, the cooling step of which allows the cryogenesis of said sample.

12. Method according to one of claims 10 or 1 1, characterized in that the association step comprises a step of introducing the sample into the container (101).

13. Method according to one of claims 10 to 12, characterized in that it comprises, after the cryogenic step of the sample, at least one control step (E103) of the state of the control device ( 100), so that a sample is classified as faulty if the checking step (E103) detects the control element (E102) in its second position.