The invention relates to a device for incubating cultures, a method for incubating cultures, and a use relating thereto.
In devices for incubating cultures, the cultures are usually incubated exposed to gas using gaseous CO2 coming directly from corresponding CO2 pressure cartridges, wherein this CO2 is existent in a self-liquefied state and highly pressurized.
Even with precisely working pressure reducing fittings, an extremely precise and, above all, safe incubation, in particular by means of CO2 in corresponding culture chambers, is not always satisfactorily possible, wherein this applies in particular to portable incubators during transport.
DE 20 2005 021 050 U1 relates to an autonomous incubator for biological material for creating and maintaining a predeterminable CO2 environment in at least one inner chamber of the incubator including a control device for controlling the CO2 concentration in the at least one inner chamber, wherein the autonomous incubator comprises a CO2 incubator.
The problem of the present invention is therefore to provide a device for incubating cultures with which a, with regard to the pressure conditions, precise and reliable metering of the respective incubation gas into the culture chambers is achieved and possible.
According to the invention, this problem is solved by a device according to claim 1, a method according to claim 7, and a use according to claim 8.
The device for incubating cultures according to the invention is one of those comprising a culture chamber storing the cultures, wherein the cultures are aerated with an incubation gas, for example and in particular with CO2, wherein in use the incubation gas source is free of liquid incubation gas when the cultures are incubated with the incubation gas. With respect to CO2, this means that, as is usually the case with liquefied CO2 contained in a pressure cartridge, this is not fed directly into the culture chamber via a pressure reducing fitting and a corresponding valve if required.
Also essential to the invention is the fact that, during the incubation of the cultures with the incubation gas, according to the invention liquid/liquefied incubation gas is dispensed with, wherein the incubation gas CO2 is in use provided for incubation by sublimation by means of dry ice.
By this embodiment according to the invention, the pressure problems known from the prior art of the expansion of liquid CO2 to gaseous CO2 with corresponding expansion of the liquid CO2 do not arise.
In this context it is further within the meaning of the invention that the incubation gas is CO2 and in use
a) present as dry ice in a storage container that is open to the outside—i.e. to the ambient atmosphere—for example and in particular in the form of a styrofoam container, or in a styrofoam container that is temporarily open by means of a valve, for example and in particular in the form of a closed styrofoam container designed with a pressure relief valve, wherein the pressure relief valve opens when a certain pressure is exceeded, and then closes again,
since no problematic overpressure conditions arise in the storage container and, for example and in particular by means of a pump, the CO2 required for the incubation can be charged into the culture chamber.
In this context, it is furthermore advantageous, since tried and tested in practice, that the incubation gas supply is interrupted or enabled upon exceeding or falling below predetermined incubation gas limit values by means of a sensor detecting the incubation gas content of the atmosphere of the culture chamber, for example and in particular, if the preventing or enabling is carried out by means of a valve and/or a metering pump.
Furthermore, it is advantageous that, in the case of CO2 as the incubation gas, the valve is opened and/or the metering pump is activated for suppling gaseous CO2 into the culture chamber if the percentage by volume CO2 in the atmosphere of the culture chamber falls below a predetermined value, for example and in particular 5% by volume CO2, so that the incubation conditions in the culture chamber are very good.
In addition, it is advantageous if the culture chamber includes a fan for gas exchange in the culture chamber in order to provide a maximally homogeneous composition in respect of the possible different gaseous constituents of the atmosphere in the culture chamber.
Finally, it is within the meaning of the invention that the device according to the invention is designed as a transport container, for example and in particular as a case-like container, in order to safely and under incubation transport sensitive cultures even over long distances, for example and in particular by means of aircraft, even across continents, without the cultures to be incubated and transported being damaged during transport.
In this context, it is advantageous, since tried and tested, if at least one element/part of the device is connected to an inner side of the transport container in an impact-resilient manner.
In this context, it is particularly advantageous, since tried and tested, if the impact-resilient connection is implemented by means of at least one member of the group consisting of an elastic element, for example and in particular a thermoplastic elastomer, for example and in particular polyisobutadiene, a cardanic mounting, and a spring element.
Furthermore, it is advantageous in this context, since tried and tested, if the element/part of the device is one of the group consisting of an incubator, the culture chamber, the storage container, a metering pump, a fan, a cell culture carrier, and a cell culture container.
In addition, it is also advantageous in this context, since tried and tested, if the cell culture carrier is mounted in the culture chamber by means of ball bearings.
Finally, it is advantageous, since tried and tested, if the storage container includes a CO2 discharge channel to the outside, this being in particular designed as a hose, in order to allow excess gaseous CO2 to escape in this way.
In this context, it is particularly advantageous, since tried and tested, if the CO2 discharge channel is disposed on an upper third of the storage container in order to discharge only excess gaseous CO2 from the storage container and the device.
Finally, it is also within the meaning of the invention if a related method for incubating cultures and/or for transporting cultures is provided, in which a device according to the invention is used.
The same applies to a use according to the invention of the device according to the invention for incubating cultures and/or for transporting cultures.
The invention is in the following explained in detail with the help of an exemplary embodiment that does not restrict the invention, in which
The embodiment of
According to the invention, a cardanic mounting is to be understood as the suspension of at least one above-mentioned element, for example and in particular, from an inner side 11 of the transport container 10, for example and in particular with the aid of two intersecting pivot bearings that are arranged perpendicular to each other.
A further embodiment of the device according to the invention is sketchily shown in
Number | Date | Country | Kind |
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10 2018 121 781.1 | Sep 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2019/000234 | 9/6/2019 | WO | 00 |