DE102008031666A1 - cryocontainers - Google Patents

Abstract

The invention relates to a cryogenic container being suitable for the storage and provision of frozen particles, comprising a thermally insulated container element having at least one accommodation chamber for frozen particles, and at least one outlet opening, a locking device, by means of which the at least one outlet opening can be closed, at least one opening element, which can be actuated in order to open the outlet opening, thus providing the frozen particles outside of the outlet opening, and an insulation element for the thermal insulation of the closing device. The invention further relates to a depot for providing frozen particles for a deposition device, a deposition device having a depot, and a method for providing frozen particles for a deposition.

Description

The The invention relates to a storage and supply of frozen Particles suitable cryocontainer, a magazine for deployment of frozen particles for a deposition apparatus for Deposition of the frozen particles using a cryogenic container, a deposition apparatus arranged for the deposition of frozen particles with a magazine, as well as a method of providing frozen Particles for a deposition device using a cryobank.

From the field of biological and medical applications, methods and devices for the deposition of particles in a target substrate are known. Particularly interesting for medical and biological purposes is the deposition of biological material, such as living cells. For the deposition of biological materials into a target substrate, particularly a target biological substrate, such as living tissue, is known in the art DE 10 2007 004 855 (German patent application, unpublished on the priority date of the present application) describes a deposition apparatus and a method, wherein particles containing biological material are shot in the frozen state into a target substrate. The particles have, for example, a cross-sectional diameter of less than one millimeter and a mass of the order of less than 10 micrograms.

There such small frozen particles naturally Thawing room temperature quickly are for the preparation the particle for the deposition special arrangements hold true. For the preparation of the frozen Particles there is the possibility of the particles directly before deposition by targeted deep freezing of smallest quantities manufacture. Another possibility is frozen particles and frozen until use for deposition store. In particular, biological materials need usually for longer storage times very low temperatures, often below -100 ° C be stored.

Therefore is responsible for the storage and delivery of the particles a need for a container which over long Times (months to years) at such low temperatures frosty or is resistant to cold. At the same time the particles are safe from contamination during storage be protected. Moreover, it is at the relatively small frozen particles particularly important to the cold chain from storage to deposition, otherwise even with very short interruptions, the risk of melting the Particle exists. Especially in the preparation of the particles for the deposition there is a risk of interruptions the cold chain and delays without proper protective measures can quickly lead to melting of the particles. Easy handling of the container is therefore important to avoid delays.

It It is therefore an object of the invention to provide a cryocontainer for the storage and provision of frozen particles for a deposition, a device for providing and for deposition the frozen particles, as well as a method of deployment indicate the frozen particles, which is a substantial maintenance Allow the cold chain and easy to handle or perform are.

The The object of the invention is achieved by a cryocontainer, a magazine, a deposition apparatus and a method for Provision of frozen particles for a deposition device with the features of the independent claims. advantageous Further developments are in the dependent claims specified.

One more suitable for the storage and provision of frozen particles Cryo container according to the invention a thermally insulating container element, which at least a receiving space for frozen particles and at least having an outlet opening. The inventive Cryo container further comprises a closure device, with the at least one outlet opening closable is and at least one opening element which can be actuated is to open the outlet opening and thereby the frozen particles outside the outlet provide. The cryocontainer according to the invention further comprises an insulation element for thermal insulation the closure device.

The cryocontainer according to the invention is preferably suitable both for long-term storage and for short-term provision for deposition. For long-term storage, the frozen particles are usually stored at temperatures below -100 ° C. The cryocontainer according to the invention is therefore preferably resistant to cold over long periods of, for example, more than one year. Suitably, it is suitable for storage at a temperature of liquid nitrogen or dry ice (CO ₂ ). The material of the container element may be, for example, plastic, PTFE or glass.

The thermally insulating container member comprises a cavity which forms a receiving space for frozen particles. The container element is designed thermally insulating to after removal of the loaded with frozen particles cryogenic container from a frozen storage as egg In an ultra-low temperature refrigerator or a nitrogen storage tank to maintain the temperature of the particles largely. The walls enclosing the cavity are therefore preferably made heat-insulating. This includes, for example, walls of a thermally insulating material but also double-walled versions in which a gap between two wall layers is evacuated similar to a Dewar. In addition, a thick container wall can have a high heat capacity and thus form a heat sink after removal from a deep-freeze store, which according to the high mass and heat capacity prevents thawing of the particles located in the receiving space.

The Container element preferably comprises only one receiving space, however, there are also designs with more than one recording room possible for frozen particles. these can then closed with one and the same closure device be or each have a separate closure device. Each receiving space has an outlet opening. The Outlet opening is an opening through which In the receiving space stored frozen particles leave the cryocontainer can. The outlet can also be used for filling of the cryocontainer with the frozen particles. But it is also possible that the cryocontainer over load a second opening with the frozen particles becomes. In this case, the outlet can already during manufacture of the unfilled invention Cryo container sealed with the closure device become. Otherwise the outlet is after filling of the cryobank with the frozen particles through the Locking device closable.

To open the closure device and providing the frozen particles for the deposition, the inventive Cryocontainer has at least one opening element, which can be operated to the closure device to open. Preferably, the closure device is included opened from the inside of the receiving space to the outside. The opening element may, for example, a stamp or be a slide-in pin, which pressed against the closure device from the inside and pierces the closure device or pushes open.

Around a good insulation and maintenance of the cold chain to ensure the invention has Cryogenic container also on the insulation element for the thermal insulation of the closure device and the receiving space opposite the environment. The isolation element is of the closure device separable. It can, for. B. completely removable or hinged be so that the closure device are completely exposed can. Preferably, the isolation element is complete removable. The isolation element preferably consists of a thermally insulating material and can also improve the insulation have an evacuated cavity. Like the thermally insulating Container element, it can also have a high heat capacity exhibit and with a large mass after removal from a cooling device z. B. a cryogenic tank as a heat sink serve.

The Isolation element is preferably a loose component, the one to the outer surface of the closure device Complementary contact surface has. The isolation element is preferably during long-term storage and in particular after removal of the cryocontainer from a cooling device with its contact surface on the outside of the Closure device and covers it completely. Thus, it serves on the one hand the thermal insulation and on the other as protection against mechanical damage of the closure device. Preferably, the insulation element is releasably attached attached to the cryocontainer. The attachment can, for example be formed by a film cuff, which is a falling apart prevents from cryocontainer and isolation element and itself can be solved by tearing open. Also one detachable adhesive bond is possible for attachment.

If the cryocontainer to prepare for a deposition a cooling device is removed, the insulation element to protect against damage and especially for the rest Isolation as long as possible to remain on the cryocontainer. For providing the frozen particles for deposition with a deposition device, the insulation element is removed, so that the closure device is exposed. This is preferably done just before the deposition, so that the isolation as possible long maintained.

The cryocontainer is then positioned with the exposed closure device at an opening of a deposition apparatus or in a magazine for providing the frozen particles. Preferably, the magazine or the deposition device is cooled, so that the cryocontainer with the frozen particles comes back into contact with a cooling device or at least a cooled body immediately after removal of the insulating element, to thaw the frozen particles in the receiving space of the cryocontainer even after removal of the insulating element reliably avoid. The cooling can be done, for example, with cold nitrogen gas or liquid nitrogen or with CO ₂ dry ice.

The positioning of the cryocontainer relative to a deposition apparatus can thereby be successful gen that the cryocontainer is placed with the exposed closure device on a loading opening of the deposition device. The loading opening serves to load the deposition apparatus or to provide the frozen particles in the deposition apparatus for deposition. In the deposition apparatus, the particles are then accelerated by means of a drive device, which will be described in more detail below. Around the loading opening, the deposition apparatus preferably has a support surface on which the cryocontainer can be positioned with the closure device. For this purpose, the outer surface of the closure device forms a contact surface, which is designed to be as complementary as possible to the support surface of the deposition device, so that an accurate fit contact between the deposition device and the cryocontainer can be made. Another way of positioning is with the help of a magazine, which is described below.

Preferably is the contact surface through the base of the Cryogenic container formed. The contact surface forms preferably a flat surface which is on a plane Support surface of the deposition device fitted accurately can be. The contact surfaces between the closed Cryo container and the deposition device or the magazine however, they can also be curved. A flat contact surface has the advantage that a cryocontainer, from which the insulation element was taken to bridge a time until positioned on the deposition apparatus on a chilled Plate can be stored. The through the locked Outlet opening of the cryocontainer formed contact surface is preferably both complementary to the support surface the Depo sitionsvorrichtung as well as the contact surface of the Designed insulation element.

To the positioning of the cryocontainer relative to the deposition apparatus the opening element is actuated, so that the Outlet opening is opened and the frozen Particles provided outside the outlet opening become. The frozen particles leave the receiving space of the Container element through the outlet opening, for example by falling out, pushing out, pushing out and / or Blow out with the help of the opening element.

One Inventive method for providing of frozen particles for a deposition device with the aid of a cryocontainer according to the invention includes the steps: Removing the insulation element, positioning the cryocontainer relative to a deposition apparatus and actuating the opening element.

The opening element may be a slide-in bolt (or punch) that projects into the receiving space and upon actuation, the closure device by pressure regurgitates. The opening element can thereby be designed so that it is exclusively on the closure device Exerts pressure without putting pressure on the frozen ones To exert particles inside the receiving space. Thereby can be a pressure-induced melting and caking the frozen particles are prevented. Alternatively, the opening element, for example also as a lever or as a device for generating an overpressure be configured in the recording room.

According to one preferred variant, the opening element is set up, when operated, the frozen ones contained in the receiving space To move particles to the outlet opening. This can be done by a punch-shaped opening element can be achieved, which presses on the frozen particles when pressed and this pushes towards the exit opening, so that the pressure is passed on to the closure device and this is opened by it. This has an advantage when the frozen particles caked together, for example by crystallization are, and so by pressing the opening element can be solved from each other. About that It is also possible with such an opening element, to move the frozen particles towards the outlet, if the direction of motion is not a component in the direction of gravity has and thus actively transported the particles from the receiving space Need to become. The frozen particles can thus with the help of the opening element from the receiving space pushed out or pushed.

The Closure device may be from one of the interior of the receiving space consist of opening flap. According to one preferred embodiment, the closure device formed by a film which the outlet opening completely covers. The film preferably closes flush with the outlet opening limiting Surface of the container element from and forms the Contact surface of the cryocontainer.

The closure device is preferably formed by a film which seals the receiving space in a sterile, airtight and watertight manner. The film consists for example of plastic or metal. The thickness of the film is for example 0.01 mm to 1 mm, preferably 20 .mu.m to 200 .mu.m and particularly preferably 50 .mu.m or 100 .mu.m. The film is preferably such that it can be torn by the opening element. Advantageously, an additional thermal insulation layer is provided on the film. The film can with the surrounding the outlet opening edge of the Be container element, for example, be welded. The outlet opening of the container element is then preferably closed during the production of the cryocontainer, as long as the cryocontainer is still unfilled. The cryocontainer can be filled in this case via a second opening.

In a preferred embodiment of the invention Cryogenic container, the opening element is set up, to open the closure device mechanically upon actuation. In the case of a closure device made of foil, this opening can occur by simply piercing the film with a bolt or punch-shaped opening element from the inside take place, wherein the film is torn.

The opening element is preferably actuated by exerting a pressure on it. In a particularly preferred variant, the opening element from a push-in pin, which projects into the receiving space. Of the Insertion bolt is for example a cylindrical Bolt, which protrudes with one end into the receiving space and with an opposite end protrudes from the receiving space and by pressing this opposite end into the receiving space can be pushed. Preferably leads in this embodiment the operation of the insertion bolt to a piercing the closure device. This puncture of the closure device can either directly by direct contact of the insertion bolt with the closure device, such as a film done or by indirect pressure through transmission the pressure over the frozen particles. The insertion bolt preferably has a length such that it can be actuated the receiving space of the cryocontainer completely projects through. In this way it can be ensured that the Recording room by pressing the opening elements is completely emptied. This is useful for a precise dosage of the frozen particles for the deposition. Preferably, the inner shape of the container element, i. H. the shape of the receiving space forming cavity, and the outer shape of the opening element adapted so that after actuation the opening element no voids in the receiving space stay in which frozen particles can stay. For example, the container element is hollow cylindrical and the opening element is cylindrically shaped, wherein the Outer diameter of the opening element to the inner diameter of the container element corresponds.

The opening element is preferably made of a thermally insulating material. This allows the interior of the receiving space in the container element towards the environment via the opening element be thermally insulated. This is especially advantageous when the opening element is operated by hand, and so on, otherwise a heat transfer from the Hand to the interior of the recording room would be feared.

While storage of the filled cryocontainer should an actuation of the opening element avoided become. For this is in a preferred variant of the invention Cryo container provided a fixing element, which fixed the opening element in an inactive state. inactive Condition means unactuated condition. At an opening element in the form of a push-in bolt as described above, the fixing element for example, consist of a sapwood or a cross slide, the container element and the opening element at least partially penetrated and thus a mutual shifting prevented. The fixing element can at one end a handle element z. B. in the form of a pull tab on which it from the cryocontainer can be pulled out to solve the fixation. For the Providing the frozen particles in a deposition apparatus then first the fixation element has to be removed, before the opening element can be actuated.

For the storage of the frozen particles to this preferably safe from moisture or other contamination due to external influences to be protected. In a preferred embodiment has the cryocontainer according to the invention therefore, a film wrapper containing the cryocontainer from external influences such as moisture and contamination protects. Preferably, the film wrapping a sterile envelope. The film wrapping encloses preferably all components of the cryocontainer including of the insulation element. The foil wrapping can thus also serve as fastening means for the insulating element, by the container element and the insulation element together wrapped in a foil wrapper. Preferably the foil cladding removable. The foil cladding may for example consist of a shrink film. She points preferably a tear tab and / or a predetermined breaking point on, at which she can be torn and then easily removed from the cryocontainer and the isolation element can be.

In a preferred embodiment, the cryocontainer according to the invention also has a display element for indicating whether the cryocontainer has exceeded a predetermined temperature. For the storage of the frozen particles, which preferably contain biological material, different critical temperatures are to be considered depending on the storage duration, which should not exceed the particles during storage. These critical temperatures depend on the type of frozen particles. By way of example follow For a storage time of the particles of more than one year, the particles should not reach temperatures above -100 ° C, for example. For a storage period of 2 months to one year, the storage temperature should not exceed -80 ° C. For a storage period of 1 week to 2 months, for example, a critical temperature of -50 ° C is sufficient, which should not be exceeded during storage. For a storage period of up to one week, the temperature should preferably not exceed -20 ° C. Accordingly, the cryocontainer preferably has a display element which serves to control whether a respective critical temperature has been exceeded during storage and therefore the particles may possibly be discarded. For example, the display element may indicate the maximum temperature reached during storage. The display element can also be provided for the qualitative indication of whether certain predetermined critical temperatures have been exceeded in each case without specifying the respectively reached maximum temperature. The display element may discolor, for example, when a critical temperature is exceeded. As a display element, a display or a transponder system for labeling is possible. The indicator may provide different responses for more than one critical temperature. However, it can also be provided a display element, which indicates only the exceeding of a certain critical temperature, for example -50 ° C. The display element may for example be mounted on an outwardly facing side of the insulating element.

alternative the display element can be attached to the film wrapping so it's right at the time of taking the packaged in foil Cryo container checked from a cryogenic cabinet can be. Otherwise, the wrapping film is preferably - at least partially - transparent and thus gives the view of the Display element free, allowing quality and usability a stored in the cryocontainer material verifiable is without first opening the foil wrapper.

The The object of the invention is also achieved by a magazine for providing frozen particles for a deposition device for the deposition of the frozen particles with one or more images for a respective cryocontainer according to the invention, which is set up, each a cryogenic container relative to position the deposition device, and which one Activation element which is adapted to the opening element a cryogenic container oriented relative to the deposition device to press, so that the contents of the cryocontainer can enter the deposition device and for deposition provided. Preferably, the inventive Magazine several shots for inventive Cryo container on, at the same time with inventive Cryogenic containers can be loaded. these can then successively positioned relative to the deposition device be, so that in each case after actuation of the activation element and the opening elements the contents of the cryocontainer get into the deposition device and provided there for deposition become.

The Alignment or positioning of the cryocontainer relative to the deposition device means here that the outlet opening of the cryocontainer so to an opening of the deposition device is positioned that upon actuation of the opening element of the cryocontainer, the frozen particles from the cryocontainer enter the deposition device and thus for deposition to be provided. For example, the deposition device has a Drive device with an acceleration tube, in which the frozen particles are subjected to a driving force should. The acceleration tube has, for example, a lateral opening, through which the frozen particles as ammunition in the acceleration tube reach. With the magazine according to the invention is an inventive cryocontainer directly positioned at the lateral opening of the accelerating tube, so that the closure device of the cryocontainer and facing the opening of the accelerating tube, or adjoin one another. In this case it is not necessary that a contact surface of the cryocontainer and a bearing surface around the loading opening of Deposition device configured complementarily. The magazine can serve as an adapter at this point to a gapless Contact between cryocontainer and deposition device manufacture. Basically, the magazine can only one have only receptacle for a cryogenic container. It then serves as a positioning aid for the cryocontainer at the deposition device.

One Inventive method for providing of frozen particles of a deposition apparatus with a Cryogenic container according to the invention and a The magazine according to the invention comprises the steps: Removing the insulation element from the cryocontainer, Positioning the cryocontainer in a receptacle of the magazine, Positioning of a cryocontainer relative to the deposition device and actuating the activation element.

In a preferred embodiment, the magazine also includes a cooling device. For example, the magazine may be purged with liquid or cold gaseous nitrogen so that the cryocontainers received therein continue stay refrigerated. This is particularly useful when a plurality of cryocontainers are accommodated in the magazine and are positioned one after the other to the deposition apparatus to provide the frozen particles contained in the positioned cryocontainer for deposition. Preferably, the magazine is cooled in all parts.

Preferably the magazine can be placed on a deposition device fasten, with the magazine is so movable in each case a cryocontainer or a receptacle for a Cryogenic container relative to the deposition device positionable is. For example, in a magazine according to the invention several receptacles for cryocontainer circular arranged and the magazine is rotatable on the deposition device attachable, so that in each case a cryocontainer by rotation of the magazine is positionable relative to the deposition device. One Such magazine can be similar to a revolver drum several cryogenic containers are loaded, each one Cryogenic container is positioned by rotation of the magazine.

to Actuation of the opening element of a relative to the deposition device positioned cryocontainer the magazine has an activation element. The activation element itself, for example, is triggered manually or automatically driven.

The The object of the invention is also achieved by a deposition device which is responsible for the deposition of frozen particles is set up in a target substrate, and which is a charging device and a drive device. The charging device is for Providing the frozen particles to the drive means and comprises an inventive Magazine. The drive device is for exercising a Driving force set up on the frozen particles for their acceleration, and example includes an acceleration line, in which the frozen particles from an inventive Cryo containers are provided for deposition. Of the Cryo container is by means of an inventive Magazine positioned relative to the acceleration line and the opening element of the cryocontainer is actuated by the activation element. As a result, the closure device of the cryocontainer opened and the frozen particles in the acceleration line the deposition device provided.

With the inventive method for providing of frozen particles for deposition are preferred provided with biological material containing frozen particles. For example, the frozen particles contain biological cells, such as eukaryotic or prokaryotic cells.

The present invention will be described below with reference to the in the 1 to 3 embodiments shown further explained. They show schematically:

1A - 1E a cryocontainer according to the invention in a sectional view during various steps of the method according to the invention;

2A a cryocontainer of the invention 1 in a to the sectional view in 1 vertical sectional view;

2 B the cryocontainer according to the invention 1 in plan view of the base of the insulating element with a display element; and

3 a sectional view of a magazine according to the invention, which is arranged on a deposition apparatus and is loaded with cryogenic containers according to the invention.

The deposition device according to the invention 60 is in 3 shown only schematically with respect to the magazine according to the invention. For a more detailed illustration of the deposition apparatus, reference is made to the earlier German patent application DE 10 2007 004 855 the same applicant (unpublished on the priority date of this application).

An in 1 shown cryocontainer 40 has a hollow cylindrical container element 41 with a recording room 41a for frozen particles and an outlet 41b on. The hollow cylindrical container element 41 consists of a thermally insulating material and is made thick-walled to provide good thermal insulation between the receiving space 41a and to ensure the environment. The outlet opening 41b is with a closure device forming the film 49 flush closed. Inside the recording room are frozen particles 50 , On the slide 49 opposite side of the hollow cylindrical container element 41 is the recording room 41a through an opening element 43 locked. The opening element 43 is formed as an elongated cylindrical insertion bolt, which has one end in the receiving space 41a protrudes and with its other end on the front side of the hollow cylindrical container element 41 protrudes. In its outer diameter corresponds to the cylindrical opening element 43 approximately the inner diameter of the hollow cylindrical container element 41 so that they almost flush with each other.

On the outside of the film 49 from the receiving space 41a From the point of view, the cryocontainer points 40 an isolation element 45 on. Like the container lement 41 are the opening element 43 and the isolation element 45 made of thermally insulating material and made compact.

For fixing the opening element 43 in non-activated form is a fixing element 44 in the form of a transverse cotter, which is a relative displacement of the container element 41 and the opening element 43 prevented each other. The fixing element 44 has at one end a pull tab with which it out of the container element 41 and the opening element 43 is removable to release the fixation.

The cryocontainer has a sterile foil wrap 46 for protection against moisture or other contamination during storage. The foil wrapper is with a tear tab 47 equipped with which it can be torn open to remove it from the cryocontainer.

To provide frozen particles for a deposition apparatus with the cryocontainer, first the sterile foil wrapper is provided 46 by tearing open with the tear tape 47 away. Then the fixing element 44 with the pull tab from the container element 41 and the opening element 43 pulled out to the mutual fixation of opening element 43 and container element 41 to solve. Subsequently, the isolation element 45 removed from the closure device. The recording room 41a of the cryocontainer 40 is now only by the closure device in the form of thin film 49 separated from the environment. To thaw the frozen particles 50 inside the receiving space 41a to prevent therefore the isolation element 45 as long as possible until shortly before the provision for deposition on the film 45 held.

Generally, the process should preferably be performed at an ambient temperature of less than -10 ° C, if the whole process does not take longer than a few minutes. For slower handling, preferably less than -30 ° C should be present. If after removal of the insulation element 45 a longer period of time can be bridged, the cryocontainer can 40 without insulation element 45 For example, be placed on a cooled plate, so that from below continues to heat into the receiving space 41a of the cryocontainer 40 is prevented. The cryocontainer 40 is then as quickly as possible relative to a deposition device 60 positioned so that the frozen particles 50 now through the closure device 49 from the deposition device 60 are separated. The deposition device 60 is in 1E only partially shown in schematic sectional view through an acceleration line. The cryocontainer 40 lies with a contact surface 51 on a support surface 52 the deposition device 60 on. The bearing surface 52 the deposition device encloses a loading opening through which the frozen particles can enter the deposition device. The bearing surface 52 the deposition device 60 and the base area 51 of the cryocontainer 40 passing through the closure device 49 is formed, are designed complementary. In this case, both are formed as flat surfaces. The opening element 43 is by pressure on the top of the insertion bolt in the direction of the receiving space 41a operated until the insertion bolt 43 the recording room 41a completely penetrated. As a result, the sealing device formed as a film 49 pierced and the frozen particles 50 from the inside of the recording room 41a through the outlet 41b and the area enclosed by the on-opening in the deposition device 60 promoted. The actuation of the opening element takes place for example by pressure by hand.

2A shows one to the drawing level 1A vertical sectional view of the cryocontainer 1A , Shown is a hollow cylindrical thick-walled container element 41 with a cylindrical receiving space 41a in which a cylindrical opening element 43 plugged. container element 41 and opening element 43 be through the fixing element 44 with the pull tab protruding from the side. The entire cryocontainer is from the sterile, waterproof foil wrapping 46 surrounded with a tear tape 47 to open. Of the film wrapping is also an insulation element 45 enclosed on the bottom of the cryocontainer, which is in 1C is shown. 2 B shows the enclosed by foil cryocontainer 40 in plan view of the underside of the insulating element 45 , The isolation element 45 has an ad element 48 to indicate whether the cryocontainer has exceeded a predetermined critical temperature during storage. The insulating element is easily detachable adhered to the, the closure device forming film.

A magazine 61 for the provision of frozen particles for deposition with a deposition device (shown in U.S. Pat 3 ) has several shots 62 for each one cryocontainer 40 on. The magazine 61 is drum-shaped and about an axis 64 rotatable on a deposition device 60 assembled. For loading the magazine 61 with a cryogenic container 40 First, the foil wrapping 46 , the fixing element 44 and the isolation element 45 away. Then, the thus unlocked cryocontainer 40 with the closure device 49 ahead in one of the shots 62 placed so that the device formed as a film Verschlussvorrich 49 to the deposition device 60 shows. The magazine 61 is preferably cooled, so too while storing the cryocontainer in the magazine 61 a thawing of the frozen particles 50 is prevented.

To provide frozen particles 50 becomes the magazine 61 twisted so that a cryocontainer 40 relative to the deposition device 60 is positioned so that the outlet opening 41b of the cryocontainer 40 opposite an opening of the deposition device 60 is placed. Now it is activated by an activation element 65 the opening element 43 of the cryocontainer 40 actuated. The closure device 49 it will open and the frozen particles from the receiving space 41a pushed so that they get into the deposition device.

The deposition device 60 has an acceleration line 67 and an accelerator 68 with which a driving force on the now provided in the acceleration line frozen particles 50 can be exercised. Once the contents of a cryobank 40 was shot by twisting the magazine 61 the next cryocontainer 40 at the opening 66 the acceleration line 67 be positioned. Again, the opening element 43 the next cryogenic container 40 through the activation element 65 be operated. magazine 61 and also deposition device 60 are preferably cooled to thaw the frozen particles 50 to prevent. The frozen particles 50 are preferably accelerated so much that they reach the target substrate in the frozen state.

The in the above description, the claims and the Drawings disclosed features of the invention can both individually as well as in combination for the realization the invention in its various embodiments of importance be.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 102007004855 [0002, 0044]

Claims (20)

Cryogenic container ( 40 ), suitable for storage and provision of frozen particles ( 50 ), comprising: - a thermally insulating container element ( 41 ), the at least one receiving space ( 41a ) for frozen particles ( 50 ) and at least one exit opening ( 41b ), - a closure device ( 49 ), with which the at least one outlet opening ( 41b ) is closable, - at least one opening element ( 43 ), which is operable to the at least one outlet opening ( 41b ), and thereby the frozen particles ( 50 ) outside the outlet ( 41b ), and - an insulation element ( 45 ) for thermal insulation of the closure device ( 49 ). Cryogenic container ( 40 ) according to claim 1, wherein the insulating element ( 45 ) is removable from the cryocontainer. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the opening element ( 43 ) is set up, when operated in the recording room ( 41a ) contained frozen particles ( 50 ) to the exit opening ( 41b ) to move. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the closure device ( 49 ) comprises a film. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the opening element ( 43 ), the closure device ( 49 ) mechanically open when actuated. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the opening element ( 43 ) is actuated by pressure. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the opening element ( 43 ) is a insertion bolt, which in the receiving space ( 41a ) and its operation pierces the closure device ( 49 ). Cryogenic container ( 40 ) according to claim 7, wherein the opening element is dimensioned so that it the receiving space ( 41a ) completely penetrates after actuation. Cryogenic container ( 40 ) according to one of the preceding claims, wherein the opening element ( 43 ) is thermally insulating. Cryogenic container ( 40 ) according to one of the preceding claims, comprising a fixing element ( 44 ) for fixing the opening element ( 43 ) in an inactive state. Cryogenic container ( 40 ) according to one of the preceding claims, comprising a removable film wrapping ( 46 ) having. Cryogenic container ( 40 ) according to one of the preceding claims, comprising a display element ( 48 ) for indicating whether the cryocontainer ( 40 ) has exceeded a predetermined temperature. Magazine ( 61 ) for the provision of frozen particles ( 50 ) for a deposition apparatus ( 60 ) for the deposition of the frozen particles ( 50 ) with one or more recordings ( 62 ) for each cryocontainer ( 40 ) according to one of the preceding claims, which is arranged in each case a cryogenic container ( 40 ) relative to the deposition device ( 60 ), and that an activation element ( 65 ), which is arranged, the opening element ( 43 ) one to the deposition device ( 60 ) positioned cryocontainer ( 40 ), so that the contents of the cryocontainer ( 40 ) into the deposition apparatus ( 60 ) and is provided for deposition. Magazine ( 61 ) according to claim 13, comprising a cooling device. Magazine ( 61 ) according to one of claims 13 and 14, which is arranged on a deposition apparatus ( 60 ) to be attached. Magazine ( 61 ) according to claim 15, which is applied to a deposition apparatus ( 60 ) is rotatably fastened, and in which several recordings ( 62 ) for cryocontainers ( 40 ) are arranged in a circle, so that by turning the magazine in each case a cryocontainer ( 40 ) relative to the deposition apparatus ( 60 ) is positionable. Deposition device ( 60 ), designed for the deposition of frozen particles ( 50 ) in a target substrate, comprising a charging device and a drive device ( 67 ), wherein the charging device for providing the frozen particles ( 50 ) on the drive device ( 67 ) and the drive device ( 67 ) for applying a driving force to the frozen particles ( 50 ), characterized in that the loading device is a magazine ( 61 ) according to any one of claims 13 to 16. Method of providing frozen particles ( 50 ) for a deposition apparatus ( 60 ) with the help of a cryogenic container ( 40 ) according to one of claims 1 to 12, comprising the steps: - opening or detaching the insulation element ( 45 ), - positioning the cryocontainer ( 40 ) relative to one Deposition device ( 60 ), - actuating the opening element ( 43 ). Method of providing frozen particles ( 50 ) for a deposition apparatus ( 60 ) with the help of a cryogenic container ( 40 ) according to one of claims 1 to 12 and a magazine ( 61 ) according to any one of claims 13 to 16, comprising the steps of: - opening or detaching the insulating element ( 45 ), - positioning the cryocontainer ( 40 ) in a recording ( 62 ) of the magazine ( 61 ), - positioning of a cryogenic container ( 40 ) relative to the deposition apparatus ( 60 ), - activating the activation element ( 43 ). A method according to any one of claims 18 and 19, wherein the frozen particles ( 50 ) contain biological material.