Arrangement for the Contamination-Free Introduction of a Sterile Object from a Container into a Containment and Method Therefor

Abstract

The arrangement for the contamination-free introduction of a sterile object (3) from a vessel (2), which has been closed by means of a semipermeable cover (23), into a working chamber (90), which is surrounded by a wall (91), of a containment (9) firstly comprises a portal unit (7) having an access flange (71) which is arranged in the wall (91) and which forms a passage (75) from the outside into the working chamber (90), and a door (5) which sealingly closes the passage (75) and which, in order to be opened, can be moved into the working chamber (90). The arrangement furthermore comprises a vessel receptacle (6) having a repository (60) for holding a vessel (2) that has been introduced into the vessel receptacle (6), an opening for the introduction of the vessel (2) into the repository (60), and a flange (61) for interacting with the access flange (71). The arrangement furthermore includes a decontamination unit (4) which is designed to, when the door (5) has been closed, the vessel receptacle (6) has been docked to the access flange (71) and the vessel (2) has been stored in the vessel receptacle (6), decontaminate an outer surface, facing toward the door (5), of the cover (23). Based on this arrangement, a method for introduction is also disclosed.

Claims

1. An arrangement for the contamination-free introduction of a sterile object (3) from a vessel (2), which has been closed by means of a semipermeable cover (23), into a working chamber (90), which is surrounded by a wall (91), of a containment (9) comprising: a) a portal unit (7) having: aa) an access flange (71) which is arranged in the wall (91) and which forms a passage (75) from the outside into the working chamber (90); and ab) a door (5) which sealingly closes the passage (75) and which, in order to be opened, can be moved into the working chamber (90); and b) a vessel receptacle (6) having: ba) a repository (60) for holding a vessel (2) that has been introduced into the vessel receptacle (6); bb) an opening (65) for the introduction of the vessel (2) into the repository (60); and bc) a flange (61) for interacting with the access flange (71), wherein c) a decontamination unit (4) is designed to, when the door (5) has been closed, the vessel receptacle (6) has been docked to the access flange (71) and the vessel (2) has been stored in the vessel receptacle (6), decontaminate an outer surface, facing toward the door (5), of the cover (23).

2. The arrangement as claimed in claim 1, wherein: a) the door (5), in a closed position, is attached in a sealed manner to the access flange (71) from the side of the working chamber (90), and the access flange (71) borders an intermediate space (70) which is situated in the passage (75); and b) the cover (23) of the vessel (2) which has been placed in the vessel receptacle (6) is sealed between the flange (61) and the access flange (71) when the vessel receptacle (6) has been pivoted into abutment against the access flange (71).

3. The arrangement as claimed in claim 1, wherein the decontamination unit (4), with a direction of action into the passage (75), is installed directly on the door (5) or laterally with respect to the portal unit (7) which has the door (5) and the access flange (71).

4. The arrangement as claimed in claim 1, wherein the decontamination unit (4) is a radiation source, for example UVC, UV, E-beam or pulsed light, or is a fumigation device, for example for atomizing an H.sub.2O.sub.2 solution.

5. The arrangement as claimed in claim 2, wherein the decontamination unit (4) is furthermore utilizable for decontamination of the outwardly facing surface of the door (5), of the intermediate space (70) and of that surface of the access flange (71) which faces toward the intermediate space (70).

6. The arrangement as claimed in claim 1, wherein a transfer apparatus (95) which is equipped, in the working chamber (90), with a tool head (96) is designed to, when the door (5) has been opened, the vessel receptacle (6) has been docked to the access flange (71) and the vessel (2) has been stored in the vessel receptacle (6): a) detach the decontaminated part of the cover (23) from the vessel (2) and move it into the working chamber (90); b) move an inlay (28), which is optionally present in the vessel (2) and which is situated above the object (3), into the working chamber (90); and c) move the object (3) resting in the vessel (2) situated in the vessel receptacle (6) from said (2) vessel into the working chamber (90).

7. The arrangement as claimed in claim 1, wherein, in accordance with the use in the laboratory technology field, the pharmaceutical industry or the biotechnology field: a) the vessel (2) has the form of a trough-shaped tub; and b) the object (3) has the form of a nest with a raster of depression-like receiving contours (31) for the storage of containers (30), for example vials or syringes.

8. The arrangement as claimed in claim 7, wherein: a) the arrangement is assigned an input station (8) with an air stream flowing through a filter (80), which stream is intended for releasing the vessels (2) from packages (1) provided with, for example bag-like, enclosures (21,22) and for providing the vessels (2), under controlled clean-room conditions, before these are placed into the vessel receptacle (6); wherein b) the cover (23) which closes the vessel (2), and which is for example composed of nonwoven fabric such as Tyvek®, maintains the sterile state of the object (3), situated in an interior space (20) of the vessel (2), with the containers (30); and c) the cover (23) which closes the vessel (2) is preferably sealed against a vessel edge (24) of the vessel (2).

9. A method for the contamination-free introduction of a sterile object (3) from a vessel (2) into a containment (9), comprising the following sequence of process phases: a) removing the vessel (2), which has been closed by means of a cover (23) and which contains an object (3), from enclosures (21,22) under controlled clean-room conditions at an input station (8); b) providing the respectively individual vessel (2), which has been closed by means of the cover (23) and which has the sterile object (3) stored therein, for contamination-free introduction into a working chamber (90) of a containment (9); here: the passage (75) to the working chamber (90) is outwardly open but, into the containment (9), is closed by the door (5), the decontamination unit (4) is inactive, the repository (60) of the vessel receptacle (6) is open and empty, and the vessel receptacle (6) is detached from the portal unit (7); c) placing the provided individual vessel (2) into the repository (60); here: it remains the case that the passage (75) is outwardly open but, into the containment (9), is closed by the door (5), the decontamination unit (4) is inactive and the vessel receptacle (6) is detached from the portal unit (7), but now the repository (60) is filled with a vessel (2); d) moving the vessel receptacle (6) into abutment against the portal unit (7); here: the access flange (71) of the portal unit (7) and the flange (61) are sealed against one another; furthermore, the passage (75) into the containment (9) is closed by the door (5), the decontamination unit (4) is inactive and the repository (60) is filled with a vessel (2); and the passage (75) is also outwardly closed, specifically by the vessel receptacle (6) docked in a sealed manner to the portal unit (7); e) activating the decontamination unit (4) or bringing the latter into a state of action; here: it remains the case that the access flange (71) of the portal unit (7) and the flange (61) are sealed against one another, the passage (75) into the containment (9) is closed by the door (5), the repository (60) is filled with a vessel (2), and the passage (75) is also outwardly closed, specifically by the vessel receptacle (6) docked in a sealed manner to the portal unit (7); and now the outer surface, exposed to the door (5), of the cover (23) and the intermediate space (70) and all surfaces facing toward this are made sterile; f) deactivating the decontamination unit (4) or bringing the latter out of a state of action, and opening the door (5); here: it remains the case that the access flange (71) of the portal unit (7) and the flange (61) are sealed against one another, the repository (60) is filled with a vessel (2), the passage (75) is outwardly closed, specifically by the vessel receptacle (6) docked in a sealed manner to the portal unit (7), and the outer surface of the cover (23), the intermediate space (70) and all surfaces facing toward this are sterile; and now the passage (75) into the containment (9) is open; g) cutting open the cover (23) of the vessel (2); here: it remains the case that the access flange (71) of the portal unit (7) and the flange (61) are sealed against one another, the repository (60) is filled with a vessel (2), the passage (75) is outwardly closed, specifically by the vessel receptacle (6) docked in a sealed manner to the portal unit (7), the outer surface of the cover (23), the intermediate space (70) and all surfaces facing toward this are sterile, and the passage (75) into the containment (9) is open; and now the access to the object (3) situated in the vessel (2) is open; h) removing the object (3) from the vessel (2) and transferring the object (3) with the containers (30) stored therein into the working chamber (90) of the containment (9) for further processing; here: it remains the case that the access flange (71) of the portal unit (7) and the flange (61) are sealed against one another, the passage (75) is outwardly closed, specifically by the vessel receptacle (6) docked in a sealed manner to the portal unit (7), and the passage (75) into the containment (9) is open; and now the repository (60) is now filled only with the empty vessel (2); and i) returning the arrangement into the starting phase, that is to say moving the door (5) into the closed position, which is thus sealed against the access flange (71) again, pivoting the vessel receptacle (6) away from the access flange (71), and removing the empty vessel (2) from the repository (60).

10. The method as claimed in claim 9, wherein: a) after the vessel receptacle (6) with the vessel (2) that has been placed in the repository (60) has been moved into abutment against the portal unit (7) and before the decontamination unit (4) is activated or brought into its state of action, the object (3) is subjected to an integrity test in order to identify whether the content of the vessel (2) satisfies the cleanliness requirement; wherein, b) if the integrity test yields a negative result, the vessel receptacle (6) is pivoted away from the portal unit (7) in order for the, in effect, defective vessel (2) to be removed from the repository (60).

11. The method as claimed in claim 9, wherein the cutting-open of the cover (23) of the vessel (2), the removal of the object (3) from the vessel (2) and the transfer of the object (3) with the containers (30) stored therein into the working chamber (90) of the containment (9) are performed by means of the transfer apparatus (95) positioned in the working chamber (90).

12. The method as claimed in claim 11, wherein a cut-away part of the cover (23) is moved into the working chamber (90) by means of the transfer apparatus (95) positioned in the working chamber (90).

13. The method as claimed in claim 9, wherein: a) the individual vessel (2) which has been closed by means of the cover (23) is, together with its sterile content, specifically the object (3) stored in the vessel (2) and the containers (30) accommodated in said object (3), provided with at least one enclosure (21,22) and thus, in the delivered state, forms a package (1); and b) the provision of the individual vessel (2) before it is placed into the vessel receptacle (6) is performed, in an input station (8) belonging to the arrangement, as a release of the vessel (2) from the respective package (1) under controlled clean-room conditions.

Description

BRIEF DESCRIPTION OF THE APPENDED DRAWINGS

[0055] In the drawings:

[0056] FIG. 1A—shows a package composed of filled vessel with enclosures, in a transparent perspective view;

[0057] FIG. 1B—shows the vessel and the separate enclosures from FIG. 1A, in a perspective view;

[0058] FIG. 10—shows the vessel from FIG. 1A, with an object in the form of a nest for receiving a multiplicity of containers, with a single container, with an inlay and with a cover, in a diagrammatic exploded view;

[0059] FIG. 1D—shows the parts as per FIG. 10, placed one inside the other, in a transparent front view;

[0060] FIGS. 2A to 10B: show the arrangement according to the invention for the contamination-free introduction of an object into a containment with portal unit, input station and vessel receptacle, and also the sequence of the process phases, in diagrammatic illustrations;

[0061] FIG. 2A—shows process phase 1: removal of the vessel, which has been closed by means of a cover and which contains an object, from the enclosures under controlled clean-room conditions at an input station;

[0062] FIG. 2B—shows the enlarged detail X1 from FIG. 2A;

[0063] FIG. 3—shows process phase 2: provision of the vessel for introduction, passage into containment closed by door, vessel receptacle empty and detached from portal unit;

[0064] FIG. 4A—shows process phase 3: placement of the vessel into vessel receptacle;

[0065] FIG. 4B—shows the enlarged detail X2 from FIG. 4A;

[0066] FIG. 5A—shows process phase 4: movement of the vessel receptacle into abutment against the portal unit and closure between access flange and flange;

[0067] FIG. 5B—shows the enlarged detail X3 from FIG. 5A;

[0068] FIG. 6A—shows process phase 5: after a possible integrity test of the object, activation of the decontamination unit;

[0069] FIG. 6B—shows the enlarged detail X4 from FIG. 6A;

[0070] FIG. 7A—shows process phase 6: switching of the decontamination unit into a passive state, opening of the door, from the side of the containment, open access to the intermediate space as far as the cover;

[0071] FIG. 7B—shows the enlarged detail X5 from FIG. 7A;

[0072] FIG. 8A—shows process phase 7: transfer apparatus equipped with cutting tool on tool head enters intermediate space, cutting-open of the cover of the vessel;

[0073] FIG. 8B—shows the enlarged detail X6 from FIG. 8A;

[0074] FIG. 9A—shows process phase 8: transfer apparatus removes cut-away section of the cover and the inlay that may be present;

[0075] FIG. 9B—shows the enlarged detail X7 from FIG. 9A;

[0076] FIG. 10A—shows process phase 9: transfer apparatus lifts object out of vessel and moves object into working chamber of the containment for further processing; and

[0077] FIG. 10B—shows the enlarged detail X8 from FIG. 10A.

EXEMPLARY EMBODIMENT

[0078] With reference to the appended drawings, the detailed description of the arrangement according to the invention for the contamination-free introduction of a sterile object from a vessel into a containment will be given below, starting with an explanation of the structural design of vessel and object contained therein. Here, the introduction will be discussed on the basis of the illustrated successive sequence of the process phases, such that a description is given of the basic configuration of the arrangement and at the same time of the method steps for introduction performed using the arrangement.

[0079] For the entirety of the description that follows, the following statement applies: where reference designations are included in a figure for the purposes of clarity of the drawing, but said reference designations are not discussed in the directly associated text of the description, reference is made to the mention thereof in preceding or subsequent figure descriptions.

FIGS. 1A to 1D

[0080] In the delivered state, the vessel 2 situated in a first, outer enclosure 21 and possibly also in an inner, second enclosure 22 forms the package 1. The two enclosures 21,22 are each of bag-like form, are closed, and are preferably provided from a nonwoven fabric or with a nonwoven window. The vessel 2, which is for example of trough-like form and is typically composed of plastic, has, uppermost, a cover 23, normally likewise composed of nonwoven fabric, such as Tyvek®, which is sealed on the vessel edge 24. Alternatively, the cover 23 has a partial surface composed of nonwoven fabric in order to enable gaseous decontaminant to access the object 3 and the containers 30.

[0081] In the interior space 20 of the vessel 2, there is situated an encircling support shoulder 25, on which the object 3 accommodated in the interior space 20 is, as it were, suspended, said object being equipped with a multiplicity of containers 30. In the pharmaceutical industry, the term “tub” is common for the vessel 2, and the term “nest” is common for the object 3, whilst the containers 30 are for example in the form of vials or syringes. The object 3 has systematically positioned receiving contours 31, which are of complementary form with respect to the containers 30 and which serve for the ordered arrangement of the containers 30. A sheetlike inlay 28, in turn composed of nonwoven fabric, could lie loosely on top of the object 3. The entire interior of the package 1, that is to say the vessel 2, its interior space 20, the inner surfaces, the bottom side of the cover 23, the inlay 28 and the object 3 and the containers 30, have been made sterile by treatment.

FIGS. 2A to 10B

[0082] On the basis of this series of pairs of figures, which illustrate the basic construction of the device and the successive sequence of the process phases 1 to 9 during the introduction, the associated detailed explanatory description will now be given. Here, when discussing the respectively next process phase, only the changes in relation to the preceding process phase will be characterized.

FIGS. 2A and 2B—Construction of the Device and Process Phase 1

[0083] In the containment 9, only a fragment of which is illustrated for this explanation, there is situated the working chamber 90 which is surrounded by the wall 91 and above which there is arranged an inlet filter 92 for the feed of a purified air stream into the working chamber 90. The working chamber 90 is equipped with a transfer apparatus 95, which, first and foremost, has a tool head 96. An exhaust-air filter 93 is installed in the lower region of the working chamber 90.

[0084] Installed in the wall 91 is a portal unit 7 which has an access flange 71, which access flange has a first seal 72 and borders an intermediate space 70. If not shut off on one side by the closed door 5 and/or on the other side by the vessel receptacle 6 that has been moved into abutment, said intermediate space 70 forms a passage 75 from the outside to the working chamber 90. The door 5 equipped with a second seal 52 is provided within the working chamber 90 and can be moved from a closed position, in which it is set into abutment against the access flange 71, into an open position, in which it has been pivoted into the working chamber 90. The door 5 is simultaneously the support for a decontamination unit 4, preferably by means of UVC radiation. The vessel receptacle 6 is positioned close to the portal unit 7, at the outside on the containment 9, and preferably so as to be pivotable into abutment against the access flange 71, and has the repository 60, accessible through the opening 65, and a flange 61 with the third seal 62 provided thereon.

[0085] In a simplified construction, the first seal 72 on the access flange 71 and the second seal 52 on the door 5 may be combined to form one common seal 72/52 arranged on the access flange 71. Such a combined seal 72/52 encompasses the access flange 71 at its inner surfaces facing toward the intermediate space 70, and thus acts at one side between the closed door 5 and the access flange 71 and at the other side between the vessel receptacle 6, which has been pivoted into abutment, and the access flange 71.

[0086] Adjoining the containment 9, there is situated the input station 8 with the filter 80 installed at the top and with the side walls 81 for conducting a downwardly flowing air stream generated by the filter 80. The input station 8 allows the removal of the vessel 2, which is closed by means of the cover 23 and contains an object 3, from the enclosures 21,22 under controlled clean-room conditions, and the provision of the vessel 2 for introduction.

[0087] In process phase 1, the following situation exists: [0088] In the input station 8, in the air stream flowing through the filter 80, the enclosures 21,22 are removed from the package 1 under controlled clean-room conditions, and the removed vessel 2 is provided. The sealed cover 23 maintains the sterile state of the object 3 with the containers 30 situated in the interior space 20. The outer surface of the cover 23, however, is no longer guaranteed to be sterile at any rate after the removal from the enclosures 21,22 and as a result of the contact with the atmosphere. [0089] The door 5 is in the closed position, sealed against the access flange 71 by means of the second seal 52, and the decontamination unit 4 and the transfer apparatus 95 are inactive. [0090] The vessel receptacle 6 with empty repository 60 has been pivoted away from the access flange 71. [0091] The passage 75 into the working chamber 90 has been shut off by the closed door 5, and the intermediate space 70 is open to the outside.

FIG. 3—Process Phase 2

[0092] The following situation now exists: [0093] The entire, now unpacked vessel 2 with the cover 23 which closes it and with the object 3 stored in the vessel 2 is situated, ready for introduction, in the input station 8.

FIGS. 4A and 4B—Process Phase 3

[0094] The following situation now exists: [0095] The entire vessel 2 has been placed from the input station 8 through the opening 65 into the vessel receptacle 6, which remains pivoted away from the access flange 71. [0096] Preferably, the vessel edge 24 projects beyond the opening 65, such that the vessel edge 24 is supported on the flange 61, and the vessel 2 is suspended in the repository 60.

FIGS. 5A and 5B—Process Phase 4

[0097] The following situation now exists: [0098] The vessel receptacle 6 with the vessel 2 accommodated therein has been pivoted into abutment against the access flange 71. Here, the third seal 62 effects the reliable seal between flange 61 and access flange 71, and the first seal 72 effects the reliable seal between flange 61 and vessel edge 24, or the preferably sealed cover 23 thereon. [0099] The passage 75 into the working chamber 90 remains shut off by the closed door 5, but now also to the outside by the vessel receptacle 6 that has been pivoted into abutment, such that the intermediate space 70 is now hermetically insulated on all sides. [0100] The content of the vessel 2 may be subjected to an integrity test in order to identify, before the process is continued, that the content satisfies the cleanliness requirement. [0101] The first seal 72 is activated.

FIGS. 6A and 6B—Process Phase 5

[0102] The following situation now exists: [0103] The decontamination unit 4 is brought into a state of action in order to make the intermediate space 70, all surfaces facing toward this, that is to say the inner annular surface of the intermediate flange 71, the outer surface of the cover 23 and the possible free surface on the first seal 72, sterile.

FIGS. 7A and 7B—Process Phase 6

[0104] The following situation now exists: [0105] The decontamination unit 4 is deactivated or is retracted while remaining in an activated state. [0106] The door 5 is opened by movement into the interior of the working chamber 90, such that the passage 75 into the intermediate space 70 as far as the cover 23 is accessible from the interior of the working chamber 90.

FIGS. 8A and 8B—Process Phase 7

[0107] The following situation now exists: [0108] The cutting tool on the tool head 96 of the transfer apparatus 95 is brought into use and pivots toward the intermediate space 70 in order to cut away the cover 23 in order to enable the object 3 to be removed from the vessel 2.

FIGS. 9A and 9B—Process Phase 8

[0109] The following situation now exists: [0110] The gripping tool on the tool head 96 of the transfer apparatus 95 is brought into use in order to move the cut-away cover 23 and possibly also the inlay 28 lying on top of the object 3 into the interior of the working chamber 90.

FIGS. 10A and 10B—Process Phase 9

[0111] The following situation now exists: [0112] By means of the gripping tool on the tool head 96 of the transfer apparatus 95, the object 3 is gripped, lifted out of the vessel 2 and moved into the working chamber 90. [0113] The object 3 with the containers 30 stored therein is supplied to the further processing operation in the containment 9. [0114] The empty object 3 can be placed back into the vessel 2. [0115] The arrangement is brought into the process phase 1 or 2, that is to say the door 5 is moved into the closed position and is thus sealed against the access flange 71 again. The vessel receptacle 6 is pivoted away from the access flange 71 in order for the vessel 2, which is now empty or laden with the empty object 3, to be removed from the vessel receptacle 6.