PROCESS FOR PREPARING A LYOPHILISED MATERIAL
A process for preparing a lyophilized material, providing a container having a penetrable envelope and containing the material in a carrier liquid, whereby the penetrable region is penetrated with a penetrator which provides a conduit through the envelope, and the carrier liquid id evaporated out of the container via the conduit, after which the penetrator is withdrawn. Apparatus suitable for performing the process is also disclosed.
This invention relates to a process for providing lyophilised materials and to apparatus for use in such a process.
Lyophilisation is a well known process in the pharmaceutical and vaccines industries in which a dispersion, e.g. a solution or suspension, of a material in a carrier liquid, normally aqueous, is frozen then exposed to reduced pressure to cause the liquid to evaporate, e.g. to perform a sublimation transition from the frozen to the vapour state. This process makes it possible to withdraw water contained in a material to make the material more stable at ambient temperature and thus to facilitate its conservation. A typical lyophilisation process is disclosed in EP-A-0 048 194.
Normally the dispersion is contained in a container typically a vial, which is exposed to the reduced pressure so that the liquid can evaporate out through an opening of the container e.g. the open mouth of a vial. Vial closures are known which can be mated with a vial mouth in a first, upper, position leaving a vent for the escape of evaporating liquid, and which can be moved downward into a second position when the lyophilisation process is complete to seal the vial. Typically vials which such closures in their upper, vented, position are arranged in a two dimensional array on a shelf for freezing and then exposure to a reduced pressure. Plural shelves are stacked vertically above each other with the underside of an upper shelf above the closures of vials on the shelf below, and when the lyophilisation process is complete upper shelves are lowered onto the closures of vials on the shelf immediately below to push the closures into the lower closed position.
Numerous types of apparatus are known for performing the lyophilisation process on such containers, generally comprising a chamber which can be hermetically closed with the containers inside and inside which suitable conditions of temperature and reduced pressure can be maintained.
A specific type of vial with a closure is disclosed in WO-A-04/018317 but is not disclosed therein for use in a lyophilisation process.
Some problems of known lyophilisation processes using the above described vials are that the mouth openings and vents of these known vials allow opportunity for ingress of contamination after a dispersion of the material has been introduced into the vial, e.g. during the subsequent stages of loading the vial containing the dispersion onto shelves suitable for the lyophilisation apparatus and of transporting such vials to the lyophilisation apparatus.
It is an object of the present invention to address these problems, and to offer further advantages, as will be disclosed below.
In a first aspect this invention provides a process for preparing a lyophilised material comprising:
providing a container bounded by an envelope having a penetrable region and containing a dispersion of the material in a carrier liquid,
with the penetrable region penetrated with a penetrator such that the penetrator provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region,
evaporating the carrier liquid out of the container via the conduit,
withdrawing the penetrator from the penetrable region.
Such a process may be performed by providing a container bounded by an envelope having a penetrable region and containing a dispersion of the material in a carrier liquid, penetrating the penetrable region with the penetrator such that the penetrator provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region, evaporating the carrier liquid out of the container via the conduit, then withdrawing the penetrator from the penetrable region.
The container may be a vial, e.g. a typical pharmaceutical vial, made of glass or plastics material, having a mouth opening closed by an elastomeric closure e.g. which plugs into the mouth opening, and the penetrable region may comprise a region of this elastomeric closure. In such a construction the combination of vial and closure comprise the said envelope.
Evaporation of the carrier liquid out of the container via the conduit may be by generally conventional lyophilisation conditions, e.g. maintaining the dispersion at a temperature such that the carrier liquid is frozen, and application of reduced pressure so that the frozen liquid sublimates directly from the solid to the vapour state. Suitable conditions of temperature and reduced pressure are for example disclosed in the Example of EP-A-0 048 194.
By “penetrates” and derived terms as used herein is included at least partially penetrates, and the term includes opening a communication passage through the penetrable region, for example actual passage of the penetrator from one surface of the envelope to another, e.g. puncturing and physically disrupting of the envelope, expansion of an already existing hole by means of the penetrator, disruption of a weakened area of the envelope by the penetrator to create an opening through the envelope.
The penetrable region may comprise a previously-formed puncture hole. For example such a previously-formed formed puncture hole may have been formed by driving a puncturing means such as a needle through the penetrable region. Such a needle may be a hollow filling needle which has been passed through the envelope and via which the dispersion has been introduced into the vial, the needle then subsequently withdrawn, and the liquid so introduced may subsequently be cooled and frozen for lyophilisation. For example such a needle may be passed through the elastomer closure of a vial. Typically with a suitable thickness of the elastomer material of the closure the elastic nature of the closure causes the elastomer material to close when the needle has been withdrawn, to thereby close the residual needle hole sufficiently to reduce the possibility of contaminants entering the vial via the puncture hole before the hole can be sealed. This offers the advantage that after introducing the liquid into a vial using a filling needle there is much less opportunity for contamination to enter the vial than would be the case with the above-mentioned known vial in which, after a liquid has been introduced into the vial, the closure is inserted into the vial mouth but in a partly open vented state. Also, advantageously after filling using such a filling needle and leaving a closed puncture hole the vial may be inspected through its transparent wall for particles, with less threat of contamination than would be with the known vials.
The process of the invention may therefore include the preceding step of providing the container bounded by an envelope having a penetrable region therein by passing a hollow filling needle through the envelope, introducing the dispersion into the container via this needle, then subsequently withdrawing the needle to leave a residual puncture hole in the closure. Preferably such a filling needle has a pyramidal point, as it is found that such a needle cuts a hole in controlled directions. Preferably such a pyramidal point has three faces to cut the hole in three controlled directions. A preferred construction of such a filling needle is for example disclosed in WO2004/096114.
A suitable construction of such a vial and closure is that disclosed in WO-A-04/018317, specifically as disclosed in and with reference to
In this embodiment the said exposed region of such an elastomeric closure, suitably when previously punctured by a needle as described above, may comprise the penetrable region. An advantage of such a vial is that it may be provided sealed by the closure and with a sterile interior, e.g. sterilised by radiation, or for example when made in a sterile state by the manufacturing process disclosed in WO2005/005128.
The process preferably comprises the further step of sealing or otherwise covering the penetrable region after the penetrator has been withdrawn from the penetrable region.
In another aspect the invention provides apparatus suitable for use in the process described herein comprising:
a penetrator capable of penetrating a penetrable region of a container bounded by an envelope having a penetrable region therein and containing a dispersion of the material in a carrier liquid such that the penetrator when penetrating the penetrable region provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region,
means to cause the penetrator to penetrate the penetrable region,
means to evaporate the carrier liquid out of the container via the conduit,
means to withdraw the penetrator from the penetrable region.
Suitable embodiments of the process, containers suitable for use with the process, and the apparatus, and working relationships between them will now be described.
The penetrator may be suitable to form a hole or enlarge a pre-existing hole through the penetrable region of the envelope, e.g. through the elastomer closure of a vial. The penetrator may be shaped, e.g. in cross section, to provide a conduit through the envelope when the penetrator has penetrated the envelope. In an embodiment the penetrator may comprise a generally tubular member having an end adapted to penetrate the penetrable region e.g. a pointed end. Alternatively the penetrator may have one or more concavity in its outer surface to provide such a conduit between the penetrator and the adjacent surface of the penetrable region. Typically such an end may be generally pointed. For example the penetrator may comprise a generally conical member, e.g. a hollow cone with an open base or an opening adjacent its base, and an opening adjacent its apex, with a conduit passing through the penetrator, e.g., linking the opening at the apex and the open base, such that its apex may penetrate the penetrable region and vapour of the carrier liquid may enter the apex, pass through the hollow interior of the cone and exit via the conduit. Such a conduit should be of suitable dimensions to allow flow of the vapour of the evaporating liquid at a sufficient rate that lyophilisation can be achieved in an acceptable time, i.e. similar to known lyophilisation processes, which will be known to those in the art. To achieve this, typically at its narrowest the conduit should have a cross section of at least 1 mm, preferably 2 mm or more.
The conduit may incorporate a barrier which is permeable to gases but obstructs the passage of particles and in particular of microorganisms to thereby reduce the likelihood of contamination entering the container. Such a barrier may comprise a thin permeable membrane, for example made of a sterile filtration media.
In a first embodiment of the process and apparatus of the invention, the penetrator may be mountable on the container, e.g. on a vial, so that the penetrator can be moved, suitably reciprocally, from a first position in which the penetrator is outside the container and does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region, and preferably then back towards a first position in which the penetrator is outside the container and does not penetrate the penetrable region.
In one form of this first embodiment, the penetrator may be provided in combination with a guide whereby the penetrator may be mounted on the container. Such a combination comprises a further aspect of this invention, comprising:
a penetrator adapted to penetrate a penetrable region of the envelope of a container to thereby provide a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region, and
a guide which is mountable on the container to thereby support the penetrator so that the penetrator can be moved from a first position in which the penetrator does not penetrate the penetrable region to a second position in which the penetrator penetrates the penetrable region, and optionally back toward a first position in which the penetrator does not penetrate the penetrable region.
For example a guide may be removably mounted on the container, capable of supporting and guiding the penetrator for such movement. In an embodiment, particularly suitable for the above-mentioned generally conical penetrator, and particularly when the container is a vial with an elastomeric closure, the guide may comprise a generally cylindrical sleeve or part sleeve within which the penetrator is movable, suitably reciprocally.
In a preferred construction of this last-mentioned apparatus, the penetrator and the guide may be made integrally, e.g. of plastics material by means of injection moulding. In this construction the penetrator and guide may be so made initially linked by one or more thin frangible integral link and with the penetrator in the first position, so that so that as the penetrator is moved from the first position toward the second position severance of the link(s) occurs.
When the vial is of the above-mentioned type disclosed in WO-A-04/018317 such a guide may be mountable upon the vial by removable engagement with the clamp part. In a preferred type of vial disclosed in WO-A-04/018317 the clamp part is itself provided with means for engagement of a cover part, being the groove 37 disclosed in FIG. 1 of WO-A-04/018317, and the guide may engage in a snap-fit with such a groove. It may be preferable to engage such a removable guide with the container such as a vial before any liquid content in the vial is frozen, as engagement features such as a snap-fit engagement may become brittle and lose their resilience at the low temperatures normally used for freezing liquids in lyophilisation processes.
The penetrator may be caused to penetrate the penetrable region by relative movement of the penetrator and the container such that the end adapted to penetrate the penetrable region contacts the penetrable region and penetrates it. For example if the penetrator comprises a tubular member with a pointed end or apex of a cone this may be a movement parallel to the longitudinal axis of the tubular member or base-apex axis of the cone.
This movement may be caused by application of a force to the penetrator to urge the penetrator in this direction. As mentioned above it is common practice in the art of lyophilisation to arrange vials for exposure to a reduced pressure in a two dimensional array on a shelf, and to stack plural shelves vertically above each other for exposure. Therefore in the process the application of force to the penetrator to urge the penetrator in the first position toward the second position direction may be achieved by arranging containers, e.g. vials, in a two dimensional array on a shelf, then causing a member to bear upon the penetrator to urge the penetrator in this direction. Such a member may comprise part of a vertically upper adjacent shelf caused to bear upon the penetrator to urge the penetrator in this direction. During the process of evaporation of the liquid this member e.g. upper shelf may bear upon the penetrator to maintain the penetrator in position.
The penetrator, and/or guide may incorporate suitable vent means e.g. apertures so that contact of such a shelf with the penetrator does not impede outflow of vapour of the carrier liquid through the conduit.
In another form of this first embodiment a penetrator is provided which is itself mountable on the container, such as a vial, in a position in which the penetrator is penetrating the penetrable region, e.g. the elastomeric closure of a vial.
Such a penetrator may as above comprise a generally conical member, and may be made of plastics material by means of injection moulding. Such a penetrator may be mountable on the container such as a vial by means of a snap fit engagement. When the vial is of the above-mentioned type disclosed in WO-A-04/018317 such a penetrator may be mountable upon the vial by removable engagement with the clamp part thereof, which as mentioned above is itself provided with means for engagement of a cover part, being the groove 37 disclosed in FIG. 1 of WO-A-04/018317, and the penetrator may engage in a snap-fit with such a groove. For example such a penetrator may comprise the conical member at least partly surrounded by a skirt extending in the cone base-apex direction, the skirt having snap-fit engagement means adjacent the rim furthest from the cone base. The conduit through the penetrator may be closed by a barrier membrane which allows gases to pass through but not particulate contaminants.
It may be preferable to engage such a penetrator with the container such as a vial before any liquid content in the vial is frozen, as engagement features such as a snap-fit engagement may become brittle and lose their resilience at the low temperatures normally used for freezing liquids in lyophilisation processes.
In use this form of penetrator may be mounted e.g. by the snap fitting onto a vial, penetrating the elastomeric closure so that the liquid may be evaporated from the vial, typically after being frozen solid. Thereafter the penetrator may be removed from its mounting on the vial. To facilitate the mounting of the penetrator on the container a mounting tool may be provided to bear upon the penetrator so that for example a snap-fit engagement engages. To facilitate the removal of the penetrator from the container a removal tool may be provided. In one construction snap fit means on the penetrator may be provided with a disengagement means, for example a pivot lever upon which the removal tool may bear to disengage the snap-fit engagement.
In a second embodiment of the process and apparatus of the invention, plural containers, e.g. vials, may be situated on an upward facing surface of a lower shelf, and a vertically adjacent upper shelf may comprise plural penetrators, and the upper and lower shelves may be moved relatively toward each other, so that the penetrators thereof are thereby moved reciprocally from a first position in which the penetrator does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region, and back into a first position in which the penetrator does not at least partly penetrate the penetrable region.
An apparatus is therefore provided particularly suitable for this second embodiment of the process, comprising a lower shelf having an upwardly facing surface suitable for locating plural containers, e.g. vials, thereon, and a vertically adjacent upper shelf having a downward facing surface which comprises plural penetrators, the upper and lower shelves being movable relatively toward each other, so that the penetrators thereof are thereby moved from a first position in which the penetrator does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region, and reciprocally back towards a first position in which the penetrator does not penetrate the penetrable region.
Such upper and lower shelves and the penetrators of this apparatus of the second embodiment may be made of metals suitable for lyophilisation processes, e.g. stainless steel.
In thus second embodiment the upper shelf may be moveable downwardly toward the lower shelf, or the lower shelf may be moveable upwardly toward the lower shelf, or the upper shelf may be moveable downwardly and the lower shelf may be moveable upwardly.
In this second embodiment each penetrator may comprise a generally conical member with its apex pointing downwardly from a lower surface of the upper shelf toward the lower shelf, e.g. a hollow cone with a opening adjacent its apex, and an open base, such that its apex may penetrate the penetrable region and vapour of the carrier liquid may enter the apex, pass through the hollow interior of the cone and exit via the open base, e.g. as described above. Such a penetrator may be made integrally with the upper shelf, or may be attached to the upper shelf.
This second embodiment of the apparatus may comprise an upper shelf having an upward facing surface on which are situated plural containers such as vials, and vertically adjacent to this first upper shelf there may be a further upper shelf which comprises plural penetrators above this upward facing surface, and this further upper shelf may be moved analogously to the upper shelf described above. The further upper shelf may itself have an upward facing surface on which are situated plural vials, so that plural such shelves may be stacked vertically relative to each other.
The weight of an upper shelf may be sufficient to maintain the penetrator, in both embodiments of the apparatus, in the second position penetrating the penetrable region, e.g. of an elastic closure against the elasticity of the closure, and/or upper and lower shelves may be held together during the evaporation procedure. Thereafter the upper and lower shelves may be moved relatively vertically apart so that the penetrator is moved toward the first position. The elasticity of an elastomeric closure can tend to urge the penetrator out of the second position.
When the weight of an upper shelf is used to hold the penetrator in the second position, penetrating the penetrable region, the elasticity of e.g. an elastomeric closure may be insufficient to subsequently urge the penetrator from the closure back towards the first position. In such a situation means may be provided to move the upper and lower shelves relatively closer together and relatively further apart, and such means may be conventional means known for raising and/or lowering shelves. For example the vertically adjacent shelves may be resiliently biased toward the first position, for example by a spring means between them.
Force applied to the penetrator and/or restraint of movement of the penetrator, e.g. the weight of an upper shelf bearing downwards upon the penetrator, may be necessary to maintain the penetrator in the second position penetrating an elastic closure against the elasticity of the closure. When such force or restraint is released e.g. by increasing the vertical separation between the lower and upper shelves until the upper shelf no longer bears on the penetrator, the elastic will tend to spring back to eject the penetrator from the closure. Increasing the vertical separation may be done whilst the elastomer closure is at the reduced temperature and then allowing the closure to warm toward ambient temperature, or alternatively the closure may be allowed to warm to ambient temperature before increasing the vertical separation.
The penetrator may be withdrawn from the penetrable region toward the first position by a movement of the penetrator relative to the container such that the end adapted to penetrate the penetrable region is withdrawn from the penetrable region. Suitable means to withdraw the penetrator from the penetrable region may use the elasticity of the elastomer material of a vial closure.
For example in processes and apparatus comprising a lower shelf upon which plural vials may be arranged in a two dimensional array, and a second shelf vertically above the first shelf and able to be moved downwardly, suitable means may comprise a means to move the upper and lower shelves apart. Such means may be generally conventional as used in lyophilisation processes.
Alternatively the upper and lower shelves may be biased toward the above-mentioned first position.
When the process of the invention is a lyophilisation process in which the dispersion is maintained at a temperature such that the carrier liquid is frozen, and sublimating the liquid directly from the solid to the vapour state under reduced pressure, at such reduced temperatures an elastomer as used for a vial closure is likely to become less elastic, hindering the ability of a penetrator to penetrate an elastomer closure. Therefore it is preferred that the penetrator penetrates such a closure before the liquid has been frozen by the reduced temperature. The elasticity of the elastomer material of a vial closure may be employed to move the penetrator back toward a first position in which the penetrator is outside the container and does not extend through the penetrable region. The elastic nature of such a closure will tend to close the penetration hole resulting from the penetration by the penetrator, and will tend to spring back to eject the penetrator from the closure. The elastomer material of a vial closure can become less elastic at lower temperatures. Therefore when the process of the invention is the above-mentioned lyophilisation process it is preferred to allow the temperature of the closure to rise toward, preferably to, ambient temperature before withdrawing the penetrator, so that the elasticity of the closure is more effective.
When the evaporation operation is completed the pressure within the container may be returned to atmospheric by the ingress of a sterilised atmosphere e.g. air or an inert gas (herein the term “sterile” and derived terms means any reduction of the level of undesirable matter such as micro-organisms etc. to a level which is acceptable in the field of lyophilised materials such as drugs or vaccines). This is preferably done before the penetrator is withdrawn so that such an atmosphere may enter the container via the conduit, and before the elastic closure of a vial has sprung back to close the puncture hole.
Suitably the apparatus also comprises means to reduce the temperature of the carrier liquid to a temperature at which it is frozen solid. Such means may comprise a hermetically sealable refrigerated enclosure in which the container and penetrator, and suitably the means to cause the penetrator to at least partly penetrate the penetrable region and the means to withdraw the penetrator from the penetrable region, may be enclosed.
Suitably the apparatus also comprises means to evaporate the carrier liquid out of the container via the conduit. Such means may comprise a conventional vacuum chamber as used in conventional lyophilsation processes to apply reduced atmospheric pressure to the liquid in its frozen state.
Suitably the apparatus also comprises means to returned the pressure to atmospheric by the ingress of a sterilised atmosphere when the evaporation operation is completed.
Suitably the apparatus also comprises means for providing a penetrable region by forming a puncture hole in the envelope. For example such means may comprise a hollow filling needle which can be passed through the envelope, for example through the elastomer closure of a vial, and via which the dispersion may be filled into the vial, and which can be subsequently withdrawn. Such means may be as discussed above.
Therefore a preferred sequence of operations for the process of this invention is firstly to introduce the liquid into the container, then to penetrate the penetrable region with the penetrator, then to reduce the temperature of the liquid in the container until it is frozen, then to evaporate the frozen liquid to thereby lyophilise the content, then to allow the temperature of the closure to rise toward ambient temperature, then to return the pressure toward atmospheric, then to withdraw the penetrator.
Preferably in a subsequent step of the process the residual hole through the penetrable region left by the penetrator is sealed. This may be achieved in various ways. For example in one way the material of the envelope, e.g. the vial closure, may be melted e.g. by application of heat or other radiation and allowed to cool and set. Such a process is for example disclosed in US-A-2002/0023409 and WO-A-2004/026735. Additionally or alternatively a cover means may be attached to the container to close the site where the penetrator has penetrated the container. Alternate sealing means may be used, for example fixing a sealing means such as a patch or fluid substance which subsequently sets, to the penetration site. It may be advantageous to remove the above-mentioned removable guide, if used, from the container before this sealing operation. The containers may be transferred by suitable means such as a conveyor to a station where a sealing operation may be performed to seal the penetration site.
After sealing the residual hole through the penetrable region left by the penetrator, if the container is a vial of the type disclosed in WO-A-2004/018317 a cover part as disclosed therein may be engaged with the vial to cover the now-sealed penetrable region.
Suitably the apparatus also comprises means for sealing the residual hole through the penetrable region left by the penetrator, which may be achieved in various ways, as discussed above. Such means may comprise a means to direct laser radiation at the site of the residual hole.
Suitably, if the container is a vial of the type disclosed in WO-A-04/018317 the apparatus may comprise means to engage a cover part with the vial to cover the sealed penetrable region.
Therefore an overall process of the invention may comprise the steps of:
introducing a dispersion of the material in a carrier liquid into a vial closed by an elastomer closure by passing a hollow filling needle through the elastomer closure and introducing the liquid through the needle, then withdrawing the needle to leave a residual puncture hole through the closure;
penetrating the elastomer closure with a penetrator such that the penetrator provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region;
reducing the temperature of the liquid so that the liquid freezes solid;
evaporating the carrier liquid out of the container via the conduit by means of reduced atmospheric pressure;
causing the temperature of the elastomer closure to rise toward, preferably to, ambient and preferably re-pressurising the inside of the vial with a sterile atmosphere;
withdrawing the penetrator from the penetrable region, then preferably sealing the residual puncture hole.
In a further aspect the invention provides a container suitable for use in a process or apparatus of the first embodiment as described above, having a penetrator moveably mounted thereon, e.g. on a vial, the penetrator being moveable reciprocally from a first position in which the penetrator is outside the container and does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region such that the penetrator provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region, and preferably back toward a first position in which the penetrator is outside the container and does not penetrate the penetrable region.
In this last-mentioned apparatus the penetrator may be as described for the preceding aspects of the invention, and may be mounted on a guide as described above. For example in an embodiment particularly suitable for container being a vial, and the above-mentioned tubular or conical penetrator, the guide may comprise a generally cylindrical sleeve or part sleeve within which the penetrator is reciprocally movable.
Suitable and preferred features of such a container having a penetrator moveably mounted thereon are as discussed above.
The invention also provides the use of such a container having a penetrator moveably mounted thereon in a process and apparatus of the first and second aspects of this invention.
The invention will now be described by way of non-limiting example only with reference to the accompanying drawings which show:
Referring to
The vial 10 contains an aqueous solution 17 of a vaccine material to be lyophilised after subsequently being frozen into a solid plug by reducing its temperature. The closure 13 has a puncture hole 18 passing completely through it. The solution 17 has been previously introduced into vial 10 by a process of radiation sterilising the interior of the vial 10, passing a hollow filling needle (not shown) through the closure 13, introducing the solution 17 into the vial 10 via this needle, then subsequently withdrawing the needle to leave the puncture hole 18. The closure 13 is sufficiently elastic that after the needle has been withdrawn the elastomer material of the closure springs together to physically close the puncture hole 18 by compressing the sides of the hole 18 together.
A penetrator 20 is shown moveably mounted on the vial 10. Penetrator 20 comprises a generally hollow conical member with its apex pointing downwardly toward the upper outer surface of the closure 13. The conical member 20 has an opening 21 at its apex with a narrowest cross section ca. 2 mm, and has an open base and has a hollow interior. The conical member 20 is moveably mounted on the vial 10 by means of the member 20 being reciprocally moveable within a cylindrical guide 30 which is removeably mounted on the clamp part 15, by means of the guide 30 having a snap fit bead 31 adjacent its lower end which can snap-fit engage with a groove 19 in the outer surface of the clamp part 15. To facilitate the reciprocal movement of the member 20 within the guide 30 the member 20 is integrally provided with an outer collar 22 which is a close conforming sliding fit inside guide 30.
The penetrator 20 can be moved reciprocally from a first position seen in
The penetrator 20 has been moved from the first position shown in
As is seen in
In the configuration shown in
When the lyophilisation process is completed the interior of the vial 10 can be re-pressurised by allowing a sterile gas such as air to enter the vial.
The shelf 40 is then raised, i.e. to a position corresponding to
Thereafter the guide 30 may be detached from the vial 10. The residual hole 18 through the closure 13 may be sealed, which may for example be achieved by the known process of directing a beam of laser radiation at the puncture hole 18 to melt the adjacent elastomer material and subsequently allow the molten material to set and seal the puncture site. A cover part (not shown) may then be engaged with the clamp part 15 to cover the now-sealed penetrable region 18.
An alternative construction (not shown) of penetrator 20 may have a conical member 20 with a pointed apex, but with one or more external concavity e.g. groove which when the member 20 is in a position corresponding to
In
In
In
In
In
In
In
In
In
In
The steps shown in
In
In
From
Suitable conveyors etc. may be used to transport the vials 10 through this process, and suitable automatic machinery may be used to assemble the parts 20,30 and to engage this assembly with the vials 10. The stack of shelves 40,50 may be moved up and down vertically by known means, e.g. hydraulically. The parts 20, 30 may be re-usable after suitable cleaning and sterilisation.
Referring to
Referring to
The arrangement shown in
Thereafter the vials 10 may be removed from lower shelf 41 and the residual puncture hole 18 in the closure 13 sealed with a focused laser beam as in
The process and apparatus illustrated in
Referring to
The guide 72 comprises a generally cylindrical sleeve within which the penetrator 71 is mounted. As shown in
The penetrator 71 and guide 72 are made integrally of plastics material, and are so made initially linked by plural (six are shown there may be more or less) thin frangible integral links 76 with the penetrator in its first position as shown in
As shown in
The penetrator 71 has an upper rim with openings 77 corresponding to the vents 24 of
Referring to
As shown in
With the penetrator 100 and vial 10 in the configuration shown in
When the evaporation is complete the penetrator 100 is removed from the vial 10. This is achieved as shown in
Claims
1. A process for preparing a lyophilised material comprising:
- providing a container bounded by an envelope having a penetrable region and containing a dispersion of the material in a carrier liquid,
- penetrating the penetrable region with a penetrator such that the penetrator provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region,
- evaporating the carrier liquid out of the container via the conduit, and
- withdrawing the penetrator from the penetrable region.
2. (canceled)
3. The process according to claim 1 wherein the container is a vial, having a mouth opening closed by an elastomeric closure, and the penetrable region comprises a region of this elastomeric closure.
4. The process according to claim 1 wherein evaporating the carrier liquid out of the container via the conduit is performed by
- maintaining the dispersion at a temperature such that the carrier liquid is frozen, and
- applying reduced pressure so that the frozen liquid sublimates directly from the solid to the vapour state.
5. The process according claim 1 wherein the penetrable region comprises a previously-formed puncture hole in the penetrable region.
6. An apparatus suitable for use in the process according to claim 1 comprising:
- a penetrator capable of penetrating a penetrable region of a container bounded by an envelope having a penetrable region therein and containing a dispersion of the material in a carrier liquid such that the penetrator when penetrating the penetrable region provides a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region,
- means to cause the penetrator to penetrate the penetrable region,
- means to evaporate the carrier liquid out of the container via the conduit, and
- means to withdraw the penetrator from the penetrable region.
7. The apparatus according to claim 6 wherein the penetrator comprises that provides a conduit between the penetrator and the adjacent surface of the penetrable region.
- a generally tubular member having an end adapted to penetrate the penetrable region, and
- one or more concavity in its outer surface
8. The apparatus according to claim 6 wherein the penetrator comprises a generally conical member with a opening adjacent its apex, an open base or an opening adjacent its base, and a conduit passing through the penetrator linking these two openings, such that its apex may penetrate the penetrable region and vapour of the carrier liquid may enter the apex, pass through the hollow interior of the conical member, and exit.
9. The apparatus according to claim 6 wherein the penetrator is mountable on a container so that the penetrator can be moved from a first position in which the penetrator is outside the container and does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region.
10. The apparatus according to claim 9 wherein the penetrator is in combination with a guide, the combination comprising: such that the penetrator can be moved from a first position in which the penetrator does not penetrate the penetrable region to a second position in which the penetrator penetrates the penetrable region, and optionally back toward a first position in which the penetrator does not penetrate the penetrable region.
- a penetrator adapted to penetrate a penetrable region of the envelope of a container to thereby provide a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region, and
- a guide which is mountable on a container to thereby support the penetrator
11. The apparatus according to claim 10 wherein the penetrator comprises a generally conical member, and the guide comprises a generally cylindrical sleeve or part sleeve within which the penetrator is movable, and which may be mounted on a vial.
12. The apparatus according to claim 10 wherein the penetrator and the guide are made integrally of plastics material and are made initially linked by one or more thin frangible integral link with the penetrator in the first position, so that so that as the penetrator is moved from the first position toward the second position severance of the link occurs.
13. The apparatus according to claim 6 further comprising a lower shelf having an upwardly facing surface suitable for locating plural containers thereon, and a vertically adjacent upper shelf having a downward facing surface which comprises plural penetrators, the upper and lower shelves being moved relatively toward each other, so that the penetrators thereof are thereby moved reciprocally from a first position in which the penetrator does not penetrate the penetrable region, to a second position in which the penetrator penetrates the penetrable region, and optionally back towards a first position in which the penetrator does not at least partly penetrate the penetrable region.
14. The apparatus according to claim 13 wherein each penetrator comprises a generally conical member with its apex pointing downwardly from a lower surface of the upper shelf toward the lower shelf.
15. The process according to claim 1 performed in the following order:
- introducing the dispersion of the material in a carrier liquid into the container,
- penetrating the penetrable region with the penetrator,
- reducing the temperature of the liquid in the container until it is frozen,
- evaporating the frozen liquid to thereby lyophilise the content,
- allowing the temperature of the container to rise toward ambient temperature,
- returning the pressure toward atmospheric, and
- withdrawing the penetrator.
16. The process according to claim 15 wherein the container is a vial with an elastomeric closure, the penetrable region comprises a puncture hole in an elastomer vial closure, and wherein the process further of comprises sealing the residual puncture hole.
17. An apparatus suitable for use in a process according to claim 1 comprising:
- a penetrator adapted to penetrate the penetrable region of the envelope of the container to thereby provide a conduit through the envelope to provide communication between the inside and outside of the container when the penetrator has penetrated the penetrable region, and
- a guide which is mountable on the container to thereby support the penetrator so that the penetrator can be moved from a first position in which the penetrator does not penetrate the penetrable region to a second position in which the penetrator penetrates the penetrable region, and optionally back toward a first position in which the penetrator does not penetrate the penetrable region.
18. The apparatus according to claim 17 characterised in that wherein the penetrator comprises
- a generally tubular member having an end adapted to penetrate the penetrable region, and
- one or more concavity in its outer surface that provides a conduit between the penetrator and the adjacent surface of the penetrable region.
19. The apparatus according to claim 17 wherein the penetrator comprises a generally conical member with an opening adjacent its apex, an open base or an opening adjacent its base, and a conduit passing through the penetrator, such that its apex may penetrate the penetrable region and vapour of the carrier liquid may enter the apex, pass through the hollow interior of the conical member, and exit.
20. The apparatus according to claim 17 wherein the penetrator comprises a generally conical member, and the guide comprises a generally cylindrical sleeve or part sleeve within which the penetrator is movable, and which may be mounted on a vial having an elastomeric closure.
21. The apparatus according to claim 17 wherein the penetrator and the guide are made integrally of plastics material and are made initially linked by one or more thin frangible integral link with the penetrator in the first position, so that as the penetrator is moved from the first position toward the second position severance of the links occurs.
22. An apparatus suitable for use in a process according to claim 1 wherein the penetrator is itself mountable on the container in a position in which the penetrator is penetrating the penetrable region of the container.
23. The apparatus according to claim 22 wherein the penetrator comprises a generally conical member, and which is mountable on the container by means of a snap fit engagement.
24. The apparatus according to claim 22 wherein the penetrator comprises a conical member at least partly surrounded by a skirt extending in the cone base-apex direction, the skirt having snap-fit engagement means adjacent the rim furthest from the cone base.
Type: Application
Filed: Oct 25, 2005
Publication Date: Jun 25, 2009
Inventors: Jacques Thilly (Rixensart), Christian Vandecasserie (Rixensart)
Application Number: 11/718,034
International Classification: F26B 5/06 (20060101); B65D 51/24 (20060101);