BI-INJECTION MOLDED HOUSING OF A LOCKING CAP FOR A PHARMACEUTICAL VIAL, AND LOCKING CAP INCLUDING SUCH A HOUSING

Abstract

A bi-injection molded housing of a locking cap for a pharmaceutical vial includes a first material forming an upper ring, legs having upper ends rigidly connected to the upper ring, and bridges connecting lower ends of the legs in pairs, at least some bridges comprising a flexible tab configured to engage under a flange of the vial. The housing further includes a second elastomer material forming a stopper configured to seal the vial when the flexible tabs engage under the flange. At least one inner face of the upper ring made of the first material is rigidly connected to the stopper made of the second material.

Claims

1. A bi-injection molded housing of a locking cap for a pharmaceutical vial, comprising: a first material forming an upper ring, legs having upper ends rigidly connected to the upper ring, and bridges connecting lower ends of the legs in pairs, at least some bridges comprising a flexible tab configured to engage under a flange of the vial; and a second elastomer material forming a stopper configured to seal the vial when the flexible tabs engage under the flange; wherein at least one inner face of the upper ring made of the first material is rigidly connected to the stopper made of the second material.

2. The housing of claim 1, wherein the stopper comprises a base sized and configured to be inserted into the neck of the vial, and a head rigidly connected to an inner face of the upper ring.

3. The housing of claim 2, wherein the head is also rigidly connected to a portion of an inner face of each leg.

4. The housing of claim 2, wherein the base has a generally cylindrical shape and comprises a window in a cylindrical wall of the base that opens on the side of a free end of the base.

5. The housing of claim 2, wherein the base has a V-shaped profile and comprises a rectangular free end in which a slot is disposed.

6. The housing of claim 2, wherein the head of the stopper extends into a central hole of the upper ring to a level flush with an outer surface of the ring delimiting the central hole.

7. The housing of claim 2, wherein the base of the stopper has a generally cylindrical shape, is recessed, and comprises a cavity extending into the head so as to limit a central thickness of the head to be passed through along a main axis of the housing.

8. The housing of claim 2, wherein the head of the stopper comprises at least one recess and at least one shoulder that are complementary to at least one shoulder and at least one recess defined on the inner face of the upper ring and/or of the legs.

9. The housing of claim 1, wherein the stopper consists essentially of a head that is rigidly connected to an inner face of the upper ring.

10. The housing of claim 9, wherein the head is also rigidly connected to a portion of an inner face of each leg.

11. The housing of claim 9, wherein the head of the stopper extends into a central hole of the upper ring to a level flush with an outer surface of the ring delimiting the central hole.

12. The housing of claim 9, wherein the base of the stopper has a generally cylindrical shape, is recessed, and comprises a cavity extending into the head so as to limit a central thickness of the head to be passed through along a main axis of the housing.

13. The housing of claim 12, wherein the head of the stopper comprises at least one recess and at least one shoulder that are complementary to at least one shoulder and at least one recess defined on the inner face of the upper ring and/or of the legs.

14. The housing of claim 1, wherein the first material is made of polycarbonate.

15. The housing of claim 1, wherein the second material is selected from among silicone and a thermoplastic elastomer material.

16. The housing of claim 1, wherein the second material has a hardness of between 20 and 45 Shore A.

17. A locking cap for a pharmaceutical vial, comprising: a bi-injection molded housing, including: a first material forming an upper ring, legs having upper ends rigidly connected to the upper ring, and bridges connecting lower ends of the legs in pairs, at least some bridges comprising a flexible tab configured to engage under a flange of the vial, and a second elastomer material forming a stopper configured to seal the vial when the flexible tabs engage under the flange, wherein at least one inner face of the upper ring made of the first material is rigidly connected to the stopper made of the second material; an external body that surrounds the housing and is fixed thereto, the external body comprising an opening in an upper face of the external body, the opening being centered on and surrounding a central hole of the upper ring of the housing; and a capsule held on an upper face of the outer body for closing the opening and preventing access to the stopper.

18. The locking cap of claim 17, wherein the stopper comprises a base sized and configured to be inserted into the neck of the vial, and a head rigidly connected to an inner face of the upper ring.

19. The locking cap of claim 19, wherein the head is also rigidly connected to a portion of an inner face of each leg.

20. The locking cap of claim 17, wherein the stopper consists essentially of a head that is rigidly connected to an inner face of the upper ring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] Other features and advantages of the present disclosure will emerge from the following detailed description of embodiments according to the present disclosure with reference to the appended figures, in which:

[0028] FIGS. 1A and 1B show a locking cap on a vial, in an intermediate holding position (FIG. 1A) and in a locking position (FIG. 1i), according to the prior art;

[0029] FIGS. 2A-2C show all or part of a locking cap according to the present disclosure, perspective view (FIG. 2A), truncated view with only the external body and capsule (FIG. 2B), perspective views with only a bi-material housing according to the present disclosure (FIG. 2C);

[0030] FIGS. 3A and 3B show a first variant of a bi-material housing according to the present disclosure, FIG. 3A being a side view and FIG. 3B being a sectional view;

[0031] FIG. 4 shows a second variant of a bi-material housing according to the present disclosure, seen in perspective view from below;

[0032] FIG. 5 shows a third variant of a bi-material housing according to the present disclosure, seen in perspective view from the side; and

[0033] FIG. 6 shows a fourth variant of a part of the bi-material housing according to the present disclosure: the perspective view only comprises the stopper of the housing in order to facilitate the viewing of its shape.

[0034] In the description, the same references in the figures may be used for elements of the same type.

DETAILED DESCRIPTION

[0035] The present disclosure relates to a locking cap 100 for a vial 200 with a neck. The vial 200 has a neck 201 of circular opening, ending with a collar or flange 202 flared relative to the outer perimeter of the neck 201, as shown in FIGS. 1A and 1B of the prior art. In the field of pharmaceutical applications, there are standards in terms of the internal diameter of the neck 201 of the vial 200: 13 mm and 20 mm are examples of this. The cap 100 is intended to block a stopper 25 in the neck 201 or against the flange 202 of the vial 200 to seal it hermetically.

[0036] When it is associated with the vial 200, the locking cap 100, as is known per se, can adopt two positions on the vial: a first position, called the intermediate holding position, wherein it remains removable, in a similar way to the illustration in FIG. 1A. It can also adopt a second position, called the locking position, wherein it is locked onto the vial 200, in a similar way to the illustration in FIG. 1B, and hermetically closes the vial 200.

[0037] The locking cap 100 comprises a capsule 40, an external body 30 and a housing 20 (FIGS. 2A-2C). The originality of the locking cap 100, relative to those of the prior art, comes from its housing 20. It is formed of a first material defining an upper ring 21, legs 22 whose upper ends are rigidly connected to the upper ring 21, and bridges 23 connecting the lower ends of the legs 22 two-by-two. These elements give the housing 20 a generally cylindrical shape centered on a main axis z. The upper ring 21 has a central hole delimited by an outer surface 21a, usually circular.

[0038] As can be seen in FIG. 2C, at least some bridges 23 comprise a tab 24 that is flexible and is inclined relative to the legs 22 toward the inside of the housing 20, at an angle of between 20? and 60?, advantageously around 30?, in the direction of the upper ring 21. These tabs 24 remain above the flange 202, to be slightly raised or to be in contact therewith, when the cap 100 is in the intermediate holding position. They are intended to bear under the flange 202 of the neck 201 of the vial 200 when the cap 100 is in the locking position.

[0039] The housing 20 is further formed of a second material, an elastomer, defining a stopper 25 configured to seal the vial 200, when the flexible tabs 24 are gripped under the flange 202, that is to say in the locked position of the cap 100 on the vial. At least one inner face (that is to say a face oriented toward the interior of the housing) of the upper ring 21 made of a first material is rigidly connected to the stopper 25 made of a second material. Advantageously, in addition to the inner face of the upper ring 21, a portion of an inner face of the legs 22 is also rigidly connected to the stopper 25, as shown in FIGS. 3A, 3B, 5.

[0040] As will be described below, the bi-material housing 20 is formed by plastic bi-injection molding.

[0041] According to a first variant (FIGS. 3A, 3B), the stopper 25 of the housing 20 comprises a base 252, of generally cylindrical shape, sized to enter and close the neck 201 of the vial 200. The stopper 25 also comprises a head 251 secured to the inner face of the upper ring 21 and, preferentially, also rigidly connected to a portion of the inner face of each leg 22.

[0042] By way of example, for a conventional vial 200, the inner diameter of the neck 201 of which is 13 mm, the diameter of the base 252 may be 13.2 mm. When the base 252 is fully pushed into the neck 201, in the locked position, the head 251 is held bearing on the flange 202 of the vial 200 with a certain level of compression and participates in the sealing of the closure. The base 252 can have different lengths, along the main axis z, for example, between 2.5 mm and 7.5 mm.

[0043] According to a second variant (FIG. 4), the stopper 25 also comprises a base 252 and a head 251, the latter being rigidly connected to the inner face of the upper ring 21 and, advantageously, also rigidly connected to a portion of the inner face of each leg 22.

[0044] This variant is particularly suitable when the contents of the vial 200 are intended to be freeze-dried, before sealing. Indeed, the base 252 of the stopper 25 has a window 252f in its cylindrical wall opening on the side of its free end, to allow the passage of the evaporator flows from the inside of the vial 200 outwardly, as long as the base 252 is not fully pushed into the neck 201, that is to say in the intermediate holding position of the locking cap 100. Optionally, at least the bridge 23 opposite this window 252f may comprise an open space, so as to further facilitate the evaporation flows. For example, the open space may be similar to that proposed in document FR3098504A1. It should be noted that the option consisting of arranging an open space in at least one bridge 23 of the housing 20 can also be implemented within the scope of the first variant or else of the third variant described below, when it is provided to freeze-dry the contents of the vial 200, with the locking cap 100 in the intermediate holding position.

[0045] According to a third variant, the stopper 25 comprises only a head 251, without a base 252. The head 251 is rigidly connected to the inner face of the upper ring 21 and, advantageously, also rigidly connected to a portion of the inner face of each leg 22, as shown in FIG. 5.

[0046] In this configuration, it is only the compression of the head 251 against the flange 202 of the vial 200, in the locking position of the cap 100, which ensures the sealing.

[0047] According to a fourth variant (FIG. 6), the stopper 25 comprises a head 251 and a base 252 with a profiled V shape. Even if the other elements of the housing 20 (ring 21, legs 22, bridges 23, tabs 24) are not shown in FIG. 6 to facilitate the viewing of the stopper 25, they are clearly part of the housing 20 according to this variant and the head 251 is here again rigidly connected to the inner face of the upper ring 21 and, advantageously, also rigidly connected to a portion of the inner face of each leg 22. The free end 252b of the base 252 is rectangular and comprises a slot, through which a pipette can be inserted, for example, to sample the solution contained in the vial 200, after removing all or some of the locking cap 100. The particular configuration of the base 252 makes it possible to maintain a seal when the pipette is removed.

[0048] In the various variants mentioned, the sealing of the vial 200 is ensured by inserting the base 252 into the neck 201 (when the base is present) and by compressing the head 251 of the stopper 25 against the flange 202 when the tabs 24 of the housing 20 are gripped under the flange 202. The thickness of the head 251 (along the main axis z) in line with the upper ring 21 of the housing 20, which thickness will also be in line with the flange 202 in the locking position of the cap 100, must therefore be precisely adjusted with the positioning of the tabs 24. The hardness of the second material forming the head 251 of the stopper 25 is also an important parameter. The thickness and the hardness of the head 251 must be able to absorb the thickness tolerances of the flange 202 of the vial 200; they must also ensure that the upper ring 21 of the housing 20 brings the head 251 into compression against the flange 202, to guarantee sealing, when the tabs 24 are gripped under the flange.

[0049] Advantageously, the hardness of the second material is between 20 and 45 Shore A.

[0050] The features of the two-material housing 20 therefore give it the double function of a stopper 25 to seal the vial 200 and a member for locking the cap on the vial 200.

[0051] As mentioned above, the first material and the second material of the housing 20 are bi-injected, that is manufactured from a known method of bi-injection molding or bi-material plastic injection molding. Such a method makes it possible to produce on a single press, with a single tool, a part (the housing 20) composed of two materials with different characteristics.

[0052] The fact that the two materials are bi-injected guarantees perfect adjustment of the dimensions and excellent securing between the various elements constituting the housing 20, namely the stopper 25, and the upper ring 21, the legs 22, the bridges 23 and the tabs 24 on the other hand.

[0053] The second material may be chosen from silicone or a thermoplastic elastomer material (TPE), materials having a low extractable profile (that is, few or no components thereof are likely to migrate into the pharmaceutical solution contained in the vial 200). The first material is advantageously polycarbonate, due to its mechanical strength. The fastening between the first and the second material may be of chemical and/or mechanical nature. It will be of chemical nature if the two materials used are able to adhere together, during bi-injection molding. In general, a mechanical fastening is implemented (with or without chemical contribution to the fastening) by defining retaining means and complementary notches at the surfaces of the two materials that are in contact. Typically, the head 251 of the stopper 25 comprises at least one first recess Ev1 and at least a first shoulder Ep1,Ep1, complementary to at least one second shoulder Ep2 and at least one second recess Ev2,Ev2 defined on the inner face of the upper ring 21 or on the inner face of the legs 22 (FIGS. 3A, 3B). The recesses and shoulders may be circular or extend only locally on the faces in contact, as can be seen in FIG. 6.

[0054] Advantageously, the head 251 of the stopper 25 extends into the central hole of the upper ring 21, until the outer surface 21a of the ring 21 is flush (FIGS. 2C, 3B). The upper surface 251a of the head 251 being at the same level, along the main axis z, as the outer surface 21a, there is no retention zone for liquid(s) or particle(s) in the central hole, a retention zone ZR that exists in the locking caps of the state of the art (FIGS. 1A and 1). Such an area may pose problems of contamination when the contents of the vial 200 are removed by inserting a collection needle through the stopper 25, at the central hole of the upper ring 21.

[0055] Also advantageously, the base 252 of the stopper 25 (when it is present and has a generally cylindrical shape) is hollowed out and comprises a cavity that can also extend into the head 251, in particular when the upper surface 251a of the head 251 is flush with the outer surface 21a of the upper ring 21, so as to limit the central thickness to be passed through along the main axis z by a sample-collection syringe (FIG. 3B). This central thickness to be passed through is intended to be identical to the usual thickness to be passed through of stoppers of the prior art (typically between 1 mm and 5 mm), so that the user does not perceive a difference during collection, regardless of the type of stopper and/or locking cap.

[0056] The locking cap 100 therefore comprises the bi-injection molded housing 20 previously described, as well as an external body 30 and a capsule 40. The external body 30 is configured to completely surround the housing 20, so as to prevent any access to the housing 20 from the outside, when the cap 100 locks the vial 200. The external body 30 has a general cylindrical shape; it is defined by an upper face 31 and a cylindrical wall 32 centered on a main axis z (FIG. 2B). The free end of the cylindrical wall 32 defines an opening, adapted to accommodate the housing 20, before the positioning of the cap 100 on the neck 201 of the vial 200. Another opening, called the upper opening, is provided in the upper face 31.

[0057] The external body 30 is attached to the housing 20, for example, by cooperation of lugs 221 with a complementary groove 321 arranged on the inner face of the cylindrical wall 32 of the body 30 (FIGS. 2B, 2C). The upper opening is centered on and surrounds a central hole of the upper ring 21 of the housing 20.

[0058] The capsule 40 held on an upper face 31 of the external body 30 for closing the upper opening and preventing access to the head 251 of the stopper 25. As shown in FIG. 2B, the capsule 40 may comprise a plurality of tabs 41, arranged in the upper opening of the body 30. These tabs 41 are then deformed to be pressed against the inner surface of the upper face 31, that is to extend substantially in the plane (x, y). The capsule 40 can be attached to the body 30 by shaping. After this step, the housing 20 can be inserted into the body 30 to be fixed axially thereto by cooperation of the lugs 221 with the complementary groove 321. The locking cap 100 thus assembled can then be arranged in the intermediate holding position and then in the locking position on the vial 200 to be sealed.

[0059] The external body 30 and the capsule 40 may be made of materials such as polycarbonate (PC), polypropylene (PP) or polybutylene terephthalate (PBT). Advantageously, the capsule 40 is formed from flexible plastics materials, such as polypropylene (PP), in order to make it easier to grasp. It is recalled, in fact, that when the user wishes to withdraw the contents of the vial 200 sealed by the locking cap 100, that person applies a force to the capsule 40 to remove it and thus have access to the stopper 25, via the upper opening of the body 30.

[0060] By virtue of the features of the locking cap 100 according to the present disclosure, and in particular thanks to the features of the bi-injection molded housing 20 with a dual function, the number of elements to be assembled to form the cap 100 is limited, the problems related to the uncertainties or variabilities of dimensions between the elements, in particular between an independent stopper and a conventional housing, are solved, and finally the disadvantages and risks of damaging the cap by its mechanical association in a conventional housing are eliminated.

[0061] Naturally, the present disclosure is not limited to the embodiments and examples that have been described, and it is possible to add alternative embodiments thereto without departing from the scope of the invention as defined by the claims.