Adaptor for a Medical Container and a Medical Container Comprising Said Adaptor

Abstract

An adaptor for connecting a medical container to a connector, the adaptor including longitudinal projections including a distal portion configured to exert a progressively increasing radial pressure on connecting means of the connector when said connector is moved axially proximally within the adaptor and a proximal portion configured to authorize the partial release of said pressure as the connector is moved further proximally, said proximal portion being further configured to be contacted by said connecting means upon said partial release of said pressure and to emit a sound when contacted by said connecting means, thereby providing an end user with a tactile and audible indication that the connection between the connector and the adaptor is secured. The disclosure also relates to a medical container having such an adaptor mounted onto its distal tip.

Claims

1. An adaptor for connecting a medical container to a connector having a proximal region provided with connecting means at its proximal end, the adaptor comprising: a proximal part configured to be secured onto a distal tip of a medical container, a distal part configured to receive said proximal region of said connector in order to establish a fluid communication between the distal tip of the medical container and the connector, a plurality of longitudinal projections configured to engage said connecting means in an axial snap fit relationship when the connector reaches a predetermined position in the adaptor, the plurality of longitudinal projections being distributed circumferentially on an inner surface of said distal part, the longitudinal projections comprising a distal portion configured to exert a progressively increasing radial pressure on said connecting means as the connector is moved axially proximally within the adaptor and a proximal portion configured to authorize the partial release of said pressure as the connector is moved further axially proximally, said proximal portion being further configured to be contacted by said connecting means upon said partial release of said pressure and to emit a sound when contacted by said connecting means, thereby providing an end user with a tactile and audible indication that the connection between the connector and the adaptor is secured, wherein the distal portion of the longitudinal projections comprises a first wall having a first radial thickness, the value of said first radial thickness increasing from a distal end of said distal portion to a proximal end of said distal portion, and wherein the proximal portion of the longitudinal projections comprises a second wall having a substantially constant second radial thickness, the value of said second radial thickness being greater than the value of said first radial thickness at the distal end of said distal portion and being less than the value of said first radial thickness at the proximal end of said distal portion.

2. The adaptor according to claim 1, wherein the longitudinal projections are regularly distributed circumferentially on the inner surface of said distal part.

3. The adaptor according to claim 1, comprising at least four longitudinal projections regularly distributed circumferentially on the inner surface of said distal part.

4. The adaptor according to claim 1, comprising six longitudinal projections regularly distributed circumferentially on the inner surface of said distal part.

5. The adaptor according to claim 1, wherein said second wall being a circumferential width W2 lower than a circumferential width W1 of said first wall.

6. A medical container comprising a distal tip and the adaptor according claim 1, said adaptor being mounted onto the distal tip of the medical container.

7. A method for manufacturing the adaptor according to claim 1, said method comprising the steps of forming the adaptor by injection molding.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] The disclosure and the advantages arising therefrom will clearly emerge from the detailed description that is given below with reference to the appended drawings as follows:

[0029] FIG. 1 is a perspective view of an adaptor according to an embodiment of the disclosure and of the distal tip of a medical container intended to receive said adaptor,

[0030] FIG. 2 is a perspective view of the adaptor and medical container of FIG. 1, where the adaptor is mounted onto the distal tip of the container,

[0031] FIG. 3 is a cross section perspective view of the adaptor taken along plane I-I′ of FIG. 1,

[0032] FIG. 4 is a perspective view of the adaptor mounted onto the distal tip of the medical container of FIG. 2 about to receive a needle hub.

DETAILED DESCRIPTION

[0033] With reference to FIG. 1 is shown an adaptor 1 according to an embodiment of the disclosure. With reference to FIGS. 1 and 2, the adaptor 1 is intended to be mounted onto the distal tip 102 of a medical container 100, in particular onto the outer surface of the distal tip 102. The outer surface of the distal tip 102 is generally distally tapered or frustoconical. Alternatively, it could be cylindrical. The adaptor 1 permits to connect a connector, such as a needle hub 200 see FIG. 4) having a proximal region 201 provided with connecting means, such as two outer wings 202, at its proximal end, to the distal tip 102.

[0034] With reference to FIGS. 1-4, the adaptor 1 comprises a proximal part 2, which may be in the form of a mounting ring, configured to be secured to the medical container 100, and a distal part 4, which may be in the form of a connecting ring, configured to receive the connector in order to establish a reliable fluid communication between a passageway of the distal tip 102 and the connector.

[0035] The connector, such as the needle hub 200, is intended to be axially connected to the adaptor 1 in a snap fit relationship.

[0036] In this view, the adaptor 1 has a plurality of longitudinal projections 5 configured to engage the outer wings 202 of the needle hub 200 in an axial snap fit relationship when the needle hub 200 reaches a predetermined position in the adaptor 1, said predetermined position being the position where the connection between the needle hub 200 and the distal tip 102 of the medical container 100 is secured and a reliable fluid communication between the needle hub 200 and the distal tip 102 is ensured. Said position is also defined as being the limit depth above which there is no leak. The leakage limit may be defined by the ISO 80369 7 of 2016, paragraphs 6.1 and 6.2.

[0037] With reference to FIGS. 1-3, the plurality of longitudinal projections 5 is distributed circumferentially on the inner surface 4a of the distal part 4 of the adaptor 1.

[0038] The longitudinal projections 5 comprise a distal portion 6 and a proximal portion 7. The distal portion 6 is configured to exert a progressively increasing radial pressure on the outer wings 202 of the needle hub 200 when the needle hub 200 is moved proximally within the adaptor 1. In the example shown, the distal portion 6 comprises a first wall 8. This first wall 8 has a first radial thickness the value of which varies from the distal end 6a of the distal portion 6 to the proximal end 6b of this distal portion 6. In particular, the value of the first radial thickness increases from the distal end 6a of the distal portion 6 to the proximal end 6b of this distal portion 6.

[0039] The proximal portion 7 is configured to authorize the partial release of the radial pressure exerted on the outer wings 202 of the needle hub 200 as the needle hub 200 is further moved proximally within the adaptor 1. The proximal portion 7 is further configured to be contacted by the outer wings 202 upon the release of said radial pressure and to emit a sound when contacted by said outer wings 202. In the example shown, the proximal portion 7 comprises a second wall 9. The second wall 9 has a second radial thickness, which may be substantially of constant value. The value of the second radial thickness is preferably less than the value of the first radial thickness at the proximal end 6b of the distal portion 6. This allows the radial pressure exerted on the outer wings 202 of the needle hub 200 to be released when the needle hub 200 is moved in the direction of the proximal part 2 of the adaptor 1 as well as ensuring that the outer wings 202 produce a sound when they contact the second wall 9 upon the release of said radial pressure.

[0040] In particular, the value of the second radial thickness is less than the value of the first radial thickness at the proximal end 6b of the distal portion 6 and greater than the value of the first radial thickness at the distal end 6a of the distal portion 6. Typically, the value of the second radial thickness of the second wall is about half of the value of the first radial thickness at the proximal end 6b. This allows firmly maintaining the outer wings 202 in abutment against the second wall 9, thereby ensuring that the needle hub 200 is firmly engaged in a snap fit relationship in the adaptor 1, with no possibility that the needle hub 200 moves and/or rotate within the adaptor 1.

[0041] With reference to FIG. 3, the second wall 9 has a circumferential width W2 which is lower than the circumferential width W1 of the first wall 8. Typically, the circumferential width W2 is about half of the circumferential width W1. Preferably, W1>W2≥0.5W1.

[0042] The longitudinal projections 5 are preferably regularly distributed on a circumference of the inner surface of the distal part 4 of the adaptor 1. The number of longitudinal projections 5 is preferably above two, for example from three to ten, in order to ensure a safe maintaining of the needle hub 200 within the adaptor 1. The number of longitudinal projections 5 may be four. In the example shown on the figures the number of longitudinal projections 5 is six. As will appear from the description of FIG. 4, such a number of longitudinal projections 5 allows ensuring that the two outer wings 202 of the needle hub 200 extend circumferentially on a distance greater than the interspaces 3 between two adjacent longitudinal projections 5. As a result, once the needle hub 200 is axially engaged in the adaptor 1 as described above, it may not be removed therefrom, the proximal face 6c see FIG. 3) of the distal portion 6 forming an abutment surface preventing the outer wing 202 to be moved in the distal direction.

[0043] The adaptor 1 may be made of a plastic material, more precisely of any rigid polymer adapted to medical use, such as high density polyethylene PE), polypropylene PP), polycarbonate PC), acrylonitrile butadiene styrene ABS), polyoxymethylene POM), polystyrene (PS), polybutylene terephthalate PBT), polyamide PA), and combinations thereof. Preferably, the adaptor 1 is made of polycarbonate PC).

[0044] The adaptor 1 may be manufactured by injection molding using two different inserts.

[0045] With reference to FIGS. 1-2 and 4, the disclosure also relates to a medical container 100 comprising a distal tip 102 and an adaptor 1 having the above described features, said adaptor 1 being mounted onto the distal tip 102 of the medical container 100. The medical container 100, which may be a syringe, such as pre fillable or prefilled syringe, comprises a tubular barrel 104 that defines a reservoir for a medical product. The tubular barrel 104 is provided with the distal tip 102 that may protrude from a distal shoulder 106. The distal tip 102 may be cylindrical or distally tapered or frustoconical. The distal tip 102 includes an internal passageway 108 in communication with the reservoir. The tubular barrel 104 and the distal tip 102 may be made of glass or of plastic material. The medical container 100 may be provided with a piston and a plunger rod not shown) so as to expel the medical product from the reservoir and through the passageway 108. The adaptor 1 may be secured to the distal tip 102 by gluing, screwing, friction force or snap fitting.

[0046] The operation of the adaptor 1 is described herein below with reference to FIGS. 3 and 4.

[0047] The user inserts the needle hub 200 axially into the distal end of the adaptor 1. In the example shown, the outer wings 202 extend circumferentially on a distance greater than the interspaces 3 as defined above. The user may therefore insert the outer wings 202 within the adaptor 1 without having to care about the orientation of the outer wings 202 with respect to the longitudinal projections 5. As the needle hub 200 is moved in the proximal direction, the outer wings 202 contact the first wall 8. Because of the increasing of the first radial thickness of the first wall 8, the radial pressure exerted onto the outer wings 202 increases as the needle hub 200 is further moved proximally. The outer wings 202 are therefore progressively squeezed and deformed in the inward radial direction. The user feels that he has to apply an increasing effort in order to insert the needle hub 200 into the adaptor 1. Once the outer wings 202 reach the proximal end 6b of the first wall 8, the radial pressure exerted on the outer wings 202 is at its peak, and further proximal movement of the needle hub 200 with respect to the adaptor 1 causes partial release of the radial pressure on the outer wings 202, which expand until they contact the second wall 9. The needle hub 202 has reached the predetermined position in which the connection between the needle hub 200 and the distal tip 102 is secured. When contacting the second wall 9, the outer wings 202 produce a sound that informs the user that the connection is correctly performed, and thus secured. Moreover, the drop in the necessary axial effort further allows the user to be informed that the connection is performed. The longitudinal projections 5 therefore provide both a tactile indication and an audible indication that the connection is safely performed.

[0048] The adaptor of the disclosure allows therefore improving the end user confidence during connection and injection.