DRUG DELIVERY DEVICE WITH A HYDRAULIC TRIGGER MECHANISM

Abstract

A device for administering a fluid medicament by injection comprises a dosing portion (1) with a collapsible reservoir (10). The reservoir (10) has a maximum volume in an extended state and a minimum volume in a collapsed state. Prior to injection, the reservoir (10) is in the extended state and contains a liquid to be administered, and the reservoir (10) is biased towards the collapsed state. The device further comprises a needle (2), wherein a lumen (20) of the needle (2) is in fluid communication with the reservoir (10). The device further comprises a shield portion (3) with a plug (30). Prior to injection, the shield portion (3) is in a deployed position where the plug (30) blocks the lumen (20) of the needle (2). The shield portion (3) is adapted to move in response to an actuation force from the deployed position to a retracted position where the lumen (20) of the needle (2) is open, thereby causing the reservoir (10) to shift to the collapsed state to expel the liquid through the needle.

Claims

1. Device for administering a liquid medicament by injection, the device comprising a dosing portion with a collapsible reservoir, the reservoir having a maximum volume in an extended state and a minimum volume in a collapsed state, wherein prior to injection the reservoir is in the extended state and contains a liquid to be administered, and wherein the reservoir is biased towards the collapsed state; an injection needle, wherein a lumen of the needle is in fluid communication with the reservoir; and a shield portion with a plug, wherein prior to injection the shield portion is in a deployed position where the plug blocks the lumen of the needle, and wherein the shield portion is adapted to move in response to an actuation force from the deployed position to a retracted position where the lumen of the needle is open, thereby causing the reservoir to shift to the collapsed state to expel the liquid through the needle.

2. Device according to claim 1, wherein the plug is arranged at the tip of the needle when the shield portion is in the deployed position.

3. Device according to claim 2, wherein the plug is adapted to be pierced by the needle as the shield portion moves from the deployed position to the retracted position thereby opening the lumen of the needle.

4. Device according to claim 1, wherein the shield portion comprises a resting surface arranged at a proximal end of the device.

5. Device according to claim 4, wherein the shield portion is displaceable in an axial direction with respect to the needle from a deployed position where the plug blocks the lumen of the needle, to a retracted position where the plug is pierced by the needle such that the lumen of the needle is open for fluid passage.

6. Device according to claim 1, wherein the shield portion is biased towards the deployed position by structure of a shield bias element.

7. Device according to claim 6, wherein the shield bias element is a compression spring.

8. Device according to claim 1, wherein the shield portion fully encases the needle.

9. Device according to claim 1, wherein the displacement of the shield and dosing portions with respect to each other is guided by guide structure, such as guide rails and cooperating lugs.

10. Device according to claim 9, wherein the guide structure comprise distal and/or proximal end stops for limiting the displacement of the shield portion with respect to the dosing portion.

11. Device according to claim 1, wherein the dosing portion comprises a housing, wherein the housing encases the collapsible reservoir.

12. Device according to claim 1, wherein the dosing portion comprises a syringe with a barrel and a cooperating plunger, wherein the barrel and the plunger in combination define the collapsible reservoir, wherein the plunger is displaceable inside the barrel from a first position corresponding to the maximum volume of the reservoir, to a second position corresponding to the minimum volume of the reservoir, wherein the plunger is biased towards the second position by structure of a plunger bias element.

13. Device according to claim 12, wherein the barrel is integrally formed with the housing.

14. Device according to claim 12, wherein the plunger bias element is a compression spring.

15. Device according to claim 12, wherein a ratio (A1 :A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 is at least (1:50).

16. Device according to claim 15, wherein a ratio (A1:A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 is at least (1:100).

17. Device according to claim 15, wherein a ratio (A1:A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 is at least (1:500).

18. Device according to claim 15, wherein a ratio (A1:A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 is at least (1:1000).

19. Device according to claim 15, wherein a ratio (A1:A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 is at least (1:5000).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0037] Preferred embodiments of the invention will be described in more detail in connection with the appended drawings, which show in

[0038] FIG. 1 a cross-sectional view of a device according to one embodiment of the invention, and in

[0039] FIG. 2 cross-sectional views of the device of FIG. 1: (a) prior to the injection procedure; (b) during the injection procedure; and (c) after the injection procedure.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0040] FIG. 1 and FIG. 2 show side cross-sectional views of a device for administering a liquid medicament by injection according to one embodiment. FIG. 1 shows the device prior to use, FIG. 2a shows the device prior to use, FIG. 2b shows the device during injection, and FIG. 2c shows the device after use.

[0041] The device comprises a dosing portion 1 with a collapsible reservoir 10, the reservoir 10 having a maximum volume in an extended state and a minimum volume in a collapsed state, wherein prior to injection the reservoir 10 is in the extended state and contains a liquid to be administered (not shown), and wherein the reservoir is biased towards the collapsed state. The device further comprises an injection needle 2, wherein a lumen 20 of the needle 2 is in fluid communication with the reservoir 10. The device further comprises a shield portion 3 with a plug 30, wherein prior to injection the shield portion 3 is in a deployed position where the plug 30 blocks the lumen 20 of the needle 2, and wherein the shield portion 3 is adapted to move in response to an actuation force from the deployed position to a retracted position where the lumen 20 of the needle 2 is open, thereby causing the reservoir 10 to shift to the collapsed state to expel the liquid through the needle 2.

[0042] Referring to FIG. 1, the collapsible reservoir 10 of the dosing portion 1 is formed as a syringe with a barrel 11 and a plunger 12. The plunger 12 has a stem 13 at a rear side facing away from the volume of the reservoir 10 and a seal 14 capping the plunger 12 at a front side facing towards the volume of the reservoir 10 and sealing the plunger 12 against the inner walls of the barrel 11. The syringe is encased by a housing 16 with a peripheral sheath portion 17 and an end cap 19 forming a distal end 4 of the device. The volume of the reservoir 10 depends on the position of the plunger 12 with respect to the barrel 11. In the extended state of the reservoir 10, the plunger is in a first position at a distal end of the barrel 11 such that the volume of the reservoir 10 is a maximum. In the collapsed state of the reservoir 10, the plunger is in a second position at a proximal end of the barrel, such that the volume of the reservoir 10 is a minimum. The reservoir 10 is biased to the collapsed state by means of a plunger bias element 15 applying a bias force to the plunger 12 in a direction towards the second position. The plunger bias element 15 is a compression spring abutting at one end the stem 13 on the rear side of the plunger 12 and at an opposite end the inside of the end cap 19. In the extended state of the reservoir 10 shown in FIG. 1 and FIG. 2a, the compression spring is compressed and in the collapsed state of the reservoir shown in FIG. 2c, the compression spring is expanded.

[0043] The injection needle 2 is oriented in the axial direction and is arranged at a proximal end of the barrel 11, opposite to the plunger 12. A distal end of the needle 2 is fixed to the barrel 11 with a needle mount 23 sealing the reservoir 10 at its proximal end. The lumen 20 of the needle 2 is in fluid communication with the reservoir 10 through an inlet opening 22 at the distal end of the needle 2. An outlet opening at the tip 21 at the proximal end of the needle 2 is inserted in the plug 30 without penetrating it, thereby blocking the lumen 20 of the needle 2.

[0044] The device further comprises a shield portion 3 holding the plug 30 in place at the tip 21 of the needle 2, when the shield portion 3 is in a deployed position. The shield portion 3 comprises a resting surface 50 arranged at a proximal end 5 of the device. The shield portion 3 is displaceable in an axial direction with respect to the needle 2 from the deployed position where the plug 30 blocks the lumen 20 of the needle 2, to a retracted position where the plug 30 is pierced by the needle 2 such that the lumen 20 of the needle 2 is open for fluid passage.

[0045] The axial movement of the shield portion 3 with respect to the dosing portion 1 is guided by guiding means 18, 32 with end stops 33, 34 determining the length of the travel. Here, the guiding means include guide rails 32 in the form of axially extending slots arranged on the side of the shield portion 3 and cooperating lugs 18 on the peripheral sheath 17 of the dosing portion housing. The lugs 18 interact with the distal end stop 33 on the guide rail 32 to define the deployed position of the shield portion 3, and with the proximal end stop 34 on the guide rail 32 to define the retracted position of the shield portion 3.

[0046] The shield portion 3 is biased towards the deployed position by means of a shield bias element 35, here in the form of a compression spring acting in the axial direction between the barrel 11 and the shield portion 3. The shield portion 3 fully encases the needle 2 when the shield is in the deployed position. The needle 2 projects from the resting surface 50 when the shield portion 3 is in the retracted position, wherein an axial distance of the needle tip 21 from the resting surface 50 corresponds to an injection depth.

[0047] In its extended state, the reservoir 10 is loaded with a liquid medicine for administration by injection, wherein the bias of the plunger 12 applies a pressure to the liquid. Since the plug 30 blocks for the passage of the fluid through the lumen 20 of the needle, it maintains the hydrostatic pressure inside the reservoir 10. The plug 30 communicates hydraulically with the plunger 12 via the liquid in the reservoir 10. The force required for keeping the plug 30 in place corresponds to the hydraulic force exerted on the plug 30 by the liquid. The hydraulic counter force exerted on the liquid by the plug 30 for maintaining the hydrostatic pressure in the reservoir 10 equals the bias force exerted on the liquid by the plunger 12 scaled down by the ratio of the cross-sectional area of the lumen 20 over the cross-sectional area of the plunger 12: F1(plug)=F2(plunger)×(A1(plug)/A2(plunger)), wherein the areas are taken in a cross-sectional plane perpendicular to the axial direction. The ratio (A1:A2) of the cross-sectional area A1 of the lumen of the needle over the cross-sectional area of the plunger A2 corresponds here to the hydraulic leverage of the plug with respect to the bias exerted by the plunger via the liquid in the reservoir. Since the lumen of a typical injection needle is significantly smaller than the cross-section of the barrel, a considerable hydraulic leverage is achieved. This allows for maintaining the liquid medicine under pressure from the biased plunger 12 by hydraulic means without the need for any further retaining means for holding the plunger 12 against the bias force in the first position. Advantageously, the ratio of the cross-sectional areas (A1:A2) and thus the hydraulic leverage is at least (1:50), alternatively at least (1:100), alternatively at least (1:500), alternatively at least (1:1000), or even at least (1:5000).

[0048] When the shield portion 3 is displaced from the deployed position towards the retracted position, the plug 30 is pierced by the needle 2, thereby opening the lumen 20 for fluid passage there through. The hydraulic counter force provided by the plug 30 to retain the biased plunger 12 in its first position is thus removed, and the plunger 12 moves from the first position to the second position. The displacement of the plunger 12 expels the liquid from the reservoir 10 through the needle 2 to the outside. In this way, piercing the needle 2 through the plug 30 by pushing the shield portion 3 towards the retracted position triggers delivery of the liquid medicine without the need for any further trigger mechanism.

[0049] A sequence of operation of the device is described in more detail by referring to FIG. 2 in the following. FIG. 2a shows the device prior to use loaded with a liquid medicine for administration to a patient by injection. Prior to use, the reservoir 10 is in the extended state where the plunger 12 is in the first position at the distal end of the barrel 11 and where the plunger bias element 15 is fully compressed. The shield portion 3 is held in the deployed position by the compression spring 35, which is expanded when the shield 3 is deployed. The shield portion 3 holds the plug 12 and comprises the resting surface 50 at the proximal end 5 of the device. The resting surface 50 is adapted for resting against an outer surface of a patient, typically the skin of the patient. The plug 30 blocks the lumen 20 of the needle 2, thereby maintaining the liquid under pressure as described above. For administration of the liquid medicine by injection to an injection site in a patient (not shown), the resting surface 50 of the shield portion 3 is typically brought in contact with the skin of the patient at the injection site. The dosing portion 1 is then pushed towards the shield portion 3 by applying an actuation force in an axial direction to an actuation surface 40 at a distal end 4 of the device as indicated by the black block arrow in FIG. 2b. The shield portion 3 is thereby pushed from the deployed position to the retracted position as best seen in FIG. 2b. The needle 2 is adapted for piercing the plug 30 and penetrating tissue of the patient to reach the site of injection. Under the continued action of the actuation force, the needle 2 therefore pierces the plug 30 and continues into the tissue. Removal of the plug 30 from the lumen 20 of the needle 2 allows the plug 12 under the action of the plunger bias element 15 to move towards the second position as indicated by the hollow block arrow in FIG. 2b. Removal of the plug 30 thus triggers the device to expel the liquid medicine through the needle as described above, and the liquid medicine is delivered to the injection site in the patient, wherein the depth of the delivery is determined by the length of the needle 2 projecting from the resting surface 50 when the shield portion 3 is in the retracted position. In the retracted position of the shield 3, the shield bias element 35 is compressed.

[0050] Thereby a reliable drug delivery device for the administration of a liquid medicine by injection is achieved, which has a simplified mechanics, is easy to produce and is particularly easy and safe to use. Further advantages include a compact design with a small form factor. The needle insertion and trigger mechanism are integrally coupled and are driven by the same actuation movement. The small diameter of the needle and the sharp tip is furthermore advantageous for the easy removal of the plug by merely piercing the plug with the needle. Furthermore, due to the hydraulic leverage the plug does not have to be so thick and solid. A reduction of the force required for piercing the plug also reduces the actuation force when actuating the device in a single gesture, such as pressing the device with its resting surface to the surface of the skin at the injection site with a force equal to or exceeding an actuation force of the device. An excessive actuation force might be inhibitive for the “single movement/gesture” actuation, in particular when performed by untrained users.

[0051] FIG. 2c shows the device after use, where the actuation-force has been removed. The shield 3 returns to the deployed position under the action of the shield bias element 35 and guided by the guiding means 18, 32, 33, 34 as described above with respect to FIG. 1. The deployment of the shield portion 3 helps removing the needle from the injection site. After removal of the device from the injection site, the deployed shield 3 avoids any unintended contact with the needle, thereby preventing injuries and avoiding the spreading of any infections. Note that after the liquid has been expelled, there is no counterforce any longer that would act against the bias of the reservoir 10 and the reservoir 10 therefore remains in the collapsed state. In the embodiment shown here, this means that the plunger 12 remains in the second position where the volume of the reservoir 10 is a minimum and the plunger bias element 15 is expanded.

REFERENCE NUMBERS

[0052] 1 dosing portion

[0053] 2 needle

[0054] 3 shield portion

[0055] 4 distal end

[0056] 5 proximal end

[0057] 10 reservoir

[0058] 11 barrel

[0059] 12 plunger

[0060] 13 stem

[0061] 14 seal

[0062] 15 plunger bias element

[0063] 16 housing

[0064] 17 sheath

[0065] 18 lug

[0066] 19 cap

[0067] 20 lumen

[0068] 21 tip

[0069] 22 inlet

[0070] 23 needle mount

[0071] 30 plug

[0072] 31 jacket

[0073] 32 guide rail

[0074] 33 end stop (deployed shield)

[0075] 34 end stop (retracted shield)

[0076] 35 shield bias element

[0077] 36 cover

[0078] Z axial direction