The present disclosure relates to a body arrangement for a drug delivery device, comprising at least one deployable body part arranged to be moved from a compact state into a deployed state, wherein the body part in the deployed state provides an enlarged grip area compared to the compact state.

A pen needle and a method of using the pen needle. The pen needle includes a housing, a needle carrier in the housing supporting a needle, a distal shroud positioned around the needle within the housing, a distal compression spring positioned around the needle between the needle carrier and the distal shroud, a proximal shroud positioned around the needle within the housing, and a proximal compression spring positioned around the needle between the needle and the proximal shroud. The proximal shroud is movable between a first position, in which it engages the distal shroud to hold it in engagement with the housing, and a second position in which the proximal shroud is disengaged from the distal shroud allowing the distal shroud to move in a distal direction to project from the housing and surround the end of the needle.

An apparatus for use with a syringe to provide a safety syringe, the apparatus comprising: a sheath (100; 300; 500; 700; 900; 1100; 1300) deployable for at least partially covering a needle of the syringe; a sheath actuator (102; 302; 502; 702; 902; 1102; 1302) for deploying the sheath; and a ratioed mechanism (104; 304; 504; 704; 904; 1104; 1304) linking the sheath and the sheath actuator and configured such that a magnitude of movement of the sheath is greater than a magnitude of movement of the sheath actuator during deployment of the sheath.

Safety needle device (1) comprising: a hub (10) configured to be connected to a vessel, a needle (20) attached to the hub (10), the needle (20) extending along a longitudinal axis (X-X) between a distal end (21), formed for insertion into a patient, and an opposed proximal end (22) formed to be connected to the vessel, a shield (30) slidable relative to the hub (10) along the longitudinal axis (X-X) and rotationally constrained around the longitudinal axis (X-X), the shield (30) being slidable irreversibly from an initial position, before injection, to a locking position, after injection passing through an intermediate position, a housing (40) attached to the hub (10) and surrounding a portion of a portion of the hub (10) and a portion of the shield (30), an elastic member (50) arranged within the housing (40) and acting the shield (30), the elastic member (50) being biased to push the shield (30) towards the distal end (21) of the needle (10) and contrast a longitudinal sliding of the shield (30) towards the proximal end of the needle (10), a sleeve (60) arranged within the housing (40) and mounted rotatable around the longitudinal axis (X-X) relative to the shield (30) and the housing (40), a locking arrangement (70) comprising at least a first locking member (71) formed on the shield (30) and at least a second locking member (72) formed on the sleeve (60), the first locking member (71) cooperating with the second locking member (72) to rotate the sleeve (60) upon sliding of the shield (30) and to lock the shield (30) in the locking position, the shield (30) surrounds at least partially the sleeve (60), the safety needle device (1) comprises a guiding arrangement (80) comprising first guiding members (81) formed on the shield (30) and second guiding members (82) formed on the housing (40), the first locking members (81) cooperating with the second locking member (82) to guide the sliding of the shield (30) along the longitudinal axis (X-X) and to prevent rotation of the shield (30) relative to the housing (40).

In one aspect, a safety pen needle assembly is provided herein which includes a hub with a needle fixed to the hub, the needle having a distal end, formed for insertion into a patient, and a proximal end. The assembly further includes a shield and a biasing member disposed between the hub and the shield configured to urge the shield distally. A protrusion extends from at least one of the hub and the shield with a channel being formed in at least the other of the hub and the shield. The channel is formed to accommodate the protrusion. The shield is movable from a first position to a second position. In the first position, the shield is spaced from the distal end of the needle such that the distal end of the needle is exposed. In the second position, the shield covers the distal end of the needle. The channel guides the protrusion as the shield moves from the first position to the second position. With this arrangement, a shield may be directed to move in a desired path with stability. In addition, the distal end of the needle may be initially exposed to permit visual confirmation of priming, while allowing the shield to cover a majority of the needle to minimize any needle-related anxiety.

Disclosed herein is an auto injector with a bi-stable clutch plate.

The application relates to a needle protection assembly (1) comprising: —a supporting element (18) and a needle shield (8), —one locking element (20) located within said needle protection assembly (1) and not accessible to the user, —urging means (24) for displacing said needle shield (8), —a peg (19) located on said supporting element (18) or on said needle shield (8), and a cam (9) located on said needle shield (8) or on said supporting element (18), and —said locking element (20) is not formed by said peg (19) and cam (9). The respective longitudinal axis of the needle shield (8) and of the locking element (20) are merged when said needle shield (8) is in its before use or in use positions, and they form an angle (a) when said needle shield (8) is in its after use position.

A safety needle (10) and a safety needle device (1). The safety needle device (1) comprises the safety needle (10), an outer protective cover (60), and a sealing membrane (70). The outer protective cover (60) cooperates with the sealing membrane (70) to seal and package the safety needle (10). The safety needle (10) comprises a needle sleeve housing (20), a syringe assembly holder (40), a needle (30), and an elastic safety cover (50). The syringe assembly holder (40) is provided at a rear end of the needle sleeve housing (20). The needle (30) is movably provided inside the needle sleeve housing (20) and the syringe assembly holder (40). The elastic safety cover (50) is provided in the needle sleeve housing (20) so as to be capable of rotating and extending and retracting. A non-return guide slot (23) having a non-return elastic plate (235) in the needle sleeve housing (20) guides a needle sheath elastic engagement component (55) of a needle sheath (51) of the elastic safety cover (50) such that the elastic safety cover (50) can extend and retract in an axial direction of the needle sleeve housing (20) and control the timing of the extension of the needle (30) outside the elastic safety cover (50). After use, the elastic safety cover (50) covering an outer side of the needle (30) can be stopped and locked in the needle sleeve housing (20) by the non-return elastic plate (235) such that the safety needle (10) cannot be used again, thus ensuring safety of use.

The invention relates to a spring driven injection device for expelling doses a liquid drug. A housing structure secures a container containing a liquid drug to be injected via a spring driven dose engine. A needle shield is rotatably relatively to the housing structure between a locked position and an unlocked position. In the locked position the needle shield is prevented from axial movement and in the unlocked position axially movement is possible by applying an axial force onto the needle shield. Axial movement of the needle shield activates the spring driven dose engine to automatically eject the dose of the liquid drug from the container. The needle shield is rotational guided from the locked position to the unlocked position in a track arrangement which is further configured to prevent the needle shield in rotation from the locked position to the unlocked position during application of the axial force to the needle shield.

A needle set includes a needle guard and a winged needle. The needle guard has upper and lower jaws, each of the upper and lower jaws defining a channel and coming together at a hinge. The upper and lower jaws are separated by slots in sides of the needle guard, which slots divide the sides into upper and lower side walls, respectively. The winged needle can be inserted between the upper and lower jaws, with wings of the winged needle passing through the slots. The hinge has an opening and a tube connected to the winged needle passes through the opening.