A medical device comprising an enclosure defining a cavity for containing agent, a lumen for receiving a pressurized gas, and a barrier positioned between the cavity and the lumen, the barrier including at least one opening for storing agent, wherein rotation of the barrier relative to the lumen establishes fluid communication between the at least one opening and the lumen for delivering agent from the at least one opening to the lumen.

A drive train for a wind-up injection device, comprises a torsional energy storage adapted to be loaded or unloaded by a rotatable element, a rotatable user handle coupled with a button, a rotationally drivable expelling mechanism, and a clutch element coupled with the torsional energy storage via the rotatable element and comprising a ratchet for maintaining the rotatable element at one of a number of discrete angular positions, wherein via the rotatable element, the clutch element is adapted to transmit a torque from the user handle to the torsional energy storage or from the torsional energy storage to the expelling mechanism, and wherein the ratchet is switchable from one position to an adjacent position by a torque transmitted from the user handle to the torsional energy storage, and wherein the drive train is adapted to dampen torque peaks by a flexible impact portion in the area of the clutch element.

A drug delivery device is disclosed that includes a housing including a channel, a drug reservoir fitting into the channel, and a friction element extending from a housing to the channel to contact an exterior side wall of the reservoir when the reservoir is inserted into the channel. The friction element is configured and oriented to wedge between the exterior wall and the reservoir when the reservoir is rotated in a first rotational direction.

A flexible plunger rod, drug delivery mechanism, drug delivery device, and methods are described that utilize the flexible plunger rod perform drug delivery operations. In embodiments, the flexible plunger rod can be stored in a curved configuration to thereby reduce a footprint of the drug delivery mechanism and device.

An injection includes a tube having opposite first and second ends. A hub is coupled to the first end. A sheath is coupled to the tube and the hub. The hub is movable relative to the tube to move the sheath between a first orientation in which the sheath covers an orifice in the second end and a second orientation in which the sheath is spaced apart from the orifice. Kits and methods of use are disclosed.

An autoinjector for dispensing a liquid product, in particular a highly viscous medication, includes: a housing, a product container, which is arranged in the housing and has a slidable piston, wherein the piston can be slid in a dispensing direction in order to dispense the product contained in the product container, a forward drive element, which acts on the piston as the product is being dispensed, a first spring, which is preloaded such that the product can be dispensed from the product container by the sliding of the forward drive element and the piston, and a rotation element, which is operatively coupled to the forward drive element, wherein the first spring acts on the rotation element in such a way that the rotation element is set into rotation in order to dispense the product, wherein the rotation element or the forward drive element has a thread having a variable pitch.

The present invention provides an injection device (1, 101, 201) comprising a housing (2, 102, 202), a cartridge (30, 130, 230) holding a medical substance and comprising an outlet and a piston (31, 131, 231), a dose expelling mechanism comprising a piston rod system (10, 50, 110, 150, 210, 250) adapted to be moved relative to the housing (2, 102, 202) during a dose expelling action to thereby advance the piston (31, 131, 231) in the cartridge (30, 130, 230), and a ratchet arm (12) operatively coupled with the piston rod system (10, 50, 110, 150, 210, 250) and configured to undergo a deflecting motion relative to the housing (2, 102, 202) during a particular movement of the piston rod system (10, 50, 110, 150, 210, 250) which corresponds to a predetermined volume of the medical substance being expelled from the cartridge (30, 130, 230), the deflecting motion comprising a first part motion which decelerates the piston rod system (10, 50, 110, 150, 210, 250) followed by a second part motion which accelerates the piston rod system (10, 50, 110, 150, 210, 250), an integrated sensor (76, 176, 276) arranged to detect occurrences of acceleration of the piston rod system (10, 50, 110, 150, 210, 250), and a processor (75, 175, 275) configured to register the occurrences detected by the integrated sensor (76, 176, 276) during the dose expelling action.

A liquid medicine ejection tool includes a syringe and a gasket pressing tool. The gasket pressing tool includes a gasket pressing member that can enter a gasket in the syringe. The gasket has an original lumen portion axial length, and a gasket-mounting portion of the gasket pressing member has an axial length longer than the original lumen portion axial length. When the gasket pressing member is mounted on the barrel of the gasket, a mounting portion distal surface of the gasket-mounting portion abuts on a lumen distal surface of a lumen portion of the gasket, and a gasket proximal surface pressing portion of the gasket pressing member becomes close to or abuts on a proximal surface of the gasket.

An injection includes a tube having opposite first and second ends. A hub is coupled to the first end. A sheath is coupled to the tube and the hub. The hub is movable relative to the tube to move the sheath between a first orientation in which the sheath covers an orifice in the second end and a second orientation in which the sheath is spaced apart from the orifice. Kits and methods of use are disclosed.

A drive assembly for a drug delivery system includes a plunger member configured to engage and move a stopper within a container, with the plunger member having a first position and a second position axially spaced from the first position, a leadscrew configured to move the plunger member from the first position to the second position, and a biasing member configured to bias the leadscrew in a rotational direction, where rotational movement of the leadscrew is configured to move the plunger member from the first position to the second position.