A manually operated mechanical pump for drug infusion through a syringe including a plunger slidable within a syringe body to cause drug contained within the syringe body to exit a front opening of the syringe. The pump has a pump body with an open front end, to which the syringe attaches, and an open rear end, at which a drive member is associated movably relative to the pump body. A pair of thrust members are provided between the drive member and the syringe to impart longitudinal thrust in a distal direction onto the plunger to cause the drug to exit the front opening. An elastic element is provided between the thrust members to store and release elastic energy when the first thrust member proximal to the drive member is manually actuated, thus causing the second thrust member proximal to the syringe to advance as the drug exits the front opening.

An autoinjector including a housing; an axially fixed product container; a torsion spring; a drive element; a propulsion element; and a needle protection sleeve is configured such that when the autoinjector is pressed against an injection location, the needle protection sleeve undergoes an actuation movement in the proximal direction. For discharging liquid from the product container through an injection needle into the injection location, the torsion spring sets the drive element into rotation and the rotating drive element causes a movement of the propulsion element and a piston in the product container in the distal direction. The autoinjector includes a coupling which, due to the actuation movement of the needle protection sleeve, releases the drive element for rotation, where the coupling is between a first and second coupling element in an engagement of locking surfaces, and can be disengaged by an axial coupling stroke of the two coupling elements.

The present invention relates to a finger grip (1) arranged to be connected to a syringe barrel having a plunger and a plunger rod for driving said plunger. The finger grip comprises a body having a lower side with finger supporting surfaces (13) for supporting fingers of a user during handling and an engagement member (5) being moveable between an inactive position where the engagement member is arranged not to engage with the plunger rod of the syringe barrel and an active position where the engagement member is arranged to engage with a grooved surface on the plunger rod of the syringe such that feedback is given to a user as the plunger is moved relative to the finger grip. An activation member (7) for moving the engagement member from said inactive position to said active position is built-in into the finger grip.

A system for delivering an injection of a fluid into a void within a subject is disclosed. A barrel extends from a first end to a second end and forms a lumen extending from the first end to the second end. A plug and a floating seal are arranged within the lumen. A hollow needle includes a distal end with an opening for fluid to flow from the lumen. The plug, the barrel and the floating seal include material and dimensions selected based on a threshold flowrate for a fluid arranged within the lumen to: overcome a force opposed to a force being applied to the fluid in the lumen to move the floating seal and the hollow needle into a tissue of the subject, and succumb to the opposing force to displace the fluid through the opening into the void.

A drug delivery device (100, 200) for delivering a fixed dose, comprising a drive mecha-nism comprising a drive spring (108, 208), and an activation mechanism comprising a connector (170, 270) adapted for activating the drive mechanism, wherein the drug de-livery device further comprises a split-dose-prevention mechanism adapted for limiting the axial movement of the connector during dosing. The split dose prevention mechanism comprises: (i) a split-dose-prevention structure (184, 284.1, 284.2) provided on the drive tube (180, 280) and extending in a circumferential direction, and (ii) a retention portion (178.3, 278.2) provided on the connector. For the drive tube being arranged in the intermediate position, the split-dose-prevention structure (184, 284.1, 284.2) and the retention portion are arranged with a transverse overlap, whereby movement of the connector in the second axial direction is limited by the split-dose prevention structure. For the drive tube being arranged in the stop position, the split-dose-prevention structure (184, 284.1, 284.2) and the retention portion are arranged with a transverse clearance and/or an axial gap, whereby the return spring (107, 207) can move the connector in the second axial direction, in response to releasing the applied force in the first direction on the connector.

A drug delivery device (100, 200) for delivering a fixed dose, comprising a drive mecha-nism comprising a drive spring (108, 208), and an activation mechanism comprising a connector (170, 270) adapted for activating the drive mechanism, wherein the drug de-livery device further comprises a split-dose-prevention mechanism adapted for limiting the axial movement of the connector during dosing. The split dose prevention mechanism comprises: (i) a split-dose-prevention structure (184, 284.1, 284.2) provided on the drive tube (180, 280) and extending in a circumferential direction, and (ii) a retention portion (178.3, 278.2) provided on the connector. For the drive tube being arranged in the intermediate position, the split-dose-prevention structure (184, 284.1, 284.2) and the retention portion are arranged with a transverse overlap, whereby movement of the connector in the second axial direction is limited by the split-dose prevention structure. For the drive tube being arranged in the stop position, the split-dose-prevention structure (184, 284.1, 284.2) and the retention portion are arranged with a transverse clearance and/or an axial gap, whereby the return spring (107, 207) can move the connector in the second axial direction, in response to releasing the applied force in the first direction on the connector.

The present disclosure relates to an injection device, in particular a micro dose injection device such as, for example, an ophthalmic injection device. An example device comprises a rotatable plunger; a solution receptacle having a first end configured to slidably receive the rotatable plunger and a second end configured to dispense solution contained in the solution receptacle; a first stop member configured to prevent the rotatable plunger from being slidably displaced to a second position while the rotatable plunger is at a first position and in a first orientation; and a second stop member configured to prevent the rotatable plunger from rotating in a first direction about the first axis while the rotatable plunger is at the first position and in the first orientation, wherein slidably displacing the rotatable plunger from the first position to the second position dispenses a quantity of the solution contained in the solution receptacle.

An electronic add-on module for an injection device includes a longitudinal axis and a discharge button arranged at a proximal end and configured to be movable in a distal direction along the longitudinal axis for discharging a liquid medication out of a container of the injection device. The add-on module includes a sensor unit, a receiving region adapted to the shape of the housing of the injection device for placing on along the longitudinal axis thereof, and a holding mechanism configured to releasably secure the add-on module against moving axially relative to the injection device. The receiving region is configured such that the discharge button can be accessed or contacted when the add-on module is on the injection device. The add-on module comprises a release element configured to be moved solely on a plane perpendicular to the longitudinal axis in a release movement for releasing the holding mechanism.

A medical syringe useful for administering an injection or withdrawing a bodily fluid, the syringe comprising a barrel, plunger assembly and a needle assembly having a selectively retractable needle, the plunger assembly further comprising a plunger handle with a plunger seal and a front tip extending forwardly of the plunger seal to extend through the barrel and into the an annular fluid seal disposed in a recess between the barrel and a forwardly projecting needle, thereby reducing dead space inside the syringe and helping anchor the annular fluid seal inside the recess.

An electric injection device at least comprises an outer case, a drive mechanism, a transmission mechanism, a linkage mechanism and a push mechanism. The drive mechanism, the transmission mechanism, the linkage mechanism and the push mechanism are all assembled in the outer case, and the drive mechanism is used to drive the transmission mechanism. The transmission mechanism can transmit power to rotate a push block regularly and drive a brake end of the linkage mechanism continuously. The push mechanism comprises at least a pushing shaft and a pushing element. The brake end can continuously push the pushing element, and the pushing element propels the pushing shaft to further push a syringe assembled on the outer case, so as to use electric injection instead of manual injection to complete the syringe.