A catheter assembly (10) comprises a catheter (22), a needle (12) having a sharp distal tip, a catheter hub (14) housing the catheter (22), the catheter hub (14) having a collar (34) including a notch (36), a needle shield (20) connected to the catheter hub (14) when the needle (12) is in a first position, and a clip (40) disposed in the needle shield (20) that cooperates with the needle (12), wherein the clip (40) engages the catheter hub (14) in the first position of the needle (12), and the clip (40) disengages the catheter hub (14) via the notch (36) when the needle (12) is retracted to a second position to cover at least a portion of the needle (12). The clip (40) is mounted in the outer housing (38) of the needle shield (20) via a spade (66) having an outer wall (70) exposed to the outside of the needle shield (20), in order to reduce the overall width of the needle shield (20).

The present invention relates to a self-sealable injection needle for inhibiting formation of fistula on an eyeball, and a method for manufacturing same. More specifically, the self-sealable injection needle for inhibiting formation of fistula on an eyeball, which is coated with hyaluronic acid on the surface thereof, can immediately close a hole that is inevitably formed when the injection needle is pulled out of an eyeball during the application of an ocular injection to prevent leakage of aqueous humor and to prevent backflow of drug out of the eyeball and can block bacterial penetration to prevent infection in the eyeball.

The disclosure relates to systems, methods and apparatus of storing, transporting, mixing, and injecting a drug as a solution, and in some embodiments, to a drug injection apparatus and system intended for use in mixing on demand a drug with a liquid, such as water, in a premeasured quantity and dosage, and injecting the drug mixture using an integrated hypodermic needle assembly. Also provided are methods of using such apparatus and systems.

Disclosed are introducer components, assemblies, and methods. For example, an introducer assembly can include a syringe and a needle assembly fluidly connected thereto. The needle assembly can include a needle and an access guidewire-advancement mechanism mounted on a proximal linear portion of a needle shaft of the needle. The needle shaft can include a sigmoid portion between a distal linear portion of the needle shaft and the proximal linear portion as well as a port in a transition from the sigmoid portion to the distal linear portion of the needle shaft. An access guidewire can be loaded in both the access guidewire-advancement mechanism and a needle-shaft lumen in the distal linear portion of the needle shaft in a ready-to-deploy state of the introducer assembly. In this way, the access guidewire can be immediately advanced into a blood-vessel lumen upon establishing a needle tract thereto with the needle.

Disclosed are introducer components, assemblies, and methods. For example, an introducer assembly can include a fluidly connected syringe and needle. The needle can include a needle shaft and a needle hub over a proximal portion of the needle shaft. The needle hub can include a port and a valve disposed in the port. The port can be in a side of the needle hub proximal of a proximal end of the needle shaft. The valve can be configured to form a fluid-tight seal around an elongate medical device such as an access guidewire when passed through the port and into a needle-hub lumen of the needle hub. Such an access guidewire can be disposed in the introducer assembly just proximal of a needle tip of the needle. In this way, the access guidewire can be immediately advanced into a blood-vessel lumen upon establishing a needle tract thereto with the needle.

A needle module for a drive-controlled handheld unit for repeatedly piercing human or animal skin, comprising a housing; a needle holder, which can be moved back and forth in the housing in a longitudinal direction of the housing; a piercing device on the needle holder, which can be moved, on account of the movement of the needle holder, between a proximal and a distal position, in which a piercing tip of the piercing device is arranged outside the housing; a coupling component, which is coupled to the needle holder in such a way that a driving movement provided with a repetition frequency by a drive device that can be coupled to the coupling component can be introduced onto the needle holder; and a damping component, which is arranged between the needle holder and the coupling component and is configured to damp a transfer of force therebetween.

Injection devices for delivering pharmaceutical compositions into the eye are described. Some devices include a resistance component for controllably deploying an injection needle through the eye wall. The resistance component may be disposed on the injector device, or on a portion of the injection device housing, or on a drug reservoir. Some devices may be removably attached to a drug reservoir, for example, through a luer connector. Other devices may comprise internal luer seal for securely connecting a drug conduit of the device to the luer cavity of a drug reservoir. Yet other devices may comprise a priming-enabling element to facilitate the drug priming of a shielded needle. Related methods and systems comprising the devices are also described.

A drive mechanism suitable for use in drug delivery devices is disclosed. The drive mechanism may be used with injector-type drug delivery devices, such as those permitting a user to set the delivery dose. The drive mechanism may include a housing, a dose dial sleeve, and a drive sleeve. A clutch is configured to permit rotation of the drive sleeve and the dose dial sleeve with respect to the housing when the dose dial sleeve and drive sleeve are coupled through the clutch. Conversely, when the dose dial sleeve and drive sleeve are in a de-coupled state, rotation of the dose dial sleeve with respect to the housing is permitted and rotation of the drive sleeve with respect to the housing is prevented. In the de-coupled state, axial movement of the drive sleeve transfers force in a longitudinal direction for actuation of a drug delivery device.

A drive mechanism suitable for use in drug delivery devices is disclosed. The drive mechanism may be used with injector-type drug delivery devices, such as those permitting a user to set the delivery dose. The drive mechanism may include a housing, a dose dial sleeve, and a drive sleeve. A clutch is configured to permit rotation of the drive sleeve and the dose dial sleeve with respect to the housing when the dose dial sleeve and drive sleeve are coupled through the clutch. Conversely, when the dose dial sleeve and drive sleeve are in a de-coupled state, rotation of the dose dial sleeve with respect to the housing is permitted and rotation of the drive sleeve with respect to the housing is prevented. In the de-coupled state, axial movement of the drive sleeve transfers force in a longitudinal direction for actuation of a drug delivery device.

The present invention provides a two-step auto-injection apparatus consisting of a housing, a protective sleeve cylinder, a pre-filled injection assembly and a drive feedback apparatus, wherein the pre-filled injection assembly is loaded into the housing, and the protective sleeve cylinder covers a needle of the pre-filled injection assembly, so that the protective sleeve cylinder directly contacts an injecting portion and the function of injection can be realized by pressing to trigger the drive feedback apparatus during use, thereby facilitating quick operation with a needle tip hidden in the whole process; the drive feedback apparatus of a piston in a needle cylinder is driven to combine a release mechanism with an ejection mechanism and a feedback mechanism, and the release mechanism is triggered by pressing the protective sleeve cylinder, so that the ejection mechanism is released, and the ejection mechanism interacts with the feedback mechanism in a form of collision, for example, to generate a sound signal and/or a haptic signal in the moment of release for prompting a patient to begin an injection; when the ejection mechanism finishes movement, the ejection mechanism interacts again with the feedback mechanism in the form of collision, for example, to generate the sound signal and/or the haptic signal for promoting the patient to finish the injection.