An inventive medical device for transcutaneously inserting a cannula into body tissue. The device has a cannula with a wall that at least partially encloses a lumen. The device also has a patch for mounting onto skin of a user. The patch has a base and has a reservoir for storing a medical fluid. The patch also has a spring driven inserter. The inserter has a drive that urges the cannula from a storage position within the patch to an inserted position within the body tissue. The inserter also has a lock configured for securing the drive in a fixed position. The lock is fixedly connected to the drive and has a snap closure. Also disclosed is a medication pump that is fluidly connectable to the cannula. A method of transcutaneously using the medical device to transcutaneously insert a cannula into body tissue is also disclosed.

The present disclosure relates to a drive mechanism which is suitable for an injection device, especially a drug delivery device. The mechanism comprises a housing having a longitudinal axis defined by a compartment for receiving a cartridge, a plunger suitable for acting on a bung of a cartridge retained in the housing, a strained pressure spring arranged between the housing and the plunger, a retaining member coupled to the plunger, and a release member operable between a first state, in which the release member constrains the retaining member to the housing, and a second state, in which the release member is movable relative to the housing.

Self-righting articles, such as self-righting capsules for administration to a subject, are generally provided. In some embodiments, the self-righting article may be configured such that the article may orient itself relative to a surface. In some embodiments, the self-righting article may have a particular shape and/or distribution of density (or mass) which, for example, enables the self-righting behavior of the article. In some embodiments, the self-righting article may comprise a tissue interfacing component and/or a pharmaceutical agent. In some cases, upon contact of the tissue with the tissue engaging surface of the article, the self-righting article may be configured to release one or more tissue interfacing components. In some cases, the tissue interfacing component may comprise and/or be associated with the pharmaceutical agent.

An engagement mechanism associated with a reciprocally movable piston of a fluid injector is configured for releasably engaging an engagement portion at a proximal end of a rolling diaphragm syringe having a flexible sidewall configured for rolling upon itself when acted upon by the piston. The engagement mechanism has a plurality of engagement elements reversibly and pivotally movable about a pivot pin relative to the engagement portion of the syringe between a first position, where the plurality of engagement elements are disengaged from the engagement portion of the syringe, and a second position, where the plurality of engagement elements are pivotally movable about the pivot pin in a radially inward direction to engage with the engagement portion of the syringe. The engagement mechanism further has a drive mechanism for moving the plurality of engagement elements between the first position and the second position.

Described herein are systems and methods for performing peritoneal dialysis. According to one aspect, the disclosure provides a sterile interface connection for connecting a water purification system to a disposable source of dialysate concentrates. The sterile interface connection can include a chamber comprising an inlet adapted to be connected to the water purification system on a proximal end and a valve on a distal end. The sterile interface connection can also include spring-loaded needle disposed in the chamber. The spring-loaded needle can move between a retracted configuration in which the spring-loaded needle is fully retracted into the chamber and the valve is closed and sealed, and an extended configuration in which the spring-loaded needle extends through the valve into the disposable source of dialysate concentrates.

In one aspect, a drug delivery device is provided for delivering drug from a plurality of drug cartridges. The drug delivery device includes: a cylindrical cassette configured to accommodate the plurality of drug cartridges; a reversibly advanceable plunger; and, an indexer for incrementally rotating the cassette to align the plurality of drug cartridges individually with the plunger. The indexer includes first and second shafts with cooperating elements which cause incremental rotation of the first shaft, relative to the second shaft, upon the second shaft engaging the first shaft.

An automatic injection device with flow regulation. The automatic injection device has an insertion needle configured to be inserted into a patient and a drug container which contains a pharmaceutical product and includes a plunger. The automatic injection device also has a fluid path which fluidly connects the drug container to the patient via an insertion needle, a potential energy source, and a regulator configured to restrict release of potential energy and restrict linear movement of the plunger and the pharmaceutical product into the fluid path at a proscribed pace. The regulator includes a clock escapement mechanism and a wire and pulley system including a wire coupled to at least one pulley. The potential energy source may be a spring that surrounds the drug container and may be directly coupled to the plunger and the wire such that movement of the spring and the wire is restricted over time.

A syringe assembly for a drug delivery device. The syringe assembly includes a syringe barrel having a proximal end, a distal end, and a longitudinal axis. A needle assembly is operatively coupled to the syringe barrel and includes a needle hub and a needle attached to the needle hub. A flexible connection is disposed between the syringe barrel and the needle hub and forms a fluid pathway between the syringe barrel and the needle. The flexible connection enables the needle assembly to be moveable from a filling position, in which a longitudinal axis of the needle assembly is parallel to a longitudinal axis of the syringe barrel, to an assembled position, in which the longitudinal axis of the needle assembly is not parallel to the longitudinal axis of the syringe barrel.

An automatic injection device with flow regulation is disclosed. The automatic injection device has an insertion needle configured to be inserted into a patient and a drug container which contains a pharmaceutical product and includes a plunger. The automatic injection device also has a fluid path which fluidly connects the drug container to the patient via the insertion needle, a potential energy source, and a regulator configured to restrict release of potential energy and restrict linear movement of the plunger and the pharmaceutical product into the fluid path at a proscribed pace. The regulator includes a clock escapement mechanism. The potential energy source may be a spring that surrounds the drug container and may be magnetically coupled to the plunger. The clock escapement mechanism is configured to control the spring at a regulated rate over a time interval using a gearbox and a rotational-to-linear translator comprising a rack and a pinion.

A drug delivery device has a housing with an adhesive pad associated with the lower surface of the housing and configured to removably attach to a human body surface. A deformable drug reservoir is positioned within the housing and includes an outlet, with a needle fluidically connected to the drug reservoir and configured to define at least a portion of a fluid flow path between the drug reservoir and said human body surface. A delivery assembly is associated with the drug reservoir and includes a roller and a drive assembly, with the drive assembly being controlled by the controller during a drug delivery routine to move the roller from a first position to a second position so as to cause the roller to contact and deform the reservoir, thereby conveying a drug from the reservoir via the outlet.