The present invention is a self-injection pen. The self-injection pen has a needle, a medication cartridge, and a pen body. The needle and the medication cartridge are standard commercially available components that are suitable for injecting a liquid medication into the subcutaneous tissue layer of a human or animal body. The medication cartridge has a dose adjustor, and the pen body has an outer casing, a dose adjustment dial and an injector button. The needle is secured to the medication cartridge and allows a liquid medication to flow from the medication cartridge into the body of the user. The dose adjustor controls the amount of liquid medication being administered from the medication cartridge.

A receptacle includes: an elongate barrel section with an axial position p determined along an axis, the elongate barrel section extending from an axial position pA to an axial position pB; a side wall extending over the elongate barrel section and having an inner surface bordering an interior with a diameter; and a layer of a lubricant located on at least a part of the inner surface, a portion of the axis extends from a first axial position p1 to a second axial position p2; a mean thickness of the layer is determined in the portion; a position pm is the midpoint between p1 and p2; TA is a mean thickness of the layer for a section from p1 to pm; TB is a mean thickness of the layer for a section from pm to p2; a ratio TA:TB is in a range from 5:1 to 1:5.

At least one hand-held injection device for the metered injection of a liquid drug into a person's tissue is disclosed. The exemplary injection device comprises an elongated drug reservoir having a longitudinal reservoir axis (A), an elongated dosing unit having a dosing unit inlet, a dosing unit outlet, and a metering cavity, the dosing unit having a longitudinal dosing unit axis (A), the elongated drug reservoir being fluidically coupled to the dosing unit inlet. The dosing unit and the drug reservoir are arranged such that the longitudinal dosing unit axis (A) is in parallel alignment with the reservoir axis (A). The dosing unit structured to allow the flow of the liquid drug from the drug reservoir into the metering cavity via the dosing unit inlet, thus charging the metering cavity, and to subsequently discharge the metering cavity by dosing drug out of the metering cavity into the dosing unit outlet.

The control device is used to control delivery of fluids from a multi-fluid delivery system during a medical injection procedure. The fluid delivery system includes an injector used to deliver injection fluids to a patient. The control device is operatively associated with the injector for controlling discrete flow rates of injection fluids delivered to the patient. The control device includes first and second actuators associated with the manual control device, and an electronic substrate disposed within the manual control device and having a conductive pattern. The first actuator is operatively associated with the conductive pattern. The conductive pattern includes a plurality of predetermined digital values corresponding to discrete flow rates of injection fluids to be delivered by the injector. The second actuator is operatively associated with the electronic substrate and initiates output signals to the injector corresponding to desired mixture ratios of the injection fluids to be delivered by the injector.

The invention relates to a drug delivery device for selecting and dispensing a number of user variable doses of a medicament. The device comprises a dosing element (40, 30), which rotates in a first direction during dose selecting and rotates in a second, opposite direction during dose dispensing, and a display (60) for indicating the selected dose. The display (60) comprises at least one belt (61, 62) having symbols for indicating the selected dose and being coupled to the dosing element (40, 130) such that a rotation of the dosing element (40, 130) spools the belt (61, 62).

A drug delivery device comprising: a housing; a plurality of sensors; and a cylindrical member supported within the housing, an outer surface of said cylindrical member being provided with a helical track, the helical track comprising track segments of a first type and track segments of a second type, the first and second types of track segments being respectively capable of inducing first and second responses in the sensors; wherein: the helical track has a width; the helical track includes across the width of the helical track at least one track segment of the first type and at least one track segment of the second type at plural positions along a length of the helical track; the device is configured such that during a first phase of a drug delivery operation the helical track is moved axially, without rotation, relative to the plurality of sensors between a first position and a second position, and during a second phase of the drug delivery operation the track is moved helically relative to the plurality of sensors from the second position; and responses induced in the plurality of sensors by the track segments of the helical track are different in the first position compared to responses induced in the plurality of sensors by the helical track in the second position.

Disclosed are systems and methods of detecting an impulse of energy given off by an injection device and determining a dosage of medicine based on the impulse. In one example, a module detects the vibrations given off by dialing a click-wheel on an autoinjector and determining the selected dosage of medicine based on the dialed dosage.

A portable vaporizer is described herein. The portable vaporizer includes a heating assembly having a base and a heating crucible. An extension adapter is coupled to the base of the heating assembly and slidably received within the chamber body. A cartridge receiver is coupled to the chamber body and receives a cartridge therein. A plunger having a head and a threaded shaft is received within the cartridge. The threaded shaft includes a flat edge. A cover having a bore is coupled to the cartridge receiver. The threaded shaft is threadably received through the bore. A mouthpiece having a central bore is received over the threaded shaft. A detent radially extends into the central bore and engages with the flat edge of the threaded shaft. A rotation of the mouthpiece causes an axial movement of the head of the plunger within the cartridge with respect to the cover.

A syringe includes a barrel having an internal surface defining an internal bore therein; a plunger having a distal end disposed within the internal bore of the barrel, and a proximal end disposed outside the internal bore of the barrel, the proximal end of the plunger being opposite the distal end of the plunger along a longitudinal direction; and a dose divider. The dose divider includes a divider flange extending at least partly in a radial direction, the radial direction being perpendicular to the longitudinal direction, the divider flange having a distal surface that faces the barrel, the distal surface of the divider flange bearing on the proximal end of the plunger, and a concave shell extending away from the distal surface of the divider flange along the longitudinal direction.

In some embodiments, an adjunct device for tracks time and/or dosage of a medicine. The device may include a connector for mounting the device to a deposable pen injector. The device may be configured to allow use of the native controls and injectors of the injector. For example the device may include a view port for viewing a dose indicator of the injector. The device may include one or more vibration sensors. A processor may be configured to differentiate increasing a dose, decreasing a dose and/or discharging the medicine based on the output of the sensors. Optionally a display of the device may be positioned for simultaneous viewing with the dosage indicator of the injector. For example a user may verify the accuracy of the adjunct device before performing a discharge.