A syringe includes a barrel having a distal end, a proximal end, and a sidewall extending therebetween along a longitudinal axis. At least one engagement member protrudes from a terminal portion of the sidewall in a proximal direction along the longitudinal axis. The at least one engagement member tapers axially in a direction from the distal end toward the proximal end. The at least one engagement member is configured for engagement with a locking mechanism of a fluid injector to releasably lock the syringe with the fluid injector. A taper of the at least one engagement member is configured to rotationally guide the syringe into alignment with the locking mechanism and axially eject the syringe upon rotation of the syringe. The locking mechanism operatively engages the at least one engagement member regardless of an orientation of the syringe about the longitudinal axis relative to the injector.

A fluid delivery system is disclosed which comprises at least one first supply station for supplying a first fluid and at least one second supply station for supplying a second fluid different from the first fluid. The fluid delivery system further comprises a pressurizing unit for pressurizing the first and second fluids, said pressurizing unit comprising first and second pump modules, and each pump module comprising a chamber and a piston provided with a plunger to define first and second variable-volume sub-chambers. The fluid delivery system further comprises first and second inlet fluid circuits, first and second outlet fluid circuits, and a first recirculation fluid pathway fluidically connecting the first and second variable-volume sub-chambers of a pump module. Moreover, a first actuator is associated to said first recirculation fluid pathway for managing the fluid passage in both directions between said first and second variable-volume sub-chambers of said pump module. Methods of operating the fluid delivery system are disclosed too.

A medical fluid pump has a housing, a front lid pivotably hinged to the housing, and a carrying handle. The carrying handle, which may have a bow-shaped design, is pivotably hinged to two opposing side faces of the housing. The carrying handle is hinged to the housing such that a handle portion of the carrying handle lies, in a swiveled-out state, in a direction of gravity substantially over a center of gravity of the fluid pump.

A vial adapter assembly that includes a housing, a first receptacle formed within the housing and configured to receive a first vial within the housing, and a second receptacle formed within the housing and configured to receive a second vial within the housing. An opening of the first receptacle and an opening of the second receptacle is in fluid communication with the upper surface of the housing. The vial adapter assembly includes a cap that is coupled and movable relative to the housing from a closed configuration to an open configuration. In the closed configuration, the cap is configured to cover the opening of the first receptacle and the opening of the second receptacle on the upper surface. In the open configuration, the cap is configured to uncover the opening of the first receptacle and the opening of the second receptacle, and expose the upper surface.

Modules for housing electronic and electromechanical medical equipment including a system to measure and record administration of one or more IV medications or fluids for IV administration.

Disclosed herein is a reservoir for use in a wearable drug delivery device having multiple chambers of potentially varying lengths or arrangement so as to efficiently utilize available space within a housing of the drug delivery device. Each of the chambers is connected to a fluid path and a liquid drug is drawn from each of the chambers by suction applied to the fluid path. Each of the chambers is fitted with a free piston which is moved within the chamber by the suction applied to the fluid path as it draws the liquid drug out of the chamber, thereby eliminating the need for a mechanical arrangement for moving the piston within each of the chambers.

A chemical-liquid injection head including a syringe holding unit which holds a syringe in which a piston member is slidably inserted into a cylinder member having a circular cylindrical shape, a piston driving mechanism having a ram member for moving the piston member of the syringe, and a first light emitting portion which emits light with a first color and illuminates the syringe and a second light emitting portion which emits light with a second color and illuminates the syringe. The first light emitting portion and the second light emitting portion, viewed in a posture at the time of use of the injection head, are provided at an upper side of the ram member.

An infusion pump can determine and display what the drug load is inside of a patient by taking into account various factors such as drug half-life, pump pauses, and delays while a drug moves from a pump to a patient. A pump can also calculate and provide times when: medication will reach the patient; the drug concentration will reach a specified level; and a physiological response is expected. The pump can compensate for pauses in the delivery—for example, by infusing larger boluses of the drug into the patient within safe boundaries for concentration and timing. The pump can also predict what the drug load or concentration will be in the patient over time after the infusion stops by providing a graph, and in some cases act on such predictions by changing a flow rate or other parameters.

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.

A system, method, and computer program product are disclosed for a flow rate algorithm that utilizes changes in fluid pressure over a set time interval to calculate a true flow rate compared to a programmed flow rate, determine any over-delivery or under-delivery in the amount of fluid delivered over the set time interval, compensate for any determined over-delivery or under-delivery in the fluid flow rate over a subsequent set time interval, and repeat the flow rate algorithm for a series of subsequent set time intervals over the duration of a fluid injection procedure.