Aspects of this disclosure relate to a pump cassette with a radio frequency identification (RFID) tag. The RFID tag can store information associated with the pump cassette, such as usage information and/or a unique identifier. The RFID tag can be embedded in a component of the pump cassette in certain embodiments. Related infusion pumps, infusion sets, and infusion systems are disclosed.

There is described a patch pump comprising a cartridge, a power source, a pump system, a drug delivery device and a control system configured to operate in particular the pump system and the drug delivery device. The pump system includes, on the one hand, a pump having a pump housing containing a pump piston and a valve piston and, on the other hand, a pump drive including a piston motor and a valve motor for driving the pump piston and the valve piston independently from each other through a first and a second transmission. The drug delivery device includes a transdermal delivery system having a needle actuation mechanism configured for transdermal insertion of a cannula.

Disclosed are methods of radioisotope infusion comprising infusing saline comprising a diagnostic dose of a radioisotope, and delivering a pre-measured volume of push saline. The disclosed methods confer improved image quality with low background noise, higher signal to noise ratio (SNR) and higher contrast to noise ratio (CNR), leading to better diagnosis and thus eliminating the need of repeating the infusion and imaging which in turn reduces exposure of a patient to radiation.

A delivery assembly includes a console including a vial containment region and a vial engagement mechanism extending from the console within the vial containment region. The engagement mechanism is configured to engage a vial assembly including a particulate material. The delivery assembly further includes a multi-port needle with a top distal port and bottom proximal port(s), the needle configured to puncture a septum of the vial assembly when the vial assembly is in the locked position, in which the top distal port is at a distance above the particulate material in the vial assembly. The ports are configured to inject a fluid into the vial assembly to mix with the particulate material upon actuation of the vial engagement mechanism in a first direction and to receive a resulting mixed fluid from the vial assembly upon actuation of the vial engagement mechanism in a second opposite direction.

In one aspect, the subject invention is directed to a method of preparing a combinatorial drug delivery device based on a predetermined selection of drug components. The method includes: preparing a plurality of containers, each accommodating one of the selected drug components; coupling the containers to a common outlet so that the drug components may be extracted from the containers and dispensed through the common outlet; and, applying negative pressure to extract the drug components from the containers and urge the drug components towards the common outlet.

A controller controls a fluid pump to deliver primary fluid from a first source at a desired rate through a respective conduit to a recipient. The controller monitors a volume of the primary fluid injected into the conduit. Subsequent to injecting a predetermined amount of the primary fluid into the conduit, the controller i) discontinues injection of the primary fluid into the conduit and ii) injects a secondary fluid through the conduit to advance a remaining portion of the primary fluid in the conduit to the recipient. The controller advances the secondary fluid into the conduit until a desired amount of the primary fluid is delivered trough the conduit to the recipient. Injection of the secondary fluid to push the remaining portion of the primary fluid reduces waste associated with the primary fluid.

Systems and methods of micro-infusion of medical fluids are disclosed. Micro-infusion systems may include a pump, a patient interface, tubing between the pump and the interface, and a micro-infusion device along the tubing. A first portion of the tubing above the micro-infusion device is longer than a second portion of the tubing below the device. The micro-infusion device may include a chamber in-line with the tubing, a first valve between the chamber and the first portion of the tubing, a second valve between the chamber and the second portion of the tubing and a third valve between the chamber and a dump chamber. The second valve may be slidably disposed within the chamber. A medical fluid may be provided into the chamber that slides the second valve displacing another fluid in the chamber through the third valve into the dump chamber.

A syringe pump determines, upon receiving a new syringe, that at least a first portion of a predetermined amount of a first fluid was previously delivered by the syringe pump according to a first fluid delivery order before the new syringe was loaded into the syringe pump, and determines a second portion of the first fluid remaining to be delivered to complete the predetermined amount of the first fluid for the first fluid delivery order. A delivery of a second fluid is initiated by the syringe pump and, when an amount of the second fluid delivered from the new syringe satisfies the second portion of the first fluid remaining to be delivered, the pump automatically, without user intervention, indicates the first fluid delivery order as being complete, de-associates the first fluid delivery order from the syringe pump, and associates the syringe pump with the second fluid delivery order.

Infusion pumps including a plurality of reservoirs arranged either serially and/or in parallel with one another are described. In some embodiments, flow channels with a desired arrangement of flow resistances, bypass flow paths, pressure sensors, and/or meniscus control structures may be included in the infusion pump to provide a desired flow of one or more therapeutic compounds into and/or out from an infusion pump.

A system for the delivery of therapeutic substances to cavities of a patient. The system can include a handpiece tool coupled with a pump. The handpiece tool can include a shaft including a first portion of a channel coupled to a multi-input tubing. The handpiece tool can include an angled portion coupled with the shaft. The handpiece tool can include a second portion of the channel, wherein the angled portion positions a tip portion within a cavity, wherein the tip portion projects from the angled portion and includes an outlet and a third portion of the channel. The handpiece tool can include a collar a distance from the outlet, the collar configured to control a distance the tip portion projects. The handpiece tool can include a mixing chamber configured to receive the components of the drug and output the mixed drug via the third portion of the channel.