A method for dynamic pressure control during a multiphase injection is described wherein the pressures of fluids in the various reservoirs of a fluid delivery system are controlled to provide desired fluid delivery parameters. The methods include advancing the first drive member to expel the first fluid from the first reservoir into a conduit, wherein the fluid is pressurized to a first fluid pressure; measuring the first fluid pressure to provide a target value; while the second reservoir is in fluid isolation from the conduit, advancing or retracting the second drive member to increase or decrease the fluid pressure of the second fluid in the second reservoir to the target value; placing the second reservoir in fluid communication with the conduit; and advancing the second drive member to expel the second fluid from the second reservoir into the conduit.

A patch-sized fluid delivery device may include a reusable portion and a disposable portion. The disposable portion may include components that come into contact with the fluid, while the reusable portion may include only components that do not come into contact with the fluid. Redundant systems, such as redundant controllers, power sources, motor actuators, and alarms, may be provided. Alternatively or additionally, certain components can be multi-functional, such a microphones and loudspeakers that may be used for both acoustic volume sensing and for other functions and a coil that may be used as both an inductive coupler for a battery recharger and an antenna for a wireless transceiver. Various types of network interfaces may be provided in order to allow for remote control and monitoring of the device.

A device (1), for a ventilation system (100), includes an inhalation valve (10) with an inhalation opening (11) for flow (301) of breathing gas (300) into a pressure chamber (110) to provide breathing gas in the pressure chamber for ventilating a patient (200). A closing element (12) is arranged movably, to close the inhalation opening to flow in a closed position (320) and to at least partially release flow in an open position (310). A transmission device (13) is connected via a connection element (14) to the closing element, to hold the closing element in the closed position in a starting position of the transmission device, such that the inhalation valve is normally closed. A control pressure source (130) provides a control pressure (PS) in a control pressure chamber (15) for the transmission device to move the transmission device out of the starting position by the control pressure.

Devices and methods are disclosed that provide a syringe actuator device for use in the distention and irrigation of a body conduit before the use in a medical procedure such as a coronary bypass graft procedure. The device can be retrofit to a syringe by attaching it to the cap of the plunger and engaged to automatically apply pressure to fluid in the syringe. In some embodiments, elastic bands attached to the device are easily engaged or removed from a syringe during a procedure to limit the pressure on the syringe to various levels. The device may be overridden by an operator pushing on the plunger of the syringe as in normal syringe operation.

A fluid delivery device and a method for controlling the delivering of a fluid to a user. The fluid delivery device includes a cartridge body; a fluid outlet nozzle attached to the cartridge body; a fluid jet ejection cartridge disposed in the cartridge body, the fluid jet ejection cartridge containing a fluid and an ejection head attached to the fluid jet ejection cartridge; wherein the ejection head contains a plurality of fluid ejectors thereon and a nozzle plate having a plurality of fluid ejection nozzles therein associated with the plurality of fluid ejectors configured to deliver the fluid to a user at a predetermined rate. A control system is disposed in the fluid delivery device that includes a differential pressure sensor for sensing an inhalation differential pressure. The control system is configured to terminate fluid delivery below a threshold inhalation differential pressure.

A method includes initiating one or more pumps of an apheresis machine, detecting a flow of fluid through the apheresis machine, detecting the flow of fluid is below a predetermined threshold, and in response to detecting the flow of fluid is below the predetermined threshold, adjusting a rate of the one or more pumps of the apheresis machine.

A peritoneal dialysis (“PD”) system includes a cycler having a micropump actuator, a pressure transducer, and at least one valve actuator; a disposable set including a micropump head sized and shaped for mating with and being driven by the micropump actuator, a pressure sensor configured to operably communicate with the pressure transducer, and at least one fluid valve portion or a portion of at least one fluid line for interfacing with the at least one valve actuator; and a control unit, wherein the disposable set may be arranged to allow, and the control unit may be programmed to operate the micropump actuator and the at least one valve actuator, so that fresh and used dialysis fluid flows through the micropump head in a same direction. The system may also dampen pressure fluctuations via pressure pods, and may analyze the outputs from the pressure pods for patient empty and occlusion detection.

A wearable automated peritoneal dialysis (“APD”) machine is disclosed herein. In an example, the APD machine includes a delivery system connected to a dialysis fluid container and a catheter connected to a peritoneal cavity of a patient. The delivery system includes a pump for pumping fresh dialysis fluid from the dialysis fluid container to the patient, and pumping used dialysis fluid from the patient to the dialysis fluid container. The delivery system also includes a control unit configured to control the pump using a flow rate measured by a flow sensor and a pressure measured by a pressure sensor. The APD machine also includes a clothing item to be worn by the patient. The clothing item includes a first section to retain the dialysis fluid container, a heating element positioned adjacent to the first section for warming the fresh dialysis fluid, and a second section to retain the delivery system.

A patch-sized fluid delivery device may include a reusable portion and a disposable portion. The disposable portion may include components that come into contact with the fluid, while the reusable portion may include only components that do not come into contact with the fluid. Redundant systems, such as redundant controllers, power sources, motor actuators, and alarms, may be provided. Alternatively or additionally, certain components can be multi-functional, such a microphones and loudspeakers that may be used for both acoustic volume sensing and for other functions and a coil that may be used as both an inductive coupler for a battery recharger and an antenna for a wireless transceiver. Various types of network interfaces may be provided in order to allow for remote control and monitoring of the device.

An apparatus for determining the volume of fluid dispensed. The apparatus has an acoustic volume sensor that acoustically excites a reference volume and a measurement chamber with a loudspeaker and measures the acoustic response with microphones acoustically coupled to the reference and the measurement chamber. The loudspeaker and sensing microphones are connected to the measurement chamber by separate ports. A detachable dispensing chamber is coupled to the acoustic volume sensor. The volume of the fluid dispensed is determined by a processor based on the acoustic response of the microphones to acoustic excitement by the loudspeaker.