An apheresis system may include an assembly for separating a component from a multi-component fluid, a processor, and a memory storing data for processing by the processor. The data, when processed, may cause the processor to run a calibration test on one or more instruments of the assembly and, based the one or more instruments failing the calibration test, calibrate the one or more instruments or lock the apheresis system for non-use. The apheresis system may include a pump configured to generate a calibration pressure at a test port and a pressure sensor configured to sense a pressure at the test port. The calibration test may include comparing the calibration pressure at the test port to the sensed pressure by the pressure sensor at the test port.

A fluid collection loop includes a flexible tube having a first end and a second end, a connector, and a fluid component collection bladder. The connector is configured to couple the first end of the flexible loop and the fluid component collection bladder. The fluid component collection bladder includes a first chamber defined between a top end and a flow chamber separator, and a second chamber defined between a bottom end and the flow chamber separator. The flow chamber separator extends from a first end of the fluid component collection bladder towards a second end of the fluid component collection bladder and a gap exists between the fluid component collection bladder and the second end of the fluid component collection bladder.

A method includes detecting a beginning of a donation process; in response to detecting the beginning of the donation process, providing an output; determining an amount of time remaining for the donation process; in response to detecting the amount of time remaining for the donation process, updating the output; detecting a loss in pressure; in response to detecting the loss in pressure, updating the output; detecting an ending of the donation process; and in response to detecting the ending of the donation process, updating the output. The donation process may include a plasma donation using an apheresis machine. The detecting the beginning of the donation process may include detecting a flow of fluid. The output may include one or more of a light and a sound. The output may be provided on a side of an apheresis machine.

An apheresis system at least partially defines a chamber and includes centrifuge that is movable between lock and unlock states. The centrifuge includes a base, cover, lock assembly, and latch assembly. The cover engages the base and defines slots. The lock assembly is coupled to the base and rotates between latched and unlatched states. The lock assembly includes tabs and a protrusion. The tabs are in the slots of the cover. The protrusion at least partially defines a receptacle. The latch assembly is coupled to the base and includes a lever and engagement component attached thereto. In the latched state, the protrusion engages the engagement component to reduce or prevent rotation of the lock assembly. In the unlatched state, the lock assembly can rotate. In the lock state, the tabs are at least partially within the slots. In the unlock state, the cover is movable with respect to the base.

This invention is directed to system and methods for the oxygenation of the blood of a patient, comprising an extracorporeal blood circulation path adapted to be coupled to the patient's vascular system, and comprising apparatus for oxygenating blood flowing therein and withdrawing CO2 therefrom, wherein the flow rate of blood flowing in said extracorporeal blood circulation path does not exceed ⅖ of the patient's blood flow. The extracorporeal blood circulation path preferably comprise a cartridge including an oxygenator and at least one cannula.

The present disclosure relates to a disposable, which includes a fluid line and a connector having a connector lumen, for fluidically connecting the fluid line to a first lumen of a first fluid guide of a port, which further includes a second lumen. It further relates to a system with a disposable according to the present disclosure and with a port for establishing a fluid communication between at least one fluid line of a medical treatment apparatus, which fluid line is assigned to an interior of the medical treatment apparatus, and a connector of a fluid line of a disposable, which fluid line is assigned to an exterior of the medical treatment apparatus.

This invention is directed to system and methods for the oxygenation of the blood of a patient, comprising an extracorporeal blood circulation path adapted to be coupled to the patient's vascular system, and comprising apparatus for oxygenating blood flowing therein and withdrawing CO2 therefrom, wherein the flow rate of blood flowing in said extracorporeal blood circulation path does not exceed ⅖ of the patient's blood flow. The extracorporeal blood circulation path preferably comprise a cartridge including an oxygenator and at least one cannula.

Dialysis systems comprising actuators that cooperate to perform dialysis functions and sensors that cooperate to monitor dialysis functions are disclosed. According to one aspect, such a hemodialysis system comprises a user interface model layer, a therapy layer, below the user interface model layer, and a machine layer below the therapy layer. The user interface model layer is configured to manage the state of a graphical user interface and receive inputs from a graphical user interface. The therapy layer is configured to run state machines that generate therapy commands based at least in part on the inputs from the graphical user interface. The machine layer is configured to provide commands for the actuators based on the therapy commands.

A system for heating/cooling a target unit. The system including a heater/cooler unit and a heat transfer fluid module. The heater/cooler unit including a heater/cooler that includes a heater/cooler element and a heater/cooler pump, and a heat exchanger that includes a heat exchange element. Where, the heater/cooler pump pumps a first fluid through the heater/cooler element and the heat exchange element and back to the heater/cooler pump. The heat transfer fluid module including a fluid reservoir with a second fluid that is pumped to and through the heat exchanger to transfer heating/cooling between the first fluid and the second fluid and pumped to and through the target unit to transfer heating/cooling between the second fluid and the target unit.

This disclosure relates to a method for determining a fluid balance between a first volume flow in a first section of a fluid circuit and a second volume flow of a second section of the fluid circuit. The method may also include adjusting, assuming or detecting a first temperature in the first section of the fluid circuit and a second temperature in the second section of the fluid circuit, or detecting a temperature difference between the first and the second sections. The method may also include detecting a second volume flow in a second section of the fluid circuit and forming a balance from at least the first volume flow and a corrected value of the second volume flow. The corrected value is determined from the detected second volume flow and the second temperature and/or the temperature difference.