A fluid control device includes a tube insertion portion formed in a casing, a fixing member that fixedly holds, in the tube insertion portion, a tube inserted into the tube insertion portion, a pressing member driven by an actuator to press the tube within the tube insertion portion, and a controller that controls the actuator for the pressing member, wherein the controller controls the pressing member to start pressing on the tube after the fixing member has fixedly hold the tube in the tube insertion portion.

A blood component collection system (10) includes a first internal pressure calculation unit (110) adapted to calculate a first internal pressure of a first pressed portion (60) using first calibration curve data (118), a second internal pressure calculation unit (112) adapted to calculate a second internal pressure of a second pressed portion (62) using second calibration curve data (120), and a correction unit (114) adapted to correct the first calibration curve data (118) in a manner so that, during a blood returning operation, the first internal pressure calculated by the first internal pressure calculation unit (110) becomes equal to the second internal pressure calculated by the second internal pressure calculation unit (112).

A breaker device (1) for acting onto a closure element (40) of a medical tubing (4) comprises a drive arrangement (2) having an electric drive device (20) and a drive element (23) driven by the drive device (20), and a breaker module (3) which is arrangeable on the drive arrangement (2). The breaker module (3) comprises a housing (30), a movable part (31) movably arranged on the housing (30) and a breaking element (315) for acting onto the closure element (40) of the tubing (4), wherein the breaker module (3) in an attached state is placed on the drive arrangement (2), the drive element (23) being in operative connection with the movable part (31) in the attached state such that a movement of the drive element (23) causes the movable part (31) to move for actuating the breaking element (315). A control device (5) serves for controlling the electric drive device (20) for driving the drive element (23). Herein, the control device (5) is constituted to control, during a detection routine, the electric drive device (20) to drive the drive element (23) in order to move the movable part (31), wherein the control device (5) is further constituted to analyse at least one feedback signal received during the detection routine for determining a type of the breaker module (3), the feedback signal being indicative of a movement of the movable part (31) during the detection routine.

A lever including a far end to engage an infusion tubing is provided. The lever includes a pivot end configured to fit into a shaft and to allow the lever to rotate about a shaft axis, the pivot end including a pocket to capture a spring having a leg protruding outside. The spring is configured to apply a bias from the lever against a door assembly. The lever includes a tab disposed on an outer side of the far end and configured to interface with the door assembly, and a pusher protruding into an inner side of the far end and configured to contact the infusion tubing when the far end engages the infusion tubing. The pusher applies a downward pressure to the infusion tubing when the door assembly is closed until the infusion tubing is properly aligned with an air-in-line sensor disposed on both sides of the tubing.

A fluid flow sensing and bubble detecting apparatus includes a housing comprising a channel configured to receive a tube through which fluid flows; a sensor apparatus disposed within the housing, which includes a first sensor operable to measure flow rate of fluid and to detect bubbles in flowing fluid; and a temperature sensor operable to detect temperature of the flowing fluid; and a processor connected to receive fluid flow rate data obtained by the first sensor, to receive bubble detection data obtained by the first sensor, and to receive fluid temperature data obtained by the temperature sensor, wherein when a tube through which fluid flows is disposed in the channel of the housing, the first sensor measures the flow rate of the flowing fluid and detects bubbles therein, and the temperature sensor measures the temperature of the flowing fluid, and the processor calculates in a short period of time a fluid flow rate corrected for temperature. All sensors are non-invasive and have no direct contact to the fluid in the tube, which might be blood. In accordance with additional embodiments, the fluid flow rate is additionally corrected for hemoglobin or hematocrit, and the effect of oxygen saturation on the hemoglobin or hematocrit data.

A device for opening and closing an infusion tube clamp includes a slide link which is axially arranged to be movable on a flap and includes at least one projecting locking element for closing an infusion tube clamp. An infusion tube clamp includes a first clamping leg and a second clamping leg pivotally connected to each other at one end, and a keeper plate which is arranged on the first clamping leg. At the locking element, the slide link includes a slide link ramp at which a switching cam of the keeper plate is adapted to slide into a stress-free final closing position.

The invention relates to a hose clamp for a blood treatment device, wherein the hose clamp has a housing (4) and an electromagnetically driven compression piece (1), with the electromagnetic drive of the compression piece (1) being configured such that the compression piece (1) is opened against a mechanical restoring force (A) in a state of the hose clamp with an applied current and is closed by the mechanical restoring force (A) in a currentless state of the hose clamp; wherein the hose clamp has, in addition to the electromechanical drive, a mechanical actuator (5) with which the compression piece (1) can be opened manually against the mechanical restoring force (A) in the currentless state of the hose clamp; and wherein the contact elements (6, 7) of the actuator (5) and of the compression piece (1) are configured such that they form a mechanical connection between the actuator (5) and the compression piece (1) after an opening of the compression piece (1) in the currentless state, said connection preventing another closing of the compression piece (1) in the currentless state of the hose clamp by the mechanical restoring force (A) and being released in the state of the hose clamp with an applied current.

A lever including a far end to engage an infusion tubing is provided. The lever includes a pivot end configured to fit into a shaft and to allow the lever to rotate about a shaft axis, the pivot end including a pocket to capture a spring having a leg protruding outside. The spring is configured to apply a bias from the lever against a door assembly. The lever includes a tab disposed on an outer side of the far end and configured to interface with the door assembly, and a pusher protruding into an inner side of the far end and configured to contact the infusion tubing when the far end engages the infusion tubing. The pusher applies a downward pressure to the infusion tubing when the door assembly is closed until the infusion tubing is properly aligned with an air-in-line sensor disposed on both sides of the tubing.

A fluid handling system for a surgical procedure includes a console and a tubing set. The console exhibits a peristaltic pump, a pinch valve, one above the other. Two recessed seats are located to the left and right sides of the pump and valve. The tubing set includes an irrigation tube and an aspiration tube each coupled to a pair of magnetic disks disposable in respective ones of the recessed seats. Upon such disposition, the irrigation tube is disposable in operative engagement with the peristaltic pump and the aspiration tube is insertable into a slot of the pinch valve.

Systems and methods are disclosed for controlling the flow of fluids in a fluid infusion system. The system may include first and second fluid containers, first and second tubes coupled to the first and second fluid containers, and an external valve coupled to the second tube and configured to be attached to the first tube. The valve may be configured to shape the first tube to form a valve region which is opened or closed by an actuating element in the valve that is driven by hydrostatic pressure from the second tube. A full second container may generate a pressure that is concentrated through a diaphragm onto a pin which presses on the shaped first tube region, closing it to allow only fluid from the second container to flow. When the fluid level in the second line falls reducing pressure, the pin's force reduces until the first tube is opened.