A conveying device for conveying a medical fluid that is guided into a hose includes a rotor and a stator. The stator includes a stator base, an area for receiving the hose in the conveying device, and a hose bed providing a counter bearing for occlusion devices. The rotor includes a rotor axis and at least two occlusion devices that are attached radially to the rotor axis and that compress the hose intermittently against the hose bed during use of the conveying device. The rotor encompasses an axial guiding element that is arranged to rotate about its own longitudinal axis for aligning the hose in the stator. The longitudinal axis of the axial guiding element extends parallel to the longitudinal axis of the rotor axis. The axial guiding element includes a middle section and a first lateral section protruding radially over the middle section.

A conveying device for conveying a medical fluid that is guided into a hose includes a rotor and a stator. The stator includes a stator base, an area for receiving the hose in the conveying device, and a hose bed providing a counter bearing for occlusion devices. The rotor includes a rotor axis and at least two occlusion devices that are attached radially to the rotor axis and that compress the hose intermittently against the hose bed during use of the conveying device. The rotor encompasses an axial guiding element that is arranged to rotate about its own longitudinal axis for aligning the hose in the stator. The longitudinal axis of the axial guiding element extends parallel to the longitudinal axis of the rotor axis. The axial guiding element includes a middle section and a first lateral section protruding radially over the middle section.

Microbubbles detached from a blood circuit and a blood purification unit are discharged with the use of a backflow generated at the instant that a roller of a blood pump releases a squeezable tube. In a normal rotation step, a region filled with a priming solution after a priming step is closed by a closing unit, and a rotor of a blood pump is rotated normally until a roller of the blood pump releases a squeezable tube to generate a backflow. After the backflow is generated at the release of the squeezable tube by the roller of the blood pump, bubbles are moved by reversely rotating the rotor while disabling the closing by the closing unit. Thus, the bubbles are discharged through a discharge unit.

Microbubbles detached from a blood circuit and a blood purification unit are discharged with the use of a backflow generated at the instant that a roller of a blood pump releases a squeezable tube. In a normal rotation step, a region filled with a priming solution after a priming step is closed by a closing unit, and a rotor of a blood pump is rotated normally until a roller of the blood pump releases a squeezable tube to generate a backflow. After the backflow is generated at the release of the squeezable tube by the roller of the blood pump, bubbles are moved by reversely rotating the rotor while disabling the closing by the closing unit. Thus, the bubbles are discharged through a discharge unit.

A peristaltic pump may include a rotor rotatably mounted on a base and an occlusion bed mounted on the base and moveable toward and away from the rotor. The peristaltic pump may also include a lid hingedly mounted to the base along a first hinge axis including a mounting bracket extending perpendicularly relative to the first hinge axis. A linkage assembly connecting the occlusion bed and the lid may include a pair of curved arms hingedly mounted to the mounting bracket along a second hinge axis parallel to the first hinge axis and a cam connecting the pair of curved arms and having a cam surface facing the mounting bracket, the cam being hingedly mounted to the occlusion bed at an end opposite the second hinge axis. The mounting bracket abuts the cam surface and form a cooperative connection between the lid and the occlusion bed via the linkage assembly.

A fluid diverting device for an apparatus for extracorporeal treatment of blood is configured to be placed in-line between a main portion (22) of the apparatus (1) and a vascular access of a patient (P) and comprises: a substantially H-shaped conduits assembly comprising a withdrawal conduit (23), a return conduit (24) and at least one bridging conduit (25, 125) connecting the withdrawal conduit (23) to the return conduit (24). The withdrawal conduit (23) is connectable upstream and downstream to a withdrawal line (6) of the apparatus (1), the return conduit (24) is connectable upstream and downstream to a return line (7) of the apparatus (1). A plurality of valves (26, 27, 28, 29, 30, 32) or distributors (201, 202) operate on the withdrawal conduit (23), on the return conduit (24) and on the at least one bridging conduit (25) and are configured to divert a flow of liquid and/or blood without disconnecting the patient (P).

A fluid diverting device for an apparatus for extracorporeal treatment of blood is configured to be placed in-line between a main portion (22) of the apparatus (1) and a vascular access of a patient (P) and comprises: a substantially H-shaped conduits assembly comprising a withdrawal conduit (23), a return conduit (24) and at least one bridging conduit (25, 125) connecting the withdrawal conduit (23) to the return conduit (24). The withdrawal conduit (23) is connectable upstream and downstream to a withdrawal line (6) of the apparatus (1), the return conduit (24) is connectable upstream and downstream to a return line (7) of the apparatus (1). A plurality of valves (26, 27, 28, 29, 30, 32) or distributors (201, 202) operate on the withdrawal conduit (23), on the return conduit (24) and on the at least one bridging conduit (25) and are configured to divert a flow of liquid and/or blood without disconnecting the patient (P).

A blood ultrafiltration system comprises a blood filter with first and second compartments separated by a semipermeable membrane. Blood input and blood output lines are connected in fluid communication with the first compartment. An effluent line is connected in fluid communication with the second compartment. A peristaltic pump is arranged for repeated engagement with first and second line segments. In a first arrangement, the first line segment is part of the blood input line or the blood output line and the second line segment is part of the effluent line. In a second arrangement, the first line segment is part of the blood input line and the second line segment is part of the blood output line. The system is operable, by the peristaltic pump, to pump blood through the blood filter and control the extraction of ultrafiltrate in the blood filter.

A blood ultrafiltration system comprises a blood filter with first and second compartments separated by a semipermeable membrane. Blood input and blood output lines are connected in fluid communication with the first compartment. An effluent line is connected in fluid communication with the second compartment. A peristaltic pump is arranged for repeated engagement with first and second line segments. In a first arrangement, the first line segment is part of the blood input line or the blood output line and the second line segment is part of the effluent line. In a second arrangement, the first line segment is part of the blood input line and the second line segment is part of the blood output line. The system is operable, by the peristaltic pump, to pump blood through the blood filter and control the extraction of ultrafiltrate in the blood filter.

The present invention relates to a method for disconnecting two fluid-conducting line sections of a medical device which are detachably interconnected, wherein a first line section of the two line sections has at least partially an elastic property. The method comprises the steps of enclosing a fluid volume in the two line sections, generating a reduced pressure in the two line sections, as a result of which elastic deformation from a starting position into a tensioned position takes place in and/or on the first line section, wherein a fluid volume contained in the first line section is lower in the tensioned position than a fluid volume contained in the starting position, and detaching the connection of the line sections, wherein the fluid volume contained in the first line section in the tensioned position increases. Furthermore, the invention relates to a medical device which is configured to carry out a method of this kind.