Described herein are devices and methods for pumping blood in a patient in need of circulatory assistance or a replacement heart. Instead of providing a temporary solution for these patients, the devices may be permanently implanted. The devices linearly reciprocate a shuttle within a housing to move blood into and out of the housing, and rotate the shuttle to selectively direct the movement of blood into and out of a plurality of ports in the housing.

A blood pumping device comprising at least a first pump and a second pump, and a first and second pump actuating means for inducing a blood flow in a body's circulatory system is disclosed. Each pump comprises one upper chamber having an inlet channel and one lower chamber having an outlet channel. The upper and lower chambers are separated by a movable valve plane provided with a valve. The pump actuating means are configured to apply a movement to said valve plane in an upward and downward direction between said upper and lower chambers in response to control signals from a control unit, such that when said valve plane moves in an upward direction the valve provided in the valve plane is in an open position allowing a flow of blood from the upper chamber to the lower chamber, and when the valve plane moves in a downward direction the valve is in the closed position and blood is ejected from the lower chamber through the outlet channel. The bottom part of the lower chamber is provided with a bag-like portion.

The present invention relates to an apparatus (500) for supporting the heart action, preferably by displacing the heart base (110) and/or the aortic root (201), comprising at least a first anchor (501) and a pulling device or guiding device (502, 503, 732, 732a, 732b) for moving the first anchor (501), wherein the first anchor (501) is provided and designed for implantation in or on the heart base (110), the heart skeleton (120), the aortic root (201) and/or a structure in local proximity to the aortic root (210), and/or comprising at least one lifting drive (502, 503). The present invention further relates to a control device (901), an insertion system, a kit and a method for supporting the heart action.

The present invention relates to an apparatus (500) for supporting the heart action, preferably by displacing the heart base (110) and/or the aortic root (201), comprising at least a first anchor (501) and a pulling device or guiding device (502, 503, 732, 732a, 732b) for moving the first anchor (501), wherein the first anchor (501) is provided and designed for implantation in or on the heart base (110), the heart skeleton (120), the aortic root (201) and/or a structure in local proximity to the aortic root (210), and/or comprising at least one lifting drive (502, 503). The present invention further relates to a control device (901), an insertion system, a kit and a method for supporting the heart action.

A blood pump housing device designed to enclose and protect a total artificial heart when implanted in a subject is disclosed. The blood pump housing device comprises a first and second artificial heart pump receiving part (3a, 3b) configured to receive and partly enclose a first and a second artificial heart pump (20a, 20b) of a total artificial heart (TAH); and a first and second pump actuation enclosing part (4a, 4b) configured to partly enclose a first and second pump actuation means (60a, 60b), said artificial heart pump receiving parts (3a, 3b) and pump actuation means enclosing parts (4a, 4b) are arranged to connect to each other in a leak-free manner.

A blood pump housing device designed to enclose and protect a total artificial heart when implanted in a subject is disclosed. The blood pump housing device comprises a first and second artificial heart pump receiving part (3a, 3b) configured to receive and partly enclose a first and a second artificial heart pump (20a, 20b) of a total artificial heart (TAH); and a first and second pump actuation enclosing part (4a, 4b) configured to partly enclose a first and second pump actuation means (60a, 60b), said artificial heart pump receiving parts (3a, 3b) and pump actuation means enclosing parts (4a, 4b) are arranged to connect to each other in a leak-free manner.

A dialysis machine (e.g., a peritoneal dialysis (PD) machine) can include a control unit configured to operate in a hybrid automated mode during a PD treatment. A processor in the control unit is configured to engage a pump during a fill phase of the PD cycle. The volume of fluid (e.g., dialysate) transferred to a patient line during the fill phase is monitored. After a dwell period, the pump is disengaged at the start of a drain phase of the PD cycle. Disengaging the pump can include: configuring valves of a disposable cassette to bypass the pump chambers of a disposable cassette; activating a bypass valve to shunt the patient line to a drain line; or moving a roller assembly of a peristaltic pump. The fluid transferred from the patient line to the drain line is monitored during the drain phase of the PD cycle.

The invention relates to a blade-type check valve for gaseous and liquid media, to be used in medical technologies as well as in waste water technology with at least three triangular blades, grouped in round configuration at the edges of a polygonal bore of a valve ring or housing, with the number of blades corresponding to the number of faces of the bore. At least at one of the three sides, the valve blades feature an integrated joint, which may also consist of fabric, whereas the two other sides of the valve blades form an articulated lock. The valve can be installed in any position and closes automatically, actuated by the backflow respectively return flow of the medium, without external energy.

Rotary lobe pump, comprising a pump housing (2, 9, 10) with a substantially cylindrical pump chamber (8) and a rotary lobe as rotor (1) with at least two blades (3) arranged opposite each other or evenly distributed in the circumferential direction and at least one sealing valve (4), characterized in that at least two sealing valves (4a, 4b) arranged opposite one another or uniformly distributed in the circumferential direction are provided, the at least two sealing valves (4a, 4b) being rotatable or pivotable, and an inlet duct (11) to at least two inlet openings (6) into the pump chamber (8) and an outlet duct (12) from at least two outlet openings (7) out of the pump chamber (8) being provided axially in a rotor axial tube (18), extending from the opposite axial ends and separated from one another.

A vascular coupling device (10), comprising a first and a second coupling element (21, 22) wherein each one of said first and second coupling elements (21, 22) has an external surface (23′, 23″) facing an external side, a coupling surface (25′, 25″) facing a coupling side, a central opening (27′, 27″), and a first and a second tubular connecting element (31, 32). Each one of said first and second tubular connecting elements (31, 32) is arranged in a corresponding central opening (27′, 27″) of the first and second coupling elements (21, 22) respectively, and with second open ends (37, 38) protruding through said central openings (27′, 27″) on said external side of each of said first and second coupling elements (21, 22). The first and second coupling elements (21, 22) being removably connected to each other into a locked configuration, or disconnected from each other into an unlocked configuration by means of a first and second locking structure (41, 42) being arranged on a centerline A and opposite to each other on an outer perimeter of said vascular coupling device (10). The vascular device further comprises a fail-safe arrangement comprising first and second cut-in portions (91, 92) arranged on said first coupling element (21) configured to receive first and second projecting elements (93, 94) arranged on said second coupling element (22), thereby preventing erroneous connection of said first and second coupling elements (21, 22) to each other.