Cardiac chamber prosthesis configured to be implanted in a cardiac chamber (10; 20; 30; 40) comprising a native outlet valve (50; 60; 70; 80) and at least one inlet aperture (50; 70) selected from the group comprising a native inlet valve (50; 70) and one or more outlet mouths of venae cavae or pulmonary veins (120; 125; 130), wherein the cardiac chamber prosthesis comprises: an inner elastic membrane (250; 255; 260; 650; 750; 850), a reference support elastic membrane structure (200; 205, 225, 290A; 600; 700; 800) comprising or consisting of an outer elastic membrane (200; 205; 600; 700; 800) provided with a plurality of clips (210) configured to grip an inner wall (45) of the cardiac chamber (10; 20; 30; 40), wherein the elastic inner and outer membranes (250, 200; 255, 205; 260, 200; 650, 600; 750, 700; 850, 800) form an outlet border (285; 675; 785; 885) configured to surround and be sutured on the native outlet valve (50; 60; 70; 80) and at least one inlet border (275; 685; 775; 875A, 875B) configured to surround and be sutured on said at least one inlet aperture (50; 70), wherein the inner elastic membrane (250; 255; 260; 650; 750; 850) and the reference support elastic membrane structure (200; 205, 225, 290A; 600; 700; 800) are connected to each other by means of a plurality of primary variable connection elements (290; 290B), whereby the inner elastic membrane (250; 255; 260; 650; 750; 850) and the reference support elastic membrane structure (200; 205, 225, 290A; 600; 700; 800) delimit a primary interspace (230; 230B; 630; 730; 830) between them that is configured to receive a fluid with varying amount and/or pressure so as to dynamically modify a volume of the primary interspace (230; 2303; 630; 730; 830) and said elastically variable volume delimited by the inner surface (254; 654; 754; 854) of the inner elastic membrane (250; 255; 260; 650; 750; 850).

The invention provides an introducer assembly for delivering a blood pump into vasculature of a subject, as well as a method for utilizing the assembly.

The disclosure relates to a method and system for processing a heart sensor output, wherein a blood flow and a simulated aortic blood pressure are derived from a sensed blood pressure using an arterial flow model and values for arterial flow parameters. The simulated aortic blood pressure is matched to a part of the sensed blood pressure in the cardiac cycle by manipulating at least one of the values for the arterial flow parameters of the arterial flow model.

A method for repairing a heart includes identifying a heart of a patient as having a reduced ejection fraction. In response to the identifying, wall stress of a ventricle of the heart is reduced by implanting apparatus that facilitates cyclical moving of fluid that is not blood of the patient into and out of the ventricle of the heart. During ventricular diastole, a volume of the fluid is moved into the ventricle in a manner that produces a corresponding decrease in a total volume of blood that fills the ventricle during diastole. During ventricular systole, the volume of the fluid is moved out of the ventricle in a manner that produces a corresponding decrease in a total volume of the ventricle during isovolumetric contraction of the ventricle. Other embodiments are also described.

A method for repairing a heart includes identifying a heart of a patient as having a reduced ejection fraction. In response to the identifying, wall stress of a ventricle of the heart is reduced by implanting apparatus that facilitates cyclical moving of fluid that is not blood of the patient into and out of the ventricle of the heart. During ventricular diastole, a volume of the fluid is moved into the ventricle in a manner that produces a corresponding decrease in a total volume of blood that fills the ventricle during diastole. During ventricular systole, the volume of the fluid is moved out of the ventricle in a manner that produces a corresponding decrease in a total volume of the ventricle during isovolumetric contraction of the ventricle. Other embodiments are also described.

An integrated sheath assembly for inserting a medical device such as a percutaneous pump into a vessel can include a first sheath having a first lumen defining a first opening between proximal and distal ends of the first sheath for passage of a portion of the pump and a second sheath having a second lumen defining a second opening between proximal and distal ends of the second sheath. The second lumen is expandable to allow passage of the first sheath containing the portion of the pump. The first sheath fills a space between the second sheath and the portion of the percutaneous pump when the first sheath containing the percutaneous pump is inserted into the second lumen. The first sheath has a first hub, and the second sheath has a second hub. In some embodiments, a single sheath and a movable connector can be integrated on the medical device.

A system for providing ventricular assistance to a heart of a subject, the system including a balloon configured to be inserted into a ventricle of the heart, wherein the balloon is configured to differentially inflate to thereby urge blood towards a semilunar valve of the ventricle; a fluid conduit in fluid communication with the balloon; a pumping mechanism attached to the fluid conduit; and, a controller configured to control the pumping mechanism to thereby selectively supply fluid into the balloon so as to inflate the balloon at least partially in accordance with the cardiac cycle.

A system for providing ventricular assistance to a heart of a subject, the system including a balloon configured to be inserted into a ventricle of the heart, wherein the balloon is configured to differentially inflate to thereby urge blood towards a semilunar valve of the ventricle; a fluid conduit in fluid communication with the balloon; a pumping mechanism attached to the fluid conduit; and, a controller configured to control the pumping mechanism to thereby selectively supply fluid into the balloon so as to inflate the balloon at least partially in accordance with the cardiac cycle.

A cardiac assist system includes a pneumatic effector which is implanted beneath a pericardial sac and over a myocardial surface overlying the patient's left ventricle. A port is implanted and receives a percutaneously introduced cannula. The port is connected to supply a driving gas received from the cannula to the pneumatic effector. An external drive unit includes a pump assembly and control circuitry which operate the pump to actuate the pneumatic effector in response to the patient's sensed heart rhythm. A connecting tube has a pump end connected to the pump and a percutaneous port-connecting end attached to the implantable port.

A cardiac assist system includes a pneumatic effector which is implanted beneath a pericardial sac and over a myocardial surface overlying the patient's left ventricle. A port is implanted and receives a percutaneously introduced cannula. The port is connected to supply a driving gas received from the cannula to the pneumatic effector. An external drive unit includes a pump assembly and control circuitry which operate the pump to actuate the pneumatic effector in response to the patient's sensed heart rhythm. A connecting tube has a pump end connected to the pump and a percutaneous port-connecting end attached to the implantable port.