A system for treating heart disease, such as pulmonary hypertension or right heart failure, including an implantable component and external components for monitoring the implantable component is provided. The implantable component may include a compliant member, e.g., balloon, coupled to a reservoir via a conduit. Preferably, the compliant member is adapted to be implanted in a pulmonary artery and the reservoir is adapted to be implanted subcutaneously. The external components may include a clinical controller component, monitoring software configured to run a clinician's computer, a patient monitoring device, and a mobile application configured to run on a patient's mobile device.

Catheters for percutaneous applications are disclosed. The catheter according to example embodiments may comprise a substantially straight section, an anchoring section positioned proximal to the substantially straight section. The anchoring section can have a curvature for providing longitudinal traction with a tissue to anchor the catheter to the tissue and a pathway extending through the catheter for transporting fluids. The pathway may comprise a first section and a second section in fluid communication with each other, where the first section extends through the length of the straight section, and the second section extends through the anchoring section and has a curvature which mimics the curvature of the anchoring section.

Catheters for percutaneous applications are disclosed. The catheter according to example embodiments may comprise a substantially straight section, an anchoring section positioned proximal to the substantially straight section. The anchoring section can have a curvature for providing longitudinal traction with a tissue to anchor the catheter to the tissue and a pathway extending through the catheter for transporting fluids. The pathway may comprise a first section and a second section in fluid communication with each other, where the first section extends through the length of the straight section, and the second section extends through the anchoring section and has a curvature which mimics the curvature of the anchoring section.

A user-controllable urinary catheter prosthesis (20) is provided for minimally-invasive insertion into a subject. The prosthesis (20) includes a proximal intra-urethral assembly (22), configured to be inserted entirely within a urethra (102) via a meatus (104). A user-activatable hydraulic activator (50) is disposed along a flexible intra-urethral catheter (30, 430), which is shaped so as to define a urinary outlet (40, 440) at a proximal end (41, 441) thereof. A distal bladder assembly (32, 132, 232, 332) is configured to be disposed in a bladder of the subject, and includes a bladder anchor (48). A hydraulic valve (60, 160, 260, 360) is configured to assume an open state, in which urine flow is allowed between the distal bladder assembly (32, 132, 232, 332) and the urinary outlet (40, 440); and a closed resting state, in which urine is entirely blocked from entering the distal bladder assembly (32, 132, 232, 332) and exiting the urinary outlet (40, 440). Application of pressure to the hydraulic activator (50) transitions the hydraulic valve (60, 160, 260, 360) from the closed resting state to the open state. Other embodiments are also described.

A user-controllable urinary catheter prosthesis (20) is provided for minimally-invasive insertion into a subject. The prosthesis (20) includes a proximal intra-urethral assembly (22), configured to be inserted entirely within a urethra (102) via a meatus (104). A user-activatable hydraulic activator (50) is disposed along a flexible intra-urethral catheter (30, 430), which is shaped so as to define a urinary outlet (40, 440) at a proximal end (41, 441) thereof. A distal bladder assembly (32, 132, 232, 332) is configured to be disposed in a bladder of the subject, and includes a bladder anchor (48). A hydraulic valve (60, 160, 260, 360) is configured to assume an open state, in which urine flow is allowed between the distal bladder assembly (32, 132, 232, 332) and the urinary outlet (40, 440); and a closed resting state, in which urine is entirely blocked from entering the distal bladder assembly (32, 132, 232, 332) and exiting the urinary outlet (40, 440). Application of pressure to the hydraulic activator (50) transitions the hydraulic valve (60, 160, 260, 360) from the closed resting state to the open state. Other embodiments are also described.

A method for accessing a mitral valve that includes forming an incision and inserting a first catheter comprising a lumen. The first catheter is adapted to be directed towards a left atrium and the first catheter has a working length of approximately 15 cm to approximately 52 cm. The method further includes utilizing a trocar in the first catheter to penetrate a pericardium and utilizing the trocar to penetrate the left atrium. The method further includes accessing the mitral valve from an antegrade direction.

A method for accessing a mitral valve that includes forming an incision and inserting a first catheter comprising a lumen. The first catheter is adapted to be directed towards a left atrium and the first catheter has a working length of approximately 15 cm to approximately 52 cm. The method further includes utilizing a trocar in the first catheter to penetrate a pericardium and utilizing the trocar to penetrate the left atrium. The method further includes accessing the mitral valve from an antegrade direction.

An expandable inter-vivos tube that allows for the use in medical procedures while limiting known complications arising from conventional inter-vivos tubes is presented, wherein the expandable inter-vivos tube comprises a slit formed longitudinally within a tube and a plurality of nipples extending from an outer surface of the tube that are insertable within a corresponding one of a plurality of slides within an outer slidable element that is slidable within the slit. A position of the nipples within the slots causes a distance between the edges of the to increase; thus, increasing a circumference of the inter-vivos tube as the outer element is slide from a proximal end of the tube element to a distal end of the tube.

An expandable inter-vivos tube that allows for the use in medical procedures while limiting known complications arising from conventional inter-vivos tubes is presented, wherein the expandable inter-vivos tube comprises a slit formed longitudinally within a tube and a plurality of nipples extending from an outer surface of the tube that are insertable within a corresponding one of a plurality of slides within an outer slidable element that is slidable within the slit. A position of the nipples within the slots causes a distance between the edges of the to increase; thus, increasing a circumference of the inter-vivos tube as the outer element is slide from a proximal end of the tube element to a distal end of the tube.

A sheath is transluminally introduced a sheath into an atrium of a heart of a subject. A guide member is advanced out of the sheath and to a chorda tendinea of the heart, the guide member having a proximal portion that includes a longitudinal element, and a distal portion that includes a helical chord-engaging element. The chord-engaging element is wrapped around the chorda tendinea. While the chord-engaging element remains wrapped around the chorda tendinea, (i) the chord-engaging element is slid over the chorda tendinea toward a papillary muscle that is coupled to the chorda tendinea; and (ii) subsequently, a tool is moved out of the sheath and toward the papillary muscle by sliding the tool along the longitudinal element. Other embodiments are also described.