The devices and method described herein allow for therapeutic damage to increase volume in these hyperdynamic hearts to allow improved physiology and ventricular filling and to reduce diastolic filling pressure by making the ventricle less stiff. For example, improving a diastolic heart function in a heart by creating at least one incision in cardiac muscle forming an interior heart wall of the interior chamber where the at least one incision extends into one or more layers of the interior heart wall without puncturing through the interior heart wall and the incision is sufficient to reduce a stiffness of the interior chamber to increase volume of the chamber and reduce diastolic filing pressure.

In a method, system and device a member is provided around an aneurysm enabling treatment and monitoring of the aneurysm. In accordance with one embodiment the device is adapted to be adjusted postoperatively. Hereby the treatment can be efficiently carried out without having to perform surgery when adjusting the member.

An implantable ventricular assist device comprises an intraventricular stent used for the creation of an artificial chamber inside the ventricle, a balloon-like structure used to drive the change of the artificial chamber between a contractile configuration and a diastolic configuration, a power system used for driving the change of the balloon-like structure between the contractile configuration and the diastolic configuration. There is also a power system and a mechanical design to operate the system working, wherein in the contractile configuration, the balloon-like structure expands and occupies the space of the artificial chamber and drives the blood inside the artificial chamber flow outside the artificial chamber, wherein in the diastolic configuration, the balloon-like structure shrinks and releases the space inside the artificial chamber, and the blood outside the artificial chamber flows back into the artificial chamber. It is easy to reach the goal of cardiac function.

An implantable ventricular assist device comprises an intraventricular stent used for the creation of an artificial chamber inside the ventricle, a balloon-like structure used to drive the change of the artificial chamber between a contractile configuration and a diastolic configuration, a power system used for driving the change of the balloon-like structure between the contractile configuration and the diastolic configuration. There is also a power system and a mechanical design to operate the system working, wherein in the contractile configuration, the balloon-like structure expands and occupies the space of the artificial chamber and drives the blood inside the artificial chamber flow outside the artificial chamber, wherein in the diastolic configuration, the balloon-like structure shrinks and releases the space inside the artificial chamber, and the blood outside the artificial chamber flows back into the artificial chamber. It is easy to reach the goal of cardiac function.

Devices and methods for blood flow enhancement and hemodynamic power monitoring are provided. A blood flow enhancement device includes a pump system configured to be coupled to a central vasculature of a subject during cardiopulmonary resuscitation (CPR). The pump system includes a pumping mechanism configured to increase forward blood flow generated during the CPR while substantially limiting backward blood flow generated during the CPR. The pumping mechanism being operated concurrently with the CPR. The hemodynamic power monitor is configured to control a chest compression device and an active valve.

Devices and methods for blood flow enhancement and hemodynamic power monitoring are provided. A blood flow enhancement device includes a pump system configured to be coupled to a central vasculature of a subject during cardiopulmonary resuscitation (CPR). The pump system includes a pumping mechanism configured to increase forward blood flow generated during the CPR while substantially limiting backward blood flow generated during the CPR. The pumping mechanism being operated concurrently with the CPR. The hemodynamic power monitor is configured to control a chest compression device and an active valve.

Disclosed is a distributed transformer or extension cord component for a transcutaneous energy transfer system used to transfer electric power to an implanted medical device. The extension cord component may enable power transfer to occur at various points on or near the body of the subject within whom the medical device is implanted. In this way, the subject may gain greater flexibility and high levels of convenience in connection with use of the transcutaneous energy transfer system.

Ventricular assist devices configured to be placed in a ventricle of a heart are described. In one embodiment, a ventricular assist device may include a pumping pouch. The pumping pouch may have an opening. The pumping pouch may be flexible, and may define an internal volume configured to fill with blood in through the opening. The ventricular assist device may also include a contraction element coupled to the contraction pouch. The contraction element may be capable of squeezing at least a portion of the pumping pouch to force at least a portion of the blood out through the opening. The ventricular assist device may also include a frame coupled to the pumping pouch. The frame may be configured to be coupled to a wall of the heart.

A medical device, such as an intra-aortic balloon pump or carrier with an extendable wheel track and handle configured to be removably carried and integrated with a cart. The wheel track is configured to extend upon extension of the handle and to return to its original position upon retraction of the handle.

The present disclosure provides medical devices, systems and methods and in particular to devices and methods useful for anchoring graft materials to bodily structures.