A method of implanting a cardiac device featuring the insertion of an inner seal member through an opening in a pericardium about a living human heart. The inner seal member has a first sealing lip disposed inside the pericardium and surrounding an aperture through the inner seal member. An outer seal member is aligned with the inner seal member. The outer seal member has a second sealing lip disposed outside the pericardium, surrounding an aperture through the outer seal member. The inner seal member is secured to the outer seal member. The firsts sealing lip is engaged against an inner surface of the pericardium. The second sealing lip is engaged against an outer surface of the pericardium. A cardiac device is inserted into the pericardium through the apertures of the inner and outer seal members.

Devices and methods for providing localized pressure to a region of a patient's heart to improve heart functioning, including: (a) a jacket made of a flexible biocompatible material, the jacket having an open top end that is received around the heart and a bottom portion that is received around the apex of the heart; and (b) at least one inflatable bladder disposed on an interior surface of the jacket, the inflatable bladder having an inelastic outer surface positioned adjacent to the jacket and an elastic inner surface such that inflation of the bladder causes the bladder to deform substantially inwardly to exert localized pressure against a region of the heart.

Methods and devices for implanting a ventricular assist device employ a coupler that engages an aperture formed in a heart wall and provides a conduit by which blood is pumped from the ventricle via the ventricular assist device. A method includes penetrating a distal end of a delivery device through a wall of a heart into a ventricle of the heart to form an aperture having a diameter in the wall. A coupler is deployed from the delivery device so that the coupler engages the aperture, expands the diameter of the aperture, and forms a conduit for a flow of blood from the ventricle. The delivery device is removed from the ventricle by retracting the delivery device through the conduit. The ventricular assist device is coupled to the coupler to receive the flow of blood from the ventricle and pump the flow of blood to assist circulation in the patient.

Systems and methods for de-airing a cardiac chamber during cardiac surgery are provided. A catheter-based inflatable device is inserted adjacent a target area of the heart, and the frequency of inflation and deflation of the inflatable device is controlled via a remote controller to change the shape of the cardiac chamber to dislodge air bubbles from their deposition site in the cardiac chamber.

Devices, systems, and methods for treating a heart of a patient may make use of structures which limit a size of a chamber of the heart, such as by deploying one or more tensile member to bring a wall of the heart and a septum of the heart into contact. A plurality of tension members may help exclude scar tissue and provide a more effective remaining ventricle chamber. The implant may be deployed during beating of the heart, often in a minimally invasive or less-invasive manner. Trauma to the tissues of the heart may be inhibited by selectively approximating tissues while a pressure within the heart is temporarily reduced. Three-dimensional implant locating devices and systems facilitate beneficial heart chamber volumetric shape remodeling.

The present invention includes a device and method for a self-expanding framework device adapted to facilitate the deployment of an extra-cardiac device. The device includes a deployment tube and a self-expanding wire framework having a structure that results in the self-expanding wire framework circumferential flaring motion and bending outwardly to advance around the heart.

Disclosed here are devices and methods for treating functional tricuspid valve regurgitation and related conditions. Disclosed devices are adapted for applying force to an area of a patient's heart along or near the atrioventricular groove, and can include a tensioning element configured to be delivered by a flexible member guided through a catheter and positioned generally along or near the atrioventricular groove, and a compression member positionable along the tensioning element and over a desired segment of the atrioventricular groove to develop force to be applied to an adjacent area of the heart by selective tensioning of the tensioning element.

Delivery systems and methods of delivering devices or implants are disclosed. The devices or implants can be configured as valve repair devices or treatment devices have gripping members that are openable and closable to attach the device to leaflets of a native heart valve. The delivery systems are configured to position the device or implant and open and close the gripping members of the device or implant.

Devices, systems, and methods for treating a heart of a patient may make use of structures which limit a size of a chamber of the heart, such as by deploying one or more tensile member to bring a wall of the heart and a septum of the heart into contact. A plurality of tension members may help exclude scar tissue and provide a more effective remaining ventricle chamber. The implant may be deployed during beating of the heart, often in a minimally invasive or less-invasive manner. Trauma to the tissues of the heart may be inhibited by selectively approximating tissues while a pressure within the heart is temporarily reduced. Three-dimensional implant locating devices and systems facilitate beneficial heart chamber volumetric shape remodeling.

A method and kit for placing an implant in a patient. The method includes placing an implant consisting of at least one from the group consisting of an electronic device and an electromechanical device into a tissue cavity of the patient and evacuating fluid from the cavity and urging tissue surrounding the cavity to abut the implant.