Abstract: A gastric band assembly has one or more bladders incorporated therein so that basal intra-band pressure in the band can be set higher than typical Green Zone basal intra-band pressures. The higher basal intra-band pressures equate to higher basal intra-luminal or contact pressures from 35 mmHg and above.

Abstract: A high fatigue life superelastic nickel-titanium (nitinol) wire, ribbon, sheet, tubing, or the like is disclosed. The nitinol has a 54.5 to 57.0 weight percent nickel with a balance of titanium composition and has less than 30 percent cold work as a final step after a full anneal and before shape setting heat treatment. Through a rotational beam fatigue test, fatigue life improvement of 37 percent has been observed.

Abstract: A cardiac harness for treating a patient's heart includes elastic rows connected by a connector assembly. The connector assembly can have a specific pattern, or can be formed of elongated elastic material connecting all of the apices of adjacent rows. The connectors maintain proper spacing between rows or rings on the harness and provide longitudinal stability.

Abstract: A self-anchoring cardiac harness is configured to fit at least a portion of a patient's heart and includes a tissue engaging element for frictionally engaging an outer surface of a heart. The engaging element produces sufficient friction relative to the outer surface of the heart, so that the harness does not migrate substantially relative to the heart. There is enough force created by the engaging element that there is no need to apply a suture to the heart in order to retain the cardiac harness. Further, the engaging element is adapted to engage the outer surface of the heart without substantially penetrating the outer surface.

Abstract: A self-anchoring cardiac harness is configured to fit at least a portion of a patient's heart and includes a tissue engaging element for frictionally engaging an outer surface of a heart. The engaging element produces sufficient friction relative to the outer surface of the heart, so that the harness does not migrate substantially relative to the heart. There is enough force created by the engaging element that there is no need to apply a suture to the heart in order to retain the cardiac harness. Further, the engaging element is adapted to engage the outer surface of the heart without substantially penetrating the outer surface.

Abstract: A cardiac harness for treating a patient's heart includes elastic rows connected by a connector assembly. The connector assembly can have a specific pattern, or can be formed of elongated elastic material connecting all of the apices of adjacent rows. The connectors maintain proper spacing between rows or rings on the harness and provide longitudinal stability.

Abstract: A cardiac harness adapted to fit generally around a least a portion of a heart includes at least one elastic spring member forming an annular portion that is elastically deformable and at least one sensor disposed on the annular portion for providing a sensor signal representative of cardiac function. The cardiac harness applies a compressive force on the heart during diastole and systole. The sensor is configured to take a measurement of impedance across the heart, impedance across a lung, evoked response of the heart, activation patterns of the heart, acceleration of a portion of the heart, position of a portion of the heart relative to an ultrasonic transmitter, pH on the heart's epicardial surface, blood oxygen saturation of a portion of the heart, or position of a portion of the heart relative to a magnetic field generating device. The cardiac harness and sensor are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A pace/sense electrode is associated with a cardiac harness for treating the heart. The pace/sense electrode is positioned on the epicardial surface of the heart, preferably under the cardiac harness, to provide pacing and sensing therapy to the heart. Compressive forces from the cardiac harness serve to hold the pace/sense electrode in place and to push the electrode into direct contact with the epicardial surface of the heart. Various means are provided for placing the pace/sense electrode under the cardiac harness in a minimally invasive procedure.

Abstract: A pace/sense electrode is associated with a cardiac harness for treating the heart. The pace/sense electrode is positioned on the epicardial surface of the heart, preferably under the cardiac harness, to provide pacing and sensing therapy to the heart. Compressive forces from the cardiac harness serve to hold the pace/sense electrode in place and to push the electrode into direct contact with the epicardial surface of the heart. Various means are provided for placing the pace/sense electrode under the cardiac harness in a minimally invasive procedure.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart including a cardiac harness configured to conform generally to at least a portion of a patient's heart. The system also includes an electrode associated with the cardiac harness and positioned on or proximate to the epicardial surface of the heart. In order to ensure that the electrode will operate with a pulse generator, the system has an impedance between approximately 10 ohms and approximately 120 ohms.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management device which does not have a lead system. Multiple pacing and sensing electrodes are attached to the cardiac harness but not to the cardiac rhythm management device. The cardiac harness applies a compressive force on the heart during diastole and systole, and the cardiac rhythm management device will deliver an electrical pulse to the pacing electrodes on the heart for pacing/sensing therapy. The cardiac harness and cardiac rhythm management device are both delivered and implanted by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management device which includes at least one set of electrodes and a power source. At least one electrode from the at least one set of electrodes is selected for sensing heart functions and providing pacing stimuli. The remaining electrodes not selected to provide pacing and sensing functions to the heart can be arranged together to deliver a defibrillating shock. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A cardiac harness for treating a patient's heart includes elastic rows connected by a connector assembly. The connector assembly can have a specific pattern, or can be formed of elongated elastic material connecting all of the apices of adjacent rows. The connectors maintain proper spacing between rows or rings on the harness and provide longitudinal stability.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management device which includes at least one electrode associated with the cardiac harness, epicardial leads attached directly to the heart, and a power source connected to the leads. The system may also include transvenous leads that are located within a chamber of the heart and attached to the power source. The cardiac harness applies a compressive force on the heart during diastole and systole, and the electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.

Abstract: A system for treating the heart includes a cardiac harness associated with a cardiac rhythm management devise which includes at least electrodes and a power source. The cardiac harness applies a compressive force on the heart during diastole and systole. The electrodes will deliver an electrical shock to the heart for defibrillation and/or can be used for pacing/sensing. The cardiac harness and electrodes are delivered and implanted on the heart by minimally invasive access.