A medical implant system is described for inhibiting infection associated with a joint prosthesis implant. An inventive system includes an implant body made of a biocompatible material which has a metal component disposed on an external surface of the implant body. A current is allowed to flow to the metal component, stimulating release of metal ions toxic to microbes, such as bacteria, protozoa, fungi, and viruses. One detailed system is completely surgically implantable in the patient such that no part of the system is external to the patient while the system is in use. In addition, externally controlled devices are provided which allow for modulation of implanted components.

Medical device delivery assemblies are disclosed. The assembly may include a catheter-based delivery system. The assembly may include a pacing element to pace a patient's heart before, during, or after a procedure. The pacing element may be a detachable, implanting pacing element. The pacing element may be an implantable pacemaker and the implantable pacemaker may be disposed on a catheter-based delivery system. The assembly may include a prosthetic heart valve with one or more pacing elements on it. The pacing element may include a pacing strip or strips. These strips may be conductive or insulative. These strips may prevent, treat, or correct abnormal electrical communication in a heart.

An array of hollow nanotubes is configured and dimensioned to allow impurities to transport through the hollow nanotubes from a first space containing an impurity-laden fluid to a second space where the impurities may be collected for removal, allowing fluids, such as blood, to be purified.

A vascular graft includes deformable sleeves that include an electrical component. The electrical component can be variable-resistance or piezoelectric, in embodiments, such that deformation of the sleeves due to pressure changes create or modify an electrical signal. A transponder can then transmit information relating to the pressure inside and outside of the vascular graft.

A medical device configured to perform an endovascular therapy can include an elongate manipulation member and an intervention member. The elongate manipulation member can include a distal end portion. The intervention member can include a proximal end portion and a mesh. The proximal end portion can be coupled with the distal end portion of the elongate manipulation member. The mesh can have a plurality of cells in a tubular configuration and being compressible to a collapsed configuration for delivery to an endovascular treatment site through a catheter and being self-expandable from the collapsed configuration to an expanded configuration. The mesh can include an anodic metal and a cathodic metal. The anodic metal and the cathodic metal can each form a fraction of a total surface area of the mesh.

A method of making a valve structure includes a step of rotating a mandrel and an electrodeposition target attached to the mandrel about a rotational axis of the mandrel. The target includes an exterior surface having at least one conductive surface portion and at least one non-conductive surface portion. The method also includes a step of electrodepositing a polymer matrix of a biodegradable, biocompatible polymer composition onto the at least one conductive surface portion and the at least one non-conductive surface portion of the exterior surface of the rotating electrodeposition target to form the valve structure.

A medical device configured to perform an endovascular therapy can include an elongate manipulation member and an intervention member. The elongate manipulation member can include a distal end portion. The intervention member can include a proximal end portion and a mesh. The proximal end portion can be coupled with the distal end portion of the elongate manipulation member. The mesh can have a plurality of cells in a tubular configuration and being compressible to a collapsed configuration for delivery to an endovascular treatment site through a catheter and being self-expandable from the collapsed configuration to an expanded configuration. The mesh can include an anodic metal and a cathodic metal. The anodic metal and the cathodic metal can each form a fraction of a total surface area of the mesh.

Described is an intravascular device including a stent structure and at least one annular band. The stent structure may be sized for insertion into a blood vessel and configured to expand to contact the wall of a blood vessel after insertion therein. The annular band is configured to change in diameter in response to an applied electrical field. A method of maintaining and accelerating pulsatile blood flow includes positioning an annular band within a blood vessel, and causing the annular band to expand and contract in response to an electrical field.

A heart support net in one aspect of the present disclosure includes a reception part configured to receive a heart and to be attached to an outer side of a ventricle. The reception part includes: a first conductive part; a second conductive part; and a non-conductive part. The first conductive part and the second conductive part are each knitted into mesh with a conductive yarn. The non-conductive part is knitted into mesh with a non-conductive yarn.

Apparatus and methods are described, including a stent configured to be placed in a lumen. The stent includes a generally cylindrical stent body including a plurality of struts, at least one electrode post protruding from the stent body, and a plurality of antenna posts protruding longitudinally from an end of the stent body. The antenna posts are longitudinally separated from the electrode post. An antenna is disposed annularly on the antenna posts, such that the antenna posts separate the antenna from the end of the stent body, and at least one electrode is coupled to the stent by being placed on the electrode post. Additional embodiments are also described.