Percutaneous connector and associated methods of use

The invention claimed is: 1. A percutaneous connector comprising: a base having a base surface, at least a portion of the base having a textured surface to promote tissue ingrowth; a skirt extending from the base, the skirt including at least one from the group consisting of silicon and Polytetrafluoroethylene ring extending around its perimeter; one or more base magnets within the base defining a plurality of magnetic poles adjacent the base surface; a cap having a cap surface; one or more cap magnets within the cap defining a plurality of magnetic poles adjacent the cap surface, the base magnets and cap magnets attract the cap to the base and align the cap and base with the cap surface and base surface confronting one another; and a release mechanism adapted to at least partially separate the cap from the base when the cap is rotated relative to the base about an axis normal to the cap surface and base surface. 2. The percutaneous connector of claim 1 , wherein the base magnets and the cap magnets each have their respective magnetic polar axes extending perpendicularly to the base surface and cap surface. 3. The percutaneous connector of claim 2 , wherein at least one of the one or more base magnets define at least one north pole and at least one south pole adjacent to the base surface, and; wherein the one or more cap magnets define at least one north pole adjacent to the cap surface and at least one south pole adjacent to the cap surface. 4. The percutaneous connector of claim 3 , wherein the base and cap have an unequal number of magnets to allow different orientations of the cap with respect to the base. 5. The percutaneous connector of claim 3 , wherein the plurality of poles defined by the base magnets and the plurality of poles defined by the cap magnets are equally spaced such that each base magnet pole aligns with a cap magnet pole. 6. The percutaneous connector of claim 5 , wherein rotation of the cap misaligns the base magnets and cap magnets to reduce the magnetic attraction between the cap and base. 7. The percutaneous connector of claim 6 , wherein further rotation of the cap causes magnetic repulsion between the base magnets and the cap magnets. 8. The percutaneous connector of claim 1 , wherein the release mechanism comprises at least one cam formed at an oblique angle to the surface of one of the cap and base and at least one mating structure adapted to engage the at least one cam formed on the other of the cap and base. 9. The percutaneous connector of claim 1 , wherein the skirt comprises a flexible material. 10. The percutaneous connector of claim 9 , wherein the textured surface includes the same material as that used for the skirt. 11. The percutaneous connector of claim 1 , further comprising a plurality of anchors associated with the skirt. 12. The percutaneous connector of claim 1 , wherein the base is adapted to be implanted at least partially in a patient's skin. 13. The percutaneous connector of claim 1 , further comprising a base contact configured to be coupled to a cap contact. 14. The percutaneous connector of claim 1 , wherein the base magnets and cap magnets are exposed at the base surface and cap surface. 15. The percutaneous connector of claim 1 , further comprising a channel extending through the base, wherein the base magnets are positioned around the channel; and a bore extending through the cap, wherein the cap magnets are positioned around the bore. 16. The percutaneous connector of claim 1 wherein the base contact and cap contact are configured to form an electrical connection providing two-way communication between an internal device and external controller. 17. The percutaneous connector of claim 16 , wherein the base contact and cap contact each comprise at least one of a pin and socket. 18. The percutaneous connector of claim 16 , wherein the internal device comprises at least one of a ventricular assist device, insulin pump, pacemaker, automatic implantable cardioverter defibrillator, and dialysis device. 19. The percutaneous connector of claim 16 , wherein the magnetic poles of the base magnets and cap magnets extend perpendicularly to the base surface and cap surface, at least one of the base magnets has a polarity adjacent the base surface opposite to the polarity of the other base magnets, and at least one of the cap magnets has a polarity adjacent the cap surface opposite to the polarity of the other cap magnets. 20. The percutaneous connector of claim 19 , wherein the base and cap self-assemble when placed in close proximity to each other. 21. The percutaneous connector of claim 1 , further comprising an inert cap adapted to be coupled to the base. 22. The percutaneous connector of claim 21 , wherein the inert cap has one or more inert cap magnets within the inert cap defining a plurality of magnetic poles adjacent the inert cap surface. 23. The percutaneous connector of claim 22 , wherein the inert cap has a sealing member creating a waterproof seal between the inert cap and the base. 24. A method of disconnecting a percutaneous connector establishing an electrical connection between an internal device and an external controller, the percutaneous connector including a cap, a base, and a skirt extending from the base, the skirt including at least one from the group consisting of silicon and Polytetrafluoroethylene ring extending around its perimeter, the cap and base each having a plurality of magnets to attract the cap to the base and orient the cap on the base to establish the electrical connection, the base having a base surface, at least a portion of the base having a textured surface to promote tissue ingrowth, the method comprising the steps of: rotating the cap relative to the base such that a cam positioned on one of the cap or base engages an element positioned on the other of the cap or base, wherein the engaged cam and element cause relative separation between the cap and base; and pulling the cap away from the base. 25. A percutaneous connector comprising: a base having a base surface, at least a portion of the base having a textured surface to promote tissue ingrowth; a skirt extending from the base, the skirt including at least one from the group consisting of silicon and Polytetrafluoroethylene ring extending around its perimeter; one or more base magnets within the base defining a plurality of magnetic poles adjacent the base surface; a cap having a cap surface; and one or more cap magnets within the cap defining a plurality of magnetic poles adjacent the cap surface, the base magnets and cap magnets attract the cap to the base and align the cap and base with the cap surface and base surface confronting one another.