Abstract: Fabricating an implantable stimulation lead by advancing work material to be wrapped with wire conductors, then, operating a plurality of payout carriers to let out the wire conductors, rotating the plurality of payout carriers to wrap the wire conductors about the work material, providing an amount of twist to each wire conductor as the wire conductors are let out, forming a lead body using the wrapped conductors, and fabricating a plurality terminals on the lead body, wherein the plurality of terminals are electrically connected to the conductive wires.

Abstract: A wire wrapping device that includes a turntable assembly that is made up of a turntable and a driver adapted to rotate the turntable. Also, a set of payout carriers are mounted on the turntable, each payout carrier adapted to let out wire to be wrapped. A driver is adapted to turn each payout carrier relative to the turn table, the driver being user adjustable to turn each payout carrier by a selectable amount, per each complete rotation of the turntable.

Abstract: A wire wrapping device that includes a turntable assembly that is made up of a turntable and a driver adapted to rotate the turntable. Also, a set of payout carriers are mounted on the turntable, each payout carrier adapted to let out wire to be wrapped. A driver is adapted to turn each payout carrier relative to the turn table, the driver being user adjustable to turn each payout carrier by a selectable amount, per each complete rotation of the turntable.

Abstract: A wire wrapping device that includes a turntable assembly that is made up of a turntable and a driver adapted to rotate the turntable. Also, a set of payout carriers are mounted on the turntable, each payout carrier adapted to let out wire to be wrapped. A driver is adapted to turn each payout carrier relative to the turn table, the driver being user adjustable to turn each payout carrier by a selectable amount, per each complete rotation of the turntable.

Abstract: In one embodiment, a method of manufacturing a biological electrical stimulus cable assembly, comprises: providing a cable portion including a plurality of first conductive wires; removing a first portion of the insulative material from a surface along the length of the insulative material at a first location to expose only one of the first conductive wires; electrically connecting a second conductive wire to the first exposed wire surface; wrapping the second conductive wire about the cable portion a plurality of times around the cable portion such that the second conductive wire forms a substantially continuous band; electrically connecting a second end of the second conductive wire to a conductive surface; and providing an electrode over the band formed by the second conductive wire, wherein the band formed by the second conductive wire extends along at least a majority of the length of the electrode.

Abstract: A wire wrapping device that includes a turntable assembly that is made up of a turntable and a driver adapted to rotate the turntable. Also, a set of payout carriers are mounted on the turntable, each payout carrier adapted to let out wire to be wrapped. A driver is adapted to turn each payout carrier relative to the turn table, the driver being user adjustable to turn each payout carrier by a selectable amount, per each complete rotation of the turntable.

Abstract: A wire wrapping device that includes a turntable assembly that is made up of a turntable and a driver adapted to rotate the turntable. Also, a set of payout carriers are mounted on the turntable, each payout carrier adapted to let out wire to be wrapped. A driver is adapted to turn each payout carrier relative to the turn table, the driver being user adjustable to turn each payout carrier by a selectable amount, per each complete rotation of the turntable.

Abstract: A method of manufacturing a biological electrical stimulus cable. The method begins with a cable portion having a plurality of first conductive wires set into a length of insulative material. A portion of the insulative material is removed from the surface creating an exposed first wire surface. Then, a second conductive wire is connected to the exposed first wire surface and a preformed conductive ring is threaded onto the cable portion and electrically connected to the second conductive wire.

Abstract: A bio-probe having a base and a tip, and comprising a longitudinal core of substantially rigid material. On the core, there is a first layer of dielectric material, supported by and substantially circumferentially surrounding the core. Also, a set of conductors, each conductor extending longitudinally along the first layer of dielectric material and a second layer of dielectric material, substantially covering each of the set of conductors. For each of the conductors, an aperture is defined through the second layer of dielectric material to the conductor, thereby defining an electrode. In one preferred embodiment of this aspect, the first layer of insulative material is in the form of a tube and wherein the core is removable from the tube.

Abstract: A method of addressing a condition of a living body comprising the steps of using an energy beam to form a set of pores in a work piece biocompatible membrane. The pores should have a mean area of less than 500 ?m through the biocompatible membrane, thereby producing a microporous membrane adapted to facilitate tissue in growth. This membrane is placed at least partially about an article that is adapted to be implanted in a living body, which is implanted into the living body, thereby addressing the condition.

Abstract: A method of producing a miniaturized set of inductive coils set mutually orthogonally inside a tube. In the method a positional template made of a sheet of substantially rigid material that defines a set of guide apertures, each of which is in the shape of one of the set of inductive coils. The guide apertures are disposed so that when an inductive coil is fitted into each one of the guide apertures the coils will be substantially orthogonal to one another.

Abstract: A method of producing a biocompatible microporous membrane comprising the steps of providing a biocompatible membrane and using an energy beam to form a set of pores having a minor axis of less than 15 ?m through the biocompatible membrane. One embodiment includes the steps of producing a first layer of material, defining a first set of pores; producing a second layer of material, defining a second set of pores and wherein the second set of pores is defined so as to cooperatively engage the first set of pores; and aligning and joining the first layer of material to the second layer of material to form a laminated membrane, having through-passageways formed by the first set of pores at least partially aligned with the second set of pores.

Abstract: An ultrasound probe assembly adapted for bio-imaging. The assembly comprises a catheter, an electrical assembly, including a set of linear conductors, at least partially housed within said catheter. An ultrasound transceiving unit is electrically connected to said electrical assembly and can be placed in both an undeployed state in which the transceiving unit is oriented coincidentally to said catheter and a deployed state in which it is directed to provide imaging signals over a volume of interest.