Abstract: An implantable pulse generator (IPG) allowing for trial stimulation in a fully implanted solution is disclosed. At the time the leads are implanted, a micro IPG having lead connection block(s) is also implanted and connected to the leads. To keep the micro IPG suitably small, it preferably does not include a battery, and is instead powered continuously via magnetic induction using a magnetic field produced by an external charger, such as a charging patch. A coil in the micro IPG picks up and rectifies this magnetic field to provide power to stimulating electronics in the IPG. Because of its small size (e.g., ?10 cm3), implantation of the micro IPG can occur at the same time the leads are implanted in the patient without inconvenience. Should stimulation therapy with the micro IPG prove effective, a larger, permanent IPG can later be implanted and connected to the implanted leads.

Abstract: An implantable pulse generator (IPG) allowing for trial stimulation in a fully implanted solution is disclosed. At the time the leads are implanted, a micro IPG having lead connection block(s) is also implanted and connected to the leads. To keep the micro IPG suitably small, it preferably does not include a battery, and is instead powered continuously via magnetic induction using a magnetic field produced by an external charger, such as a charging patch. A coil in the micro IPG picks up and rectifies this magnetic field to provide power to stimulating electronics in the IPG. Because of its small size (e.g., ?10 cm3), implantation of the micro IPG can occur at the same time the leads are implanted in the patient without inconvenience. Should stimulation therapy with the micro IPG prove effective, a larger, permanent IPG can later be implanted and connected to the implanted leads.

Abstract: An implantable microstimulator can include a housing having a first end; an electronic subassembly disposed within the housing; a plurality of electrodes disposed on the housing and coupled to the electronic subassembly; and a dissecting tip disposed at the first end of the housing. Another implantable microstimulator includes a housing having a first end; an electronic subassembly disposed within the housing; a plurality of electrodes disposed on the housing and coupled to the electronic subassembly; and a extraction aid disposed at the first end of the housing and configured and arranged for attachment of an extraction line.

Abstract: An implantable cardiac lead system suitable for placement in the coronary sinus region of the heart. The lead system comprises a lead having two or more non-helical bends in its distal portion. The two or more non-helical bends cooperate to prevent the lead from dislodgment or displacement inside the coronary sinus. The lead system may further comprise a stylet suitable for steering the lead into at least one of the coronary sinus vein, great cardiac vein, left marginal vein, left posterior ventricular vein, and small cardiac vein. The stylet is tapered in its distal portion to provide enhanced maneuverability and steerability inside the coronary sinus region. The lead system may also comprise an introducer which aids in introducing the lead into the heart.

Abstract: A lead assembly and a method of making a lead are provided. The lead comprises a terminal, proximal end having a plurality of terminal contacts and material separating the terminal contacts. In one embodiment of the lead, the terminal contacts are separated by a preformed spacer, that may be made from various hard materials such as polyurethane, PEEK and polysulfone. Epoxy may be used to fill spaces at the proximal lead end, including between the spacer and terminal contacts. In one embodiment of the lead, the terminal contacts are separated by epoxy only. The lead may include a plurality of conductor lumens that contain conductors. The lead may also include a stylet lumen for accepting a stylet.

Abstract: A system for stimulation includes an implantable pulse generator, a lead, and conductors. The lead includes an array body disposed at a distal end of the lead and electrodes concentrically arranged on the array body. A center electrode may also be disposed on the array body. The electrodes may be arranged in more than one concentric ring. A method of using an implantable stimulator includes implanting an implantable stimulator and providing an electrical signal to at least one electrode of the implantable stimulator to stimulate a tissue. The electrical signal may be provided between diametrically opposed electrodes or between electrodes that are not diametrically opposed. If the implantable stimulator has a center electrode, the electrical signal may be provided between the center electrode and at least one concentrically arranged electrode.

Abstract: An implantable microstimulator can include a housing having a first end; an electronic subassembly disposed within the housing; a plurality of electrodes disposed on the housing and coupled to the electronic subassembly; and a dissecting tip disposed at the first end of the housing. Another implantable microstimulator includes a housing having a first end; an electronic subassembly disposed within the housing; a plurality of electrodes disposed on the housing and coupled to the electronic subassembly; and a extraction aid disposed at the first end of the housing and configured and arranged for attachment of an extraction line.

Abstract: A lead assembly (20) for a small implantable medical device (10) (a.k.a., microdevice (10) provides means to attach a remote electrode (14) to microdevice (10), which means inhibit fluid ingress when microdevice (10) is not attached to lead assembly (20). Microdevices may provide either or both tissue stimulation and sensing. Known microdevices (10) include spaced apart electrodes (12a, 12b) on the outer surface of the microdevice. Lead assembly (20) includes an insulated lead (16) including a proximal end and a distal end, with at least one conductor therebetween; at least one electrode (14) at the distal end of the lead and electrically connected to the at least one conductor, and a connector (18) attached to the proximal end of the lead and adapted to be removably connectable to microdevice (10).