Abstract: Methods of using unidirectionally propagating action potentials (UPAPs) for vagus nerve stimulation and for certain disorders are provided. Stimulators capable of creating such UPAPs include, but are not limited to, miniature implantable stimulators (i.e., microstimulators), possibly with programmably configurable electrodes.

Abstract: An implantable microstimulator configured to be implanted beneath a patient's skin for tissue stimulation employs a bi-directional RF telemetry link for allowing data-containing signals to be sent to and from the implantable microstimulator from at least two external devices. Further, a separate electromagnetic inductive telemetry link allows data containing signals to be sent to the implantable microstimulator from at least one of the two external devices. The RF bidirectional telemetry link allows the microstimulator to inform the patient or clinician regarding the status of the microstimulator device, including the charge level of a power source, and stimulation parameter states. The microstimulator has a cylindrical hermetically sealed case having a length no greater than about 27 mm and a diameter no greater than about 3.3 mm. A reference electrode is located on one end of the case and an active electrode is located on the other end of the case.

Abstract: Disclosed are implantable electronic devices and systems including a pair of microstimulators. The microstimulators include coils that are energized to generate magnetic fields aligned along a common axis.

Abstract: Compact electronic modules, which may be used with implantable microstimulators and other medical and non-medical devices, and manufacture/assembly of such modules are described. Component and circuitry designs utilize unique redistribution techniques and attachment methods. A number of component designs and packaging configurations maximize the volume efficiency of electronic modules. Also included are improved processes and systems enabling the manufacture and assembly of such compact packages.

Abstract: A stimulator includes an implantable pulse generator comprising circuit elements, a first power source, such as an ultracapacitor, that provides operating power for the circuit elements of the pulse generator. The pulse generator can also have a memory associated therewith, such as a volatile memory for storing programming data. A second power source that has higher voltage retention than the first power source can also be included. The second power source can be dedicated to the volatile memory and can provide operating power for the volatile memory.

Abstract: Methods of using unidirectionally propagating action potentials (UPAPs) for cavernous nerve stimulation and for certain disorders are provided. Stimulators capable of creating such UPAPs include, but are not limited to, miniature implantable stimulators (i.e., microstimulators), possibly with programmably configurable electrodes.

Abstract: An implantable stimulator that includes a housing, a first plastic component, and a second plastic component, where the first and second plastic components form a polymer-polymer interface. A light absorbing metal layer is disposed over at least a portion of the interface and an electronic subassembly is disposed within the housing. The first and second plastic components can be welded together by irradiating the light absorbing metal layer which converts the light to heat.

Abstract: Exemplary implantable stimulators for stimulating a stimulation site within a patient include an electronic module configured to generate stimulation and a housing configured to house the electronic module. The housing has a shape allowing the a stimulator and a surgical device to be accommodated together within an insertion tool used to insert the stimulator into the patient. Exemplary methods of stimulating a stimulation site within a patient include generating stimulation with an electronic module and housing the electronic module in a housing. The housing has a shape allowing the housing and a surgical device to be accommodated together within an insertion tool used to insert the housing into the patient.

Abstract: Exemplary systems for treating a patient with multiple stimulation therapies include a stimulator configured to automatically apply two or more stimulation signals to a stimulation site via a single channel. Each of the stimulation signals is defined by a distinct set of stimulation parameters. Exemplary methods of treating a patient with multiple stimulation therapies include defining two or more stimulation signals with two or more sets of stimulation parameters and applying the stimulation signals via a single channel to a stimulation site with a stimulator.

Abstract: An implantable stimulator includes a base, two prongs extending from the base and an electrode disposed on each of the prongs. This stimulator may be part of a system that includes an external device for transcutaneously communicating with the implanted stimulator. A method of using the implantable stimulator includes generating a current gradient between the electrodes on the two prongs to stimulate a target site in a patient. A method of making the implantable stimulator includes coating electrode material on the prongs except where the electrode surfaces are to be formed.

Abstract: An implantable stimulator includes a device for delivering a stimulus and a casing having a first, metal portion and a second, portion which is formed from a plastic or polymer. A method of forming an implantable stimulator includes preparing a coil on a ferrite tube and molding a casing body on the coil, such that the coil is embedded in a wall of the casing which is formed of a plastic or polymer. Another method of forming an implantable stimulator includes forming an annular metal connector and molding a plastic or polymer casing body on the metal connector.

Abstract: Systems for adjusting a position of an implanted medical device within a patient include an engagement tool configured to couple to the implanted medical device. The engagement tool adjusts the position of the medical device when coupled to the implanted medical device. Methods of adjusting a position of an implanted medical device within a patient include locating the implanted medical device, coupling an engagement tool to the medical device, and adjusting a position of the engagement tool to adjust the position of the medical device.

Abstract: A combination, voltage converter circuit for use within an implantable device, such as a microstimulator, uses a coil, instead of capacitors, to provide a voltage step up and step down conversion functions. The output voltage is controlled, or adjusted, through duty-cycle modulation. In accordance with one aspect of the invention, applicable to implantable devices having an existing RF coil through which primary or charging power is provided, the existing RF coil is used in a time-multiplexing scheme to provide both the receipt of the RF signal and the voltage conversion function. This minimizes the number of components needed within the device, and thus allows the device to be packaged in a smaller housing or frees up additional space within an existing housing for other circuit components. In accordance with another aspect of the invention, the voltage up/down converter circuit is controlled by a pulse width modulation (PWM) low power control circuit.

Abstract: Compact electronic modules, which may be used with implantable microstimulators and other medical and non-medical devices, and manufacture/assembly of such modules are described. Component and circuitry designs utilize unique redistribution techniques and attachment methods. A number of component designs and packaging configurations maximize the volume efficiency of electronic modules. Also included are improved processes and systems enabling the manufacture and assembly of such compact packages.

Abstract: An implantable microstimulator configured to be implanted beneath a patient's skin for tissue stimulation employs a bidirectional RF telemetry link for allowing data-containing signals to be sent to and from the implantable microstimulator from at least two external devices. Further, a separate electromagnetic inductive telemetry link allows data containing signals to be sent to the implantable microstimulator from at least one of the two external devices. The RF bidirectional telemetry link allows the microstimulator to inform the patient or clinician regarding the status of the microstimulator device, including the charge level of a power source, and stimulation parameter states. The microstimulator has a cylindrical hermetically sealed case having a length no greater than about 27 mm and a diameter no greater than about 3.3mm. A reference electrode is located on one end of the case and an active electrode is located on the other end of the case.