Abstract: An implementation provides a system that includes: a control module including a first antenna, the control module configured to generate a first radio frequency (RF) signal and transmit the first RF signal using the first antenna; an implantable lead module including a second antenna and at least one electrode configured to stimulate excitable tissue of a subject; and a relay module configured to receive the first RF signal; generate a second RF signal based on the first RF signal, the second RF signal encoding a stimulus waveform to be applied by the at least one electrodes of the implantable lead module to stimulate the excitable tissue of the subject; and transmit the second RF signal to the implantable lead module.

Abstract: A method for treating neurological pain includes inserting an introducer needle of gauge 18 or smaller through a percutaneous incision site on a body, coupling a first mating feature at a distal end of an elongate member of a stylet to a second mating feature of an implantable device that is configured to receive a wireless signal and to generate one or more electrical pulses from the wireless signal for exciting a tissue within the body, advancing the stylet and the implantable device together as an assembly to the tissue within the body through a lumen of the introducer needle, and applying the one or more electrical pulses to one or more electrodes of the implantable device to modulate the tissue within the body.

Abstract: A method of percutaneously implanting a tissue stimulator at a tissue of a body includes inserting a sheath of an implantation device into the body through an incision adjacent the tissue and inserting the tissue stimulator into the sheath to position one or more fixation mechanisms of the tissue stimulator near the tissue within the body. With at least a portion of the sheath inside of the body, the method further includes separating the sheath into two or more portions and moving the two or more portions apart from each other to remove the sheath from the tissue stimulator. The method further includes withdrawing the two or more portions of the sheath from the body through the incision.

Abstract: A method and system is presented for an implantable wireless power receiver for use with a medical stimulation or monitoring device. The receiver receives transmitted energy through one or more non-inductive antenna(s), utilizes microelectronics to perform rectification of the received signal for generation of a DC power supply to power an implantable device, and may also utilize microelectronics to provide parameter settings to the device, or stimulating or other waveforms to a tissue.

Abstract: A method for implanting a wireless neural stimulator device, the method including: inserting a device through on a patient's skin on a posterior side of the patient's neck region, wherein the device includes a proximal end, a distal end, a first opening at the proximal end, a second opening at the distal end, and a lumen extending between the first opening and the second opening; after inserting the device through the patient's skin, advancing the distal end into the epidural space of the patient; inserting the wireless neural stimulator device through the first opening; advancing the wireless neural stimulator from the first opening through the lumen until the wireless neural stimulator exits the second opening and into the patient's epidural space; and advancing the wireless neural stimulator through the epidural space until a target site is reached.

Abstract: An implantable wireless lead includes an enclosure, the enclosure housing: one or more electrodes configured to apply one or more electrical pulses to a neural tissue; a first antenna configured to: receive, from a second antenna and through electrical radiative coupling, an input signal containing electrical energy, the second antenna being physically separate from the implantable neural stimulator lead; one or more circuits electrically connected to the first antenna, the circuits configured to: create the one or more electrical pulses suitable for stimulation of the neural tissue using the electrical energy contained in the input signal; and supply the one or more electrical pulses to the one or more electrodes, wherein the enclosure is shaped and arranged for delivery into a subject's body through an introducer or a needle.

Abstract: Some implementations provide a method for modulating excitable tissue in a body of a patient, the method including: placing a wireless implantable stimulator device at a target site in the patient's body, the stimulator device including one or more electrodes; reconfiguring the wireless implantable stimulator device to form an enclosure that substantially surrounds the excitable tissue at the target site with the electrodes on the inside of the enclosure and facing the nerve; and causing electrical impulses to be delivered to the electrodes on the wireless implantable stimulator device such that neural modulation is applied to the excitable tissue substantially surrounded by the enclosure.

Abstract: An integrated circuit includes: a radio-frequency (RF) to direct current (DC) rectifying circuit coupled to one or more antenna on an implantable wirelessly powered device, the rectifying circuit configured to: rectify an input RF signal received at the one or more antennas and from an external controller through electric radiative coupling; and extract DC electric power and configuration data from the input RF signal; a logic control circuit connected to the rectifying circuit and a driving circuit, the logic control circuit configured to: generate a current for the driving circuit solely using the extracted DC electrical power; in accordance with the extracted configuration data, set polarity state information for each electrode; and a driving circuit coupled to one or more electrode, the driving circuit comprising current mirrors and being configured to: steer, to each electrode and via the current mirrors, a stimulating current solely from the generated current.

Abstract: An ear-piece assembly includes (i) an antenna portion enclosing a transmitting antenna configured to send one or more input signals containing electrical energy to a passive implantable neural stimulator device such that the passive implantable neural stimulator generates one or more stimulation pulses suitable for stimulating a neural structure in the craniofacial region solely using the electrical energy in the input signals; and (ii) an enclosure coupled to the antenna portion, wherein enclosure is sized and shaped to be mounted on a helix portion of an ear such that, when worn by a patient, weight from the enclosure is distributed over the helix portion of the ear for the enclosure to rest thereon, wherein the enclosure comprises (i) a controller module configured to provide the one or more input signals to the transmitting antenna, and (ii) a battery adapted to provide energy to the ear-piece assembly.

Abstract: An ear-piece assembly includes (i) an antenna portion enclosing a transmitting antenna configured to send one or more input signals containing electrical energy to a passive implantable neural stimulator device such that the passive implantable neural stimulator generates one or more stimulation pulses suitable for stimulating a neural structure in the craniofacial region solely using the electrical energy in the input signals; and (ii) an enclosure coupled to the antenna portion, wherein enclosure is sized and shaped to be mounted on a helix portion of an ear such that, when worn by a patient, weight from the enclosure is distributed over the helix portion of the ear for the enclosure to rest thereon, wherein the enclosure includes (i) a controller module configured to provide the one or more input signals to the transmitting antenna, and (ii) a battery adapted to provide energy to the ear-piece assembly.

Abstract: A fixation device for securing a catheter to a tissue within a body includes a shaft defining a lumen configured to receive the catheter and multiple anchors disposed along the shaft. Each anchor of the multiple anchors includes multiple protrusive elements that are biased to an extended configuration in which the multiple protrusive elements extend radially from the shaft for engaging the tissue to secure the catheter to the tissue when the catheter is disposed within the lumen. The multiple protrusive elements can be adjusted from the extended configuration to a collapsed configuration in which the multiple protrusive elements are oriented parallel to the shaft.

Abstract: An implantable pulse generator includes a controller configured to generate a forward signal carrying electrical energy, a first antenna configured to send the forward signal to an implanted tissue stimulator such that the implanted tissue stimulator can use the electrical energy to generate one or more electrical pulses and deliver the one or more electrical pulses to a tissue, a communication module configured to receive instructions carried by an input signal from a programming module for generating the forward signal at the controller, and a second antenna configured to receive the input signal from the programming module.

Abstract: A headset for positioning an electronic device against a head of a patient includes a flexible frame configured to surround a portion of the head, the flexible frame defining an interior channel and an exterior slot, a curved structure configured to grasp an ear of the patient, the curved structure being movable within the interior channel of the flexible frame for accommodating a size of the head, and a mount including a support base to which the electronic device can be attached, the mount being slidable along the exterior slot of the flexible frame to position the electronic device along the head.

Abstract: An implantable electronic device includes a flexible circuit board, one or more circuit components attached to the flexible circuit board and configured to convert electrical energy into electrical pulses, and one or more electrodes attached to the flexible circuit board without cables connecting the electrodes to each other or to the flexible circuit board, the one or more electrodes configured to apply the electrical pulses to a tissue adjacent the implantable electronic device.

Abstract: An antenna assembly includes: a wearable antenna including a conductive signal layer having a radiating surface; a feed conductive layer; and an insulating layer in between the conductive signal layer and the feed conductive layer, and wherein the conductive signal layer, the feed conductive layer, and the insulating layer are fabric-based, wherein the wearable antenna is shaped and sized to be embedded in a subject's clothing with sufficient flexibility to be stretched and bent as the subject implanted with a passive implantable stimulator device maintains routine daily activities, and wherein the wearable antenna is electrically tuned and configured to have the radiating surface of the conductive signal layer facing the subject's skin and a feed point of the feed conductive layer connecting to a controller such that the wearable antenna is non-inductively coupled to the implanted passive stimulator device to supply power the passive implantable stimulator device wirelessly and non-inductively.

Abstract: A device for securing a tissue stimulator to a tissue within a body includes a first housing and a second housing. The first housing defines a first receptacle configured to grasp the tissue stimulator and a protrusion extending away from the receptacle. The second housing defines a second receptacle configured to grasp the tissue stimulator and an opening configured to receive the protrusion to secure the first and second housings together such that the first and second receptacles are aligned to form a channel that surrounds the tissue stimulator and fixes a position of the tissue stimulator relative to the first and second housings. The device further includes an attachment feature by which either or both of the first and second housings can be secured to the tissue with the tissue stimulator carried therein.

Abstract: Some implementations provide a method for treating craniofacial pain in a patient, the method including: placing a wirelessly powered passive device through an opening into a target site in a head or neck region of the patient's body, the wirelessly powered passive device configured to receive an input signal non-inductively from an external antenna; positioning the wirelessly powered passive device adjacent to or near a nerve at the target site; and causing neural modulation to the nerve through one or more electrodes on the wirelessly powered passive device.

Abstract: A wirelessly powered implantable stimulator device includes one or more antenna configured to receive an input signal non-inductively from an external antenna, the input signal containing (i) electrical energy to operate the implantable stimulator device and (ii) configuration data according to which a pulse-density modulation (PDM) encoded stimulus waveform signal is retrieved to synthesize a desired stimulation waveform; a circuit coupled to the one or more antenna; and one or more electrodes coupled to the circuit and configured to apply the desired stimulation waveform to neural tissue, wherein the circuit is configured to: rectify the input signal received at the one or more antennas non-inductively; extract the electrical energy and the configuration data from the input signal; and in accordance with the extracted configuration data, retrieve the pulse-density modulation (PDM) signal to synthesize the desired stimulation waveform therefrom.

Abstract: A computer-assisted method that includes: establishing a communication link between a programming device and a controller device, the controller device wirelessly and non-inductively powering and controlling a passive implantable stimulator device; presenting configuration options to the patient user of the passive implantable stimulator device, the configuration options comprising stimulation waveform parameters for driving the passive implantable stimulator; receiving a specification of the configuration options in response to the presented configuration options; receiving user feedback when the user specified configuration options are transferred to the controller device which, in turn, drives the implantable stimulator device according to the specified configuration options; building, at the programming device, a profile that correlates the user specified configuration options with the corresponding quantitative index of pain; and recommending at least one configuration option based on the profile built f

Abstract: An antenna assembly includes: a wearable antenna including a conductive signal layer having a radiating surface; a feed conductive layer; and an insulating layer in between the conductive signal layer and the feed conductive layer, and wherein the conductive signal layer, the feed conductive layer, and the insulating layer are fabric-based, wherein the wearable antenna is shaped and sized to be embedded in a subject's clothing with sufficient flexibility to be stretched and bent as the subject implanted with a passive implantable stimulator device maintains routine daily activities, and wherein the wearable antenna is electrically tuned and configured to have the radiating surface of the conductive signal layer facing the subject's skin and a feed point of the feed conductive layer connecting to a controller such that the wearable antenna is non-inductively coupled to the implanted passive stimulator device to supply power the passive implantable stimulator device wirelessly and non-inductively.