A method for spinal cord stimulation treatment includes positioning eight implantable electrodes to a dura matter in an epidural space proximate to a subject's spinal cord so that (i) a first circuit is created between a first and second electrode on a first channel, (ii) a second circuit is created between a third and fourth electrode on a second channel, (iii) a third circuit is created between a fifth and sixth electrode on a third channel, and (iv) a fourth circuit is created between a seventh and eighth electrode on a fourth channel, transmitting signals through the first and second circuits that interfere to produce a first beat signal, transmitting signals through the third and fourth circuits that interfere to produce a second beat signal, and interaction of the first and second beat signals results in a combined beat signal proximate to the subject's spinal cord.

Implementations described and claimed herein provide thin film devices and methods of manufacturing and implanting the same. In one implementation, a shaped insulator is formed having an inner surface, an outer surface, and a profile shaped according to a selected dielectric use. A layer of conductive traces is fabricated on the inner surface of the shaped insulator using biocompatible metallization. An insulating layer is applied over the layer of conductive traces. An electrode array and a connection array are fabricated on the outer surface of the shaped insulator and/or the insulating layer, and the electrode array and the connection array are in electrical communication with the layer of conductive traces to form a flexible circuit. The implantable thin film device is formed from the flexible circuit according to the selected dialectic use.

Devices and methods for manipulating devices such as micro-scale devices are provided. The devices can include a tether of various materials surrounded by a stiff body. The tether interfaces with microscale devices to draw them against the stiff body, holding the microscale devices in a locked position for insertion into or extraction out of tissue. The tensional hook and stiff body are configurable in a multitude of positions and geometries to provide increased engagement. Such configurations allow for a range of implantation and extraction surgical procedures for the device within research and clinical settings.

This disclosure relates to a device for applying a neural stimulus. A battery supplies electrical energy at a battery voltage and an electrode applies the electrical energy to neural tissue. A circuit measures the nervous response of the tissue and a voltage converter receives the electrical energy from the battery and controls a voltage applied to the electrode based on the measured nervous response of the tissue. This direct voltage control is energy efficient because losses across a typical current mirror are avoided. Further, the control based on the measured nervous response leads to automatic compensation of impedance variation due to in-growth or change in posture. As a result, the stimulation results in a desired neural response.

Chronic pain management can be achieved by electrically anesthetizing a peripheral nerve with on-demand electrical nerve block (OD-ENB). OD-ENB can be provided by an implantable capsule. Externally, at least a portion of the capsule can be constructed of a conductive membrane and the rest of the capsule comprises a biocompatible material. A blocking electrode contact, a return electrode contact, and a powering/communication component can be within the capsule. The blocking electrode contact can deliver a direct current (DC) through a portion of the conductive membrane to block conduction in the neural tissue to provide the OD-ENB. The return electrode contact can receive a return current from the neural tissue through another portion of the conductive membrane. The powering/communication component can communicate with one or more external components located external to the patient's body to receive a power signal. Notably the capsule has no internal battery.

Embodiments of the present disclosure include a method for treating a condition of a subject. An implant defining a longitudinal axis is implanted between a nerve and skin of the subject. The implant includes an insulating member disposed, along the longitudinal axis, on at least a skin-facing side of the implant. Exactly two electrodes are disposed, along the longitudinal axis, at respective portions of a nerve-facing side of the implant. While the electrodes are driven to apply a treatment that stimulates the nerve, the insulating member is used to inhibit direct stimulation of sensory nerve fibers of the skin that are adjacent to the skin-facing side of the implant. Other embodiments are also described.

A closed-loop implantable neurostimulator system for mitigating chronic pain, the closed-loop implantable neurostimulator system including a neuromodulation device comprising one or more electrodes configured to measure a physiological signal of a subject and deliver an electrical stimulation signal to a target area in the subject and a controller, in communication with the one or more electrodes, comprising a processor and a computer-readable memory storing a trained healthy computer model, the controller configured to analyze the physiological signal that is measured using the trained healthy computer model to identify a corrective electrical stimulation signal that, when delivered by the one or more electrodes to the target area, reduces pathological neuronal events in the target area while preserving acute pain response.

An example of a system may include a processor, and a memory device comprising instructions, which when executed by the processor, cause the processor to access at least one of patient input, clinician input, or automatic input, use the patient input, clinician input, or automatic input in a search method, the search method designed to evaluate a plurality of candidate neuromodulation parameter sets to identify an optimal neuromodulation parameter set, and program a neuromodulator using the optimal neuromodulation parameter set to stimulate a patient.

An electrical treatment device includes: a plurality of electrodes to be in contact with a part of a body of a user; and a controller that performs a treatment onto the part by applying, to the plurality of electrodes, a burst wave that is constituted of a continuous wave of a plurality of pulses. The controller outputs a first burst wave including a plurality of pulses each having a first amplitude, and after outputting the first burst wave, controller repeatedly outputs a second burst wave including a plurality of positive pulses each having a second amplitude and a third burst wave including a plurality of negative pulses having a third amplitude. The first amplitude is larger than each of the second amplitude and the third amplitude.

A method, system, and apparatus for temporarily modifying an impedance of a neural stimulator. The apparatus includes an antenna comprising a first pole and a second pole, a switching circuit configured to output switched signals, a rectifier configured to receive switched signals from the switching circuit, a plurality of electrodes, and a controller, wherein the switching circuit, based on the control signal, modifies one or more of a first pole signal or a second pole signal. The impedance may be modified via one or more switches in a switching circuit of the neural stimulator. The impedance change may be sensed by an external circuit. Also, an electrode-tissue impedance of the neural stimulator may be determined and an impedance of an external circuit modified based on the electrode-tissue impedance of the neural stimulator.