A prosthetic device includes a closed loop system for maintaining a predetermined concentration of a target ion in a region in proximity to a cell, such as a nerve cell. The device includes a controller and an ion-selective electrode assembly operatively connected to the controller, wherein the ion-selective electrode configuration is configured to sense the concentration of the target ion by potentiometric measurement and to convey the concentration to the controller. The controller is configured to modulate the current to the ion-selective electrode assembly based on the concentration of the target ion to control the concentration of the target ion so as to maintain the predetermined concentration of the target ion.

The present disclosure relates to implantable neuromodulation devices and methods of fabrication, and in particular to a separable high density connectors for implantable neuromodulation devices. Particularly, aspects of the present disclosure are directed to a medical device comprising an electronics module and a header for connecting the electronics module to a lead assembly. The header includes: a housing that includes (i) a cavity having a central axis or plane and an internal surface, and (ii) an opening aligned with the central axis or plane of the cavity, an array of retractable contacts extending from the internal surface towards the central axis or plane of the cavity, and an array of connection terminals on the housing, where each connection terminal of the array of connection terminals is: (i) electrically connected to the electronics module, and (ii) electrically connectable to a retractable contact of the array of retractable contacts.

Systems and methods are described for functional brain mapping using neuronavigational equipment and additional features. For example, some implementations described combine novel cortical stimulator tools with stereotactic navigation for three-dimensional position tracking of the cortical stimulator tools. In some implementations, the systems and methods described herein can be used on an awake patient. In some implementations, the systems and methods described herein can be used on a patient that is asleep, via motor evoked potentials (MEPs), phase reversal, or electromyography (EMG) monitoring. Accordingly, in some cases sensory and language regions of the brain can be identified in addition to motor regions.

Methods and systems for fabricating 3D electronic devices, such as multielectrode arrays, including metalized, 3D printed structures using integrated 3D printing and photolithography techniques are disclosed. As one embodiment, a multielectrode array comprises a flexible substrate, a plurality of photopatterned electrical traces spaced apart and insulated from one another on the substrate, and a plurality of 3D printed electrodes. Each 3D printed electrode comprises a photopolymer coated in metal and has a 3D structure that extends outward from the substrate, and each 3D printed electrode is electrically connected to a corresponding electrical trace of the plurality of photopatterned electrical traces.

Methods and systems for providing stimulation to a patient's brain using one or more electrode leads implanted in the patient's brain are described. The methods and systems help a clinician determine locations upon the lead where stimulation is expected to provide the best therapeutic benefit and the least side effects. Different locations upon the lead are used to provide stimulation and for each stimulation location evoked potentials are recorded. The evoked potentials are associated with likely beneficial therapeutic stimulation. Signals indicative of unwanted motor activity in the patient are also recorded for each of the stimulation locations. The recorded evoked potential signals and motor signals are used to determine stimulation locations that provide therapeutic benefit with minimal side effects. They can also be used to determine therapeutic windows for the potential stimulation locations.

Disclosed are devices, electrodes, systems, methods, and other implementations, including a system that includes a subdural sound comprising an elongated structure configured to be placed within a subdural space of a brain area of a patient, and an electrode comprising an elongated body, a plurality of electrical contacts disposed on a substantially flat first side of the elongated body, and a soundage channel defined along a longitudinal axis of the electrode and open at opposite ends. The soundage channel at the leading end of the electrode is fitted on the trailing end of the elongated structure of the subdural sound so as to be advanced, when the subdural sound is placed within the subdural space, to a target site in the subdural space for tangential placement on target tissue in the subdural space of the brain area.

Systems, methods, and devices for automatic generation of a stimulation therapy that mimics electrographic activity in the brain at natural seizure termination define a stimulation therapy to be generated by an implanted component of a medical device system and delivered to a subject through identifying data characterizing a patient's seizures, especially at termination. A machine learning model identifies the seizures or seizure types from which to establish a canonical seizure or seizure type, and an algorithm translates the canonical seizure or seizure type into data that can be used to characterize a stimulation therapy. The systems, methods, and devices, include those configured to deliver the stimulation therapy that emulates the canonical seizure or seizure type when the seizure is detected, with the aim of terminating the seizure sooner than it would terminate without intervention.

Amyloid fibers-based electrodes and apparatuses comprising the same. Additionally, methods for manufacturing amyloid fibers-based electrodes.

Synchronized stimulation of cardiac tissue can be implemented by implanting two or more rectifier-based AM receivers into different positions within a subject's heart. Each receiver is tuned to a different frequency, and generates an output signal that is capable of stimulating cardiac tissue when a signal at the corresponding tuned frequency arrives at the receiver. An AM transmitter can activate any given one of the receivers by transmitting a signal into the subject's body at the proper frequency. A controller controls the transmitter by commanding the transmitter to transmit pulses of AC at different frequencies at different times, so that when those pulses are received by the correspondingly-tuned receivers, each of the receivers will generate respective output signals that stimulate respective parts of the heart at respective times to promote improved cardiac performance.

An insertion device is proposed for implanting a flexible implantable strip in the cortex of a living being in a reliable and accurate manner. The insertion device comprises a wire maintained within a lumen of a penetration member so that a free tip portion configured to engage an anchoring hole of the implantable strip protrudes from a distal end of the penetration member Thanks to reduced dimensions of the tip portion of the wire compared to that of the implantable strip, removing the wire from the lumen results in the implantable strip being released from the penetration member while still adhering to the cortex. The wire may be withdrawn by pulling at an end portion opposite to the tip portion. The penetration member can be chosen among a needle and a tube