A device for reducing foreign body response in a subject caused by an electrode implanted in a subject's tissue. A base is secured to the subject, having a base aperture in proximity to the target site. The base can receive and align a body thereon. A body contains a chamber extending between a chamber aperture, aligned with the base aperture, at one end and a chamber opening at an opposite end. The chamber contains an acoustic coupling medium, such as polyvinyl alcohol cryogel, transmits acoustic vibrations from a transducer without altering their frequency. The transducer is mounted to the device and is configured to transmit acoustic vibrations into the chamber and through said acoustic coupling medium to the subject tissue at the target site, creating an acoustic field in the target site sufficient to reduce foreign body response in the subject where the electrode contacts the target tissue.

A method of performing personalized neuromodulation on a subject is provided. The method includes acquiring functional magnetic resonance imaging (fMRI) data of a brain of the subject. The method also includes calculating functional connectivity of the brain between a voxel in a subcortical region of the brain and a voxel in a cortical region of the brain, based on the fMRI data. The method also includes identifying a target location in the brain to be targeted by neuromodulation based on the calculated functional connectivity.

The problem of a potentially high amount of supra-threshold charge passing through the patient's tissue at the end of an Implantable Pulse Generator (IPG) program is addressed by circuitry that periodically dissipates only small amount of the charge stored on capacitances (e.g., DC-blocking capacitors) during a pulsed post-program recovery period. This occurs by periodically activating control signals to turn on passive recovery switches to form a series of discharge pulses each dissipating a sub-threshold amount of charge. Such periodic pulsed dissipation may extend the duration of post-program recovery, but is not likely to be noticeable by the patient when the programming in the IPG changes from a first to a second program. Periodic pulsed dissipation of charge may also be used during a program, such as between stimulation pulses.

An example of a system for programming neurostimulation according to a stimulation configuration may include stimulation configuration circuitry, volume definition circuitry, stimulation effect circuitry, and recording circuitry. The stimulation configuration circuitry may be configured to determine the stimulation configuration. The volume definition circuitry may be configured to determine stimulation field model(s) (SFM(s)) each representing a volume of tissue activated by the neurostimulation. The stimulation effect circuitry may be configured to determine a stimulation effect type for each tagging point specified for the SFM(s) and to tag the SFM(s) at each tagging point with the stimulation effect type determined for that tagging point. The stimulation effect type for each tagging point is a type of stimulation resulting from the neurostimulation as measured at that tagging point. The recording circuitry may be configured to generate SFM data representing the determined SFM(s) with the stimulation effect type tagged at each tagging point.

The present disclosure relates to the treatment of patients with Parkinson's Disease using subthalmic nucleus deep brain stimulation to a specific region of the brain. By positioning the electrode in the margin of the dorsal-lateral and anterior region of the subthalamic nucleus, improved benefits are obtained.

A deep brain stimulation transparent electrode array and a neural signal detection method using the same are proposed. The deep brain stimulation transparent electrode array includes a biocompatible dielectric substrate, a plurality of electrode sites arranged on one side of the substrate, a plurality of electrically conductive contacts arranged on the other side of the substrate, and an interconnector extended from each electrode site so as to be connected to each contact. The deep brain stimulation transparent electrode array is capable of conducting deep brain electrical stimulation and brain wave detection while minimizing image distortion in magnetic resonance imaging, and accuracy of the deep brain electrical stimulation and the brain wave detection may be increased by enhancing ability to carry electric current and minimizing the image distortion in the magnetic resonance imaging.

The present disclosure relates to a system for generating a predefined electrical signal in an MR scanner for use in electrical stimulation of a subject during MRI or functional MRI of said subject, wherein said MR scanner is located inside a shielded MRI room. The system comprises a control unit to be located outside the MRI room for generating an electrical signal and an electrical to optical converter to be located outside the MRI room for converting said electrical signal to a corresponding optical signal. An optical transmitting element, such as an optical fiber, is used for transmitting the optical signal into the MRI room, and an optical to electrical converter is used for converting the optical signal to said predefined electrical signal for electrical stimulation of the subject during magnetic resonance imaging. The optical to electrical converter is configured for being located inside the MRI room and for operation during magnetic resonance imaging.

Disclosed herein are systems and methods for electrically modulating tissue. Systems can include a current generator; at least one implantable working electrode, the at least one implantable working electrode configured to be in electrical communication with the current generator; at least one indifferent electrode; and a controller configured to signal the current generator to: generate a set of currents with a set of initial polarities to be delivered to the working electrodes; and wherein the at least one indifferent electrode absorbs a bias current which is equal in magnitude and opposite in polarity to a summation of the set of currents.

Electrode devices are provided having certain thin film components, including at least one thin film contact and a temperature sensor associated with the contact. The temperature sensor can be used to monitor the temperature during use of the electrode device, including during electrical stimulation or ablation. Further, the temperature sensor can be used to identify the most effective temperature for stimulation or ablation.

Described herein is an implantable device having a sensor configured to detect an amount of an analyte, a pH, a temperature, strain, or a pressure; and an ultrasonic transducer with a length of about 5 mm or less in the longest dimension, configured to receive current modulated based on the analyte amount, the pH, the temperature, or the pressure detected by the sensor, and emit an ultrasonic backscatter based on the received current. The implantable device can be implanted in a subject, such as an animal or a plant. Also described herein are systems including one or more implantable devices and an interrogator comprising one or more ultrasonic transducers configured to transmit ultrasonic waves to the one or more implantable devices or receive ultrasonic backscatter from the one or more implantable devices. Also described are methods of detecting an amount of an analyte, a pH, a temperature, a strain, or a pressure.