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 methods, devices and systems used for the treatment of medical disorders via stimulation of the superficial elements of the trigeminal nerve. More specifically, cutaneous methods of stimulation of the superficial branches of the trigeminal nerve located extracranially in the face, namely the supraorbital, supratrochlear, infraorbital, auriculotemporal, zygomaticotemporal, zygomaticoorbital, zygomaticofacial, infraorbital, nasal and mentalis nerves (also referred to collectively as the superficial trigeminal nerve) are disclosed herein.

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.

Disclosed herein are systems and methods for increasing performance, improving sleep and improving relaxation that involve specifically coordinating nerve stimulation of a cranial nerve (e.g. vagus nerve) in conjunction with augmented reality (AR). According to certain embodiments disclosed are systems that include an AR component that presents information or a stimulus and provides cranial nerve fiber stimulation (CNFS) at strategic times to reduce anxiety/arousal/related during user activity or scenarios and reinforce learning.

Disclosed are various examples and embodiments of systems, devices, components and methods configured to treat mood disorders in a patient using a compact implantable neurostimulator and corresponding lead(s) that are shaped, sized and configured to be implanted beneath a patient's skin in the head or neck, and to stimulate one or more target cranial nerves. The one or more medical electrical leads comprising electrode(s) are positioned adjacent to, in contact with, or in operative positional relationship to, the one or more target cranial nerves of the patient. In some embodiments, electrical stimulation is provided to the one or more target cranial nerve(s) of the patient for periods of time ranging between 30 and 60 minutes, once or twice per day. In some embodiments, power is provided to the implantable neurostimulator transcutaneously by inductive, wireless, RF, acoustic, microwave, or other suitable non-invasive means.

Disclosed is a method of enhancing exposure therapy including providing an exposure therapy to a patient and stimulating the patient's vagus nerve at the same time as the exposure therapy. Also disclosed is a post-traumatic stress disorder therapy method including providing an exposure event to a patient and stimulating the patient's vagus nerve during the exposure event. Also disclosed is a phobia disorder therapy method including providing an extinction event to a patient and stimulating the patient's vagus nerve during the exposure event. Also disclosed is an obsessive compulsive disorder therapy method including providing a therapy event to a patient and stimulating the patient's vagus nerve during the therapy event. Also disclosed is an addiction disorder therapy method including providing a therapy event to a patient and stimulating the patient's vagus nerve during the therapy event.

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.

Differential charge-balancing can be used in high-frequency neural stimulation. For example, a neural stimulation apparatus can have first and second electrodes configured to be coupled proximate to a nerve fiber to implement a neural stimulation procedure. A neural stimulation circuit can be electrically coupled to the first and second electrodes. The neural stimulation circuit can apply stimulation currents to the nerve fiber through the first and second electrodes during a first stimulation phase of the neural stimulation procedure. The neural stimulation circuit can also apply a modified stimulation current to the nerve fiber through the first electrode during a second stimulation phase of the neural stimulation procedure. The modified stimulation current can be generated based on a difference between (i) a voltage at the first electrode, and (ii) a reference voltage derived from voltages on the first and second electrodes.

A method includes configuring, by a computing device, stimulation settings for each electrode in an at least one electrode array in physical contact with a patient, the stimulation settings having adjustable parameters comprising frequency, pulse width, and amplitude, obtaining, by the computing device, feedback information from the patient, and automatically adjusting, by the computing device, at least one of the adjustable parameters based on the feedback information from the patient.

Techniques for providing therapy to a patient via electrical stimulation are described. The techniques include, for example, determining, relative to a start time of providing the electrical stimulation, one or more efficacy times that correspond to an efficacy indicator, determining, according to the efficacy times, efficacy data items for the patient, comparing the efficacy data items with the efficacy indicator, and generating, based on the comparison, a prediction of an expected response to the therapy manifesting in the patient at a prospective time.