A system for monitoring patient intake includes an acquisition and transmission device having an electrode configured to detect vagus nerve activity. A first internal inductive coil is configured to communicate a signal indicative of the vagus nerve activity detected by the electrode to a second external inductive coil. The system also includes a processor configured to execute instructions stored in a memory that cause the system to process the signal received by the second induction coil into data corresponding to intake of the patient and communicate the data to a server that is accessible by a clinician.

A device for neurostimulation including an electrode structure for delivering stimulation pulses to a nerve as well as for processing and extracting evoked compound action potentials, wherein the electrode structure comprises at least a first anode, at least a second anode opposing the first anode and a plurality of cathodes arranged between said anodes, wherein said cathodes are asymmetrically arranged with respect to said at least first and second anode to permit evoked compound action potential sensing via the anode electrodes simultaneously with stimulation.

Techniques for non-invasively controlling targeted neural activity of a subject are provided herein. The techniques include applying a stimulus input to the subject, the stimulus input being formed by a deep artificial neural network (ANN) model and being configured to elicit targeted neural activity within a brain of the subject. The stimulus input may be a pattern of luminous power generated by the deep ANN model and applied to retinae of the subject. The stimulus input may be generated by the deep ANN model based on a mapping of the subject's neural responses to neurons of the deep ANN model.

Systems, devices and methods are disclosed for the treatment of injured peripheral nerves or other tissue using electrical stimulation. The systems can be used either in intraoperative or peri-operative settings and incorporate the use of either a plurality of monopolar electrodes with a patch used as return or a plurality of bipolar electrodes such as a cuff. The systems can provide hands-free delivery of electrical stimulation therapy over a predetermined set of time.

The present technology relates generally to the field of electrophysiology and specifically to automated devices, components, systems, and related methods for monitoring potential injury to the nervous system using evoked potentials during intraoperative neurophysiologic monitoring.

The disclosure describes devices and methods for providing transdermal electrical stimulation therapy to a subject including positioning a stimulator electrode over a glabrous skin surface overlying a palm of the subject and delivering electrical stimulation via a pulse generator transdermally through the glabrous skin surface and to a target nerve or tissue within the hand to stimulate the target nerve or tissue within the hand so that pain felt by the subject is mitigated. The pulses generated during the electrical stimulation therapy may include pulses of two different magnitudes.

A nerve cuff for establishing a nerve block on a nerve can have a cuff body with a channel for receiving a nerve, a reservoir for holding a drug, and an elongate opening slit extending the length of the cuff body that can be opened to provide access to the channel and can be closed to enclose the cuff body around the nerve. The nerve cuff can also include an electrode for detecting and measuring electrical signals generated by the nerve. A controller can be used to control delivery of the drug based on the electrical signals generated by the nerve.

Methods and devices are disclosed for inducing analgesia in a localized region of tissue. Inducing analgesia may be performed by identifying a nerve associated with the localized region, determining a resonant frequency for target neuronal cell membranes of the nerve, and generating a peripheral nerve blockade using the determined resonant frequency. The resonant frequency may be a frequency at which impedance of the nerve approaches a maximum.

An intravascular catheter for nerve activity ablation and/or sensing includes one or more needles advanced through supported guide tubes (needle guiding elements) which expand to contact the interior surface of the wall of the renal artery or other vessel of a human body allowing the needles to be advanced though the vessel wall into the extra-luminal tissue including the media, adventitia and periadvential space. The catheter also includes structures which provide radial and lateral support to the guide tubes so that the guide tubes open uniformly and maintain their position against the interior surface of the vessel wall as the sharpened needles are advanced to penetrate into the vessel wall. Electrodes at the distal ends of the guide tubes allow sensing of nerve activity before and after attempted renal denervation. In a combination embodiment ablative energy or fluid is delivered to ablate nerves outside of the media.

An injectable electrode which is manufactured in the body by curing from a liquid phase to a solid phase, and therefore molding to the contours of the bodily structures where it is injected.