Systems and methods for treating a fibrous mass, which is comprised of a Morton's neuroma, are disclosed. In one exemplary implementation, a method may comprise identifying a location of the fibrous mass and non-surgically delivering electromagnetic energy to the fibrous mass. Embodiments may include delivering the energy via a Nd:Yag laser at various specified parameters, such as duration, pulse count, and tissue depth, among others.

A system is provided for connecting a surgically implantable neurostimulation device to an neurophysiological monitoring device. The system includes an apparatus connecting the neurophysiological monitoring device to the implanted neurostimulation device. The connecting apparatus includes a port couplable to the neurostimulation device and a plurality of electrode pin connectors extending from the port that are connectable to the neurophysiologic monitoring device. Using the connecting apparatus, signals from the neurophysiologic monitoring device can be transmitted for stimulation and responses can be transmitted to the neurophysiologic monitoring device to enable accurate positioning of electrodes of the neurostimulation device.

An implantable device for controlling electrical conditions of body tissue. A feedback sense electrode and a compensation electrode are positioned proximal to the tissue to make electrical contact with the tissue. A feedback amplifier is referenced to ground, and takes as an input a feedback signal from the feedback sense electrode. The output of the feedback amplifier is connected to the compensation electrode. The feedback amplifier thus drives the neural tissue via the compensation electrode in a feedback arrangement which seeks to drive the feedback signal to ground, or other desired electrical value.

The invention provides a method (10) for detecting a neural respiratory drive measure of a user. The method includes obtaining (100) an EMG signal and processing (200, 280) the EMG signal to produce a surrogate respiration signal and a processed EMG signal. Inhalations of the user are then detected (300) based on the surrogate respiration signal. The detected inhalations are then used in conjunction with the processed EMG signal to determine (400) a neural respiratory drive measure of the user.

Embodiments of the present disclosure provide an apparatus, method and system for physical, pre-action, extremity and related spinal cord, brain stem and neural therapies. An apparatus according to the present disclosure can include: a computing device configured to convert an input control action into a simulation instruction, wherein the input control action is provided by an input device; at least one simulated extremity operatively connected to the computing device and configured to simulate at least one modeled human anatomical movement based on the simulation instruction, wherein the at least one modeled human anatomical movement is distinct from the input control action; and a feedback device operatively connected to the computing device and configured to transmit a sensory response, wherein the sensory response is based on the modeled human anatomical movement.

A system and methods utilizing electrical stimulation to achieve a desired therapeutic effect are provided. In one aspect, a method for controlling nerve activity in a subject is provided. The method includes receiving input indicating a desired therapeutic effect for at least one neural structure of a subject, and selecting, based on the input received, an electrical stimulation configured to achieve the desired therapeutic effect. The method also includes controlling a sympathetic nerve activity in the subject by delivering the electrical stimulation using electrodes positioned proximate to nerves innervating the subject's skin.

A medical image processing apparatus according to an embodiment includes processing circuitry configured to: extract position information of innervation from subject data; convert a subject nerve region that is based on the extracted position information into atlas data; analyze a position relation between a functional area in a brain in the atlas data and the converted subject nerve region; and convert the analysis result into the subject data.

The present invention is directed to a system and method for enhancing in situ visualization of a target site within a patient during a medical procedure using fluorescence. As such, the system includes a plurality of fluorescent molecules configured to selectively target and bind to one or more locations at the target site within the patient and a delivery mechanism for delivering the fluorescent molecules into the patient. In addition, the system includes a detection device configured to generate a detectable signal containing information relating to the target site and send the detectable signal to an imaging system for viewing by a user, such as a physician. Thus, the fluorescent molecules enhance in situ visualization of the target site when viewed through the skin of the patient.

A nerve integrity monitoring device includes a control module and a physical layer module. The control module is configured to generate a payload request. The payload request (i) requests a data payload from a sensor in a wireless nerve integrity monitoring network, and (ii) indicates whether a stimulation probe device is to generate a stimulation pulse. The physical layer module is configured to (i) wirelessly transmit the payload request to the sensor and the stimulation probe device, or (ii) transmit the payload request to a console interface module. The physical layer module is also configured to, in response to the payload request, (i) receive the data payload from the sensor, and (ii) receive stimulation pulse information from the stimulation probe device. The data payload includes data corresponding to an evoked response of a patient. The evoked response is generated based on the stimulation pulse.

A system for recording, processing, and monitoring biosignals is provided, the system being configured to suspend data acquisition whenever an electric surgical tool or other generator of high frequency interference is in use. Such a system may protect the hardware of the system and reduce or eliminate the acquisition of distorted signals. The system of some embodiments includes an amplifier system configured to detect the presence of high frequency interference. Related methods are also disclosed.