A system and method for producing a report about a subject from data collected from the subject using a magnetic resonance imaging (MRI) system. The method includes directing the MRI system to perform a pulse sequence to manipulate exchangeable magnetization in the subject and acquiring, with the MRI system, imaging data from the subject in response to the pulse sequence. The method also includes analyzing the effects of the frequencies of applied RF energy on the imaging data to identify inhomogeneous lines formed by a summation of multiple sublines centered at multiple different frequencies. The method further includes generating a report pertaining to inhomogeneous magnetization transfer occurring in the subject in response to the pulse sequence.

An automated EP analysis apparatus for monitoring, detecting and identifying changes (adverse or recovering) to a physiological system generating the analyzed EPs, wherein the apparatus is adapted to characterize and classify EPs and create alerts of changes (adverse or recovering) to the physiological systems generating the EPs if the acquired EP waveforms change significantly in latency, amplitude or morphology.

Systems and methods for mapping a cavernous nerve near an organ. The system includes: one or more processors; and a memory that is communicatively coupled to the one or more processors and stores one or more sequences of instructions, which when executed by one or more processors causes steps to be performed comprising: applying an excitation signal to an electrode at a tip of an laparoscope, the tip being configured to contact a point on a tissue near an organ; responsive to the excitation signal, measuring a change in a signal from a pair of electrodes configured to be installed on the penis, the change in the signal being associated with an erectile function of the penis; and based on the change in the signal from the pair of electrodes, determining a distance between the point on the tissue and a cavernous nerve near the organ.

A method and apparatus to assess sudomotor function to detect early stage peripheral distal neuropathy. The method sends a low voltage direct current of 1 to 5 volts between pairs of electrodes for a time of between 15 and 60 seconds, switches the current at the middle of the time and measures the peak and slope of the decreased conductance. The method can be used to assess skin blood flow and/or sweat gland density depending on the direction of the current.

A biological information measurement device includes a heart rate counting unit for measuring an HR value indicating a heart rate on a basis of heart-rate data obtained by capturing heartbeats when a subject to be measured exercises, an analysis unit for performing power spectrum analysis on a heart rate variability frequency of the heart-rate data to calculate an LF value which is an integral value of low frequency components, and a detection unit for obtaining an HR/LF value by dividing the HR value by the LF value with respect to exercise intensity of the subject to be measured.

An intraoperative neural monitoring system for use during a surgical procedure on a subject includes a mechanical sensor and a processor. The mechanical sensor is configured to monitor a physical motion of a muscle of the subject and provide a mechanomyography (MMG) signal corresponding to the monitored physical motion. The processor is configured to receive the MMG signal, apply a wavelet transform to the MMG signal, and determine, from the output of the wavelet transform, if the monitored physical motion of the muscle is an artificially induced neuromuscular response that is attributable to an applied electrical stimulus. If the processor determines that the monitored physical motion of the muscle is an artificially induced neuromuscular response, it then provides an indication to a user.

A bipolar stimulation probe including a first electrode, a second electrode, a control module, and switches. The control module is configured to stimulate nerve tissue of a patient by generating (i) a first output signal indicative of a first pulse to be output from the first electrode, and (ii) a second output signal indicative of a second pulse to be output from the second electrode. The first pulse and the second pulse are monophasic. The switches are configured to output from the bipolar stimulation probe (i) the first pulse on the first electrode based on the first output signal, and (ii) the second pulse on the second electrode based on the second output signal.

A stimulation electrode assembly configured to be positioned relative to a patient for an operative procedure is disclosed. An evoked stimulation response may be sensed by a sensor near a portion of a subject. The evoked response may be sensed by an electrode and determined with a monitoring system. The evoked response may additionally and/or alternatively be sensed with a motion sensor. A position sensor may be provided to measure or determine whether the sensor has moved during a procedure.

A method for detecting an artificially induced neuromuscular response in a subject includes receiving a mechanomyography (MMG) output signal from a mechanical sensor in contact with a muscle of the subject; applying one or more conditioning filters to the MMG output signal to generate a conditioned signal and analyzing the conditioned signal to identify one or more candidate waveforms. Each candidate waveform meets one or more analog or digital signal characteristic criteria associated with an artificially induced neuromuscular response. The method then compares a first candidate waveform to a second candidate waveform to determine a degree of similarity between the first and second candidate waveforms, and provides an alert to a user that indicates detection of the artificially induced neuromuscular response when the degree of similarity exceeds a predetermined threshold.

A training simulator for intraoperative neuromonitoring (IONM) systems includes channels where at least one of the channels is identified as an active stimulation channel and a subset of the rest of the channels is identified as reference or pick up sites. Channels of the subset having signal data that exceed a predefined threshold are retained for further processing, while channels with signal data that do not exceed the threshold are eliminated from further reporting. Response data for the remaining channels are generated in advance of a future time when the response would occur. The generated data is time stamped and stored for display at a time window when requested by the system.