A swallowing action measurement device includes a holder, a sound detector and a posture detector. The holder is fitted to a neck region of a person being measured from behind. The sound detector is held in the holder in contact with the outer side surface of the neck region close to the epiglottis, and detects sound associated with at least a swallowing action of the person being measured and outputs a measured sound signal. The posture detector detects a posture of the person being measured.

A method and system are provided for measuring changes in a pose of a human jaw within a coordinate system of a pose tracking system. The method involves providing a configurable arm; configuring the configurable arm such that at least one rigid target portion of the configurable arm is compliant with operational conditions of the pose tracking system when a selected anchor region of a surface of an anchor portion of the configurable arm is in close proximity to a selected attachment region of the human jaw; positioning the configurable arm such that the anchor region is in close proximity to the attachment region; applying and curing a paste to rigidly couple the anchor region to the attachment region, and operating the pose tracking system to measure changes to the pose of the at least one rigid target portion when the configurable arm is rigidly coupled to the human jaw.

A wearable device operably worn by a user for monitoring musculoskeletal loading on structure inside the body of the user includes a plurality of sensors, each sensor operably worn by the user at a predetermined location and configured to detect information about a biomechanical activity of musculoskeletal tissues, a limb segment orientation, and/or a loading magnitude or location thereon; and a processing unit in communication with the plurality of sensors and configured to process the detected information by the plurality of sensors to estimate the musculoskeletal loading, and communicate the estimated musculoskeletal loading to the user and/or a party of interest.

Systems and methods are described for monitoring, treating, and preventing a pain state of an individual. In an aspect, a system includes, but is not limited to, a deformable substrate; a sensor assembly coupled to the deformable substrate, the sensor assembly including a motion sensor and a physiological sensor, the sensor assembly configured to generate one or more sense signals based on detection of a movement of the body portion by the motion sensor and a physiological parameter of the body portion by the physiological sensor; a processor including circuitry configured to identify a physiological state of the individual subject based on at least one of the movement of the body portion or the physiological parameter; and an effector operably coupled to the processor and configured to affect the body portion responsive to control by the processor.

Systems and methods are described for monitoring, treating, and preventing a pain state of an individual. In an aspect, a system includes, but is not limited to, a deformable substrate; a sensor assembly coupled to the deformable substrate, the sensor assembly including a motion sensor and a physiological sensor, the sensor assembly configured to generate one or more sense signals based on detection of a movement of the body portion by the motion sensor and a physiological parameter of the body portion by the physiological sensor; a processor including circuitry configured to identify a physiological state of the individual subject based on at least one of the movement of the body portion or the physiological parameter; and an effector operably coupled to the processor and configured to affect the body portion responsive to control by the processor.

A sensing and stimulation system includes a central hub, and a plurality of flexible arms extending from the central hub. Each of the arms includes at least one electrode and at least one sensor. Each of the arms is configured to perform sensing and stimulation including electrically stimulating biological material, and sensing biological responses and changes. The system includes a port configured to be alternatively connected to a remote control module for wireless operation of the system and a leaded connector for wired operation of the system.

A method for differentiating between tissue states or types including receiving a sequence of thermal data of a tissue, wherein the sequence is sampled at at least one location of the tissue while the tissue is being thermally disturbed, deriving from the thermal data at least one tissue-related thermal variable associated with each of the tissue locations, segmenting the tissue into segments comprising the locations having corresponding the at least one thermal variable and generating an output indicating the tissue segments. The disclosure also includes a system and computer product for differentiating between tissue states or types.

An automated method and system for determining the risk of developing a cancer in a subject, the method comprising preparing a tissue sample obtained from the subject for visually identifying at least one biological marker associated with the cancer, digitally scanning the prepared tissue sample, analyzing the scanned image of the tissue sample to identify regions of interest, quantifying at least one parameter associated with the marker, and executing an algorithm using the quantified parameter to calculate a risk score, wherein the risk score is representative of the risk of the individual developing the cancer.

The present invention relates to a method of diagnosing the primary lesions that give rise to a chronic condition or incorrect structure in myofascial units and associated structures in a human patient. The invention also relates to a method of therapeutic treatment of the diagnosed conditions, in particular by application of a variable vacuum stimulus.

In one example, a sensor is configured to be implanted into a patient's body. The sensor has at least one sensing element, a measurement device in communication with the at least one sensing element, and an internal wireless communicator in communication with the measurement device. The at least one sensing element includes a resistor, and the measurement device includes a capacitor. The measurement device measures a discharge time of the capacitor through the resistor so as to generate a measurement value that is proportional to a value of an anatomical property of the anatomical body, such as strain, that is observed by the sensor. The internal wireless communicator wirelessly communicates the measurement value through skin of the patient to an external wireless communicator situated outside of the patient's body.