The invention provides an electroactive material (preferably electroactive polymer) sensor system, comprising an electroactive material sensor (22) and a control system (28) for performing measurements relating to the impedance of the electroactive material sensor at at least first and second different frequencies. From these measurements a temperature at the sensor and an external pressure or force applied to the sensor can be determined. The sensor can thus be used as a pressure sensor and as a temperature sensor. When used in combination with actuation, an electroactive material actuator with integrated temperature sensing functionality is able to measure the temperature at the exact actuator position, which is always closer than an external thermocouple.

Method, device and machine for calculating an index representative of properties of a material of the bone type of an individual to be subjected to tests, particularly wherein the method includes a first acquisition step for acquiring at least one image having a plurality of elementary units of a sample of the material, wherein a generation step is provided for generating a grid of elementary geometric elements, or cells, which is associated with, in particular superimposed on, the image, an image processing step in which it is provided to calculate at least the apparent elastic modulus and a density coefficient of the material, both as a function of characteristic values of each cell, and a calculation step for calculating the index representative of the properties of a material, wherein the index is a function of the value of the apparent elastic modulus net of the contribution of the density coefficient.

A percussive therapy system that includes a percussive massage device including a network interface, and an intelligence engine. The intelligence engine is configured to receive manual capture data and real-time tracking data from the percussive massage device, receive remote data from a remote data source, and generate recommendation data comprising a recommended protocol to be performed by the percussive massage device. The recommendation data is generated from demographic, activity, temporal, analytics, and biometric data, received from the manual capture data, the real-time tracking data, and the remote data inputs.

A catheter has a distal assembly with at least one loop with ring electrodes. A single continuous puller wire for bidirectional deflection is pre-bent into two long portions and a U-shape bend therebetween. The U-shape bend is anchored at a distal end of a deflectable section which is reinforced by at least one washer having at least two holes, each hole axially aligned with a respective lumen in the deflectable section. Each hole is centered with a lumen so that each puller wire portion therethrough is straight and subjected to tensile force only. A proximal end of the support member is flattened and serrated to provide a better bonding to the distal end of the deflectable section.

A comprehensive evaluation of the female pelvic floor tissues and structures is facilitated by a method of image fusion of two different imaging modalities, a tactile response data or tactile image is described as fused with ultrasound image. Both tactile response and ultrasound images may be acquired at the same time using a vaginal probe equipped with adjacent arrays of tactile sensors and ultrasound transducer elements.

Fragrance compositions comprising one or more fragrance compounds for use in increasing the duration of sleep and/or improving quality of sleep in a subject is disclosed. Fragrance compositions comprising one or more fragrance compounds for use in increasing the quality of sleep in a subject (i.e., an increase in the time the subject is asleep during the night, a decrease in the time the subject is awake during the night, an increase in the time the subject experiences REM sleep, an increase in the time the subject experiences deep sleep, an increase in the time the subject experiences light sleep; and an increase in overall sleep efficiency) is disclosed. The composition can be incorporated into various consumer end products.

Disclosed are a method and an apparatus for rehabilitation training of a cognitive function. A method for rehabilitation training of a cognitive function may comprise the steps of: performing a cognitive function test by a cognitive rehabilitation service server; receiving a cognitive function test result of the cognitive function test by the cognitive rehabilitation service server; determining a rehabilitation method matching the cognitive function test result, by the cognitive rehabilitation service server; and providing a user device with a rehabilitation content according to the rehabilitation method so as to perform rehabilitation training, by the cognitive rehabilitation service server.

Described herein are novel fMRI-based neurologic signatures that predict fibromyalgia (FM), clinical severity, and treatment outcomes. Further described are methods for diagnosing FM and for predicting or evaluating efficacy of a treatment of FM based on the neurologic signature.

A pressure compensating non-invasive blood-component measuring device has electrically insulated parallel electrodes mounted on a dielectric membrane (106). A main circuit board (201) provides electrical connections to the electrodes and has an orifice (402) to allow flexing. A housing supports the main circuit board, with a second orifice to facilitate the application of a finger onto the insulated electrodes. A bottom circuit board (401) supports a force sensor (408) and fixing elements (313, 314) secure the bottom circuit board to the top circuit board, such that the bottom circuit board does not contact the housing directly. An intermediate board (316) is guided but not restrained by the fixing elements, and is arranged to apply force onto said force sensor.

The present disclosure provides systems and methods for predicting a disease state of a subject using ultrasound imaging and ancillary information to the ultrasound imaging. At least two quantitative measurements of a subject, including at least one measurement taken using ultrasound imaging, as part of quantified information can be identified. One of the quantitative measurements can be compared to a first predetermined standard, included as part of ancillary information to the quantified information, in order to identify a first initial value. Further, another of the quantitative measurements can be compared to a second predetermined standard, included as part of the ancillary information, in order to identify a second initial value. Subsequently, the quantitative information can be correlated with the ancillary information using the first initial value and the second initial value to determine a final value that is predictive of a disease state of the subject.