A system and a method of using dual-energy absoptiometry to estimate visceral fat metrics and display results, preferably as related to normative data. The process involves deriving x-ray measurements for respective pixel positions related to a two-dimensional projection image of a body slice containing visceral fat as well as subcutaneous fat; at least some of the measurements being dual-energy x-ray measurements, processing the measurements to derive estimates of metrics related to the visceral fat in the slice; and using the resulting estimates.

The present invention generally provides improved medical devices, systems, and methods, particularly for treating one or both lungs of a patient with an implant, such as a coil, having a strength tuned to a patient's tissue treatment region. More particularly, embodiments of the present invention include implant assemblies and systems for treating a lung of a patient with chronic obstructive pulmonary disease. The implant assemblies may comprise an elongate body comprising an alloy that may be characterized by its austenite final tuning. The implant may include multiple portions that may be of different austenite final tunings.

A method and a device of measuring tissue element and a wearable apparatus are provided. The method includes: irradiating a measurement region with incident light having multiple predetermined wavelengths, where each beam of the incident light passes through the measurement region to form exit light exited from at least one exit position; obtaining a light intensity value corresponding to each beam of the exit light acquired by M photosensitive surfaces, to obtain T output light intensities each obtained by processing the light intensity value of the exit light acquired by one or more photosensitive surfaces, and each photosensitive surface is used to acquire the light intensity value of the exit light exited from the exit position within a predetermined anti-jitter range corresponding to the photosensitive surface, 1?T?M; and determining a concentration of a measured tissue element according to at least one output light intensity corresponding to the predetermined wavelengths.

A method and a device of detecting a living tissue element and a wearable apparatus are provided. The method includes: irradiating a detection region with incident light, where the incident light passes through the detection region to form exit light exited from at least one exit position; obtaining a light intensity value corresponding to each beam of the exit light acquired by M photosensitive surfaces, to obtain T output light intensities, where each output light intensity is obtained by processing the light intensity value of the exit light acquired by one or more photosensitive surfaces, and each photosensitive surface is used to acquire the light intensity value of the exit light exited from the exit position within a predetermined anti-jitter range corresponding to the photosensitive surface, 1?T?M; and determining a concentration of at least one detected tissue element according to at least one output light intensity.

A method and a device of measuring a tissue element, and a wearable apparatus. The method includes: obtaining, in response to a reproducibility of a controllable measurement condition being met, an output light intensity corresponding to exit light having at least one predetermined wavelength, where the output light intensity is acquired by a measurement probe, the measurement probe is provided on a device of measuring a tissue element, and the device of measuring a tissue element has a signal-to-noise ratio level for distinguishing an expected change in a concentration of a tissue element; and processing at least one output light intensity corresponding to the at least one predetermined wavelength based on an interference suppression method, so as to determine a concentration of a detected tissue element.

Systems and methods for non-invasive fat reduction can include targeting a region of interest below a surface of skin, which contains fat and delivering ultrasound energy to the region of interest. The ultrasound energy generates a thermal lesion with said ultrasound energy on a fat cell. The lesion can create an opening in the surface of the fat cell, which allows the draining of a fluid out of the fat cell and through the opening. In addition, by applying ultrasound energy to fat cells to increase the temperature to between 43 degrees and 49 degrees, cell apoptosis can be realized, thereby resulting in reduction of fat.

An advice generation system including: a measuring unit which measures a subject's activity status and outputs activity data based on the activity status; an achievement state acquisition unit which acquires achievement state information that is achievement state information with respect to a goal to be achieved by the subject; an amount of action calculation unit which calculates action information amount that is a cumulative amount of action taken by the subject to achieve the goal, based on the activity data acquired by the measuring unit; a motivation determination unit which determines the subject's motivation to achieve the goal based on trends of change in the achievement state information and in the amount of action information, during a period until the achievement of the goal planned by the subject; and an advice generation unit which generates advice for the subject based on the determination's result on the motivation.

A hyperspectral/multispectral imager comprising a housing is provided. At least one light source is attached to the housing. An objective lens, in an optical communication path comprising originating and terminating ends, is further attached to the housing and causes light to (i) be backscattered by the tissue of a subject at the originating end and then (ii) pass through the objective lens to a beam steering element at the terminating end of the communication path inside the housing. The beam steering element has a plurality of operating modes each of which causes the element to be in optical communication with a different optical detector in a plurality of optical detectors offset from the optical communication path. Each respective detector filter in a plurality of detector filters covers a corresponding optical detector in the plurality of optical detectors thereby filtering light received by the corresponding detector from the beam steering element.

A method and a device for nondestructively detecting an elasticity of a viscoelastic medium are provided. The method includes: driving an ultrasonic transducer probe with a low-frequency vibration by a vibrator so as to produce an elastic wave in the viscoelastic medium; producing an ultrasonic wave by the ultrasonic transducer probe, and transmitting the ultrasonic wave to the viscoelastic medium; collecting an ultrasonic echo when the elastic wave is propagated in the viscoelastic medium and the ultrasonic transducer probe stops or almost stops vibrating; calculating an elastic parameter of the viscoelastic medium according to the collected ultrasonic echo.

A method and a device for nondestructively detecting an elasticity of a viscoelastic medium are provided. The method includes: acquiring with an ultrasonic imaging probe an ultrasonic image of the viscoelastic medium; determining an area to detect the elasticity of the viscoelastic medium according to the ultrasonic image; driving the ultrasonic transducer probe with a low-frequency vibration by a vibrator so as to produce an elastic wave in the viscoelastic medium; producing an ultrasonic wave by the ultrasonic transducer probe, and transmitting the ultrasonic wave to the viscoelastic medium; collecting an ultrasonic echo; calculating an elastic parameter of the viscoelastic medium according to the collected ultrasonic echo.