A method for estimating fractional fat content of an object of interest is described. The method comprises obtaining thermoacoustic data of a region of interest containing an object of interest and a reference, and estimating fractional fat content of the object of interest using the thermoacoustic data and at least one parameter of the reference.

A sensor device is described herein. The sensor device includes a multi-dimensional optical sensor and processing circuitry, wherein the multi-dimensional optical sensor generates images and the processing circuitry is configured to output data that is indicative of hemodynamics of a user based upon the images. The sensor device is non-invasive, and is able to be incorporated into wearable devices, thereby allowing for continuous output of the data that is indicative of the hemodynamics of the user.

The present disclosure relates to systems and methods for determining the renal glomerular filtration rate or assessing the renal function in a patient in need thereof. The system includes a computing device, a power supply, one or more sensors, and at least one tracer agent that fluoresces when exposed to electromagnetic radiation. The electromagnetic radiation is detected using the sensors, and the rate in which the fluorescence decreases in the patient is used to calculate the renal glomerular filtration rate in the patient.

A system and method is configured for use with an endoscope, a biopsy needle, and a data acquisition system. The system includes a sensor tip and a pressure sensor coupled to the sensor tip and having at least one piezo-resistor component with an internal-facing side and an external-facing side, and an opening adjacent to the at least one piezo-resistor component to allow fluid access to the internal-facing side and the external-facing side. The system also includes a tubing member with a distal end and a proximal end, the sensor tip coupled to the distal end, the sensor tip and the tubing member configured to be routed through the biopsy needle and connection elements coupled to the proximal end of the tubing member, the connection elements configured to mount the tubing member relative to the biopsy needle and to couple the pressure sensor to the data acquisition system.

A thermoacoustic imaging system is provided for use in combination with an ultrasound imaging system for imaging features of tissue, the ultrasound imaging system including an ultrasound imaging probe including a transmit-receive transducer array with a plurality of transmit-receive array elements. The thermoacoustic imaging system includes a receive-only transducer array with a plurality of receive-only array elements, registered with the plurality of transmit-receive array elements. The transmit-receive transducer array is housed in an ultrasound imaging probe, and the receive-only transducer array is housed in a thermoacoustic imaging probe. The thermoacoustic imaging probe is mechanically joined to the ultrasound imaging probe, e.g., as a sleeve fitted to the ultrasound imaging probe. A combined ultrasound transducer system including the ultrasound imaging probe and an thermoacoustic imaging probe may be used in composite imaging of tissue based upon the registration of the receive-only array elements with the transmit-receive array elements.

Systems and methods for electronically monitoring chest sounds and/or sensing electrical cardiac signals such as ECG signals are provided. In one embodiment, a hybrid stethdiographer has a sensing assembly with a chestpiece and a user interface. Stethdiographer also includes a conduit, a power source compartment, a pair of binaurals and a corresponding pair of earpieces. The user interface includes a record button, a mode selector and a display screen. The chestpiece includes a diaphragm and a plurality of electrical cardiac sensors.

The present invention relates to a mobile terminal and a method capable of performing authentication using a smart watch, including: detecting a request for authentication for executing an application; measuring a user's heartbeat rhythm through a sensor mounted in a bottom of the smart watch when detecting the request for the authentication; and comparing the measured heartbeat rhythm with an already-stored heartbeat rhythm and thus performing the authentication on the application.

The present disclosure is associated with monitoring health of a patient. An example electromagnetic-evoked acoustic device includes an electromagnetic component to emit energy toward tissue of a patient to cause the energy to be absorbed by the tissue; an ultrasound transmission component to transmit acoustic energy toward the tissue to cause a biological response from the tissue; and an ultrasound sensing component to sense the biological response from the tissue to permit a status of the tissue to be determined, wherein the biological response is sensed based on the energy absorbed by the tissue during the biological response.

[Problem] To provide a device with which it is possible to learn calorie consumption state by performing monitoring.

[Solution] This absorbed calorie measuring device comprises: an irradiating unit which irradiates a subject with light; a light receiving unit which detects the intensity of reception light that has passed through the subject and emitted outside the subject; and a control unit which calculates absorbed calorie from the reception light intensity.

Method and systems for optimizing acoustic energy transmission in implantable devices are disclosed. Transducer elements transmit acoustic locator signals towards a receiver assembly, and the receiver responds with a location signal. The location signal can reveal information related to the location of the receiver and the efficiency of the transmitted acoustic beam received by the receiver. This information enables the transmitter to target the receiver and optimize the acoustic energy transfer between the transmitter and the receiver. The energy can be used for therapeutic purposes, for example, stimulating tissue or for diagnostic purposes.