Systems, devices and methods transmit data from a patient device to a location, for example a remote location, where the patient is monitored. The system may comprise a server system, for example a backend server system, a gateway and the patient worn device. The gateway can be configured to communicate with the patient worn device in response to a list transmitted from the server, for example an approved patient device list transmitted from the server to the gateway. The gateway may exclude communication with patient worn devices that are not on the list. This use of the list can control data throughput from the patient device to the gateway and also from the gateway to the server, such that the communication from the device on the list to the server is maintained and appropriate information can be reliably sent from the patient device to the server.

An electronic device and method for measuring user body information are provided. The method for measuring user body information includes detecting a contact of a user's body portion on at least two spots of a touch screen of the electronic device, upon detecting the contact of the user's body portion on the at least two spots of the touch screen, applying power to a first coil in the electronic device, and measuring the user body information using at least one of a voltage and a second current measured after a first current is induced across the user's body by a first magnetic field generated from the first coil as the power is applied.

A method for generating activity recommendations in a diabetes treatment plan includes receiving physiological data, preferences, and suggested activities for a person with diabetes (PwD), generating physiological profiles for the PwD, providing the physiological profiles to a virtual physiological model, receiving projections from a virtual physiological model, generating weighted values based on the suggested activities and preference data, each weighted value corresponding to a likelihood of the PwD adhering to a suggested activity, ranking each activity based on the estimated change in the physiological characteristic of a projection associated with the activity relative to a baseline physiological projection and scaled by the weighted value corresponding to each activity, and generating an output including a predetermined number of suggested activities ordered based on the ranking of activities that provide a greatest change in the physiological characteristic given the likelihood of the PwD adhering to the suggested activities.

Aspects of the present disclosure are presented for a surgical instrument having one or more sensors at or a near an end effector and configured to aide in the detection of tissues and other materials and structures at a surgical site. The detections may then be used to aide in the placement of the end effector and to confirm which objects to operate on, or alternatively, to avoid. Examples of sensors include laser sensors used to employ Doppler shift principles to detect movement of objects at the surgical site, such as blood cells; resistance sensors to detect the presence of metal; monochromatic light sources that allow for different levels of absorption from different types of substances present at the surgical site, and near infrared spectrometers with small form factors.

Various systems and methods for providing a wellness mirror are provided herein. A system for providing a wellness mirror includes a display; a modeler to receive depth images from a depth camera that is communicatively coupled to the system, and provide a model of a subject in the depth images; a health profiler to analyze the model and produce a health and wellness analysis; and a user interface to present the health and wellness analysis on the display.

A solar bioelectrical impedance spectrometer includes a microprocessor module, a radio module connected with the microprocessor module, a spectrometer module connected with the microprocessor module, a battery management module, a battery module connected with the battery management module, a solar power supply management module separately connected with the battery management module and the microprocessor module and a wearable solar cell module connected with the solar power supply management module. The battery management module is configured for receiving current output from the solar power supply management module under a preset condition and charging the battery module by the current. The spectrometer module includes an impedance network analyzer, a differential amplifier connected with the impedance network analyzer, and a wide-band current source connected with the impedance network analyzer.

A system and method is provided to measure intrathoracic complex impedance and to identify and indicate disease conditions based on the impedance measurements. Multiple impedance vectors may be taken into account, and an optimal vector may be selected to provide the most useful impedance measurement for the identification and indication of disease conditions.

Devices, systems, and techniques are disclosed for intelligent semiconductor based medical tweezers and instrumentation including microscale sensors, actuators and circuitry for tissue detection and characterization. In one aspect, a tweezer device includes a hinge structure to enable tweezing motion of the device for clamping a sample, two leg components coupled to the hinge structure, a plurality of microprobes configured on both of the two leg components, and an electronic circuit electrically coupled to the microprobes to process and/or transmit the electronic signals. The microprobes include sensors in a sensing tip structured to penetrate into the sample when the device clamps the sample and produce electronic signals from the sensors of a property of the sample, the sensors of the sensing tip including at least one of an electrode to measure an electrical potential, an electrical permittivity sensor to measure electrical permittivity, or a strain gauge to measure mechanical compliance.

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.

A method for monitoring an intrabody region of a patient. The method comprises intercepting electromagnetic (EM) radiation from the intrabody region in a plurality of EM radiation sessions during a period of at least 6 hours, calculating a dielectric related change of the intrabody region by analyzing respective the intercepted EM radiation, detecting a physiological pattern according to said dielectric related change and outputting a notification indicating the physiological pattern.