An orthopedic system configured for use in a pre-operative, intra-operative, and post-operative assessment. The orthopedic system comprises a first screw, a second screw, a first device, a second device, and a computer. The first device and the second device are respectively coupled to a first bone and a second bone of a musculoskeletal system. The first and second devices each include electronic circuitry, one or more sensors, and an IMU. A bracket, wrap, or sleeve can be used to hold the first and second devices to the musculoskeletal system. The first and second devices are configured to send measurement data to a computer. The first and second devices each have an antenna system. Electronic circuitry in the first or second devices are configured to harvest energy from a received radio frequency signal to recharge a battery to maintain operation.

A biofeedback system for monitoring a limb of an animal. The biofeedback system comprises a non-rigid wrap configured to encircle the limb when the non-rigid wrap is attached to the limb and a plurality of sensors configured to be disposed within an interior of the non-rigid wrap when the non-rigid wrap is attached to the limb. Each of the plurality of sensors measures a first biometric value. The biofeedback system further includes a control module disposed within the interior of the non-rigid wrap and coupled to the plurality of sensors. The control module reads from each of the plurality of sensors first biometric values recorded during exercise of the animal.

A biofeedback system for monitoring a limb of an animal. The biofeedback system comprises a non-rigid wrap configured to encircle the limb when the non-rigid wrap is attached to the limb and a plurality of sensors configured to be disposed within an interior of the non-rigid wrap when the non-rigid wrap is attached to the limb. Each of the plurality of sensors measures a first biometric value. The biofeedback system further includes a control module disposed within the interior of the non-rigid wrap and coupled to the plurality of sensors. The control module reads from each of the plurality of sensors first biometric values recorded during exercise of the animal.

An apparatus for collecting information communicating with a server and a collecting device includes scanning a bar code and transmit identification information of the apparatus to the server; the bar code is configured to link to a webpage of the server; acquiring biological characteristic information of a user of the apparatus collected by the collecting device; acquiring the identification information and the biological characteristic information matched by the server; and displaying the identification information and the biological characteristic information synchronized with the server. A method and a server for collecting information are also disclosed.

Disclosed are a multiple physiological data collection device and system that collect, manually mark, sampling—physiological data for machine learning and AI analyses in a single operation background. Physiological data uploaded by sensing devices of different type and function, described in different formation, recorded at different times and/or pertaining to different person can be processed in one system. The invented system comprises a data uploading device, a data storage device and a data edition device and, optionally, an automated data analysis device.

Disclosed are a multiple physiological data collection device and system that collect, manually mark, sampling—physiological data for machine learning and AI analyses in a single operation background. Physiological data uploaded by sensing devices of different type and function, described in different formation, recorded at different times and/or pertaining to different person can be processed in one system. The invented system comprises a data uploading device, a data storage device and a data edition device and, optionally, an automated data analysis device.

A breast milk flow monitoring system in the form of a milk flow monitoring sensor is described and includes an array of electrodes and a controller. The electrodes include electrically conductive surfaces that are arranged to contact a skin surface of a breast. The controller generates a first excitation signal that is communicated via the first electrode to a first location on the breast, and generates a second excitation signal that is communicated via the first electrode to the first location on the breast. The controller receives a first current response signal and a second current response signal. A bio-impedance spectroscopic analysis of the first current response signal and the second current response signal is executed, wherein the bio-impedance spectroscopic analysis is calibrated for breast milk flow. A breast milk flow parameter is determined based upon the bio-impedance spectroscopic analysis.

A breast milk flow monitoring system in the form of a milk flow monitoring sensor is described and includes an array of electrodes and a controller. The electrodes include electrically conductive surfaces that are arranged to contact a skin surface of a breast. The controller generates a first excitation signal that is communicated via the first electrode to a first location on the breast, and generates a second excitation signal that is communicated via the first electrode to the first location on the breast. The controller receives a first current response signal and a second current response signal. A bio-impedance spectroscopic analysis of the first current response signal and the second current response signal is executed, wherein the bio-impedance spectroscopic analysis is calibrated for breast milk flow. A breast milk flow parameter is determined based upon the bio-impedance spectroscopic analysis.

Embodiments herein relate to devices and methods for assessing deep tissue temperature using optical sensing. In an embodiment an optical temperature monitoring device is included having an optical emitter, wherein the optical emitter is configured to emit light at a first wavelength from 100 nm to 2000 nm. The optical temperature monitoring device also includes an optical detector configured to detect incident light. The optical temperature monitoring device can be configured so that the light from the optical emitter propagates at a depth of at least 1 cm through tissue as measured from a surface of the optical temperature monitoring device and back to the optical detector and the incident light detected by the optical detector is used to determine a temperature of the tissue at depths of at least 1 cm as measured from a surface of the optical temperature monitoring device. Other embodiments are also included herein.

Embodiments herein relate to devices and methods for assessing deep tissue temperature using optical sensing. In an embodiment an optical temperature monitoring device is included having an optical emitter, wherein the optical emitter is configured to emit light at a first wavelength from 100 nm to 2000 nm. The optical temperature monitoring device also includes an optical detector configured to detect incident light. The optical temperature monitoring device can be configured so that the light from the optical emitter propagates at a depth of at least 1 cm through tissue as measured from a surface of the optical temperature monitoring device and back to the optical detector and the incident light detected by the optical detector is used to determine a temperature of the tissue at depths of at least 1 cm as measured from a surface of the optical temperature monitoring device. Other embodiments are also included herein.