Methods and systems for adaptive configuration of ophthalmic devices are disclosed. An example method may comprise receiving, by a first sensor system disposed on or in a first ophthalmic device, sensor data representing movement of an eye of a user, wherein the first ophthalmic device is disposed within or upon an eye of the user; causing, based on the sensor data, storage of a history of movement of the eye; determining, based on the history of movement, a dwell characteristic indicating a distance at which the eye is fixated when an event occurs; and causing output of a signal indicative of performing an action in response to determining the dwell characteristic.

A portable customizable smart helmet, cap or splint for wound care, trauma and critical care.

A sensor arrangement is for mounting along an elongate device. The sensor arrangement is for positioning along a line sensor arrangements and has terminal blocks at a proximal and distal side, each for connection to one or more wires. A connection circuit controls the coupling of sensor signals to the proximal wires and the coupling of the distal wires to the proximal wires. In this way, a bypass function is implemented through the connection circuit, which avoids the need for physical wires of a distal sensor arrangement to bypass the sensor arrangement itself.

A pulse wave measuring device includes a processor and a memory. The processor obtains a visible light image, in a visible light wavelength range, of a user irradiated with visible light by a visible light source, obtains an infrared light image, in an infrared light wavelength range, of the user irradiated with infrared light by an infrared light source, extracts a visible light wave indicative of a user's pulse wave from the visible light image, extracts an infrared light wave indicative of a user's pulse wave from the infrared light image, computes a correlation value between the visible and infrared light waves, supplies a control signal for controlling the amount of infrared light emitted from the infrared light source to the infrared light source in accordance with the correlation value, calculates biological information by using at least one of the visible and infrared light waves, and outputs the biological information.

Disclosed herein is a head-mounted apparatus, including: an optical sensor having a contact face for contacting with the head of a user; a supporting unit disposed around the optical sensor and configured to contact with the head of the user; and a sensor supporting mechanism configured to support the optical sensor so as to permit a movement of the optical sensor in a contact direction that is a direction perpendicular to the contact face.

Systems and methods are described herein for use in synchronizing electrical activity monitored by a plurality of external electrodes with supplemental cardiac data for use in evaluating a patient's cardiac condition and configuring cardiac therapy. The supplemental cardiac data may include one or more markers indicative of the occurrence of cardiac events and/or data representative of representative of at least one of cardiac electrical signals, cardiac sounds, cardiac pressures, blood flow, and an estimated instantaneous flow waveform provided by a left ventricular assist device.

An emergency cardiac and electrocardiogram (ECG) electrode placement device is disclosed herein. The emergency cardiac and electrocardiogram (ECG) electrode placement device incorporates electrical conducting materials and elastic material into a pad that is applied to a chest wall of a patient, which places multiple electrodes in the appropriate anatomic locations on the patient to quickly obtain an ECG in a pre-hospital setting.

A system for facilitating arterial blood gas (ABG) sampling. The system includes a main part, a first plurality of pulse sensors attached in a row on an inner surface of the main part, a first plurality of lights attached in a row on an external surface of the main part, a first opening on the main part adjacent to the first plurality of pulse sensors, and a processor. The processor is configured to receive a first plurality of radial pulse intensities from the first plurality of pulse sensors, determine a highest radial pulse intensity among the first plurality of radial pulse intensities, and turn on a light from the first plurality of lights associated with the highest pulse intensity among the first plurality of radial pulse intensities.

An electronic device is disclosed. The electronic device includes a case and a battery cover forming an appearance of the electronic device and a printed circuit board mounted inside the case and provided with electronic elements. A measurement sensor is mounted on at least a portion of the printed circuit board. One surface of a recess of the printed circuit board, on which the measurement sensor is mounted, is formed at a different height from other portion of the printed circuit board in a thickness direction of the electronic device. The recess, on which the measurement sensor is mounted, is thinner than the other portion and is spaced apart from the other portion, and thus the electronic device can more accurately measure a body temperature of a user.

A blood flow disorder detection device includes: a sensor sheet including a flexible substrate and a plurality of sensors provided on the flexible substrate; and an analyzer that analyzes outputs of the plurality of sensors. The plurality of sensors measure different types of blood flow information of a living tissue, the blood flow information being obtained by attaching the sensor sheet to the living tissue. The analyzer detects a blood flow disorder in the living tissue by analyzing the different types of blood flow information from the plurality of sensors.