The present disclosure provides an ear tip. The ear tip includes a main body, a first conductive element at least partially embedded in the main body, a second conductive element at least partially embedded in the main body and spaced apart from the first conductive element. The main body includes a central portion having a top and a tail portion extending from the top of the central portion. The first conductive element is proximal to the top of the central portion and the second conductive element is distal from the top of the central portion. A wearable device is also disclosed.

The present biological electrode includes a conductive fabric (2) formed of base fibers which are filled with a conductor and/or to which the conductor is adhered, a thin metallic wire (3) formed into a spiral shape and connected with the conductive fabric (2) at a distal end of the thin metallic wire, and a filling material (5) with which a gap between the conductive fabric (2) and the thin metallic wire (3) is filled and which supports the conductive fabric (2) and the thin metallic wire (3), the conductive fabric (2) is supported in a roll shape, and the conductor is electrically connected with the thin metallic wire (3).

An illustrative system includes a brain interface system configured to be worn by a user and to output brain measurement data representative of brain activity of the user while the user is engaged in an electronic messaging session provided by an electronic messaging platform and a computing device configured to obtain the brain measurement data, determine, based on the brain measurement data, a graphical emotion symbol representative of a mental state of the user while the user is engaged in the electronic messaging session, and provide the graphical emotion symbol for use during the electronic messaging session.

A photoplethysmographic sensor comprising a light source for emitting light onto a tissue and an optical detector for receiving light that interacts with the tissue is provided. The sensor comprises a liquid crystalline polymer.

Disclosed is a system (100) and method (200) for 12-lead ECG recording and wireless remote monitoring. The system (100) provides a wearable ECG acquisition unit (40) recording 12-lead ECG from torso positions of electrode sensors on user's body thereby permitting unrestrained free movement during recording without compromising on accuracy achieved by conventional 12-lead ECG system. Thus, the system (100) and method (200) provides a reliable, quick to deploy, cost effective and portable alternative to bulky conventional 12-lead ECG systems and eliminates need for resorting to skilled physician every time the 12-lead ECG is to be recorded. The system (100) and method (200) is universal in use and torso placement positions, facilitating uniform acquisition of the 12-lead ECG without altering the placement positions of the electrode sensors irrespective of ECG modalities, thereby serving as a standard format for ECG recording and long term ECG monitoring.

Disclosed is a system (100) and method (200) for 12-lead ECG recording and wireless remote monitoring. The system (100) provides a wearable ECG acquisition unit (40) recording 12-lead ECG from torso positions of electrode sensors on user's body thereby permitting unrestrained free movement during recording without compromising on accuracy achieved by conventional 12-lead ECG system. Thus, the system (100) and method (200) provides a reliable, quick to deploy, cost effective and portable alternative to bulky conventional 12-lead ECG systems and eliminates need for resorting to skilled physician every time the 12-lead ECG is to be recorded. The system (100) and method (200) is universal in use and torso placement positions, facilitating uniform acquisition of the 12-lead ECG without altering the placement positions of the electrode sensors irrespective of ECG modalities, thereby serving as a standard format for ECG recording and long term ECG monitoring.

There is provided a system for mixed imaging modalities including impedance based analysis of a body portion of a patient, comprising: multi conductor busbar(s), each connected to a controller and at least two of multiple sensing components, a controller arranged to: iteratively perform: sequentially activate as a current source, a first sensing component previously un-used as the current source in earlier iterations, sequentially activating as a current sink, a second sensing component previously un-used as the current sink in earlier iterations, obtain surface voltages, by sequentially activating each of the other sensing components as a respective voltage sensor, and obtaining a respective voltage reading while alternating current is transmitted between the first and second sensing components, wherein the voltages and current obtained for each pair of first and second sensing component of each iteration are provided for computation of a 3D dataset of 3D impedance values of the body portion.

A device and method for determining the severity of sleep apnea using electroencephalography and electromyography. The device includes a headgear having a head pan sized to cover the head of a patient, at least at the locations where the measuring points C3 and C4 of the electroencephalography are situated, and a chin part, and wherein the head part has two electrodes for sensing EEG-signals of the electroencephalography at the electroencephalography points C3 and C4, and the chin part has at least one electrode for sensing the EMG-signal of the electromyography in the chin.

Disclosed herein are wearable bands for biomarker tracking and methods for making the wearable bands. The biomarker tracking wearable band having a printed circuit board assembly (PCBA), the PCBA including an electrocardiography (ECG) sensor utilizing printed Silver-Silver Chloride (Ag-AgCl) electrodes and an optical photoplethysmography (PPG) sensor utilizing more than two light emitting diodes (LEDs), and a directly over molded band encasing the PCBA.

A wearable sensor device includes a temperature and humidity sensor that measures ambient environmental information around a living body, a snap button connected to a bioelectrode, a biological information measurement unit that measures biological information, an inertial sensor that measures inertial information, a calculation unit that calculates a biological feature amount based on the biological information and calculates an inertial feature amount based on the inertial information, and a wireless communication unit that transmits the biological information, the inertial information, the biological feature amount, the inertial feature amount, and the environmental information to the outside.