Disclosed are devices and methods for estimating blood pressure, which implement a pulse-transit-time-based blood pressure model that can be calibrated. Some implementations provide reliable and user friendly means for calibrating the blood pressure model using blood pressure perturbation methods and multiple sensors.

A bio-optical measuring apparatus according to an embodiment of the present disclosure includes a light source that emits coherent light; and three or more optical receivers that receive reflected light from a living body, of light outputted from the light source toward the living body. The bio-optical measuring apparatus further includes a signal processing unit that obtains a low-noise signal by performing averaging processing based on detection signals outputted from the respective optical receivers in response to reception of the reflected light.

Disclosed are devices and methods for non-invasively measuring arterial stiffness using pulse wave analysis of photoplethysmogram data. In some implementations, wearable biometric monitoring devices provided herein for measuring arterial stiffness have the ability to automatically and intelligently obtain PPG data under suitable conditions while the user is engaged in activities or exercises. In some implementations, wearable biometric monitoring devices are provided herein with the ability to remove PPG data variance caused by factors unrelated to arterial stiffness. In some implementations, wearable biometric monitoring devices have the ability to perform PWA while accounting for the user’s activities, conditions, or status.

A biological information measurement device includes a first light emitting portion that emits first light, a second light emitting portion that emits second light, a light receiving portion that receives the first light reflected by an epidermis of a skin, a dermis of the skin, and a subcutaneous layer, and the second light reflected by the epidermis and dermis of the skin, and a processing unit that calculates biological information by removing noise, from a first detection signal output based on the first light received by the light receiving portion, using a second detection signal output based on the second light received by the light receiving portion.

A method for positioning a portable multispectral imaging device within a target distance range relative to a surface for imaging a region of interest (ROI) of the surface. The method generally involves determining a distance between the portable multispectral imaging device and the ROI of the surface determining whether the distance is within the target distance range generating a signal indicating to a user that the portable multispectral imaging device is not within the target distance range and providing instructions to the user to guide that the user for repositioning the portable multispectral imaging device; and triggering an image capturing sequence when the portable multispectral imaging device is within the target distance range. A method for calibrating a light source unit of the portable multispectral imaging device and a portable multispectral imaging device are also described.

Apparatus and methods provide wireless, disposable, continuous pulse oximeter sensor technology, useful and beneficial for a number of applications including relatively extended periods of data collection, and/or packaged in compact and easy-to-use assemblies. Economic fabrication and use provides flexible methodologies that can reduce the overall costs of monitoring and collecting patient's physiological data, and provide relatively greater ease and comfort to the patient. A disposable wireless continuous pulse oximeter sensor has a reduced emitter-detector separation, a low-power frontend, and a low-cost processor that sends waveforms to a host device so that the host can calculate and display the parameters of interest. Complications created by the reduced distance between emitter and detector are minimized by using an emitter-detector assembly with an optically dark background, and a bandage for improved optical compliance.

A sensing module is provided. The sensing module includes a light source, unit pixels, a leakage current detector, and a pixel driving circuit. The light source outputs an optical signal. The unit pixels are connected to row lines and column lines, and sense the optical signal to generate a pixel signal. The leakage current detector compares an amplitude of the pixel signal generated by the unit pixels with a first reference voltage, in a state in which the light source is deactivated, to detect a unit pixel, among the unit pixels, in which a leakage current equal to or greater than a threshold value is generated. The pixel driving circuit deactivates the detected unit pixel in a state in which the light source is activated.

A sensor cover according to embodiments of the disclosure is capable of being used with a non-invasive physiological sensor, such as a pulse oximetry sensor. Certain embodiments of the sensor cover reduce or eliminate false readings from the sensor when the sensor is not in use, for example, by blocking a light detecting component of a pulse oximeter sensor when the pulse oximeter sensor is active but not in use. Further, embodiments of the sensor cover can prevent damage to the sensor. Additionally, embodiments of the sensor cover prevent contamination of the sensor.

The present disclosure relates generally to a system and method for detecting or indicating a state of impairment of a test subject or user due to drugs or alcohol, and more particularly to a method, system and application or software program configured to creating a virtual-reality (“VR”) environment that implements drug and alcohol impairment tests, and which utilizes eye tracking technology to detect or indicate impairment.

Provided is a sweat sensing device (100). The device comprises a body (102) for positioning against skin (104). A recess (108) is defined in the body for receiving sweat from a skin area. The device further comprises an optical detection assembly (114) configured to detect a discrete sweat droplet (106) protruding into the recess from a sweat pore (110) in the skin area, and a fluidic system (116) configured to transport the sweat droplet (106) away from the recess (108) following detection of the sweat droplet by the optical detection assembly (114).