A system for sensing glucose concentration is provided and includes following components. A light source generates a light beam. The system may include a polarization state generator (PSG) for changing the polarization of the light beam, and then the light beam is emitted to a biological tissue. A polarization state analyzer (PSA) receives the light beam reflected from the biological tissue, and the received light beam is used to calculate Stokes vectors. A Mueller matrix is calculated according to the Stokes vectors. In some embodiments, the system includes an optical coherence tomography (OCT) in which the light beam is sensed by a detector for calculating the Mueller matrix. An optical rotation angle and a depolarization index are calculated in accordance with the differential Mueller matrix formalism. The glucose concentration is calculated in accordance with the optical rotation angle and the depolarization index.

System and method for non-invasive monitoring of physiological measurements of a subject, including at least one monitoring device, to detect changes in measured physiological signals, the monitoring device including at least one measuring unit, wherein each measuring unit includes: at least two light emitting sources, and at least one sensor, to detect light beams emitted from the at least two light emitting source, and a computerized device, in communication with the at least one monitoring device, the computerized device to receive data from monitoring device, wherein the monitoring device is configured to be removably attachable to the subject's body.

According to examples, an apparatus may include a processor and a memory on which is stored machine-readable instructions that when executed by the processor, cause the processor to access a detected polarization state of light reflected from an individual's eye, identify conditions associated with a detection of the polarization state of the light reflected from the individual's eye, determine whether the identified conditions match certain conditions within predefined difference levels, and determine a variance in the detected polarization state of the light from a previously detected polarization state based on a determination that the identified conditions match the certain conditions within the predefined difference levels, in which a change in a glucose level of the individual is to be determined based on the determined variance.

A glucose sensor comprising an optical energy source having an emitter with an emission pattern; a first polarizer intersecting the emission pattern; a second polarizer spaced a distance from the first polarizer and intersecting the emission pattern, the second polarizer rotated relative to the first polarizer by a first rotational amount ; a first optical detector intersecting the emission pattern; a second optical detector positioned proximal to the second polarizer, the first polarizer and the second polarizer being positioned between the optical energy source and the second optical detector, the second optical detector intersecting the emission pattern; a compensating circuit coupled to the second optical detector; and a subtractor circuit coupled to the compensating circuit and the first optical detector.

The present invention relates to a wearable device for acquiring physiological information of a subject. To combine the advantages of a contact sensor and a contactless sensor, the wearable device comprises an optical emitter (10) for emitting light into the subject's skin, an optical sensor (20) for receiving light scattered back from the subject's skin in response to the emission of light into the subject's skin, the received light representing or allowing the derivation of physiological information of the subject, and a carrier (30) for being held at the subject's skin and for carrying said emitter (10) and said sensor (20) such that a light receiving area (12), at which the emitted light enters the subject's skin, substantially corresponds to a light reflecting area (22), at which at least part of the scattered light leaves the subject's skin and is received by said optical sensor, the optical sensor (20) is arranged between the optical emitter (10) and the light receiving area (12) and is at least partially transparent for the light emitted by the optical emitter or the optical emitter (10) is arranged between the optical sensor (20) and the light reflecting area (22) and is at least partially transparent for the light reflected from the light reflecting area.

A photoplethysmography device comprises a light source configured to direct source light towards an external object; a light sensor arranged and configured to provide a sensor signal indicative of an intensity of a first source light fraction, which has been scattered by the external object; a casing for housing the light source and the light sensor, and having a cover plate transparent for the source light and an outer face to be facing the external object; and an optical blocking arrangement in the casing between the at least one light source and the outer face of the cover plate and configured to block a second source light fraction on its propagation path extending from the light source to the outer face of the cover plate and from the outer face of the cover plate to the light sensor without leaving the casing.

The invention provides a skin detection device using different detecting lights, such as white light or UV light. When white light is used, the user's original skin image is acquired, and further analyzed to determine the user's skin condition, such as pore size or dullness of spots. When UV light is used, it is determined whether there is metal remnant or acne on the user's skin. By using the skin detection device, various user skin conditions can be found to help the following cosmetic consultation.

The present disclosure provides a vital sign measuring device and method that may measure a heart rate signal of a living body in a motion state. The method comprises detecting two different signals, using an adaptive noise removal algorithm for removing noise from the two signals, and obtaining a more accurate heat rate signal after a certain operation.

Methods, apparatuses, and systems for measuring collagen organization in the cervix, assessing the health of a woman's cervix (including a pregnant woman's cervix), characterizing the composition and structure of cervical tissue, and measuring preterm labor risk are provided. Polarization sensitive techniques and properties of cervical tissue, including birefringence, can be used. A method can include acquiring in vivo images of cervical tissue, applying Mueller matrix (MM) polarimetry (including 44 Mueller matrix polarimetry), and determining one or more parameters of the cervical tissue using the Mueller matrix (MM) polarimetry. The in vivo images can be analyzed and various parameters that characterize the cervical tissue can be determined. Graphs and maps of the cervical tissue can be generated for use as care provider tools.

The invention provides a non-invasive blood glucose monitoring module with polarized light, which comprises a light emitting component, a light receiving component and a connecting member. The light emitting component includes a light emitting element and a first polarizing element, and light emitted from the light emitting element passes through the first polarizing element to transform into polarized light. A light emitting surface is formed for the light emitting component. The light receiving component includes a light sensing element, a magnetic crystal layer and a second polarizing element, and the light sensing element receives the polarized light being reflected and sequentially passing through the magnetic crystal layer and the second polarizing element. A light receiving surface is formed for the light receiving component. The connecting member connects one side of the light emitting component and one side of the light receiving component.