An example system includes a chamber to hold a mixture that includes a whole blood sample from a patient, a light source to illuminate the mixture in the chamber, a detector to detect light from the light source transmitted through the mixture in the chamber, and one or more processing devices to determine, based on the light detected by the detector, a platelet aggregation value of the whole blood sample that is substantially independent of a hematocrit of the whole blood sample.

An example system includes a chamber to hold a mixture that includes a whole blood sample from a patient, a light source to illuminate the mixture in the chamber, a detector to detect light from the light source transmitted through the mixture in the chamber, and one or more processing devices to determine, based on the light detected by the detector, a platelet aggregation value of the whole blood sample that is substantially independent of a hematocrit of the whole blood sample.

A label-free optical device for near real time quantification of the multifractal micro-optical properties of a sample includes a source of broadband light; a tunable filter that receives at least a portion of the broadband light and then transmits narrowband light, whereby a specific band of light is selected to avoid unwanted absorption of light by the sample; where the narrowband light is configured to illuminate a selected area of the sample, and in response elastically-scattered light is dispersed from the sample; a light collection device configured to collect at least some of the elastically-scattered light; where at least some of the collected elastically-scattered light is configured to be transmitted to a detector by the light collection device, and the detector is configured to record a light scattering signal; and where the detector is configured to perform light scattering signal measurements at multiple angles or wavelengths to determine a refractive index multifractality of the sample.

A label-free optical device for near real time quantification of the multifractal micro-optical properties of a sample includes a source of broadband light; a tunable filter that receives at least a portion of the broadband light and then transmits narrowband light, whereby a specific band of light is selected to avoid unwanted absorption of light by the sample; where the narrowband light is configured to illuminate a selected area of the sample, and in response elastically-scattered light is dispersed from the sample; a light collection device configured to collect at least some of the elastically-scattered light; where at least some of the collected elastically-scattered light is configured to be transmitted to a detector by the light collection device, and the detector is configured to record a light scattering signal; and where the detector is configured to perform light scattering signal measurements at multiple angles or wavelengths to determine a refractive index multifractality of the sample.

The present disclosure relates to high-throughput screening methods for identifying one or more chromatography operational parameters (e.g., binding parameters) and/or reagents for purifying EVs (e.g., exosomes) from a sample using chromatography. Also disclosed herein are methods for improving one or more aspects of EV (e.g., exosome) purification, e.g., improving EV yield, increasing EV ligand density, and/or reducing impurity recovery.

The present disclosure relates to high-throughput screening methods for identifying one or more chromatography operational parameters (e.g., binding parameters) and/or reagents for purifying EVs (e.g., exosomes) from a sample using chromatography. Also disclosed herein are methods for improving one or more aspects of EV (e.g., exosome) purification, e.g., improving EV yield, increasing EV ligand density, and/or reducing impurity recovery.

The invention concerns method and an apparatus for analyzing the quality and quantity of bubbles or droplets of a dispersed phase in a construction material. The method may be used on construction materials before or during curing of the material, while in a non-solid state with the dispersed phase being entrapped therein. The inventive analyzing includes the steps of: applying a first side of an at least partially transparent plate in contact with a sample of said construction material to make a surface of said sample visible through said transparent plate; illuminating said surface of said sample through said plate from an opposite second side of said plate with at least one light source; providing a photosensitive sensor on said second side of said plate for receiving light reflected from said sample through said transparent plate, receiving from said photosensitive sensor electrical signals corresponding to said received reflected light and rendering from said electrical signals a visual representation of said surface of said sample using an imaging device; analyzing said visual representation with a computer system, by identifying bubbles or droplets of said dispersed phase from the surface of the sample by a spatial illumination encoding of the sample; and by determining the size and location of identified bubbles or droplets of said dispersed phase.

Finally, an indication of the quality of said construction material is computed, based on the size and distribution of the identified bubbles or droplets of said dispersed phase in said sample.

An apparatus for estimating bio-information includes an optical sensor including a light source configured to emit light of multiple wavelengths onto an object, and including a plurality of detectors configured to detect light of each wavelength which is scattered or reflected from the object. The apparatus includes a processor configured to obtain spectra based on light of each wavelength which is detected by each detector, determine valid spectra of the obtained spectra, and estimate a bio-information value based on the valid spectra.

An apparatus for estimating bio-information includes an optical sensor including a light source configured to emit light of multiple wavelengths onto an object, and including a plurality of detectors configured to detect light of each wavelength which is scattered or reflected from the object. The apparatus includes a processor configured to obtain spectra based on light of each wavelength which is detected by each detector, determine valid spectra of the obtained spectra, and estimate a bio-information value based on the valid spectra.

Optical property measurement using a sensor behind a display screen Examples of this application disclose a method for measuring optical properties of a target. The method comprises illuminating the target with an illumination area with a display screen in contact with the target, and analysing signals reflected from the target and transmitted back through the display screen to a sensor positioned behind the display screen, to determine the optical properties of the target.