The invention relates to a retroreflector able to be placed in contact with an environment, comprising, by way of constituent material, a material enabling a parameter of said environment to be picked up, said material modifying the optical transmission properties of the retroreflector when said parameter is present, said retroreflector being able to receive an incident light beam via a first face and to reemit a light beam via said first face.

A hydrogen sensor and preparation method therefor, and a method for implementing hydrogen detection based on the hydrogen sensor. The hydrogen sensor includes an elastomeric substrate and a hydrogen sensitive material-based nanostructure positioned on the elastomeric substrate, the surface of the elastomeric substrate close to the hydrogen sensitive material-based nanostructure has a nanoarray structure, and the hydrogen sensitive material-based nanostructure and the nanoarray structure are complementary to each other. In addition, the present disclosure provides a preparation method for the hydrogen sensor and a method for implementing hydrogen detection based on the hydrogen sensor.

A component measurement device for measuring a component of interest in blood on a basis of optical characteristics of a mixture containing a color component produced by a color reaction between the component of interest in the blood and a reagent includes: a first light source configured to emit first irradiation light of a first predetermined wavelength to the mixture; and a second light source configured to emit second irradiation light of a second predetermined wavelength to the mixture, the second irradiation light to be used for estimation of a noise amount contained in a measured value of absorbance of the mixture measured by using the first irradiation light of the first light source, the noise amount being derived other than from the color component.

Apparatus and methods for the detection of proteins in biological fluids such as urine using a label-free assay is described. Specific proteins are detected by their binding to highly specific capture reagents such as SOMAmers that are attached to the surface of a substrate. Changes to these capture reagents and their local environment upon protein binding modify the behavior of color centers (e.g., fluorescence, ionization state, spin state, etc.) embedded in the substrate beneath the bound capture reagents. These changes can be read out, for example, optically or electrically, for an individual color center or as an average response of many color centers.

The invention relates to a polymeric indicator fixed in a polymeric gel carrier, wherein the polymeric gel carrier comprises a hydrophilic polymer, wherein the polymeric indicator and the hydrophilic polymer are present together in the form of a combined cross-linked hydrogel network fixed by chemical bonds.

The invention further relates to a method for preparing a polymeric indicator fixed in a polymeric gel carrier and to a sensor for measuring pH, which comprises the polymeric indicator fixed in a polymeric gel carrier.

The present invention relates to a responsive photonic coating and to a substrate provided with such a responsive photonic coating. The present invention also relates to a sensor. An object of the present invention is to provide a responsive photonic coating that can be used for simultaneously measuring the exposure to high temperature and steam, such as in an autoclave.

An optical detector (100, 200, 300) for detecting gas and suspended matter therein includes a test chamber (111, 113), at least one light source (12), a sensing object (131, 133), a test optical sensor (141) and a processor (19). The test chamber (111, 113) accommodates a gas to be analyzed. The at least one light source (12) emits an incident light that enters the test chamber (111, 113). The sensing object (131, 133) is exposed to gas in the test chamber (111, 113), receives the incident light, and reflects or transmits a portion of the incident light to form a test light. The test optical sensor (141) receives the test light and generates a detected spectral signal. The processor (19) receives the detected spectral signal and calculates a detection result according to the detected spectral signal.

A sensor for use in biosensing is disclosed. The sensor comprises a photonic crystal waveguide comprising a photonic crystal comprising holes in a layer of dielectric material and a waveguide in the photonic crystal. The sensor comprises at least one strip disposed on the photonic crystal waveguide, spaced apart along, and running across the photonic crystal waveguide so as to form respective strip cavities, each of the at least one strip including a respective layer of material for sensing presence of a respective analyte; and a slot running along the waveguide of the photonic crystal waveguide.

Provided herein is an air monitoring system with a venturi pump including an air supply passageway, a sample passageway, and a discharge passageway, the discharge passageway in fluid communication with the air supply passageway and the sample passageway, and a detection device including a biochip, a light emitting source, a photodetector, and a controller electronically coupled to the photodetector. Also provided herein is a photonic biogel and uses thereof for spectroscopic detection of airborne pathogens.

The sensing arrangement (1), comprising:—a sensing area (10), for accommodating a sensing substance (20) selected for experimenting an optical response as a response of an external stimulus;—a light emitter (11), for emitting light towards said sensing area (10);—a light receiver (12), for receiving a light from said sensing area (10);—a substrate (13) having a first substrate surface (131) and a second substrate surface (132); wherein, said light emitter (11) comprise a first LED (110) and said light receiver (12) comprise a second LED (120), both LEDs (110, 120) formed on said first substrate surface (131); and said sensing arrangement (1) further comprises a trench (14), formed between said first LED (110) and said second LED (120).