A method of optical analysis comprises receiving light at an optical spectrometer module from a light source, distributing the received light into two or more light beams with a light distribution component of the optical spectrometer module, concurrently exposing each of a reference and one or more test samples to one of the two or more light beams, and concurrently measuring a property of the light associated with each of the reference sample and one or more test samples with a corresponding detector.

A device for monitoring at least one parameter of a fluid specimen obtained from a patient. The device has a fluid conduit holder comprising a clamp configured to position a fluid conduit, which holds the fluid specimen obtained from the patient, in a position for optical analysis, and an optical analyzer having a light source and a light detector. The optical analyzer is configured to expose the fluid specimen contained within the fluid conduit to an illuminant and measure light received at the detector. The device has an optical alignment mechanism mechanically coupling the light source, the clamp, and the light detector together, and configured to align at least the light detector with the fluid conduit at the position for optical analysis.

A microscope apparatus includes a sample carrying module, a light source module and a lens module. The sample carrying module includes an adhesive element and a body having a light-transmission region and a sample viewing surface. The adhesive element is detachably adhered to the body, and at least partially covers the light-transmission region, such that the adhesive element is disposed adjacent to the sample viewing surface. The light source module is detachably disposed at a side of the body, and includes a base and a light source. The base has an aperture, and the sample carrying module is detachably disposed at a side of the aperture. The light source is disposed in the base. The lens module includes at least one lens, which is detachably disposed at one side of the sample carrying module and substantially focuses at the sample viewing surface, and corresponds to the light source module.

A gene analyzer has a structure in which a metal block, a heater installed on an outer surface of the metal block, and a heat insulator applied onto an outer surface of the heater are integrally formed, thereby miniaturizing the gene analyzer. Further, parts for light measurement, such as a light source element, a light-receiving element, a light source filter, a fluorescent filter, a light source lens, a fluorescent lens, and the like, are installed in a heat insulator light source path and a heat insulator fluorescent path formed in the heat insulator, and the paths formed in the heat insulator are aligned with a block light source path and a block fluorescent path of the metal block.

A sample structure measuring device includes a light source, a path splitting portion configured to split light from the light source into light on a measurement path passing through a sample and light on a reference path, an optical path merging portion configured to merge the measurement path and the reference path, a photodetector having pixels and configured to detect incident light from the path merging portion and output phase data of the incident light, and a processor. A first region is a region where the sample is present and a second region is a region where the sample is not present. The processor divides the phase data into the first region and the second region, sets an initial estimated sample structure based on the first region, and optimizes the estimated sample structure using simulated light transmitted through the estimated sample structure and measurement light transmitted through the sample.

The invention relates to a microplate (10) for microscopy of an organoid (30), comprising: a body (11) having at least one recess (20), the recess (20) being adapted to contain and restrict movement of the organoid (30), and a reflective surface (40), the reflective surface (40) being inclined in relation to the recess (20), such that an incoming beam of light towards the microplate (10) is directed onto the organoid (30) in a substantially horizontal direction.

Provided are a light scattering measuring apparatus. The light scattering measuring apparatus includes: light sources; a single light receiver; a sample holder including a cell, a frame body, a first opening formed in an incident portion of a first optical path used for forward measurement or side measurement, and a second opening formed in an incident portion of a second optical path used for back measurement, and an optical element; and a moving mechanism. The first optical path and the second optical path are separated from each other in vertical direction. The moving mechanism moves the first opening to a position of the incident portion of the first optical path when the forward or side measurement is to be performed, and to move the second opening to a position of the incident portion of the second optical path when the back measurement is to be performed.

A microplate reader having a receiving apparatus for receiving a microplate having predefined dimensions and a multiplicity of wells, and an optical detector for detecting an optical radiation at respective individual ones of the wells of a microplate that in the receiving apparatus. The receiving apparatus is arranged to be movable in at least one spatial direction by a positioning mechanism to position the received microplate relative to the optical detector for successive measurements at different wells. The movable receiving apparatus has an interface device configured to provide an energy and/or data connection and/or a media supply connection and/or media disposal from the microplate reader to an accessory apparatus for additional functions. The interface device enables additional hardware provided as an accessory apparatus, which can be inserted into the receiving apparatus jointly with or instead of a microplate or some other sample container, to be supplied with energy and communication.

An optical measuring device for measuring light emitted from a sample includes a container cavity for receiving a container in which the sample is enclosed; a light detection unit for detecting light from the sample; a light guide path for guiding the light from the sample to the light detection unit; and a light absorbing unit for absorbing incident light. An end of the light guide path to receive the incident light faces the container cavity, a light exit end of the light guide path faces the light detection unit, and the light absorbing unit covers the perimeter of the light guide path other than the light-receiving-end and the light exit end thereof.

A system includes a cuvette including a cuvette body forming a substantially planar exterior surface and having a sensor window defined within the substantially planar exterior surface. The cuvette further includes a probe retention structure extending from the cuvette body. The system includes a probe with a probe body and a protrusion that is removably coupled to the probe retention structure.