A highly-reliable absorbance measuring device that enables highly-accurate measurement of absorbance, and a method thereof are provided.

A liquid containing unit that can contain a chemical substance solution to be measured, a nozzle that communicates with a suction/discharge mechanism that sucks/discharges gas, a flow tube that includes a mouth part, which can be inserted into the liquid containing unit, at a lower end and that is detachably attached to the nozzle at an upper end, an emitting end that can emit measurement light, a light receiving end that can receive the light emitted from the emitting end, and a control unit are included. The control unit is configured to suck a prescribed amount of the chemical substance solution into the flow tube, and to lead absorbance on the basis of intensity of transmitted light acquired by emission of measurement light in a vertical direction into the flow tube.

Sensor systems including an interferometer system are disclosed herein. In a general embodiment, the sensor system includes an optical fiber that is embedded into a sample, where the optical fiber has a reflective tip. The optical fiber is optically coupled to a sensor and a detector of the laser interferometer system. The sensor system further includes a computing device or circuit that is configured to receive electrical signals generated by the detector. The laser source is configured to emit light, which is coupled into the optical fiber. The light travels through the optical fiber until the light reaches the reflective tip, where it is reflected back through the optical fiber. The detector is impacted by the reflected light, and generates an electrical signal based upon the reflected light. The computing device generates a value that is indicative of a behavior of the sample based upon the electrical signal.

Instruments, components thereof, consumables therefor, and associated methods are generally provided. Advantageously, some instruments described herein may be capable of performing and/or configured to perform assays at a rate that is faster and/or requires less input from an operator than assays performed by other methods. Some methods may comprise performing assays at such faster rates and/or involving such reduced input.

A chemical and/or biochemical apparatus (10) includes a thermal mount (14) having wells (26) for receiving reaction vessels (12), a thermal module (16) having a first side thermally coupled to the thermal mount (14), a first heat sink (18) thermally coupled to a second side of the thermal module, the heat sink (18) having a body and thermally conductive fins (32) extending outwards from the body of the first heat sink (18), and a printed circuit board (54) having electronic components for controlling at least the thermal module (16), an excitation light source (62), and a light sensor (52). A first set of light waveguides (60) delivers excitation light to a reaction vessel, and a second set of light waveguides (38) receives light from a reaction vessel and delivers the light to the light sensor (52). The printed circuit board (54), the excitation light source (62), the light sensor (52) and the light waveguides (38, 60) are arranged within an interior space (5) of the first heat sink (18).

In order to perform gas detection at multiple locations with a simple configuration and at a low cost, the gas detection device is provided with: a transmission unit for outputting to a transmission path, as a first optical signal, pulse light that has a temporally changing wavelength and that is generated by pulse light modulated by an optical wavelength modulator; and a reception unit for receiving a second optical signal output from a sensor head outputting the first optical signal propagated through the atmosphere as the second optical signal, converting the second optical signal received into an electric the signal detecting, by each sensor head, a predetermined type of gas contained in the atmosphere based on a temporal change in amplitude of the electric signal, and outputting a result of detection of the gas.

A photoacoustic remote sensing system (PARS) for imaging a subsurface structure in a sample has an excitation beam configured to generate ultrasonic signals in the sample at an excitation location; an interrogation beam incident on the sample at the excitation location, a portion of the interrogation beam returning from the sample that is indicative of the generated ultrasonic signals; an optical system that focuses at least one of the excitation beam and the interrogation beam with a focal point that is below the surface of the sample; and a detector that detects the returning portion of the interrogation beam.

A system including a light source, sampling tray, and a plurality of fiber optics positioned to achieve high contrast to improve accuracy and eliminate the need to rotate the sample. A composite light image from the fiber optics is fed to a spectrometer which converts the reflected light into a fingerprint corresponding to the concentration of at least one substance in the sample. The fingerprint is processed by a statistical model to determine concentration level of the at least one substance in the sample and the concentration level is then displayed.

Disclosed herein is a system, particularly a microscope system, for confocal Raman-spectroscopic measurements. The system is configured to detect minute sample amounts of microbes in a sample chamber with a lid, wherein the system is configured such that a comparably large working distance between the objective lens and the sample is sustained such that a measurement can be performed through the lid of the sample chamber. This allows for cultivating and measuring the sample in the same container.

A biological material measuring instrument is described. The biological material measuring instrument includes a rotating body and a main body. The rotating body includes one or more cartridge holders having cuvettes in which a reagent and an analyte in a sample react. The main body includes a pair of light-emitting parts and light-receiving parts to optically measure the analyte in the sample. The rotating body further includes a light-emitting optical waveguide for guiding the light of the light-emitting parts to the cuvette, and a light-receiving optical waveguide for guiding.

Instruments, devices and methods of analysis are provided which fully integrate a significant number of process steps in a continuous operation. Accurate positioning and full contact between components is also provided by the relative movement the designs allow. An effect interface between a low cost disposable cartridge or device and the instrument to process it is also detailed.