In order to provide an absorption analyzer capable of directly measuring an analysis target gas flowing into or produced in a vessel such as a chamber and preventing a measurement error due to moisture condensation, the absorption analyzer is adapted to include: a light emission module that is attached covering a first opening of the vessel into which the analysis target gas flows or in which the analysis target gas is produced and emits light into the vessel; and a light detection module that detects the light emitted from the light emission module and passing through the vessel. In addition, the light emission module is adapted to include: a base flange that is attached around the first opening on an outer surface of the vessel; a window material whose outer surface is tilted at a predetermined angle; a seal member; and a pressing body.

A flow cell assembly (16) for a fluid analyzer (14) that analyzes a sample (12) includes (i) a base (350) that includes a base window (350B); (ii) a cap (352) having a cap window (352B) that is spaced apart from the base window (350B); and (iii) a gasket (360) that is secured to and positioned between the base (350) and the cap (352), the gasket (360) having a gasket body (360A) that includes a gasket opening (360B). The gasket body (360A), the base (350) and the cap (352) cooperate to define a flow cell chamber (362). Moreover, an inlet passageway (366) extends into the flow cell chamber (362) to direct the sample (12) into the flow cell chamber (362); and an outlet passageway (368) extends into the flow cell chamber (362) to allow the sample (12) to exit the flow cell chamber (362).

An identification apparatus includes a window unit including a passage surface on an upper side configured to allow a sample supplied from a conveyance unit to slide along and pass on the passage surface, a light irradiation unit disposed below the window unit, spaced a certain distance from the passage surface, and configured to irradiate the sample with a primary light through the window unit, a light collection unit disposed below the window unit and configured to collect a secondary light from the sample through the window unit, and an acquisition unit configured to acquire identification information for identifying a property of the sample based on the secondary light collected by the light collection unit.

A system for containing a sample for analysis by a spectrometer, comprising a sample receptacle unit with a well for containment of the sample, the well comprising a well inner wall and well floor, a floor aperture in the well floor, and comprising a first spectroscopy element, the first spectroscopy element spanning the opening of floor aperture, wherein the well further comprises a sealing material at the interface of the inner wall with the first spectroscopy element, wherein radiation is free to pass through the floor aperture to the first spectroscopy element.

A detection method uses a reaction vessel including a container including a housing part having a first opening opened at an upper portion and a second opening opened at a side portion, and a side wall member fixed to the container so that a capturing region on a metal film is exposed in the second opening. First, a liquid containing a specimen is provided to the housing part. Next, the liquid in the housing part is stirred to capture, into the capturing region, a substance to be detected in the liquid. Next, the metal film is irradiated with light so that surface plasmon resonance occurs in the metal film, and light emitted from the reaction vessel and having a light amount changing depending on the amount of the substance to be detected captured in the capturing region is detected. In the step of providing the liquid to the housing part, an amount of liquid in which the liquid is not in contact with the capturing region when the liquid in the housing part is left still, and the liquid is in contact with the capturing region when the liquid in the housing part is stirred is provided to the housing part.

An in situ near infrared sensing unit includes a housing allowing the sensing unit to be inserted in a variety of media. A transparent window is formed in the sidewall of the housing. A sensing element is mounted inside the housing. The sensing element is configured to emit near infrared light provided from a light source external to the housing, and the sensing element is configured to collect near infrared light transmitted through the transparent window. A mirror is mounted in the housing at an angle with respect to the transparent window and opposite the sensing element. The angle allows the mirror to reflect the near infrared light, emitted by the sensing element, through the transparent window.

A specimen chamber for transmitted light microscopy includes a chamber body having a specimen space that is sealed off in a transmitted light direction on opposite sides by transparent first and second observation windows, respectively, a seal being interposed in each case. First and second clamping elements are configured to fix the two observation windows to the specimen space. The clamping elements comprise observation openings into the specimen chamber. The first observation window comprises a first plane-parallel shoulder that protrudes into the first observation opening of the first clamping-element so as to fit exactly. The second observation window comprises a second plane-parallel shoulder that protrudes into the second observation opening of the second clamping element so as to fit exactly. The two seals are resistant to high pressure. The observation windows and the seals each consist of a plastomer.

A method, computer program product, and apparatus are provided for controlling components of a detection device. The device may detect turbidity of liquid with sensors such as a density sensor and/or nephelometric sensor. A light modulation pattern may reduce or eliminate interference in sensor readings. Readings may be performed during off cycles of an illumination light to reduce interference but to provide improved visibility of a tube. Dark and light sensor readings may be performed with an emitter respectively off or on to account for ambient light in subsequent readings. Readings from the density sensor and/or nephelometric sensor may be used to calculate McFarland values. The device may be zeroed based on an emitter level that results in a sensor reading satisfying a predetermined criterion.

A system of measuring hemoglobin and bilirubin parameters in a whole blood sample using optical absorbance. The system includes an optical-sample module, a spectrometer module, an optical fiber module optically connecting the optical-sample module to the spectrometer module, and a processor module. The optical-sample module has a light-emitting module having a LED light source, a cuvette and a calibrating-light module. The processor module receives and processes an electrical signal from the spectrometer module and transforms the electrical signal into an output signal useable for displaying and reporting hemoglobin parameter values and/or total bilirubin parameter values for the whole blood sample.

An exemplary method for measuring a refractive index of a substance being measured through an optical window, includes arranging the optical window in contact with the substance being measured, directing light to the interface of the optical window and substance being measured, where part of the light is absorbed by the substance being measured and part of it is reflected from the substance being measured to form an image, in which the location of the boundary of light and dark areas expresses a critical angle of the total reflection dependent on the refractive index of the substance being measured, and examining the formed image. Light is directed on a first structure and to desired angles on an interface between the optical window and substance being measured. Light reflected from the interface of the optical window and substance being measured is directed on a second structure.