Aspects of the present disclosure are directed to, for example, an optical measurement unit for obtaining measurement signals from liquid media which are present in cuvettes lined up next to one another. In one embodiment, the optical measurement unit includes a light-supplying unit for emitting an inlet radiation into the cuvettes, and a detection unit for detecting a measurement radiation exiting from the cuvettes and for converting the measurement radiation into an electrical measurement signal. In such an embodiment, the light-supplying unit has a plurality of LED light sources which emit in a spectrally different manner in the UV/VIS/NIR wavelength range, and wherein the detection unit includes at least one photodiode fixedly assigned to each cuvette of a cuvette array.

An optical milk measuring arrangement operative during a milking operation, and including an optical measuring device for measuring optical properties of milk in a measuring region, in which at least part of the milk fed to the measuring arrangement collects. The measuring arrangement includes a main channel and a measuring channel, and these channels are in fluid communication with one another in a region of a common inlet and a common outlet, and the measuring channel has a lower flow velocity than a flow velocity in the main channel.

A blood sample collector can be used to collect a blood sample from a subject. The blood sample collector can be placed in a receptacle of a spectrometer to measure spectral data from the blood sample while the blood sample separates. The container may comprise a window to allow light such as infrared light to pass through the container, with the blood sample at least partially separating within the container between spectral measurements, which can provide improved accuracy of the measurements and additional information regarding the sample. The container may comprise an elongate axis and the container configured for placement in the spectrometer receptacle with the elongate axis extending toward a vertical direction in order to improve gravimetric separation of the blood sample. The spectrometer can be configured to measure the blood sample at a plurality of heights along the sample as the sample separates.

Described herein is a receptacle for holding a sample under spectrophotometer analysis comprising: a body, first and second opposing windows separated by a gap to provide a volume for a sample, wherein at least the first opposing window is supported by a first compliant member, and wherein under a force, the first compliant member allows positioning of the first opposing window relative to a first datum to set a desired: a) gap between the first and second opposing windows, and/or b) relative orientation of the first and second opposing windows.

A device for holding samples to be analyzed using the infrared transmission spectroscopy comprised of three or more infrared transparent windows that creates unparalleled gaps while maintaining a consistent path length, which eliminates interference fringes and ensures that quantitative analysis can be achieved. The present invention allows the use of high refractive index material, silicon, as window material. The device using silicon windows can serve both purposes of sample storage and infrared measuring cell. All-purpose disposable sample holders are now possible. In one embodiment, a pre-assembled sample holder is most suitable for loading and analyzing flowable liquid samples. In another embodiment, a sample holder can be easily assembled after high-viscosity fluids and deformable solid samples are loaded. In an alternative embodiment, the device comprised of two or more infrared transparent windows and a reflective mirror can be used for quantitative analysis using transflection infrared spectroscopy.

Described herein is a receptacle for holding a sample under spectrophotometer analysis comprising: a body, first and second opposing windows separated by a gap to provide a volume for a sample, wherein at least the first opposing window is supported by a first compliant member, and wherein under a force, the first compliant member allows positioning of the first opposing window relative to a first datum to set a desired: a) gap between the first and second opposing windows, and/or b) relative orientation of the first and second opposing windows.

A method and apparatus are disclosed which enable the reduction of sample carryover in the measurement cell of an analytical instrument. A sample cell is defined as a region sealed within a first o-ring. Located outside of said sample region is another o-ring which seals and defines a seal wash region as the region between the first and second o-ring. After the fluid sample is injected into the measurement cell a pressure is applied to the seal wash region, forcing the first o-ring to the innermost extent of the groove in which it sits, expelling any trapped solvent and removing from the measurement cell a significant dead volume while the cell is flushed and prepared for a new sample and corresponding measurement.

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 apparatus for the real time evaluation of in vivo tissue ablation is provided. The apparatus comprises a Near Infrared illumination source that delivers light to one side of a windowed flow-thru cuvette and exit to a Fourier-Transform Infrared [FTIR] spectrometer opposite the light source. The light traversal is via fiberoptic cables. While surgical smoke traverses the cuvette, the smoke is subjected to continuous FTIR sampling and those samples are compared in real time to a database of known cancer, necrotic or diseased tissue spectrums, utilizing Artificial Intelligence [AI] software. The apparatus in real-time indicates to the surgeon weather the ablation smoke contains cancerous or normal tissue via LED's, sounds, or tactile indicators.

An apparatus includes an emitter comprising an ultraviolet light emitting diode (UV-LED) disposed on a first end of an optical cuvette. An extraction cuvette may hold a liquid having a positive Langelier saturation index (LSI), and having a quantity of ozone gas dissolved therein. Air may be bubbled through the liquid in the extraction cuvette, and may then be directed to the optical cuvette. A detector comprising an ultraviolet light sensor (UV sensor) can be disposed on a second end of the optical cuvette. The UV-LED may be a point source, and the emitter may generate a parallel beam of light. A concentration of ozone in the gas in the optical cuvette can be determined based on a diminution of the UV light beam passing therethrough. This concentration can then be used to determine an ozone concentration in the liquid contained in the extraction cuvette.