The present invention relates to a measurement device including a trace sample-use high sensitivity light absorbing cell, the device comprising: a light absorbing cell containing a capillary tube of which both ends are open hollow shaped; a light absorbing cell mounting block on which one end of the light absorbing cell is mounted, and which comprises a light emitting unit, disposed on the upper portion of the light absorbing cell, for irradiating light to one end of the light absorbing cell; and a light receiving block which comprises a light metering immersion unit disposed in such a manner that the other end of the light absorbing cell is immersed in a sample contained therein, and which detects light that is irradiated to one end of the light absorbing cell and emitted to the other end thereof.

A multipass cell assembly for monitoring of fluid is described, as well as fluid processing systems utilizing same, and associated methods of use of such multipass cell assembly for fluid monitoring. The multipass cell assembly is usefully employed in fluid processing operations such as monitoring of vapor deposition process reactants, e.g., reactants used for vapor deposition metallization of tungsten from a tungsten carbonyl precursor.

Tissue sample cassettes for receiving tissue samples include an upper tray including compartments separated by dividers, a lower tray coupled to the upper tray and having a central recess, and an absorbent material located in the recess of the lower tray. Related systems and methods for automated gross processing of tissue samples are also disclosed.

Tissue sample cassettes for receiving tissue samples include an upper tray including compartments separated by dividers, a lower tray coupled to the upper tray and having a central recess, and an absorbent material located in the recess of the lower tray. Related systems and methods for automated gross processing of tissue samples are also disclosed.

The present disclosure relates to a lid for a microtiter plate, which has a plurality of cavities arranged on a top of the microtiter plate and serve for receiving samples, wherein the lid is securable on the microtiter plate such that it covers of the microtiter plate. The lid has a basic body, which is embodied such that at least in regions, which are located above the cavities when the lid is on the microtiter plate, it is transmissive for light of predeterminable wavelength, and wherein the lid includes at least one closure element, which is embodied and/or arranged in such a manner that it closes at least one of the cavities in the microtiter plate when the lid is on the microtiter plate.

The present invention relates to a device (10) for use in fluid sample analysis. It is described to position (310) a top part (20) of the device (10) adjacent to a base part (30) of the device so as to define a fluidic receiving region in between, the top part being provided with a through opening fluidly connected to the fluidic receiving region, and the bottom part being provided with a radiation window adjacent to the fluidic receiving region. A fluidic sample is supplied (320) through the opening (24). The fluidic sample is moved laterally (330) in the fluid receiving region without the use of an intermediary membrane between the top part and the base part. A radiation is emitted (340) to the fluid receiving region. A radiation is detected (350) that is reflected by the device. A presence of the fluidic sample is determined (360) on the basis of a measured reflectance value based on the detected radiation.

The present disclosure describes a method and apparatus of measuring dynamic light scattering of a sample. In an embodiment, the apparatus includes a platen, a light source underneath the platen and configured to emit emitted light through the platen and into the sample, collector optics underneath the platen and configured to capture scattered light, and an optical absorber configured to be in contact with the sample, configured to absorb transmitted light, and configured to redirect reflected light away from the collector optics. In an embodiment, the method includes depositing a sample on a platen, emitting emitted light from a light source underneath the platen through the platen and into the sample, capturing via collector optics underneath the platen scattered light, contacting the sample with an optical absorber, absorbing via the absorber transmitted light, and redirecting via the absorber reflected light away from the collector optics.

A rectangular cell is a bottomed rectangular cell mounted in a photometric analyzer, and has an opening at a top end face for accommodating a test sample to be analyzed. The rectangular cell has a low flat area that is lower than an upper flat area on an inner face on a lower side of an outer face of a wall surface through which a measurement light from the analyzer is transmitted when the rectangular cell is mounted in the analyzer. This low area extends substantially over the entire width in the horizontal direction. When the rectangular cell is mounted in a recess in the photometric analyzer, an area through which the measurement light passes in the rectangular cell is not damaged by dust, even if fine hard dust adheres to the side surface of the recess. Further, the low region can have a mirror-finished surface by polishing.

The biometric system comprises: a measurement cartridge; and a meter, equipped with the measurement cartridge, for measuring an analyte present in a sample of the measurement cartridge. The measurement cartridge comprises a reagent container, a capillary module, and a reagent rod. The reagent container receives a liquid reagent and has a top sealed with a sealing film. The capillary module comprises a capillary tube which is located on an upper side of the reagent container and collects the sample by a capillary phenomenon, and the capillary tube is introduced into the reagent container by rupturing a contact portion to the sealing film by an applied pressure.

The biometric system comprises: a measurement cartridge; and a meter, equipped with the measurement cartridge, for measuring an analyte present in a sample of the measurement cartridge. The measurement cartridge comprises a reagent container, a capillary module, and a reagent rod. The reagent container receives a liquid reagent and has a top sealed with a sealing film. The capillary module comprises a capillary tube which is located on an upper side of the reagent container and collects the sample by a capillary phenomenon, and the capillary tube is introduced into the reagent container by rupturing a contact portion to the sealing film by an applied pressure.