Embodiments described herein provide for a method and system for the inspection of fluids for defects. A plurality of containers with fluids disposed therein are inspected for defects in an inspection system. A timing sequence is used to control the timing of light pulses directed to the fluid residing in the plurality of containers. A high-resolution camera is utilized to obtain images of the fluid disposed in the plurality of containers. An illumination time of pulses of light in the inspection zone is less than an exposure time of each frame of a plurality of frames of the high-resolution camera. As such, the inspection system and method of utilizing the inspection system allows for high-resolution images of the fluid to be captured without smearing of the defects in the captured images.

A feeding system (2) for feeding disc-shaped objects such as sample cups (4) to an analyzer. The system (2) includes as infeed trade (22) angled downward from horizontal and the outfeed track (24) angled downward, plus a reject chute. The disc feeding system (2) uses two RFID readers/writers, one (32) a standalone desktop and a second (190) proximate the sample bay of the analyzer for more comprehensive track-and-trace capability. The information read from the cup (4) tag as it is scanned is also stored with the resultant spectra so that predictive processing is applied properly and without error. For post scan (after the sample scan is completed) the scan information itself may be written directly to the sample cup RFID tag including, reflection/transmission, characteristics, constituent results etc.

The automatic analysis device includes: a reagent tank that holds a reagent container that contains a reagent; and a lid opening/closing device including a lid opening/closing member configured to be movable in a first direction parallel to a vertical direction and a second direction perpendicular to the first direction. The lid opening/closing member having a first member for opening a lid of the reagent container and a second member for closing the lid and configured to be movable between a first position and a second position, the first position located above the reagent container and the second position located below the first position in the first direction such that the bottom surface of the lid opening/closing member comes into contact with the reagent container and configured to be movable between the second position and a third position that is away from the second position in the second direction.

The automatic analysis device includes: a reagent tank that holds a reagent container that contains a reagent; and a lid opening/closing device including a lid opening/closing member configured to be movable in a first direction parallel to a vertical direction and a second direction perpendicular to the first direction. The lid opening/closing member having a first member for opening a lid of the reagent container and a second member for closing the lid and configured to be movable between a first position and a second position, the first position located above the reagent container and the second position located below the first position in the first direction such that the bottom surface of the lid opening/closing member comes into contact with the reagent container and configured to be movable between the second position and a third position that is away from the second position in the second direction.

A plasmon resonance (PR) system, instrument, and/or device and configurations thereof for measuring molecular interactions is disclosed. In some embodiments, the PR system, instrument, and/or device is a localized surface plasmon resonance (LSPR) system, instrument, and/or device. In other embodiments, the PR system, instrument, and/or device is a surface plasmon resonance (SPR) system, instrument. The PR system, instrument, and/or device may include, for example, force feedback for reliable flow cell sealing, optical feedback for reliable flow cell sealing, local thermal control of an LSPR chip (e.g., a ring Peltier, a continuous Peltier), dual displacement pumps for constant flow delivery to a microfluidic device, a dual channel LSPR sensor, and any combinations thereof.

The present invention is to provide a diffracted light removal slit and an optical sample detection system including the same, in which diffracted light of excitation light can be reliably removed without affecting reflected light of the excitation light in a sample detection device utilizing the reflected light of the excitation light. A diffracted light removal slit is provided between a light source unit and an excitation light reflector in an optical sample detection system that emits excitation light from the light source unit and also performs predetermined measurement using reflected light of the excitation light reflected at the excitation light reflector. The diffracted light removal slit includes: a main portion provided in a direction substantially perpendicular to an optical path of the excitation light; and a sidewall portion extending from an end portion of the main portion and inclined toward an upstream side in an optical path direction of the excitation light.

This detection device has a holder and a heating unit. The holder holds a detection chip that has the following: a prism that has an incidence surface and a film-formation surface; a metal film formed on said film-formation surface; trapping bodies laid out on the surface of said metal film; and a substrate that is laid out on the surface of the metal film, and together with the metal film, forms a liquid collection section in which a liquid is collected. The heating unit heats at least one of the substrate, the prism, and the metal film either while in contact therewith or without contacting same. Also, the heating unit is positioned so as to avoid the path that excitation light takes from an excitation-light emission unit to the abovementioned incidence surface.

An instrument for determining thermal diffusivity of disc shaped opaque solid or quasi solid materials using a high intensity short duration flash of light from a single LED, a planar LED array, or laser diode source is disclosed. This instrument comprises an axially and radially indexed cylindrical sample holder able to accommodate a plurality of test samples and sequentially bring them into a designated testing position to expose one face of each sample to the flash of light while the obverse face of the disc is observed by a temperature measuring device, for the purpose of recording the attendant thermal excursion. An improved calculating method, based on empirical data observed during each test, is used for calculating thermal diffusivity.

An instrument for determining thermal diffusivity of disc shaped opaque solid or quasi solid materials using a high intensity short duration flash of light from a single LED, a planar LED array, or laser diode source is disclosed. This instrument comprises an axially and radially indexed cylindrical sample holder able to accommodate a plurality of test samples and sequentially bring them into a designated testing position to expose one face of each sample to the flash of light while the obverse face of the disc is observed by a temperature measuring device, for the purpose of recording the attendant thermal excursion. An improved calculating method, based on empirical data observed during each test, is used for calculating thermal diffusivity.

A quality check module for characterizing a specimen and/or a specimen container. The quality check module includes an imaging location within the quality check module configured to receive a specimen container containing a specimen, one or more cameras located at one or more viewpoints adjacent to the imaging location, and one or more spectrally-switchable light source including a light panel assembly located adjacent the imaging location and configured to provide lighting for the one or more cameras, the spectrally-switchable light source configured to be operatively switchable between multiple different spectra. Methods of imaging a specimen and/or specimen container and specimen, and specimen testing apparatus including a quality check module adapted to carry out the method are described herein, as are other aspects.