Provide is a blood collection container capable of suppressing the occurrence of blood clots involving bubbles when blood containing heparin is coagulated, and capable of suppressing the production of fibrin in serum after separation when blood containing heparin is separated into serum and blood clots. A blood collection container according to the present invention includes: a blood collection container main body having an opening at one end thereof and a closed bottom at the other end thereof; a serine protease disposed in the blood collection container main body; and a heparin neutralizing agent disposed in the blood collection container main body, wherein when a region in which the serine protease is disposed is defined as a first region, and a region in which the heparin neutralizing agent is disposed is defined as a second region, the second region includes a region present on an other end side with respect to an end on the other end side of the first region.

The present invention relates to a sensor assembly (1) for body fluids. The sensor assembly (1) comprises: a measurement chamber (2) extending in an axial direction from an inlet end (3) to an outlet end (4), the measurement chamber having a transverse cross-section with side walls (5, 6) defining a chamber width in a horizontal direction, and with top and bottom walls (8, 7) defining a chamber height in a vertical direction, each of the side walls (5, 6), top wall (8) and bottom wall (7) having a respective wall wettability for aqueous solutions; a first sensor (10a-h) adapted to measure a first parameter of body fluids, the first sensor (10 a-h) having a first sensor surface (11a-h) exposed to the inside of the measurement chamber at a first axial position, the first sensor surface (11a-h) having a first wettability for aqueous solutions; and a second sensor (20) adapted to measure a second parameter of body fluids, the second sensor (20) having a second sensor surface (21) exposed to the inside of the measurement chamber (2) at a second axial position upstream or downstream from the first axial position, the second sensor surface (21) having a second wettability for aqueous solutions higher than the first wettability. At the second axial position, the chamber width exceeds the width of the second sensor surface (21), and the measurement chamber has a widening (22) in a horizontal direction as compared to the first axial position.

A test specimen for detecting or determining a spatial distribution of microbes, the test specimen having measuring surfaces and a plurality of microbe collecting elements on each of the measuring surfaces. The invention also relates to a test chamber with such a test specimen, to an associated use and to an associated method.

The invention is related to a device (1) for receiving a biological sample (3) wherein the device (1) comprises a plurality of wells (10) wherein each well (10) comprises an inner surface (14) facing a volume (60) for receiving a biological sample (3). The inner surface (14) comprises a top section (20) and a bottom section (30). The top section (20) and the bottom section (30) are connected via a circumferential step (40). The circumferential step (40) forms a stop for a tip of a pipette (70).

Provided is a cell isolation instrument capable of smoothly performing a plurality of steps associated with isolation of cells, including gripping of a biological tissue, transferring of the biological tissue, and isolating of the biological tissue. A container has an opening. A sealing member seals the opening. A pair of pinching parts is connected to the sealing member, and the pair of pinching parts opens or closes by being pressed.

In a state where an operator performs operation using a safety cabinet while confirming standard operating procedures and sample data, a display device such as a monitor screen provided in the safety cabinet is arranged at a position that is not subject to effects of deterioration due to diffused reflection of light from a fluorescent lamp or sterilization lamp irradiation, and that does not generate resistance in an airflow path, while also protecting the display device from decontamination operation and preventing dirt from being adhered to a portion related to display. Transparent windows are provided on both a portion of a back wall or a side wall of a work space in the safety cabinet and a portion of a rear wall or a side wall of the body of the safety cabinet separated from the back wall or the side wall of the work space by a circulation flow path, which allow the operator to see through both walls, and the display device is placed on an outer side portion of the transparent window provided at the portion of the rear wall or the side wall of the body of the safety cabinet.

There is provided a well plate including a plate and a well which is opened in an upper surface of the plate, wherein the well includes a flat bottom surface part and a circumferential wall part rising upward from the circumferential edge of the bottom surface part; the circumferential wall part has a stepped part in the circumferential direction at an arbitrary height position; an upper circumferential wall part, which is located above the stepped part in the circumferential wall part, is larger in a cross sectional area than a lower circumferential wall part located below; and the stepped part indicates the lower limit of the liquid level height of a liquid sample contained in the well.

Disclosed is a detection apparatus that transfers magnetic particles through a plurality of chambers in a cartridge which includes the plurality of chambers and a channel connecting between the plurality of chambers, and that causes the magnetic particles to carry a complex of a test substance and a labelling substance, to detect the test substance on the basis of the labelling substance in the complex. The detection apparatus includes: a rotation mechanism configured to rotate the cartridge about a rotation shaft; a magnet configured to collect the magnetic particles in the chambers; a movement mechanism configured to move the magnet in a direction different from a circumferential direction of a circle in which the rotation shaft is centered; a detector configured to detect the test substance; and a controller programmed to control the rotation mechanism and the movement mechanism so as to transfer the magnetic particles from one of the chambers to another one of the chambers.

A method for processing particles contained in a liquid biological sample is presented. The method uses a rotatable vessel for processing particles contained in a liquid biological sample. The rotatable vessel has a longitudinal axis about which the vessel is rotatable, an upper portion comprising a top opening for receiving the liquid comprising the particles, a lower portion for holding the liquid while the rotatable vessel is resting, the lower portion comprising a bottom, and an intermediate portion located between the upper portion and the lower portion, the intermediate portion comprising a lateral collection chamber for holding the liquid while the rotatable vessel is rotating. The method employs dedicated acceleration and deceleration profiles for sedimentation and re-suspension of the particles of interest.

Provided are an automated analyzer for analyzing a substance contained in an unknown sample and a liquid reservoir, the analyzer and the reservoir being capable of saving users' operation without remarkably increasing the number of components. A flow path outlet of an overflow portion of the liquid reservoirs projects closer to the inner circumferential side of a drain flow path than to an inner circumferential surface side of an outer wall of the drain flow path serving as a destination to which liquid overflows. In addition, the flow path outlet projects so as to come into contact with an outer wall of the inner pipe. The flow path outlet of the overflow portion projects into the drain flow path so as to be located below an upper end of the outer wall of the drain flow path.