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 having 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 having a bottom, and an intermediate portion located between the upper portion and the lower portion, the intermediate portion having 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.

An automated in situ heat induced antigen recovery and staining method and apparatus for treating a plurality of microscope slides. The process of heat induced antigen recovery and the process of staining the biological sample on the microscope slide are conducted in the same apparatus, wherein the microscope slides do not need to be physically removed from one apparatus to another. Each treatment step occurs within the same reaction compartment. The reaction conditions of each reaction compartment for treating a slide can preferably be controlled independently, including the individualized application of reagents to each slide and the individualized treatment of each slide.

A microscope slide staining system has a chamber, a plurality of slide support elements, a plurality of spreading devices positionable in association with microscope slides supported on the slide support elements so the spreading devices define a gap between the spreading device and the microscope slide and so the spreading device and the microscope slide are movable relative to one another to spread at least one reagent on the microscope slide independent of the other spreading devices and microscope slides.

The invention provides a small-sized automatic analyzer being compact, enabling a large number of analysis items to be carried out, and having a high processing speed. The automatic analyzer is particularly suitably applied to a medical analyzer used for qualitative/quantitative analysis of living body samples, such as urine and blood. A plurality of sample dispensing mechanism s capable of being operated independently of each other are provided to suck a sample from any one of a plurality of sample suction positions and to discharge the sucked sample to any one of a plurality of positions on a reaction disk. The automatic analyzer having a high processing capability can be thus realized without increasing the system size.

An automated in situ heat induced antigen recovery and staining method and apparatus for treating a plurality of microscope slides. The process of heat induced antigen recovery and the process of staining the biological sample on the microscope slide are conducted in the same apparatus, wherein the microscope slides do not need to be physically removed from one apparatus to another. The reaction conditions for treating a slide can preferably be controlled independently, including the individualized application of reagents to each slide and the individualized treatment of each slide.

An apparatus for spreading at least one reagent on at least a portion of a microscope slide includes a spreading device positionable in association with a microscope slide in a way that the spreading device defines a gap between the spreading device and the microscope slide and in a way that the spreading device and the microscope slide are movable relative to one another to spread at least one reagent on at least a portion of the microscope. The spreading device has a reservoir in which the at least one reagent is stored in a way that the at least one reagent is dischargeable from the reservoir onto the microscope slide when the spreading device is positioned in association with the microscope slide.

The automatic analyzer includes a sample storage section for accommodating a plurality of samples, a reagent storage section for accommodating a plurality of reagents, an analysis section for carrying out an analysis by reacting the sample with the reagent, a display, a storage section for storing a setting of an operation item to be automatically executed, which is effective only at restarting, and a control section which displays a screen for setting the operation item to be automatically executed upon acceptance of power shutdown operation by an operator during the analysis on the display to accept the setting from the operator, and automatically executes or omits execution of the operation item to be automatically executed, which has been set by the operator in accordance with the setting read from the storage section at the restarting.

A microscope slide staining system has a chamber, a plurality of slide support elements, a plurality of spreading devices positionable in association with microscope slides supported on the slide support elements so the spreading devices define a gap between the spreading device and the microscope slide and so the spreading device and the microscope slide are movable relative to one another to spread at least one reagent on the microscope slide independent of the other spreading devices and microscope slides.

An apparatus for spreading at least one reagent on at least a portion of a microscope slide includes a spreading device positionable in association with a microscope slide in a way that the spreading device defines a gap between the spreading device and the microscope slide and in a way that the spreading device and the microscope slide are movable relative to one another to spread at least one reagent on at least a portion of the microscope. The spreading device has a reservoir in which the at least one reagent is stored in a way that the at least one reagent is dischargeable from the reservoir onto the microscope slide when the spreading device is positioned in association with the microscope slide.

An analyzing device includes a rotation axis, and a separating cavity having first, second and third sidewalls. The first sidewall connects the second and the third sidewalls, and the second sidewall extends from a position connecting the first sidewall and the second sidewall toward the rotation axis. The third sidewall has a first end and a second end, with the first end located closer to the rotation axis than the second end. The analyzing device further includes a measurement channel configured to allow a sample liquid to be filled therein by a capillary force and having a capacity of a first predetermined amount.