In one embodiment, a biological sample analyzer has a housing having at least one outer wall that defines a cavity therein. A receptacle, which can support a consumable holder containing a biological sample, is disposed within the internal cavity. At least one heater applies heat to the receptacle when the consumable holder is supported by the receptacle. At least one heater sensor detect temperatures of the receptacle over time. A controller detects whether the consumable holder is below an ambient temperature based on a decrease in temperature of the receptacle when the consumable holder is inserted into the receptacle. The controller also increases an amount of thermal energy transferred from the at least one heater to the consumable holder when the controller detects that the consumable holder is below the ambient temperature so as to heat the consumable holder to a target temperature.

Provided is a new analysis device capable of heating an analysis chip and reducing the size thereof. The analysis device (1) of the present invention includes a set unit (15) for setting an analysis chip, an accommodation chamber to be accommodated in the set unit (15), a blower fan (19) that blows air to the set analysis chip, a heating unit (20) that heats the air to be blown, a drive unit (16) that rotates the analysis chip, and an analysis unit that analyzes the analysis chip, wherein the accommodation chamber becomes an analysis chamber for the analysis chip when the set unit (15) is stored therein, the analysis portion is disposed in a position where the analysis chip is analyzed when the set portion (15) is accommodated in the accommodation chamber, and in the accommodation chamber, the direction of the air blown by the blower fan (19) and the rotation direction of the analysis chip rotated by the drive unit (16) are opposite to each other, or the direction of the air blown by the blower fan (19) is perpendicular to the rotation direction of the analysis chip rotated by the drive unit (16) and is toward the analysis chip

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 device includes a sample rack having a mounting region for mounting a sample plate that holds a sample, a housing in which a temperature adjustment space for adjusting a temperature of the sample plate mounted on the sample rack while accommodating the sample rack inside is provided therein, and the housing having, in a lateral surface, a rack insertion opening through which the sample rack is inserted into the temperature adjustment space; and an air temperature adjustment part having an air intake port for taking in air in the temperature adjustment space, a temperature adjustment element for cooling or heating air taken in from the air intake portion, and an outlet for blowing out air cooled or heated by the temperature adjustment element.

Temperature adjustment with a pipette tip temperature adjustment unit (7) and a drive unit (54) for raising and lowering a pipette tip (51), an environment temperature sensor (10) for sensing temperature inside an analysis apparatus (1A), a pump (53) for drawing a liquid into pipette tip (51) and discharging liquid in the pipette tip (51), and a control unit (6a) for setting, in advance, temperature control target value during sample analysis for unit (7) based on environment temperature sensed by sensor (10), and during sample analysis, drive unit (54) lowers pipette tip (51), pump (53) performs pumping wherein intake and discharge are repeated in a state in which unit (7) blows air, and unit (6a) sets, in advance, the temperature value for use during sample analysis for the pipette tip temperature adjustment unit (7) on the basis of analysis reagent information and the environment temperature sensed by e sensor (10).

Methods and apparatus that enable drying and curing a plurality of specimens carried by a plurality of microscope slides. Slide carriers are positioned at a first position while the slide carrier holds the microscope slides. Each of the specimens can be carried by one of the microscope slides. The slide carrier can be robotically moved to move the slide carrier into a circulation loop defined by a heater apparatus. The specimens and/or microscope slides can be convectively heated while the slide carrier is located in the circulation loop.

An automatic analyzer which realizes stable reagent heating and high dispensing accuracy includes a thermostat bath for controlling a reagent or a reaction solution in reaction cells arranged on a circumference of a reaction disk to have a constant temperature; a first reagent dispensing mechanism dispenses a reagent into the reaction cells; a photometer detects transmitted light or scattered light in the reaction cell; and a disposable reaction container for allowing the sample and the reagent to mix and react with each other. The analyzer also includes a second reagent dispensing mechanism with a reagent heating function which dispenses the reagent into the disposable reaction container; a coagulation time detection section; a reaction container temperature control block; a reagent dispensing syringe which is connected to the second reagent dispensing mechanism; and a fluid temperature control mechanism which controls the temperature of an internal fluid of the reagent dispensing syringe.

Method and apparatus for thermal processing of nucleic acid in a thermal profile is provided. The method employs at least a first bath and a second bath, the method further employing a reactor holder for holding reactor(s) accommodating reaction material containing the nucleic acid. The method comprises maintaining bath mediums in the baths at two different temperatures; and alternately allowing the reactor(s) to be in the two baths in a plurality of thermal cycles to alternately attain a predetermined high target temperature THT, and a predetermined low target temperature TLT, wherein the bath medium in at least one of the baths is a high thermal conductivity powder.

Methods and apparatus that enable drying and curing a plurality of specimens carried by a plurality of microscope slides. Slide carriers are positioned at a first position while the slide carrier holds the microscope slides. Each of the specimens can be carried by one of the microscope slides. The slide carrier can be robotically moved to move the slide carrier into a circulation loop defined by a heater apparatus. The specimens and/or microscope slides can be convectively heated while the slide carrier is located in the circulation loop.

A method and an apparatus for thermal processing of nucleic acid in a thermal profile. The method employs at least a first bath and a second bath, the method further employing a reactor holder for holding reactor(s) accommodating reaction material containing the nucleic acid. The method includes maintaining bath mediums in the baths at two different temperatures; and alternately allowing the reactor(s) to be in the two baths in a plurality of thermal cycles to alternately attain a predetermined high target temperature T.sub.HT, and a predetermined low target temperature T.sub.LT, wherein the bath medium in at least one of the baths is a high thermal conductivity powder.