The present invention relates to the field of biological sample testing technology, and in particular, to a biological sample reaction vessel. A reagent storage portion and a push rod movable relative to the reagent storage portion are packaged in the reaction vessel; the reagent storage portion comprises at least one reagent containing cavity, and the reagent containing cavity is sealed by a sealing element; and the push rod is connected to the sealing element, and the push rod is used for cooperation with an external device to separate the sealing element from the reagent storage portion. In this application, the reagent storage portion and the push rod are both packaged in the biological sample reaction vessel, and in reaction, the biological sample reaction vessel only needs to cooperate with a test cassette. With one operation, that is, inserting the biological sample reaction vessel into the external device, the reagent in the reagent storage portion can be released rapidly.

When taking in outside air with a fan to control the temperature inside a covered portion where a specimen is installed, the internal temperature may change depending on an environment temperature to cause a difference in temperature control. The wind generated by the fan may blow against a reaction container depending on its loading position and it may influence the temperature control over individual specimens and lead to problems with temperature accuracy, temperature rise speed, and temperature drop speed. A reaction container avoiding these problems has a covered portion which performs temperature control on the reaction container and in which a cover and a fin cover have a heat insulating structure. A heat source is provided for controlling an internal temperature of an internal covered space. The internal temperature is kept constant and the influence of the environment temperature over the temperature control of the reaction container is minimized.

A disposable fluidic cartridge has a recess therein. A mechanically-actuated mechanism is disposed within the recess for effecting an operation of the fluidic cartridge. The cartridge further comprises a machine-readable identification code on a breakable label covering at least a portion of the recess such that the portion of the breakable label covering the recess may be broken upon insertion of a mechanical actuator into the recess to actuate the mechanically-actuated mechanism. This renders the identification code unreadable and prevents reuse of the cartridge.

Devices, systems and methods for making and handling liquid samples are disclosed.

An insulated chamber having an interior chamber for storing items therein includes a phase change material to facilitate controlling the temperature of the interior chamber and the items. A heating device or cooling device may be used to melt or freeze the phase change material, which may be in various locations such as the walls of the chamber or packets which may serve as shelves and may be removable from the interior chamber with the items thereon. The packets may have recesses for receiving the items. The phase change material may be within capsules which may be within a liquid or a solid matrix. Controls may be provided to control humidity and carbon dioxide within the interior chamber.

Systems and methods for air cooling a microfluidic device using confinement channels to isolate cooling air from exposed liquids are disclosed. The systems and methods may also thermally condition the cooling airflow for improved robustness of the microfluidic device. In one embodiment, the air cooling system includes a split-level cooling manifold including an inlet duct that directs cooling air to a microfluidic device and an outlet duct that directs air heated by the microfluidic device away from the microfluidic device. The temperature of cooling air may be measured. The cooling air may be preheated to a temperature that is higher than an expected ambient temperature. The temperature of the cooling air after being heated by a microfluidic device may be measured.

A disposable fluidic cartridge has a recess therein. A mechanically-actuated mechanism is disposed within the recess for effecting an operation of the fluidic cartridge. The cartridge further comprises a machine-readable identification code on a breakable label covering at least a portion of the recess such that the portion of the breakable label covering the recess may be broken upon insertion of a mechanical actuator into the recess to actuate the mechanically-actuated mechanism. This renders the identification code unreadable and prevents reuse of the cartridge.

Ingestible devices configured to obtain samples when present in the GI tract of a subject, as well as related systems and methods, are disclosed. Sampling systems that include an absorbent material a preservative, such as an analyte preservative, as well as related materials and methods, are also disclosed.

Sampling systems that include an absorbent material a preservative, such as an analyte preservative, as well as related materials and methods, are disclosed.

A microfabricated thermal platform can be formed over a substrate, such as a silicon wafer, that may form part of the platform. The substrate is coated in a thermally-insulating material, which may be an organic polymer such, as polyimide or SUS. The surface of the thermally-insulating material may include an arrangement of one or more thermal sites, with each site having a reaction plate (or thermal plate) over which chemical reactions may occur. A heating element may be positioned beneath each reaction plate. A fluidic medium, such as a liquid or a gas, may be disposed over the thermal sites. One application is in chemical and biological reactions. In such reactions, the fluidic medium may be an aqueous solution which comprises reagents for those reactions. The fluidic medium may be an ionically conducting fluid, organic solution or a gas. Precise temperature control enables the correct reactions.