To provide a reagent cooler reduced in size as compared with that in the related art by reducing a thickness of a heat insulation material of the reagent cooler, and an automated analyzer including the reagent cooler. In the reagent cooler of the automated analyzer, a vacuum heat insulation material is disposed in a periphery (on a side surface, or/and upper and lower portions) of a cooling jacket of the reagent cooler. Then, an end portion of the vacuum heat insulation material is disposed at a position shifted from upper and lower end portions and a side surface end portion of the cooling jacket and a distance between the end portion of the vacuum heat insulation material and the cooling jacket is taken as much as possible.

The self-contained kit comprises methods for receiving and preparing the biological samples for the nucleic acid amplification and sensing the presence of the target assay. The kit consists of a self-heating pack to provide the heat for nucleic acid sample preparation and amplification processes. The change of the amplification is indicated through colorimetric or turbidity sensing and detected through a mobile phone camera and associated mobile application for photographic scanning of physical or chemical differences of the samples to produce the test results.

The self-contained kit comprises methods for receiving and preparing the biological samples for the nucleic acid amplification and sensing the presence of the target assay. The kit consists of a self-heating pack to provide the heat for nucleic acid sample preparation and amplification processes. The change of the amplification is indicated through colorimetric or turbidity sensing and detected through a mobile phone camera and associated mobile application for photographic scanning of physical or chemical differences of the samples to produce the test results.

The invention relates to a container system for transport of biological material comprising a container casing and an insulating device, wherein the container casing defines a container interior space for accommodation of the insulating device and for accommodation of biological material to be transported, and wherein the insulating device is constituted of at least two insulating portions, which are formed so as to surround the biological material inside the container interior space. The invention further relates to uses of such a container system for packaging and transport of biological material, as well as methods of packaging biological material for transport.

The invention relates to a container system for transport of biological material comprising a container casing and an insulating device, wherein the container casing defines a container interior space for accommodation of the insulating device and for accommodation of biological material to be transported, and wherein the insulating device is constituted of at least two insulating portions, which are formed so as to surround the biological material inside the container interior space. The invention further relates to uses of such a container system for packaging and transport of biological material, as well as methods of packaging biological material for transport.

The present disclosure relates to the field of liquid handling and dispensing systems in combination with additive manufacturing. In particular, it relates to temperature-controlled units, i.e. dispensing heads and source well holders, for receiving, holding and releasing liquid and semi-liquid material, liquid-handling and dispensing systems, apparatuses and methods for applying temperature-sensitive liquids. A temperature-controlled unit (1) comprises at least one Peltier element (3), each Peltier element having opposite first and second surfaces (4a, 4b). The unit (1) further comprises at least one cooling element (5). The at least one Peltier element (3) is arranged to have each respective first surface (4a) facing a reservoir block (2) of the unit (1). The at least one cooling element (5) is thermally connected to the Peltier element (3) and arranged to transfer heat generated by the at least one Peltier element (3) and dissipate the transferred heat away from the at least one Peltier element (3).

A portable temperature-controlled container for receiving and housing one or more handheld carriers, each handheld carrier configured to transfer samples to and from a temperature-controlled storage environment, the handheld carrier including a handle and a tray portion, the tray portion configured to be slid into a port of a rack or tower provided in the temperature-controlled storage environment in order to withdraw a sample located in the port, the portable temperature-controlled container including a housing having an opening forming an internal cavity configured to receive one or more handheld carriers, and a lid configured to substantially close the opening, where the housing includes a recess configured to receive the handle of the handheld carrier such that closing of the lid substantially seals the internal cavity when the one or more handheld carriers are placed in the housing.

Cryogenic devices are provided in which solid carbon dioxide (dry ice) is used to maintain a temperature zone in which samples can be manipulated under conditions in which the sample is maintained at a temperature below −50° C.

Cryogenic devices are provided in which solid carbon dioxide (dry ice) is used to maintain a temperature zone in which samples can be manipulated under conditions in which the sample is maintained at a temperature below −50° C.

The present invention relates to a heat preservation shell (4) for an analyzer. At least one liquid passage (402) for conveying the liquid is embedded in a shell wall of the heat preservation shell. The liquid passage (402) is embedded in the shell wall of the heat preservation shell (4), on one hand, the liquid transported or preserved in the liquid passage is subjected to the heat preservation function of the heat preservation shell, so that the liquid transported or preserved in the liquid passage (402) maintains the preset temperature, thereby avoiding the influence of the external environment temperature on the transported liquid; and on the other hand, the space of the shell wall of the heat preservation shell is effectively utilized, the situation that various liquid pipelines are intricately distributed inside or outside the heat preservation shell (4) is avoided, thereby increasing the space utilization rate.