A nucleic acid analysis apparatus includes a casing, a main frame, a fluid delivery unit, a thermal unit, a driving unit, and at least one optical unit. The casing has an upper casing and a lower casing. The main frame is disposed in the lower casing and has a chamber for mounting a cartridge therein. The fluid delivery unit is adapted to transport reagents within the cartridge for sample purification and/or nucleic acid extraction. The thermal unit is adapted to provide a predefined temperature for nucleic acid amplification. The driving unit is disposed in the lower casing and connected with the main frame, and includes a motion control unit capable of pressing the cartridge during sample purification and/or nucleic acid extraction and rotating the cartridge with a predefined program during nucleic acid amplification and/or detection. The optical unit includes plural optical components for detection.

A nucleic acid analysis apparatus includes a casing, a main frame, a fluid delivery unit, a thermal unit, a driving unit, and at least one optical unit. The casing has an upper casing and a lower casing. The main frame is disposed in the lower casing and has a chamber for mounting a cartridge therein. The fluid delivery unit is adapted to transport reagents within the cartridge for sample purification and/or nucleic acid extraction. The thermal unit is adapted to provide a predefined temperature for nucleic acid amplification. The driving unit is disposed in the lower casing and connected with the main frame, and includes a motion control unit capable of pressing the cartridge during sample purification and/or nucleic acid extraction and rotating the cartridge with a predefined program during nucleic acid amplification and/or detection. The optical unit includes plural optical components for detection.

A tissue sample that has been removed from a subject can be properly fixed for evaluation using the disclosed transporter assembly for carrying a tissue sample and method for fixing an unfixed tissue sample. In one embodiment, the disclosed assembly includes a transport container, a fixative in the transport container, and a cooling device that reduces and/or maintains the temperature of the fixative to perform a pre-soaking process at a temperature of less than about 7° C. The pre-soaking process can, for example, be performed during sample transport or during extended periods of storage, such as over a weekend.

A tissue sample that has been removed from a subject can be properly fixed for evaluation using the disclosed transporter assembly for carrying a tissue sample and method for fixing an unfixed tissue sample. In one embodiment, the disclosed assembly includes a transport container, a fixative in the transport container, and a cooling device that reduces and/or maintains the temperature of the fixative to perform a pre-soaking process at a temperature of less than about 7° C. The pre-soaking process can, for example, be performed during sample transport or during extended periods of storage, such as over a weekend.

A container may include a storage volume configured to store a payload. A thermal insulation layer may surround the storage volume. A thermoregulation layer may surround the thermal insulation layer. There may be activation of a chemical reaction in the thermoregulation layer. The thermal insulation layer may have R-value per inch configured to expose the payload to a desired temperature to ensure viability of the payload and dampen a temperature spike of the chemical reaction. A system of containers may include a system storage volume with N containers in the system storage volume, wherein N is a whole number of 2 or more. A method of making an insulated container may include preparing an outer skin barrier layer, stacking a thermoregulation layer on the outer skin barrier layer, stacking a thermal insulation layer on the thermoregulation layer, and stacking an inner skin barrier layer on the thermal insulation layer.

Provided herein are apparatus for independently manipulating the temperature of a plurality of reaction vessels, e.g., for automated processing of nucleic acids present in the vessels. Printed circuit boards (PCBs) comprising a mount area arranged to have mounted thereon a through-hole thermoelectric device (TED) to facilitate independent temperature control of reaction vessels are also provided, as well as methods relating to the same.

Provided herein are apparatus for independently manipulating the temperature of a plurality of reaction vessels, e.g., for automated processing of nucleic acids present in the vessels. Printed circuit boards (PCBs) comprising a mount area arranged to have mounted thereon a through-hole thermoelectric device (TED) to facilitate independent temperature control of reaction vessels are also provided, as well as methods relating to the same.

A microfluidic chip assembly for rapidly performing digital polymerase chain reaction (PCR) and use thereof are provided. The microfluidic chip assembly includes at least one microfluidic chip, a heat sink arranged below the microfluidic chip, a heater arranged above the microfluidic chip, a semiconductor cooler arranged between the heat sink and the microfluidic chip, and a heat-conducting plate arranged above the semiconductor cooler. A thin film layer is bonded at the bottom of the microfluidic chip, and the thin film layer abuts against the heat-conducting plate.

An apparatus comprising a magnetic assembly and methods for operating the apparatus are provided. The magnetic assembly may be used to manipulate molecules in a liquid preparation, for example to isolate or separate the molecules from the liquid. The magnetic assembly may be used to wash and/or isolate nucleic acid molecules of interest from a liquid preparation.

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.