Luminescence test measurements are conducted using an assay module having integrated electrodes with a reader apparatus adapted to receive assay modules, induce luminescence, preferably electrode induced luminescence, in the wells or assay regions of the assay modules and measure the induced luminescence.

The sample plate has a principal plane in which a plurality of wells is arranged. The sample plate has a plurality of through-holes each allowing a sampling needle to pass through in a region of the principal plane where the wells are not provided, and positions of the wells and positions of the through-holes are designed such that when two pieces of the sample plates are arranged up and down with a predetermined positional relationship in a state in which respective principal planes are arranged in parallel each other, the through-holes of the sample plate arranged on an upper side is arranged at positions directly above respective wells of the sample plate arranged on a lower side.

The technology described herein generally relates to systems for extracting polynucleotides from multiple samples, particularly from biological samples, and additionally to systems that subsequently amplify and detect the extracted polynucleotides. The technology more particularly relates to microfluidic systems that carry out PCR on multiple samples of nucleotides of interest within microfluidic channels, and detect those nucleotides.

The present disclosure relates to a cuvette box conveying device, a cuvette box conveying method, and a sample analyzer. The cuvette box conveying device includes a frame. The frame includes a new box placing position and a waste box recycling position. The new box placing position and the waste box recycling position are arranged on different layers in the direction of Z axis, so as to reduce the space occupied by the new box placing position and the waste box recycling position on an XY plane. In the cuvette box conveying device, the space occupied by the new box placing position and the waste box recycling position on the XY plane is reduced by arranging the new box placing position and the waste box recycling position on different layers in the direction of Z axis.

An instrument for processing a biological sample includes a chassis. Connected to the chassis is a tape path along which a tape with a matrix of wells can be automatically advanced through the instrument, a dispensing assembly for dispensing the biological sample and a reagent into the matrix of wells of the tape to form a biological sample and reagent mixture, a sealing assembly for sealing the biological sample and reagent mixture in the tape, and an amplification and detection assembly for detecting a signal from the biological sample and reagent mixture in the matrix of wells in the tape.

The technology described herein generally relates to systems for extracting polynucleotides from multiple samples, particularly from biological samples, and additionally to systems that subsequently amplify and detect the extracted polynucleotides. The technology more particularly relates to microfluidic systems that carry out PCR on multiple samples of nucleotides of interest within microfluidic channels, and detect those nucleotides.

A low temperature storage system, a transport mechanism, and a low temperature storage vessel are provided, which enable downsizing and simplification of the transport mechanism, as well as stable transport of stored objects. A low temperature storage system (1) includes a low temperature storage vessel (10) and a transport mechanism (20). The transport mechanism (20) includes a reciprocating part (30) that has a holding part (35) and that is capable of reciprocating along a transfer direction, and guide unit (40). The guide unit (40) include an in-vessel guide (50) fixedly placed inside the low temperature storage vessel (10), and a telescopic guide (60) configured to be able to extend and contract along the transfer direction. The telescopic guide (60) is provided independently of the in-vessel guide (50) so as to be connectable to the in-vessel guide (50).

An automated system and method for storing/retrieving vessel holders is presented. A first storage compartment comprises first storage sections. A first translating mechanism vertically translates one storage section to a loading level for loading holders into the first storage compartment and translates one storage section to a handing-in level for handing in holders to/from an analyzer. A second storage compartment comprises second storage sections. A second translating mechanism vertically translates one second storage sections to a handing-out level and translates one storage section to an unloading level for unloading holders from the second storage compartment. A first transport mechanism comprises a first conveyor for transporting holders from a first storage section at the handing-in level to a handing-over station. A second transport mechanism comprises a second conveyor for transporting holders from the handing-over station to a second storage section at the handing-out level. A controller operates the mechanisms.

A separating system (1) comprises a housing (60) sized to receive a stack of articles having at least one first article (12) stacked on top of a second article (10). The system (1) also includes a lifter (20) movable into a contact position adjacent a surface (13) on the at least one first article (12). The lifter (20) is adapted to apply a lifting force to the surface (13) to lift at least a portion of the first article (12) above the contact position. An extractor (40) moves the second article (10) away from the stack of articles after the at least one first article (12) has been lifted above the contact position by the lifter (20). The housing (60) prevents the at least one first article (12) from moving with the second article (10) when the second article (10) is moved by the extractor (40) and guides the stack of articles downward after the second article (10) is moved away.