A system (1) for infectious disease screening. The system is for use with an assay device (2) which incorporates an ultrasonic transducer for generating ultrasonic waves to lyse cells in a biological sample. The system (1) comprises a frequency control module which is configured to control the ultrasonic transducer (49) to oscillate at an optimum frequency for cell lysis, a PCR arrangement (16) which is configured to receive and amplify the DNA from the sample; and a detection arrangement (70) which is configured to detect the presence of an infectious disease in the amplified DNA and to provide an output which is indicative of whether or not the detection arrangement (70) detects the presence of an infectious disease in the amplified DNA.

A cap that is securable to a vial includes a plug configured for insertion into an open end of the vial. An upper portion of the cap defines a probe recess with an open top end and configured to receive a distal end of a probe of a pipettor inserted into the open top end, to frictionally secure the cap to an end of the probe. The cap includes a radially-oriented annular surface with one or more locking members depending from a periphery of the annular surface. The locking members are spaced from the plug and each locking member includes a radial locking groove and a radial locking ridge beneath the radial locking groove. A lip of the vial snaps into the radial locking groove above the radial locking ridge to secure the cap to the vial when the plug is inserted into the open end of the vial.

A thermal cycling method and associated device is described. The method is for carrying out a polymerase chain reaction (PCR) process to amplify deoxyribonucleic acid (DNA), and the method includes: pre-heating a series of blocks to respective temperatures that correspond to different respective heating stages in a PCR process, in which each block of the series of blocks defines a respective heat transfer surface, in which the series of blocks define a sequence of positions along a path, with each position defined by a respective heat transfer surface of a respective block; and moving a PCR reaction vessel, which contains deoxyribonucleic acid (DNA) and PCR reagents, along the path into and out of each respective position in the sequence of positions according to a schedule, in which, at each respective position the PCR reaction vessel is in thermal contact with the respective heat transfer surface to equilibrate a temperature of the PCR reaction vessel to a target temperature that corresponds to a respective heating stage in the PCR process.

Methods, devices, and kits are provided for performing PCR in <20 seconds per cycle, with improved efficiency and yield.

A processing module is configured to extend the capabilities of an analyzer configured to process substances within each of a plurality of receptacles. The module includes a container transport configured to transport a container from a location within the processing module to a location within the analyzer that is accessible to a substance transfer device of the analyzer. A receptacle distribution system is configured to receive a receptacle from the analyzer, transfer the receptacle into the processing module, and to move the receptacle between different locations within the analyzer. A substance transfer device of the module is configured to dispense substances into or remove substances from the receptacle within the processing module. A reagent card exchanger provides an input device for inserting reagent cards into and removing reagent cards from the module, stores reagent cards within the module, and transfers reagent cards to different location within the module.

Described is a polymerase chain reaction (PCR) device including a PCR thermal block including a first substrate and heating units, a PCR chip including a second substrate and reaction chambers, and an unidirectional sliding driver for sliding the PCR chip relative to the PCR thermal block while maintaining a contact between the second substrate of the PCR chip and the first substrate of the PCR thermal block. The first and second heaters of each of the plurality of heating units are spaced apart from each other along a sliding direction, and the unidirectional sliding driver causes any reaction chamber in the PCR chip to have a sequential thermal contact from a heater of the plurality of heating units mounted at one end of the PCR thermal block to a heater of the plurality of heating units mounted at another end of the PCR thermal block.

A dispensing system (1) comprising a material cartridge (2) provided with a nozzle (3), a temperature-regulating unit (4) provided with a nozzle temperature-regulating zone (5) arranged to regulate the temperature of the material cartridge nozzle (3) when the material cartridge nozzle (3) is arranged within the nozzle temperature-regulating zone (5), and a positioning unit (6) arranged for movement of the material cartridge (2) and the nozzle temperature-regulating zone (5) relative to each other between a first position (A) and a second position (B). In the first position (A) the material cartridge nozzle (3) is arranged within the nozzle temperature-regulating zone (5), and in the second position (B) at least a leading end portion (3a) of the material cartridge nozzle (3) is arranged outside the nozzle temperature-regulating zone (5).

A consistent and repeatable thawing method of frozen samples in a bag-format storage vessel is described herein. Methods and systems may allow for multiple bag-format storage vessel sizes to be used in the same device. A subset of a plurality of sensors may be qualified for the thawing method. The method may further include heating a frozen sample using a first heater bank and a second heater bank. In addition, the method may include measuring a plurality of second temperatures of the bag-format vessel. At or slightly after a second threshold temperature, the method may include heating using the first heater bank and terminating heating using the second heater bank. The method may include terminating the heating of the partially thawed sample using the first heater bank after the partially thawed sample has been heated using the first heater bank for a duration.

A diagnostic system is configured to perform first and second, different nucleic acid amplification reactions. The system includes a bulk reagent container compartment configured to store first bulk reagent container containing a first bulk reagent for performing sample preparation processes with a first subset and a second subset of a plurality of samples and a second bulk reagent container containing a second bulk reagent for performing the first nucleic acid amplification reaction. The system includes a unit-dose reagent compartment storing a unit-dose reagent pack including unit-dose reagents for performing the second nucleic acid amplification reaction. The system is configured to perform the sample preparation process using the first bulk reagent on the first and second subsets of the samples, perform the first nucleic acid amplification reaction using the second bulk reagent on the first subset of the samples, and perform the second nucleic acid amplification reaction using the unit-dose reagents on the second subset of the samples.

Methods and systems for thermally controlling a chemical reaction in droplets. In an exemplary method, a first thermal zone and a second thermal zone having different temperatures from one another may be created in a reaction chamber. An emulsion including droplets encapsulated by a carrier fluid may be held in the reaction chamber. The droplets may have a density mismatch with the carrier fluid, and each droplet may include one or more reactants for the chemical reaction. An orientation of the reaction chamber may be changed to move the droplets from the first thermal zone to the second thermal zone, such that a rate of the chemical reaction changes in at least a subset of the droplets.