An automated system for preparing, detecting and analyzing a first fluid sample containing biological species, the preparation, detection and analysis system including at least one fluidic cartridge that includes at least one fluidic concentration and lysis module and one fluidic detection module including an array of several amplification chambers arranged in parallel, an apparatus including a mechanical assembly comprising at least one movable rod fastened to the frame and comprising a free end arranged to cooperate with a flexible membrane of the fluidic concentration and lysis module, an optical measurement system for measuring fluorescence through one or more amplification chambers of the fluidic detection module of the cartridge, a control and processing unit.

Systems and methods for performing simultaneous nucleic acid amplification and detection. The systems and methods comprise methods for managing a plurality of protocols in conjunction with directing a sensor array across each of a plurality of reaction chambers. In certain embodiments, the protocols comprise thermocycling profiles and the methods may introduce offsets and duration extensions into the thermocycling profiles to achieve more efficient detection behavior.

An example system includes an array of retaining features in a microfluidic cavity, an array of thermally controlled releasing features, and a controller coupled to each releasing feature in the array of releasing feature. Each retaining feature in the array of retaining features is to position capsules at a predetermined location, the capsules having a thermally degradable shell enclosing a biological reagent therein. Each releasing feature in the array of releasing features corresponds to a retaining feature and is to selectively cause degradation of the shell of a capsule. Each releasing feature is to generate thermal energy to facilitate degradation of the shell. The controller is to selectively activate at least one releasing feature in the array of thermally controlled releasing features to release the biological reagent in the capsules positioned at the retaining feature corresponding to the activated releasing feature.

A reaction analysis system includes a first flow path through which a reaction fluid, obtained by mixing reactants in a mixer, flows, a second flow path through which the reaction fluid flows and that has higher heat exchange efficiency than the first flow path, a temperature measurer that measures a temperature distribution of the reaction fluid along the first flow path, and a reaction analysis device that specifies a reaction state of the reaction fluid based on a reaction parameter. The reaction parameter is obtained from the measured temperature distribution and indicates the reaction state of the reaction fluid.

The present invention generally concerns an automated system capable of performing quantitative PCR (qPCR) analysis of a nucleic acid present in a biological sample together with preparation of a sequencing-ready nucleic acid library from the sample, either simultaneously or sequentially. In a further aspect, the present invention also provides a method for performing qPCR of a nucleic acid present in a biological sample together with simultaneous of sequential preparation of a sequencing-ready nucleic acid library from the sample. Finally, the present invention also provides removable cartridges for use in the automated systems and methods according to the invention.

The present invention relates to a diagnostic cartridge for microfluidics and an on-site molecular diagnosis system including same, wherein an infuser, an extraction chamber, and an amplification chamber are arrayed vertically to minimize the flow path of a fluid, and thus the extraction, amplification and analysis results of a nucleic acid can be detected in real time.

Apparatus and methods for analyzing samples, including for example, samples containing nucleic acids, antibodies, and/or antigens are described. The apparatus may include a frame having a cartridge receiver, two optical devices, thermal cycler, lysis assembly, hybridization heater, and sample transfer assembly. In use, the apparatus may perform multiple sample preparation and analysis processes within the same disposable cartridge including, for example, performing a PCR assay and immunoassay in the same cartridge.

Systems, methods, and devices for discretizing and analyzing fluidic samples are provided. In one aspect, a microfluidic array for discretizing a fluidic sample comprises one or more flow channels and a plurality of fluidic compartments in fluidic communication with the one or more flow channels. In another aspect, a system for discretizing and analyzing fluidic samples comprises a rotor assembly shaped to receive a microfluidic device.

In one embodiment, a biological sample analyzer has a housing having at least one outer wall that defines a cavity therein. A receptacle, which can support a consumable holder containing a biological sample, is disposed within the cavity. At least one heater applies heat to the consumable holder when the consumable holder is supported by the receptacle. At least one heater sensor detects a temperature of the receptacle over time. A controller directs the at least one heater to apply an elevated temperature to the consumable holder and reduces an amount of heat applied to the consumable holder before the consumable holder exceeds a target temperature that is less than the elevated temperature. By applying the elevated temperature, the consumable holder can be heated quicker than if it where heated at only the target temperature.

In one embodiment, a biological sample analyzer has a housing having at least one outer wall that defines a cavity therein. A receptacle, which can support a consumable holder containing a biological sample, is disposed within the internal cavity. At least one heater applies heat to the receptacle when the consumable holder is supported by the receptacle. At least one heater sensor detect temperatures of the receptacle over time. A controller detects whether the consumable holder is below an ambient temperature based on a decrease in temperature of the receptacle when the consumable holder is inserted into the receptacle. The controller also increases an amount of thermal energy transferred from the at least one heater to the consumable holder when the controller detects that the consumable holder is below the ambient temperature so as to heat the consumable holder to a target temperature.