An apparatus for preparing samples for chemical analysis includes a container receptacle for receiving a sample container having a crucible portion and an expansion portion. The container receptacle includes a heating compartment and a cooling compartment spaced apart from the heating compartment. The heating compartment is shaped to receive the crucible portion of the sample container, and the cooling compartment is shaped to receive the expansion portion of the sample container. The apparatus also includes a heating mechanism for heating the sample within the crucible portion of the sample container, a first cooling mechanism for cooling the expansion portion of the sample container, and a second cooling mechanism for cooling the crucible portion of the sample container.

In one embodiment, a diagnostic system includes an instrument coupled to a client device and having at least one sample processing bay. The diagnostic system has a software architecture including instrument software (ISW) associated with the instrument. The ISW receives an assay definition file (ADF) that has a control file and an assay analysis module (AAM) file. The processing bay prepares and senses the sample according to parameters in the OPUS file and then generates sensor scan data. The diagnostic system then analyzes the sensor scan data and prepares a report according to the AAM file.

A fluidic component including a fluidic circuit having at least one fluidic access through which a fluid is intended to pass, an actuator capable of expanding, a deformable membrane that can be actuated by the expansion of the actuator, sealing device for sealing off the fluidic access and including at least a body made of a meltable compound configured to adopt two states: a solid first state, a molten second state obtained under the effect of an increase in temperature, the body of meltable compound being designed to be moved in the molten state, by the expansion of the actuator, between a standby position and a distinct sealing-off position for sealing off the fluidic access.

A fluidic component intended to be associated with a heating module and in which there is formed a fluidic circuit including a fluidic channel intended for the circulation of a fluid, the fluidic channel including at least one passage for the fluid and a widened portion forming a location produced at the periphery of the passage, the component including a fluidic valve mechanism including at least an actuating element capable of expanding, trapped by at least one body made of a meltable compound in the location.

Systems and methods for conducting surface-mediated chemical and/or biochemical reactions within an enclosed chamber are disclosed. Systems and methods of the present disclosure may be used in conducting hybridization reactions of biopolymers. In some examples, an improved method for mixing thin films of solutions in a hybridization chamber includes altering the direction of mixing at least once over the course of a reaction. In some examples, an improved method for mixing thin films of solutions in a hybridization chamber includes altering the speed of mixing at least once over the course of a reaction. In some examples, an improved method for mixing thin films of solutions in a hybridization chamber includes altering the speed of mixing and the direction of mixing at least once over the course of a reaction.

The present invention discloses a Polymerase Chain Reaction (PCR) apparatus for real-time detecting of one or more fluorescent signals. According to the apparatus, the PCR is performed by controlling heating and cooling intervals of a reagent container receiving space. With the aid of an added specific probe and fluorescent material, as well as a light source and a spectrometer, a generated fluorescent signal is detected. Meanwhile, the apparatus is also pre-loaded with an algorithm configured to analyze and quantify the fluorescent signal in a real-time manner.

A measurement cell (3) for measuring at least one constituent of a liquid sample, in particular blood, includes a reception space (9) for receiving the sample includes a measurement system (8) having at least one sensor electrode (10) exposed within the reception space; a first heat supply equipment (12) extending over a first area (91); a second heat supply equipment (14) extending over a second area (93), the first and second heat supply equipment being arranged to heat the sample within the reception space (9), wherein the second area (93) is larger than the first area (91).

Apparatus is provided for testing a biological fluid for presence of a biological particulate. The apparatus includes a tube, a plunger sized and shaped to be inserted into and advanced within the tube, and a filter. The apparatus is configured such that as the plunger is advanced within the tube while the biological fluid is within the tube, the biological fluid in the tube is pushed through the filter, thereby trapping, by the filter, the biological particulate present in the biological fluid. The apparatus is shaped so as to define at least one enclosed cavity containing a biological particulate-presence-testing-facilitation solution configured to test for the presence of the biological particulate trapped by the filter. The enclosed cavity is configured to open while the plunger is inside the tube, so as to release the biological particulate-presence-testing-facilitation solution within the tube. Other embodiments are also described.

A bench top incubator is described. The bench top incubator includes a first tray stack designed to retain microscope slides in a plurality of slide trays and a second tray stack designed to retain multi-well plates in a plurality of plate trays. The incubator is relatively simple and small in design and can be conveniently located to carry out temperature processing of biological samples such as fixed cells and tissues, biological fluids, and so forth.

A system, methods, and apparatus are described to collect and prepare cells, nuclei, subcellular components, and biomolecules from specimens including FFPE and OCT preserved tissues. The system can perform deparaffinization, rehydration, enzymatic and/or chemical and physical disruption of the FFPE tissue, or residue removal of the OCT tissue, to dissociate it into a single cell or nuclei suspension.