Examples of the disclosure relate to an apparatus for analysing fluid samples. The apparatus is sized and shaped so that it can fit into an input port of an electronic device. The input port could be an existing port of the electronic device such as an input port for a memory card or a charger. The electronic device can be configured with a heat transfer means so that, when the apparatus is inserted into the electronic device, heat from the electronic device can be used to control the temperature of a fluid sample within the apparatus. This can enable the reaction conditions within the apparatus to be controlled.

A system for nucleic acid amplification is to synthesize amplified target nucleic acids or determine the presence of target nucleic acid. The mobile device of the system implements with an interface for controlling the reaction as well as optionally recording or delivering the reaction results or protocols to a cloud for sharing. In addition, current invention also discloses an airborne molecule detector integrating both air sampler and biochemical analysis component. The device can monitor the bioaerosols on real time. The reaction product can be used for nucleic acid sequencing as well. Furthermore, a pH test strip is used to replace a halochromic agent in a reaction mix for determining the nucleic acid amplification.

Apparatuses, systems, and methods are disclosed for target detection based on collateral cleavage of a reporter by an enzyme. A biologically gated transistor may include a channel and a reporter moiety immobilized to the channel. The state of the reporter moiety may affect one or more output signals from the biologically gated transistor when excitation conditions are applied to the biologically gated transistor and a sample fluid is applied in contact with the channel. A sample fluid may include an enzyme configured to activate in response to a target nucleic acid to cleave the reporter moiety. Excitation circuitry may apply the excitation conditions, and measurement circuitry may measure output signals from the biologically gated transistor. An analysis module may determine a parameter relating to presence of the target nucleic acid, based on the one or more measurements.

A reaction vessel comprises a lower chamber with a first volume, and an upper chamber with a second volume greater than the first volume. A thermocycling system for heating the reaction vessel includes a lower heating zone to heat the lower chamber, an upper heating zone to heat the upper chamber, and a lid heater to heat an opening of the upper chamber. A method comprises loading a sample into a lower chamber of a reaction vessel, thermocycling the lower chamber using a lower heating zone of the thermo cycler, combining an additive into the sample to produce a combination filling the lower chamber and at least partially filling an upper chamber of the reaction vessel, and incubating the upper and lower chambers using the lower heating zone and an upper heating zone. The lower and upper chambers can have different wall thicknesses to facilitate heat transfer.

Provided is a temperature control system applied to an apparatus for analyzing a sample using a pipette nozzle and a reaction container, including a pipette tip temperature controller that heats a pipette tip which is fitted on the pipette nozzle and aspirates or discharges liquid and a reaction container temperature controller that heats the reaction container. The pipette tip temperature controller heats, in a concentrated manner, at least a distal end portion of the pipette tip of the pipette nozzle located at a predetermined heating position with hot air emitted from a heat source and is configured such that a distal end is capable of arriving at the reaction container by lowering the pipette nozzle from the heating position.

Digital microfluidic (DMF) apparatuses and methods for optically-induced heating and manipulating droplets are described herein. DMF apparatuses employing photonic heating as described herein provide radical simplification of routing droplets/reagents in complex, multistep protocols and/or highly plexed workflows.

A microfluidic device includes a microfluidic substrate having a porous media channel, an oil inlet port in fluid communication with the porous media channel, a fluid inlet port in fluid communication with the porous media channel, and an outlet port in fluid communication with the porous media channel. The porous media channel has a plurality of dividers that provide the porous media channel with a network of fluid pathways. A method for assessing miscibility of an oil composition and a fluid includes flowing an aliquot of a fluid through a porous media channel to displace at least an oil composition from the porous media channel, and conducting an optical investigation of the porous media channel to assess the miscibility of the oil composition and the fluid at the test pressure and test temperature.

A method and biological sample analyzer is described that adjusts airflow within a housing based upon altitude. A first volume of air is moved by at least one fan within a housing of a biological sample analyzer. A temperature of the first volume of air is measured within the biological sample analyzer with a temperature sensor within the housing of the biological sample. Power output of at least one heater positioned within the housing of the biological sample analyzer is measured. The measured power output of the at least one heater is analyzed at the measured temperature within the biological sample analyzer. And, the fan is adjusted to move a second volume of air different from the first volume of air by comparing the measured power output of the at least one heater and expected power output of the at least one heater.

Systems and methods for probe tip heating are disclosed. An exemplary system for probe tip heating can include an enclosure enclosing a probe tip, a heating device, and a fan. The probe tip can be configured to access an internal volume of a stoppered container and to aspirate or dispense a material from or to the internal volume of the stoppered container. The heating device can be configured to heat air circulating within the enclosure. The fan can be positioned to circulate air within the enclosure to heat the tip of the probe

A device includes a multiple analyte sensor, a transimpedance amplifier, and a differential amplifier. The multiple analyte sensor includes a first working electrode, a second working electrode, a counter electrode, and a reference electrode. Each of the first working electrode and the second working electrode is configured to receive a signal indicative of a presence of a respective analyte. The counter electrode is a sum of the received signal of each of the first working electrode and the second working electrode. The transimpedance amplifier is configured to receive a first signal of the received signals from the first working electrode and a second signal of the received signals from the second working electrode. The transimpedance amplifier converts the received first signal and the received second signal to an output including a variable bias offset. The differential amplifier is configured to subtract the variable bias offset from the output.