An example apparatus comprises a thermal cell lysis chamber, including a substrate and a lid coupled to the substrate to form a microfluidic channel therethrough. The apparatus includes cell detection circuitry to detect presence of a cell within the microfluidic channel and to detect lysis of the cell. The apparatus also includes a thermal lysing element disposed in the lid to apply heat to a cell detected by the cell detection circuitry, and lysis control circuitry. The lysis control circuitry is to regulate a temperature applied by the thermal lysing element, based on detection by the cell detection circuitry of a cell within the microfluidic channel and based on detection by the cell detection circuitry of a lysis event, and record the temperature applied by the thermal lysing element at which the lysis event occurred.

Aspects relate to systems and methods for fluid sensing using passive flow. An exemplary system includes a microfluidic device, the microfluidic device including at least a reservoir configured to contain at least a fluid and at least a passive flow component in fluidic communication with the at least a reservoir and configured to flow the at least a fluid with predetermined flow properties, at least an sensor device configured to be in sensed communication with the at least a fluid and detect at least a sensed property; and at least an sensor interface configured to wet at least a surface of the at least a sensor device with the at least a fluid.

A system, apparatus, and method include a pump to deliver vapor including airborne contaminants including organic compounds including a target analyte; a collector to transfer the airborne contaminants by autonomous liquid extraction into a mobile organic liquid phase; a micro-fluidic chamber including immobilized biorecognition elements that bind to analytes delivered from the mobile organic liquid phase; a mechanism to introduce the mobile organic liquid phase to a buffer containing a plurality of substrates causing a series of biochemical reactions that create a change corresponding to a concentration of the target analyte; and a detector to perform real-time analysis that correlates to a concentration of the organic compounds to determine a presence of the target analyte.

A system or method for detecting an immune system activation state in a patient can include a sample preparation system configured to isolate white blood cells from a sample of the patient, a cytometry module configured to determine biophysical properties of the white blood cells of the sample, and an analysis module configured to analyze the biophysical properties.

The disclosure relates to devices, solutions and methods for collecting and processing samples of bodily fluids containing cells (as well as embodiments for the collection, and processing and/or analysis of other fluids including toxic and/or hazardous substances/fluids). In addition, the disclosure relates generally to function genomic studies and to the isolation and preservation of cells from saliva and other bodily fluids (e.g., urine), for cellular analysis. With respect to devices for collection of bodily fluids, some embodiments include two mating bodies, a cap and a tube (for example), where, in some embodiments, the cap includes a closed interior space for holding a sample preservative solution and mates with the tube to constitute the (closed) sample collection device. Upon mating, the preservation solution flows into the closed interior space to preserve cells in the bodily fluid. The tube is configured to receive a donor sample of bodily fluid (e.g., saliva, urine), which can then be subjected to processing to extract a plurality of cells. The plurality of cells can be further processed to isolate one and/or another cell type therefrom. The plurality of cells, as well as the isolated cell type(s), can be analyzed for functional genomic and epigenetic studies, as well as biomarker discovery.

Methods and systems for processing polynucleotides (e.g., DNA) are disclosed. A processing region includes one or more surfaces (e.g., particle surfaces) modified with ligands that retain polynucleotides under a first set of conditions (e.g., temperature and pH) and release the polynucleotides under a second set of conditions (e.g., higher temperature and/or more basic pH). The processing region can be used to, for example, concentrate polynucleotides of a sample and/or separate inhibitors of amplification reactions from the polynucleotides. Microfluidic devices with a processing region are disclosed.

A method for determining the activity of creatininase includes providing an amount of creatininase to be measured for enzyme activity and providing an excess amount of creatinine, the excess amount being greater than an amount that will ordinarily react with the amount of creatininase. The method further includes reacting the amount of creatininase with the excess amount of creatinine to produce creatine. The method further includes reacting the creatine with diacetyl and 1-naphatol and producing a pink color. The method further includes measuring an intensity of the pink color and determining an amount of the creatine that was created based on the intensity. The method further includes calculating a specific activity of the creatininase based on the amount of creatine.

An apparatus for gene amplification includes a gene amplification chip including a well configured to accept a sample that is loaded into the well; the gene amplification chip being configured to: thermally dissolve the sample in the well so that a microbe present in the sample is thermally dissolved in the well to release genes in the microbe; and amplify the released genes in the well. The apparatus for gene amplification also includes a temperature controller configured to control a thermal dissolution temperature and a gene amplification temperature of the well.

A system for extracting analytes from a biological sample, which includes: an electronic pipette having pipette cones with a tip; a well support; a pipette holder including: a base which can removably house each well support; a pipette support into which the pipette is inserted, and which can move relative to the base between a first position in which the tips of the cones are inserted in a well of the support and at least one second position in which the tips are outside the wells; a housing facing the pipette cones above their tip when the pipette support is in the first position, and facing the tips of the pipette cones when the pipette support is in the second position; and a magnetized part removably inserted in the housing.

The disclosed microfluidic valves may include a valve body having at least one cavity therein, a gate transmission element separating the cavity into an input gate terminal and an output gate terminal, a gate port configured to convey drive fluid into the input gate terminal, and a fluid channel. The gate transmission element may include a flexible membrane and a plunger coupled to the flexible membrane. The gate transmission element may be configured to move within the cavity to inhibit a subject fluid flow from an inlet port to an outlet port of the fluid channel upon pressurization of the input gate terminal, and to allow subject fluid flow from the inlet port to the outlet port upon depressurization of the input gate terminal. Various other related systems and methods are also disclosed.