The present disclosure relates to systems and methods for whole cell analysis. In particular, the present disclosure relates to single cell genomic analysis (e.g., gene expression analysis.

Disclosed is a module for sampling from a surface of an industrial vessel without requiring a person to descend into the industrial vessel, using a swab including a stem and a sampling tip, including a swab holder and a conveyor; the swab holder is adapted to receive and secure one end of the swab stem; and the conveyor is configured to set the swab holder in motion on the surface of the vessel.

A measurement chip (100) is disclosed for use with a microfluidic resistance network (20) comprising a microfluidic sample preparation stage (34, 38), a sample outlet (42) and a waste outlet (44) both in fluidic communication with said preparation stage. The measurement chip comprises a sample channel (104) for receiving a sample from said sample outlet (42), the sample channel comprising measurement means (120, 130) and having a first fluidic resistance; and a waste channel (114) for receiving a waste stream from said waste outlet (44) and having a second fluidic resistance.

Assay cartridges are described that have purification, reaction, and detection zones and other fluidic components which can include sample chambers, waste chambers, conduits, vents, reagent chambers, reconstitution chambers and the like. The assay cartridges are used to conduct multiplexed nucleic acid measurements. Also described are kits including such cartridges, methods of using the same, and a reader configured to analyze an assay conducted using an assay cartridge.

A flow control system for a microfluidic device includes: a plurality of fluid flow controllers, each fluid flow controller associated with a respective microfluidic device inlet of the microfluidic device, and wherein each fluid flow controller includes: a controller inlet for receiving a fluid flow, a first fluid channel and a second fluid channel, each of the first and the second fluid channels having a first end connected to the controller inlet and a second end connected to a supply channel, and a valve for selecting the fluid flow to be passed from the controller inlet to the first fluid channel or to the second fluid channel, wherein the first fluid channel has a first flow resistance that smaller than a second flow resistance of the second fluid channel.

A multiplex PCR chip capable of simultaneously detecting multiple target genes and a multiplex PCR method using the same are proposed. More specifically, in the multiplex PCR chip and multiplex PCR method, after a plurality of spatially separated particle-forming grooves is formed in one or more reaction chambers and a probe in a solution state is injected into the particle-forming grooves, planar shapes of the particle-forming grooves are varied or shapes and patterns of particle holders respectively formed on inner surfaces of the particle-forming grooves are varied, and the probe including primers specifically hybridizing with sequences of different nucleic acid molecules is injected into the particle-forming grooves, whereby simultaneous multiplex detection is possible by allowing multiple target genes to be detected on the basis of positions and shapes of the probe particles and the shapes and patterns of the particle holders respectively formed inside of the probe particles.

Provided herein are devices and methods for generating positive and negative pressures. The devices and methods are suited for the generation of pressures; in particular, the pressures generated can be useful for controlling the flow of fluids, such as in fluidic device.

The invention is directed to devices and methods for performing rapid low-cost bioassays in self-contained disposable cartridges that provide efficient mixing of sample and reactants under a layer of liquid wax. Some embodiments additionally use gravity assisted distribution of sample and assay reagents in conjunction with an appliance containing all necessary valves, pneumatic sources, heat sources and detection stations.

An apparatus for performing a thermocyclic process, such as amplifying DNA, includes a microfluidic chip with a channel formed therein and one or more thermal distribution elements disposed over portions of the chip. Each thermal distribution element is configured to distribute thermal energy from an external thermal energy source substantially uniformly over the portion of the chip covered by the thermal distribution element. The portion of the chip covered by the thermal distribution element thereby comprises a discrete temperature zone. Other temperature zones can be defined by other thermal distribution elements or by portions of the chip not covered by a thermal distribution element. The channel is configured so that a fluid flowing through the channel would enter and exit the different temperature zones a plurality of times, thereby alternately exposing the fluid to the temperature of each zone for a period of time required for the fluid to traverse the zone.

A double-sided diaphragm micro gas-preconcentrator has a micro-gas chamber which is formed by stacking an upper silicon substrate with a lower silicon substrate with a back-on-face configuration. One or more suspended membranes are provided on every silicon substrate. The silicon where the suspended membrane is provided is completely removed for forming a cavity. A thin-film heater is deposited on every suspended membrane. A sorptive film is coated on an inner wall of every suspended membrane. Thus, the upper and lower sides of the preconcentrator in the present invention are suspended membranes, which improve the area of the sorptive film on the diaphragm. As a result, the preconcentrating factor is improved while keeping the small heat capacity, fast heating rate, and low power consumption features of the planar diaphragm preconcentrator.