A microfluidic device containing an inlet, a microchannel in fluid communication with the inlet, and a plurality of outlets in fluid communication with the microchannel. The microchannel contains a loop; or from about 1 loop to about 50 loops; or from about 2 loops to about 25 loops; or from about 5 loops to about 15 loops. A method for detecting an infected cell may employ the microfluidic device.

Provided is an apparatus for cell particle sorting based on microfluidic-chip flow, by using a design in which Dean flow focusing occurring in a spiral channel and hydrodynamic filtration are coupled. The apparatus comprises a first substrate including a spiral channel having an inner surface and an outer surface based on a radius of curvature, a sample solution inlet, a medium inlet, and a spiral inner-outlet and a spiral outer-outlet both for discharging the particles, and a second substrate including a main channel in which the sample solution discharged from the first substrate and passing through an inter-substrate way flows and a cut-off width W.sub.C is set, a side channel allowing a medium introduced into the medium inlet to flow to focus the sample solution on a sidewall of the main channel, a plurality of branch channels connected to the sidewall of main channel and configured to receive the particles from the main channel, a main channel outlet, and at least one branch channel outlet.

A collection plate for a cascade impactor is provided that includes: a container; an absorbent layer including a bottom surface and a top surface, the absorbent layer residing within the container, the absorbent layer further including a liquid medium within the absorbent layer; and an impaction membrane placed on the top surface of the absorbent layer, such that the impaction membrane is in fluidic communication with the absorbent layer. The absorbent layer is configured to hydrate the impaction membrane for at least four hours in a temperature of about 78° F. at 37% RH. The collection plate may be utilized as a component in a cascade impactor and/or in a method of collecting a biological sample with a cascade impactor.

A microfluidic device includes: a first microfluidic channel; a second microfluidic channel extending along the first microfluidic channel; and a first array of islands separating the first microfluidic channel from the second microfluidic channel, in which each island is separated from an adjacent island in the array by an opening that fluidly couples the first microfluidic channel to the second microfluidic channel, in which the first microfluidic channel, the second microfluidic channel, and the islands are arranged so that a fluidic resistance of the first microfluidic channel increases relative to a fluidic resistance of the second microfluidic channel along a longitudinal direction of the first microfluidic channel such that, during use of the microfluidic device, a portion of a fluid sample flowing through the first microfluidic channel passes through one or more of the openings between adjacent islands into the second microfluidic channel.

Methods and systems for processing material in a host fluid use an acoustophoresis device. These methods and systems can deflect material (e.g., a second fluid, cells, beads or other particles, exosomes, viruses, oil droplets) in host fluid streams at high flow rates.

The objective of the present invention is to provide a particle detection device and a particle detection method that can individually and continuously detect a wide range of particles. The objective is achieved by a particle detection device including: a particle separation channel through which particles are separated according to particle sizes in a perpendicular direction to the flow of fluid; and two or more particle recovery channels that are connected to and branched from the particle separation channel, in which each of the particle recovery channels includes a particle detection unit that includes an aperture and an electric detector.

The invention relates to a sampling machine with multi-channel flow distributing structure, belongs to the particulate matters collecting technology field. The invention provides a simple structure and uses the aerodynamic principle to cut particulate matters by impact to avoid dust accumulation. The invention comprises, a cutting flow-distributing machine connected with inlet of the sampling machine, multi-channel collecting pipelines are connected to the bottom of the cutting flow-distributing machine, collecting pipelines are provided with a cutting machine, a membrane component, a flow controller and a sampling pump, the cutting flow-distributing machine comprises a casing, an impact pipe, an impact plate and a distributing pipe, the impact plate, the impact pipe and the distributing pipes are mounted inside, on the top and at the bottom of the casing respectively, the impact pipe and the distributing pipes are extend to the inside of the casing.

According to an example aspect of the present invention, there is provided an apparatus, comprising: a channel for receiving gas; thermophoretic unit configured to create a temperature gradient in the channel, and a particle detector for detecting particles in the gas on the basis of particle landing positions in the channel.

A sensor for the continuous in-situ analysis of an aerosol flow for measuring the mass of the micron/submicron particles suspended in the air flow, including an aeraulic sorter allowing the particles to be sorted according to their size with an impactor body with a cascade of one or more stages; at least one MEMS microbalance per stage, with an oscillating silicon membrane located on the impaction zone of the particles; processor connected to each MEMS microbalance to determine the mass of all the particles on the impaction zone; a system for cleaning the MEMS microbalances allowing the evacuation of the particles from the MEMS microbalances; means for driving the aerosol flow.

A method and apparatus for monitoring particulate concentrations in ambient air use digital in-line holography and automated digital algorithms to classify and determine mass density and other characteristics of particles within a determined mass and size range. An embodiment provides a sampling plate on which particles are deposited at locations which depend on sizes and masses of the particles. A digital in-line hologram of the sampling plate is processed to obtain information about the particles. The method and apparatus have example application to environmental monitoring.