An example system includes an input channel having a first end and a second end to receive particles through the first end, a sensor to categorize particles in the input channel into one of at least two categories, and at least two output channels Each output channel is coupled to the second end of the input channel to receive particles from the input channel, and each output channel is associated with at least one category of the at least two categories. Each output channel has a corresponding pump operable, based on the categorization of a detected particle in a category associated with a different output channel, to selectively slow, stop, or reverse a flow of particles into the output channel from the input channel.

A method for fabricating a fluidic device includes depositing a sacrificial material on a pillar array arranged on a substrate. The method also includes removing a portion of the sacrificial material. The method further includes depositing a sealing layer on the pillar array to form a sealed fluidic cavity.

Devices for sorting components (e.g., cells) contained in a liquid sample are provided. In certain aspects, the devices include a magnetic separation device and an acoustic concentrator device fluidically coupled to magnetic separation device. Aspects of the invention further include methods for sorting cells in a liquid sample, and systems, and kits for practicing the subject methods.

A technique relates sorting biopolymers. The biopolymers are introduced into a nanopillar array, and the biopolymers include a first population and a second population. The nanopillar array includes nanopillars arranged to have a gap separating one from another. The biopolymers are sorted through the nanopillar array by transporting the first population of the biopolymers less than a predetermined bumping size according to a fluid flow direction and by transporting the second population of the biopolymers at least the predetermined bumping size according to a bumped direction different from the fluid flow direction. The nanopillar array is configured to employ the gap with a gap size less than 300 nanometers in order to sort the biopolymers.

A method for measuring, in particular simultaneously measuring, different particle concentrations, in particular particulate matter concentrations, preferably in a flow, using a particle measuring system, in particular a particulate matter measuring system, comprising a photometric scattered light unit (1) with a measurement volume (16), wherein the scattered light unit (1) consists of at least one light transmitter (7) which emits (13) light signals, in particular pulsed light signals, and of at least one light-sensitive receiver system (8), which is arranged at at least one angle (15) and which receives the scattered light (14) from the particles (12) forming the particle concentration, characterized in that the scattered light unit (1) with measurement volume (16) is hermetically sealed with the exception of at least one fluid inlet (1a) and/or at least one fluid outlet (1b), which are provided with blocking devices (2, 3), wherein a sample of the fluid to be examined is applied to the scattered light unit (1) with measurement volume (16) and a predeterminable first number of measurement values is recorded.

A microchannel for processing cells by compression of the cells including an inlet, ridges and an outlet. Each ridge including a compressive surface and a cell adhesion entity. The outlet configured to remove at least one of a first portion of the cells and a second portion of the cells from the microchannel. Each ridge oriented at an angle of from 25 degrees to 70 degrees relative to a center axis of the microchannel. The cell adhesion entity configured such that the first portion of the cells has a first adhesion property relative to the cell adhesion entity to follow a first trajectory through the microchannel. The cell adhesion entity further configured such that the second portion of the cells has a second adhesion property relative to the cell adhesion entity to follow a second trajectory through the microchannel. The first trajectory is different from the second trajectory.

Techniques relate to forming a sorting device. A mesh is formed on top of a substrate. Metal assisted chemical etching is performed to remove substrate material of the substrate at locations of the mesh. Pillars are formed in the substrate by removal of the substrate material. The mesh is removed to leave the pillars in a nanopillar array. The pillars in the nanopillar array are designed with a spacing to sort particles of different sizes such that the particles at or above a predetermined dimension are sorted in a first direction and the particles below the predetermined dimension are sorted in a second direction.

A sorting chamber (1) for sorting first particles (25) from second particles (26) comprising: an internal chamber (7), which is delimited by a base wall (2), a top wall (4), and a spacer (6), set between the base wall (2) and the top wall (4); an internal chamber (7), which is at least partially-delimited by the base wall (2) and top wall (4); two passages (8), which set in communication the internal chamber (7) with the external environment; and a plurality of cavities (9), which are designed to house the first particles (25), are made in the base wall (2) and have openings (10) towards the internal chamber (7) with widths of from 4 to 6 μm.

A centrifugal field-flow fractionation device capable of improving analysis performance and shortening analysis time is provided. A first channel 111 communicating with a channel member is formed on a rotational shaft 11 that rotates together with a rotor. A second channel 644 communicating with the first channel 111 is formed on a fixing portion 60 fixed in a state of facing the rotational shaft 11 along a rotational axis L. A mechanical seal 66 having a pair of seal rings 661 and 662 that come into contact with each other and a biasing member 663 is provided to attach one seal ring 661 to the rotational shaft 11 and the other seal ring 662 to the fixing portion 60. The biasing member 663 biases the pair of seal rings 661 and 662 in a direction in which the pair of seal rings come in contact with each other. Since the rotational shaft 11 can be rotated at a high speed and the liquid sample can be fed at a high pressure, the analysis performance can be improved and the analysis time can be shortened.

A system for processing a sample includes a chamber having at least one inlet and at least one outlet, where the chamber is configured to accommodate flow of the sample from the at least one inlet toward the at least one outlet, and an imager array configured to image the flow of the sample in the chamber, where the imager array includes at least one lensless image sensor configurable opposite at least one light source.