A microfluidic device may include at least four interconnected microfluidic channels and a set of fluid actuators. The set of fluid actuators may include a fluid actuator asymmetrically located within at least two of the at least four interconnected microfluidic channels. Each of the at least four interconnected microfluidic channels may be activated to a fluid inputting state, a fluid outputting state and a fluid blocking state in response to selective actuation of different combinations of fluid actuators of the set.

A microfluidic chip may include a substrate, chamber supported by the substrate, a sacrificial material in the chamber, a spectroscopically active nano particle assembly anchored within the chamber by the sacrificial material and a fluid supply port connected to the chamber. Each spectroscopically active nano particle assembly may include a cluster of nanoparticles.

A group of micro-objects in a holding pen in a micro-fluidic device can be selected and moved to a staging area, from which the micro-objects can be exported from the micro-fluidic device. The micro-fluidic device can have a plurality of holding pens, and each holding pen can isolate micro-objects located in the holding pen from micro-objects located in the other holding pens or elsewhere in the micro-fluidic device. The selected group of micro-objects can comprise one or more biological cells, such as a clonal population of cells. Embodiments of the invention can thus select a particular group of clonal cells in a micro-fluidic device, move the clonal cells to a staging area, and export the clonal cells from the micro-fluidic device while maintaining the clonal nature of the exported group.

High-throughput digital microfluidic (DMF) systems and methods (including devices, systems, cartridges, DMF apparatuses, etc.), are described herein. The systems, apparatuses and methods integrate liquid handling with the DMF apparatuses, providing flexible and efficient sample reactions and sample preparation. These systems, apparatuses and methods may be used with a variety of cartridge configurations and sizes.

Aniosotropic Ratchet Conveyor (ARC)-based biomolecule processing devices and related methods are described. The ARC-based biomolecule processing devices include (i) a substrate having an ARC track defined on or within the substrate and including a biomolecule receiving area, which is designed to receive biomolecule, and a reconstituting area, which is designed to contain dry reagents and is designed to receive a transport solution such that at the reconstituting area, dry reagents are reconstituted with transport solution; and (ii) a microheater area disposed at or near the biomolecule receiving area, fitted with a microheater, which is designed to heat biomolecule that is received through the biomolecule receiving area and designed to process heated biomolecule and dry reagents reconstituted with transport solution. The ARC track includes an arrangement of a plurality of hydrophilic rungs disposed on a hydrophobic region such that between consecutive hydrophobic rungs, a portion of the hydrophobic region is exposed.

A microfluidic device can comprise at least one swept region that is fluidically connected to unswept regions. The fluidic connections between the swept region and the unswept regions can enable diffusion but substantially no flow of media between the swept region and the unswept regions. The capability of biological micro-objects to produce an analyte of interest can be assayed in such a microfluidic device. Biological micro-objects in sample material loaded into a microfluidic device can be selected for particular characteristics and disposed into unswept regions. The sample material can then be flowed out of the swept region and an assay material flowed into the swept region. Flows of medium in the swept region do not substantially affect the biological micro-objects in the unswept regions, but any analyte of interest produced by a biological micro-object can diffuse from an unswept region into the swept region, where the analyte can react with the assay material to produce a localized detectable reaction. Any such detected reactions can be analyzed to determine which, if any, of the biological micro-objects are producers of the analyte of interest.

A multiple sample automatic dosing and cleaning system comprising a first receiving carousel for sequentially receiving multiple samples in sample cups for automatic sequential filling a dosing head. The receiving carousel is rotated around its axis and synchronized with the dosing device. Each destination cup is weighed empty on a balance scale in the destination carousel having openings for multiple cups. The destination carousel has means for rotation movement and vertical and horizontal movement. The destination carousels empty and tared cups placed on the balance scale receive the samples and flux for automatic dosing. A cleaning vacuum device is used to clean the dosing head every time each sample is dosed for integrity sample dosing. The carousels are serviced by gantry support which provides linear and vertical movement of the dosing device.

The invention discloses a quasi-volumetric sensing system and method. Plural short-range order (SRO) units are configured on the carrier of a quasi-volumetric device, and arranged as an array, i.e. a long-range order (LRO) unit. Protrusions, configured on the SRO units, can modify the wettability of the carrier to control the liquid volume retained thereon so that the precise volume of the liquid sample or droplets are calculated. Based on the applied force on the LRO unit and the gradient of hydrophilicity-hydrophobicity on the surface, the redundant volume of the liquid sample is removed. Macromolecules, e.g. antibodies, complements, receptor proteins, aptamers, oligosaccharides or oligonucleotides, configured on the protrusions are coupled to specific molecules in the liquid sample or droplets so as to determine characteristics of the specific molecules. Therefore, the open chip device of the invention can be used to achieve the quasi-volumetric measurement and the analysis of specific molecules.

A spectroscopically active nano-particle assembly is provided. The nano-particle assembly includes a cluster of metallic nano-particles. A first protective coating is formed over a first side of the cluster, and a second protective coating is formed over a second side of the cluster, wherein the second side of the cluster is opposite the first side.

An embodiment of a system includes a compartment-generating device, a compartment detector, and electronic computing circuitry. The device is configured to generate compartments of a digital assay, at least one of the compartments having a respective volume that is different from a respective volume of each of at least another one of the compartments. The detector is configured to determine a number of the compartments each having a respective number of a target that is greater than a threshold number of the target. And the electronic circuitry is configured to determine a bulk concentration of the target in a source of the sample in response to the determined number of compartments. Because such a system can be configured to estimate a bulk concentration of a target in a source from a polydisperse digital assay, the system can be portable, and lower-cost and faster, than conventional systems.