A system and method for isolating and analyzing single cells, wherein the system includes: an array of wells defined at a substrate, each well including an open surface and a well cavity configured to capture cells in one of a single-cell format and single-cluster format, and a fluid delivery module including a fluid reservoir superior to the array of wells through which fluid flow is controlled along a fluid path in a direction parallel to the broad face of the substrate; and wherein the method includes: capturing a population of non-cell particles into the array of wells in single-particle format; releasing, from the non-cell particles, a set of probes into the array of wells; capturing a population of cells into the array of wells in single-cell format; releasing biomolecules from each captured cell into the array of wells; and generating a set of genetic complexes comprising the biomolecules associated with a single captured cell and a subset of probes within individual wells of the array of wells.

Splitting of biological samples is provided by flowing the samples through a flow splitter where the sample strikes a stationary blade and is split into two pieces that end up in separate output channels. Samples can be single cells or multi-cellular samples. The split ratio of the pieces can be 50:50 or it can be other values as determined by design. To first order, the split ratio of the pieces is the same as the split ratio of the fluid flows in the output channels.

Disclosed is a microfluidic biosensing system including a processor, in which a Raman barcode database corresponding to at least one Raman spectrum signal is stored, a plurality of Raman barcode beads mixed with a target fluid and coupled to at least one target bioparticle in the target fluid, a microfluidic channel disposed to make the target fluid mixed with the Raman barcode beads flow therethrough, a light source disposed on the microfluidic channel, and a spectral detection device connected to the processor and disposed to correspond to the light source. The spectral detection device receives the Raman spectrum signal generated when the target bioparticle coupled with the Raman barcode bead is irradiated, and transfers the received Raman spectrum signal to the processor. The processor determines a type of the bioparticle(s) and calculates the number of bioparticle(s) by matching the Raman spectrum signal(s) to the Raman barcode database.

A microfluidic device includes a plurality of reaction wells; and a plurality of solid supports, and each of the solid supports has a reagent attached thereto. The reagent is attached to the solid support via a labile reagent/support bond such that the reagent is configured to be cleaved from the support via a cleaving operation.

Systems and methods for improved flow properties in fluidic and microfluidic systems are disclosed. The system includes a microfluidic device having a first microchannel, a fluid reservoir having a working fluid and a pressurized gas, a pump in communication with the fluid reservoir to maintain a desired pressure of the pressurized gas, and a fluid-resistance element located within a fluid path between the fluid reservoir and the first microchannel. The fluid-resistance element includes a first fluidic resistance that is substantially larger than a second fluidic resistance associated with the first microchannel.

The microfluidic devices and systems disclosed herein reduce sample loss and help decrease sample processing bottlenecks for applications such as next generation sequencing (NGS). The microfluidic devices include a plurality of reaction modules. Each reaction module may comprise one or more reaction circuits. Each reaction circuit may comprise a single reaction flow channel with each reaction circuit connected by a bridge flow channel. Alternatively, each reaction circuit may comprise two or more reaction flow channels connected by two or more bridge flow channels. The combination of any two bridge flow channels and a portion of the two or more reaction flow channels between the any two bridge flow channels defining may define the reaction circuit. The reaction module may be arranged as nodes connected by bridge flow channels or each reaction module may be arranged in a parallel fashion on the microfluidic device.

Disclosed herein are devices, apparatus, systems, methods and kits for collecting and storing a fluid sample from a subject. A device for collecting the fluid sample can include a housing comprising a recess having an opening, a vacuum chamber in the housing and in fluidic communication with the recess, and one or more piercing elements that are extendable through the opening to penetrate skin of the subject. The vacuum chamber can be configured for having a vacuum that draws the skin into the recess. The recess can be configured having a size or shape that enables an increased volume of the fluid sample to be accumulated in the skin drawn into the recess.

Provided are an introduction step of using a particle capturing device (1) for introducing a fluid including target particles (CT) and non-target particles (CA)-(CC) from an inlet channel (18) into a chamber (20), an enrichment step of enriching the target particles (CT) and at least a part of the non-target particles (CA) in a filter (12) by discharging at least a part of the fluid through the first outlet channel (8), a separation step of separating the filtered out non-target particles (CA) from the target particles (CT) by a suction unit (30), and a storage step of storing the target particles (CT) in wells.

A microfluidic system for analyzing a sample solution includes a division chamber for accommodating an input volume of the sample solution. The division chamber has a plurality of partial volume segments for accommodating a plurality of partial volumes of the sample solution, which partial volumes can be used for detection reactions. The microfluidic system also has a displacing device configured to divide the input volume into the plurality of partial volumes.

A microfluidic device capable of trapping contents in a manner suitable for high-throughput imaging is described herein. The microfluidic device may include one or more trapping devices, with each trapping device having a plurality of trapping channels. The trapping channels may be configured to receive contents via an inlet channel that connects a sample reservoir to the trapping channels via fluid communication. The trapping channels are shaped such that contents within the trapping channels are positioned for optimal imaging purposes. The trapping channels are also connect to at least one exit channel via fluid communication. The fluid, and contents within the fluid, may be controlled via hydraulic pressure.