Apparatus, system and method for dispensing a particle-laden fluid from a fluid holding and dispensing micro-feature. In some implementations, the apparatus includes: a chamber having one or more surfaces that define a volume to receive fluid containing particulate matter, and an outlet port to dispense at least a portion of the fluid from the chamber. The outlet port may have a normal vector that, when the apparatus is positioned to dispense the fluid, is substantially perpendicular to gravity. The apparatus may be used to measure a number of individual particles from the fluid that flow through the outlet port over a period of them, measure a total volume of the fluid dispensed through the outlet port over the period of time, and calculate a concentration of the particulate matter within the chamber. In some implementations, the particle-laden fluid may be whole blood.

A platform and method for conducting multi-variable combinational interactions are provided. An array of multiplexing chambers in formed in a body. The body also includes a common well communicating with each multiplexing chamber of the array of multiplexing chambers and a plurality of variable wells. Each of variable wells communicates with at least one multiplexing chamber of the array of multiplexing chambers. The common well is loaded with a first variable and different variables are loaded in each of the plurality of variable wells. The interaction of the first variable with at least one of the different variables in each multiplexing chamber of the array of multiplexing chambers is observed.

Microfluidic system, including methods and apparatus, for processing fluid, such as by droplet generation. In an exemplary method, a sample-containing fluid may be dispensed into a well through a sample port of a channel component. The channel component may include (a) a body having a bottom surface attached to the well, and a top surface with a microchannel formed therein, and (b) an input tube projecting into the well from the bottom surface of the body. The sample-containing fluid when dispensed may contact a bottom end of the input tube and may be retained, with assistance from gravity, out of contact with the microchannel. A pressure differential may be created that drives at least a portion of the sample-containing fluid from the well via the input tube and through the microchannel.

A tissue dissociation device includes an inlet coupled to a first stage having a single channel having an upstream end and a downstream end; a plurality of serially arranged intermediate stages, wherein a first intermediate stage of the plurality is fluidically coupled to the downstream end of the first stage, and wherein each subsequent intermediate stage of the plurality has an increasing number of channels (with channels of smaller dimensions); and an outlet coupled to a last stage of the intermediate stages.

An apparatus and method to detect disease-specific antigens assists in disease diagnosis. Point-of-care (POC) micro biochip incorporates at least one hydrophilic microchannel for controlled and self-driven flow of body fluid. Metallic nano-interdigitated electrodes disposed within the channels give enhanced sensitivity detection. Microchannel controls flow and amplifies a capillary effect. Electrodes are fabricated on microchannel surface to detect biomolecular interactions. When a sample flows through microchannel, disease-specific antigens from the sample form antigen-antibody complex with antibodies immobilized on electrodes. Antigen-antibody interaction is detected via an electrical change in the biochip's nano circuit. Each electrode may include a different antibody to detect different antigens. Capacitance during antigen-antibody interaction without microfluidic flow is higher than with microfluidic flow due to immobilized antibodies instability on sensing surface caused by shear stress. POC biochip provides nano level detection of many disease-specific antigens of any type based on micro volume or single drop sized sample.

Methods and device for quantification of an analyte in a sample are provided. An example has the following steps: the sample is introduced into at least one test split channel (306). The test split channel (306) comprises a test reaction portion (306a). The analyte (410) in the sample is to bind to capture reagents (408) provided in the reaction portion. Analyte (410) bound to the capture reagents (408) is contacted with a reactant solution. The reactant solution comprises a plurality of reagent coated microparticles (412) for binding with the analyte (410). Residual reactant solution comprising unbound microparticles is received. The residual reactant solution is analyzed to quantify the analyte.

A microfluidic device for detecting rare cells in a fluid sample comprises the rare cell and other cells. The microfluidic device comprises an inlet for receiving the fluid sample, a labyrinth channel structure in fluid communication with the inlet, and an outlet in fluid communication with the labyrinth channel structure for collecting the rare cells separated from the other cells in the fluid sample. The labyrinth channel structure comprises at least one channel through which the fluid sample flows. The at least one channel has a plurality of segments and a plurality of corners with each corner defined between adjacent segments. The presence of the plurality of corners induces separation of the rare cells from the other cells in the fluid sample as the rare cells move to a first equilibrium position within the at least one channel when a ratio of inertial lift forces (F.sub.Z) and Dean flow (F.sub.D) of the fluid sample is from 2 to 10.

A fluidic device includes a valve configured to adjust a fluid flow in a first direction of a flow path. The fluidic device includes: a diaphragm of the valve; a first substrate having a groove that constitutes the flow path and a protrusion part at a position facing the diaphragm in the groove; and a second substrate to which the diaphragm is fixed at a first fixation part and a second fixation part, wherein a length from a first end part of the protrusion part to a second end part of the protrusion part seen in the first direction is greater than a length from the first fixation part to the second fixation part.

A method and cartridge for determining an amount of at least two analytes in a biological sample and an automatic analyzer are disclosed. The cartridge may comprise a cartridge inlet, a sample holding chamber fluidically connected to the inlet, and two or more metering chambers. Each metering chamber may comprise a sample inlet, a sample outlet, and a metered outlet for dispensing a predetermined volume. At least one sample distribution channel is connected between the sample outlet of a metering chamber with a sample inlet of another metering chamber. For each metering chamber, a connecting tube fluidically connects the sample inlet with the sample holding chamber, a microfluidic structure for processing the sample into a processed sample connects to the sample outlet, and a measurement structure fluidically connects to the microfluidic structure and enables measurement of the processed sample to determine the amount of the analyte in the processed sample.

The invention relates to a method and system for generating droplets of an aqueous solution on a microfluidic chip with an air continuous phase. Specifically, the droplet generator according to the present invention is integrated into a microfluidic chip to generate and introduce droplets of an aqueous solution into the microfluidic chip. The droplets travelling in a network of chip channels may be captured in on-chip traps in a manner defined by hydrodynamic resistances of chip channels. A biological reaction may be performed on a droplet trapped on the microfluidic chip.