A device includes a collimated light source operable to generate a collimated light source beam, which includes a beam direction. The device includes a first channel in a first plane and a second channel in a second plane different from the first plane. The second channel communicates with the first channel and includes a flow direction. The second channel is oriented to receive the collimated light source beam. The device includes a third channel in a third plane different from the second plane and communicates with the second channel. The collimated light source beam is oriented to enter a cross-section of the first channel, then to pass through the second channel, and then to enter a cross-section of the third channel such that the beam direction is opposite to the flow direction in the second channel. The device includes a focused particle stream nozzle operably connected to the first channel.

The invention presents a microfluidic device that provides investigation of distance dependent interactions between cells and various factors. A method that uses the device to determine distance dependent interactions between cells and various factors and agents that can change these interactions is also presented.

A processing instrument flowcell having a flowcell channel with an upstream channel end, a downstream channel end, a longitudinal axis extending from the upstream channel end to the downstream channel end, and a first operative surface extending between the upstream channel end and the downstream channel end and configured to receive a first number of DNA templates. A first reagent inlet is fluidically connected to the upstream channel end at a location adjacent the first operative surface. A buffer inlet is fluidically connected to the upstream channel end at a location spaced from the first operative surface. An outlet fluidically connected to the downstream channel end. Also provided is a method for operating a flowcell channel under laminar flow conditions to maintain a first reagent adjacent a first operative surface and a buffer fluid spaced from the first operative surface. The flowcell channel may have multiple separate operative surfaces.

This disclosure relates to a system for sorting sperm cells in a microfluidic chip. In particular, various features are incorporated into the system for aligning and orienting sperm in flow channels, as well as, for determining sperm orientation and measuring relative DNA content for analysis and/or sorting.

There is provided a microparticle sorting method including a procedure of collecting a microparticle in a fluid that flows through a main channel in a branch channel that is in communication with the main channel by generating a negative pressure in the branch channel. In the procedure, a flow of a fluid is formed that flows toward a side of the main channel from a side of the branch channel at a communication opening between the main channel and the branch channel.

A system and method are provided for harvesting target biological substances. The system includes a substrate and a first and second channel formed in the substrate. The channels longitudinally extending substantially parallel to each other. A series of gaps extend from the first channel to the second channel to create a fluid communication path passing between a series of columns with the columns being longitudinally separated by a predetermined separation distance. The system also includes a first source configured to selectively introduce into the first channel a first biological composition at a first channel flow rate and a second source configured to selectively introduce into the second channel a second biological composition at a second channel flow rate. The sources are configured to create a differential between the first and second channel flow rates to generate physiological shear rates along the second channel that are bounded within a predetermined range.

Embodiments of the microfluidic device may include of an array of microfluidic cell capture chambers, each functionalized with a different antibody to recognize a target antigen, and a network of code-multiplexed Coulter counters placed at strategic nodes across the device to quantify the fraction of cell population captured in each microfluidic chamber. For example, an apparatus may comprise a fluid inlet port divided into a plurality of separate microfluidic paths, each separate microfluidic path configured to transport a plurality of cells, the plurality of separate microfluidic paths, each comprising a plurality of microfluidic cell capture chambers, an outlet port to discharge a merged output of cells from the plurality of microfluidic cell capture chambers, and a plurality of sensors to detect cells passing into or out of a microfluidic cell capture chamber.

Devices, methods, and kits are provided for allergy testing based on basophil activation in a blood sample. Susceptibility of an individual to an allergic reaction to an allergen is detected by collecting a blood sample from the individual and assaying for activation of basophils in response to stimulation with an allergen. In particular, a microfluidic device is provided for automating the assay for detecting basophil activation as an indication of the susceptibility of an individual to an allergic reaction as well as kits containing such a device and diagnostic methods for using such a device for allergy testing. Additionally, such a microfluidic device can be adapted for multiplexed detection of allergic responses to multiple allergens by performing assays in parallel to detect the basophil responses to each allergen.

Provided herein are microfluidic viscometer assemblies and methods using the same, that include a microfluidic cartridge having microfluidic circuits that have channels adapted for viscosity determination without the need of a control fluid or oil. The viscometer assemblies also include an image recording system and a pressure control unit. In some embodiments, a temperature control unit is included as well. During methods using the viscometers provided herein, microfluidic cartridges can be loaded and removed from a viscometer, and disposed of.

The invention provides a method, apparatus and system for separating blood and other types of cellular components, and can be combined with holographic optical trapping manipulation or other forms of optical tweezing. One of the exemplary methods includes providing a first flow having a plurality of blood components; providing a second flow; contacting the first flow with the second flow to provide a first separation region; and differentially sedimenting a first blood cellular component of the plurality of blood components into the second flow while concurrently maintaining a second blood cellular component of the plurality of blood components in the first flow. The second flow having the first blood cellular component is then differentially removed from the first flow having the second blood cellular component. Holographic optical traps may also be utilized in conjunction with the various flows to move selected components from one flow to another, as part of or in addition to a separation stage.