A nucleic acid amplifier may include a sample preparation zone, a fluid ejector, an amplification zone and a capillary break between the amplification zone and the fluid ejector.

A microfluidic device for analysing a specimen comprises a loading area for loading the specimen of interest and an analytical column. The loading area is connected on two sides to a first duct and a second duct respectively, both integrated in the microfluidic device. The microfluidic device comprises a first integrated input connected to the first duct to take the specimen into the loading area, a first integrated output connected to the second duct to discharge the rest of the specimen, once it has flown through the loading area, and a second integrated output downstream the analytical column. The first integrated output is arranged for during a first loading period of time being in circuit connected to the first integrated input so as to load the sample into the loading zone of the device while preventing loss of specimen during loading of the sample into the analytical column.

Provided herein are methods of splitting droplets containing magnetically responsive beads in a droplet actuator. A droplet actuator having a plurality of droplet operations electrodes configured to transport the droplet, and a magnetic field present at the droplet operations electrodes, is provided. The magnetically responsive beads in the droplet are immobilized using the magnetic field and the plurality of droplet operations electrodes are used to split the droplet into first and second droplets while the magnetically responsive beads remain substantially immobilized.

The invention concerns a lateral flow device, system, kit and method for analyzing a fluid sample. The device comprises a support structure, a flow channel formed in the support structure, and an injection zone in fluidic connection with the flow channel for introducing the fluid sample into the flow channel. According to the invention the flow channel comprises at least two indicator zones at least one of which is capable of producing an optically detectable response signal when interacting with the fluid sample, and the indicator zones are arranged at least partly adjacent to each other on different sections of the flow channel. The invention allows for low-cost imaging devices, such as cameras of mobile phones to be used for making challenging lateral flow diagnostics on a variety of fields of technology.

There are provided methods, and devices for assaying for a binding interaction between a protein, such as a monoclonal antibody, produced by a cell, and a biomolecule. The method may include retaining the cell within a chamber having an aperture; exposing the protein produced by the cell to a capture substrate, wherein the capture substrate is in fluid communication with the protein produced by the cell and wherein the capture substrate is operable to bind the protein produced by the cell; flowing a fluid volume comprising the biomolecule through the chamber via said aperture, wherein the fluid volume is in fluid communication with the capture substrate; and determining a binding interaction between the protein produced by the cell and the biomolecule.

There are provided methods, and devices for assaying for a binding interaction between a protein, such as a monoclonal antibody, produced by a cell, and a biomolecule. The method may include retaining the cell within a chamber having an aperture; exposing the protein produced by the cell to a capture substrate, wherein the capture substrate is in fluid communication with the protein produced by the cell and wherein the capture substrate is operable to bind the protein produced by the cell; flowing a fluid volume comprising the biomolecule through the chamber via said aperture, wherein the fluid volume is in fluid communication with the capture substrate; and determining a binding interaction between the protein produced by the cell and the biomolecule.

An apparatus for detecting a disease in a biological subject comprises a delivery system and at least two sub-equipment units which are combined or integrated in the apparatus, wherein the delivery system is capable of delivering the biological subject to at least one of the sub-equipment units and each sub-equipment unit is capable of detecting at least one property of the biological subject. Methods for detecting a disease with the apparatus are also provided.

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.

A microfabricated sheath flow structure for producing a sheath flow includes a primary sheath flow channel for conveying a sheath fluid, a sample inlet for injecting a sample into the sheath fluid in the primary sheath flow channel, a primary focusing region for focusing the sample within the sheath fluid and a secondary focusing region for providing additional focusing of the sample within the sheath fluid. The secondary focusing region may be formed by a flow channel intersecting the primary sheath flow channel to inject additional sheath fluid into the primary sheath flow channel from a selected direction. A sheath flow system may comprise a plurality of sheath flow structures operating in parallel on a microfluidic chip.

The present invention relates to, inter alia, a microfluidic device for performing single cell genomic DNA isolation and amplification under flow. The microfluidic device comprises a solid substrate having one or more microfluidic channel system formed therein. Each microfluidic channel system of the microfluidic device comprises: (a) an intake region comprising a single microchannel; (b) a plurality of cell segregation microchannels; (c) a cell capture site located downstream of each cell segregation microchannel; and (d) a DNA capture array positioned downstream of the cell capture site and comprising a plurality of micropillars. Also disclosed is a whole genome amplification system that includes the microfluidic device of the present disclosure, as well as a method for conducting single cell DNA analysis via on-chip whole genome amplification while under flow, and a method for multiple displacement amplification (MDA) reactions of one or more nucleic acid sequence isolated single cells.