A biosensor apparatus is provided. The biosensor apparatus includes a base substrate; a first fluid channel layer on the base substrate and having a first fluid channel passing therethrough; a foundation layer on a side of the first fluid channel layer away from the base substrate, a foundation layer throughhole extending through the foundation layer to connect to the first fluid channel; and a micropore layer on a side of the foundation layer away from the base substrate, a micropore extending through the micropore layer to connect to the first fluid channel through the foundation layer throughhole. The micropore layer extends into the foundation layer throughhole and at least partially covers an inner wall of the foundation layer throughhole.

An electric field gradient focusing device is provided that includes: (i) a fluidic channel having an inlet and an outlet for a fluid, (ii) a first actuator configured to induce a fluid flow in the fluidic channel from the inlet to the outlet via AC electroosmosis, and (iii) a second actuator configured to generate a DC electric field gradient along at least part of the fluidic channel.

This disclosure provides an integrated and automated sample-to-answer system that, starting from a sample comprising biological material, generates a genetic profile in less than two hours. In certain embodiments, the biological material is DNA and the genetic profile involves determining alleles at one or a plurality of loci (e.g., genetic loci) of a subject, for example, an STR (short tandem repeat) profile, for example as used in the CODIS system. The system can perform several operations, including (a) extraction and isolation of nucleic acid; (b) amplification of nucleotide sequences at selected loci (e.g., genetic loci); and (c) detection and analysis of amplification product. These operations can be carried out in a system that comprises several integrated modules, including an analyte preparation module; a detection and analysis module and a control module.

To form a layer separating two volumes of aqueous solution, there is used an apparatus comprising elements defining a chamber, the elements including a body of non-conductive material having formed therein at least one recess opening into the chamber, the recess containing an electrode. A pre-treatment coating of a hydrophobic fluid is applied to the body across the recess. Aqueous solution, having amphiphilic molecules added thereto, is flowed across the body to cover the recess so that aqueous solution is introduced into the recess from the chamber and a layer of the amphiphilic molecules forms across the recess separating a volume of aqueous solution introduced into the recess from the remaining volume of aqueous solution.

Systems and methods for measuring hemoglobin, G6PD activity, and or bilirubin activity in a sample, including measuring the absorbance of a sample, removing background interfering signals, and quantifying the relevant analyte. Systems and methods for reconstituting a reagent in a droplet actuator. Systems and methods for separating plasma from a whole blood sample on a droplet actuator, including combining a sample droplet with an agglutination reagent droplet and using a novel combination of droplet operations to split the sample into a plasma and an agglutinated red blood cell fraction.

A mechanism is provided for presenting single strands of a double strand molecule to a membrane. The double strand molecule is driven to a first side of the membrane by an electric field. The membrane has a first and second nanopore spaced apart by a nanopore separation distance. The first strand of the double strand molecule is captured in the first nanopore when driven to the first side of the membrane. The second strand is captured in the second nanopore by having the nanopore separation distance between the first nanopore and the second nanopore corresponding to a strand separation distance between the first and second strands, and/or by having captured the first strand to limit diffusion of the second strand. The first and second strands respectively in the first and second nanopores are individually stretched, by the first and second strands recombining on the second side of the membrane.

A microchip includes a plurality of laminated elastic sheets. Each of the elastic sheets forming a first intermediate layer as an intermediate layer formed with the plurality of elastic sheets have an inadhesive section(s) for forming a first flow path on the first intermediate layer. Each of the elastic sheets for forming a second intermediate layer as an intermediate layer formed with the plurality of elastic sheets have an inadhesive section(s) for forming a second flow path on the second intermediate layer. An elastic sheet(s) interposed between the first and second intermediate layers has a connecting section(s) connecting the first flow path and the second flow path. A flow path width at the connecting section(s) of the first flow path is narrower than a flow path width at the connecting section(s) of the second flow path.

This disclosure relates to mesofluidic devices and methods for eluting and concentrating a plurality of nucleic acid molecules. The mesofluidic device includes a device frame having a bottom surface upon which is defined a first reservoir and the second reservoir. The first reservoir includes a first electrode, and the second reservoir includes a second electrode. The first and second electrodes are configured for electrical connection. The mesofluidic device includes an elongated channel extending between the first reservoir and the second reservoir. The mesofluidic device includes a first slot having a first slot width. The first slot is configured to receive an insert. The first slot intersects the elongated channel. The mesofluidic device includes a second slot having a second slot width. The second slot is configured to receive a separation material having a first porosity. The second slot intersects the elongated channel.

A method for concentrating electrically charged objects in a non-Newtonian liquid medium comprises: feeding a sample containing electrically charged objects into a channel having a flow axis, a first transverse cross-section orthogonal to the flow axis, and at least one second transverse cross-section orthogonal to the flow axis, one dimension of the second cross-section being less than the corresponding dimension of the first cross-section; and applying a hydrodynamic flow in a direction of the channel together with the application, in the opposite direction, of an electric field in the channel, thus making it possible to move the electrically charged objects in the channel along the flow axis from the first cross-section to the second cross-section, stop the objects, and concentrate the objects in at least one area upstream from the second transverse cross-section.

A sample processing apparatus (102) includes a plurality of processing stations (108) configured to process a sample that includes a DNA sample and an ILS substance carried by a sample carrier. One of the plurality of processing stations includes an electrophoresis processing station. The sample processing apparatus further includes an optical reader (110) that generates a plurality of DNA sample color group signals and an ILS signal based on a result of the electrophoresis processing station. One of the DNA sample color group signals includes at least the locus amelogenin X-peak. The sample processing apparatus further includes an ILS signal validator (112) that validates peaks of the ILS signal as true peaks of the ILS signal only if the amelogenin X-peak of the one of the DNA sample color group signals is found between two peaks of the ILS signal.