A flow control and processing cartridge includes a cartridge body and a reaction chip. The cartridge body includes plural first chambers and plural first channels for storing and processing at least one of a sample, a reagent and a buffer and configured to perform nucleic acid extraction. The reaction chip is in conjunction with the cartridge body and includes plural second chambers and plural second channels configured to store and process an amplification reaction solution, and at least two fluidic networks configured to perform nucleic acid amplification and detection. One of the fluidic networks includes plural detection wells, a main fluid channel connected with the detection wells and configured to dispense the sample or control liquids into the detection wells, and a gas releasing channel connected with the detection wells and configured to release gas from the detection wells, wherein one of the fluidic networks is configured for quality control.

A device for detecting nucleic acids in a biological sample has a sample port, a lysis station and a sample conduit configured to mix a sample and lysis agent to form a sample-lysis mixture, pass the sample-lysis mixture across a solid-state membrane to capture nucleic acids in the biological sample therein, and receive the remainder of the sample-lysis mixture in a waste chamber. The wash station is configured to introduce the wash solution following the sample-lysis mixture, pass the wash solution across the solid-state membrane to purify nucleic acids captured therein, and receive the wash solution from the solid-state membrane in the waste chamber. The elution station is configured to pass the eluent across the solid-state membrane, elute captured nucleic acids from the solid-state membrane, and pass the captured nucleic acids into one or more reaction chambers for amplifying and detecting the captured nucleic acids.

In various embodiments methods of determining methylation of DNA are provided. In one illustrative, but non-limiting embodiment the method comprises i) contacting a biological sample comprising a nucleic acid to a first matrix material comprising a first column or filter where said matrix material binds and/or filters nucleic acids in said sample and thereby purifies the DNA; ii) eluting the bound DNA from the first matrix material and denaturing the DNA to produce eluted denatured DNA; iii) heating the eluted DNA in the presence of bisulfite ions to produce a deaminated nucleic acid; iv) contacting said deaminated nucleic acid to a second matrix material comprising a second column to bind said deaminated nucleic acid to said second matrix material; v) desulfonating the bound deaminated nucleic acid and/or simultaneously eluting and desulfonating the nucleic acid by contacting the deaminated nucleic acid with an alkaline solution to produce a bisulfite converted nucleic acid; vi) eluting said bisulfite converted nucleic acid from said second matrix material; and vii) performing methylation specific PCR and/or nucleic acid sequencing, and/or high resolution melting analysis (HRM) on said bisulfite-converted nucleic acid to determine the methylation of said nucleic acid, wherein at least steps iv) through vi) are performed in a single reaction cartridge.

A sample processing tubule is provided including, from a proximate to a distal end, an opening through which a sample is introducible, at least three segments, and an reagent introduction port operatively connected to a distal segment of the at least three segments. The reagent introduction port enables the addition of a reagent in the distal segment of the tubule, enabling the user to create a customizable assay tubule.

Intermittent warming of a biologic sample including a nucleic acid includes receiving at a first end of a channel of a microfluidic device, a biologic sample including a nucleic acid, and warming a subset of a plurality of heating elements disposed adjacent to the channel. The method includes warming the heating elements to a particular temperature of a particular warming and cooling protocol. The method includes moving the biologic sample from the first end of the channel to a second end of the channel opposite the first end at a particular flow rate associated with the warming and cooling protocol, and intermittently warming the biologic sample using the subset of heating elements while the biologic sample moves from the first end of the channel to the second end of the channel.

Methods and apparatus for long read, label-free, optical nanopore long chain molecule sequencing. In general, the present disclosure describes a novel sequencing technology based on the integration of nanochannels to deliver single long-chain molecules with widely spaced (>wavelength), ˜1-nm aperture “tortuous” nanopores that slow translocation sufficiently to provide massively parallel, single base resolution using optical techniques. A novel, directed self-assembly nanofabrication scheme using simple colloidal nanoparticles is used to form the nanopore arrays atop nanochannels that unfold the long chain molecules. At the surface of the nanoparticle array, strongly localized electromagnetic fields in engineered plasmonic/polaritonic structures allow for single base resolution using optical techniques.

A microfluidic device comprises: a sensor provided in a sensing chamber; a liquid inlet and liquid outlet connecting to the sensor chamber for respectively passing liquid into and out of the sensing chamber and; a sample input port in fluid communication with the liquid inlet; a liquid collection channel downstream of the sensing chamber outlet; a flow path interruption between the liquid outlet and the liquid collection channel, preventing liquid from flowing into the liquid collection channel from upstream; a buffer liquid filling from the sample input port to the sensing chamber, and filling the sensing chamber and filing from the liquid outlet to the flow path interruption; an activation system operable to complete the flow path between the liquid outlet and the liquid collection channel such that the sensor remains unexposed to gas or a gas/liquid interface.

The present invention relates to a device and a method for qualitative and quantitative analysis of heavy metals and more particularly provides a device and a method for qualitative and quantitative analysis of heavy metals utilizing a rotary disc system.

Provided are methods, devices, and kits for the isolation of extracellular vesicles using silicon nanomembranes. A method for EV isolation includes the steps of collecting a biofluid sample, contacting the biofluid sample with a pre-filtration membrane, thereby forming a first filtrate and a first retentate, optionally, washing the first retentate of the pre-filtration membrane, contacting the first filtrate from the pre-filtration membrane with a capture membrane, thereby forming a second filtrate and a second retentate, optionally, washing the second retentate, and eluting the second retentate from the capture membrane or lysing the second retentate to recover the contents.

There is provided a sample processing cartridge comprising a. a sample entry location; b. a closed sample processing chamber; c. a sample analysis location comprising a sample analysis well; d. a first channel fluidly connecting the sample entry location and the sample processing chamber; e. a second channel connecting the sample analysis location and the sample processing chamber, the second channel comprising a closed or closable second channel valve;
wherein the sample processing chamber comprises a second channel port providing fluid connection between the second channel and the sample processing chamber, the second channel port being positioned in a sample accumulating region of the sample processing chamber.

There is also provided a sample processing system comprising the cartridge, and methods of use of the cartridge and processing system in a sample processing assay.