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.

A microfluidic device comprising a plurality of microreactors is provided. Each microreactor includes at least a first inlet and a second inlet for supplying a first fluid and a second fluid, respectively, to said microreactor and at least one waste channel for draining fluid from said microreactor. The device further comprises a shared first microfluidic supply system for supplying a first fluid to the first inlets of the plurality of microreactors, a shared second microfluidic supply system for supplying a second fluid to the second inlets of the plurality of microreactors. At least one of said inlets to each microreactor comprises at least one valve-less fluidic resistance element having a fluidic resistance that is substantially larger than the fluidic resistance of the corresponding shared microfluidic supply system. A chemical reaction sequencer apparatus including the microfluidic device and a method for supplying reagents to a plurality of microreactors are also provided.

A microfluidic test device has a body, a first chamber having an outlet provided with a first valve and holding a first buffer having a first buffer volume, a primary reaction chamber, a sample inlet for receiving and feeding a sample having a sample volume, into the microfluidic test device, a first fluid path connecting the outlet of the first chamber and the sample inlet, a second fluid path connecting the sample inlet and the primary reaction chamber, a primary test part having a primary test chamber, a third primary fluid path connecting the primary reaction chamber and the primary test part, a primary valve arranged in the third primary fluid path, a flow driving device configured to move fluid from the primary reaction chamber to the primary test part, and a heating assembly configured to heat a reaction fluid in the primary reaction chamber.

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.

Disclosed herein are microfluidic devices and methods to deliver concentration gradients to biological material such as oocytes and embryos for the purpose of cryopreparation, cryopreservation, or thawing. Cryopreservation methods, such as vitrification, involve the use of cryoprotectants to reduce formation of damaging ice crystals in cells during freezing. Microfluidic devices and methods described herein improve cell viability and efficiency during handling and cryopreservation of biological materials.

A system and method for automated single cell capture and processing is described, where the system includes a deck supporting and positioning a set of sample processing elements; a gantry for actuating tools for interactions with the set of sample processing elements supported by the deck; and a base supporting various processing subsystems and a control subsystems in communication with the processing subsystems. The system can automatically execute workflows associated with single cell processing, including mRNA capture, cDNA synthesis, protein-associated assays, and library preparation, for next generation sequencing.

A sample carrier may include a sample preparation module and an amplification module. A sample mixes with a lysis medium and a nucleic acid amplification medium in the sample preparation module and then flows into a plurality of microfluidic chambers in the amplification module. The microfluidic chambers have disposed therein primers configured to initiate amplification of one or more target nucleic acid sequences corresponding to one or more pathogens. The sample carrier is inserted into an apparatus that includes a plurality of Sight sources and a camera. The light sources illuminate the microfluidic chambers with excitation light, a fluorophore emits fluorescence light indicative of nucleic acid amplification in response to the excitation-light, and the camera captures images of the microfluidic chambers. A target nucleic acid sequence in the sample is indicated by the images showing an increasing fluorescence in a microfluidic chamber that has the primers for that sequence.

Provided herein, among other aspects, are methods and apparatuses for analyzing particles in a sample. In some aspects, the particles can be analytes, cells, nucleic acids, or proteins and can be contacted with a tag, partitioned into aliquots, detected by a ranking device, and isolated. The methods and apparatuses provided herein may include a microfluidic chip. In some aspects, the methods and apparatuses may be used to quantify rare particles in a sample, such as cancer cells and other rare cells for disease diagnosis, prognosis, or treatment.

The present invention provides systems, methods and apparatus for enabling a female user to hygienically collect a urine sample, the apparatus includes a container including a urine collection body for receiving a urine sample from the female user with and a separator mechanism for separating a first volume of urine of the urine sample to a first urine storage element and a second volume of urine of the urine sample to a second urine storage element, a lid for closing the container after the urine sample has been received and optionally a handle for holding the container.

A detection apparatus having a read head including a plurality of microfluorometers positioned to simultaneously acquire a plurality of the wide-field images in a common plane; and (b) a translation stage configured to move the read head along a substrate that is in the common plane. The substrate can be a flow cell that is included in a cartridge, the cartridge also including a housing for (i) a sample reservoir, (ii) a fluidic line between the sample reservoir and the flow cell; (iii) several reagent reservoirs in fluid communication with the flow cell, (iv) at least one valve configured to mediate fluid communication between the reservoirs and the flow cell; and (v) at least one pressure source configured to move liquids from the reservoirs to the flow cell. The detection apparatus and cartridge can be used together or independent of each other.