Apparatuses and a method for plate-based oligonucleotide synthesis are disclosed. In one example, an apparatus used in oligonucleotide synthesis includes a machined block to receive a commercially-available synthesis plate. A keeper is used to apply pressure to the commercially-available synthesis plate, and a sealing element is used to seal the commercially-available synthesis plate to the machined block. Other methods and apparatuses are disclosed.

Methods of preparing a crosslinked hydraulic fracturing fluid include combining a hydraulic fracturing fluid comprising a polyacrylamide polymer with a plurality of coated proppants. The plurality of coated proppants include a proppant particle and a resin proppant coating on the proppant particle. The resin proppant coating includes resin and a zirconium oxide crosslinker. The resin includes at least one of phenol, furan, epoxy, urethane, phenol-formaldehyde, polyester, vinyl ester, and urea aldehyde. Methods further include allowing the zirconium oxide crosslinker within the resin proppant coating to crosslink the polyacrylamide polymer within the hydraulic fracturing fluid at a pH of at least 10, thereby forming the crosslinked hydraulic fracturing fluid.

Methods of preparing a crosslinked hydraulic fracturing fluid include combining a hydraulic fracturing fluid comprising a polyacrylamide polymer with a plurality of coated proppants. The plurality of coated proppants include a proppant particle and a resin proppant coating on the proppant particle. The resin proppant coating includes resin and a zirconium oxide crosslinker. The resin includes at least one of phenol, furan, epoxy, urethane, phenol-formaldehyde, polyester, vinyl ester, and urea aldehyde. Methods further include allowing the zirconium oxide crosslinker within the resin proppant coating to crosslink the polyacrylamide polymer within the hydraulic fracturing fluid at a pH of at least 10, thereby forming the crosslinked hydraulic fracturing fluid.

Arrays of droplet-on-demand dispensers are controlled by a row-column addressing scheme that can reduce the number of on-chip address lines, thereby making it feasible to construct large dispenser arrays. Decoders are used to further reduce the number of control lines that select a specific address line. A microfluidic logic controller includes row-select lines, each coupled to dispensers disposed on the same row, and column-select lines, each coupled to dispensers disposed on the same column such that each dispenser is associated with a unique row-column address. A logic circuit can actuate a dispenser only if the logic circuit receives signals from both of the row-select line and the column-select line corresponding to the row-column address of the selected dispenser. Reagents can be dispensed from the dispenser array, thereby allowing for rapid formatting of a reagent library into microfluidic droplets.

Systems and methods for dispensing a liquid on a substrate are disclosed. The system may be used to coat a substrate and/or a sample (e.g., a biological sample) with a liquid. The system includes a rotating device configured to rotate about an axis and a substrate disposed on the rotating device. The substrate comprises a well configured to hold a liquid and the substrate is positioned on a surface of the rotating device perpendicular to and concentric with the axis. The system further includes a liquid handler configured to dispense the liquid into the well. The rotating device is configured to rotate at a speed sufficient to disperse the liquid within the well.

Apparatuses and a method for plate-based oligonucleotide synthesis are disclosed. In one example, an apparatus used in oligonucleotide synthesis includes a machined block to receive a commercially-available synthesis plate. A keeper is used to apply pressure to the commercially-available synthesis plate, and a sealing element is used to seal the commercially-available synthesis plate to the machined block. Other methods and apparatuses are disclosed.

A microreactor array platform and method for sealing a reagent in microreactors of an array of microreactors are provided. The microreactor array platform includes an array of microreactors, and a sealing film having a first surface and an opposite second surface, the sealing film configured to movably seal the array of microreactors. The microreactor array platform also includes an injector for delivering a reagent into the array of microreactors via a fluid path between the array and the second surface of the sealing film, and an applicator for directing a sealing liquid against the first surface of the sealing film. The microreactor array platform further includes a system for creating a pressure differential between the reagent in the injector and a space between the array of microreactors and the second surface of the sealing film.

A microreactor array platform and method for sealing a reagent in microreactors of an array of microreactors are provided. The microreactor array platform includes an array of microreactors, and a sealing film having a first surface and an opposite second surface, the sealing film configured to movably seal the array of microreactors. The microreactor array platform also includes an injector for delivering a reagent into the array of microreactors via a fluid path between the array and the second surface of the sealing film, and an applicator for directing a sealing liquid against the first surface of the sealing film. The microreactor array platform further includes a system for creating a pressure differential between the reagent in the injector and a space between the array of microreactors and the second surface of the sealing film.

Arrays of droplet-on-demand dispensers are controlled by a row-column addressing scheme that can reduce the number of on-chip address lines, thereby making it feasible to construct large dispenser arrays. Decoders are used to further reduce the number of control lines that select a specific address line. A microfluidic logic controller includes row-select lines, each coupled to dispensers disposed on the same row, and column-select lines, each coupled to dispensers disposed on the same column such that each dispenser is associated with a unique row-column address. A logic circuit can actuate a dispenser only if the logic circuit receives signals from both of the row-select line and the column-select line corresponding to the row-column address of the selected dispenser. Reagents can be dispensed from the dispenser array, thereby allowing for rapid formatting of a reagent library into microfluidic droplets.

A vacuum system, including a condenser including a first inlet, a first outlet, and a second outlet, a first ejector connected to a motive fluid source, and a second ejector connected to the motive fluid source and the condenser.