The present invention provides microfluidic technology enabling rapid and economical manipulation of reactions on the femtoliter to microliter scale.

Apparatus and methods for using a flow cell array are provided herein. A method includes delivering multiple items of chemical matter independently to multiple reaction sites of a flow cell array across multiple distinct instances of time; imaging multiple parallel chemical reactions at the multiple reaction sites of the flow cell array; and recording an emission from each of the multiple chemical reactions site.

Apparatus and methods for using a flow cell array are provided herein. A method includes determining placement of multiple reaction site openings, wherein each reaction site opening is connected to a first sub-surface channel; connecting the first sub-surface channel to two or more additional sub-surface channels by multiple vias; and providing a material for multiple reaction sites, wherein an overlap of the multiple reaction site openings and the material delineate the multiple reaction sites.

The present invention relates to a method for preparing glufosinate or an analogue and an intermediate thereof. The method comprises: a) reacting a compound of formula (II), an alcohol of formula (III) and a compound of formula (V); and b) hydrolyzing the product of the reaction above to obtain glufosinate of formula (IV) or an analogue thereof.

The present invention provides microfluidic technology enabling rapid and economical manipulation of reactions on the femtoliter to microliter scale.

The present invention provides microfluidic technology enabling rapid and economical manipulation of reactions on the femtoliter to microliter scale.

Apparatus and methods for using a flow cell array are provided herein. An apparatus includes an array comprising one or more pixels, wherein each of the one or more pixels comprises multiple reaction sites openings; a first set of one or more sub-surface channels, wherein each of the multiple reaction site openings is connected to a sub-surface channel from the first set of one or more sub-surface channels; a second set of two or more sub-surface channels; and multiple vias connecting each channel from the first set of one or more sub-surface channels to (i) a first sub-surface channel from the second set of two or more sub-surface channels and (ii) a second sub-surface channel from the second set of two or more sub-surface channels.

Apparatus and methods for using a flow cell array are provided herein. A method includes determining placement of one or more reaction sites on a first component; providing a material for the one or more reaction sites in one or more surface channels of the first component; connecting the first component to a second component to form an array, wherein the one or more surface channels of the first component connect the one or more reaction sites with one or more vias, and wherein the second component comprises the one or more vias connected to multiple sub-surface channels; and aligning the one or more surface channels of the first component with the one or more vias of the second component to form a connection between the first component and the second component.

A kit and a method for enriching target nucleic acid sequences from a biological sample are disclosed. The method includes preparing, and contacting with the biological sample, a first RNA probe set and a second RNA probe set respectively targeting both of the two antiparallel strands of a duplex segment in each target nucleic acid sequence. Each RNA probe in the first RNA probe set and the second RNA probe set can be generated by chemical synthesis or by in vitro or in vivo transcription, and can be biotin-labelled to thereby allow capturing of the target nucleic acid sequences by magnetic beads labelled with streptavidin, or can be engineered to a microfluidic channel to facilitate the capturing. The method can be applied to capture double-stranded nucleic acid sequences or single-stranded nucleic acid sequences having duplex segments, and the nucleic acid sequences can include DNAs, RNAs, or DNA-RNA hybrid molecules.

The present invention provides microfluidic technology enabling rapid and economical manipulation of reactions on the femtoliter to microliter scale.