Abstract: Methods are described herein for isolating clonal populations of cells having a defined genetic modification. The methods are performed, at least in part, in a microfluidic device comprising one or more sequestration pens. The methods include the steps of: maintaining individual cells (or precursors thereof) that have undergone a genomic editing process in corresponding sequestration pens of a microfluidic device; expanding the individual cells into respective clonal populations of cells; and detecting, in one or more cells of each clonal population, the presence of a first nucleic acid sequence that is indicative of the presence of an on-target genome edit in the clonal population of cells. Also described are methods of performing genome editing within a microfluidic device, and compositions comprising one or more clonal populations of cells generated according to the methods disclosed herein.

Abstract: Methods are described herein for isolating clonal populations of cells having a defined genetic modification. The methods are performed, at least in part, in a microfluidic device comprising one or more sequestration pens. The methods include the steps of: maintaining individual cells (or precursors thereof) that have undergone a genomic editing process in corresponding sequestration pens of a microfluidic device; expanding the individual cells into respective clonal populations of cells; and detecting, in one or more cells of each clonal population, the presence of a first nucleic acid sequence that is indicative of the presence of an on-target genome edit in the clonal population of cells. Also described are methods of performing genome editing within a microfluidic device, and compositions comprising one or more clonal populations of cells generated according to the methods disclosed herein.

Abstract: Apparatuses and methods are described for the use of optically driven bubble, convective and displacing fluidic flow to provide motive force in microfluidic devices. Alternative motive modalities are useful to selectively dislodge and displace micro-objects, including biological cells, from a variety of locations within the enclosure of a microfluidic device.

Abstract: Methods are described herein for isolating clonal populations of cells having a defined genetic modification. The methods are performed, at least in part, in a microfluidic device comprising one or more sequestration pens. The methods include the steps of: maintaining individual cells (or precursors thereof) that have undergone a genomic editing process in corresponding sequestration pens of a microfluidic device; expanding the individual cells into respective clonal populations of cells; and detecting, in one or more cells of each clonal population, the presence of a first nucleic acid sequence that is indicative of the presence of an on-target genome edit in the clonal population of cells. Also described are methods of performing genome editing within a microfluidic device, and compositions comprising one or more clonal populations of cells generated according to the methods disclosed herein.

Abstract: In situ-generated microfluidic capture structures incorporating a solidified polymer network, methods of preparation and use, compositions and kits therefor are described. Microfluidic capture structures may be advantageously used for assays performed within the microfluidic environment, providing flexibility in assaying micro-objects such as biological cells. Assay reagents and analytes may be incorporated within the microfluidic capture structures.

Abstract: In situ-generated microfluidic isolation structures incorporating a solidified polymer network, methods of preparation and use, compositions and kits therefor are described. The ability to introduce in real time, a variety of isolating structures including pens and barriers offers improved methods of micro-object manipulation in microfluidic devices. The in situ-generated isolation structures may be permanently or temporarily installed.