System and device for high throughput generation of combinatorial droplets and methods of use

We claim: 1. A microfluidic system comprising: a microfluidic chip comprising a chip body defining: a droplet formation section comprising: a main channel, a sample input channel having a first end fluidly connected to said main channel and a second end configured to receive sample and rinsing fluid, an input-channel valve in said sample input channel to selectively allow and block fluid flow from said sample input channel to said main channel, a rinsing channel fluidly connected to said sample input channel at a position between said input-channel valve and said second end of said sample input channel, and a rinsing-channel valve in said rinsing channel to selectively allow and block fluid flow from said sample input channel to said rinsing channel, wherein said droplet formation section has a first configuration in which said input-channel valve is open and said rinsing-channel valve is closed to provide a sample droplet having a substantially predetermined volume in said main channel suspended in an inert fluid, and wherein said droplet formation section has a second configuration in which said input-channel valve is closed and said rinsing-channel valve is open such that rinsing fluid rinses said sample input channel by a flow of said rinsing fluid through said sample input channel and out said rinsing channel; a droplet splitting section fluidly connected to said main channel of said droplet formation section to receive said sample droplet from said main channel and split said sample droplet into a plurality of daughter droplets to be output from said droplet splitting section in a respective one of a plurality of secondary channels; and a reagent injection section fluidly connected to each of said plurality of secondary channels and having a corresponding plurality of reagent injection channels arranged such that each reagent of a plurality of reagents is injectable substantially simultaneously into a respective one of said plurality of daughter droplets while said daughter droplets are in said plurality of secondary channels to provide a plurality of sample-reagent droplets output in a corresponding one of a plurality of output channels; a first sample source selectively connected to said sample input channel; a second sample source selectively connected to said sample input channel; and a rinsing fluid source selectively connected to said sample input channel, wherein the plurality of output channels are fluidly connected to the plurality of secondary channels and are configured to receive the plurality of sample-reagent droplets, and wherein said droplet splitting section is a multistage droplet splitter. 2. A microfluidic system as in claim 1 , wherein an automated sample loading system is fluidly connected to said microfluidic chip. 3. A microfluidic system as in claim 1 , wherein an impedance detection system is fluidly connected to said microfluidic chip. 4. A microfluidic system as in claim 1 , wherein a sample detection system is fluidly connected to said microfluidic chip. 5. A microfluidic chip comprising a chip body defining: a droplet formation section comprising: a main channel, a sample input channel having a first end fluidly connected to said main channel and a second end configured to receive sample and rinsing fluid, an input-channel valve in said sample input channel to selectively allow and block fluid flow from said sample input channel to said main channel, a rinsing channel fluidly connected to said sample input channel at a position between said input-channel valve and said second end of said sample input channel, and a rinsing-channel valve in said rinsing channel to selectively allow and block fluid flow from said sample input channel to said rinsing channel, wherein said droplet formation section has a first configuration in which said input-channel valve is open and said rinsing-channel valve is closed to provide a sample droplet having a substantially predetermined volume in said main channel suspended in an inert fluid, and wherein said droplet formation section has a second configuration in which said input-channel valve is closed and said rinsing-channel valve is open such that rinsing fluid rinses said sample input channel by a flow of said rinsing fluid through said sample input channel and out said rinsing channel; a droplet splitting section fluidly connected to said main channel of said droplet formation section to receive said sample droplet from said main channel and split said sample droplet into a plurality of daughter droplets to be output from said droplet splitting section in a respective one of a plurality of secondary channels; and a reagent injection section fluidly connected to each of said plurality of secondary channels and having a corresponding plurality of reagent injection channels arranged such that each reagent of a plurality of reagents is injectable substantially simultaneously into a respective one of said plurality of daughter droplets while said daughter droplets are in said plurality of secondary channels to provide a plurality of sample-reagent droplets output in a corresponding one of a plurality of output channels; wherein the plurality of output channels are fluidly connected to the plurality of secondary channels and are configured to receive the plurality of sample-reagent droplets, and wherein said droplet splitting section is a multistage droplet splitter. 6. A microfluidic chip according to claim 5 , wherein said droplet formation section comprises a pressure relief channel to controllably regulate pressure on said sample droplet while being formed. 7. A microfluidic chip according to claim 5 , wherein said reagent injection section comprises a pressure relief channel to controllably regulate pressure on said plurality of daughter droplets while each of said plurality of reagents is being injected into a corresponding one of said plurality of daughter droplets. 8. A microfluidic chip according to claim 5 , further comprising a sample-reagent droplet splitting section fluidly connected to each of said plurality of output channels to receive said plurality of sample-reagent droplets and split each of said sample-reagent droplets into a plurality of daughter sample-reagent droplets to be output from said sample-reagent droplet splitting section in a respective one of a plurality of second output channels. 9. A microfluidic chip according to claim 8 , wherein said sample-reagent droplet splitting section is a multistage droplet splitter. 10. A microfluidic chip according to claim 8 , further comprising an incubation section fluidly connected to each of said plurality of second output channels such that each of said sample-reagent droplets flows into a respective one incubation channel so as to maintain identifiable sample and reagent information thereof. 11. A microfluidic chip according to claim 10 , wherein said incubation channels are of an equal length. 12. A microfluidic chip according to claim 5 , further comprising a section with detection channels wherein said detection channels are at least partially transparent for optical measurements. 13. A microfluidic chip according to claim 5 , wherein said reagent injection section further comprises: a reagent injection valve in each of said plurality of reagent injection channels to selectively allow and block fluid flow from each of said plurality of reagent injection channels to said plurality of secondary channels, a rinsing channel fluidly connected to each of said plurality of reagent injection channels, and a rinsing-channel valve in said rinsing channel to selectively allow and block fluid flow from