Devices for simultaneous generation and storage of isolated droplets, and methods of making and using the same

What is claimed is: 1. A method of isolating a mixture comprising at least two different aqueous solutions, the method comprising: selectively introducing the at least two different aqueous solutions, including first and second aqueous solutions, and a separate non-aqueous fluid into at least one chamber based on pressure levels of the at least two different aqueous solutions and the non-aqueous fluid, such that the separate non-aqueous fluid isolates the first aqueous solution from the second aqueous solution prior to the second aqueous solution entering the at least one chamber. 2. A microfluidic device comprising: at least one isolation unit having at least one chamber; the at least one chamber configured to receive and hold at least two different aqueous solutions; and at least one capillary valve configured to allow for the at least two different aqueous solutions to be introduced into the at least one chamber without mixing prior to entering the at least one chamber based at least in part on pressure levels of the at least two different aqueous solutions, such that the at least two different aqueous solutions are isolated from one another prior to entering the at least one chamber. 3. The microfluidic device of claim 2 , wherein a relative volume of each of the at least two different aqueous solutions when introduced into the at least one chamber is determined by a location of a bypass capillary valve within the at least one chamber. 4. The microfluidic device of claim 2 , further comprising a main channel, wherein the at least one chamber is in fluid communication with the main channel via the at least one capillary valve, the main channel comprising an inlet, an outlet, an upstream portion, and a downstream portion. 5. The microfluidic device of claim 4 , wherein the upstream portion is disposed between the inlet and the downstream portion, and the downstream portion is disposed between the upstream portion and the outlet. 6. The microfluidic device of claim 4 , wherein the at least one chamber is at least two chambers, and wherein the at least one capillary valve includes a first capillary valve, a second capillary valve, and a third capillary valve. 7. The microfluidic device of claim 6 , further comprising: a first fluid path providing fluid communication between a first chamber of the at least two chambers and the upstream portion of the main channel, the first fluid path including the first capillary valve, the first capillary valve having a first pressure threshold; a second fluid path providing fluid communication between the first chamber and a second chamber of the at least two chambers, the second fluid path including the second capillary valve, the second capillary valve having a second pressure threshold; a third fluid path providing fluid communication between the second chamber and the downstream portion of the main channel, the third fluid path including the third capillary valve, the third capillary valve having a third pressure threshold; and a bypass fluid path providing fluid communication between one of the at least two chambers and the downstream portion of the main channel, the bypass fluid path including a bypass capillary valve having a bypass pressure threshold. 8. The microfluidic device of claim 7 , wherein the bypass fluid path provides fluid communication between the first chamber and the downstream portion, the bypass fluid path connecting to the first chamber upstream of the second fluid path. 9. The microfluidic device of claim 7 , wherein the bypass fluid path provides fluid communication between the second chamber and the downstream portion, the bypass fluid path connecting to the second chamber upstream of the third fluid path. 10. The microfluidic device of claim 8 , wherein the bypass fluid path is positioned at a location wherein introducing a first aqueous solution of the at least two different aqueous solutions fills a first portion of the at least two chambers and subsequently introducing a non-aqueous fluid fills a second portion of the at least two chambers, thereby separating the first aqueous solution from the upstream portion of the main channel, and wherein introducing a second aqueous solution of the at least two different aqueous solutions fills the second portion of the at least two chambers and forces the non-aqueous fluid out of the at least two chambers through the bypass fluid path. 11. The microfluidic device of claim 6 , wherein the at least two chambers is at least three chambers including a first chamber, a second chamber, and a third chamber. 12. The microfluidic device of claim 11 , further comprising: a first fluid path providing fluid communication between the first chamber of the at least three chambers and the upstream portion of the main channel, the first fluid path including the first capillary valve, the first capillary valve having a first pressure threshold; a second fluid path providing fluid communication between the first chamber and a second chamber of the at least three chambers, the second fluid path including the second capillary valve, the second capillary valve having a second pressure threshold; a third fluid path providing fluid communication between the second chamber and the third chamber of the at least three chambers, the third fluid path including the third capillary valve, the third capillary valve having a third pressure threshold; a fourth fluid path providing fluid communication between the third chamber and the downstream portion of the main channel, the fourth fluid path including a fourth capillary valve, the fourth capillary valve having a fourth pressure threshold; and a bypass fluid path providing fluid communication between one of the at least three chambers and the downstream portion of the main channel, the bypass fluid path including a bypass capillary valve having a bypass pressure threshold. 13. The microfluidic device of claim 7 , wherein the second pressure threshold is greater than the first pressure threshold, the third pressure threshold is greater than the second pressure threshold, and the bypass pressure threshold is greater than the second pressure threshold but less than the third pressure threshold. 14. The microfluidic device of claim 12 , wherein the second pressure threshold is greater than the first pressure threshold, the third pressure threshold is greater than the second pressure threshold, the fourth pressure threshold is greater than the third pressure threshold, and the bypass pressure threshold is greater than the third pressure threshold and less than the fourth pressure threshold. 15. The microfluidic device of claim 12 , wherein the bypass fluid path provides fluid communication between: i) the first chamber and the downstream portion, the bypass fluid path connecting to the first chamber upstream of the second fluid path; ii) wherein the bypass fluid path provides fluid communication between the second chamber and the downstream portion, the bypass fluid path connecting to the second chamber upstream of the third fluid path; or iii) wherein the bypass fluid path provides fluid communication between the third chamber and the downstream portion, the bypass fluid path connecting to the third chamber upstream of the fourth fluid path. 16. The microfluidic device of claim 15 , wherein the bypass fluid path is positioned at a location wherein introducing a first aqueous solution of the at least two different aqueous solutions fills a first portion of the at least three chambers and subsequently introducing a non-aqueous fluid fills a second portion of the at