Methods for multiple single-cell capturing and processing using micro fluidics

What is claimed is: 1. A method of preamplification utilizing a microfluidic device configured to capture and to process individual cells from a plurality of cells, the method comprising: priming the microfluidic device utilizing one or more solutions; flowing the plurality of cells through channels of the microfluidic device such that individual cells from the plurality of cells are captured at individual capture sites of the microfluidic device, wherein each said individual capture site is configured to capture a single cell and is coupled with an individual microfluidic multi-chamber reaction configuration; lysing the plurality of captured individual cells at the individual capture sites of the microfluidic device thereby releasing RNA from each lysed captured individual cell into the corresponding individual multi-chamber reaction configuration; performing reverse transcription of the released RNA of each lysed captured individual cell within the multi-chamber reaction configuration to produce reverse transcription products associated with each respective individual cell; and performing preamplification, within the multi-chamber reaction configuration, on the respective reverse transcription products associated with each respectively lysed individual cell to produce preamplification products associated with each individual captured cell, wherein the multi-chamber reaction configuration comprises a first reaction chamber, a second reaction chamber, a third reaction chamber, and a fourth reaction chamber fluidically linked in series such that a solution can flow from the capture site into the first reaction chamber, from the first reaction chamber into the second reaction chamber, and then into the third reaction chamber, and then into the fourth reaction chamber; and the solution can flow from the first reaction chamber to any one of the second, third and fourth reaction chambers without flowing through any other of the second, third and fourth reaction chambers; solution can flow from the second reaction chamber to the third reaction chamber without flowing through either of the first or fourth reaction chambers and solution can flow from the second reaction chamber to the fourth reaction chamber without flowing through the first or third reaction chambers; solution can flow from the third reaction chamber to the fourth reaction chamber without flowing through either of the first or second reaction chambers. 2. The method of claim 1 , further comprising: exporting the preamplification products from each multi-chamber reaction configuration through a harvest inlet associated with the specific individual configuration from a plurality of harvest inlets of the microfluidic device. 3. The method of claim 1 , further comprising loading the one or more solutions into the microfluidic device. 4. The method of claim 1 , wherein the one or more solutions includes at least one or more reagents or one or more buffers. 5. The method of claim 1 , further comprising loading the plurality of cells into the microfluidic device. 6. The method of claim 1 , further comprising imaging one or more of the captured individual cells on the microfluidic device. 7. The method of claim 1 , further comprising: loading at least one or more lysis reagents, one or more reverse transcription reagents, or one or more preamplification reagents into the microfluidic device. 8. The method of claim 2 , further comprising: removing one or more protective layers of one or more harvesting inlets; and harvesting the preamplification products from each respective harvest inlet from the plurality of harvest inlets of the microfluidic device. 9. The method of claim 1 , further comprising staining the one or more individual capture cells on the microfluidic device. 10. The method of claim 9 , further comprising determining whether the one or more individual captured cells are alive or dead based on the staining. 11. The method of claim 6 , further comprising determining whether the one or more individual captured cells are alive or dead based on the imaging. 12. The method of claim 1 , wherein the microfluidic device comprises: a plurality of capture configurations coupled in series, each respective capture configuration comprising: two or a plurality of bypass channels coupled with an input channel and an output channel; a capture nest coupled with said bypass channels and with a drain channel, wherein the capture nest is configured to capture an individual cell from the plurality of cells, wherein a cell that enters the capture nest stops flow though the drain channel; and wherein the capture nest and bypass channels are configured such that, when the capture nest is occupied by a captured cell, other cells of the plurality are diverted into the bypass channel(s) and flow to a downstream capture configuration; a plurality of multi-chamber reaction configurations, wherein each respective multi-chamber reaction configuration is coupled with a respective capture configuration from the plurality of capture configurations and is configured for single-cell processing. 13. A method of preamplification utilizing a microfluidic device configured to capture and to process individual cells from a plurality of cells, the method comprising: loading one or more solutions into the microfluidic device; priming the microfluidic device utilizing the one or more solutions; loading the plurality of cells into the microfluidic device; flowing the plurality of cells through the microfluidic device such that individual cells from the plurality of cells are captured at individual capture sites of the microfluidic device; imaging one or more of the captured individual cells on the microfluidic device; determining for each individual capture site the absence of a cell, the presence of one cell, or the presence of two cells, and then; loading at least one or more lysis reagents, one or more reverse transcription reagents, or one or more preamplification reagents into the microfluidic device; lysing the plurality of captured individual cells at the individual capture sites of the microfluidic device; performing reverse transcription, within the microfluidic device, on the plurality of individual lysed cells to produce reverse transcription products associated with each respective individual cell; performing preamplification, within the microfluidic device, on the respective reverse transcription products associated with each respectively lysed individual cell to produce preamplification products associated with each individual capture cell; delivering the preamplification products associated with each individual capture cell to a respective harvest inlet from a plurality of harvest inlets of the microfluidic device; removing one or more protective layers of one or more harvesting inlets; and harvesting the preamplification products from each respective harvest inlet from the plurality of harvest inlets of the microfluidic device.