Pulsed laser triggered high speed microfluidic switch and applications in fluorescent activated cell sorting

What is claimed is: 1. A high-speed microfluidic switch, said switch comprising: a first microfluidic channel comprising a bifurcation into a first path and a second path; a liquid or gel filled second microfluidic channel adjacent to said first microfluidic channel where said liquid or gel flows through said second microfluidic channel and said second microfluidic channel is disposed such that formation of a gas or plasma cavitation bubble in the liquid or gel in said second microfluidic channel redirects particles flowing into said first path so they flow into said second path; a pulse laser focused on said second microfluidic channel and configured to provide sufficient energy to form said cavitation bubble; wherein said switch comprises a wall between said second channel and said first channel where said second microfluidic channel and said wall are disposed such that formation of a gas or plasma bubble in said second channel deforms said wall to redirect particles flowing into said first path so they flow into said second path. 2. A high-speed microfluidic switch, said switch comprising: a first microfluidic channel comprising a bifurcation into a first path and a second path; a liquid or gel filled second microfluidic channel adjacent to said first microfluidic channel and disposed such that formation of a gas or plasma cavitation bubble in the liquid or gel in said second microfluidic channel redirects particles flowing into said first path so they flow into said second path, wherein said liquid or gel comprises light-absorbing dye molecules or nanoparticles; a wall or a port, or a channel between said second channel and said first channel; and a pulse laser focused on said second microfluidic channel and configured to provide sufficient energy to form said cavitation bubble. 3. A method for detecting or sorting particles or cells, said method comprising: flowing said particles or cells through a switch according to claim 2 ; and activating said pulse laser to form a cavitation bubble that channels desired particles into a desired flow path. 4. A high-speed microfluidic switch, said switch comprising: a first microfluidic channel comprising a bifurcation into a first path and a second path; a second microfluidic channel adjacent to said first microfluidic channel; a connecting port or channel connecting said second microfluidic channel to said first microfluidic channel; a liquid or gel-filled third microfluidic channel adjacent to said second microfluidic channel disposed such that the formation of a cavitation bubble in the liquid or gel in said third channel induces a fluid flow or pressure through said connecting port or channel that redirects particles flowing into said first path so they flow into said second path, wherein said liquid or gel comprises light-absorbing dye molecules or nanoparticles; and a pulse laser focused on said third microfluidic channel and configured to provide sufficient energy to form said cavitation bubble. 5. A method for detecting or sorting particles or cells, said method comprising: flowing said particles or cells through a switch according to claim 4 ; and activating said pulse laser to form a cavitation bubble that channels desired particles into a desired flow path. 6. The switch according to any one of claims 1 , 2 , or 4 , wherein said first microfluidic channel is a Y-shaped microchannel. 7. The switch according to any one of claims 1 , 2 , or 4 , wherein said first microfluidic channel is formed from an elastomeric material. 8. The switch of claim 7 , wherein said elastomeric material is PDMS. 9. The switch according to any one of claims 1 , 2 , or 4 , wherein said laser provides a pulse energy and frequency to permit switching of particles from said first path to said second path in a time of less than 100 μ sec. 10. The switch of claim 9 , wherein said laser provides a pulse energy and frequency to permit switching of particles from said first path to said second path in a time of less than 70 μ sec or less. 11. The switch according to any one of claims 1 , 2 , or 4 , wherein said liquid or gel is a liquid. 12. The switch according to any of claims 1 , 2 , or 4 , wherein said switch is disposed on a substrate comprising a material selected from the group consisting of a polymer, a plastic, a glass, quartz, a dielectric material, a semiconductor, silicon, germanium, ceramic, and a metal or metal alloy. 13. The switch according to any of claims 1 , 2 , or 4 , wherein said switch is integrated with other microfluidic components selected from the group consisting of PDMS channels, wells, and/or valves. 14. The switch according to any of claims 1 , 2 , or 4 , wherein said switch is a component of a lab-on-a-chip. 15. The switch according to any of claims 1 , 2 , or 4 , wherein said switch is a component of a cell sorter. 16. A system for controlling microfluidic flow, said system comprising a switch according to any of claims 1 , 2 , or 4 , and components for detecting particles or cells in said system. 17. A method for detecting or sorting particles or cells, said method comprising: flowing said particles or cells through a switch according to any of claim 1 , 2 , or 4 ; and activating said pulse laser to form a cavitation bubble that channels desired particles into a desired flow path.