Spray chambers and methods of using them

What is claimed is: 1. A spray chamber configured to couple to a nebulizer at an inlet end to receive a liquid sample from the nebulizer and provide an aerosolized sample spray at an outlet end to an ionization device, the spray chamber comprising: an outer chamber comprising the inlet end, the outlet end and dual makeup gas inlet ports each configured to receive a gas to provide a tangential gas flow within the outer chamber; and an inner tube within the outer chamber, the inner tube comprising a plurality of internal microchannels configured to receive makeup gas introduced into the outer chamber from the dual makeup gas inlets, in which the inner tube is sized and arranged to provide a laminar flow between an outer surface of the inner tube and an inner surface of the outer chamber to reduce droplet deposition on the inner tube. 2. The spray chamber of claim 1 , wherein at least one microchannel of the plurality of microchannels is positioned to prevent backflow of the received liquid sample. 3. The spray chamber of claim 1 , wherein the outer chamber comprises rounded edges at the inlet end to promote the laminar flow. 4. The spray chamber of claim 1 , wherein the dual makeup gas inlets are positioned in a same radial plane. 5. The spray chamber of claim 1 , wherein the outer chamber further comprises a drain port. 6. The spray chamber of claim 1 , wherein the inner tube comprises a cone shape. 7. The spray chamber of claim 1 , wherein an inner diameter of the outer chamber is smaller at the outlet end than at the inlet end. 8. The spray chamber of claim 1 , wherein the dual makeup gas inlets are positioned adjacent to the inlet end of the outer chamber. 9. The spray chamber of claim 1 , wherein the dual makeup gas inlets are positioned adjacent to the outlet end of the outer chamber. 10. The spray chamber of claim 1 , wherein an inner diameter of the inner tube increases in a longitudinal direction from the inlet end toward the outlet end of the outer chamber. 11. The spray chamber of claim 1 , wherein an inner diameter of the inner tube decreases in a longitudinal direction from the inlet end toward the outlet end of the outer chamber. 12. The spray chamber of claim 1 , wherein the outer chamber comprises the dual makeup gas inlets adjacent to the inlet end, an inner diameter of the inner tube increases in a longitudinal direction from the inlet end toward the outlet end of the outer chamber, and an inner diameter of the outer chamber is smaller at the outlet end than at the inlet end. 13. The spray chamber of claim 1 , wherein the outer chamber comprises the dual makeup gas inlets adjacent to the inlet end, an inner diameter of the inner tube is substantially constant in a longitudinal direction, and an inner diameter of the outer chamber is smaller at the outlet end than at the inlet end. 14. The spray chamber of claim 1 , wherein the outer chamber comprises the dual makeup gas inlets adjacent to the outlet end, an inner diameter of the inner tube is smaller at the outlet end of the outer chamber than at the inlet end of the outer chamber, and an inner diameter of the outer chamber is substantially constant from the inlet end to the outlet end. 15. The spray chamber of claim 14 , wherein the outer chamber comprises internal rounded edges at the inlet end. 16. A spray chamber configured to fluidically couple to a liquid sample delivery device at an inlet end and to select and spray a single particle or cell at an outlet end to a ionization device fluidically coupled to the spray chamber, the spray chamber comprising an outer chamber comprising dual gas inlet ports each configured to fluidically couple to a makeup gas source configured to provide a makeup gas to provide tangential gas flow within the outer chamber, the spray chamber further comprising an inner tube within and coupled to the outer chamber, the inner tube comprising a plurality of microchannels each configured to receive the makeup gas to prevent droplets of the liquid sample from depositing on surfaces of the inner tube, wherein the inner tube is positioned to provide a laminar flow within the outer chamber to prevent droplet formation on inner surfaces of the outer chamber. 17. The spray chamber of claim 16 , wherein at least one microchannel of the plurality of microchannels is positioned to prevent backflow of the liquid sample in the outer chamber. 18. The spray chamber of claim 16 , wherein the outer chamber comprises rounded edges at the inlet end to promote the laminar flow. 19. The spray chamber of claim 16 , wherein the dual gas inlets are positioned in a same radial plane. 20. The spray chamber of claim 16 , wherein the outer chamber further comprises a drain port.