Multilayer hydrodynamic sheath flow structure

The invention claimed is: 1. A sheath flow structure for suspending a particle in a sheath fluid, comprising: a substrate having a primary sheath flow channel formed therein for conveying a sheath fluid; a sample inlet provided on a surface of the substrate for injecting a particle into the sheath fluid conveyed through the primary sheath flow channel; a first sheath fluid inlet; first and second sheath fluid branch channels configured to receive sheath fluid from the first sheath fluid inlet; a second sheath fluid inlet; third and fourth sheath fluid branch channels configured to receive sheath fluid from the second sheath fluid inlet; a primary focusing region downstream of the sample inlet and fluidically coupled to the primary sheath flow channel to receive the particle and focus the particle in at least a horizontal direction using sheath fluid from the first and second sheath fluid branch channels; and a secondary focusing region provided downstream of and fluidically coupled to the primary focusing region to receive the particle and to receive the sheath fluid from the third and fourth sheath fluid branch channels, the particle being focused in at least a vertical direction by the sheath fluid from the third and fourth sheath fluid branch channels. 2. The sheath flow structure of claim 1 , wherein the primary focusing region is configured to symmetrically receive sheath fluid from the first and second sheath fluid branch channels relative to a centerline of a sample fluid flowing in the primary focusing region. 3. The sheath flow structure of claim 1 , wherein the secondary focusing region is configured to symmetrically receive sheath fluid from the third and fourth sheath fluid branch channels relative to a centerline of a sample fluid flowing in the secondary focusing region. 4. The sheath flow structure of claim 1 , wherein the sample inlet, the first sheath fluid inlet and the second sheath fluid inlet are all provided on the same surface of the substrate. 5. The sheath flow structure of claim 1 , wherein a sample fluid channel, the first and second sheath fluid branch channels, and the third and fourth sheath fluid branch channels are formed when an upper substrate layer is stacked on a lower substrate layer. 6. The sheath flow structure of claim 1 , wherein the primary focusing region and the secondary focusing region are provided as portions of a primary flow channel, and wherein a width of the primary flow channel at an upstream end of the primary focusing region is greater than a width of the primary flow channel at a downstream end of the secondary focusing region. 7. The sheath flow structure of claim 1 , wherein the primary focusing region and the secondary focusing region are provided as portions of a primary flow channel and wherein a cross-sectional flow area of the primary flow channel at an upstream end of the primary focusing region is greater than a cross-sectional flow area of the primary flow channel at a downstream end of the secondary focusing region. 8. The sheath flow structure of claim 1 , wherein the primary focusing region is configured to receive sheath fluid to focus a sample fluid in a first direction, and wherein the secondary focusing region is configured to receive sheath fluid to focus the sample fluid in a second direction. 9. The sheath flow structure of claim 1 , wherein the primary focusing region is configured to receive sheath fluid to width-wise focus a sample fluid, and wherein the secondary focusing region is configured to receive sheath fluid to height-wise focus the sample fluid. 10. The sheath flow structure of claim 1 , further comprising a particle sorting system downstream of the secondary focusing region.