Blood washing and separation system

What is claimed is: 1. A blood washing system, comprising: a rotor defining an internal chamber for receiving a multi-component fluid, the rotor being rotatable about a rotational axis at a first speed to fractionate the multi-component fluid into a plurality of fractions; a skimmer assembly including at least one buoy moveable along a buoy track positioned within the internal chamber, wherein the buoy defines an orifice fluidly connected to an access port in the rotor; and a brake operable to reduce rotation of the rotor to a second speed slower than the first speed to stack the plurality of fractions vertically within the rotor; wherein the buoy track extends radially outward from the access port such that the buoy moves radially outward from the rotational axis along the buoy track; wherein the buoy track is oriented downward such that the buoy moves downward as the buoy moves radially outward from the rotational axis along the buoy track; and wherein the buoy comprises a specific gravity corresponding to a selected fraction of the plurality of fractions such that the buoy floats on the selected fraction. 2. The blood washing system of claim 1 , the rotor having a radial wall extending from a bottom wall. 3. The blood washing system of claim 2 , wherein the rotor further comprises: a top cap engageable to the radial wall to enclose the internal chamber; wherein the top cap defines the access port. 4. The blood washing system of claim 1 , wherein the skimmer assembly further comprises: an access tube extending through the access port, the access tube defining an access channel for moving materials into and out of the internal chamber; wherein the orifice of the buoy is fluidly connected to the access channel. 5. The blood washing system of claim 4 , wherein the access tube is configured to be coupled to a device for supplying or withdrawing fluid from the internal chamber of the rotor. 6. The blood washing system of claim 4 , wherein the access tube is aligned with the rotational axis. 7. The blood washing system of claim 4 , wherein the rotor further comprises: a rotating seal positioned within the access port to prevent passage of material around the access tube. 8. A blood washing system, comprising: a rotor defining an internal chamber for receiving a multi-component fluid, the rotor being rotatable about a rotational axis at a first speed to fractionate the multi-component fluid into a plurality of fractions; and a skimmer assembly including at least one buoy moveable along a buoy track positioned within the internal chamber, wherein the buoy defines an orifice fluidly connected to an access port in the rotor, the skimmer assembly further including an access tube extending through the access port, the access tube defining an access channel for moving materials into and out of the internal chamber; wherein the orifice of the buoy is fluidly connected to the access channel; wherein the buoy comprises a specific gravity corresponding to a selected fraction of the plurality of fractions such that the buoy floats on the selected fraction; wherein the buoy track extends radially outward from the access tube such that the buoy moves radially outward from the rotational axis along the buoy track; and wherein the buoy track is oriented downward such that the buoy moves downward as the buoy moves radially outward from the rotational axis along the buoy track. 9. The blood washing system of claim 4 , wherein the skimmer assembly comprises: a first buoy defining a first orifice and moveable on a first buoy track; and a second buoy defining a second orifice and moveable on a second buoy track; wherein the first buoy track and the second buoy track extend radially outward from the rotational axis in opposite directions to balance the rotor during rotation. 10. The blood washing system of claim 9 , wherein the skimmer assembly further comprises: an adapter having a plurality of connectors including: a first connector connected to the first orifice, and a second connector connected to the second orifice; wherein the adapter is fluidly connected to the access channel to connect the first and second buoys to the access tube. 11. The blood washing system of claim 2 , wherein the bottom wall of the rotor includes a slanted surface slanted toward an apex. 12. The blood washing system of claim 1 , wherein the specific gravity of the buoy is less than 1 g/cc. 13. A method of washing blood, comprising: providing a multi-component fluid into an internal chamber of a rotor, wherein a skimmer assembly including at least one buoy moveable along a buoy track is positioned within the internal chamber; rotating the rotor at a first speed to fractionate the multi-component fluid into a plurality of fractions; braking the rotor to reduce the rotation of the rotor to a second speed slower than the first speed such that the plurality of fractions is stacked vertically within the rotor; wherein the buoy comprises a specific gravity corresponding to a selected fraction of the plurality of fractions such that the buoy floats on the selected fraction. 14. The method of claim 13 , wherein the buoy defines an orifice fluidly connected to an access port in the rotor. 15. The method of claim 14 , further comprising: withdrawing at least one fraction of the plurality of the fractions floating above the selected fraction through the orifice in the buoy. 16. The method of claim 13 , wherein the selected fraction comprises a supernatant over a solid fraction. 17. The method of claim 16 , further comprising: adding at least one of wash fluids and red cell compatible fluids to the internal chamber; and rotating the rotor to agitate the solid fraction and intermix the wash fluids with the solid fraction. 18. The method of claim 17 , further comprising: rotating the rotor to fractionate the wash fluid and solid fraction into a plurality of fractions; braking the rotor to reduce the rotation of the rotor to stack the plurality of fractions vertically arranged within the rotor; and withdrawing at least one fraction of the plurality of the fractions floating above the supernatant of the selected fraction through the orifice in the buoy. 19. The method of claim 16 , further comprising: adding a suspension quantity of wash fluids; rotating the rotor to agitate the solid fraction and intermix the wash fluids with the solid fraction; and withdrawing the intermixed solid and wash fluid mixture.