Methods for cell washing with on-line dilution of cell feed

The invention claimed is: 1. A method for washing a suspension comprising blood cells having a known cellular concentration to achieve a final volume of washed blood cells having a specified concentration with a fluid circuit comprising a spinning membrane separator including a porous membrane and for which a maximum output concentration of the blood cells to be washed that can be processed by the separator without loss of the blood cells has been established, the fluid circuit further comprising an in-process container and a final product container, the method comprising an initial wash cycle in which the suspension of blood cells to be washed is flowed from a source container to the spinning membrane separator for washing and washed, concentrated blood cells are flowed from the spinning membrane separator to the in-process container, and one or more intermediate wash cycles in which blood cells are flowed from the in-process container to the spinning membrane separator for further washing and concentration and washed, concentrated blood cells are flowed either back into the in-process container for further washing or to the final product container, the method further comprising: a) determining a concentration ratio of the blood cells to be washed for each cycle in the washing procedure; b) determining a maximum input concentration of the blood cells to be washed by dividing the maximum output concentration by the concentration ratio; c) determining a volume of wash solution to be used for washing the blood cells for each wash cycle as being a volume sufficient to dilute the cellular concentration of the blood cells to be washed to the maximum input concentration over the entire course for each wash cycle to determine a total volume of wash solution to be used for the wash procedure; d) attaching to the fluid circuit one or more wash solution containers holding at least the total volume of wash solution to be used for the wash procedure; e) drawing blood cells from either the source container in a first wash cycle or from the in-process container in an intermediate wash cycle; f) adding wash solution from the one or more wash solution containers to dilute the blood cells so that the cellular concentration of the blood cells in the spinning membrane separator does not exceed the maximum input concentration; g) introducing the diluted blood cells into the spinning membrane separator; h) separating said blood cells from at least some of said wash solution; i) concentrating said blood cells; j) removing at least some of the concentrated blood cells from the spinning membrane separator through a first outlet to the in-process container; k) removing at least some of said separated wash solution from the spinning membrane separator through a second outlet to a waste container; l) continuously calculating the cellular concentration of the blood cells in the in-process container and comparing the determined cellular concentration to a cellular concentration specified for that wash cycle; and m) if the cellular concentration of the blood cells is substantially the same as the cellular concentration specified for that wash cycle, then exiting that wash cycle; or n) if the cellular concentration of the blood cells is not substantially the same as the cellular concentration specified for that wash cycle, then flowing the blood cells back to the spinning membrane separator and continuously adding wash solution in an amount that does not exceed the maximum input concentration based on the calculated cellular concentration of the blood cells in the in-process container. 2. The method of claim 1 further comprising if the cellular concentration of the blood cells is substantially the same as the cellular concentration specified for that wash cycle, the wash cycle is exited and the washed blood cells are transferred to the final product container. 3. The method of claim 1 further comprising if the cellular concentration of the blood cells is not substantially the same as the cellular concentration specified for that wash cycle, then continuing that wash cycle by returning to step e). 4. The method of claim 1 further comprising empirically deriving the maximum output concentration for the separator. 5. The method of claim 1 further comprising diluting said blood cells by combining said blood cells with said wash solution and introducing said combination of blood cells and wash solution into said separator. 6. The method of claim 1 comprising diluting said blood cells by first introducing said wash solution into said separator followed by adding blood cells to said separator. 7. The method of claim 1 wherein the concentration ratio of the blood cells to be washed is from 2:1 (for frozen, thawed blood cell products) to 10:1 (for fresh blood cell products). 8. The method of claim 1 wherein the maximum input concentration is from 3% (for fresh blood cell products) to 15% (for frozen, thawed blood cell products). 9. The method of claim 1 wherein the blood cells are fresh blood cell products. 10. The method of claim 1 wherein the blood cells are frozen, thawed blood cell products. 11. The method of claim 1 wherein the blood cells are red blood cells. 12. The method of claim 11 wherein the wash solution comprises a red blood cell additive solution comprising dextrose, mannitol and a buffer. 13. A system for processing biological fluids comprising: a fluid flow circuit including a container of biological fluid to be washed, a container of wash solution, and a separator having a relatively rotatable cylindrical housing and an internal member, wherein said cylindrical housing has an interior surface and said internal member has an exterior surface, said surfaces defining a gap therebetween, wherein at least one of said surfaces includes a porous membrane and for which a maximum output concentration that can be processed by the separator has been established, the separator further comprising an inlet and first and second outlets; and a programmable controller with a user interface, the controller being configured to perform the method of claim 1 . 14. The system of claim 13 wherein the porous membrane comprises pores ranging in size from 0.8 μm to 30 μm and has a thickness of from 10.0 μm to 50 μm. 15. The system of claim 14 wherein the porous membrane comprises polycarbonate.