Systems and methods for real time calibration of pump stroke volumes during a blood separation procedure

The invention claimed is: 1. In a blood separation procedure having sequentially-performed draw and return phases including at least a first and a second draw phase separated by a first return phase, the procedure utilizing a tubing set comprising a tubing through which fluid is flowed and a reusable hardware component comprising at least one pump having a stroke volume, a rotational rate, and an inlet through which fluid is flowed by operation of the pump and a programmable controller for automatically performing the fluid processing procedure based at least in part on a fluid flow rate through the pump, the fluid flow rate being a product of the pump stroke volume and the pump rotational rate, a method for real time calibration of the pump stroke volume to achieve a target fluid flow rate comprising: a) programming the controller with first and second continuous functions defining a relationship between pump inlet pressure and pump stroke volume for each of the draw phase and the return phase; b) commencing the first draw phase of the blood separation procedure to operate the pump to draw blood through the tubing; c) measuring fluid pressure in the tubing at the inlet of the pump; d) calculating a current pump stroke volume for the first draw phase with the controller based on the continuous function for the draw phase and the pump rotational rate; e) determining an adjusted pump rotational rate utilized by the controller to control the procedure to achieve the target fluid flow rate; f) conforming the pump rotational rate to the adjusted pump rotational rate; g) upon completion of the first draw phase, commencing the first return phase; and h) upon completion of the first return phase, commencing the second draw phase. 2. The method of claim 1 wherein the relationship between pump inlet pressure and the pump stroke volume is determined empirically over a predetermined range of inlet pressures. 3. The method of claim 1 further comprising measuring the fluid pressure at the pump inlet at regular intervals during the fluid processing procedure. 4. The method of claim 3 wherein the regular intervals are based on a number of pump strokes. 5. The method of claim 3 wherein the regular intervals are based on time. 6. In a blood separation procedure having sequentially-performed draw and return phases including at least a first and a second draw phase separated by a first return phase, the procedure utilizing a tubing set comprising a tubing through which fluid is flowed and a reusable hardware component comprising at least one pump having a stroke volume, a rotational rate, and an inlet through which fluid is flowed by operation of the pump and a programmable controller for automatically performing the fluid processing procedure, wherein the controller is programmed with first and second continuous functions defining a relationship between pump inlet pressure and pump stroke volume for each of the draw phase and the return phase, and the controller controls the separation procedure based at least in part on a fluid flow rate through the pump, the fluid flow rate being a product of the pump stroke volume and the pump rotational rate, a method for real time calibration of the pump stroke volume to achieve a target fluid flow rate comprising: a) commencing the first draw phase of the blood separation procedure to operate the pump to draw blood through the tubing; b) measuring fluid pressure in the tubing at the inlet of the pump; c) calculating a current pump stroke volume and pump rotational rate for the first draw phase with the controller based on the continuous function for the draw phase and the pump rotational rate; d) determining an adjusted pump rotational rate utilized by the controller to control the procedure to achieve the target fluid flow rate; e) conforming the pump rotational rate to the adjusted pump rotational rate; f) upon completion of the first draw phase, commencing the first return phase; and g) upon completion of the first return phase, commencing the second draw phase. 7. The method of claim 6 wherein the relationship between pump inlet pressure and the pump stroke volume is determined empirically over a predetermined range of inlet pressures. 8. The method of claim 6 further comprising measuring the fluid pressure at the pump inlet at regular intervals during the fluid processing procedure. 9. The method of claim 8 wherein the regular intervals are based on a number of pump strokes. 10. The method of claim 8 wherein the regular intervals are based on time. 11. The method of claim 1 wherein the real time calibration method is used in conjunction with a second pump calibration method programmed into the controller different from the real time calibration method. 12. A blood processing system for processing whole blood or a whole blood component, the processing system comprising at least one pump and a controller with a user interface and having a fluid flow circuit having at least one tubing associated therewith, the controller being configured to perform the method of claim 1 . 13. The method of claim 11 wherein the second pump calibration method is based on a change in weight of reservoirs associated with performance of the first draw stage, and the adjusted pump rotational rate determined during the first draw phase is inputted into the second method. 14. The method of claim 13 wherein a second return phase is performed after the second draw phase comprising: i) measuring fluid pressure in the tubing at the inlet of the pump during the first return phase; j) calculating a current pump stroke volume for the first return phase with the controller based on the continuous function for the return phase; k) determining an adjusted pump rotational rate to be utilized by the controller; and l) upon completion of the second draw phase, commencing the second return phase using the adjusted pump rotational rate determined during the first return phase and the second pump calibration method. 15. The method of claim 1 wherein the pump is operated in a first direction during each draw phase and in a second direction opposite to the first direction in the first return phase.