Methods for controlling a spinning membrane separator so as to limit fouling of the membrane by changing the rotation rate of the spinning membrane in response to the fouling rate, while maintaining a constant outlet cellular concentration. Increasing the spinner rotation rate will increase the strength of the Taylor vortices generated within the separator by the spinning of the membrane, which should reduce fouling of the membrane. The goal of the method is to rotate the spinning membrane at the slowest rate possible without unacceptable fouling. Two specific methods to control fouling are disclosed. In a first, unidirectional method, the spin rate of the membrane is only increased in response to undesirable fouling in order to prevent the fouling from continuing. In a second, bidirectional method, the spin rate of the membrane may be either increased or decreased in response to the measured fouling rate in order to maintain the fouling rate within a desired range.

A method for automated processing of a cellular product comprising target substrate cells, the method comprising providing a separation apparatus configured to associate with a disposable sterile circuit comprising a separator in communication with the cellular product. The apparatus and disposable sterile circuit are configured to remove platelets from the cellular product to form a platelet-depleted cellular product, resuspend the platelet-depleted cellular product in media to form a resuspended platelet-depleted cellular product, receive an agent having an association with the target substrate cells of the resuspended platelet-depleted cellular product, incubate the agent with the target substrate cells over a period sufficient for the agent to bind with and/or enter the target substrate cells to form a first mixture comprising agent-target substrate cell complexes, unbound/unassociated agent, and non-target substrate cells, and remove unbound/unassociated agent to form a second mixture comprising the agent-target substrate cell complexes and non-target substrate cells.

A cell processing system includes at least one processor connectable to a source container filled with a biological fluid, the at least one processor including a spinning membrane configured to receive and separate target cells from the biological fluid, the target cells exiting at a first outlet, one or more containers selectively connected to the first outlet; and, and a magnet. The system also includes a controller coupled to the at least one processor and configured to operate the spinning membrane to receive biological fluid from the source container and to direct the target cells to one of the one or more containers, to pause to permit magnetic particles to be associated with the target cells, and to operate the spinning membrane to receive the contents of one of the one or more containers with the magnet applied to the target cells associated with the magnetic particles.

Systems and methods for the washing and processsing of biological fluid/biological cells are disclosed. The systems and methods prevent inadvertent target cell loss by monitoring pressure and providing for the dilution of the cell feed.

A fluid processing system for controlling fluid flow comprises a cassette having a defined passageway on a first side. The first side includes flexible sheeting disposed over the passageway. The system comprises a durable processing device configured to engage the first side of the cassette, the durable processing device comprising a valve actuator configured to engage the flexible sheeting at a valve location along the passageway. The system comprises a first pump configured to draw fluid away from the valve location along the passageway. The first pump is disposed downstream of the valve location. The system comprises a second pump configured to pump fluid towards the valve location along the defined passageway. The second pump is disposed upstream of the valve location. The first and second pumps are configured to operate in concert and configured to provide pressure to prevent collapsing of the flexible sheeting against the passageway during operation.

Systems and methods for the washing and processing of biological fluid/biological cells are disclosed. The systems and methods utilize a disposable fluid circuit including a spinning membrane separation device to wash the biological cells.

A method and system for collecting leukoreduced red blood cells employing a spinning membrane separator including a housing having an upper end region and a lower end region in an operating position with a red blood cell outlet in the upper end region of the housing and a whole blood inlet in the lower end region of the housing. The method and system provide for flowing additive solution into the whole blood inlet of the housing to prime the separator; flowing whole blood into the whole blood inlet of the housing; separating red blood cells from the whole blood; flowing separated red blood cells out of the red blood cell outlet of the housing; combining the separated red blood cells with additive solution: passing the separated red blood cells and additive solution combination through a leukoreduction filter; and collecting the filtered red blood cells and additive solution.

A cell processing system includes a processor to receive a biological fluid to be processed, a controller coupled to the processor, the controller configured to operate the processor according to at least one modifiable process parameter, and at least one input coupled to the controller, the at least one input configured to receive an identifier and at least one process parameter control associated with the at least one process parameter that limits modification of the at least one process parameter if applied. The controller is configured to determine if the identifier is associated with an administrator authorization and to apply the at least one processor parameter control to the at least one process parameter if the identifier is associated with an administrator authorization.

Systems and methods for performing hemodialysis to remove metabolic waste from the blood of a patient are disclosed. The systems and methods preferably comprise at least one blood processing apparatus that receives whole blood from a patient. Cellular blood components are removed from the whole blood by hemofiltration, to provide filtered plasma comprising metabolic waste that is substantially reduced of blood cells. The cellular blood components may be returned to the patient. The filtered plasma comprising waste may be removed from the blood processing apparatus through a waste path for further processing in a separate apparatus, or in the same apparatus in a second stage processing procedure to remove metabolic waste components and excess water from the plasma by hemodialysis. At least one of the hemofiltration and hemodialysis processing apparatus comprises a Taylor vortex-enhanced separation apparatus.

A method of processing blood includes receiving from a touch screen user input data for a protocol for a wash procedure. The user input data includes a numeric value. The method includes storing the protocol in a memory, receiving an identifier from a user, determining if the identifier permits the user to modify the protocol and receiving a modification of the protocol from the user. The method includes providing a plurality of authorizations, a second authorization being a default and an administrator authorization permitting the user to change a setting. The method includes comparing a password to a password stored in memory and, if there is a match, determining that the password is associated with an administrator. If a command to change the setting is received, the command is applied to change the setting. The blood is processed employing a wash procedure using the modified protocol and the changed setting.