A centrifugal separation device of a blood component collection system, which is one form of a biological component collection system, performs a pressure release step of stopping a collection and returning pump at the end of a returning operation, and releasing a positive pressure inside a filter structural member, a clamp closure step of closing an inlet flow passage and an outlet flow passage of the filter structural member, and a collection operation starting step of starting a subsequent collection operation.

Disclosed are a blood filter which exhibits excellent leukocyte elimination performance as well as significantly improved blood throughput per unit time and erythrocyte recovery rate and a method of manufacturing the same. The blood filter of the present invention includes a pre-treatment filter which is a laminate of first non-woven fabrics having a mean fiber diameter of 5 to 30 μm and a mean pore size of 10 to 30 μm, and a main filter which is a laminate of second non-woven fabrics having a mean fiber diameter of 1 to 5 μm, a mean pore size of 5 to 10 μm and a mean pore size distribution rate of 30% or more. A filling density of the pre-treatment filter and a filling density of the main filter, with respect to a target blood throughput of the blood filter, are 0.1 g/100 ml to 1 g/100 ml and 1 g/100 ml to 3 g/100 ml, respectively.

Systems and methods are provided for depleting platelets from blood. The system includes a multi-stage blood separation chamber in which blood is separated into red blood cells and platelet-rich plasma. The platelet-rich plasma is conveyed from a first stage of the chamber to a second stage, where it is separated into platelets and platelet-poor plasma. The platelet-poor plasma is conveyed out of the chamber while the platelets are allowed to accumulate in the second stage of the chamber. When a controller of the system has determined that the maximum chamber capacity of platelets has been accumulated in the second stage of the chamber, the platelets are conveyed out of the chamber to a waste container. The cycle of separating blood into its components, accumulating platelets in the chamber, and then flushing the platelets from the chamber is repeated until a target platelet concentration of the blood is achieved.

An autologous cell concentrating system and method are disclosed. The system has a blood separation component, a first vessel, a second vessel, a first valve, a second valve, and a concentration and flow logic and control component. The concentration and flow logic and control component is configured to: determine a first volume of a target cell-poor fraction in the first vessel to mix with a target cell-rich fraction in the second vessel in order to form a target cell-rich concentrate having a concentration of target cells that is within a target concentration range; and control the second valve to transfer the first volume of the target cell-rich fraction from the first vessel to the second vessel to form the target cell-rich concentrate. The target concentration range is between 1.0 and 1.5×106 target cells/μL.

A method of collecting plasma includes receiving donor parameters at a controller of a plasma collection device electronically from a donor management system. The method includes storing a target volume for raw plasma which is based at least in part on donor height and weight used to calculate total donor blood volume, the target volume for raw plasma based on the total donor blood volume. The method includes setting the target volume for raw plasma and controlling the plasma collection device to operate draw and return phases to withdraw whole blood from a donor and separate the whole blood into the plasma product and a second blood component comprising red blood cells and to return the second blood component to the donor. The controller operates the draw and return phases until a volume of raw plasma in the collection container equals the target volume of raw plasma.

The present invention relates to a method for separating lymphocytes and/or stem cells from whole blood in an automated blood separation system, wherein the quality of the collected lymphocytes and/or stem cells fractions is increased and the cell collection procedure is further automated by use of an optical sensor comprised in a detector device to measure turbidity and colour in the claimed method and in a cell separator, which can be used to perform the claimed method. The method of the invention is particularly useful to collect lymphocytes and/or stem cells fractions from whole blood, wherein the contamination of the collected cell fractions by platelets, red blood cells and granulocytes is reduced.

Described are embodiments that include methods and devices for separating components from multi-component fluids. Embodiments may involve use of separation vessels and movement of components into and out of separation vessels through ports. Embodiments may involve the separation of plasma from whole blood. Also described are embodiments that include methods and devices for positioning portions, e.g., loops, of disposables in medical devices. Embodiments may involve use of surfaces for automatically guiding loops to position them into a predetermined position.

A method for the re-anticoagulation of platelet rich plasma in a blood apheresis system includes priming the blood apheresis system with anticoagulant, such that a volume of anticoagulant is transferred to a PRP container. The method may then transfer the anticoagulant within the PRP container to a red blood cell container, and collect a volume of platelet rich plasma within the PRP container. The platelet rich plasma may be collected in a plurality of cycles. Between collection cycles, the method may transfer a portion of the volume of anticoagulant from the red blood cell container to the PRP container.

A blood component separation device includes a centrifuge bowl for separating a blood component from blood, a plasma bag for storing a plasma component, a platelet intermediate bag for storing high-concentration platelet liquid having high-concentration of platelets, and a temporary storage bag (also used as a buffy coat bag) for storing low-concentration platelet liquid having low-concentration of platelets. The blood component separation device performs control, from the second cycle onward, to mix the low-concentration platelet liquid stored in the temporary storage bag in the immediately preceding cycle with whole blood to supply the mixed liquid to the centrifuge bowl. An amount of high-concentration platelet liquid to be collected in the platelet intermediate bag in the first cycle is set to be smallest among all cycles, and an amount of high-concentration platelet liquid to be collected in a last cycle is set to be greatest among all the cycles.

A system for blood cell separation, comprising:

a separation chamber (10) comprising an inlet port for blood (12), an outlet port for plasma (14) and at least an outlet port for cellular blood components (16) for the separation of whole blood;

a blood pump (20) for pumping whole blood into the inlet port for blood (12);

a plasma pump (22) for pumping plasma and/or target cells from the outlet port for plasma (14) out of the separation chamber (10);

a red blood cell tube (30) comprising a first end (32) and a second end (34), wherein the first end (32) of the red blood cell tube (30) is connected to the outlet port for cellular blood components (16) for allowing red blood cells to leave the separation chamber (10); and

a drip chamber (40) comprising a reservoir (42) and an inlet (46), wherein the second end (34) of the red blood cell tube (30) is connected to the inlet (46), wherein the second end (34) of the red blood cell tube (30) extends into the volume of the reservoir (42) for pressure equalization during pumping from the outlet port for plasma (14).