A medicine-holding body is disposed in a flow path of a nozzle portion of an adapter for blood dispensing. The medicine-holding body is formed of a plurality of fibers which is made of polyester and is bundled by aligning a longitudinal direction thereof in a flowing direction which is a direction in which blood flows. The medicine-holding body holds an anticoagulant for suppressing coagulation of blood, as a medicine to be mixed into blood. The surface area of the medicine-holding body is greater than or equal to 10 mm.sup.2 and less than 600 mm.sup.2. In a case where the surface area of the medicine-holding body is greater than or equal to 10 mm.sup.2, the concentration of the anticoagulant becomes greater than or equal to a lower limit value of 10 U/mL even under most severe conditions such as a dispensing speed of 500 L/second. In a case where the surface area of the medicine-holding body is less than 600 mm.sup.2, it is possible to maintain the occurrence rate of hemolysis to be less than or equal to 10%.

A blood treatment filter comprising a filter element, an inlet-side flexible container and an outlet-side flexible container, an inlet port, and a tubular outlet port, further comprises: an outlet-side frame sheet disposed between the filter element and the outlet-side flexible container; a first seal portion provided by sealing at least the filter element and the outlet-side frame sheet in a belt-shaped manner; and an annular second seal portion provided to surround the first seal portion, wherein on an outlet side of the filter element, a valley portion is formed at the first seal portion, the outlet port includes a protruding portion that protrudes to an inside of the container, and the protruding portion is provided with an opening at least a part of which overlaps with the first seal portion and which can communicate with a gap region formed by the valley portion.

A blood processing system for collecting plasma reduced platelets and anticipating plasma return includes a venous access device, a blood component separation device, a first return line, a recirculation line, and a second return line. The venous access device draws whole blood from a subject and returns blood components to the subject using a first pump. The blood component separation device separates the drawn blood into a first blood component and a second blood component, and sends the first blood component to a first blood component bag. The first return line fluidly connects the venous-access device and the blood component separation device. The recirculation line connects the first blood component container and the separation device. The second return line fluidly connects the first blood component container and the first return line and is configured to return the first blood component within the first blood container to the subject.

In a blood transfusion system (a blood transfusion kit, a blood transfusion kit for emergency blood transfusion, or a method of using a blood transfusion kit), a flow path through which blood flows is formed using a tube having a channel therein. The flow path includes: a first path that connects an upstream path and a downstream path and has a leukocyte removal filter removing leukocytes at an intermediate position of the channel and a second path that connects the upstream path and the downstream path and bypasses the leukocyte removal filter.

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.

A blood component collection system (10) includes a first internal pressure calculation unit (110) adapted to calculate a first internal pressure of a first pressed portion (60) using first calibration curve data (118), a second internal pressure calculation unit (112) adapted to calculate a second internal pressure of a second pressed portion (62) using second calibration curve data (120), and a correction unit (114) adapted to correct the first calibration curve data (118) in a manner so that, during a blood returning operation, the first internal pressure calculated by the first internal pressure calculation unit (110) becomes equal to the second internal pressure calculated by the second internal pressure calculation unit (112).

Blood from a blood source is drawn into a fluid flow circuit. A mononuclear cell product is separated from the blood, followed by at least a portion of the mononuclear cell product being conveyed into an electroporation device without disconnecting the blood source from the fluid flow circuit. The electroporation device opens pores in a membrane of at least one of the cells of the mononuclear cell product to allow DNA material (which is added to the mononuclear cell product prior to electroporation) to enter and modify the genome of the cell. At least a portion of the modified mononuclear cell product is returned to the blood source. The mononuclear cell product may be washed prior to being conveyed into the electroporation device. The modified mononuclear cell product may be washed after exiting the electroporation device.

A biological component collection system and a circuit internal pressure acquisition method are provided, which are capable of accurately measuring the circuit internal pressure. A centrifugal separation device of a blood component collection system comprises an estimated data calculation unit that calculates estimated data B on the basis of initial data A, and a correction unit that corrects the estimated data B in a manner so that the internal pressure calculated by a first internal pressure calculation unit becomes equivalent to the internal pressure calculated by a second internal pressure calculation unit.

A device for aseptic delivery of biological material from a vial includes a tubular barrel, a filter assembly, and a dispersion assembly. The dispersion assembly is at least partially disposed within the tubular barrel. The dispersion assembly includes a dispersion element, a piston, and a one-way valve. The dispersion element is in fluid communication with the vial to disperse the biological material from the vial. The piston is disposed at the distal end of the dispersion assembly and is in sealing contact with the tubular barrel. The one-way valve forms a fluid passageway in fluid communication with the dispersion element and the tubular barrel. The one-way valve is configured to allow a flow of the dispersed biological material from the dispersion element, through the fluid passageway, and into the tubular barrel, and to prevent a flow of the dispersed biological material from the tubular barrel into the dispersion assembly.

A flow path is formed in a cassette body of a blood component collection cassette. The cassette body includes a bulging structure in which at least a portion of the flow path is formed. A first gripped member, which is configured to be gripped by a first gripping member provided on a centrifugal separation device, is disposed on one surface of the bulging structure in a thickness direction thereof. A second gripped member, which is configured to be gripped by a second gripping member to which a load detection unit that is provided on the centrifugal separation device is fixed, is disposed on another surface of the bulging structure in the thickness direction thereof.