An irradiation device includes a fluid treatment chamber having first and second opposing sides configured to receive a biological fluid container therebetween, and at least one light source disposed adjacent at least one of the first and second sides of the fluid treatment chamber. The at least one light source includes a light guide having a front planar surface that defines in part the at least one of the first and second sides of the fluid treatment chamber, and at least one light emitting diode (LED) disposed at an edge of the light guide outside the fluid treatment chamber and configured to direct light into the light guide. The light guide has a back surface opposite the front planar surface, the back surface with one or more reflectors that depend into the light guide in the direction of the front surface.

Systems and methods are provided for separating platelets from blood. Prior to blood separation, a volume of blood to be processed, a volume of platelets to be collected, and/or a time required to complete blood draw from a source during a blood separation procedure is determined. Based on that determination, a procedure setpoint is calculated from the completion of the blood draw. Blood is subsequently drawn from a source into a separator in which the blood is separated into a mononuclear cell-containing fraction and a platelet-containing fraction. At least a portion of the platelet-containing fraction is conveyed from the separator, while the volume of the mononuclear cell-containing fraction in the separator increases. The mononuclear cell-containing fraction is conveyed to the source from the separator at the procedure setpoint. The blood draw and separation are then ended.

A clip of the present application generally comprises a first clip member, a second clip member, and a retention feature. The first clip member and the second clip member are coupled together and capable of being placed in at least two positions. In the first position, the clip is capable of receiving a bag containing a fluid, and, in the second position, the bag is capable of being held between the first and second clip members. While the clip is holding the bag, two or more pockets are formed in the bag, and the fluid is generally restricted or prohibited from transferring from one pocket to another pocket while the clip is in this position. A retention feature retains the clip, which is holding a bag, to a centrifuge receptacle and allows the clip to be placed in a predetermined position on the centrifuge receptacle.

The invention relates to a system, comprising: a) a sample processing unit, comprising an input port and an output port coupled to a rotating container having at least one sample chamber, the sample processing unit configured provide a first processing step to a sample or to rotate the container so as to apply a centrifugal force to a sample deposited in the chamber and separate at least a first component and a second component of the deposited sample; and b) a sample separation unit coupled to the output port of the sample processing unit, the cell separation unit comprising separation column holder (42), a pump (64) and a plurality of valves (1-11) configured to at least partially control fluid flow through a fluid circuitry and a separation column (40) positioned in the holder, the separation column configured to separate labeled and unlabeled components of sample flowed through the column.

A disposable fluid pump is provided with a housing including first and second faces, with a sidewall extending between the first and second faces. The housing defines a chamber, with an inlet and an outlet in fluid communication with the chamber. An impeller is rotatably mounted within the chamber and includes a plurality of flexible vanes. Such a pump may be incorporated into a disposable fluid flow circuit that is adapted to be mounted on a durable hardware for processing a fluid. In such a fluid flow circuit, the fluid pump may be integrated into a cassette of the circuit or, alternatively, the inlet and outlet of the fluid pump may be directly connected to fluid flow conduits of the circuit.

A method for collecting plasma includes determining the weight and hematocrit of a donor, and inserting a venous-access device into the donor. The method then withdraws blood from the donor through a draw line connected to a blood component separation device, and introduces anticoagulant into the withdrawn blood. The blood component separation device separates the blood into a plasma component and a second blood component, and the plasma component is collected from the blood component separation device and into a plasma collection container. The method may then calculate (1) a percentage of anticoagulant in the collected plasma component, and (2) a volume of pure plasma collected within the plasma collection container. The volume of pure plasma may be based, at least in part, on the calculated percentage of anticoagulant. The method may continue until a target volume of pure plasma is collected within the plasma collection container.

A fluid separation device includes a centrifugal separator configured to receive a centrifugal separation chamber of a disposable fluid flow circuit, a pump system configured to convey a fluid into the centrifugal separation chamber and to remove a separated fluid component from the centrifugal separation chamber via an outlet, a color-based interface monitoring system configured to determine an interface position between separated fluid components continuously flowing through the centrifugal separation chamber based on dominant wavelength measurements of layers of separated fluid components during a centrifugal separation procedure, and a controller configured to measure the dominant wavelengths of the layers, calculate a duration as a color time for each measured dominant wavelength, set target color times, calculate error signals and calculate control signals to adjust the pump system to control the flow rate and interface position.

A device and method for separating whole blood includes flowing whole blood to a centrifuge, separating whole blood into blood components within the centrifuge, and flowing separated blood components out of the centrifuge. The device and method include a flow rate stoppage phase executed one or more times during the method. The flow rate stoppage phase includes (i) stopping the flow of whole blood to the centrifuge and stopping the flow of separated blood components out of the centrifuge; (ii) spinning the centrifuge at a selected rate; and (iii) after a selected time ending the flow rate stoppage phase and resuming the flow of whole blood to the centrifuge and the flow of separated blood components out of the centrifuge.

Apparatus and methods for concentrating platelet-rich plasma is described herein. One variation may generally comprise a tube having a length and defining a channel within and one or more ports located at a proximal end of the tube and in fluid communication with the channel. A plunger may slidably translatable within the channel while forming a seal against an inner surface of the channel and a float may have a pre-selected density and defining a concave interface surface, wherein the float is slidably contained within the channel such that the concave interface surface is in apposition to the one or more ports.

A fluid processing system may include a flow control cassette comprising at least one interface sensor chamber in fluid communication with at least one of a plurality of separate channels, the at least one interface sensor chamber defined at least in part by a wall, and at least one capacitive sensor disposed on the wall of the at least one interface sensor chamber. The fluid processing system may include, in the alternative or in addition, at least one syringe comprising a wall defining a barrel having a first end and a second end, the barrel having a bore with or without a piston or plunger disposed therein, and at least one capacitive sensor disposed on an outer surface of the wall of the syringe.