A platelet collection method includes a step of accommodating whole blood in a first chamber (44) and performing centrifugal separation, a step of transferring a buffy coat resulting from the centrifugal separation to a second chamber (50), and a step of performing centrifugal separation on the buffy coat. Subsequently, a step of transferring a platelet-containing component resulting from the centrifugal separation to a third chamber (52) and a step of performing centrifugal separation on the platelet-containing component are executed. Also performed in the collection method are a step of introducing a platelet additive solution into the third chamber (52) and replacing plasma resulting from the centrifugal separation and a step of collecting platelets remaining in the third chamber (52) along with the platelet additive solution.

Provided is a chamber configuration for a reverse flow centrifuge, and a reverse flow centrifuge system configured for low fluid volume and small radius rotation. The compact reverse flow centrifuge system has a reusable subsystem and a single use replaceable subsystem. The replaceable subsystem comprises a separation chamber, fluid delivery manifold and rotational mounting connecting the separation chamber to the fluid manifold. The single use replaceable subsystem provides a closed environment for execution of reverse flow centrifugation processes. The separation chamber has a substantially conical fluid enclosure portion connected to a neck portion, and a dip tube extends centrally through the conical fluid enclosure to provide a fluid path to the tip of the conical fluid enclosure.

An apparatus and method for performing counter flow centrifugation. The apparatus includes at least one vessel, a gear fixedly attached to at least a portion of the vessel such that rotation of the gear rotates the vessel, a handle assembly and a plurality of tubes extending through the handle assembly and to the vessel. The gear is configured to be rotated by a drive system. The handle assembly is rotatably attached to the gear and includes an opening therein. At least a portion of the gear engages at least a portion of the drive system through the opening. The handle assembly is configured to be rotated by the drive system. The vessel can be rotated at twice a speed of the handle assembly when the apparatus is inserted into a bowl of the counter flow centrifuge.

The invention relates to an elutriation chamber for an elutriator system for washing and/or isolating cells, in particular thrombocytes, which elutriation chamber comprises a feed line (1) for an aqueous medium containing the cells to be washed and/or to be isolated in suspended form, and a discharge line (2) for the washed and/or isolated cells, wherein the chamber (5) is rotationally symmetrical to the axis (a), characterized in that the ratio of the area of the section through the lumen of the chamber (5) perpendicular to the axis (a) at the widest point (5a-5b) to the area of the section (1a) through the feed line (1) is in the range of 1,000 to 250,000.

Embodiments are described that include systems and methods for separating components of a composite fluid, e.g., whole blood. Some embodiments provide for processing a composite fluid by subjecting a volume of the fluid to a first centripetal acceleration for an initial separation, followed by a second centripetal acceleration for a second separation.

A funnel element having an open end and a closed pointed end configured to receive a multi-component fluid containing a solid fraction. The solid fraction can comprise cellular material that sediments toward the closed pointed end to form a cell pack. A wash fluid can be pumped through the cell pack to entrain microparticles and soluble contaminants. The wash fluid can be introduced into the funnel element below the cell pack such that the wash fluid percolates through the cell pack. The percolating wash fluid can dislodge microparticles or other contaminants trapped within the cell pack. Additional wash fluids can be added to funnel element where excess wash fluids overflow from the funnel element through the open end of the funnel element.

Embodiments are described for separating/collecting components from a multi-component fluid such as whole blood. Some embodiments provide for controlling the amount of a component, such as platelets, introduced into a separation chamber to ensure that the density of fluid in the separation chamber does not exceed a particular value. This may provide for collecting purer components. Other embodiments may provide for determining a chamber flow rate based on a concentration of a component in the multi-component fluid, which may then be used to determine a centrifuge speed, to collect purer concentrated components.

Embodiments provide a fluid recovery system and method for use with concentrator systems for concentrating particles suspended in a fluid and where this suspension is recovered from a fluid stream drawn from the concentrator system. A controller is configured to control valve actuation to direct concentrate being drawn from the concentrator chamber through a recovery tube to a recovery reservoir based on fluid volume movement. The system can use a density sensor to detect density transitions in fluid in the fluid recovery tube to identify leading and trailing edges of a portion of concentrated particles in fluid suspension passing through the recovery tube and actuate recovery valves based on objectives for maximising particle recovery with minimal dilution.

An apparatus for manipulating particles includes: a rotor rotatable at a speed about an axis, the rotor having an outer periphery and front and rear opposite sides; at least one chamber mounted on the rotor, each chamber having an inlet and an outlet; an umbilical assembly rotatable about the axis; and a drive mechanism configured to rotate the umbilical assembly at about one-half the speed of the rotor. The umbilical assembly includes: a curvilinear guide tube connecting to a drum at the rear side of the rotor; a flexible conduit residing in the guide tube; and first and second elongate passageways for each chamber extending through the conduit, wherein the first passageway is in fluid communication with the inlet of a respective chamber and the second passageway is in fluid communication with the outlet of the respective chamber. The passageways are held in a spaced-apart relationship relative to one another.

A liquid-driven separation system for separating hydrated organic materials from drenched mixed solid waste is disclosed. The system includes a funnel-shaped housing defining an upper, open end, a tapering sidewall defining the funnel-shaped housing, and a lower end having a smaller circumference than the upper, open end; vertically offset openings arranged along the tapering sidewall; impellers extend along a vertical axis of the housing; a drive device that rotates the impellers; and an extraction device configured to extract fractions of the mixed solid waste from the housing. A mixture of waste and water is received at the upper end of the housing. The drive device rotates the impellers causing the impellers to generate a centrifugal force such that the mixture spins within the housing and the mixed solid waste separates into fractions at least based on a density of components in the mixed solid waste, for further extraction.