Flexible housing filters for filtration of fluids and methods of making such filters are disclosed. The filters may include one or more peripheral seals in the flexible housing.

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 blood filter device having an iron-chelating molecule, a haem-binding molecule and a haemoglobin-binding molecule bound to a support. Use of the device in a vessel containing blood, for example a blood bag or a flow line, removes haemolysis-derived components from the blood.

A device for conditioning blood including a heat exchanger module including a heat exchanger fiber layer including heat exchanger fibers to receive a heat exchanger fluid and exchange heat with the blood, a gaseous micro-emboli removal module including a micro-porous fiber layer including micro-porous fibers to receive atmospheric or sub-atmospheric pressures such that at least some gaseous micro-emboli are drawn from the blood through the micro-porous fibers, a gas exchanger module including a gas exchanger fiber layer including gas exchanger fibers to receive a gas mixture and exchange gas with the blood, and a potting material body that embeds the heat exchanger fibers, the micro-porous fibers, and the gas exchanger fibers and defines a blood compartment that extends through the heat exchanger module, the gaseous micro-emboli removal module, and the gas exchanger module.

Devices and methods for withdrawing blood from a patient and separating plasma from the blood are disclosed herein. In some embodiments, a fluid cartridge can be coupled to a collection device and configured to receive whole blood withdrawn from the patient using the collection device. The cartridge can include a housing having a reservoir portion configured to receive the whole blood, and a plasma separation substrate positioned within the housing. The substrate can be folded to define (a) a crease, (b) a first strip portion extending away from the crease, and (c) a second strip portion extending away from the crease. The crease can be positioned adjacent to the reservoir portion to receive the whole blood, and the plasma separation substrate can be configured to wick the whole blood along the first and second strip portions to separate the plasma from the whole blood.

The present invention discloses a microstructured discrimination device for separating hydrophobic-hydrophilic fluidic composites comprising particulate and/or fluids in a fluid flow. The discrimination is the result of surface energy gradients obtained by physically varying a textured surface and/or by varying surface chemical properties, both of which are spatially graded. Such surfaces discriminate and spatially separate particulate and/or fluids without external energy input. The device of the present invention comprises a platform having bifurcating microchannels arranged radially. The lumenal surfaces of the microchannels may have a surface energy gradient created by varying the periodicity of hierarchically arranged microstructures along a dimension. The surface energy gradient is varied in two regions. In one pre-bifurcation region the surface energy gradient generates a fluid flow. In the other post-bifurcation region, there is a difference in surface energy proximal to the bifurcation such that different flow fractions are divided into separate channels in response to different surface energy gradients in each of the post-bifurcation channels. Accordingly, fluids of different hydrophobicity and/or particulate of different hydrophobicity are driven into separate channels by a global minimization of the fluid system energy.

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 treatment material adsorbs and removes blood components such as activated leukocytes and inflammatory cytokines with a high efficiency. The blood treatment material includes a water-insoluble material in the form of fibers or particles, wherein the difference between the maximum value (RaA) and the minimum value (RaB) of the arithmetic average roughness (Ra) of the surface of the water-insoluble material, as calculated using a laser microscope, is from 0.30 to 1.50 μm.

An object is to provide a blood processing filter favorable in both of the effectiveness (leukocyte removing performance) and the safety (reduction in the amount of elutable substances). The object can be achieved by a blood processing filter comprising a filtration medium including a polyester fiber, wherein a surface area of the filtration medium is 6.0 m.sup.2 or more, and a maximum absorbance of an aqueous extract of the blood processing filter in the range from 240 to 245 nm is 0.03 or less.

A blood separation method using a blood separation filter (10A) includes: an arrangement step of arranging a housing (18) such that a blood inflow chamber (20) is positioned below a filter member (24) and the blood outflow chamber (22) is positioned above a filter medium (38); a blood treatment step of allowing blood to flow in the filter medium (38) upward from vertically below; and a post residual treatment blood collection step of arranging the housing (18) such that an outflow port (28) is positioned vertically below the blood outflow chamber (22) so as to guide the post-separation residual blood in the housing (18) to the outflow port (28).