A system and method for the practice of apheresis employs modules in the system which can be selected for a particular patient to treat particular situations or combinations of difficulties. In one example, Gal-3 mediates a large number of body reactions, and is an effective protector of tumor microenvironments and the like, as well inflammation driver. Removal of Gal-3 may make antic-cancer treatments, like photopheresis and TNF administration more effective. Separate modules, such as one for photopheresis and one for TNF receptor removal, may be combined with a module for the reduction of Gal-3, to render the combination of treatments each more effective than if administered alone.

The disclosure relates to novel epitopes specific for narcolepsy and their uses in methods for evaluating a subject for narcolepsy, in medical and diagnostic devices and in therapy.

The present disclosure is directed to methods of removing proteins, including cytokines, from blood and blood products, the methods comprising contacting the blood or blood product with a form of carbon having high graphitic contents and slit-shaped mesopores and macropores, the pore size dimensions chosen to be comparable to the size of the proteins, wherein the contacting results in the removal of high levels of the protein from the blood or blood product in minutes or hours.

This document provides bioartificial liver (BAL) devices. Methods for making and using BAL devices also are provided.

The present invention relates to an apparatus for carrying out an apheresis treatment, wherein the apparatus has an extracorporeal circuit in which a regenerable single adsorber is located for separating substances from blood or for separating substances from plasma acquired by means of a plasma separator, wherein a line is provided for conducting the blood or the plasma which extends to the adsorber and via which blood or plasma is applied to the adsorber, wherein a reservoir is provided for receiving blood or plasma and is arranged upstream of the adsorber in the line or is in communication with the line upstream of the adsorber; and in that a controller or switching means is provided which is configured such that the reservoir is filled with blood or plasma and the application of blood or plasma to the adsorber is suppressed when the regeneration of the adsorber is carried out.

A range of carbon materials can be produced using lignin in combination with synthetic phenolic resins or naturally occurring lingo-cellulosic materials. The lignin, which is essentially a naturally occurring phenolic resin, has a carbon yield on pyrolysis similar to that of the synthetic resins, which aids processing. The lignin can be used as a binder phase for synthetic resin or lignocellulosic materials allowing the production of monolithic carbons from a wide range of precursors, as the primary structural material where the thermal processing is modified by the addition of small quantities of synthetic resin materials or as structure modified in the production of meso/macro porous carbons in either bead, granular or monolithic form. A carbonised monolith is provided comprising mesoporous and/or macroporous carbon particles dispersed in a matrix of microporous carbon particles with voids between the particles defining paths for fluid to flow into and through the structure. The monolith may take the form of a shaped body having walls defining a multiplicity of internal transport channels for fluid flow, the transport channels being directed along the extrusion direction. The monolith may be made by carbonising a shaped phenolic body based on phenolic resin precursors. In a method for producing such a carbonisable shaped resin body solid particles of a first phenolic resin are provided which is partially cured so that the particles are sinterable but do not melt on carbonisation. The particles of the first phenolic resin are mixed with particles of a second phenolic resin that has a greater degree of cure than said first phenolic resin and has a mesoporous and/or macroporous microstructure that is preserved on carbonisation. The resulting mixture is formed into a dough e.g. by mixing the resin particles with methyl cellulose, PEO and water, after which the dough is extruded to form a shaped product and stabilising in its shape by sintering.

Methods and devices for powdered sorbent regeneration of biologic fluids are disclosed. The present invention includes three novel methods, which may be used singly or in any combination, for constraining or immobilizing powders so that they can be perfused with a biological fluid or dialysate: a porous carbon block filter, a filtration bed of very fine powder, and a cone-shaped reactor.

The invention provides apheresis devices and their use for removal of substantially all types of cell free DNA (cfDNA) in patients' blood, including nucleosome-bound cfDNA, exosome-bound cfDNA and unbound cfDNA (including double stranded DNA (dsDNA), single stranded DNA (ssDNA) and oligonucleotides), to limit the negative effects of the circulating cfDNA and to treat various diseases.

The invention relates to a removable cap for a blood filter cartridge useful in facilitating dispersal of whole blood in the cartridge. The cartridge has a removable cap on at least one and preferably both of its input and output ends. The caps comprise an annular flange means having attached thereto an outer annular wall and an annular inner wall. The annular inner wall defining a cavity covered by a conical, concave filter mesh. The end cap also comprises a channel means positioned under the cavity and a part of said flange means, for reception of any fluid which passes through said concave filter mesh.

A carbon dioxide absorption medium. The absorption medium includes a plurality of hollow fibers and a plurality of binder particles. The hollow fibers have walls comprising a selectively permeable membrane that is configured to permit passage of gaseous carbon dioxide but not liquids. The plurality bind particles are dispersed between the hollow fibers and comprise an absorbent material configured to absorb gaseous carbon dioxide and to bind the carbon dioxide in a solid state.