A method for ex vivo treating blood or plasma is provided. The method includes (a) ex vivo contacting a blood or plasma with an enzyme composition to react the enzyme composition with the blood or plasma, wherein the enzyme composition is capable of eliminating electronegative low-density lipoprotein from the blood or plasma by the activity of the enzyme composition, and the enzyme composition is selected from a group consisting of: a first enzyme for eliminating a glycan residue of an electronegative low-density lipoprotein (LDL); a second enzyme for eliminating ceramide carried by a electronegative low-density lipoprotein (LDL); and a combination thereof; and (b) terminating contact between the blood or plasma and the enzyme composition to terminate the reaction of the enzyme composition with the blood or plasma.

A method of collecting mononuclear cells includes separating whole blood into plasma and cellular components, purifying the plasma through a plasma adsorption column to create purified plasma, combining the cellular components with the purified plasma to form a first mixture, and separating the first mixture into mononuclear cells and at least one component. Alternatively, whole blood may be flowed through an adsorption column to create purified whole blood, with the purified whole blood then being separated into mononuclear cells and at least one component.

An airtrap for a medical or physiological fluid in one embodiment includes a conical housing having a radius that increases from its top to its bottom when the housing is positioned for operation; a medical or physiological fluid inlet located at an upper portion of the conical housing; a medical or physiological fluid outlet located at a lower portion of the conical housing, the inlet and the outlet positioned and arranged so that medical or physiological fluid spirals in an increasing arc around an inside of the conical housing downwardly from the inlet to the outlet; and a gas collection area located at an upper portion of the conical housing. In another embodiment, the airtrap is shaped like a seahorse having a head section and a tail section. Any of the airtraps herein may be used for example in blood sets, peritoneal dialysis cassette tubing, and drug delivery sets.

The present invention relates to an apparatus for the extracorporeal removal of protein-bound toxins from blood comprising at least one blood purification apparatus, in particular at least one dialysis machine, hemofilter or adsorber, as well as at least one means for generating a field in the blood purification apparatus and/or in an element in flow communication with the blood purification apparatus, in particular in a line section connected to the blood purification apparatus, wherein the means comprises at least two strip conductors which are arranged on at least two preferably oppositely disposed sides of the blood purification apparatus or of the element such that the field is preferably predominantly generated within the blood purification apparatus or preferably predominantly within the element.

The present invention relates to a method and apparatus for the isolation, modification and re-administration of a molecule or biomolecule, or a class of biomolecules, from the body fluid of a mammal via an extracorporeal closed circuit device. The device is able to capture and modify the biomolecule by the covalent or non-covalent attachment of a secondary molecule or protein, by cross-linking the captured molecule, or by altering the structure of the molecule (for example, by deglycosylation, peptide cleavage, or aggregation). The apparatus can be used to return the modified molecule or biomolecule to the mammalian subject. The device and methods may be utilized for the patient-specific diagnosis and/or treatment of a disease state which presents an associated molecule or protein in plasma or any other fluidized physiological system. The methods and apparatus may also be employed as a closed system allowing the on-line purification and/or modification of a target molecule or biomolecule from a fluid source such as a bioreactor or perfusion bioreactor.

A process is provided for producing a structure into which blood or other bio-fluids can flow by capillary action, e.g. for a whole blood microsampling probe. The process comprises mixing particles of novolak resin and particles of hydrocarbon polymer, producing an uncarbonized structure from the mixture by pressurised moulding and carbonizing the moulded structure, the hydrocarbon resin being a polymer such as polystyrene that on pyrolysis has a zero carbon yield, and the particles of the hydrocarbon polymer leaving voids in the carbonized structure of sufficient size for flow of whole blood into and through the structure. The particles may be of partly cured and milled novolak resin, the novolak particles when in the moulded structure not exhibiting bulk flow during carbonization but sintering at inter-particle contact points during carbonization to provide a consolidated structure. In this variant, ethylene glycol may be used as a sintering aid. Alternatively, the particles may be of fully cured and milled novolak resin, and are mixed with the hydrocarbon polymer , the lubricant and with a binder such as lignin for providing a consolidated structure.

Provided herein are compositions including biocompatible magnetizeable nanoparticles. The nanoparticles have a diameter (average diameter) from about 10 to about 300 nanometers and are biocompatible and magnetic. The nanoparticles may be a disc formed from iron oxide. The disc may be conjugated to a target-binding moiety capable of binding a target. The target may be cancer cells, pathogens, fat cells, or atherosclerotic plaques.

Antiviral biomimetic polymers (ABPs) are disclosed that can be used to prevent and/or treat viral disease. The ABPs are discovered by a process involving high-throughput screening of polymer libraries using disease-relevant bioactive molecules as target molecules. ABPs can be nanoscale (termed nanoABPs) or larger. Methods are described for the preparation and use of ABPs as prophylactics and therapeutics (in vivo) and as preventative agents, for example, in personal protective equipment (ex vivo). ABPs can be used to prevent and treat viral diseases including those caused by Filoviridae.

The present disclosure provides methods and systems for treating a biological fluid of a subject suffering from a microbial infection (e.g., a drug-resistant microbial infection). In some embodiments, these methods and systems involve a complement receptor immobilized on, or otherwise associated with a polymer substrate, for example, high surface area particles, membranes, hollow fibers, and/or other porous or non-porous media. In other embodiments, the methods and systems involve a complement receptor present in a dialysate used in a dialyzer for extracting pathogens out of a biological fluid, for example, the blood of a patient.

This invention teaches a targeted apheresis method of treating a pregnant woman with preeclampsia, or who is predisposed to developing preeclampsia, utilizing immobilized binding agents contained within an apheresis device to remove sVEGFR-1 and sVEGFR-2, and one or more other harmful factors associated with preeclampsia selected from a list that includes: sEndoglin, Endothelin-1, TNF, IL-1, IL-6, IL-12, IL-18, digitalis-like factor, ouabain-like factor,

marinobufagenin, .marinobufotoxenin, and telocinobufagin. The binding agents used are antibodies or aptamers or binding peptides. Reducing the concentration of sVEGFR-1, sVEGFR-2 and other harmful factors in the pregnant woman's blood using targeted apheresis will alleviate or delay the symptoms of preeclampsia, and thus postpone premature delivery of the baby so that the baby is born at term or as close to term as possible.