Excess water can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Each channel is wide enough for blood to flow through, and the nanotubes are spaced close enough to each other to retain the blood within the channels. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the excess water in the blood evaporates into the gas. In other embodiments, an undesirable molecule (e.g., ammonia) can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the undesirable molecule in the blood diffuses into the gas.

A molecule can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Each channel is wide enough for blood to flow through, and the nanotubes are spaced close enough to each other to retain the blood within the channels. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the molecule in the blood diffuses into the gas. In other embodiments, a molecule can be introduced into blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Gas that includes the molecule passes through the spaces between the nanotubes outside the channels. The gas comes into contact with the blood at the outer boundaries of the channels, and the molecule in the gas diffuses into the blood.

Apparatus and method for photo-chemical oxidation are disclosed herein. In one embodiment, a dialysis fluid regeneration system includes: a nanostructured anode; a source of light configured to illuminate the anode; and a cathode that is oxygen permeable.

Apparatus and method for photo-chemical oxidation are disclosed herein. In one embodiment, a method for regenerating a dialysis fluid includes: flowing the dialysis fluid between an anode and a cathode of a dialysis system, where the anode comprises a plurality of nanostructures; illuminating the anode with a source of light; flowing oxygen through the cathode toward the dialysis fluid; and converting urea in the dialysis fluid into CO2, N2 and H2O thereby regenerating the dialysis fluid.

A sorbent based monitoring system for measuring the solute concentration of at least one component of a fluid. The system has a sorbent regeneration system for regeneration of the fluid and has a sorbent cartridge that has at least one material layer. The fluid is conveyed through the sorbent cartridge and contacts at least one sensor after having contacted at least one material layer.

In a method for producing a cell concentrate using a cell suspension treatment system including a storage container of a cell suspension, which has a solution inlet port, a circulation outlet port, and a circulation inlet port, a cell suspension treatment device for concentrating the cell suspension by separating liquid from the cell suspension by filtration, the device including a container having a cell suspension introduction port, a cell suspension lead-out port, and a filtrate outlet, which is filled with a hollow fiber separation membrane, a circulation circuit for concentrating the cell suspension while circulating the cell suspension between the storage container and the cell suspension treatment device, a collection container of a cell concentrate obtained by concentration, a collection path for feeding the cell concentrate to the collection container, an injection path for injecting a solution into the solution inlet port of the storage container, and a detecting unit.

The invention relates to an apparatus for extracorporeal removal of protein-bound toxins from blood plasma comprising a first line device, a second line device, a third line device and a fourth line device, a dialyzer or hemofilter arranged between the first line device and the second line device and/or an adsorber, means for generating a field, at least partially surrounding the first line device and/or the dialyzer or hemofilter and/or the adsorber, a controllable fluid conveyance device arranged in the first line device and/or the second line device, and at least one controllable body fluid conveyance unit arranged in the third line device and/or the fourth line device, a filter, wherein the permeate side of the filter is connected to the first line device and the second line device, and the side of the filter to be dialyzed is connected at its inlet to the third line device, which can be connected to a patient and is connected at its outlet to the fourth line device which can be connected to the patient, wherein a controllable flow of fluid through the line devices and the dialyzer or hemofilter and/or the adsorber can be generated by means of the fluid conveyance devices.

A blood filtration system may include a blood circuit. The blood filtration system may include an adjustable cuff configured to receive a portion of a limb of a patient. The cuff may selectively engage with the limb to apply an external force to the limb. Applying force to the limb with the cuff may inhibit flow of blood within the vasculature of the limb. The system may adjust the cuff to change the force applied to the limb, for example to correspondingly change flow of blood from the vasculature to the blood circuit. The blood filtration system may include a controller. The controller may communicate with the cuff. The controller may operate the cuff to adjust the force applied to the limb of the patient.

An extracorporeal blood treatment apparatus is provided comprising a filtration unit (2) connected to a blood circuit (17) and to a dialysate circuit (32), a preparation device (9) for preparing and regulating the composition of the dialysis fluid, and a sensor (11) for measuring conductivity of the dialysate (i.e. spent dialysis fluid); a control unit (12) configured for setting a sodium concentration in the dialysis fluid and after setting the dialysis fluid at the initial set point, circulating the dialysis fluid and/or the substitution fluid, measuring an initial conductivity value of the dialysate at the beginning of the treatment, and calculating, based on the measured initial conductivity value of the spent dialysis fluid and on the corresponding conductivity value of the dialysis fluid, the value of the initial plasma conductivity, said circulating the dialysis fluid up to the calculating of the initial plasma conductivity being performed maintaining the dialysis fluid conductivity substantially constant.

An extracorporeal blood treatment apparatus is provided comprising a filtration unit (2) connected to a blood circuit (17) and to a dialysate circuit (32); a control unit (12) is configured for calculating a sodium concentration value for the blood; the estimation of the sodium concentration includes the sub-step of calculating the sodium concentration value as an algebraic sum of a main contribution term based on the isoconductive sodium concentrate and of an offset contribution term based on a concentration of at least a substance in the dialysis fluid chosen in the group including bicarbonate, potassium, acetate, lactate, citrate, magnesium, calcium, sulphate and phosphate.