Described are peritoneal dialysis systems and methods that involve the use of crossflow filtration of a used dialysate withdrawn from the peritoneal space of a patient. The filtration forms a retentate containing amounts of an osmotic agent and a permeate containing amounts of water and nitrogen-containing waste products of the patient. The retentate, or a fraction thereof, can be returned to the peritoneal space of the patient to return osmotic agent to the patient. The permeate, or a fraction thereof, can be discarded to discard nitrogen-containing waste products of the patient.

A blood filtering machine having a blood circuit, which has a plurality of ducts made of a transparent material, and a measuring system, which has a plurality of optical sensors coupled to respective ducts. Each optical sensor has a reading window placed in a point of the respective duct, a light emitter and a light receiver. The measuring system comprises one single spectrometer, an optical mixer comprising a plurality of inputs, each connected to the light receiver of a respective one of the optical sensors, and an output, which is connected to an input of the spectrometer, and a control unit is configured to activate the light emitter of one optical sensor at a time so as to measure a parameter of one organic fluid at a time.

An implantable renal replacement therapy device may include: a first catheter configured to be inserted into a blood vessel in a subject's body; a pump in fluid communication with the first catheter, the pump is configured to pump subject's blood from the blood vessel; a filter in fluid communication with the pump, the filter is configured to: receive the subject's blood from the pump, and filter the received blood to provide a filtered blood and a filtrate liquid, wherein the filter is in fluid communication with the first catheter to cause an outflow of the filtered blood from the filter to the blood vessel; and a second catheter in fluid communication with the filter and configured to be inserted into an urinary bladder in the subject's body to cause an outflow of the filtrate liquid from the filter to the urinary bladder.

The present invention generally relates to systems and methods for the regeneration of spent dialysis solutions. The present invention further relates to systems and methods for continuously regenerating spent dialysis solution during dialysis. The present invention further relates to systems and methods for conducting dialysis that further include using chemical and physical separators in conjunction with ion exchange cartridges and/or adsorption cartridges.

The present invention relates to an extracorporeal circuit for CO.sub.2 removal from blood comprising a line for taking blood from the patient, a decarboxylation assembly and a line for returning the blood to the patient; said decarboxylation assembly comprising a first filtering unit, an oxygenator, an electrodialyzer adapted to generate an acid solution and a basic solution and means for the infusion of said acid solution upstream of said oxygenator, wherein said electrodialyzer comprises a first electrodialysis chamber and a second electrodialysis chamber, said first and second electrodialysis chambers being separated by an ionic membrane, and in that wherein said first chamber and said second chamber are respectively separated from the positive electrode, or anode, and from the negative electrode, or cathode, by means of a bipolar membrane.

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.

A catheter (100) for treating hypervolemia in a patient includes a luminal ingress (112) joined to a luminal egress (114) at a distal end portion (116) of the catheter having a closed distal end (102). The distal end portion is configured to at least temporarily reside within a vessel of the patient, the distal end portion including a semipermeable membrane. The luminal ingress is designed to convey an influent having a first osmotic concentration to the distal end portion. The semipermeable membrane is configured to pass blood-borne water from the vessel into the distal portion. The blood-borne water is absorbed by the influent to produce an effluent having a second osmotic concentration lower than the first osmotic concentration. Systems (200) with the catheter and methods for treating hypervolemia are also disclosed.

A blood filtration system may to couple to an infusion pump that is external to the blood filtration system. The blood filtration system may include a blood circuit, for instance a variable-volume blood circuit. An infusion port may be in communication with the blood circuit and may receive an infusion fluid pumped by the infusion pump. A filtration pump may extract a filtrate fluid from a filter. The filtrate fluid may include filtered plasma constituents. A fluid characteristic sensor may measure one or more of pressure or flow rate of the infusion fluid pumped by the infusion pump. A controller may monitor the fluid characteristic sensor to determine a change in the pressure or flow rate of the infusion fluid. The controller may modulate a speed of the variable-speed filtration pump based on the change in the pressure or flow rate of the infusion fluid.

A blood filtering device includes a filter having two compartments, at least one allows the passage of blood, being separated by a membrane allow passage of a filtered fraction from the first to the second compartment. The filtering device includes an outlet conduit to collect the filtered fraction leaving the filter. The filtered fraction flows along the outlet conduit along a flow direction. A first sensor includes at least one semiconductor laser source with a laser cavity adapted to generate a laser light beam striking the outlet conduit along an irradiation direction incident to the flow direction; and at least one front and one lateral photodiode, at least in correspondence of the semiconductor laser source, the outlet conduit is transparent to the laser light beam.

The filtering device processes said the two electrical signals to generate a signal indicative of the quantity of suspended particles moving along the outlet conduit.

The invention provides a method and an apparatus or system for dialysis. The method and apparatus or system are useful for removing an undesirable protein-binding substance such as a toxin from a biological fluid such as blood or blood plasma. As such, the method and apparatus or system are useful for treating a subject in need of dialysis such as a subject suffering from hepatic disease. The methods feature a) dialyzing a biological fluid against a dialysis fluid containing an adsorber for a protein-binding substance to be removed through a semipermeable membrane, b) adjusting the dialysis fluid so that the binding affinity of the adsorber for the protein-bound substance to be removed is lowered and the substance to be removed passes into solution, and c) balancing the volume or flow of one or more fluids in the apparatus or system suitable for dialyzing a biological fluid containing a protein-binding substance to be removed. The apparatus or system features a) a biological fluid circuit (3); b) a dialysis fluid circuit (2); c) a means (4; 6; 7; 8; 9) for solubilizing the protein-binding substance to be removed; d) a dialysis, filtration or diafiltration device (5); e) a balancing system or apparatus suitable for balancing the volume or flow of one or more fluids in the apparatus or system suitable for dialyzing a biological fluid containing a protein-binding substance to be removed; and f) a dialysate regeneration unit.