The invention relates to veterinary science. An extrarenal blood purification procedure is performed to remove toxins from the blood. Baseline parameters of urea and creatinine in the blood serum are measured during the blood purification procedure; on the basis of the data obtained, a dialysis intensity index (DII) is determined as the ratio of the patient's total fluid volume to the volume of the fluid purified of toxins and a uremic toxin accumulation index (UTAI) is determined as the rate of accumulation of the quantity of urea or creatinine per unit of time. Moreover, it is deemed necessary to repeat the hemodialysis procedure if the UTAI value for urea is more than 0.5 and/or the UTAI value for creatinine is more than 8, and/or the DII value is less than 0.9.

The present disclosure relates to diffusion and/or filtration devices comprising hollow fiber membranes, e.g., ultrafilters for water purification, plasma filters, or capillary dialyzers for blood purification; housings and end caps for the devices; and methods for the production of the devices.

A renal failure therapy system (10) includes a dialyzer (102); a blood circuit (100) in fluid communication with the dialyzer (102); a dialysis fluid circuit (30) in fluid communication with the dialyzer (102); and an electrically floating fluid pathway (140) comprising at least a portion of the blood circuit (100) and at least a portion of the dialysis fluid circuit (30), wherein the only electrical path to ground is via used dialysis fluid traveling through machine (12) to earth ground (28), and wherein at least one electrical component (46, 90, 82, 66, 102, 116) in the at least a portion of the dialysis fluid circuit (30) of the electrically floating fluid pathway (140) is electrically bypassed.

A dialysis system includes: (i) a source of water made suitable for a dialysis treatment; (ii) at least one concentrate for mixing with the water from the source; (iii) a dialysis fluid pump; and (iv) a disposable set operable with the dialysis fluid pump and in fluid communication with the source of water and the at least one concentrate, the disposable set including a container having a first end and a second end, the container configured to allow the water and the at least one concentrate pumped by the dialysis fluid pump to enter at the second end and exit from the first end to mix for the dialysis treatment.

A technology that provides various modular biomimetic microfluidic modules emulating varieties of microvasculature in body. These microfluidic-base capillaries and lymphatic Technology modules are constructed as multilayered-microfluidic microchannels of various shapes, and aspect ratios using diverse biocompatible microfluidic polymers. Then, various semipermeable membranes are sandwiched in between these multilayered microfluidic microchannels. These membranes have different chemical, physical characteristics and MWCO values. Consequently, this design will produce much smaller dimension channels similar to human vasculature to achieve biomimetic properties like of human organs and tissues. By interchanging microfluidic-layers or the membranes various diverse modules are designed that act as building blocks for constructing various medical devices, various forms of dialysis devices including albumin and lipid dialysis, water purification, bioreactors bio-artificial organ support systems. Connecting various modules in diverse combinations, permutations, in parallel ad/or in series to ultimately design many unrelated medical devices such as dialysis, bioreactors and organ support devices.

Dialysis systems and methods are described which can include a number of features. The dialysis systems described can be to provide dialysis therapy to a patient in the comfort of their own home. The dialysis system can be configured to prepare purified water from a tap water source in real-time that is used for creating a dialysate solution. The dialysis systems described also include features that make it easy for a patient to self-administer therapy. For example, the dialysis systems include disposable cartridge and patient tubing sets that are easily installed on the dialysis system and automatically align the tubing set, sensors, venous drip chamber, and other features with the corresponding components on the dialysis system. Methods of use are also provided, including automated priming sequences, blood return sequences, and dynamic balancing methods for controlling a rate of fluid transfer during different types of dialysis, including hemodialysis, ultrafiltration, and hemodiafiltration.

Filtration membrane with improved mechanical stability and increased resistance to pressure is provided. The filtration membrane is useful for in vivo implantable filtration devices, such as, an artificial kidney. In vivo implantable filtration devices are also provided.

Dialysis systems and methods are described which can include a number of features. The dialysis systems described can be to provide dialysis therapy to a patient in the comfort of their own home. The dialysis system can be configured to prepare purified water from a tap water source in real-time that is used for creating a dialysate solution. The dialysis systems described also include features that make it easy for a patient to self-administer therapy. For example, the dialysis systems include disposable cartridge and patient tubing sets that are easily installed on the dialysis system and automatically align the tubing set, sensors, venous drip chamber, and other features with the corresponding components on the dialysis system. Methods of use are also provided, including automated priming sequences, blood return sequences, and dynamic balancing methods for controlling a rate of fluid transfer during different types of dialysis, including hemodialysis, ultrafiltration, and hemodiafiltration.

The present teachings provide a blood purification apparatus including a drain-liquid temporary chamber that stores drain liquid drained from a blood purifier that purifies blood of a patient, a first drain-liquid drain line through which the drain liquid flows into the drain-liquid temporary chamber, a second drain-liquid drain line through which the drain liquid stored in the drain-liquid temporary chamber is drained to an outside of the apparatus, a draining unit provided to the second drain-liquid drain line and that drains the drain liquid stored in the drain-liquid temporary chamber to the outside of the apparatus, a remaining-amount-detecting unit that detects an amount of drain liquid remaining in the drain-liquid temporary chamber, a judging unit that judges whether or not a reference remaining amount is reached by the drain liquid in the drain-liquid temporary chamber from a result of detection by the remaining-amount-detecting unit, and a control unit that controls the draining unit. The control unit executes a draining process in which the draining unit is controlled such that the drain liquid in the drain-liquid temporary chamber is drained to the outside of the apparatus. The draining process is ended if it is judged by the judging unit that the reference remaining amount is reached by the drain liquid in the drain-liquid temporary chamber.

The disclosed arterial chambers for hemodialysis may include a cap with a blood inlet port for conveying an intended patient's blood into the arterial chamber, an auxiliary port configured to provide fluid access to the arterial chamber, and a needleless access port configured to couple to a needleless syringe. The needleless access port may be configured for administering a substance to an interior of the arterial chamber from the needleless syringe and/or for withdrawing blood from the interior of the arterial chamber into the needleless syringe. Various tubing sets, hemodialysis systems, and other components, systems, and methods are also disclosed.