A renal failure blood therapy system includes a renal failure blood therapy machine, concentration levels for each of a plurality of solutes removed from a patient's blood at each of the multiple times, a display device configured to display for selection at least one removed blood solute from the plurality of removed blood solutes, and a device programmed to (i) estimate at least one renal failure blood therapy patient parameter using the determined concentration levels for the at least one selected removed blood solute, (ii) determine a plurality of acceptable renal failure blood therapy treatments that meet a predetermined removed blood solute clearance for the at least one selected removed blood solute using the at least one renal failure blood therapy patient parameter, and (iii) enable selection of at least one of the plurality of acceptable renal failure blood therapy treatments for operation at the renal failure blood therapy machine.

Dialysis is enhanced by using nanoclay sorbents to better absorb body wastes in a flow-through system. The nanoclay sorbents, using montmorillonite, bentonite, and other clays, absorb significantly more ammonium, phosphate, and creatinine, and the like, than conventional sorbents. The montmorillonite, the bentonite, and the other clays may be used in wearable systems, in which a dialysis fluid is circulated through a filter with the nanoclay sorbents. Waste products are absorbed by the montmorillonite, the bentonite, and the other clays and the dialysis fluid is recycled to a patient's peritoneum. Using an ion-exchange capability of the montmorillonite, the bentonite, and the other clays, waste ions in the dialysis fluid are replaced with desirable ions, such as calcium, magnesium, and bicarbonate. The nanoclay sorbents are also useful for refreshing a dialysis fluid used in hemodialysis and thus reducing a quantity of the dialysis fluid needed for the hemodialysis.

An apparatus and method for replenishing urease in a sorbent cartridge for use in sorbent dialysis. The system is configured to allow insertion of a urease pouch, injection of a urease solution, or addition of a urease cartridge, into a dialysis cabinet containing a dialysis flow loop. The urease can be dissolved and the resulting urease solution added to the sorbent cartridge in the flow loop to replenish the urease within the sorbent cartridge. The sorbent cartridge can also comprise other, rechargeable, sorbent materials for removing toxins other than urea from spent dialysate.

A processor of a medical device configured to communicate with a remote server can be programmed to protect the medical device from exposure to unauthorized or malicious software. A system or method to implement this form of protection can include, for example, at least one processor on the medical device, a control software module that controls the operation of the medical device and is executable on the processor, a data management module that manages data flow to and from the control software module from sources external to the medical device, and an agent module that has access to a limited number of designated memory locations in the medical device. In addition, a hemodialysis apparatus can be configured to operate in conjunction with an apparatus for providing purified water from a source such as a municipal water supply or a well. A system for controlling delivery of purified water to the hemodialysis apparatus can comprise a therapy controller of the hemodialysis apparatus configured to communicate with a controller of a water purification device, and a user interface controller of the hemodialysis apparatus configured to communicate with the therapy controller, and to send data to and receive data from a user interface.

The invention relates to systems and methods for estimating a patient urea level at any arbitrary time during dialysis treatment. The systems and methods use either one or more urea sensors or any two of a pH sensor, ammonia sensor, and ammonium sensor to determine an amount of urea removed by a dialysate regeneration system. The systems and methods use the amount of urea removed by the dialysate regeneration system to estimate the patient urea level.

An apparatus and method for replenishing urease in a sorbent cartridge for use in sorbent dialysis. The system is configured to allow insertion of a urease pouch, injection of a urease solution, or addition of a urease cartridge, into a dialysis cabinet containing a dialysis flow loop. The urease can be dissolved and the resulting urease solution added to the sorbent cartridge in the flow loop to replenish the urease within the sorbent cartridge. The sorbent cartridge can also comprise other, rechargeable, sorbent materials for removing toxins other than urea from spent dialysate.

A blood based solute monitoring system for measuring at least one blood solute species that has a first recirculation flow path in fluid communication with a dialyzer. The first recirculation flow path is configured to allow a fluid to recirculate through a dialyzer such that the concentration of at least one solute species in the fluid becomes equilibrated to the solute species concentration of the blood in a blood compartment of the dialyzer. The blood solute monitoring system has at least one sensor to measure a fluid characteristic.

A catheter insertion device which employs back-and-forth longitudinal axial movement to advance the catheter by the cooperative interface of an incline ramp and a decline ramp with a split gripping mechanism is described.

To provide a concentration calculating module configured to measure the concentrations of two constituents simultaneously with higher accuracy.

The concentration measuring module includes a light source configured to emit light into a housing; a first light receiving unit configured to have sensitivity to a wavelength of output light of the light source and receive light radiated from inside the housing; and a second light receiving unit configured to have sensitivity to a longer wavelength than the first light receiving unit and receive light radiated from inside the housing. The light source, the first light receiving unit, and the second light receiving unit are arranged to have a positional relationship in which a light emitting surface of the light source faces a light receiving surface of the first light receiving unit, and a normal to a light receiving surface of the second light receiving unit is orthogonal to, of a line through the light source and the first light receiving unit, a line segment corresponding to the inside of the housing, and a length X of, of the line through the light source and the first light receiving unit, the line segment corresponding to the inside of the housing and then a length Y of, of a line including the normal to the light receiving surface of the second light receiving unit, a line segment corresponding to the inside of the housing satisfy Y/X>1. The concentration measuring module calculates the concentrations of two constituents simultaneously on the basis of first and second signals output from the first and second light receiving units.

The invention relates to a device for hemodiafiltration with an extracorporeal circulation (10) for receiving blood to be purified and having a hemodialyzer and/or hemofilter (20) which is connected to the blood circulation (10), such that the blood circulation (10) has at least one inlet line (12, 14) for the supply of a replacement fluid upstream and downstream from the hemodialyzer and/or hemofilter (20), characterized in that the apparatus also comprises measurement apparatuses for recording the transmembrane pressure and/or hematocrit (HKT) and/or blood density, such that the measurement apparatuses are connected to a control unit (100) for controlling one or more of the transmembrane pressure and/or the hematocrit (HKT) and/or the blood density, the control unit (100) being constructed so that the control is implemented with the help of at least one of the infusion rates (Q.sub.spre, Q.sub.spost) of the replacement fluid (13, 15), and the blood to be purified is exposed to a high-frequency electromagnetic field and/or an electric DC field (70) before and/or during contact with the hemodialyzer and/or hemofilter (20).