An implantable device for venous or peritoneal access including a housing including a void having distal a proximal openings; an insert for insertion through the proximal opening comprising a venous or peritoneal catheter; a valve element mounted in a cylindrical recess of the insert; an extracorporeal coupling member of which a terminal portion can be inserted into a proximal recess of the valve element; one or two conduits extending from the catheter to the proximal end of the coupling member via the valve element and the insert for providing fluid communication, which can be interrupted by rotating the coupling member. The coupling member can be extracted from the recess only in a state of interrupted communication.

The present invention relates to a device configured with an analyte sensor to measure analytes through an existing peritoneal dialysis catheter and to a method for using the device and to a method for changing of a dialysis protocol in a patient undergoing peritoneal dialysis using the device.

A medical fluid delivery system includes a source of purified water; a source of concentrate for mixing with water from the water source; a disposable set including a pumping portion, a water line in fluid communication with the source of purified water and the pumping portion, the water line including a filter for filtering the water, a concentrate line in fluid communication with the concentrate source and the pumping portion, and a heater/mixing container in fluid communication with the pumping portion; a medical fluid delivery machine including, a pump actuator operable with the pumping portion of the disposable set, and a heater/mixing pan configured to support the heater/mixing container; and at least one leveling foot positioned and arranged to enable the heater/mixing pan to be oriented in a desired position for mixing the concentrate and purified water. A leveling tray and leveling foot are provided additionally.

A system for dialysis is disclosed. An example peritoneal dialysis system includes a peritoneal dialysis machine including a pumping mechanism, and a sensor configured to measure a property of peritoneal dialysis fluid. The peritoneal dialysis system also includes a disposable cassette operable with the peritoneal dialysis machine. The disposable cassette includes a fluid source inlet for accepting fluid from a fluid source and a fluid flow path in fluid communication with the fluid source inlet. The fluid flow path includes a pump chamber operable with the pumping mechanism to pump fluid through the fluid flow path. The disposable cassette also includes a concentrate inlet for fluidly communicating concentrate to the fluid flow path, and a sensor chamber located along the fluid flow path and operable with the sensor. The sensor is configured to provide feedback to the peritoneal dialysis machine for mixing the concentrate for forming peritoneal dialysis fluid.

Medical fluid tubing described herein is configured to be advantageously tolerant of kinking and/or crushing. That is, the tubing is configured such that even if the tubing is kinked or fully compressed at least some portion of the lumen defined by the tubing will remain open, and some fluid will continue to flow through the tubing. Such kink and compression tolerant medical tubing can be advantageously used in association with medical fluid pumping systems (e.g., peritoneal dialysis systems and the like). In some examples, the tubing described herein is used in conjunction with, or as a part of, a medical fluid cassette that interfaces with such medical fluid pumping systems.

This application relates to a system, apparatus, and methods for renal dialysis training the patients, providers, and caretakers without harming or injuring an actual patient. The renal dialysis may be hemodialysis, peritoneal dialysis, or both. The system comprises at least one closed-loop apparatus with at least one of the followingartificial blood, cannulatable vascular system, heart, peritoneal membrane and cavity, vascular valves, artificial skin, and/or other artificial organs set inside a mannequin, humanoid, or any human-like machine. The artificial organ in the mannequin can be accessed through an opening in the chest, arm, abdominal cavity, thigh, groin, neck, and any combination thereof. The renal dialysis may be through catheter access, arterio-venous graft access, and peritoneal catheter access.

An automated peritoneal dialysis (APD) device, system and method is provided, which utilizes mechanisms to admix customized dialysate solutions from multiple sources, while maximizing volumetric accuracy. The present automated peritoneal dialysis (APD) device can accomplish these goals all within the convenience and comfort of the patient's home utilizing filtered tap water.

A direct sodium removal (DSR) infusate regimen and methods of use are provided for removing sodium and reducing fluid overload in patients with severe renal dysfunction and/or heart failure, in which a patient has at least a first DSR session with a first DSR infusate having no or low sodium that is instilled into a patient's peritoneal cavity for a first dwell period to cause sodium and excess fluid to migrate to the patient's peritoneal cavity, and thereafter, the patient may undergo conventional dialysis to rebalance the patient's fluid and sodium levels.

A fluid extraction implantable system shaped and sized to be implanted in a patient, including: a fluid extraction chamber having a flat and thin shape connected to a draining tube and including at least one external flat surface, wherein the at least one external flat surface is configured to be attached to a tissue surface when a negative pressure is applied on the draining tube, wherein the chamber extracts fluids from the tissue by applying the negative pressure through the flat surface on the attached tissue surface.

The present invention relates to subcutaneously implanted graft-port systems, devices and methods for establishing access to the vascular system of a patient requiring multiple blood treatments over an extended period of time. The systems, devices and methods disclosed herein reduce miscannulation, promote intra-session hemostasis, and decrease the incidence of bacteremia and sepsis among other improvements and advantages. The devices include a port with a flattened plateau-like surface for receiving an access tube. The flat surface may include a tactile or visual guide to assist with placement of the access tube into the tapered seat. Optional valve mechanisms reduce the size and form factor of the implantable graft-port device and seals the conduit of the port closed to physiologic pressures until the valve is opened upon percutaneous insertion of the access tube. The access tube does not pass into the conduit. A mismatch fit between the access tube and tapered seat causes a decrease in the cross-sectional sealing area, a reduction in the overall device size, and an increase in blood flow during treatment. Lock solutions to prevent fowling and infection are also disclosed.