According to some embodiments, a system may treat blood outside the body of a patient. The system may include one or more pumps configured to pump blood in a fluid flow path at a collective rate over 5 liters per minute. The system may include one or more heat exchangers operable to heat at least a portion of the blood to a temperature of at least 42 degrees Celsius and to allow the blood to cool one or more degrees following heating. The system may include one or more convection dialysis modules configured to perform convection dialysis on at least a portion of the blood at least after the one or more heat exchangers allow the blood to cool one or more degrees.

Dialysis systems and methods for operating dialysis machines (e.g., peritoneal dialysis machines) for conducting dialysis treatments are disclosed. The dialysis system may include a dialysis machine for transferring dialysate to a patient from a dialysate source. The dialysate may flow from the dialysate source through a cartridge or cassette (e.g., a disposable cartridge or cassette) positionable within the dialysis machine. The cassette includes a fluid flow channel. The dialysis machine includes a heating chamber for in-line heating of the dialysate in the fluid flow channel. The fluid flow channel is arranged and configured to provide turbulent flow of the dialysate through the fluid flow channel to provide increased heat transfer from the heating chamber to the dialysate.

An apparatus for capturing circulating tumor cells (CTCs) from blood. The apparatus includes a wearable device that receives fluid from vasculature of a subject through an input channel. A pump is coupled to the input channel the pump configured to receive blood at a first flow rate and to convert the flow of the blood to a second flow rate. The device further includes a replaceable candidate cell capture module having a microfluidic capture stage with herringbone channel structures configured to capture the candidate cells by antibodies. The device is further configured to provide the blood back to the vasculature of the subject.

To provide a prediction display system and the like that utilize information obtained before an operation and during the operation, and predict an onset risk of a postoperative complication such as an acute kidney injury which has become a particularly great clinical problem. A prediction display system is configured such that an onset risk of a complication occurring after an operation is predicted using at least one of pH (hydrogen ion exponent), pO2 (oxygen partial pressure), Ht (hematocrit value), Hb (hemoglobin), DO2 (transportation amount of oxygen), and pCO2 (arterial blood carbon dioxide partial pressure) as parameters of blood gas taken before the operation and during the operation, and the onset risk of the complication occurring after the operation is displayed.

An embodiment includes a valve comprising: a valve channel that couples a valve input to a valve output; a one-way valve included within the channel; a filter; a first pressure relief port, wherein the first pressure relief port is configured to relieve negative pressure when pressure at the valve output is less than pressure at the valve input; a second pressure relief port, wherein the second pressure relief port is configured to relieve positive pressure when pressure at the valve output is greater than pressure at the valve input; wherein the one-way valve includes a monolithic portion that simultaneously seals the channel, the first pressure relief port, and the second pressure relief port; wherein the filter covers the first pressure relief port.

A method and a kit for the prevention of venous stenosis associated with the use of hemodialysis AV shunts. The kit may use a bifurcated needle for providing access to the shunt or blood vessel. One of the arms is used for returning the blood to the subject after dialysis treatment, while the other arm is used for inserting a device for cleaning the vein, the device being either an autonomous crawling device, or a passive tethered device moved down the vein by the blood flow. The autonomous crawling device may be a series of sequentially inflatable chambers, the stenosis being cleared by pressure from the outer walls of the chambers when inflated and moved. The passive device may be an element having a flexible disc-like structure, whose flexible peripheral edge slides along the inner walls of the blood vessel, compressing or clearing the material attached thereto.

A machine for extracorporeal blood treatment includes a user interface having a touch screen and a controller programmed to display on a screen (16) a display in which two distinct areas are arranged, one of which (161) exhibits a series of touch keys (17), wherein activation of any one touch key (17) causes visualization of an image in a second area (162) of the screen, wherein the images are displayed alternatively and are at least partly different one from another, wherein each touch key (17) is associated to an instruction, or to a group of instructions, each concerned with readying the machine for use, wherein each image is a pictograph of a configuration of the machine, correlated with an instruction associated to the touch key (17) selected, and wherein the operator is aided in making the machine ready for treatment.

A connection apparatus for sealing to a pathway of a mounting structure includes a body; and a port including a threaded portion extending from the body and a non-threaded portion extending from the threaded portion, the non-threaded portion carrying a gasket, the gasket positioned along the non-threaded portion such that the mounting structure to which the connection apparatus is mounted contacts the gasket prior to the threaded portion engaging a mating threaded portion of the mounting structure, the port providing fluid communication between the body and the pathway of the mounting structure. The body may be that of a valve that supplies any of air, water or oil as an operating fluid to, for example, inlet and outlet valves and a pump chamber of a medical fluid pump of a medical fluid delivery machine.

System and methods are provided for harvesting one or more organs, e.g., a lung from a donor body. In one embodiment, a distal end of a tubular member is introduced into the donor body's vasculature via a percutaneous access site, and the tubular member is manipulated until the distal end of the tubular member is disposed within the thoracic duct. Fluid is removed from the thoracic duct through the tubular member to a location exterior to the patient's body, and one or more organs are removed from the donor body. Optionally, one or more parameters within the thoracic duct or other parameters of the donor body may be monitored and fluid removal may be adjusted to reduce fluid accumulation within the one or more organs.

The present invention relates to medical fluid treatments, such as the treatment of renal failure. More specifically, the present invention relates to the testing of such systems.