An extracorporeal blood heating and cooling system that is connectable to an oxygenator of a cardiopulmonary bypass system, the heating and cooling system comprising: a heater-cooler unit; a coolant flow circuit that is configured to pass coolant through the heater-cooler unit and the oxygenator; and a cardioplegia coolant circuit that is configured to pass coolant through the heater-cooler unit and a cardioplegia heat exchanger; wherein when the heating and cooling system is in a purging mode, the coolant flow circuit and the cardioplegia coolant circuit contain temperature-controlled coolant having a trisodium phosphate concentration of about 1-35 millimole/liter; wherein when the heating and cooling system is in a coolant mode, the coolant flow circuit and the cardioplegia coolant circuit contain temperature-controlled coolant having a trisodium phosphate concentration of about 1-10 millimole/liter; and wherein when the heating and cooling system is in the coolant mode or the purging mode, a first and second plurality of coolant conduits within the oxygenator and the cardioplegia heat exchanger are capable of maintaining a trisodium phosphate concentration ratio across the wall of such coolant conduits of at least 100:1, from the interior to the exterior of each coolant conduit. Methods of purging and operating such extracorporeal blood heating and cooling systems are also disclosed.

Methods and for treatment of cancer and other diseases including complications from late stage viral infections by inducing hyperthermia in a patient relying on withdrawing blood from the patient and returning the withdrawn blood to the patient to establish an extracorporeal flow circuit. Blood is heated by passing through the extracorporeal circuit at a controlled rate until a target body core temperature in is achieved. Usually, the blood will be subjected to a continuously re-circulating dialysis to balance electrolytes. Additionally, the blood will be subjected to a continuously recirculating regeneration through a carbon sorbent column where toxins and contaminants are removed. The blood temperature is maintained at the target blood temperature for a treatment period, and the blood is cooled after the treatment period has been completed. The method can also be effective in treating rheumatoid arthritis, scleroderma, hepatitis, sepsis, the Epstein-Barr virus, and patients with life threatening complications from other viruses, including the COVID-19 virus. A method for removing viruses from the blood supply in an external circuit is also presented.

A biphasic system and method for assisting breathing of a patient by controllably providing breathing gas to the patient and taking exhaled gas from the patient during inspiration and expiration phases. The system and method having a pair of pressure-controlling means such as hydrostatic pressures or pop-off valves that are coupled to the patient breathing interface. Various means for controlling gas pressure at the breathing interface are described.

An oxygenator includes a housing having a blood inlet and a blood outlet, the blood inlet extending into an interior of the housing. A heat exchanger is disposed within the housing, and is coupled, at an inlet end, to a heat-exchange fluid inlet. A gas exchanger also is disposed within the housing, and includes a bundle of gas-exchange fibers coupled, at a gas outlet end, to a gas-exchange fluid outlet. The oxygenator includes at least one insulator configured to thermally insulate at least the gas outlet end of the bundle of gas-exchange fibers.

The present application refers to a heat transfer liquid for a temperature control device for human body temperature control during extracorporeal circulation, a temperature control device, the use of heat transfer liquid for extracorporeal circulation and a method of human body temperature control using a heat transfer liquid. The head transfer liquid consists of ethylene glycol or propylene glycol at about 25 volume-percent to about 35 volume-percent, hydrogen peroxide at 0.05 volume-percent or less and sterile, filtered and de-mineralized water as rest.

A working fluid cassette for an intravascular heat exchange catheter includes a frame holding two closely spaced, square polymeric membranes in tension. Working fluid from the catheter is directed between the membranes. The cassette is closely received between two refrigerant cold plates to exchange heat with the working fluid, which is circulated back to the catheter.

Systems, devices, and methods for organ Retroperfusion along with regional mild hypothermia. One such system includes a hypothermia system including a hypothermia system outlet and a hypothermia system inlet; and a connector comprising a coolant inlet, a coolant outlet, a coolant reservoir, and a blood lumen, whereby the coolant inlet is configured to couple to the hypothermia system outlet and whereby the coolant outlet is configured to couple to the hypothermia system inlet; whereby a cooling product, when the hypothermia system is connected to the connector, can flow from the hypothermia system, through the hypothermia system outlet, into the coolant inlet, through the coolant reservoir, into the coolant outlet, and into the hypothermia system inlet, so that the cooling product can cool blood flowing through the blood lumen.

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.

The present invention relates to a method of replenishing a system for injecting a substance into the patient's body, when the system is implanted in the patient's body. The method involves replenishing the implanted reservoir by a replenishing needle penetrating the patient's skin and injecting infusion liquid comprising the substance through the replenishing needle directly or indirectly into the reservoir.

An extracorporeal blood cooling or heating circuit includes an intravenous catheter for withdrawing a patient's blood coupled to a combined pump/heat exchanger device. One or more sensors are provided upstream and/or downstream of the pump/heat exchanger device for measuring pressure, temperature, fluid flow, blood oxygenation, and other parameters. A controller is operatively coupled to the pump/heat exchanger device and the one or more sensors to control the speed of the pump inside the pump/heat exchanger device and regulate the blood temperature by controlling the operation of the heat exchanger. The combined pump/heat exchanger device includes a housing having at least one inlet and at least one outlet, a pump portion defining a blood circuit inside the housing, and a heat exchanger portion contained within the housing for selectively heating or cooling the blood.