A test bench assembly for simulating cardiac surgery includes a passive heart having at least one pair of cardiac chambers with an atrial chamber and a ventricular chamber. A reservoir is adapted to house working fluid. A pressure generator fluidically connects both to the ventricular chamber of the passive heart and to the reservoir. A pressure regulation device provides working fluid in input to the atrial chamber with preload pressure, and working fluid in output from the ventricular chamber with afterload pressure. The pressure regulation device fluidically connects both to the atrial chamber of the passive heart and to the ventricular chamber of the passive heart. The pressure regulation device has a single compliant element for each pair of cardiac chambers, which provides working fluid with both preload, and afterload pressures.

A system for lung preservation is described. The system includes a cooler at least partially housing a cooling coil, the cooling coil including a proximal end configured to connect to an oxygen source and a distal end configured to connect to endotracheal tubing. The endotracheal tubing is in fluid communication with a conduit extending through the cooling coil. A positive end expiratory pressure valve connected to the endotracheal tubing. A method for preserving a lung and a method for preserving a lung for transportation are also described.

Methods and systems of maintaining, evaluating, and providing therapy to a lung ex vivo. The methods and systems involve positioning the lung in an ex vivo perfusion circuit; circulating a perfusion fluid through the lung, the fluid entering the lung through a pulmonary artery interface and leaving the lung through a left atrial interface; and ventilating the lung by flowing a ventilation gas through a tracheal interface. Maintaining the lung for extended periods involves causing the lung to rebreath a captive volume of air, and reaching an equilibrium state between the perfusion fluid and the ventilation gas. Evaluating the gas exchange capability of the lung involves deoxygenating the perfusion fluid and measuring a time taken to reoxygenate the perfusion fluid by ventilating the lung with an oxygenation gas.

An organ perfusion device includes an inlet for connection to the organ, and an outlet for connection to the organ. The device also includes a perfusion circuit including: a reservoir configured to hold a perfusion fluid; a waste receptacle, and a plurality of fluid conduits. The fluid conduits define: a delivery fluid path connecting the reservoir with the inlet; a return fluid path, independent of the delivery fluid path, connecting the reservoir with the outlet; and a waste fluid path connecting the reservoir with the waste receptacle. The device also includes a first flow control device configured to selectively prevent or allow fluid flow from the reservoir to the organ via the delivery fluid path; and a second flow control device configured to selectively prevent or allow fluid flow from the reservoir to the waste receptacle via the waste fluid path.

A repaired ex vivo organ suitable for transplantation in a human, said repaired ex vivo organ having undergone ex vivo organ perfusion for a maintenance period, wherein said organ had been assessed as being unsuitable for transplantation into a human before the maintenance period and was determined to be suitable for transplantation after the maintenance period.

The invention generally relates to systems, methods, and devices for ex vivo organ care. More particularly, in various embodiments, the invention relates to caring for a liver ex vivo at physiologic or near-physiologic conditions.

A donor organ treatment apparatus has a container for holding an organ and a perfusion liquid circuit. The perfusion circuit includes a supply conduit downstream of an oxygenator and a heat exchanger for supplying perfusion liquid from the oxygenator and the heat exchanger to an organ in the container and a return conduit upstream of the oxygenator and the heat exchanger for guiding perfusion liquid from the organ inside the container to the oxygenator and the heat exchanger. The supply conduit is provided with an outlet port coupling for connection to a perfusion catheter and the return conduit is provided with an inlet port coupling for connection to a return catheter. A method for successively perfusing an organ in-situ and ex-vivo with liquid circulating through the same perfusion circuit is also described.

A system and method for growing and maintaining biological material including producing a protein associated with the tissue, selecting cells associated with the tissue, expanding the cells, creating at least one tissue bio-ink including the expanded cells, printing the at least one tissue bio-ink in at least one tissue growth medium mixture, growing the tissue from the printed at least one tissue bio-ink, and maintaining viability of the tissue.

The present invention relates to the field of bio-artificial liver technology. Particularly, the invention provides an integrated hybrid bio-artificial liver support system that provides the features of artificial liver assist devices with that of bio-artificial liver support systems.

The disclosure generally relates to a system for perfusing an ex-vivo liver including a pump configured to pump a perfusion fluid through a perfusion circuit, the pump in fluid communication with a hepatic artery interface and a portal vein interface; an oxygenator; a heater; an inferior vena cava interface in fluid communication with an inferior vena cava of the ex-vivo liver; and a reservoir configured to receive the perfusion fluid from the inferior vena cava of the ex-vivo liver and store a volume of fluid.