A perfusion lumen is connected to at least one perfusion blood vessel among a plurality of blood vessels that extends from a branch of a plurality of blood vessels protruding from a liver, the branch existing on a distal side viewed from the liver, to a further distal side viewed from the liver. The perfusion lumen is supplied with perfusate to perfuse the liver and maintain the condition of the liver. Among blood vessels that are not connected to the perfusion lumen, at least one conserved blood vessel is obstructed and conserved for anastomosis to a blood vessel of the living body. Accordingly, the perfusion state of the liver is maintained even during anastomosis to the blood vessels of the living body. This enables anastomosis to the blood vessels of the living body while maintaining the perfusion state of the liver.

An apparatus for perfusing an organ or tissue including a perfusion circuit for perfusing the organ or tissue with liquid perfusate; and an oxygenation system for oxygenating perfusate that recirculates through the perfusion circuit. The oxygenation system includes an oxygen circuit for delivering oxygen to the liquid perfusate and an air circuit for delivering ambient air to the liquid perfusate. The air may be pumped through the oxygenation system via an air pump. The air or oxygen may be bubble through the perfusate to increase oxygen levels in the perfusate. Such supplemental oxygen may beneficial during hypothermic preservation of organs.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially lung tissue, through the use of an expandable accumulator to maintain a constant pressure within the lumen of the organ even during external pressure fluctuations due to, for example, flight. Systems and methods may include prolonging donor organ viability in storage through the use of an organ container that mimics the geometry and orientation of the organ in vivo.

Systems and methods to perfuse isolated tissue are provided to avoid ischemia-related tissue damage over an extended perfusion time is provided. A system can comprise a reservoir sized and dimensioned to contain a perfusate. A perfusion supply line can comprise a pump, a cooling system, an oxygenator, and at least one filter. The perfusion supply line can be in fluid communication with the reservoir to draw the perfusate from the reservoir and cool and oxygenate the perfusate. The system can also include an arterial line in fluid communication with the perfusion supply line to direct perfusate from the reservoir to the isolated tissue. A venous outflow can be in fluid communication with the isolated tissue to remove the perfusate from the isolated tissue. A perfusion return line can be in fluid communication with the venous outflow to return the perfusate from the isolated tissue to the reservoir.

A system for the hypothermic transport of biological samples, such as tissues, organs, or body fluids. The system includes a self-purging preservation apparatus to suspend a sample in preservation fluid and perfuse a tissue with preservation fluid. The self-purging preservation apparatus is placed in an insulated transport container having a cooling medium. When assembled, the system allows for transport of biological samples for extended periods of time at a stable temperature.

The invention provides, in various embodiments, devices and methods relating to ex-vivo organ care. In certain embodiments, the invention relates to aortic cannulas for use in perfusion systems to return perfusate to the heart or delivering perfusate from the heart while the organ is sustained ex vivo at physiologic or near-physiologic conditions.

Apparatus for perfusion of multiple types of organs include base unit configured to removably couple with a perfusion module for perfusing an organ. The base unit has conduits for connecting a source of a perfusate to the organ to circulate the perfusate through the organ; first and second pumps coupled to the conduits for driving circulation of the perfusate in the conduits; and a controller configured and connected for controlling the first and second pumps to regulate the circulation of the perfusate through the organ. The controller is operable to control the first and second pumps to perfuse the organ in accordance with organ specific perfusion parameters. The organ specific perfusions parameters are selected based on the type of the organ, and may be selected by an operator for at least two organ types selected from the group of heart, liver, kidney and lung.

A perfusion bioreactor and a perfusion device. Each perfusion device has a mesh structure, and an encapsulated organ tissue (EOT) disposed in the mesh structure. The EOT has a body with a thickness defined between a first surface of the body and a second surface of the body. The body has at least one channel extending into the body from one of the first and second surfaces to receive a fluid therein. The at least one channel has a diameter selected to diffuse solutes out of the fluid and into the body. The perfusion devices are arranged one adjacent to another and spaced apart from each other along the length of the bioreactor to receive fluid, and to perfuse the fluid to the EOT of each perfusion device and to the at least one channel therein. A method of processing blood plasma and an artificial liver system are also disclosed.

Systems and methods of the invention generally relate to prolonging viability of bodily tissue, especially an organ such as a lung, by adjusting pressure as needed to maintain a constant pressure within the organ even during external pressure fluctuations due, for example, to transportation of the organ in an airplane. Gas passing into and out of the organ may be conditioned to prolong tissue viability.

A portable, ex vivo perfusion system for preserving detached biological tissue includes a receptacle for housing the tissue in a normothermic environment, a perfusion core to pump perfusate through the tissue via at least one conduit, at least one detection device to measure parameters during perfusion, and at least one parameter control device to maintain the parameter in a predetermined threshold. The system also include a controller with instructions to receive the measured parameters, compare the parameters to predetermined thresholds, and when the parameters are outside the thresholds change an output of the at least one parameter control device to get the parameters within the threshold and alert a user that parameters were outside the thresholds.