Organ perfusion device

The invention claimed is: 1. An organ perfusion device, comprising: a fluid container configured to hold an organ submerged in a perfusion fluid having a concentration of oxygen dissolved therein; a first fluid channel comprising a first inlet configured to be submerged in the container, a first outlet configured to be submerged in the container, and a first pump configured to circulate the perfusion fluid from the first inlet to the first outlet; a second fluid channel comprising a second inlet configured to be submerged in the container, a second outlet configured to be submerged in the container, and a second pump configured to circulate the perfusion fluid from the second inlet to the second outlet; and an oxygenation means configured to increase the concentration of oxygen dissolved in the perfusion fluid; wherein the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet is greater than the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet. 2. The organ perfusion device of claim 1 , wherein the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet is at least 25% greater than the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet. 3. The organ perfusion device of claim 1 , wherein the oxygenation means is disposed on the first fluid channel between the first pump and the first outlet. 4. The organ perfusion device of claim 3 , wherein the oxygenation means is only disposed on the first fluid channel. 5. The organ perfusion device of claim 3 , further comprising a fluid communication channel extending from the first fluid channel, downstream of the oxygenation means, to the second fluid channel. 6. The organ perfusion device of claim 1 , wherein the first outlet has a smaller inner diameter than the second outlet. 7. An organ perfusion device, comprising: a fluid container configured to hold an organ submerged in a perfusion fluid having a concentration of oxygen dissolved therein; a first channel comprising a first inlet configured to be submerged in the fluid container, a first outlet configured to be configured to be connected to the organ, and a first pump configured to circulate the perfusion fluid from the first inlet to the first outlet; a second channel comprising a second inlet configured to be submerged in the fluid container, a second outlet configured to be configured to be connected to the organ, and a second pump configured to circulate the perfusion fluid from the second inlet to the second outlet; and an oxygenation means configured to inject and dissolve oxygen in the perfusion fluid; wherein the oxygenation means is configured to create a difference between the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet and the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet. 8. The organ perfusion device of claim 7 , wherein the perfusion fluid has a first flow rate at the first outlet and a second flow rate at the second outlet, the second flow rate being greater than the first flow rate. 9. The organ perfusion device of claim 8 , wherein the second flow rate at the second outlet is at least 25% greater than the first flow rate at the first outlet. 10. The organ perfusion device of claim 7 , wherein the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet is greater than the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet. 11. The organ perfusion device of claim 7 , further comprising a temperature regulation means disposed on the second fluid channel between the second pump and the second outlet. 12. The organ perfusion device of claim 11 , wherein the temperature regulation means is only disposed on the second fluid channel. 13. A method of perfusing an organ submerged in a fluid container in a perfusion fluid having a concentration of oxygen dissolved therein, the method comprising: submerging a first outlet of a first fluid channel in the fluid container, the first fluid channel comprising a first inlet submerged in the fluid container and a first pump circulating the perfusion fluid from the first inlet to the first outlet; submerging a second outlet of a second fluid channel in the fluid container, the second fluid channel comprising a second inlet submerged in the fluid container and a second pump circulating the perfusion fluid from the second inlet to the second outlet; and creating a difference between the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet and the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet. 14. The method of claim 13 , wherein submerging the first outlet in the fluid container includes coupling the first outlet to the organ. 15. The method of claim 13 , wherein submerging the second outlet in the fluid container includes coupling the second outlet to the organ. 16. The method of claim 13 , wherein creating the difference between the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet and the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet includes giving more oxygen to the perfusion fluid leaving the first outlet than the perfusion fluid leaving the second outlet. 17. The method of claim 16 , wherein creating the difference between the concentration of oxygen dissolved in the perfusion fluid leaving the first outlet and the concentration of oxygen dissolved in the perfusion fluid leaving the second outlet includes giving at least 25% more oxygen to the perfusion fluid leaving the first outlet than the perfusion fluid leaving the second outlet. 18. The method of claim 13 , further comprising regulating a temperature of the perfusion fluid within the second fluid channel between the second pump and the second outlet. 19. The method of claim 13 , further comprising controlling the first pump and the second pump such that the perfusion fluid has a first flow rate at the first outlet and a second flow rate at the second outlet, the second flow rate being greater than the first flow rate. 20. The method of claim 19 , wherein the second flow rate at the second outlet is at least 25% greater than the first flow rate at the first outlet.