Hemodialysis system

What is claimed is: 1. A blood circuit assembly for a dialysis unit, comprising: a pair of pneumatic pumps for circulating blood received from a patient through a circuit including a dialyzer unit and returning the blood to the patient, the pneumatic pumps having pneumatic control ports arranged for alignment and mating with corresponding ports located on an exposed panel of the dialysis unit by pushing the control ports into engagement with the corresponding ports with mounting of the blood circuit assembly to the exposed panel; an air trap having an inlet and an outlet arranged to remove air from blood circulating in the circuit; a single unitary member that defines, at least in part, the pumps, a retaining member for the air trap and a plurality of routing channels for flexible tubing, the plurality of routing channels including a routing channel for a tube extending from the outlet of the air trap to an occluder position, the retaining member for the air trap being configured to support the air trap at a location above a lowermost part of the routing channel for the tube and above an air-in-line detector configured to detect air in the tube; a pair of dialyzer connections arranged to connect to the inlet and outlet of a dialyzer unit; a pair of blood line connectors, including an arterial blood line connector for receiving blood from the patient and providing blood to the pneumatic pumps and a venous blood line connector for returning blood to the patient; and flexible tubing fluidly connecting the pumps, the air trap, the dialyzer connections and the blood line connectors. 2. The blood circuit assembly of claim 1 , further comprising an anticoagulant connection for engaging with an anticoagulant source and providing anticoagulant into the circuit. 3. The blood circuit assembly of claim 2 , further comprising a pump for pumping anticoagulant from the anticoagulant source to the circuit. 4. The blood circuit assembly of claim 3 , wherein the pair of pneumatic pumps, the anticoagulant connection, and the anticoagulant pump are part of a pump cassette. 5. The blood circuit assembly of claim 4 , wherein the arterial blood line connector is connected to an inlet for the pump cassette, an outlet for the pump cassette is connected to a dialyzer inlet connector, a dialyzer outlet connector is connected to the inlet of the air trap, and an outlet of the air trap is connected to the venous blood line connector. 6. The blood circuit assembly of claim 2 , wherein the anticoagulant connection includes a vial holder and a spike, and the anticoagulant source is a vial of heparin. 7. The blood circuit assembly of claim 1 , wherein the inlet of the air trap is supported by the single unitary member at a position above the outlet of the air trap when the blood circuit assembly is mounted to a dialysis unit. 8. The blood circuit assembly of claim 1 , wherein the pneumatic pumps are diaphragm pumps. 9. The blood circuit assembly of claim 1 , wherein the blood line connectors are arranged for a threaded luer-type connection to a patient access, and are arranged for a press-in type connection to the dialysis unit. 10. The blood circuit assembly of claim 9 , wherein the blood line connectors include a frustoconical member with an internal thread for the luer-type connection, and a central tube extending from a center of the frustoconical member. 11. The blood circuit assembly of claim 1 , wherein the single unitary member includes tube engagement members having a hole through which a respective tube passes, the engagement members engaging with the respective tube to allow the tube to be pulled and stretched for engagement with an occluder of the dialysis unit. 12. The blood circuit assembly of claim 1 , wherein the single unitary member defines the pneumatic control ports for the pumps. 13. The blood circuit assembly of claim 1 , wherein the single unitary member defines a concave chamber portion for the pumps. 14. The blood circuit assembly of claim 1 , wherein the single unitary member defines a chamber portion of a plurality of valves used to control flow through the pumps. 15. The blood circuit assembly of claim 1 , wherein the single unitary member defines routing channels for flexible tubing to position the tubing for engagement with an occluder when the assembly is mounted to the dialysis unit. 16. A blood circuit assembly and drain cassette for a dialysis unit, the blood circuit assembly comprising: a blood pump cassette comprising a pair of pneumatic pumps for circulating blood received from a patient through a circuit including a dialyzer unit and returning the blood to the patient; an organizing tray formed as a single unitary member with a back plate of the blood pump cassette; an air trap attached to the organizing tray arranged to remove air from blood circulating in the circuit; a pair of dialyzer connections fluidly connected to the air trap and the pumps and arranged to connect to the inlet and outlet of a dialyzer unit; a pair of blood line connectors fluidly connected to the pumps and the air trap, including an arterial blood line connector for receiving blood from the patient and providing blood to the pneumatic pumps and a venous blood line connector for returning blood to the patient; and flexible tubing fluidly connecting the pumps, the air trap, the dialyzer connections and the blood line connectors; wherein the organizing tray engages with at least a portion of the flexible tubing to position the flexible tubing for mounting at an occluder position for interaction with an occluder of the dialysis unit, and wherein the organizing tray supports the air trap at a location that is above the occluder position and above an air-in-line detector configured to detect air in a tube extending from an outlet of the air trap to the occluder position. 17. The blood circuit assembly of claim 16 , wherein single unitary member additionally defines a plurality of routing channels for at least a portion of the flexible tubing. 18. The blood circuit assembly of claim 16 , wherein the single unitary member additionally defines an air trap cavity that receives the air trap. 19. The blood circuit assembly of claim 16 , wherein the pneumatic pumps comprise pneumatic control ports arranged for alignment and mating with corresponding ports located on an exposed panel of the dialysis unit by pushing the control ports into engagement with the corresponding ports with mounting of the blood circuit assembly to the exposed panel, and the single unitary member defines the pneumatic control ports for the pumps. 20. The blood circuit assembly of claim 16 , wherein the single unitary member defines a concave chamber portion for the pumps. 21. The blood circuit assembly of claim 16 , wherein the single unitary member defines a chamber portion of a plurality of valves used to control flow through the pumps. 22. The blood circuit assembly of claim 16 , wherein the single unitary member defines routing channels for flexible tubing to position the tubing at the occluder position for engagement with an occluder when the assembly is mounted to the dialysis unit. 23. The blood circuit assembly of claim 16 , wherein the arterial blood line connector is connected to an inlet for the pneumatic pumps, an outlet for the pneumatic pumps is connected to a dialyzer inlet connector, a dialyzer outlet connector is connected to the inlet of the air trap, and an outlet of the air trap is connected to t