Rotary seal for cantilevered rotor pump and methods for axial flow blood pumping

What is claimed is: 1. An implantable blood pump comprising: a pump housing defining a blood flow passage therethrough; a rotor including a rotatable rotor shaft that extends into the blood flow passage such that a distal portion of the rotor facilitates blood flow through the blood flow passage upon rotation of the rotatable rotor shaft; a mechanical bearing assembly coupled with a proximal portion of the rotatable rotor shaft so as to allow rotation of the rotor during operation of the pump; and a rotary blood seal assembly disposed at an interface of a first portion of the pump housing and the rotatable rotor shaft, wherein the rotary blood seal assembly comprises a first face seal component disposed on the rotatable rotor shaft and a second face seal component disposed on the first portion of the pump housing, the first and second face seal components being slidably engaged with each other so as to allow rotation of the rotatable rotor shaft, wherein the rotary blood seal assembly is configured with a preload at an interface between the first and second face seal components to inhibit any leakage path therebetween thereby avoiding contact between the mechanical bearing assembly and any blood flowing through the blood flow passage during operation of the pump, wherein the preload is provided at least in part by a first magnet disposed along the first face seal component and a second magnet disposed along the second face seal component, the first magnet and the second magnet being configured such that an associated magnetic force during operation of the pump increases a contact force between the first and second face seal components. 2. The blood pump of claim 1 , wherein the first portion of the pump housing is a rear cover removably coupleable with a second portion of the pump housing. 3. The blood pump of claim 1 , wherein the first and second face seal components comprise silicon carbide, ceramics or any suitable high wear material. 4. The blood pump of claim 3 , wherein the rotary blood seal assembly includes a compliance member adapted to provide another part of the preload at the interface between the first and second face seal components when the pump is assembled. 5. The blood pump of claim 4 , wherein the compliance member is deflectable in a direction along which the rotor extends. 6. The blood pump of claim 4 , wherein the compliance member is sufficiently rigid to exert a desired biasing force towards the first face seal component of the rotatable rotor shaft so as to ensure engagement between the first and second face seal components of the rotary blood seal assembly. 7. The blood pump of claim 4 , further comprising a rear cover of the pump housing, wherein the compliance member is a ridge or membrane extending from the rear cover of the pump housing that extends at least partly about an opening through which the proximal portion of the rotatable rotor shaft extends. 8. The blood pump of claim 7 , wherein the ridge or membrane is integral with the rear cover and deflectable in a proximal direction of the rotatable rotor shaft so as to exert a biasing force in a distal direction along the rotatable rotor shaft. 9. The blood pump of claim 7 , wherein the ridge or membrane is a separate member coupled with the rear cover by a weld so as to be deflectable in a proximal direction of the rotatable rotor shaft so as to exert a biasing force in a distal direction along the rotatable rotor shaft. 10. The blood pump of claim 1 , wherein the rotary blood seal assembly further includes a bio-absorbable seal to further inhibit intrusion of blood between the first and second face seal components. 11. The blood pump of claim 1 , wherein at least one of the first and second magnets includes a permanent magnet. 12. The blood pump of claim 1 , wherein the first magnet is disposed distally of the first face seal component along the rotor. 13. The blood pump of claim 12 , wherein the second magnet is disposed proximally of the second face seal component along the rotor. 14. A method of pumping blood with a blood pump, the method comprising: operating a blood pump so as to transport blood along a blood flow path through a pump housing of the blood pump, wherein operating the blood pump comprises rotating a rotatable rotor shaft of a rotor so that movement of the rotor forces blood along the blood flow path, the rotor being rotatably supported by a bearing assembly; and sealing the bearing assembly from any contact with blood flowing along the blood flow path with a rotary blood seal assembly between a first portion of the pump housing and a portion of the rotatable rotor shaft, wherein sealing comprises slidably engaging a first face seal component disposed on the rotatable rotor shaft and a second face seal component disposed on the first portion of the pump housing, the first and second face seal components being slidably engaged with each other so as to allow rotation of the rotatable rotor shaft, wherein the rotary blood seal assembly is configured with a preload at an interface between the first and second face seal components to inhibit any leakage path therebetween thereby avoiding contact between the bearing assembly and any blood flowing through the blood flow path during operation of the pump, wherein the preload is provided at least in part by a first magnet disposed along the first face seal component and a second magnet disposed along the second face seal component, the first magnet and the second magnet being configured such that an associated magnetic force during operation of the pump increases a contact force between the first and second face seal components. 15. The method of claim 14 , wherein the first portion of the pump housing is a rear cover removably coupleable with a second portion of the pump housing. 16. The method of claim 14 , wherein the rotary blood seal assembly includes a compliance member adapted to provide another part of the preload at the interface between the first and second face seal components when the pump is assembled. 17. The method of claim 16 , wherein sealing comprises deflecting the compliance member in a direction along which the rotor extends. 18. The method of claim 17 , wherein the compliance member is sufficiently rigid to exert a desired biasing force towards the first face seal component of the rotatable rotor shaft so as to ensure engagement between the first and second face seal components of the rotary blood seal assembly. 19. The method of claim 14 , wherein at least one of the first and second magnets are permanent magnets. 20. The method of claim 19 , wherein the first magnet is disposed distally of the first face seal component along the rotor and the second magnet is disposed proximally of the second face seal component along the rotor. 21. The method of claim 14 , wherein the interface between the first and second face seal components comprises a sintered surface or a bio-absorbable fill material, the sealing further comprising forming a neointima layer along the interface between the first and second face seal components.