Reduced rotational mass motor assembly for catheter pump

What is claimed is: 1. A catheter pump assembly for mechanical circulatory support of a heart, the catheter pump comprising: a catheter body having a proximal catheter portion, a distal catheter portion and an internal lumen defined in the catheter body; a drive shaft extending through the first lumen; an impeller coupled to the distal end and to the drive shaft for circulating blood in a medical procedure for treating a heart condition; and a motor comprising: an enclosure including a stationary stator electromagnetically coupled to a rotor that rotates in response to energizing the stator; an output shaft mechanically coupled to the rotor, the output shaft further being mechanically coupled to the drive shaft at the proximal catheter portion of the catheter body; and a first bearing configured to maintain the rotor in a radial alignment and an axial alignment with the stator inside the enclosure; wherein the first bearing includes at least one fluid passage for an axial flow of a cooling and lubricating fluid through the first bearing while the impeller is operating to provide the mechanical circulatory support. 2. The catheter pump assembly of claim 1 , further comprising a second bearing spaced from the first bearing inside the enclosure, wherein the rotor extends between the first bearing and the second bearing. 3. The catheter pump assembly of claim 1 , wherein the output shaft is rotatable relative to the first bearing. 4. The catheter pump assembly of claim 1 , the motor further comprising a rotor chamber inside the enclosure, wherein the first bearing is fixed inside the rotor chamber. 5. The catheter pump assembly of claim 1 , wherein the at least one cooling fluid passage comprises a plurality of cooling fluid passages. 6. The catheter pump assembly of claim 1 , wherein the first bearing comprises a cross-shaped structure having a plurality of radially extending arms. 7. The catheter pump assembly of claim 6 , wherein a gap is defined between adjacent ones of the plurality of radially extending arms, and wherein a cooling fluid passage is defined in each respective gap for an axial flow of the cooling and lubricating fluid inside the enclosure. 8. The catheter pump assembly of claim 1 , further comprising a cooling and lubricating fluid supply line in fluid communication with the at least one bearing while the impeller is operating. 9. The catheter pump assembly of claim 2 , wherein the cooling and lubricating fluid supply line is connected to the catheter body for a distal flow of cooling and lubricating fluid within the catheter body toward the impeller while the impeller is operating. 10. The catheter pump assembly of claim 3 , wherein the at least one fluid passage of the first bearing receives a proximal return flow of the cooling and lubricating fluid toward the motor from within the catheter body. 11. The catheter pump assembly of claim 1 , wherein the heart condition is a cardiogenic shock condition. 12. The catheter pump system of claim 1 , wherein the impeller is operable inside of a patient's vasculature while the motor is located outside of the patient's vasculature. 13. A motor for a catheter assembly including a drive shaft extending through a first lumen defined in a catheter body, the drive shaft including a proximal portion and a distal portion coupled to an impeller for moving blood, the motor comprising: an enclosure; a stator mounted stationary in the enclosure; a rotor received in the stator, the rotor being electromagnetically coupled to the stator and configured to rotate in response to energizing the stator; an output shaft mechanically coupled to the rotor, the output shaft being configured for mechanical coupling to the proximal portion of the drive shaft, wherein a rotation of the output shaft causes a rotation of the impeller via the drive shaft; and a first bearing configured to radially and axially align the rotor relative to the stator inside the enclosure; wherein the first bearing is configured to receive a flow of cooling and lubricating fluid while the impeller is rotating to move blood. 14. The motor of claim 13 , further comprising a second bearing spaced from the first bearing inside the enclosure, wherein the rotor extends between the first bearing and the second bearing. 15. The motor of claim 13 , wherein the output shaft is rotatable relative to the first bearing. 16. The motor of claim 13 , further comprising a rotor chamber inside the enclosure, wherein the first bearing is fixed inside the rotor chamber. 17. The motor of claim 13 , wherein the first bearing includes at least one cooling fluid passage for an axial flow of the cooling and lubricating fluid inside the enclosure. 18. The motor of claim 17 , wherein the at least one cooling fluid passage comprises a plurality of cooling fluid passages. 19. The motor of claim 13 , wherein the first bearing comprises a cross-shaped structure having a plurality of radially extending arms. 20. The motor of claim 19 , wherein a gap is defined between adjacent ones of the plurality of radially extending arms, and wherein a cooling fluid passage is defined in each respective gap to receive the flow of the cooling and lubricating fluid. 21. The motor of claim 13 , wherein the output shaft comprises a plurality of holes defined therein to facilitate a fastening of the drive shaft. 22. The motor of claim 13 , further comprising a second bearing spaced from first bearing with the rotor extending between the first bearing and the second bearing, wherein the first bearing and the second bearing each comprise at least one cooling fluid passage for an axial flow of cooling fluid inside the enclosure. 23. The motor of claim 13 , in combination with a cooling and lubricating fluid supply line in fluid communication with the first bearing while the impeller is operating. 24. The motor of claim 23 , wherein the fluid supply line outputs a distal flow of cooling and lubricating fluid toward the impeller. 25. The motor of claim 24 , wherein at least a portion of the distal flow of cooling and lubricating fluid is returned through the catheter body in a proximal direction toward the motor. 26. The motor of claim 24 , wherein the impeller is percutaneously insertable into a patient's vasculature, and wherein the motor is located outside of the patient's vasculature.