Renal pump

The invention claimed is: 1. A method comprising: identifying a subject as suffering from a condition selected from the group consisting of: cardiac dysfunction, congestive heart failure, reduced renal blood flow, increased renal vascular resistance, arterial hypertension, and kidney dysfunction; and in response thereto, reducing blood pressure within a renal vein of the subject, by placing an impeller inside the subject's renal vein and activating the impeller to pump blood from the renal vein into a vena cava of the subject. 2. The method according to claim 1 , wherein activating the impeller to pump blood from the renal vein into the vena cava comprises enhancing a rate of blood flow from the renal vein into the vena cava, without causing a substantial change in a direction of the blood flow relative to a direction of blood flow from the renal vein into the vena cava in an absence of activating the pump. 3. The method according to claim 1 , wherein activating the impeller to pump blood from the renal vein into the vena cava comprises activating the impeller to pump blood from the renal vein directly into a portion of the vena cava that is adjacent to the renal vein. 4. The method according to claim 1 , wherein activating the impeller to pump blood from the renal vein into the vena cava comprises activating the impeller to pump blood from the renal vein into the vena cava, without removing blood from a venous system of the subject into a non-venous receptacle. 5. The method according to claim 1 , wherein placing the impeller inside the renal vein comprises protecting the subject's renal vein from being injured by the impeller, by placing the impeller into the renal vein, with a cage disposed around the impeller, the cage separating an inner wall of the renal vein from the impeller. 6. The method according to claim 5 , wherein placing the impeller into the renal vein with the cage disposed around the impeller comprises placing the impeller into the renal vein, with the cage disposed around the impeller, the cage and the impeller being engaged to one another by an engagement mechanism, such that in response to the cage becoming radially compressed, the impeller becomes axially elongated such that the cage maintains a separation between the wall of the renal vein and the impeller. 7. The method according to claim 1 , wherein: placing the impeller inside the subject's renal vein comprises: placing inside the subject's renal vein: an impeller configured, in a radially-expanded configuration thereof, to pump blood through the renal vein by rotating; and a radially-expandable cage disposed around the impeller; radially expanding the cage and the impeller inside the renal vein, such that the impeller is separated from an inner wall of the renal vein by the cage, the impeller being engaged with respect to the cage, such that, in response to the cage becoming radially compressed, the impeller is axially elongated, such that the impeller remains separated from the inner wall of the renal vein; and activating the impeller to pump blood from the renal vein into the subject's vena cava comprises operating a control unit to pump blood from the renal vein into the subject's vena cava, by rotating the impeller. 8. The method according to claim 7 , further comprising operating the control unit to: measure pressure within the subject's renal vein at a first location within the renal vein that is upstream of the impeller, and at a second location within the renal vein that is downstream of the impeller; and control rotation of the impeller responsively to the pressure measured at the first and second locations. 9. The method according to claim 7 , wherein operating the control unit to rotate the impeller comprises operating the control unit to rotate the impeller, while the cage is maintained in a rotationally fixed position. 10. The method according to claim 7 , wherein the cage includes struts that are shaped to define cells, and wherein radially expanding the cage comprises separating the renal vein wall from the impeller even if the renal vein wall protrudes through a cell of the cage, by radially expanding the cage. 11. The method according to claim 7 , wherein: placing the impeller and the cage inside the renal vein comprises placing the impeller and the cage inside the renal vein, the impeller being coupled to the cage such that a longitudinal axis of the impeller is aligned with a longitudinal axis of the cage, the cage includes a cage that defines a central portion thereof that has a generally cylindrical shape, an outer surface of the cage at the generally cylindrical portion of the cage being parallel to the longitudinal axis of the cage, and radially expanding the cage inside the renal vein comprises radially expanding the cage inside the renal vein such that the outer surface of the cage at the generally cylindrical portion of the cage engages the inner wall of the renal vein, the cage thereby becoming oriented within the renal vein such that a longitudinal axis of the cage is parallel to a local longitudinal axis of the renal vein. 12. The method according to claim 7 , wherein: the renal vein has a given diameter in an absence of the cage; radially expanding the cage comprises widening a portion of the renal vein such that a diameter of the portion of the renal vein is greater than the given diameter; and radially expanding the impeller comprises radially expanding the impeller such that a span of the impeller is at least equal to the given diameter. 13. The method according to claim 7 , further comprising operating the control unit to: measure flow through the renal vein; and control rotation of the impeller responsively to the measured flow. 14. The method according to 13 , wherein operating the control unit to measure flow through the renal vein comprises operating the control unit to measure blood flow via a thermal flow sensor that is disposed within a housing, the housing being configured such that blood flow through the housing is substantially in a direction parallel to a local longitudinal axis of the renal vein.