초록 ▼

Apparatus is provided including an element shaped so as to define at least one surface. The element is adapted to be implanted in an ascending aorta of a subject in a vicinity of an aortic valve, and, during systole, to store, as potential energy, work applied to the surface by blood of the subject

Apparatus is provided including an element shaped so as to define at least one surface. The element is adapted to be implanted in an ascending aorta of a subject in a vicinity of an aortic valve, and, during systole, to store, as potential energy, work applied to the surface by blood of the subject passing through the element. The element allows at least 75% of the blood passing into the element during systole of each cardiac cycle to exit the element during systole of the respective cardiac cycle. The element applies the stored energy to push blood towards at least one coronary artery of the subject during diastole. For some applications, the surface includes a first surface, and the element is shaped so as to define a second surface, which is configured to apply the stored energy. Other embodiments are also described.

대표청구항 ▼

The invention claimed is: 1. Apparatus, comprising: a passive rotating device, configured to be implanted in an artery of a subject, comprising an axial shaft and one or more blades coupled to the shaft, configured to rotate due to blood passing through the rotating device during systole applying w

The invention claimed is: 1. Apparatus, comprising: a passive rotating device, configured to be implanted in an artery of a subject, comprising an axial shaft and one or more blades coupled to the shaft, configured to rotate due to blood passing through the rotating device during systole applying work to the blades, and configured to push blood towards an artery of the subject other than the artery in which the apparatus is implanted, in response to the blood applying work to the blades; and a casing, configured to couple the rotating device to the artery. 2. The apparatus according to claim 1, wherein the passive rotating device is configured to be implanted in an aorta of the subject. 3. The apparatus according to claim 1, wherein the passive rotating device is configured to be implanted in the artery of the subject by aligning the axis of the rotating device with an axis of the artery. 4. The apparatus according to claim 1, wherein in pushing blood towards the artery of the subject other than the artery in which the apparatus is implanted, the passive rotating device is configured to push the blood towards a periphery of the artery in which the apparatus is implanted. 5. The apparatus according to claim 1, wherein the passive rotating device is configured to push blood towards the artery of the subject other than the artery in which the apparatus is implanted, during at least a portion of diastole. 6. The apparatus according to claim 1, wherein the passive rotating device is configured to be implanted in an aorta of the subject, and wherein in pushing blood towards the artery of the subject other than the artery in which the apparatus is implanted, the passive rotating device is configured to push the blood into a coronary artery of the subject. 7. Blood-flow energy storage apparatus comprising: an always-open blood-flow pathway portion arranged to be implanted in a blood vessel of a subject; and a displaceable blood-flow energy storage portion: at least partially located within the always-open blood-flow pathway portion and being displaceable in response to blood flow through the energy storage portion, for receiving kinetic energy from the blood flow and temporarily storing the kinetic energy, and comprising a turbine, comprising an axial shaft and one or more turbine blades coupled to the shaft, the turbine rotating in a first direction in response to blood flow therethrough. 8. The apparatus according to claim 7, wherein the blood-flow energy storage portion further comprises an elastic element, coupled to the turbine, the turbine storing the kinetic energy from the blood flow by storing the energy in the elastic element, and the elastic element releasing the stored energy by rotating the turbine in a second direction opposite the first direction. 9. The apparatus according to claim 8, wherein the turbine is rotated by the blood flow therethrough during systole of the subject, and wherein the elastic element drives the blades to push blood towards at least one coronary artery of the subject by rotating the turbine in the second direction during diastole of the subject.