A blood pump includes a hub having an axis of rotation and a generally cylindrical shape. The hub has an upstream end region, a central region, and a downstream end region, and the hub includes a magnetic material. Blades that are disposed on the downstream end region of the hub extend downstream of
A blood pump includes a hub having an axis of rotation and a generally cylindrical shape. The hub has an upstream end region, a central region, and a downstream end region, and the hub includes a magnetic material. Blades that are disposed on the downstream end region of the hub extend downstream of the hub.
대표청구항▼
1. A graft assembly for connecting a pump outlet to tissue, comprising: a woven material defining a lumen;a reinforcement component about an outer circumference of the woven material;a support structure molded about an end region of the woven material for coupling the woven material to the pump outl
1. A graft assembly for connecting a pump outlet to tissue, comprising: a woven material defining a lumen;a reinforcement component about an outer circumference of the woven material;a support structure molded about an end region of the woven material for coupling the woven material to the pump outlet, the support structure including an integral flange; anda fitting slidably positioned over the support structure, the fitting configured to engage the flange of the support structure and capture the graft assembly to an outlet portion of a pump, the fitting configured to attach to the outlet portion of the pump by sliding linearly over the outlet portion. 2. The graft assembly of claim 1, wherein the flange of the support structure is formed of a compressible material, and wherein the fitting is configured to snap over a raised portion on an outer surface about the pump outlet, the fitting compressing the flange of the support structure such that the compressed flange forms a hermetic seal around the pump outlet. 3. The graft assembly of claim 1, wherein the reinforcement component about the outer circumference of the woven material comprises a member that extends helically about the outer circumference of the woven material. 4. The graft assembly of claim 3, wherein the member wrapped helically about the outer circumference of the woven material comprises a wire or a polymer monofilament wrapped helically about the outer circumference of the woven material. 5. The graft assembly of claim 1, wherein a portion of the reinforcement member is embedded in the support structure. 6. The graft assembly of claim 1, wherein the support structure is generally cylindrical and the flange is located at an end of the support structure. 7. The graft assembly of claim 1, wherein the support structure is formed of a resilient material. 8. The graft assembly of claim 1, wherein the fitting is configured to capture the support structure to the outlet portion of the pump by sliding linearly along an outlet axis of the pump outlet. 9. The graft assembly of claim 1, wherein the fitting comprises inwardly extending portions configured to project inward to connect the fitting to the outlet portion after the fitting slides over the outlet portion. 10. The graft assembly of claim 1, wherein the support structure extends circumferentially about a central longitudinal axis of the support structure, and wherein the fitting is configured to compress the flange radially inward toward the central longitudinal axis of the support structure. 11. The graft assembly of claim 1, wherein the flange of the support structure extends circumferentially around a central longitudinal axis of the support structure, and the flange has a cross-section in a plane including the central longitudinal axis, the cross-section of the flange having a curved outer perimeter. 12. A graft assembly for connecting a pump outlet to tissue, comprising: a woven material defining a lumen;a reinforcement component about an outer circumference of the woven material; anda support structure molded about an end region of the woven material for coupling the woven material to the pump outlet, the support structure including a flange configured to be compressed by a fitting, the flange of the support structure being formed of a compressible material, wherein the flange forms a circumferential hermetic seal directly thereunder when the flange is compressed between the fitting and an outer perimeter of the pump outlet. 13. The graft assembly of claim 12, wherein the support structure extends circumferentially about a central longitudinal axis of the support structure, and wherein graft assembly further comprises a fitting configured to compress the flange radially inward toward the central longitudinal axis of the support structure. 14. The graft assembly of claim 12, further comprising a fitting configured to capture the support structure to an outlet portion of the pump by sliding linearly over the outlet portion along an outlet axis of the pump outlet. 15. The graft assembly of claim 12, wherein the flange of the support structure extends circumferentially around a central longitudinal axis of the support structure, and the flange has a cross-section in a plane including the central longitudinal axis, the cross-section of the flange having a curved outer perimeter. 16. The graft assembly of claim 12, further comprising a fitting configured to mesh with a threaded portion on an outer surface about the pump outlet, the fitting configured to compress the flange of the support structure such that the flange forms a hermetic seal around the pump outlet. 17. An implantable graft assembly for connecting a heart pump outlet to a blood vessel, comprising: a woven material defining a lumen;a reinforcement component about an outer circumference of the woven material; anda support structure molded about an end region of the woven material for coupling the woven material to the heart pump outlet, the support structure including a flange which extends continuously circumferentially around the support structure and is configured to be captured by a fitting;wherein the heart pump outlet is defined by an outflow cannula of a heart pump, and the support structure is configured such that the flange extends circumferentially around the outflow cannula when the implantable graft assembly is attached to the heart pump outlet. 18. The graft assembly of claim 17, wherein the support structure extends circumferentially about a central longitudinal axis of the support structure, and wherein the graft assembly further comprises a fitting configured to compress the flange radially inward toward the central longitudinal axis of the support structure. 19. The graft assembly of claim 17, the graft assembly further comprising a fitting slidably positioned over the support structure, the fitting configured to engage the flange of the support structure and capture the graft assembly to the outflow cannula, the fitting configured to attach to the outflow cannula by sliding linearly over the outlet portion. 20. The graft assembly of claim 17, further comprising a fitting configured to mesh with a threaded portion on an outer surface about the pump outlet, the fitting configured to compress the flange of the support structure such that the flange forms a hermetic seal around the pump outlet.
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