Intravascular ventricular assist device
First Claim
1. A rotor for a blood circulating pump, the rotor comprising a body having an upstream end, a downstream end and a rotational axis, the rotor body including a plurality of lobes, each of said lobes having a pressure surface facing in a forward circumferential direction and a suction surface facing in a reverse circumferential direction opposite to the forward circumferential direction, the pressure and suction surfaces of each lobe, as viewed in a sectional view looking in the direction of the axis, curving away from one another in opposite circumferential directions so that the circumferential extent of each lobe increases in a radially outward direction away from the axis, each of said lobes having a support surface facing generally radially outwardly, the rotor being adapted to pump blood downstream upon rotation in the forward circumferential direction, each said support surface including a hydrodynamic bearing region sloping radially outwardly away from the axis in the reverse circumferential direction.
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Accused Products
Abstract
One aspect of an intravascular ventricular assist device is an implantable blood pump where the pump includes a housing defining a bore having an axis, one or more rotors disposed within the bore, each rotor including a plurality of magnetic poles, and one or more stators surrounding the bore for providing a magnetic field within the bore to induce rotation of each of the one or more rotors. Another aspect of the invention includes methods of providing cardiac assistance to a mammalian subject as, for example, a human. Further aspects of the invention include rotor bodies having helical channels formed longitudinally along the length of the body of the rotor where each helical channel is formed between peripheral support surface areas facing radially outwardly and extending generally in circumferential directions around the rotational axis of the rotor.
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Citations
21 Claims
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1. A rotor for a blood circulating pump, the rotor comprising a body having an upstream end, a downstream end and a rotational axis, the rotor body including a plurality of lobes, each of said lobes having a pressure surface facing in a forward circumferential direction and a suction surface facing in a reverse circumferential direction opposite to the forward circumferential direction, the pressure and suction surfaces of each lobe, as viewed in a sectional view looking in the direction of the axis, curving away from one another in opposite circumferential directions so that the circumferential extent of each lobe increases in a radially outward direction away from the axis, each of said lobes having a support surface facing generally radially outwardly, the rotor being adapted to pump blood downstream upon rotation in the forward circumferential direction, each said support surface including a hydrodynamic bearing region sloping radially outwardly away from the axis in the reverse circumferential direction.
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2. A rotor for a blood circulating pump, the rotor comprising a body having an upstream end, a downstream end and a rotational axis, the rotor body including a helix region and a support region downstream from the helix region, the helix region having a plurality of vanes defining a plurality of generally helical channels, the support region having a plurality of lobes each defining one or more support surfaces facing substantially radially outwardly and extending generally in circumferential directions around the axis, each said lobe being continuous with one of said vanes, the lobes of the support region defining a plurality of passages, each said helical channel being continuous with only one of said passages, so that the one or more passages and said helical channels cooperatively define a plurality of continuous flow paths extending between the upstream and downstream ends, the channels having greater aggregate cross-sectional area than the passages, the rotor being adapted to impel blood downstream upon rotation of the rotor about the rotational axis.
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3. A rotor for a blood circulating pump, the rotor comprising a body having an upstream end, a downstream end and a rotational axis, the rotor body including a helix region and a support region downstream from the helix region, the helix region of the body having a plurality of vanes defining a plurality of generally helical channels, the support region having a plurality of lobes each defining one or more support surfaces facing substantially radially outwardly and extending generally in circumferential directions around the axis, each said lobe being continuous with one of said vanes, the lobes of the support region defining one or more passages, each said channel being continuous with only one of said passages, so that the one or more passages and the channels cooperatively define a plurality of continuous flow paths extending between the upstream and downstream ends, the support region having greater solidity than the helix region, the rotor being adapted to impel blood downstream upon rotation of the rotor about the rotational axis.
- 4. A rotor for a blood circulating pump, the rotor comprising a body having an upstream end, a downstream end and a rotational axis, the rotor body including a helix region and a support region axially offset from the helix region, the helix region including a plurality of vanes defining a plurality of generally helical channels, the vanes having peripheral surfaces facing outwardly away from said axis, the support region including a plurality of lobes projecting outwardly away from said axis and passages between the lobes, each lobe being continuous with one of said vanes, each said helical channel being continuous with only one of said passages, the lobes defining one or more support surfaces facing outwardly away from the axis, the support surfaces having an aggregate extent in a circumferential direction around the axis greater than an aggregate extent of said peripheral surfaces in the circumferential direction, the walls of said helical channels having a pitch in a forward circumferential direction toward the upstream end of said body and the support surfaces including hydrodynamic bearing regions sloping outwardly away from the axis in a reverse circumferential direction opposite to the forward circumferential direction, the hydrodynamic bearing regions of the each lobe including a first hydrodynamic bearing region and a second hydrodynamic bearing region disposed downstream of the first hydrodynamic bearing region.
Specification
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- Resources
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Current AssigneeHeartware,Inc. (Medtronic Plc)
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Original AssigneeHeartware,Inc. (Medtronic Plc)
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InventorsLaRose, Jeffrey A., Shambaugh, Charles R. Jr., White, Daniel G., Marquis, Richard A., White, Steven A., Trichi, Kartikeyan
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Primary Examiner(s)Patel, Niketa
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Assistant Examiner(s)FAIRCHILD, MALLIKA DIPAYAN
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Application NumberUS13/196,693Publication NumberTime in Patent Office917 DaysField of Search600 16- 18, 623 31- 33US Class Current600/16CPC Class CodesA61M 2205/0211 CeramicsA61M 2205/0272 Electro-active or magneto-a...A61M 2205/8206 battery-operatedA61M 2210/127 AortaA61M 60/13 by means of a catheter allo...A61M 60/135 inside a blood vessel, e.g....A61M 60/148 in line with a blood vessel...A61M 60/174 discharging the blood to th...A61M 60/237 the blood flow through the ...A61M 60/419 the force acting on the blo...A61M 60/422 the force acting on the blo...A61M 60/538 Regulation using real-time ...A61M 60/806 Vanes or bladesA61M 60/81 Pump housingsA61M 60/824 Hydrodynamic or fluid film ...A61M 60/861 Connections or anchorings f...A61M 60/873 specially adapted for wirel...A61M 60/876 Implantable batteriesA61M 60/878 Electrical connections with...
