CATHETER PUMP ARRANGEMENT AND FLEXIBLE SHAFT ARRANGEMENT HAVING A CORE

Abstract

A flexible shaft arrangement is described herein having a flexible hollow shaft (1, 2) which has an end at the drive side and an end at the output side, wherein the hollow shaft is reinforced sectionally between these ends by a core (3, 4) extending in its interior. Stiffer and more flexible sections can hereby be selectively positioned within the shaft arrangement.

Claims

1-16. (canceled)

17. A heart catheter pump arrangement comprising: a blood pump and a flexible drive shaft arrangement, wherein the blood pump comprises an axial pump and a rotor, and the flexible drive shaft arrangement comprises: a drive shaft having a proximal end and a distal end, the drive shaft formed with a hollow lumen, wherein the drive shaft comprises: a first portion having a first bending stiffness, and a second portion having a second bending stiffness that is different from the first bending stiffness.

18. The heart catheter pump arrangement of claim 17, wherein the proximal end of the drive shaft is connected to a motor and the distal end of the drive shaft is connected to the blood pump.

19. The heart catheter pump arrangement of claim 18, wherein the first portion of the drive shaft is in proximity to the proximal end of the drive shaft and the second portion of the drive shaft is distal of the first portion of the drive shaft, and wherein the first bending stiffness of the first portion is greater than the second bending stiffness of the second portion.

20. The heart catheter pump arrangement of claim 17, wherein the rotor is configured to be driven by the flexible drive shaft arrangement at speeds between 10,000 and 20,000 revolutions per minute.

21. The heart catheter pump arrangement of claim 17, wherein the first bending stiffness of the first portion is greater than the second bending stiffness of the second portion.

22. The heart catheter pump arrangement of claim 17, further comprising a first core disposed within the hollow lumen along the first portion of the drive shaft.

23. The heart catheter pump arrangement of claim 22, wherein the first core has a first end, a first end region, a second end, a second end region, and an outer diameter, wherein, in the first end region, the outer diameter continuously decreases toward the first end, and, in the second end region, the outer diameter continuously decreases toward the second end.

24. The heart catheter pump arrangement of claim 22, wherein the first core reinforces the first portion of the drive shaft such that the first portion has the first bending stiffness.

25. The heart catheter pump arrangement of claim 22, wherein the hollow lumen does not include a core along the second portion.

26. The heart catheter pump arrangement of claim 22, wherein the first core is configured to rotate with the drive shaft.

27. The heart catheter pump arrangement of claim 22, wherein the first core is fastened within the hollow lumen.

28. The heart catheter pump arrangement of claim 27, wherein the first core is welded or soldered to an interior of the hollow lumen.

29. The heart catheter pump arrangement of claim 22, wherein the first core comprises a stranded body.

30. The heart catheter pump arrangement of claim 29, wherein the stranded body comprises a plurality of strand elements.

31. The heart catheter pump arrangement of claim 30, wherein the strand elements are formed by wires.

32. The heart catheter pump arrangement of claim 22, wherein the first core comprises a solid body.

33. The heart catheter pump arrangement of claim 32, wherein the solid body comprises a metal body or a plastic body.

34. The heart catheter pump arrangement of claim 17, wherein the drive shaft comprises a first helical spring and a second helical spring, wherein the first helical spring is wound in a direction opposite to the second helical spring and the first helical spring is coaxial with the second helical spring.

35. The heart catheter pump arrangement of claim 17, wherein: the drive shaft comprises a third portion having a third bending stiffness, the second portion is disposed between the first portion and the third portion, and the first bending stiffness and the third bending stiffness are each greater than the second bending stiffness such that, for a given bending strain, the first portion and the third portion of the drive shaft have a greater bending radius than the second portion of the drive shaft.

36. The heart catheter pump arrangement of claim 35, further comprising a first core disposed within the hollow lumen along the first portion of the drive shaft and a second core disposed within the hollow lumen along the third portion of the drive shaft, wherein, along the second portion of the drive shaft, the hollow lumen does not include a core.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0036] The invention will be shown and subsequently described in the following with reference to an embodiment in a drawing.

[0037] There are shown

[0038] FIG. 1 a shaft arrangement in accordance with the invention in a three-dimensional representation having a plurality of sections reinforced by a core;

[0039] FIG. 2 a cross-section of the shaft arrangement of FIG. 1 along line A-A indicated in FIG. 1;

[0040] FIG. 3 a further embodiment of the shaft arrangement in a schematic representation;

[0041] FIG. 4 an embodiment of the shaft arrangement in accordance with the invention in bent form; and

[0042] FIG. 5 the use of the shaft arrangement in accordance with the invention in a heart pump.

DETAILED DESCRIPTION OF THE INVENTION

[0043] FIG. 1 shows, in a three-dimensional view, a hollow shaft which comprises two helical screws 1, 2 which are wound in opposite senses and of which the first is shown as light and the second as dark. The winding in opposite senses of the two helical springs has the effect that one of the springs is compressed and the other is stretched in each direction of rotation. There is thus no deformation overall in the axial direction in dependence on the direction of rotation which is to be transferred.

[0044] The density of the windings of the individual springs and the thickness of the spring wire determine, on the one hand, the flexibility or stiffness respectively of the hollow shaft and, on the other hand, the torque which can be transferred.

[0045] Two core sections 3, 4 are furthermore shown in FIG. 1 which each stiffen the shaft arrangement in the axial sections 5, 6. The hollow shaft remains free in the axial section lying therebetween and is correspondingly more flexible there.

[0046] The core sections 3, 4 can be made as solid bodies, for example as plastic bodies or metal bodies, which have a high spring elasticity and break resistance as well as a high resistance to fatigue.

[0047] The core sections can, however, also be stranded cores which then comprise a plurality of strand elements, for example wires. This embodiment is shown in more detail in FIG. 2 where a section shows the radial arrangement of the two helical springs 1, 2 and of the core 3. It is also shown there that the core 3 comprises a plurality of strand elements 8, 9, whereby it becomes very flexibly and permanently deformable.

[0048] The two helical springs 1, 2 are dimensioned and arranged such that they are assembled radially into one another and coaxially to one another in a press fit so that a distribution of the torque to be transferred takes place between them. In addition, bending loads are also taken up together by both helical springs. The corresponding loads are likewise taken up in the sections in which a core is located within the hollow space of the helical springs 1, 2 by said core since it fits tightly in the hollow space.

[0049] It is shown with reference to FIG. 3 that the core sections each have an end converging to a taper, whereby the end region 10, 11 of the core 3 becomes more and more flexible toward the end. The stiffness is thereby not reduced abruptly to the degree of stiffness of the hollow shaft toward the end of each core section in the total observation of the shaft arrangement, but a constant transition rather takes place which results in a continuous distribution on a bending strain of the shaft arrangement to reduce the kinking strains and to reduce the risk of a tearing of the shaft arrangement.

[0050] The result is, with a given bending strain, that the bending radius is considerably increased in those sections 5, 6 in which the hollow shaft is reinforced by a core or by a core section. A substantially smaller bending radius is achieved in those sections in which no core is present. The above-described design of the end region of the core sections is suitable to avoid kinks between these regions.

[0051] In FIG. 4, a bent shaft arrangement in accordance with the invention is shown by way of example, with two cores 3, 4 being shown in sections 5, 6 which extend almost straight or have a large bending radius. The hollow shaft arrangement is particularly bent in the section 7, as it is in section 12.

[0052] The general transition of the stiffness by a corresponding design of the ends of the cores 3, 4 in the regions 10, 13 has the effect that the risk of kinking is reduced.

[0053] In one aspect, the shaft has an unchanging or constant outer diameter from the proximal end of the shaft to the distal end of the shaft.

[0054] Spacers are shown by way of example between the cores 3, 4 in FIG. 4, just as between the core 3 and the end of the shaft arrangement at the drive side. The spacers are labeled by 14, 15 and can be made as more or less stiff, thin cores which have a substantially smaller diameter than the cores 3, 4, and equally a substantially smaller stiffness. The spacers 14, 15 can, however, simply be made only as a thread with negligible stiffness, with it being expedient in this case to fasten the spacers suitably at both ends of the hollow shaft arrangement to be able to keep the core sections 3, 4 tensioned as on a chain and to be able to keep them stable at preset spacings.

[0055] This embodiment has the advantage that, depending on the demands on the distribution of different stiffnesses along the hollow shaft arrangement, a series of cores/core sections can be drawn into the existing hollow shaft with spacers, with the length of the individual spacers being individually adaptable in accordance with the purpose of the shaft arrangement.

[0056] FIG. 5 schematically shows an application for the shaft arrangement in accordance with the invention, with the shaft arrangement there only being shown schematically and being labeled by 16. The shaft arrangement 16 is connected to a motor 17 at the drive side and extends in a hollow catheter 18 which can be introduced into a blood vessel 19 of a body, for example a human body, and can be introduced into a ventricle 20 via the path of this blood vessel.

[0057] A heart pump 21 is located at the end of the hollow catheter 18 and is made as an axial pump and has a rotor in its interior which can be driven by means of the shaft arrangement 16 at high speeds, for example between 10,000 and 20,000 revolutions per minute.

[0058] The advantages of the shaft arrangement in accordance with the invention are shown in that, on the one hand, the shaft arrangement can be easily inserted through the blood vessel 19 due to suitable stiff regions, but that in the distal region, viewed from the introduction point, that is in the region of the aortic arch toward the ventricle, a high flexibility of the shaft arrangement is given so that the heart pump 21 can be introduced into the ventricle there without the stiffness of the shaft arrangement or of the hollow catheter being able to result in injuries to the ventricle walls or to the aorta in the region of the aortic arch. A knocking of the shaft and acoustic resonance are reliably avoided by the suitable distribution of the core(s) along the shaft arrangement.