DE102016122268B4 - Catheter pump with a pump head for insertion into the aorta - Google Patents

Abstract

Catheter pump (34) with a pump head (10) for insertion into the aorta, the pump head having a rotor (12), the propeller (14) of which from a folded-in insertion position, in which the pump head (10) can be inserted into the aorta, into a unfolded operating position, in which the rotor (12) can be set in rotation, are displaceable, and has a cage (16) surrounding the propellers (14), the cage (16) having a distal and a proximal sleeve (18, 20) as well has filaments (21) running between the sleeves, and wherein the sleeves (18, 20) are moved towards one another during or before the propellers (14) are unfolded so that the areas of the filaments (18, 20) lying between the sleeves (18, 20) 21) expand radially outward to form a space surrounding the unfolded propellers (14), the filaments (21) being designed in such a way that they each have at least one main section (28) engaging a sleeve (18, 20), which moves in the direction of the other H The sleeve (20, 18) splits into two secondary sections (30), characterized in that in each case two secondary sections (30) of main sections (28) engaging adjacent to a sleeve (18, 20) in the direction of the other sleeve (20, 18) unite in a main section (28 ″) which engages the respective other sleeve (20, 18).

Description

The invention relates to a catheter pump with a pump head for insertion into the aorta, in particular into the aorta of a person, with a rotor, the propeller of which from a folded-in insertion position in which the pump head can be inserted into the aorta, into an unfolded operating position in which the rotor can be set in rotation, displaced. Furthermore, a cage is provided which surrounds the propellers and has a distal and a proximal sleeve as well as filaments running between the sleeves. The sleeves are arranged in such a way that they are moved towards each other during or before the propellers are unfolded so that the areas of the filaments located between the sleeves expand radially outward to form a space surrounding the unfolded propellers.

A catheter pump with such a pump head is, for example, from EP 0 768 900 B1 or the EP 2 308 422 B1 known. The propellers are set in rotation by a drive shaft located inside a catheter. The movement of the sleeves towards or away from one another, and thus the expansion or compression of the cage, takes place via an axial displacement of an inner catheter against an outer catheter and an associated axial displacement of the proximal sleeve.

In the known prior art, the filaments between the sleeves are designed as bands or strips that run in the axial direction and have predetermined bending points.

During operation of such catheter pump heads, that is to say in the expanded state of the cage, the filaments regularly come into contact with the vessel wall. It has been shown that the contact points between the filaments and the inner wall of the vessel can lead to unwanted vessel injuries (traumatization of the vessel wall). In addition, it has been found that the filaments of the cages of the known catheter pump heads tend to deflect laterally due to the forces acting on them.

From the US 2016/0022890 A1 a catheter pump with features of the preamble of claim 1 is known. Similar items are from the US 2016/0136343 A1 and the US 2016/0287771 A1 known.

The present invention is based on the object of proposing a catheter pump which remedies the disadvantages mentioned. This object is achieved by a catheter pump with the features of claim 1.

The catheter pump according to the invention is therefore particularly characterized in that at least some or all of the filaments are designed in such a way that they each have at least one main section which engages on a sleeve and which splits into at least two secondary sections in the direction of the other sleeve. Because a main section splits into several secondary sections, greater stability of the, in particular, expanded cage can be achieved. Overall, both lateral and higher forces can act on the cage without it being unintentionally deformed or without individual filaments being inadvertently deflected laterally. The division of the main section into secondary sections can in particular run in a Y-like manner, which results in suitable stability.

Furthermore, it is provided that in each case two secondary sections of main sections which can be attacked adjacent to a sleeve in the direction of the other sleeve are combined in a main section which engages the respective other sleeve. Starting from one sleeve, the main section is consequently divided into two secondary sections towards the other sleeve. In each case two adjacent secondary sections of different main sections then unite again to form a main section which engages the other sleeve. This results in a suitable symmetrical arrangement in which the filaments only provide secondary sections in the central area between the sleeves and only main sections in the areas close to the sleeves. Furthermore, there is a comparatively high stability, since the secondary sections are then designed as struts between adjacent main sections each engaging the other sleeve.

The division of the main sections into the secondary sections also has the advantage that, if necessary, further catheters to be inserted into the aorta can be safely guided past the pump head. These additional catheters can then, for example, come to rest against the Y-like splits on the side facing away from the main section. The additional catheter can be prevented from getting too close to the rotating propellers by placing the Y-shaped splitter accordingly.

It is advantageous if the main section extends over 1/5 to 2/5 of the length and preferably over a range of 1/4 to 1/3 of the respective filament. With a uniform expansion of the individual filaments, it can be achieved that not the main section but the secondary sections come to rest against the vessel wall. Since the main sections split into secondary sections, the pressing force of the cage, or, its filaments, distributed on the inner wall of the vessel over the several secondary sections. Since, overall, more secondary sections are provided than main sections, the pressing forces are better distributed and are thus lower in the secondary sections than in the previously known prior art, which only has main sections. The risk of vascular injury (trauma) is reduced due to the lower pressure against the vascular wall. Overall, an atraumatic effect, that is to say a tissue-sparing effect, can be achieved as a result. It is advantageous if the secondary sections extend at least over the central regions of the filaments, since the central regions of the filaments tend to come into contact with the inner wall of the vessel when the catheter head is in operation. In addition, a suitable choice of the length of the main sections can prevent an additional catheter, which is guided past the pump head, from coming too close to the rotating propellers.

It is also advantageous if the cross-sectional area of the respective main section is larger than the cross-sectional area of a respective associated secondary section. An atraumatic effect can also be achieved in this way.

It has been shown that it is advantageous if the cross-sectional area of the main section essentially corresponds to the sum of the cross-sectional areas of the secondary sections. If, for example, two secondary sections are provided, their cross-sectional area can correspond to the cross-sectional area of the main section. To implement the secondary sections, for example, a main section can be split in the middle into two secondary sections.

The arrangement of the main sections is furthermore advantageously such that the main sections engaging one sleeve lie in an axial extension, in particular centrally between two adjacent main sections engaging the other sleeve. In a side view there is always a main section that engages one sleeve between two main sections that engage another sleeve.

In order to achieve a sufficient and specific expansion of the filaments, it is advantageous if the filaments have a transition section with a reduced cross-sectional area between the main sections and the respective sleeves. This can ensure that when the sleeves are moved towards one another, the filaments assume an intended position.

A nickel-titanium alloy has proven to be particularly advantageous as the material for the cage. Such alloys have the necessary super-elastic properties and offer the required fatigue strength to ensure a safe cage. The cage can, however, also be made from a plastic with corresponding properties.

The pump head is preferably arranged in the area of a free end of a catheter. The catheter preferably comprises a drive shaft, which is rotatably mounted in the catheter, for driving the rotor and a drive for driving the drive shaft. The drive is advantageously arranged on the side of the drive shaft facing away from the pump head.

Further details of advantageous embodiments of the invention can be found in the following description, on the basis of which an exemplary embodiment of the invention is described and explained in more detail.

• 1 den Pumpenkopf einer erfindungsgemäßen Katheterpumpe in Betriebslage;
• 2 einen Längsschnitt durch den Käfig des Pumpenkopfs nach 1 in der Betriebslage; und
• 3 eine erfindungsgemäße Katheterpumpe mit einem Pumpenkopf gemäß 1.

Show it:

• 1 the pump head of a catheter pump according to the invention in the operating position;
• 2 a longitudinal section through the cage of the pump head 1 in the operating position; and
• 3 a catheter pump according to the invention with a pump head according to FIG 1 .

The pump head shown in the figures 10 includes a rotor 12th with two propellers 14th . Furthermore, one is the rotor 12th surrounding cage 16 provided, which has a distal sleeve 18th and a proximal sleeve 20th and filaments running between the sleeves 21 includes.

The rotor 12th is about a shaft section 22nd with the distal sleeve 18th coupled in motion in the axial direction. On that of the case 18th the opposite side is the rotor 12th via a drive shaft 24 that are inside an outer catheter 26th is arranged rotatably and displaceably in the axial direction, coupled in motion.

The Indian 1 shown pump head 10 is in the operating position in which the two propellers 14th are unfolded.

For inserting the pump head 10 In the aorta, the two sleeves 18, 20 are in a spaced-apart position in which the propellers 14th are folded in and the filaments 21 close to the rotor 12th or on the shaft section 22nd and the drive shaft 24 issue.

To expand the cage 16 becomes that of the rotor 20th adjacent section of the drive shaft 24 into the outer catheter 26th retracted, making the sleeve 18th towards the sleeve 20th is moved. In this first step, the filaments expand 21 of the cage 16 radially outwards. With further relocation of the sleeve 18th towards the sleeve 20th fold the propellers 14th of the rotor 12th in the operating position, as in 1 shown.

Like that 1 and 2 can be clearly seen are the filaments 21 designed in such a way that they each have one on a sleeve 18th , 20th attacking main section 28 have, which extends in the direction of the other sleeve 18th , 20th in two sub-sections 30th Splits in a Y-like manner. The two subsidiary sections 30th enclose an angle α of approx. 15 ° to 35 °, in particular in the range of 30 °, in the operating position. The main sections 28 extend over a length l. In the embodiment shown, the length l is approximately 1/3 of the total length of the respective filament 21 . The minor sections 30th extend over the central area of the filaments 21 and have the length g, which is also about 1/3 of the total length of the filaments 21 occupies. By choosing the length l and g, a certain opening behavior or a certain cage diameter can be achieved. Different values then result in each case for the angle α.

The cross-sectional area of a major section 28 is about twice as large as the cross-sectional area of the respective main section 28 subsequent subsidiary sections 30th .

Like in particular from 2 becomes clear, two sub-sections come together 30th , 30 ' from neighboring, on a sleeve 18th , 20th attacking main sections 30th , 30 ' towards the other sleeve 20th , 18th in a common main section 28 ″. The minor sections 30th , 30 ' thereby form overall struts between adjacent main sections 28 , 28 ' .

The main sections 28 that come in a sleeve 20th , 18th attack are offset in the axial direction to the main sections 28 arranged on the other sleeve 18th , 20th attack. The main sections 28 on a sleeve 20th , 18th are preferably centered between the main sections 28 that on the other sleeve 18th , 20th attack. This is done in 2 indicated by the line m, which is the axis of the main section 28 ' that on the sleeve 18th attacks, illustrated. The line m lies centrally between the main sections 28 ″, which are on the sleeve 20th attack.

Through the arrangement and design of the filaments 21 like them in the 1 until 3 are shown, on the one hand, a more uniform distribution of the forces acting on the inner wall of the vessel during operation of the catheter pump 34 achieved. Overall, this reduces the stress on the vessel wall. On the other hand, the cage learns 16 a very high stability with sufficient flow properties for the blood to be pumped.

An additional catheter can also be used 42 , the Indian 1 is shown past the catheter 26th and past the pump head 10 can be passed through the vessel without this additional catheter 42 the function of the pump head 10 and the rotating propellers 14th impaired. The additional catheter 42 will be between the secondary sections 30th guided and can due to the adjoining sections 30th subsequent main sections 28 not in the rotation range of the propeller 14th reach.

From the 1 and 2 it is also clear that the filaments 21 between the main sections 28 and the pods 18th , 20th each a transition section 32 have, which has a reduced cross-sectional area with respect to the main portion. This enables favorable elastic properties of the filaments 21 in the area of the sleeves 18th and 20th will be realized.

In the 3 is a catheter pump according to the invention 34 shown having a pump head according to the invention 10 having in the region of a free end of the catheter 26th is provided. In the catheter 26th is the drive shaft 24 provided by means of which the rotor 12th can be set in rotation. On that of the pump head 10 the opposite end sees the catheter 26th a drive section 38 before that in a drive unit 40 can be inserted, by means of which ultimately the drive shaft 24 , us with it the rotor 12th , can be set in rotation.

Claims (12)

Catheter pump (34) with a pump head (10) for insertion into the aorta, the pump head having a rotor (12), the propeller (14) of which from a folded-in insertion position, in which the pump head (10) can be inserted into the aorta, into a unfolded operating position, in which the rotor (12) can be set in rotation, are displaceable, and has a cage (16) surrounding the propellers (14), the cage (16) having a distal and a proximal sleeve (18, 20) as well has filaments (21) running between the sleeves, and wherein the sleeves (18, 20) are moved towards one another during or before the propellers (14) are unfolded so that the areas of the filaments (18, 20) lying between the sleeves (18, 20) 21) expand radially outward to form a space surrounding the unfolded propellers (14), the filaments (21) being designed in such a way that they each have at least one main section (28) engaging a sleeve (18, 20), which moves in the direction of the other H Ulse (20, 18) splits into two secondary sections (30), thereby characterized in that in each case two secondary sections (30) of main sections (28) engaging adjacent to a sleeve (18, 20) in the direction of the other sleeve (20, 18) unite in a main section (28 ″) which is connected to the respective other sleeve (20, 18) engages. Catheter pump (10) Claim 1 , characterized in that the respective main section (28) extends over a range from 1/5 to 2/5 and preferably over a range from 1/4 to 1/3 of the length of the respective filament (21). Catheter pump (10) Claim 1 or 2 , characterized in that the open cage diameter and the shape of the cage (16) are defined by the selection of the length (1) of the respective main section (28). Catheter pump (10) Claim 1 or 2 , characterized in that the length (1) of the respective main section (28) is selected such that another (42) can be guided past the pump head (10) without the rotating propellers (14) coming into contact with the other . Catheter pump (10) according to one of the preceding claims, characterized in that the secondary sections (30) extend over at least the central regions (g) of the filaments (21). Catheter pump (10) according to one of the preceding claims, characterized in that the cross-sectional area of a main section (28) is larger than the cross-sectional area of an associated secondary section (30). Catheter pump (10) Claim 6 , characterized in that the cross-sectional area of the main section (28) at least largely corresponds to the sum of the cross-sectional areas of the secondary sections (30). Catheter pump (10) according to one of the preceding claims, characterized in that the main sections (28) engaging one sleeve (18, 20) lie in an axial extension between two adjacent main sections (28) engaging the other sleeve (20, 18). Catheter pump (10) according to one of the preceding claims, characterized in that the filaments (21) between the main sections (28) and the respective sleeves (18, 20) have a transition section (32) with a reduced cross-sectional area. Catheter pump (10) according to one of the preceding claims, characterized in that the cage (16) consists of a resilient material. Catheter pump (10) Claims 10 , characterized in that the resilient material is a nickel-titanium alloy or made of a plastic. Catheter pump (34) according to one of the preceding claims, with a drive shaft (24) provided in the catheter (26) for driving the rotor (12) and with a drive (40) for driving the drive shaft (24).

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