The invention relates to a medical arrangement for introducing an object, such as an implant into an anatomical target position, such as a cardiac implant (like an annuloplasty medical device) into an annulus of a heart valve, such as a mitral valve or tricuspid valve.
In some conditions of degenerated heart function, the leaflets do not present a solid surface, as in a degenerative valve disease. The leaflet may also be ruptured, most commonly at an edge of a leaflet, resulting in an incomplete coaptation. Hence, cardiac devices and methods are developed for repairing of one or more leaflets of a heart valve, or other related anatomical structures, such as the chordae attached to the ventricular side of leaflets.
The implant is typically delivered via a catheter and has thus typically a delivery state, where the implant has an elongated form. In said delivery state the implant can be transferred advantageously through a catheter having diameter 7-10 mm, for example. The implant comprises typically a shape memory material having a first shape, such as the elongated form of the delivery state in a first temperature, and the second shape, such as the loop-shaped form in a second temperature. The second temperature corresponds advantageously essentially to the body temperature, whereupon the implant takes the second shape, corresponding to the loop-shaped form, when introduced for example with the blood flow in the atrium.
In addition, some problems arise due to a catheter system having both inner and outer catheters, usually steerable catheters, sometimes numerous inner catheters, where the inner catheter(s) locating inside the outer catheter limit(s) space from the implant.
It is found that the prior art cardiac implants, such as depicted above, work very well, but there are still some disadvantages relating to the introduction devices, such as catheter type devices, to deliver the implant into the anatomical target position, such as into the annulus of the heart valve. The catheter based systems are based for delivering a relatively thick main catheter having a first curve portion into a first portion of the anatomical target position, such as to an atrium, then a second catheter having a second curve portion into a second portion of the anatomical target position, such as next to annulus or leaflets of the heart valve, and then a third catheter having a third curve portion into a third portion of the anatomical target position, such as around the annulus of the heart valve. In some systems there might be even further catheters with further curve portions to be delivered before the implant can be delivered and introduced into its position. The third or further catheter if used, is called as a delivery catheter. The implant is then delivered to its position inside the feeding catheters, which is delivered to its position inside the other catheters.
There are some drawbacks related to the prior art catheter based systems, such as at least the main catheter must be thick (7-10 mm or even more) so that it can carry the further catheters inside. In addition, also the delivery catheter must be relatively thick so that the implant can be delivered inside the delivery catheter. When the catheters are relatively thick, it is very hard to insert the catheters into the anatomical target position. For example, a sub-annular space below the annulus, so between the chordae and wall or septum, is very narrow, whereupon the best channel for the thick catheters is very difficult to find and deliver, in particular when the maneuverability and steerability of the catheters is poor. Furthermore, the surface of the inner wall is rough, having additionally numerous attachment points of chordae, which easily causes stuck of the catheters. Additional challenges arise when the catheters, especially also the delivery catheter, have memory properties or predetermined shapes, which might activate too early and thereby raising possibility to stuck the catheter into the wall or other structures of the anatomical target position, such as the heart. Thus, the time limit to insert the catheters, in particularly the delivery catheter, having memory properties, is very limited so that the catheters can be inserted into their right and accurate position before the memory property will be activated by the temperature of the anatomical target position, such as the heart.
It is an object of the invention to alleviate and eliminate the problems relating to the known prior art. Especially the object of the invention is to provide a medical arrangement for introducing an implant into an anatomical target position in an easy, fast, safe and accurate manner with a high degree of control. In addition, the object of the invention is to minimize the sizes of the catheters used and at the same time minimize stuck of the catheters and thereby minimize stress introduced for the anatomical target position. The object of the invention can be achieved by the features of independent claim.
The invention relates to a medical arrangement for introducing an implant into an anatomical target position, such as a cardiac implant into an annulus of a heart valve, according to claim 1.
A medical arrangement according to the invention is configured to introduce an object, such as an implant, and in particularly such as a cardiac implant, or an annuloplasty medical device, from a distal end of the arrangement into an anatomical target position, such as into an annulus of a heart valve. The heart valve may be a mitral valve or tricuspid valve, for example, not limiting to those only. It is to be understood that the object can be also some other object, such as medicine, for example.
According to an example the object is the implant, which comprises in a use a loop shaped support portion, having either one or more loops or coils so that at least one first loop-shaped structure can be configured to abut a first side of the heart valve and at least one second loop-shaped structure to abut a second, opposite, side of the valve to thereby trap a portion of the valve tissue between the second and the first support structures. It is also possible that there is only the one first loop-shaped structure, which is configured to abut a first side of the heart valve, and not the second support structures, or vice versa. The implant is advantageously adapted to support a mitral valve upon being fully delivered. According to an embodiment the medical arrangement comprises a first introducer, a guiding catheter (delivery catheter), and a guide wire. The first introducer is advantageously an outer steerable catheter, which is delivered for example to the atrium or ventricle, but not to the anatomical target end position as such, where the implant is to be introduced. The guiding catheter is arranged to be operable between the first introducer and the guide wire. In addition, at least a distal portion of the guiding catheter is configured to be introduced from the distal end portion of the first introducer after the guide wire is at least partially introduced into or towards said anatomical target position.
According to an embodiment the guide wire is configured to be introduced into or towards said anatomical target position via the first introducer but before the implant, as well as before the guiding catheter (meaning that the guide wire is delivered beforehand so that it can guide especially the delivery of the guiding catheter). Also, the guiding catheter is configured to be introduced into or towards said anatomical target position before the implant. When the guide wire is delivered into the right position, the guiding catheter is then delivered along the guide wire and guided by the guide wire (and inside the first introducer) into the anatomical target position.
The implant is configured to be delivered and instructed inside the guiding catheter (and inside the first introducer) into or towards said anatomical target position after at least the distal portion of the guiding catheter is introduced from the distal end portion of the first introducer into or towards said anatomical target position. Advantageously the implant is configured to be delivered and instructed inside the guiding catheter after the distal portion of the guiding catheter has reached the anatomical target position, even if the delivering of both the guiding catheter and the implant can be made sequentially and periodically. However, and advantageously, the implant is delivered only after the guide wire is retracted away from said anatomical target position, but so that the guiding catheter into is still left into said anatomical target position). By this more space can be left for the implant when delivered inside the guiding catheter. In addition, when the guide wire is used for guiding the guiding catheter, a more flexible and thinner guiding catheter can be used, because the guiding catheter does not need to be any controllable or steerable catheter, for example. It is enough that said guiding catheter can follow the guide wire towards or into the anatomical target position, and protect the tissue and prevent possible jamming of the implant to the tissue during introduction of the implant, and if the object to be delivered is e.g. liquid medicament, the guiding catheter enables the delivering of the liquid medicament to the target position.
The guide wire has advantageously an activated shape and an inactivated shape, wherein in said inactivated shape the guide wire can be delivered in a straightened configuration through the first introducer and in said activated shape the guide wire takes at least a first curved shape within or near the anatomical target position, such as in the atrium or ventricle or proximate the mitral valve. The guide wire advantageously has a preformed shape so to take the activated shape when introduced to the anatomical target position and introduced from the distal end of the first introducer. According to an embodiment the guide wire is at least partially formed from a shape memory material and thereby operable to assume said activated shape when meet the temperature of the anatomical target position. The activated shape can be achieved also via another techniques known by the skilled person. When the guide wire is activated to said at least first curved shape, it is delivered to the anatomical target position, after which the guiding catheter is delivered along and guided by the guide wire to the anatomical target position, as is described in this document.
In addition, the distal end of the guide wire may comprise a curvature tip portion, such as a J-shape, in order to allowing smooth delivery of the distal end of the guide wire and to prevent the distal end of the guide wire to get tangled in to tissue. The curvature tip portion may have a preformed shape or being at least partially formed from a shape memory material and thereby taking the shape of the curvature tip portion when introduced into the anatomical target position.
According to an embodiment the guiding catheter is configured to take the shape of the at least first curved shape of the guide wire when it is delivered along the guide wire (which already has taken the first curved shape) and retain said first curved shape after the guide wire is retracted away from said anatomical target position before delivering the implant. The implant is then configured to follow said guiding catheter and said first curved shape into said anatomical target position during introduction and delivering.
The implant may comprise a hollow or solid tubular structure. The implant can be delivered into said anatomical target position so that it travels inside the guiding catheter (advantageously after the guide wire is retracted). This offers clear advantages over the known prior art solutions namely because the guide wire is very thin compared to the catheters, it is remarkable easy, fast, safe and accurate to insert the guiding catheter, even if it is flexible and soft, via very small and narrow channels of the anatomical target position to the correct place. When the guiding catheter is delivered to the correct position and the guide wire is removed, the implant can be easily delivered along and inside the guiding catheter to the correct end position.
The implant can be made from metal, but also fabric, polyurethane or polyester and there is no need for the implant to have any memory property. The implant can be delivered to the position for example by a pusher coupled to the proximal end of the implant, whereupon the implant can be pushed to the position by the pusher. In the case of non-rigid implant, for example if the implant is made of textile or the like, the pusher can be coupled to the distal end of the implant and thereby to draw the implant to the position.
According to an embodiment the implant may have at least a first curved shape having a preformed shape and capable of being delivered in a straightened configuration through the first introducer, whereupon the implant is activated to at least a first curved shape within or near the anatomical target position, such as in the atrium or ventricle proximate the mitral valve of the heart. The implant may comprise e.g. a shape memory property and be biased to said curved shape. However, it is to be noted that according to the invention, in particular the implants without any memory property can be delivered and guided by the guide wire, which is delivered to the position first.
It is to be noted that the implant is configured to follow said guiding catheter and said first curved shape of the guiding catheter into said anatomical target position. When the implant has been introduced into said anatomical target position, also the guiding catheter can be retracted and the implant essentially maintains the shape taken when introduced into said anatomical target position, corresponding to the shape of the guide wire and the guiding catheter in the anatomical target position. It is to be noted that the implant can be attached, such as sutured, into its position for example by keeping the implant in its position during the attaching by the guiding catheter in the case, where the guiding catheter is only partially retracted to uncover. The implant can also be as a self-attaching version having e.g. teeth, whereupon when the catheter over the implant is retracted the teeth can dig into the tissue and thereby attach the implant into its position.
In addition, when the implant is inside the guiding catheter and delivered to the anatomical target position, the position of the implant can still be adjusted by manipulating the guiding catheter, such as by dragging the guiding catheter and thereby adjusting the position or orientation of the implant (a whole packet of the guiding catheter and the implant), which is very advantageous in many situations. In addition, if something goes wrong, the implant can still be retracted away by the guiding catheter.
According to an embodiment the arrangement may additionally comprise a second introducer, such as a catheter and in particular an inner steerable catheter. The second introducer is arranged to be operable between the first introducer and the guide wire. The second introducer is configured to be introduced from the distal end portion of the first introducer. According to an embodiment, the second introducer is an optional introducer and can be used for example to bypass the leaflets of the heart or other anatomical portion in or near the target position, as well as to achieve an additional turn to a specific direction by turning the distal end of the second introducer (namely turnability of the introducers are limited). However, according to an embodiment at least a distal portion of the second introducer is configured to be introduced from the distal end portion of the first introducer before the guide wire, and thereby guide or instruct the guide wire to bypass for example a certain anatomical portion, such as leaflets.
If the second introducer is used, the implant can be delivered inside the second introducer (and inside the first introducer), and again inside the guiding catheter into or towards the anatomical target position after at least the distal portion of the second introducer is introduced from the distal end portion of the first introducer.
However, the second introducer is advantageously configured to be retracted after said guide wire and the guiding catheter are introduced into said anatomical target position and before said implant is introduced into said anatomical target position. This is not mandatory but by this more space can be provided for the implant to the guiding catheter, and in particular when the guiding catheter is flexible and expandable so that the diameter of guiding catheter can expand when the implant is delivered.
When the implant is delivered into the anatomical target position, the guiding catheter is configured to be retracted away so that said implant essentially maintains the shape taken when introduced into said anatomical target position. The guiding catheter is configured to be retracted either at once or sequentially, thereby uncovering the implant, which can be then secured, such as sutured or stapled for example, to the anatomical target position.
Still in addition, the arrangement may also comprise a cooling arrangement for cooling the guide wire for example during retracting the guide wire, but also in other phases. When the guide wire is cooled down it can be easily reshaped and for example retracted out essentially easily transformable state. The cooling arrangement may be arranged so that there is an inlet for a cooling agent, such as cool water, in the proximal end of the first introducer, second introducer and/or guiding catheter, whereupon the cooling agent can flow between the walls of the first introducer, second introducer and/or guiding catheter from the proximal ends towards the distal ends, for example. According to an embodiment the distal ends may have openings so that the cooling agent can flow out.
The present invention offers advantages over the known prior art, such as an easy, safe, precise and time saving manner to reliable delivering the implant to the anatomical target position such as to the annulus of the valve. Still, the guide wire is very convenient to deliver to the target position, namely it is very thin compared to the catheters and thus it does not tangle to the tissue. When the guide wire is delivered into the target position, the subsequent catheters, even flexible catheters, can be delivered easily along and guided by the guide wire. In addition, the guiding catheter can be used as a rescue device during securing the object, like the implant, namely if something goes wrong in securing, any device used for pulling out the implant can be delivered to the proximal end of the implant along and guided by the guiding catheter, because the guiding catheter can be kept in the target position or at least to extend over the proximal end portion of the implant as long as the implant is secured.
In addition, the present invention provides for a compact arrangement for delivering the implant. The compact medical device allows minimally invasive procedure. Furthermore, when using the compact catheter-operated medical device, risks for having any medical drawbacks or symptoms are much lower than e.g. in the traditional open-heart operation. Also, the patient recovery process is much faster.
The exemplary embodiments presented in this text are not to be interpreted to pose limitations to the applicability of the appended claims. The verb “to comprise” is used in this text as an open limitation that does not exclude the existence of also un-recited features. The features recited in depending claims are mutually freely combinable unless otherwise explicitly stated.
The novel features which are considered as characteristic of the invention are set forth in particular in the appended claims. The invention itself, however, both as to its construction and its method of operation, together with additional objects and advantages thereof, will be best understood from the following description of specific example embodiments when read in connection with the accompanying drawings.
Next the invention will be described in greater detail with reference to exemplary embodiments in accordance with the accompanying drawings, in which:
When the second introducer has bypassed the leaflets 22, 24, the guide wire 103 can be delivered into or towards the position 20. It is to be noted that the guide wire 103 is delivered into the position before the implant 110 and guiding catheter 104.
The guide wire 103 has advantageously an activated shape and an inactivated shape, wherein in said inactivated shape the guide wire 103 can be delivered in a straightened configuration 1031 through the first introducer 101, as can be seen in
The guiding catheter 104 is delivered along the guide wire 103 into or towards said anatomical target position 20 after the guide wire 103 is at least partially introduced from the distal end portion 101A of the first introducer 101, as can be seen in
When the guide wire 103 and the guiding catheter 104 are delivered into the position, the second introducer 102 is retracted and it is retracted advantageously before delivering the implant 110 into the anatomical target position 20, as is the case in
In addition, after the guiding catheter 104 has been delivered into the anatomical target position, the guide wire 103 can be retracted, as can be seen in
The guiding catheter 104 can be retracted after the implant 110 has been introduced into the anatomical target position 20. After removing the guiding catheter 104, the implant can be secured to the tissue by securing members 114, as can be seen in
It is to be noted that the guiding catheter 104 can be retracted at once, as is the case in
In addition,
It is to be noted that the first introducer is introduced next to the annulus and the second as well as additional second introducers 102, 102x are used to bypass the leaflets 22, 24 and to be introduced to the opposite side of the annulus as the first introducer is delivered.
It is to be noted that according to an embodiment the first introducer 101 can be retracted already after the second introducer 102 is delivered and before the delivery of the additional second introducer 102x, guiding catheter 104 and implant, and the second introducer 102 can be retracted after the additional second introducer 102x is delivered and before the delivery of the guiding catheter 104 and implant, and that the additional second introducer 102x can be retracted after the guiding catheter 104 is delivered toward or into the anatomical target position and before the delivery of the implant 110. In this way a maximum space can be provided for the delivering catheter 104, or the guiding catheter 104, and in particular when the guiding catheter 104 in an expandable introducer 104, whereupon a relatively big implant can be delivered into the anatomical target position. Previously, the diameter of the all additional introducers or catheters must have been smaller and smaller, whereupon the diameter of the last delivering catheter is particularly small, which remarkably limits also the size of the object, such as the implant, to be delivered.
The invention has been explained above with reference to the aforementioned embodiments, and several advantages of the invention have been demonstrated. It is clear that the invention is not only restricted to these embodiments, but comprises all possible embodiments within the spirit and scope of the inventive thought and the following patent claims. For example the guide wire is at least partially formed from a shape memory material operable to assume an activated shape and an inactivated shape, wherein in said inactivated shape the guide wire is configured to be delivered in a straightened configuration through said first introducer and in said activated shape the guide wire is configured to take said at least first curved shape within or near the anatomical target position. The guide wire is advantageously configured to be introduced before the implant into or towards the anatomical target position. However, it is to be noted that the guide wire should at least reach the target position before the implant.
In addition, it is to be noted that even if the implant is described in this document as an example to be delivered, also other kinds of object can be delivered according to the invention, such as medicaments, for example. Furthermore, even if the heart is described in many embodiments, it is to be understood that the heart is only an example of the anatomical target. Still, in addition it is to be noted that the implant can be rigid or flexible.
Number | Date | Country | Kind |
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19185007.2 | Jul 2019 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/068873 | 7/3/2020 | WO |