RF Surgical Resection Snare for Flexible Endoscopy

Abstract

A polypectomy snare comprising two snare parts has a snare part that is completely electrically insulated and another snare part that is not electrically insulated in at least one distal portion thereof. The snare furthermore has at least one electrically insulated, HF surgically inactive skid at its distal end.

Claims

1.-17. (canceled)

18. A resection snare comprising: a first snare portion having a first electrical conductor, a first length, a first proximal end, and a first distal end, the first electrical conductor having a first insulation element electrically insulating said first electrical conductor at the first proximal end; a second snare portion having a first electrical conductor, a second length, a second proximal end, and a second distal end, the second electrical conductor having a second insulation element electrically insulating said second electrical conductor at the second proximal end; a catheter containing and configured to guide a manipulation wire therein, wherein the first and second proximal ends are connected with or merging in said manipulation wire; wherein the first and second snare portions form a snare tip at the first and second distal ends wherein at least one of the first and second electrical conductors includes a not electrically-insulated region at a corresponding distal end from the first and second distal ends; and wherein the resection snare includes at least one electrically-insulated HF-surgically inactive skid at a distal end of the snare.

19. A resection snare according to claim 1, wherein said not electrically-insulated region of the at least one of the first and second electrical conductors has a length in a range from 10 mm to 30 mm.

20. A resection snare according to claim 2, wherein said at least one electrically-insulated HF surgically inactive skid is present on an opposite side of said non electrically-insulated region as seen from a snare center.

21. A resection snare according to claim 19, wherein at least one of the first and second snare portions includes at least one of (i) a resilient metallic braid and (ii) a resilient metallic wire, said metallic wire being round or flat.

22. A resection snare according to claim 19, wherein said snare is configured to have a snare loop, formed by the first and second snare portions, moveable in and out of the catheter with the manipulation wire.

23. A resection snare according to claim 18, wherein said at least one electrically-insulated HF surgically inactive skid is present on an opposite side of said non electrically-insulated region as seen from a snare center.

24. A resection snare according to claim 23, wherein said at least one electrically-insulated HF surgically inactive skid is present on an opposite side of said non electrically-insulated region as seen from a snare center.

25. A resection snare according to claim 23, wherein at least one of the first and second snare portions includes at least one of (i) a resilient metallic braid and (ii) a resilient metallic wire, said metallic wire being round or flat.

26. A resection snare according to claim 23, wherein said snare is configured to have a snare loop, formed by the first and second snare portions, moveable in and out of the catheter with the manipulation wire.

27. A resection snare according to claim 18, wherein at least one of the first and second snare portions includes at least one of (i) a resilient metallic braid and (ii) a resilient metallic wire, said metallic wire being round or flat.

28. A resection snare according to claim 26, wherein said snare is configured to have a snare loop, formed by the first and second snare portions, moveable in and out of the catheter with the manipulation wire.

Description

DESCRIPTION OF THE DRAWINGS

[0030] FIG. 1 shows a snare according to the invention.

[0031] FIG. 2 shows a snare with two skids.

[0032] FIG. 3 shows a snare with straight skids.

[0033] FIG. 4 shows a snare with a symmetrically arranged skid.

[0034] FIG. 5 shows a snare with a flat skid.

[0035] FIG. 6 shows the risk of penetrating of a cutting snare into an organ wall.

[0036] FIG. 7 shows the effect of a skid.

[0037] In FIG. 1, an inventive HF-surgical resection snare 1 for flexible endoscopy is shown. It comprises a first snare part 2 and a second snare part 3. These snare parts comprise preferably resilient, metallic round and/or flat wire. Alternatively, they may also comprise metallic braid. The snare parts each have a proximal end 11 and a distal end 10. The proximal ends of the snare parts together form the proximal end 11 of the snare. They are mechanically and electrically conductive connected with at least one manipulation wire 8, for example by a connecting element 12, or they are formed as a manipulation wire. For example, at least one of the snare parts may be considerably extended at its proximal side, such that the extension serves as a manipulation wire. Furthermore, the both snare parts form a distal snare end 10 with a snare tip 7. The snare tip is optional, but is usually required to design a snare being retractable into a catheter. Both snare parts may also be formed by a continuous wire. Furthermore, the two snare parts are preformed, such that they together form a resiliently deformable HF-surgical snare 1. With such a snare, a polyp-shaped or flat-growing pathological tissue area can be wrapped and removed from an organ wall with or without suitable preparation, for example sub-mucosal injections and circumferential circumcision.

[0038] Furthermore, the first snare part 2 is preferably completely electrically insulated. The second snare part 3 is electrically insulated in a proximal region and electrically non-insulated in a distal region 5.

[0039] For better evaluation of cutting progress, markers 13a, 13b are provided on the snare parts and/or the manipulation wire. Preferably, they show a significant color contrast against each other. In this way, movement with respect to the distal end 9 of the catheter can be well observed.

[0040] A skid 14 starts from the first snare part 2. It may as well start from the second snare part 3. However, the embodiment illustrated here is particularly advantageous, as the end of the skid lies behind the non-insulated region 5 when seen from snare center, and thus allows a mechanical support just behind this region.

[0041] The centroid of the region enclosed by the snare can be used as snare center, for example. In the embodiment illustrated here, the skid 14 intersects the non-insulated region 5. Preferably, there is a protection 15 located at the end of the skid. The snare gets closer upon further contracting it, such that the first snare part and the second snare part approach each other. Thus, in this embodiment, the skid 14 pivots in a direction parallel to the longitudinal axis of the catheter. In the illustration according to FIG. 1, this corresponds to an upwards pivoting.

[0042] When the snare is completely drawn into the catheter, the skid 14 lies above the catheter tip 7.

[0043] In FIG. 2, a further embodiment with two skids 18a, 18b is shown. These skids have a protection 15a, 15b at their respective ends. In this exemplary embodiment, the first snare part 2 has a first non-insulated region 16 and the second snare part 3 has a second non-insulated region 17.

[0044] Basically, in line with this invention, one or more non-insulated regions can be combined with the various skids illustrated herein. However, it is particularly preferred to use two skids, when two non-insulated snare parts are present, as shown in FIG. 2.

[0045] In FIG. 3, a further embodiment is shown, in which the skids are formed straight.

[0046] In FIG. 4, a single symmetrically arranged skid 19 is shown.

[0047] In FIG. 5, a flat skid 20 is shown. It may, for example, be rolled up to guide it through the catheter.

[0048] FIG. 6 shows, that cutting without skid bears the risk of an undesired penetration into the organ wall. A pathological tissue area 50 is enclosed by the snare.

[0049] Here, the second snare part is visible in the side view. Usually, the catheter 6 comes out of the middle of the hollow organ, such as the intestine, and thus lies under an angle with respect to the organ wall 51. In order to be able to remove the pathological area as close as possible to the organ wall, the snare must be pressed against the organ wall. This produces a force in the direction of penetration 58 towards the organ wall. Thus, the non-insulated region 5 of the snare can now penetrate in the direction 58 into the organ wall and damage it, resulting in the worst case in perforation of the organ.

[0050] FIG. 7 shows, how penetration of the snare into the organ wall is avoided by means of a skid. Here, the skid 14 with its protection 15 rests on the organ wall and thus prevents penetration of the non-insulated region 5 into the organ wall.

[0051] It is obvious that with a longer skid 14, a longer lever and thus a better protection against penetration of the non-insulated region 5 into the intestinal wall can be achieved. Likewise, the bearing surface on the organ wall 51 can be enlarged by a longer skid 14 and/or by a greater protection 15. Often, the surface of the organ wall itself is elastic and gives way at least slightly upon pressure by skid.

[0052] This can be counteracted by increasing the bearing surface.

LIST OF REFERENCE NUMBERS

[0053] 1 resection snare [0054] 2 first snare part [0055] 3 second snare part [0056] 5 non-insulated region [0057] 6 catheter [0058] 7 catheter tip [0059] 8 manipulation wire [0060] 9 distal end of the catheter [0061] 10 distal end of the resection snare [0062] 11 proximal end of the resection snare [0063] 12 connecting element [0064] 13a, 13b contrasting markings [0065] 14 skid [0066] 15 protection [0067] 16 first non-insulated region [0068] 17 second non-insulated region [0069] 18a, 18b skid [0070] 19 skid [0071] 20 flat skid [0072] 50 pathological tissue area [0073] 51 organ wall [0074] 58 penetration direction