JP7510481B2 - Surgical instruments - Google Patents

Description

The present invention relates to surgical equipment, and in particular to surgical instruments used in bone drilling surgery.

During the treatment of bone damage caused by external force, disease, or degeneration, the strength of the bone can be increased by inserting an intramedullary nail into the damaged bone, or the bone can be fixed to promote healing. Generally speaking, before inserting the intramedullary nail into the bone, a drill bit is used to cut into the bone tissue to create an implant hole for the intramedullary nail.

U.S. Pat. No. 5,954,671

However, after the bone tissue is cut, bone damage is likely to occur, and further bone loss can occur, requiring additional bone filling surgery. In addition, the bone damage can lead to osteonecrosis, and the growth of bone tissue can be hindered after surgery, increasing the risk of surgery and increasing the cost of surgery.

Based on the above-mentioned problems, the above-mentioned conventional surgical instruments must be further improved.

In order to solve the above problems, the present invention aims to provide a surgical instrument that can prevent damage to bone tissue.

The terms of direction or approximations thereof used throughout the specification of the present invention, such as "front," "rear," "left," "right," "top," "bottom," "inside," "outside," and "side," primarily indicate directions in the accompanying drawings, and the terms of each direction or approximations thereof are intended to aid in the explanation and understanding of each embodiment of the present invention, and are not intended to limit the present invention.

The use of the counters "one" or "one piece" for parts and members described throughout the specification of this invention is for convenience only and to provide the usual meaning within the scope of this invention, and should be read as including one or at least one in this invention, and the single concept also includes multiple situations, unless clearly indicating otherwise.

In the present specification, the terms "connected," "combined," "assembled," and similar terms include those in which the members can be separated without being destroyed even after being connected, or those in which the members cannot be separated after being connected, and this can be selected by a person having ordinary skill in the art depending on the materials of the members to be connected or the needs of the assembly.

The surgical instrument of the present invention includes a rod and a pressing part, the rod has an axis extending to both opposing ends, the axis being formed as one rotation axis of the rod, the pressing part is connected to one end of the rod, the other end of the pressing part has a blade part, the pressing part has a plurality of accommodation grooves, the plurality of accommodation grooves are recessed into one surface of the pressing part, the plurality of accommodation grooves are spaced apart, a rib is formed on the pressing part between two adjacent accommodation grooves, the upper end of the rib in the radial cross section of the pressing part is the surface, each rib in the radial cross section of the pressing part has a guide surface, the guide surface is connected to the surface, and the included angle at the point where the guide surface is connected to the surface in the radial cross section toward the rotation direction is greater than 90°.

As a result, in the surgical instrument of the present invention, the pressing part has a plurality of receiving grooves, and a rib is formed on the pressing part between two adjacent receiving grooves, and the surface is formed on the upper end of the rib in the radial cross section, and an obtuse angle is formed at the portion where the guide surface and the surface are connected, so that the rib does not cause cutting on the inner wall of the bone tissue, and after the pressing part penetrates into the bone, the bone chips generated by the blade penetrating into the bone enter the receiving groove and are guided to the surface of the upper end of the rib and are further pressed toward the inner wall of the bone tissue, so that the bone chips and the inner wall of the bone tissue form a dense layer together by pressing, forming strong bone tissue, which can further reduce the loss of bone tissue, increase the stability of bone quality, and be useful for postoperative recovery, thereby increasing the success rate of surgery for osteoporosis patients.

The extension direction of each of the grooves is at an angle of 1 to 45 degrees with respect to the axis. In this way, after the bone chips enter each groove, they are pressed and can move toward the inner wall and the back of the bone tissue.

The first end of the pressing part is connected to one end of the rod, the second end of the pressing part is the blade part, and the pressing part is formed so as to gradually shrink in the radial direction from the first end to the second end. In this way, the pressing part has the effect of penetrating into the bone and helping to enlarge the hole.

The surface of the pressing portion, which is formed to gradually shrink, is inclined at an angle of 1 to 16 degrees with respect to the axis. This has the effect of improving the hole-making ability of the pressing portion.

The surgical instrument of the present invention further includes a position specifying member, which is connected to the outer surface of the rod so as to be freely displaceable in the axial direction, and which has a positioning portion that is used to position the position specifying member at a predetermined position on the rod. In this way, the operator can know the penetration depth of the pressing portion by the position specifying member approaching or abutting the skin or the bone surface.

The position specifying member is an annular body, the positioning portion has a bolt and a screw hole, the screw hole penetrates the inner and outer surfaces of the position specifying member, and the bolt can be connected to the screw hole so as to abut against the rod. In this way, the position specifying member can be positioned at a predetermined position on the rod, which has the effect of setting the intended depth to which the pressing portion will penetrate into the bone.

The surgical instrument also includes a sleeve tube having an abutment end and an insertion end, and the insertion end is used to insert the rod and the pressing part. In this way, the sleeve tube can be positioned at a predetermined hole drilling position, and a passage for the rod to enter can be formed, which has the effect of making it easier for the operator to drill the hole.

The edge of the abutment end has a plurality of locking portions, which are a plurality of protruding teeth or a plurality of recesses. In this way, the abutment end can generate resistance in the rotational direction, which has the effect of preventing errors in drilling holes due to rotation or displacement of the sleeve tube during the surgical process.

The outer wall of the sleeve tube has a drop-out prevention portion, which is a plurality of annular bodies protruding in the radial direction. In this way, the drop-out prevention portion reduces the resistance force generated in the axial direction of the sleeve tube, preventing the sleeve tube from escaping from the tissue during the surgical procedure, which has the effect of allowing the hole-making surgery to be performed smoothly.

The fall-prevention portion also has a unidirectional inclined surface. In this way, the fall-prevention portion allows the guide member to be easily placed into the skin or minimally invasive wound, and further allows the operator to easily remove the guide member from the skin or minimally invasive wound after surgery.

The surgical instrument further includes at least one guide member, the at least one guide member having a connecting handle portion, and at least one end of the connecting handle portion having a sleeve tube. In this way, the connecting handle portion can be easily grasped by the operator, which has the effect of improving convenience in use.

In addition, both ends of the connecting handle portion each have a sleeve tube, and the sleeve tubes each have a different inner diameter. In this way, the guide member can be used to match two rods with different outer diameters, thereby reducing the number of surgical instruments, which has the effect of making the surgical procedure simple and smooth.

In addition, there are two guide members, and the inner diameter of the sleeve tube of one of the guide members corresponds to or is slightly larger than the outer diameter of the sleeve tube of the other guide member. In this way, the sleeve tube of one guide member can be fitted into the sleeve tube of the other guide member, so that the two types of rods with different outer diameters can be used together to easily and smoothly perform the step-by-step hole enlargement operation.

FIG. 1 is an exploded perspective view of a first embodiment of the present invention. 2 is a cross-sectional view taken along line AA in FIG. 1. FIG. 2 is a state diagram showing a state where a hole is drilled using the first embodiment of the present invention. FIG. 11 is an exploded perspective view of a second embodiment of the present invention. FIG. 11 is a state diagram showing a state in which a hole is drilled using the second embodiment of the present invention. FIG. 10 is an exploded perspective view of a third embodiment of the present invention. FIG. 11 is a cross-sectional view showing a usage state of a third embodiment of the present invention. FIG. 13 is an exploded perspective view of a fourth embodiment of the present invention. FIG. 13 is a perspective view of an example of use of the fourth embodiment according to the present invention. FIG. 11 is a cross-sectional view showing a usage state of the fourth embodiment of the present invention.

In order to make the above and other objects, features and advantages of the present invention clearer and easier to understand, the present invention will be described in detail with reference to the following embodiments and drawings. In addition, the same reference numerals in different drawings are regarded as the same, and the description thereof will be omitted.

As shown in FIG. 1, in a first embodiment of the surgical instrument of the present invention, the surgical instrument includes a rod 1 and a pressing portion 2, and the pressing portion 2 is formed to be located at one end of the rod 1.

The rod 1 is made of a material having a certain rigidity, so that the rod 1 has sufficient strength to be driven to rotate by the driving member. The rod 1 is made of SUS420 medical grade stainless steel, so that it is possible to avoid the occurrence of rejection or allergic reactions in human tissue, and the outer surface of the rod 1 has a chromium carbide plating layer, so that the rod 1 has relatively good corrosion resistance and wear resistance properties. The rod 1 has an axis extending to both opposing ends, and when the rod 1 is driven by the driving member, the rod can rotate about the axis L.

1 and 3, the pressing part 2 is connected to one end of the rod 1, and the pressing part 2 can be integrally formed with the rod 1, or the pressing part 2 can be detachably connected to one end of the rod 1 by a method such as engagement, locking or screwing, so that the pressing part 2 can be easily replaced after wear. The pressing part 2 can also be made of SUS420 medical grade stainless steel, or the outer surface of the pressing part 2 can also have a chromium carbide plating layer. In this embodiment, the pressing part 2 has a first end 2a, a second end 2b and a surface C, the first end 2a is connected to one end of the rod 1, the second end 2b is a blade part, and is used to contact a predetermined position on the bone surface, and when the rod 1 rotates in a rotation direction D, the pressing part 2 can rotate together, and the blade part of the second end 2b can penetrate into the bone. In addition, the pressing portion 2 is formed so as to gradually shrink radially from the first end 2a to the second end 2b, so that the pressing portion 2 is formed to have a taper. In another embodiment, the surface of the pressing portion 2 formed to gradually shrink is inclined at 1 to 16 degrees with respect to the axis L. In this way, the pressing portion 2 can penetrate into the bone and help expand the hole.

2 and 3, the pressing part 2 has a plurality of accommodating grooves 21, which are located on the surface C of the pressing part 2 and are recessed to extend between the first end 2a and the second end 2b, and can be used for the entry of bone chips cut by the blade portion of the second end 2b. Each of the accommodating grooves 21 is obliquely provided on the surface C of the pressing part 2. The extension direction of each of the accommodating grooves 21 forms an included angle θ1 with respect to the axis L, and the included angle θ1 can be 1 to 45°. Going further, a rib 22 is formed on the pressing part 2 between two adjacent receiving grooves 21, and the upper end of the rib 22 in the radial cross section is the surface C. After the pressing part 2 penetrates into the bone, the surface C can be used to press the inner wall of the bone tissue without causing cutting against the inner wall of the bone tissue, thereby reducing damage to the inner wall of the bone tissue.

A guide surface 22a is formed on each rib 22 in the radial cross section of the pressing part 2, and the guide surface 22a is connected to the surface C. When the pressing part 2 rotates in the rotation direction D, the bone chips cut by the blade of the second end part 2b enter each of the accommodation grooves 21 and then move toward the inner wall of the bone tissue by being pushed out by the guide surface 22a. In addition, an included angle θ2 is formed at the portion where the guide surface 22a is connected to the surface C in the radial cross section, and the included angle θ2 is greater than 90°. In this way, an obtuse angle can be formed at the portion where the guide surface 22a is connected to the surface C, so that damage to the inner wall of the bone tissue can be reduced without causing cutting of the inner wall of the bone tissue.

1, the rod 1 can further be coupled to a positioning member 3, which is coupled to the outer surface of the rod 1 so as to be freely displaceable in the axial direction. The positioning member 3 can have a positioning portion 31, so that the positioning member 3 can be positioned at a predetermined position on the rod 1. In this embodiment, the positioning member 3 is an annular body, which is provided around the outer surface of the rod 1 and can slide axially on the outer surface of the rod 1. The positioning portion 31 can be made of an elastically deformable material on the inner wall of the positioning member 3 so that the positioning member 3 is tightly fitted to the outer surface of the rod 1. Alternatively, as shown in FIG. 1, the positioning portion 31 of the positioning member 3 has a bolt 31a and a screw hole 31b, which penetrates the inner and outer surfaces of the positioning member 3, and the bolt 31a can be coupled to the screw hole 31b so as to abut against the rod 1. In this way, the positioning member 3 can be positioned on the rod 1 and has a predetermined distance from the pressing part 2, which can be set to the intended depth of penetration into the bone, and the positioning member 3 gradually approaches the skin as the rod 1 penetrates, so that the operator can know the penetration depth of the pressing part 2 by the positioning member 3.

3, when an operator performs surgery with a bone drill, the operator selects the pressing part 2 having a predetermined outer diameter dimension on the surface C, contacts the blade part of the second end 2b of the pressing part 2 with a predetermined position on the surface of the bone, and drives the rod 1 to rotate in the rotation direction D, so that the blade part of the second end 2b can drill deeply inward while cutting the bone tissue. At this time, the bone chips cut by the blade part of the second end 2b enter the receiving groove 21, and the bone chips move toward the inner wall of the bone tissue according to the extrusion of the guide surface 22a, and are pressed toward the inner wall of the bone tissue by the surface C, and the surface C can press the inner wall of the bone tissue at the same time. In this way, by drilling deeply inward with the blade part of the second end 2b and pressing toward the inner wall of the bone tissue with the surface C of the pressing part 2, the bone chips and the inner wall of the bone tissue can form a dense layer together to form strong bone tissue. In addition, the operator can use the pressing parts 2 with multiple different outer diameters and gradually expand the hole from a small outer diameter to a large outer diameter in an orderly manner, thereby reducing the risk of bone necrosis through gradual hole expansion.

As shown in Figures 4 and 5, in the second embodiment of the surgical instrument of the present invention, compared to the first embodiment, this embodiment can further include a sleeve tube 4, and the inner diameter dimension of the sleeve tube 4 can be formed to correspond to or be slightly larger than the outer diameter dimension of the rod 1, and the sleeve tube 4 can be used to insert the rod 1 and the pressing part 2. In addition, the maximum outer diameter of the pressing part 2 can be formed not to be larger than the outer diameter of the rod 1, and thus, by the inner diameter dimension of the sleeve tube 4 corresponding only to the outer diameter of the rod 1, the rod 1 and the pressing part 2 can be inserted at the same time, which can provide better convenience in manufacturing.

The sleeve tube 4 has an abutment end 4a and an insertion end 4b, and the abutment end 4a can abut the predetermined hole drilling position on the bone surface, or the abutment end 4a can abut into muscle tissue, and the rod 1 and the pressing part 2 can be inserted from the insertion end 4b, so that a hole can be drilled at the predetermined hole drilling position. For example, when performing minimally invasive surgery, the predetermined hole drilling position on the bone surface at the affected area is covered by skin or muscle tissue, and thus, the sleeve tube 4 is formed to be positioned at the predetermined hole drilling position by entering a minimally invasive wound previously opened in the skin or muscle tissue using the sleeve tube 4, and further formed as a passage for the rod 1 and the pressing part 2 to enter, which can help the operator to drill the hole.

The edge of the abutting end 4a may have a plurality of locking portions 41, which may consist of a plurality of protruding teeth or a plurality of recesses. Thus, the locking portions 41 of the abutting end 4a may form a resistance force in the rotational direction, so that the sleeve tube may avoid errors in drilling holes due to rotation or displacement during the surgical procedure. Alternatively, the outer wall of the sleeve tube 4 may have a drop-out prevention portion 42, which may be a plurality of annular bodies protruding in the radial direction, and may have a unidirectional inclined surface, so that the drop-out prevention portion 42 may be easily placed in the skin or a minimally invasive wound, and the resistance force generated in the axial direction may be small, so that the sleeve tube 4 may be prevented from escaping from the tissue during the surgical procedure, and the hole drilling operation may be performed smoothly. Of course, the skin or minimally invasive wound may be expanded in the radial direction, so that the operator may easily remove the sleeve tube 4 from the skin or minimally invasive wound after the operation. The locking portion 41 or the anti-falling portion 42 can be selectively formed on the sleeve tube 4 either alone or together, but this is not limited to this in the present invention.

6, in the third embodiment of the surgical instrument of the present invention, compared to the first embodiment, the present embodiment may further include a guide member 5, the guide member 5 having a connecting handle portion 51, and at least one end of the connecting handle portion 51 having a sleeve tube 52. Preferably, both ends of the connecting handle portion 51 each have a sleeve tube 52, and each sleeve tube 52 has an abutment end 52a and an insertion end 52b as shown in the second embodiment, and each sleeve tube 52 may have the above-mentioned locking portion 53 and/or anti-dropping portion 54, and the insertion end 52b is used to insert the rod 1 and the pressing portion 2, so that a hole can be made at a predetermined hole opening position. In addition, the locking portion 53 and the anti-dropping portion 54 in the third embodiment have the same or similar structure as the locking portion 41 and the anti-dropping portion 42 in the second embodiment, respectively. It should be noted that the sleeve tubes 52 at both ends of the connecting handle 51 can have different inner diameters, and thus the guide member 5 can be used with rods 1 and pressure parts 2 with two different outer diameters, reducing the number of surgical instruments and simplifying the surgical procedure, thereby increasing convenience in use.

7, in the cross-sectional view of the use of the third embodiment of the present invention, the operator holds the connecting handle 51 of the guiding member 5 with one hand, and the sleeve tube 52 of the guiding member 5 can abut the predetermined hole drilling position on the bone surface with the abutment end 52a, or the abutment end 52a can abut into the muscle tissue, and select the pressing part 2 having a predetermined outer diameter dimension on the surface C, insert the rod 1 and the pressing part 2 from the insertion end 52b, and drive the rod 1 to rotate in the rotation direction D, and the blade part of the second end 2b can drill deeply inward while cutting the bone tissue. The bone chips cut by the blade part enter the receiving groove 21, and the bone chips can move toward the inner wall of the bone tissue according to the extrusion of the guide surface 22a. In this way, by drilling deeply inward with the cutting edge of the second end 2b while pressing against the inner wall of the bone tissue with the surface C of the pressing part 2, the bone chips and the inner wall of the bone tissue together form a dense layer, forming strong bone tissue.

As shown in FIG. 8, in the fourth embodiment of the surgical instrument of the present invention, compared to the third embodiment, this embodiment can further include two guide members 5a and 5b, and the two guide members 5a and 5b can have a sleeve tube 52 at at least one end of the connecting handle portion 51 of the two guide members 5a and 5b as described in the third embodiment, or both ends of the connecting handle portion 51 each have a sleeve tube 52, and each sleeve tube 52 has an abutment end 52a and an insertion end 52b as described in the third embodiment, and each sleeve tube 52 can have the aforementioned locking portion 53 and/or anti-dropping portion 54, and the insertion end 52b is used to insert the rod 1 and the pressing portion 2, so that a hole can be drilled at a specified hole drilling position.

It should be noted that the sleeve tubes 52 at both ends of the connecting handle 51 of the two guide members 5a and 5b can have different inner diameters. Thus, the two guide members 5a and 5b can be used with rods 1 and pressing parts 2 with four different outer diameters, which can reduce the number of surgical instruments and simplify the surgical procedure to improve convenience. In addition, in another embodiment, the inner diameter of one of the two sleeve tubes 52 can be made slightly larger than the outer diameter of the other sleeve tube 52. Thus, when two guide members 5 are used, the sleeve tube 52 of one of the guide members 5a and 5b can be inserted into the sleeve tube 52 of the other guide member 5a and 5b, allowing for a step-by-step hole enlargement operation.

9, in the perspective view of the fourth embodiment of the present invention, when an operator must perform a step-by-step hole enlargement operation using a plurality of rods 1 and pressing parts 2 with different outer diameters, the hole can be enlarged in an orderly and gradual manner from a small outer diameter to a large outer diameter. In this embodiment, an example using two of the guide members 5a and 5b will be described. First, the relatively small inner diameter sleeve tube 52 of one of the guide members 5b can be fitted into the relatively large inner diameter sleeve tube 52 of the other guide member 5a (as shown in Figures 9 and 10). At this time, the relatively small inner diameter sleeve tube 52 is first used to guide the relatively small outer diameter rod 1 and the pressing part 2 to open a hole, and then the relatively small inner diameter sleeve tube 52 guide member 5b is removed (as shown in Figure 7). With the other guide member 5a still in position, the relatively large inner diameter sleeve tube 52 continues to guide the relatively large outer diameter rod 1 and the pressing part 2 to expand the hole, completing the step-by-step hole expansion operation.

In summary, the surgical instrument of the present invention has a pressing part with a plurality of receiving grooves, and a rib is formed on the pressing part between two adjacent receiving grooves, and the surface is formed on the upper end of the rib in the radial cross section, and an obtuse angle is formed at the portion where the guide surface and the surface are connected, so that the rib does not cut the inner wall of the bone tissue, and after the pressing part penetrates into the bone, the bone chips generated by the blade penetrating into the bone enter the receiving groove and are guided to the surface of the upper end of the rib and are further pressed toward the inner wall of the bone tissue, so that the bone chips and the inner wall of the bone tissue form a dense layer together by pressing, forming strong bone tissue, which can further reduce the loss of bone tissue, increase the stability of bone quality, and be useful for postoperative recovery, thereby increasing the success rate of surgery for osteoporosis patients.

Although the present invention has already been presented using the above-mentioned relatively good examples, the present invention is not limited to the above-mentioned examples, and as long as a person familiar with this technology does not deviate from the spirit and scope of the present invention, various changes and modifications corresponding to the above-mentioned examples still fall within the technical scope protected by the present invention, and the scope of protection of the present invention should naturally include modifications within the meaning and equivalent range described in the claims of the attached patent. Furthermore, if a combination of the above-mentioned multiple examples is possible, the present invention includes embodiments using any combination.

REFERENCE SIGNS LIST 1 Rod 2 Pressing portion 2a First end 2b Second end 21 Accommodation groove 22 Rib 22a Guide surface 3 Positioning member 31 Positioning portion 31a Bolt 31b Screw hole 4 Sleeve tube 4a Contact end 4b Insertion end 41 Locking portion 42 Fall-off prevention portion 5 Guiding member 5a Guiding member 5b Guiding member 51 Connecting handle portion 52 Sleeve tube 52a Contact end 52b Insertion end 53 Locking portion 54 Fall-off prevention portion L Axis D Rotation direction C Surface θ1 Angle θ2 Angle

Claims (11)

The device includes a rod, a pressing portion, and two guiding members,
the rod has an axis extending to opposite ends, the axis being defined as one axis of rotation of the rod;
the pressing part is connected to one end of the rod, the other end of the pressing part has a blade part, the pressing part has a plurality of accommodating grooves, the plurality of accommodating grooves are recessed into one surface of the pressing part, the plurality of accommodating grooves are spaced apart, a rib is formed on the pressing part between two adjacent accommodating grooves, the upper end of the rib in the radial cross section of the pressing part is the surface, each rib in the radial cross section of the pressing part has a guide surface, the guide surface is connected to the surface, the guide surface faces the direction of rotation, and the included angle at the point where the guide surface is connected to the surface in the radial cross section is greater than 90°;
a first end of the pressing portion is connected to one end of the rod, a second end of the pressing portion is the blade portion, and the pressing portion is formed so as to gradually decrease in diameter from the first end toward the second end;
The surface of the pressing portion formed to gradually shrink is inclined at an angle of 1 to 16 degrees with respect to the axis,
The surgical instrument is characterized in that the guiding member has a connecting handle portion for being gripped by the hand of an operator, and each end of the connecting handle portion has a sleeve tube, the sleeve tubes having different inner diameter dimensions, and the inner diameter dimension of one sleeve tube corresponds to the outer dimension of the other sleeve tube so that the sleeve tube of one guiding member can be fitted into the sleeve tube of the other guiding member. The surgical instrument according to claim 1, characterized in that the extension direction of each of the housing grooves extending from the tip to the base end is at an angle of 1 to 45° with respect to the axis. The surgical instrument according to claim 1, further comprising a position-specifying member, the position-specifying member being connected to the outer surface of the rod so as to be freely displaceable in the axial direction, the position-specifying member having a positioning portion, and the positioning portion being used to position the position-specifying member at a predetermined position on the rod. The surgical instrument according to claim 3, characterized in that the position-specifying member is an annular body, the positioning portion has a bolt and a threaded hole, the threaded hole penetrates the inner and outer surfaces of the position-specifying member, and the bolt can be connected to the threaded hole so as to abut against the rod. The surgical instrument according to any one of claims 1 to 4, characterized in that the sleeve tube has an abutment end and an insertion end, the insertion end being used for inserting the rod and the pressing portion. The surgical instrument according to claim 5, characterized in that the edge of the abutting end has a plurality of protruding teeth or a plurality of recesses. 6. The surgical instrument according to claim 5 , wherein an outer wall of the sleeve tube has a fall-off prevention portion consisting of a plurality of annular bodies protruding radially to prevent the sleeve tube from falling off the tissue during surgery. The surgical instrument according to claim 7, characterized in that the fall-prevention part has a unidirectional inclined surface. The surgical instrument according to claim 1, characterized in that the sleeve tube has an abutment end and an insertion end, the insertion end is used for inserting the rod, and the edge of the abutment end has a plurality of protruding teeth or a plurality of recesses. The surgical instrument according to claim 1, characterized in that the outer wall of the sleeve tube has a fall prevention part consisting of multiple ring-shaped bodies protruding in the radial direction to prevent the sleeve tube from falling off the tissue during surgery. The surgical instrument according to claim 10, characterized in that the fall-off prevention part has a unidirectional inclined surface.