Patent Description:
Osteotomy has been applied to knee osteoarthritis, for example, when the articular cartilage of the patella or the femur is damaged. In osteotomy, after an incision is made in a bone and malalignment of the bone is corrected, the bone is fixed by using a bone joining member, such as a plate, until the bone is healed (for example, refer to PTL <NUM>).

<CIT> refers to a system that comprises a bone forceps including two elongates arms pivotally coupled to one another at a joint. The joint includes a bore extending through each of the arms with a clamping screw pivotally received therein. The clamping screw also secures an extension member to the arms. The extension member is an elongated element having a proximal end coupled to the arms and including a first section extending from the proximal end substantially parallel to the portions of the arms proximal of the joint to a second section extending away from the first section at an angle selected so that, when the arms are in a desired position gripping a fractured portion of a bone, the second section extends approximately parallel to a surface of the bone. A first bore extending through the first section is sized to receive a threaded shaft of the clamping screw therethrough. The second section includes a second bore extending therethrough configured to receive a set screw having an increased diameter head and a threaded shaft. A distal end of the threaded shaft is connected to a plate shoe via a ball joint.

<CIT> refers to an aiming device comprising a substantially cylindrical hooked arm, a longitudinal section and a hooked section with a pointed tip. A handle over the arm includes a through-hole configured to slidably receive the arm therethrough and a tightening mechanism to lock the position of the handle relative to the arm. A free end of the handle comprises a substantially cylindrical pin having approximately a same diameter as screw holes of a bone plate.

<CIT> refers to a bone clamp including a pair of elongated body members pivotally joined in crossed relation intermediate their ends by a pivot bolt. The body members extend forwardly from said pivot to form respectively spaced apart jaw members. Formed in an inner surface of each of said jaws is a groove. Carried in each of said grooves is a clamping member. An inner surface of an upper jaw member among the jaw members is recessed at a location to provide a space between the upper jaw member and a bone immediately adjacent a clamp bar. A set screw is threaded through the upper jaw member, and is adapted to contact a plate at its inner end to hold said plate firmly in position against the bone.

<CIT> refers to a bone holding tool that has a main body which extends in a shape of a long measure, a hook section which is prepared at a leading edge of the main body and is engaged with a bone, and a support part which is prepared at the leading edge of the main body, extends towards an inner peripheral face side of the hook section, and supports a reinforcement implement in the case of fixation of reinforcement implement.

<CIT> discloses a pressing guide including a main support portion including a nut and a guide cylinder inserted through the nut. The guide cylinder has a through hole and a smooth and blunt cylinder tip.

<CIT> discloses an orthopedic positioner capable of adjusting an positioning point. The device includes a sliding rod and a U-shape support at the end of the sliding rod for facilitating the adjustment of the positioning point.

PTL <NUM> discloses a bone retainer that can retain both the bone and the bone joining member while the bone joining member is aligned with respect to the bone. According to this bone retainer, screws for fixing the bone joining member to the bone can be driven into the bone via through holes formed in a support portion that supports the bone joining member while the bone and the bone joining member are retained; thus, the task of fixing the bone joining member to the bone can be easily carried out.

When fixing the bone joining member to the bone, the bone must be corrected so that the osteotomy surfaces formed at the incision are in close contact with each other, and to do so, a compression force in the longitudinal axis direction of the bone, which is the direction in which the osteotomy surfaces are drawn toward each other, must be applied to the bone from both sides of the osteotomy surfaces. However, although the bone retainer described in PTL <NUM> is capable of applying a compression force to the bone and the bone joining member in the bone radial direction to bring the bone and the bone joining member into close contact with each other, the bone retainer cannot apply a force to the bone in the longitudinal axis direction and has a problem in that it is difficult to correct the bone so that the osteotomy surfaces are in close contact with each other.

The present invention has been made under the circumstances described above, and an object thereof is to provide a pressing tool for bone surgery, with which a compression force can be applied in both the bone radial direction and longitudinal axis direction so that close contact can be achieved between the bone and the bone joining member and between the osteotomy surfaces of the bone.

In order to achieve the object described above, the present invention provides the following solution.

The present invention provides a pressing tool as defined in claim <NUM>. Associated methods are also described herein to aid understanding of the invention, but these do not form part of the claimed invention.

In one aspect, a pressing tool for bone surgery may comprise: a pressurizing member formed substantially columnar shape having, at one end, a pressing surface formed of a convex and substantially spherical surface; and a hook member formed to have a hook shape that is to be engaged with a surface of a bone, the hook member having a support portion at a first end, the support portion supporting the pressing member so that the pressing surface is directed toward a second end, and a projection portion at the second end, the projection portion projecting toward the support portion and being to be bited into the surface of the bone, wherein the support portion supports the pressing member so that the pressing member is movable in a longitudinal direction toward the projection portion.

According to the aforementioned aspect, after a bone joining member is placed on a surface of the bone in which an incision is made so as to bridge the incision, the hook member engages with the surface of the bone in such a manner that the bone and the bone joining member are sandwiched in the bone radial direction between the projection portion and the support portion at two ends of the hook member, and the projection portion is allowed to bite into the surface of the bone to fix the projection portion to the surface of the bone. The pressing member supported by the support portion is moved toward the projection portion in such a manner that the pressing surface presses the bone joining member toward the bone. As a result, a compression force in the bone radial direction is applied to the bone and the bone joining member sandwiched between the projection portion and the pressing member, and thus the bone and the bone joining member can make close contact with each other.

In this case, the direction in which the compression force is applied to the bone and the bone joining member is coincident with the direction in which the pressing member moves. Thus, when the hook member engages with the surface of the bone so that the longitudinal direction of the pressing member is inclined relative to the longitudinal axis direction of the bone, a compression force in both the bone radial direction and longitudinal axis direction is applied, and close contact can be achieved between the bone and the bone joining member and between the osteotomy surfaces of the bone.

Furthermore, in a state in which the hook member is engaged with the bone so that the pressing member is inclined with respect to the longitudinal axis direction of the bone, a large compression force can be stably applied to the bone and the bone joining member between the projection portion and the pressing member by fixing the projection portion at the second end of the hook member to the surface of the bone. In addition, since the pressing surface contacting the bone joining member is substantially spherical, the orientation of the hook member can be easily changed by rotating the pressing surface at the same position relative to the bone joining member and by shifting the projection portion in the longitudinal axis direction of the bone.

In the aspect described above, the pressing member has a male thread and a head portion that is disposed at one end of the male thread and has the pressing surface, and the support portion has a screw hole to be fastened to the male thread.

In this manner, since the rotation of the male thread inside the screw hole is converted into movement of the shaft portion in the longitudinal direction, it is easy to finely adjust the amount of the movement of the male thread to control the compression force applied to the bone and the bone joining member.

In the aspect described above, the projection portion may be positioned on an extended line of an axis line along which the pressing member is movable.

In this manner, only a pressing force in the longitudinal direction of the pressing member can be applied to the bone joining member.

In the aspect described above, the projection portion may be at a position offset from an extended line of an axis line along which the pressing member is movable, in a direction intersecting the extended line.

In this manner, in addition to the pressing force in the longitudinal direction of the pressing member, a moment in a direction opposite to the offset direction of the projection portion intersecting the longitudinal direction of the pressing member can be applied to the bone joining member, and thus the bone joining member can be moved not only in a direction toward the bone but also in a direction opposite to the offset direction of the projection portion.

In the aspect described above, a distance between an extended line of an axis line along which the pressing member is movable and a middle portion of the hook member may be <NUM> or more and <NUM> or less.

In this manner, the size of the hook member becomes suitable for a large bone, such as the femur or the tibia.

In the aspect described above, the projection portion may have one or more pyramid-shaped projections having pointed ends.

In this manner, the pointed ends of the projections bite into the hard cortical bone covering the surface of the bone, and the projection portion can be easily fixed thereby.

In the aspect described above, the hook member has a slit that allows an interior of the screw hole and an exterior of the support portion to communicate with each other in a radial direction of the screw hole and that extends in a direction along a center axis of the screw hole, wherein a guide pin is inserted into the screw hole in the radial direction.

In this manner, the hook member can be easily installed relative to the guide pin preliminarily inserted into the bone.

In the aspect described above, the pressing tool may further include a plug having a receiving portion having a concave receiving surface that supports the pressing surface, and a connecting portion that can connect the receiving portion to a bone joining member that is to be fixed to the surface of the bone.

In this manner, compared to the case in which the pressing surface is directly pressed against the bone joining member, the position of the pressing surface relative to the bone joining member can be stabilized by fitting the pressing surface to the receiving surface of the receiving portion of the plug connected to the bone joining member, and a pressing force can more efficiently be applied from the pressing surface to the bone joining member.

In the aspect described above, the plug may have a through hole that opens substantially at the center of the receiving surface and allows a guide pin to pass therethrough.

In this manner, the guide pin inserted into the bone passes through the bone joining member, the plug, and the pressing member, and thus, the positions of the bone joining member, the plug, and the pressing member relative to the bone can be stabilized. Considering the diameter of the guide pin typically used in osteotomy, the diameter of the through hole of the plug is preferably <NUM> or more.

In the aspect described above, the receiving surface of the receiving portion may have a solid angle of <NUM> steradians or more.

In this manner, the surface of the head portion opposite from the shaft portion can be more stably supported by the receiving surface, and a pressing force can be reliably applied from the pressing member to the bone joining member. The solid angle of the receiving surface is more preferably 2π steradians or more so that no less than half of the outer surface of the head portion can be supported by the receiving surface.

The present invention affords advantageous effects in that compression force can be applied in both the bone radial direction and longitudinal axis direction so that close contact can be achieved between the bone and the bone joining member and between the osteotomy surfaces of the bone.

In the description below, a pressing tool <NUM> for bone surgery according to one embodiment of the present invention is described with reference to the drawings.

As illustrated in <FIG>, the pressing tool <NUM> for bone surgery according to this embodiment is used in a closed wedge high tibial osteotomy (CWHTO) which involves removing a bone block from the lateral side of the tibia X, closing the bone block excision site Y to correct deformation of the tibia X, and fixing the tibia X with a bone plate (bone joining member) <NUM>. In <FIG>, an example of a hybrid HTO which combines the closed wedge method and an open wedge method that involves forming an incision in the medial surface of the tibia X and expanding the incision is illustrated.

As illustrated in <FIG>, the bone plate <NUM> is a long strip-shaped member placed on a side surface of the tibia X so as to extend in a direction along the longitudinal axis of the tibia X. A plurality of screw holes 10a into which screws <NUM> for fixing the bone plate <NUM> to the tibia X are to be inserted are formed in the bone plate <NUM> so as to be spaced from one another in the longitudinal direction. Reference sign <NUM> denotes a drill sleeve.

As illustrated in <FIG>, the pressing tool <NUM> for bone surgery of this embodiment is equipped with a hook member <NUM> that engages with a side surface of the tibia X, and a pressing screw (pressing member) <NUM> that presses the bone plate <NUM> toward the side surface of the tibia X so as to apply a compression force to the tibia X and the bone plate <NUM>. The hook member <NUM> and the pressing screw <NUM> are formed of a high-strength metal such as titanium or stainless steel.

The hook member <NUM> includes a curved portion <NUM> that is curved to form a shape resembling a hook and that can engage with the side surface of the tibia X; a support portion <NUM> disposed at a first end of the curved portion <NUM> to support the pressing screw <NUM>; and a projection portion <NUM> disposed at a second end of the curved portion <NUM> and capable of being fixed to the side surface of the tibia X.

The curved portion <NUM> is formed of a long columnar member and is curved to form a shape resembling a hook so as to cover half around the side surface of the tibia X from the lateral side to the medial side of the tibia X. In a state in which the curved portion <NUM> is allowed to engage with the side surface of the tibia X along the circumferential direction, the support portion <NUM> is disposed on the lateral side of the tibia X, and the projection portion <NUM> is disposed on the medial side of the tibia X.

The support portion <NUM> has a cylindrical shape having a columnar screw hole 5a that penetrates through in the longitudinal direction and has thread grooves formed in the inner surface. The screw hole 5a extends along a line that connects the first end and the second end of the curved portion <NUM>, and the projection portion <NUM> is positioned on the extended line of a center axis (axis line) A of the screw hole 5a. The distance D between a middle portion between the first end and the second end of the curved portion <NUM> and the extended line of the center axis A of the screw hole 5a is preferably <NUM> or more and <NUM> or less so that when the curved portion <NUM> engages with a thick bone, such as the tibia X or the femur, the pressing screw <NUM> is positioned so as to be suitable for compressing the lateral surface of the bone.

The projection portion <NUM> projects from the second end of the curved portion <NUM> toward the support portion <NUM>. As illustrated in <FIG>, a V-shaped groove is formed at the center of the tip of the projection portion <NUM>, and, thus, the tip of the projection portion <NUM> has two pyramid-shaped projections 6a each having a pointed end 6b. The pointed ends 6b of the projections 6a are caused to bite into the side surface of the tibia X so that the projection portion <NUM> can be fixed relative to the tibia X.

The number of projections 6a formed at the tip of the projection portion <NUM> is not limited to <NUM> and may be <NUM> or <NUM> or more. For example, as illustrated in <FIG>, one relatively large projection 6a may be provided, or as illustrated in <FIG>, three or more circularly arranged projections 6a may be provided.

The pressing screw <NUM> has a straight, columnar shaft portion 3a and a substantially spherical head portion 3b disposed at one end of the shaft portion 3a. The surface of the head portion 3b opposite to the shaft portion 3a is a pressing surface 3c that applies a pressing force to the bone plate <NUM> when fitted into a screw hole 10a in the bone plate <NUM>. This surface is formed as a convex and substantially spherical surface.

The shaft portion 3a is a male thread with a screw thread formed in the side surface so that the shaft portion 3a can be fastened to the screw hole 5a in the support portion <NUM>, and is fastened to the screw hole 5a so that the pressing surface 3c of the head portion 3b faces the projection portion <NUM>. As the shaft portion 3a rotates about the center axis thereof, the pressing screw <NUM> moves along the center axis (axis line) of the screw hole 5a in the longitudinal direction, and the head portion 3b moves along the extended line of the center axis A of the screw hole 5a in a direction toward or away from the projection portion <NUM>.

Next, the effects of the pressing tool <NUM> for bone surgery having the aforementioned structure are described.

In order to treat knee osteoarthritis by the hybrid HTO technique using the pressing tool <NUM> for bone surgery of this embodiment, two incisions are formed from the upper lateral surface in the tibia X toward the medial side in directions oblique with respect to the longitudinal axis of the tibia X, and a bone block between two incisions is excised with a particular tool. Next, as illustrated in <FIG> and <FIG>, the bone plate <NUM> is placed on the lateral surface of the tibia X so as to bridge the bone block excision site Y, and an upper end portion of the bone plate <NUM> is fixed with the screws <NUM> to the tibia X at a position higher than the excision site Y.

Next, as illustrated in <FIG>, the curved portion <NUM> of the hook member <NUM> is allowed to engage with the side surface of the tibia X, and the projection portion <NUM> is fixed to the medial surface of the tibia X by allowing the pointed ends 6b of the projections 6a to bite into the medial surface of the tibia X. In addition, the support portion <NUM> supporting the pressing screw <NUM> is placed so that the bone plate <NUM> is sandwiched between the lateral surface of the tibia X and the support portion <NUM>.

Next, the pressing surface 3c of the head portion 3b is fitted into the screw hole 10a located on the lower side of the excision site Y, and the shaft portion 3a is rotated to advance the pressing screw <NUM> toward the bone plate <NUM>. As a result, the distance between the head portion 3b and the projection portion <NUM> is shortened, and the tibia X and the bone plate <NUM> sandwiched between the head portion 3b and the projection portion <NUM> are compressed by the head portion 3b and the projection portion <NUM> and move close to each other. At this stage, since the projection portion <NUM> is located on the extended line of the center axis A of the screw hole 5a in which the pressing screw <NUM> moves, only a compression force working in the center axis A direction of the screw hole 5a, which is the direction in which the pressing screw <NUM> moves, is applied to the tibia X and the bone plate <NUM>, and the tibia X and the bone plate <NUM> move only in the center axis A direction.

As illustrated in <FIG>, after the shaft portion 3a has been rotated until the bone plate <NUM> is in close contact with the lateral surface of the tibia X, the screws <NUM> are inserted into the rest of the screw holes 10a in the bone plate <NUM> to fix the bone plate <NUM> to the tibia X.

In this case, when aligning the tibia X and the bone plate <NUM>, as illustrated in <FIG>, two portions, X1 and X2, of the tibia X respectively located on the higher side and the lower side of the excision site Y of the tibia X must be aligned so that the two osteotomy surfaces Y1 and Y2 at the excision site Y of the tibia X come into close contact with each other. In other words, a compression force in the longitudinal axis direction must be applied to the tibia X so that the higher portion X1 and the lower portion X2 are drawn toward each other.

According to this embodiment, as described above, the direction of the compression force applied to the tibia X and the bone plate <NUM> is coincident with the center axis A direction of the screw hole 5a; thus, as illustrated in <FIG>, the direction of the compression force can be easily controlled to a desired direction by adjusting the inclination angle of the center axis A of the screw hole 5a with respect to the longitudinal axis of the tibia X.

In other words, by placing the hook member <NUM> so that the center axis A of the screw hole 5a is inclined with respect to the longitudinal axis of the tibia X, a compression force in a direction oblique to the longitudinal axis of the tibia X is applied to the tibia X and the bone plate <NUM> so that a compression force in the tibia X radial direction that draws the tibia X and the bone plate <NUM> close to each other can be generated, and, at the same time, a compression force in the longitudinal axis direction, which is the direction in which the higher portion X1 and the lower portion X2 of the tibia X are drawn toward each other, can be generated. Increasing the inclination angle of the center axis A of the screw hole 5a with respect to the longitudinal axis of the tibia X increases the compression force in the longitudinal axis direction. As such, there is an advantage in that, by applying a compression force in both the direction in which the tibia X and the bone plate <NUM> are drawn close to each other and the direction in which the osteotomy surfaces Y1 and Y2 are drawn close to each other, the relative position between the three parts, i.e., the higher portion X1 and the lower portion X2 of the tibia X and the bone plate <NUM>, can be adjusted so as to eliminate the gap between the osteotomy surfaces Y1 and Y2.

Moreover, the direction of the compression force can be changed merely by temporarily detaching the pointed ends 6b biting into the tibia X from the tibia X, then shifting the position of the projection portion <NUM> in the tibia X longitudinal axis direction, and then allowing the pointed ends 6b to again bite into the tibia X. During this process, since the pressing surface 3c of the head portion 3b is spherical, the position of the projection portion <NUM> can be easily shifted by using the head portion 3b as the supporting point and by rotating the head portion 3b in the screw hole 10a. As such, there is an advantage in that the direction of the compression force applied to the tibia X and the bone plate <NUM> can be easily changed.

Also, there is an advantage in that if alignment of the higher portion X1 and the lower portion X2 of the tibia X and the bone plate <NUM> was not successfully carried out in the first attempt, the compressing operation can be easily repeated by rotating the shaft portion 3a in the opposite direction to retract the pressing screw <NUM> to the side opposite from the bone plate <NUM>.

In this embodiment, as illustrated in <FIG>, a through hole 3d through which a guide pin <NUM> can pass may be formed in the pressing screw <NUM> so as to pass therethrough along the center axis of the shaft portion 3a so that the pressing tool <NUM> for bone surgery can be used in combination with the guide pin <NUM> of the screw <NUM>. Considering the diameter of the guide pin <NUM> typically used in HTO, the diameter of the through hole 3d is preferably <NUM> or more.

In this manner, since the pressing screw <NUM> is guided along the guide pin <NUM> inserted into the through hole 3d, the position and the orientation of the pressing screw <NUM> with respect to the tibia X and the bone plate <NUM> can be stabilized.

Furthermore, as illustrated in <FIG>, a slit 2a for inserting and removing the guide pin <NUM> into and from inside the support portion <NUM> in the radial direction is formed in the hook member <NUM>. The slit 2a extends from the outer circumferential surface to the inner circumferential surface of the support portion <NUM> so that the interior of the screw hole 5a communicates with the exterior of the support portion <NUM>, and is formed throughout the entire length in the longitudinal direction.

According to the hook member <NUM> having this slit 2a, after the guide pin <NUM> is inserted into the tibia X, the guide pin <NUM> is inserted into the support portion <NUM> through the slit 2a, and thus the hook member <NUM> can be easily installed with respect to the tibia X and the bone plate <NUM>.

As illustrated in <FIG>, the slit 2a may be formed so that the guide pin <NUM> is inserted into and removed from the screw hole 5a via the curved portion <NUM>. In other words, the slit 2a may be formed throughout the entire length from the tip of the projection portion <NUM> to the screw hole 5a so as to halve the curved portion <NUM> and the projection portion <NUM>.

In this embodiment, the head portion 3b of the pressing screw <NUM> is directly fitted into the screw hole 10a of the bone plate <NUM>; alternatively, as illustrated in <FIG>, a plug <NUM> that can be attached to the screw hole 10a and supports the head portion 3b may be further provided.

As illustrated in <FIG>, the plug <NUM> is equipped with a connecting portion 7a formed of a male thread that can be fastened to the screw hole 10a in the bone plate <NUM>, and a receiving portion 7b that is disposed at one end of the connecting portion 7a and receives the head portion 3b. On the opposite side of the connecting portion 7a, the receiving portion 7b has a receiving surface 7c which is a concave and substantially spherical surface complementary to the substantially spherical pressing surface 3c of the head portion 3b and which supports the pressing surface 3c.

The compression force can be efficiently transmitted to the bone plate <NUM> from the pressing surface 3c of the head portion 3b via the receiving surface 7c by fitting the head portion 3b to the receiving surface 7c of the plug <NUM>, the connecting portion 7a of which is attached to the screw hole 10a in the bone plate <NUM>.

The solid angle of the receiving surface 7c is preferably <NUM> steradians or more and more preferably 2π steradians or more. In this manner, the pressing surface 3c of the head portion 3b can be stably supported by the receiving surface 7c, and when the head portion 3b is rotated within the receiving surface 7c to adjust the direction of the compression force, displacement of the head portion 3b from the receiving surface 7c can be prevented.

The shape of the receiving surface 7c is not limited to the concave spherical surface, and may be any other shape externally tangential to the pressing surface 3c of the head portion 3b, for example, a polygonal shape.

To enable use of the plug <NUM> in combination with the guide pin <NUM>, a through hole 7d through which a guide pin <NUM> can pass may be formed in the plug <NUM>. The through hole 7d penetrates through the plug <NUM> along the center axis of the connecting portion 7a and opens at the center of the receiving surface 7c. The diameter of the through hole 7d is preferably <NUM> or more as with the diameter of the through hole 3d of the pressing screw <NUM>.

In this manner, the screw hole 10a and the guide pin <NUM> passing through the through holes 7d and 3d can further stabilize the positions of the bone plate <NUM>, the plug <NUM>, and the pressing screw <NUM> relative to the tibia X.

In this embodiment, the projection portion <NUM> is positioned on the extended line of the center axis A of the screw hole 5a; alternatively, as illustrated in <FIG>, the position of the projection portion <NUM> may be offset from the extended line of the center axis A of the screw hole 5a in a direction intersecting the extended line.

In this case, a moment in a direction opposite to the offset direction of the projection portion <NUM> intersecting the center axis A of the screw hole 5a acts on the bone plate <NUM>. Due to this moment, the bone plate <NUM> can also be moved in the bone plate <NUM> width direction with respect to the tibia X to adjust the position of the bone plate <NUM>.

In this embodiment, physical power of the user is used as the driving force for advancing and retracting the pressing screw <NUM>; alternatively, the pressing screw <NUM> may be moved by using oil pressure or water pressure, or by using an electric motor.

Moreover, in this embodiment, the pressing screw <NUM> is used as the pressing member for pushing the bone plate <NUM> and generating a compression force; alternatively, a different pressing member may be used. For example, as illustrated in <FIG>, a pressing member <NUM> may be equipped with a shaft portion 31a having a smooth side surface instead of the male thread 3a. In this case, a support portion <NUM> may have, instead of the screw hole 5a, a guide hole 51a which has a smooth inner surface and into which the shaft portion 31a of the pressing member fits so as to be movable in the longitudinal direction. The shaft portion 31a may be driven by using a tool that converts a particular motion of the user into a motion in the longitudinal direction of the shaft portion 31a.

For example, as illustrated in <FIG>, a tool <NUM> that converts a rocking motion of a grip 50a that occurs when the user grasps the grip 50a, into a motion in the longitudinal direction of the shaft portion 31a may be used. The structure is preferably configured so that the following relationship is established between the force Fi the user applies to the grip 50a and the force Fo acting on the pressing member <NUM>.

In other words, the tool <NUM> is preferably configured to amplify the force Fi applied to the grip 50a and transmit the amplified force to the pressing member <NUM>.

Claim 1:
A pressing tool (<NUM>) for bone surgery, comprising:
a pressing member (<NUM>) formed in a columnar shape shaft along a longitudinal axis having, at one end, a pressing surface (3c) formed of a convex and spherical surface and a male thread extending from the pressing surface (3c) in a longitudinal direction; and
a hook member (<NUM>) that has a curved portion (<NUM>) being curved to form a hook shape configured to cover half around a side surface of a bone and to engage with the side surface of the bone, the hook member having a cylindrical support portion (<NUM>) provided at a first end of the curved portion (<NUM>) configured to support the pressing member (<NUM>) so that the pressing surface (3c) is directed toward a second end of the curved portion (<NUM>), the hook member having a projection portion (<NUM>) at the second end, the projection portion (<NUM>) projecting toward the support portion (<NUM>) and being configured to bite into the side surface of the bone,
wherein the support portion (<NUM>) has a screw hole (5a) extending in the longitudinal direction and supports the pressing member (<NUM>) in state of the pressing member (<NUM>) is movable in the longitudinal direction toward the projection portion (<NUM>) by the male thread being fastened to the screw hole (5a),
wherein the support portion (<NUM>) has a slit (2a) that extends from an outer circumferential surface to an inner circumferential surface of the support portion (<NUM>) so that an interior of the screw hole (5a) communicates with an exterior of the support portion (<NUM>) in a radial direction of the screw hole (5a), the slit (2a) being formed throughout an entire length of the support portion (<NUM>) in the longitudinal direction, and
wherein a guide pin (<NUM>) is inserted into the support portion (<NUM>) in the radial direction through the slit (2a).