JP6464218B2 - Bone retainer and osteosynthesis reinforcement provided with the same - Google Patents

Description

  The present invention relates to a bone retainer for holding a bone in a state in which the joint of a fractured bone is reinforced, and an osteosynthesis reinforcement provided with the same.

Conventionally, for treatment of a femoral neck fracture or the like, a fractured portion is fixed and reinforced by installing an osteosynthesis reinforcing tool on the bone (for example, Patent Document 1).
Generally, this osteosynthesis reinforcing tool includes a fixed main body portion embedded in the diaphysis portion and a screw portion that is inserted through the fixed main body portion. Then, with the fixed main body portion buried in the diaphysis, the screw portion is inserted obliquely upward from the side of the diaphysis to the bone head, and the screw portion is inserted into the fixed main body portion. Furthermore, with the tip of the screw part inserted to a predetermined position in the bone head, the fixing main body part and the screw part are fixed. Thereby, joining of a bone head and a diaphysis part is reinforced.

JP 2013-252404 A

  However, although the above-mentioned osteosynthesis reinforcement device can reinforce the joint between the bone head and the diaphysis, there is a problem that it cannot reinforce a fracture such as a greater trochanter. .

  The present invention has been made to solve such a problem, and a bone holder that can easily reinforce the joining of a plurality of fractured parts and adjust the reinforcing position thereof, and a bone joining reinforcing tool including the same. The purpose is to provide.

In order to solve the above problems, the present invention provides the following means.
The present invention relates to a bone retainer that holds the bone by being connected to a main body reinforcing tool that reinforces the joining of fractured bones, and is an annular connection that is concentrically connected to an annular fixing portion of the main body reinforcing tool. And a support portion that extends from the connecting portion and holds the bone, and one edge of the connecting portion has a rotational position around the axis of the connecting portion with respect to the annular fixing portion. Complementary shape that can be changed in stages.

  Moreover, the one edge part of the said connection part may carry out uneven fitting with respect to the said annular fixed part so that the fitting position in the circumferential direction of the said connection part can be changed.

  Further, saw teeth that are concavo-convexly fitted to each other may be formed on one edge portion of the connecting portion and the annular fixing portion.

  Moreover, the one edge part of the said connection part and the sawtooth of the said annular fixing part may comprise the mountain shape which continued in the said circumferential direction.

  In addition, the auxiliary holding portion is connected to the body reinforcing tool and holds a portion different from the bone portion held by the support portion, and the auxiliary holding portion is concentric with the other edge of the connecting portion. And an annular auxiliary connecting portion connected to the main body reinforcing tool, wherein one edge of the auxiliary connecting portion has a rotational position around the axis with respect to the other edge of the connecting portion. It may have a complementary shape that can be changed in stages.

  Moreover, you may provide the bone | frame holder as described in any one of Claims 1-5, and the said main body reinforcement tool.

  According to the present invention, it is possible to easily reinforce the joining of a plurality of broken sites and adjust the reinforcing position.

It is a front view which shows the bone holder and osteosynthesis reinforcement as embodiment of this invention. It is explanatory drawing which decomposes | disassembles and shows the osteosynthesis reinforcement tool of FIG. It is a perspective view which shows the main holding part of FIG. It is a figure which shows a mode that the main holding | maintenance part of FIG. 3 was seen from the side, Comprising: It is explanatory drawing which shows a mode that a holding | maintenance part rotates. It is a perspective view which shows the holding | maintenance part of FIG. It is a top view which shows a mode that the auxiliary | assistant holding | maintenance part of FIG. 2 was seen from the axial direction of the auxiliary | assistant connection part. It is a side view of the auxiliary | assistant holding | maintenance part of FIG. It is explanatory drawing which shows a mode that the main body reinforcement tool was embedded in the inside of a bone, and the main holding part and the auxiliary holding part were distribute | arranged to the vicinity of the greater trochanter part. It is explanatory drawing which shows a mode that the holding | maintenance part of FIG. 8 is rotated and the large trochanter part is hold | maintained. It is explanatory drawing which shows a mode that the osteosynthesis reinforcement tool of FIG. 8 was seen from another angle. It is explanatory drawing which shows a mode that the auxiliary | assistant support part of FIG. 10 is rotated and the other position of the greater trochanter part is hold | maintained.

(Embodiment)
Hereinafter, the bone retainer and the osteosynthesis reinforcement in the embodiment of the present invention will be described.
FIG. 1 is a front view showing an osteosynthesis reinforcement 1 and a bone holder 5.
The bone cement reinforcing tool 1 includes a main body reinforcing tool 2 embedded in a bone and a bone holder 5 connected to the main body reinforcing tool 2.
The main body reinforcing tool 2 includes a cylindrical main body portion 21 extending in a long shape. The cylindrical main body 21 is formed in a cylindrical shape. As shown in FIG. 2, an annular fixing portion 21c is detachably provided at the proximal end portion of the cylindrical main body portion 21 via an insertion portion 21b. The insertion portion 21b is elongated. And the insertion part 21b is inserted in the inside of the cylindrical main-body part 21. As shown in FIG. The annular fixing portion 21c is formed in an annular shape. A mountain-shaped saw tooth 211c that is continuous over the entire length in the circumferential direction is formed at the upper edge of the annular fixing portion 21c.

Further, the cylindrical main body portion 21 is provided with a through hole 21a directed in a direction crossing the axial direction. A columnar screw portion 22 is inserted into the through-hole 21a so as to be obliquely upward with respect to the cylindrical main body portion 21. A male screw portion 23 is formed at the tip of the screw portion 22.
Under such a configuration, when the screw portion 22 is inserted into the cylindrical main body portion 21 through the through-hole 21a, the screw of the unillustrated screw is tightened to form the insertion portion 21b inside the cylindrical main body portion 21. The distal end abuts on the screw part 22, and the screw part 22 is fixed to the cylindrical main body part 21.

The bone holder 5 includes a main holding part 3 connected to the annular fixing part 21 c and an auxiliary holding part 4 connected to the main holding part 3.
As shown in FIG. 3, the main holding part 3 includes an annular connecting part 31 (connecting part) formed in an annular shape and a support part 32 extended from the annular connecting part 31.
On one edge of the annular connecting portion 31, a mountain-shaped saw tooth 31 a that is continuous over the entire length in the circumferential direction is formed. The saw teeth 31a have a complementary shape to the saw teeth 211c (shown in FIG. 2), are arranged concentrically with each other, and are engaged with each other over the entire length in the circumferential direction. And even if the annular connecting portion 31 is rotated around the axis A of the annular connecting portion 31 with respect to the annular fixing portion 21c, the saw tooth 31a and the saw tooth 211c can be concavo-convexly fitted. Also in the position, the rotational position of the annular connecting portion 31 is regulated. In other words, the rotational position of the annular coupling portion 31 with respect to the annular fixing portion 21c is changed stepwise by shifting the concave-convex fitting between the saw tooth 31a and the saw tooth 211c in the circumferential direction, thereby changing the annular coupling portion 31 to the annular fixing portion. It can be fixed to 21c.
A similar saw tooth 31 b is also formed on the other edge of the annular connecting portion 31.

The support portion 32 is fixedly extended from the annular coupling portion 31. The term “fixed” refers to being fixedly connected to the annular connecting portion 31 without being movable with respect to the annular connecting portion 31. For example, it is formed integrally with the annular connecting portion 31.
The support portion 32 includes a plate-like support substrate portion 32a that is integrally extended from the annular coupling portion 31, and a plate-like support body portion 32b that is integrally extended with the support substrate portion 32a. .
The support substrate portion 32a extends from the annular coupling portion 31 outward in the radial direction E, and is formed in a rectangular plate shape. The support main body portion 32b is extended from the tip of the support substrate portion 32a in the radial direction E.
The support substrate portion 32a and the support main body portion 32b are integrally formed in a gentle R shape.

As shown in FIG. 4, the support main body portion 32 b extends from the tip of the support substrate portion 32 a over a region Ed in the axis A direction. Here, a region in the radial direction E of the annular coupling portion 31 is defined as a radial region Em, and a region in the lower direction (one direction) in the axis A direction from the radial region Em is defined as one region Ed. Further, an area in the upper direction (other direction) in the direction of the axis A from the radial direction area Em is set as another area Eu.
The support main body portion 32b extends from the tip of the support substrate portion 32a in an inclined manner over a region Ed in the axis A direction. That is, the support main body 32b is inclined at an angle θ1 with respect to the axis A so that the distance from the axis A gradually increases from the base end 32e to the tip 32f of the support main body 32b. ing.
The support main body 32b is convexly curved toward the surface 32A (outward in the radial direction E) from the base end 32e to the tip 32f. Further, the support main body portion 32b is curved to protrude toward the surface 32A over the entire length in the width direction Wa (shown in FIG. 3). The width direction Wa refers to the direction in which the surface 32A extends among the directions orthogonal to the direction extending from the base end portion 32e to the distal end portion 32f, and the radial direction in which the axis A direction and the support substrate portion 32a extend. A direction perpendicular to E.

Further, the width dimension W1 of the base end portion 32e is smaller than the width dimension W2 of the tip end portion 32f. Further, the leading edge of the support main body 32b is gradually tapered.
Further, a through hole 32c is formed in the support main body 32b so as to penetrate along the axis A from the front surface 32A to the back surface 32B. A female screw portion (not shown) is formed on the inner wall of the through hole 32c. A screw N is tightened in the through hole 32c from the front surface 32A toward the back surface 32B. When the screw N passes through the through hole 32c through a female screw portion (not shown), the tip of the screw N protrudes from the back surface 32B along the direction of the axis A.
In addition, a rectangular protruding portion 32g (protruding portion) that extends from the base end portion 32e to the distal end portion 32f in the center of the width direction Wa of the back surface 32B is provided. The rectangular protrusion 32g protrudes in a rectangular shape with respect to the back surface 32B. And the protrusion dimension with respect to the back surface 32B of the rectangular protrusion part 32g becomes small gradually as it goes to the front-end | tip part 32f from the base end part 32e.
Further, a recess (not shown) extending in the width direction Wa is provided on the back surface 32B of the tip 32f. And in this recessed part, the rotating shaft part 32d extended in the width direction Wa is provided.

Further, the holding portion 33 is rotatably connected to the rotation shaft portion 32d.
The holding portion 33 includes a plate-like holding extension portion 33a (extension portion) that extends outward in the radial direction of the rotation shaft portion 32d. The holding extension portion 33a is convexly curved toward the surface 33A side (the support main body portion 32b side) from the base end portion 33f to the tip end portion 33g. Furthermore, the holding extension portion 33a is curved to protrude toward the surface 33A over the entire length in the width direction Wb. The width direction Wb refers to the direction of the axis G of the rotation shaft portion 32d, and refers to a direction orthogonal to the direction of the axis A and the radial direction E of the support substrate portion 32a.

Further, the width dimension W4 of the distal end portion 33g is smaller than the width dimension W5 of the proximal end portion 33f. Furthermore, the most proximal end of the holding extension 33a is gradually tapered.
In addition, a long groove 33d extending from the base end portion 33f of the holding extension portion 33a to the tip end edge portion 33h is formed on the surface 33A. The long groove 33d is immersed in a rectangular shape from the base end portion 33f to the distal end edge portion 33h at the center in the width direction Wb. The depth dimension of the long groove 33d gradually increases from the proximal end portion 33f to the distal end edge portion 33h.
The tip end portion 33g of the holding extension portion 33a is a pair of holding tip portions 33e provided in the width direction Wb with the long groove 33d interposed therebetween. The holding tip 33e is formed in a rectangular shape. On the back surface 33B of the holding distal end portion 33e, claw portions 33c that are folded back toward the base end portion 33f are provided.
In addition, a cylindrical rotation coupling portion 33b is provided at the most proximal end of the proximal end portion 33f. The rotation connecting portion 33b is provided offset on the surface 33A of the base end portion 33f. The axis of the rotation connecting portion 33b is directed in the width direction Wb, and the width dimension W6 of the rotation connecting portion 33b is smaller than the width dimension W5.

  With such a configuration, the rotation connecting portion 33b is fitted to the rotation shaft portion 32d, and as shown in FIG. 4, on the back surface 32B side of the support main body portion 32b, the holding portion 33 with the axis G as the rotation center. However, it rotates in the direction approaching / separating from the back surface 32B. That is, the holding portion 33 is connected to the support main body portion 32b so as to be openable and closable on the back surface 32B side. The rotating shaft portion 32d is provided with a spring (not shown), and the holding portion 33 is urged in a direction approaching the back surface 32B side. And when the holding | maintenance part 33 is closed with respect to the support main-body part 32b, the rectangular protrusion part 32g is fitted by the long groove 33d, and the holding | maintenance part 33 is the back surface 32B side in the state by which 33 A of front surfaces were distribute | arranged along the back surface 32B. Is to be housed.

6 and 7 show the auxiliary holding part 4.
The auxiliary holding part 4 includes an auxiliary connection part 41 formed in an annular shape and an auxiliary support part 42 extended from the auxiliary connection part 41.
On one edge portion of the auxiliary connecting portion 41, a mountain-shaped saw tooth 41a that is continuous over the entire length in the circumferential direction is formed. The saw teeth 41a have a complementary shape to the saw teeth 31b (shown in FIG. 2) of the main holding portion 3, and are arranged concentrically with each other so as to be concavo-convexly fitted over the entire length in the circumferential direction. Even if the auxiliary connecting portion 41 is rotated around the axis A with respect to the annular connecting portion 31, the saw tooth 41a and the saw tooth 31b can be concavo-convexly fitted, and the auxiliary connecting portion can be connected at any position in the circumferential direction. The rotational position of the part 41 is regulated. That is, the rotational position of the auxiliary connecting portion 41 with respect to the annular connecting portion 31c is changed stepwise by shifting the concave-convex fitting between the saw tooth 41a and the saw tooth 31b in the circumferential direction, thereby changing the auxiliary connecting portion 41 to the annular connecting portion. 31 can be fixed.

The auxiliary support portion 42 is fixedly extended from the auxiliary connecting portion 41.
The auxiliary support portion 42 includes a plate-like auxiliary substrate portion 42a that is integrally extended from the auxiliary connecting portion 41, and a plate-like auxiliary main body portion 42b that is integrally extended from the auxiliary substrate portion 42a. Yes.
The auxiliary board portion 42a extends outward in the radial direction E from the auxiliary connecting portion 41, and is formed in a rectangular plate shape. In addition, the auxiliary board portion 42 a is provided offset to the claw portion 42 h side described later in the tangential direction S of the auxiliary connecting portion 41. That is, the virtual imaginary line Ea through which the virtual center line K of the auxiliary board portion 42a that passes through the center point K1 of the auxiliary board portion 42a in the tangential direction S and is directed in the extending direction of the auxiliary board portion 42a passes through the axis A. On the other hand, it is shifted parallel to the claw portion 42h side in the tangential direction S.

An auxiliary main body portion 42b extends from the tip of the auxiliary substrate portion 42a in the radial direction E.
The auxiliary board portion 42a and the auxiliary main body portion 42b are connected in an integral manner with a gentle R shape.
The auxiliary main body portion 42b extends from the tip of the auxiliary substrate portion 42a in an inclined manner over a region Ed in the axis A direction. That is, the auxiliary main body portion 42b is inclined at an angle θ2 with respect to the axis A so that the distance dimension from the axis A gradually increases as it goes from the base end portion 42f of the auxiliary main body portion 42b to the tip end portion 42g. ing.
Further, the auxiliary main body 42b is convexly curved toward the surface 42A over the entire length in the width direction Wc. The width direction Wc refers to the direction in which the surface 42A extends among the directions orthogonal to the direction extending from the base end portion 42f to the tip end portion 42g. The width direction Wc is orthogonal to the axis A direction and intersects the radial direction E in which the auxiliary substrate portion 42a extends. That is, the width direction Wc intersects the radial direction E in which the auxiliary substrate portion 42a extends at an angle θ3 so that the claw portion 42h side approaches the axis A. The angle θ3 is smaller than 90 °. That is, the auxiliary main body portion 42b is connected to the auxiliary substrate portion 42a at one end in the width direction Wc, and the claw portion 42h is provided at the other end in the width direction Wc. Is smaller than the distance between the one end in the width direction Wc and the axis A. In other words, the auxiliary main body portion 42b is twisted so that the other end in the width direction Wc is closer to the auxiliary connecting portion 41 than the one end when viewed from the direction of the axis A.

The claw portion 42h is separated into a plurality in the direction extending from the base end portion 42f of the auxiliary substrate portion 42a to the tip end portion 42g. That is, a plurality of claw portions 42h protrude from one end to the other end in the width direction Wc.
The claw portion 42h includes a plurality of arm portions 42d and auxiliary claw portions 42c that are folded back to the back surface 42B at the tips of the arm portions 42d.
The arm part 42d is convexly curved toward the surface 42A. A through hole 42e that penetrates in the direction extending from the base end part 42f to the tip end part 42g is formed at the tip end part of the arm part 42d. Thus, a wire (not shown) is passed from the uppermost through hole 42e to the lowermost through hole 42e.

Next, a method of using the osteosynthesis reinforcement 1 and the bone holder 5 will be described.
Here, for example, treatment of a femoral neck fracture will be described.
First, as shown in FIG. 2, the insertion part 21b is inserted into the cylindrical main body part 21, and the annular fixing part 21c is tightened. And the main holding | maintenance part 3 is connected with the cyclic | annular fixing | fixed part 21c. That is, the saw tooth 31a is concavo-convexly fitted to the saw tooth 211c. At this time, the rotational position of the annular connecting portion 31 around the axis A is adjusted so that the support portion 32 is arranged in the direction in which the through hole 21a is directed. At this time, the holding portion 33 is accommodated on the back surface 32B side of the support main body portion 32b.
Further, the auxiliary holding part 4 is connected to the main holding part 3. That is, the sawtooth 41a is concavo-convexly fitted to the sawtooth 31b. Thereby, the annular fixing portion 21c, the annular coupling portion 31, and the auxiliary coupling portion 41 are arranged concentrically with the axis A as the center. Then, the rotational position of the auxiliary connecting portion 41 around the axis A is adjusted so that the auxiliary support portion 42 is arranged in a direction intersecting the direction in which the through hole 21a is directed.

From this state, as shown in FIG. 8, the skin on the side above the thigh is incised, and the cylindrical main body 21 is screwed from above the diaphysis Bs. And it screws in until the base end part of the cylindrical main-body part 21 will be in the state protruded from the upper direction of the diaphysis Bs. At this time, the holding part 33 is not in contact with the greater trochanter part Bu.
Further, the screw part 22 is screwed obliquely upward from the side of the skin toward the bone head Bf. That is, the screw portion 22 is screwed through the through-hole 21a and fed until the male screw portion 23 is arranged at a predetermined position in the bone head Bf. When the annular fixing portion 21 c is tightened from this state, the insertion portion 21 b moves toward the tip inside the cylindrical main body portion 21. Then, the distal end of the insertion portion 21 b comes into contact with the outer wall of the screw portion 22, and the screw portion 22 is fixed to the cylindrical main body portion 21. Thereby, joining of bone head Bf and diaphysis Bs is reinforced.

Further, in the vicinity of the top Bu1 of the greater trochanter bu, the annular connecting portion 31 is rotated around the axis A so that the support main body 32b is disposed at a position where the joining is to be reinforced, and the rotational position is adjusted. .
Then, the screw N is tightened in the through hole 32c. The screw N passes through the through hole 32c and protrudes from the back surface 32B of the support main body portion 32b. And the front-end | tip of the screw | thread N contact | abuts to the surface 33A of the holding | maintenance part 33, and pushes the holding | maintenance part 33 below in the axis line A direction. Thereby, the holding | maintenance part 33 rotates in the direction spaced apart with respect to the back surface 32B centering on the axis line G. FIG. That is, as shown in FIG. 9, the holding part 33 opens with respect to the back surface 32B. Further, as the screw N is tightened, the holding portion 33 opens, and the claw portion 33c comes into contact with the vicinity of the top portion Bu1 of the greater trochanter portion Bu via the muscle, and presses the vicinity of the top portion Bu1. Go. When the tightening of the screw N is stopped, the holding portion 33 is fixed in a state where the claw portion 33c presses the vicinity of the top portion Bu1. Thereby, the joint in the vicinity of the top Bu1 is reinforced.

Further, as shown in FIG. 10, the auxiliary connecting portion 41 is arranged so that the auxiliary main body portion 42 b is arranged on the bone head Bf side of the front portion of the greater trochanter portion Bu than the reinforcing position Bu2 where the joining is to be reinforced. Rotate around axis A and adjust its rotational position.
And the auxiliary | assistant connection part 41 is rotated to the surroundings of the axis line A in the direction which the auxiliary | assistant main-body part 42b leaves | separates from the bone head Bf. Then, the auxiliary claw portion 42c comes into contact with the vicinity of the reinforcing position Bu2 through the muscle. Further, when the auxiliary connecting portion 41 is rotated around the axis A in the same direction, as shown in FIG. 11, the auxiliary main body portion 42b is arranged at the reinforcing position Bu2 while the auxiliary claw portion 42c pulls the muscle. Then, when the rotation of the auxiliary connecting portion 41 is stopped, the rotation is restricted at that position and the auxiliary main body portion 42b is fixed by the concave and convex fitting between the saw tooth 41a and the saw tooth 31b. Thereby, joining of reinforcement position Bu2 is reinforced. If necessary, the auxiliary connecting portion 41 may be fixed to the reinforcing position Bu2 by passing a wire (not shown) over the plurality of through holes 42e and winding the wire around the diaphyseal portion Bs or the like.

As described above, according to the bone joining reinforcing tool 1 and the bone holding tool 5 in the present embodiment, the holding part 33 holds the vicinity of the top part Bu1 of the greater trochanter part Bu in a state of being connected to the main body reinforcing tool 2. Therefore, not only the joint of the bone head Bf and the diaphysis Bs but also the joint of the top Bu1 can be reinforced.
For this reason, it is possible to easily reinforce the joining of a plurality of broken sites.
In addition, since the support portion 32 is fixed to the annular coupling portion 31 and the holding portion 33 rotates to the back surface 32B side of the support portion 32, the osteosynthesis 1 is attached to the diaphyseal portion while reducing skin incision. In addition to being easily fixed to Bs, the support force of the support portion 32 can be further reinforced.

Further, since the rotation shaft portion 32d is provided at the distal end portion 32f of the support main body portion 32b and the holding extension portion 33a is provided, the bone can be held over the entire back surface 32B of the holding extension portion 33a. it can. Moreover, since the nail | claw part 33c is provided in the front-end | tip part 33g of the holding | maintenance extension part 33a, a bone can be hold | maintained via a muscle.
Further, since the long groove 33d is provided in the holding extension portion 33a, the rigidity of the holding extension portion 33a can be increased, and the bone joint can be reinforced over a long period of time.
In addition, since the support body 32b is provided with the rectangular protrusion 32g, not only can the rigidity of the support body 32b be increased, but the holding protrusion can be obtained by fitting the rectangular protrusion 32g into the long groove 33d. 33 can be accommodated on the back surface 32B side of the support main body 32b, and the space can be reduced.
Further, since the support main body portion 32b is inclined at an angle θ1, the space of the support portion 32 can be reduced.

Moreover, since the holding | maintenance front-end | tip part 33e is provided in the front-end | tip part 33g of the holding | maintenance extension part 33a, and the nail | claw part 33c is each provided in these holding | maintenance front-end | tip parts 33e, the contact with respect to the muscle of the nail | claw part 33c is carried out locally. It is possible to increase the reinforcing force of osteosynthesis.
Further, since the support main body portion 32b is curved outward from the base end portion 32e to the distal end portion 32f, the rigidity of the support main body portion 32b can be increased. Furthermore, since the support main body 32b is curved outward in the width direction Wa, the rigidity can be further increased.
Further, since the holding extension portion 33a is curved outward from the base end portion 33f to the tip end portion 33g, the rigidity of the holding extension portion 33a can be increased. Furthermore, since the holding extension 33a is curved outward in the width direction Wb, the rigidity can be further increased.
Further, since the auxiliary main body portion 42b is curved outward in the width direction Wc, the rigidity of the auxiliary main body portion 42b can be increased.

Moreover, since the width dimension W1 of the base end part 32e of the support main body part 32b is smaller than the width dimension W2 of the front end part 32f, the rigidity of the front end part 32f of the support main body part 32b can be increased. Furthermore, since the tip of the support main body 32b is tapered, the osteosynthesis reinforcing tool 1 can be easily placed in the body.
Further, since the rotation shaft portion 32d is provided on the back surface 32B side and the rotation connecting portion 33b is provided offset to the front surface 32A, the holding portion 33 can be accommodated compactly on the back surface 32B side.
Moreover, since the width dimension W4 of the front-end | tip part 33g of the holding | maintenance extension part 33a is smaller than the width dimension W5 of the base end part 33f, the rigidity of the base end part 33f can be improved. Further, since the width dimension W6 of the rotation connecting portion 33b is smaller than the width dimension W5, the contact area with the rotation shaft portion 32d can be reduced, and the holding extension portion 33a can be easily rotated. it can.
Further, the depth dimension of the long groove 33d is gradually increased from the base end part 33f to the tip end edge part 33h, and the protrusion dimension of the rectangular protrusion part 32g with respect to the back surface 32B is gradually decreased from the base end part 32e to the tip end part 32f. Therefore, the holding portion 33 can be accommodated compactly on the back surface 32B side of the support main body portion 32b.

Further, since the auxiliary holding part 4 is provided, it is possible to further reinforce the joining of a plurality of parts.
Further, since the saw teeth 211c, 31a, 31b, and 41a are concavo-convexly fitted, the rotational positions around the axis A of the annular connecting portion 31 and the auxiliary connecting portion 41 can be easily changed step by step, and the support portion 32. And the arrangement | positioning of the auxiliary | assistant support part 42 can be adjusted easily according to a condition.
Further, since the claw portion 42h is divided into a plurality of parts in the direction extending from the base end portion 42f to the distal end portion 42g of the auxiliary substrate portion 42a, the contact of the claw portion 42h with the muscle is locally performed to reinforce the bone joint. Not only can the force be increased, but also the auxiliary support portion 42 can be easily visually confirmed in the X-ray irradiation image.

Further, since the auxiliary main body portion 42b is fixed to the auxiliary substrate portion 42a, it is possible to increase the reinforcing force for osteosynthesis.
Further, as shown in FIG. 6, since the auxiliary board portion 42a is offset toward the claw portion 42h in the tangential direction S, the rigidity of the auxiliary main body portion 42b can be increased. That is, in order for the auxiliary claw portion 42c to effectively involve the muscle, a predetermined width dimension in the width direction Wc of the auxiliary main body portion 42b is required, but the auxiliary substrate portion 42a is located on the side of the claw portion 42h. Therefore, the auxiliary claw portion 42c can effectively reduce the width of the auxiliary main body portion 42b while effectively wrapping the muscle.
Further, since the auxiliary main body portion 42b is twisted so that the other end in the width direction Wc is closer to the auxiliary connecting portion 41 than one end when viewed from the direction of the axis A, the reinforcement of the bone joint is performed in a state where the muscle is involved. The power can be increased.

Further, since the auxiliary main body portion 42b is inclined at an angle θ2, the space for the auxiliary support portion 42 can be reduced.
Further, since the auxiliary main body portion 42b is convexly curved toward the surface 42A over the entire length in the width direction Wc, the rigidity of the auxiliary main body portion 42b can be increased.

The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, the rotation shaft portion 32d is provided at the distal end portion 32f of the support portion 32, but the present invention is not limited to this, and the installation position can be changed as appropriate. For example, you may provide in the center of the base end part 32e and the support part 32. FIG.
Moreover, although the rotation connection part 33b was provided in the most proximal end of the holding | maintenance part 33, it is not restricted to this, The installation position can be changed suitably. For example, you may provide in the center of the base end part 33f holding | maintenance part 33. FIG.
Although the claw portion 33c is provided, the present invention is not limited to this, and the claw portion 33c may not be provided.
Although the long groove 33d is provided, the present invention is not limited to this, and the long groove 33d may not be provided.
Moreover, although the rectangular protrusion part 32g was provided, it is not restricted to this, The rectangular protrusion part 32g does not need to be provided.

Moreover, although the holding | maintenance front-end | tip part 33e was provided, it is not restricted to this, The holding | maintenance front-end | tip part 33e does not need to be provided.
Moreover, although the support main body part 32b curved from the base end part 32e to the front-end | tip part 32f, it is not restricted to this, The shape can be changed suitably.
Further, although the support main body 32b is curved over the width direction Wa, the shape is not limited to this, and the shape can be changed as appropriate.
Moreover, although the holding extension part 33a curved from the base end part 33f to the front end part 33g, it is not restricted to this, The shape can be changed suitably.
Further, although the holding extension portion 33a is curved over the width direction Wb, the shape is not limited to this, and the shape can be appropriately changed.

Moreover, although the width dimension W4 of the holding | maintenance extension part 33a was made smaller than the width dimension W5, it is not restricted to this, The shape can be changed suitably.
Moreover, although the width dimension W1 of the support main body part 32b was made smaller than the width dimension W2, it is not restricted to this, The shape can be changed suitably.
Although the auxiliary holding part 4 is provided, the present invention is not limited to this, and the auxiliary holding part 4 may not be provided.
Moreover, although the saw teeth 211c, 31a, 31b, and 41a are provided, the present invention is not limited to this, and the saw teeth 211c, 31a, 31b, and 41a may not be provided.
Although the claw portion 42h is provided, the present invention is not limited to this, and the claw portion 42h may not be provided.

In addition, although the auxiliary substrate portion 42a is offset to the claw portion 42h side in the tangential direction S, the present invention is not limited to this, and the installation position can be changed as appropriate. For example, the auxiliary substrate part 42a may be provided at a position where the virtual center line K and the radial virtual line Ea coincide.
Further, although the support portion 32 is inclined at an angle θ1, the present invention is not limited to this, and the angle θ1 can be appropriately changed. For example, the angle θ1 may be 90 °.
Further, although the auxiliary support portion 42 is inclined at an angle θ2, the present invention is not limited to this, and the angle θ2 can be changed as appropriate. For example, the angle θ2 may be 90 °.
In addition, although the auxiliary main body portion 42b forms the angle θ3 with respect to the radial virtual line Ea, the present invention is not limited to this, and the angle θ3 can be changed as appropriate. For example, the angle θ3 may be 90 °.

In addition, although a plurality of claw portions 42h are provided, the present invention is not limited to this, and one claw portion 42h may be provided.
Moreover, although the annular connection part 31 and the support part 32 are being integrally fixed, it is not restricted to this, The structure can be changed suitably. For example, the annular coupling portion 31 and the support portion 32 may be fixedly coupled, or the support portion 32 may be movable with respect to the annular coupling portion 31.
Moreover, although the auxiliary | assistant connection part 41 and the auxiliary | assistant support part 42 are being integrally fixed, it is not restricted to this, The structure can be changed suitably. For example, the auxiliary connecting portion 41 and the auxiliary supporting portion 42 may be fixedly connected, or the auxiliary supporting portion 42 may be movable with respect to the auxiliary connecting portion 41.

Moreover, although the spring was provided in the rotating shaft part 32d, it is not restricted to this, It is not necessary to provide the said spring. That is, the holding portion 33 may be released without being biased.
In addition, although the annular fixing portion 21c, the annular coupling portion 31, and the auxiliary coupling portion 41 are formed in an annular shape, the shape is not limited to this, and the shape can be changed as appropriate. For example, it may be a polygonal shape such as a triangular shape or a quadrangular shape, or another shape.

Further, the following supplementary notes are disclosed.
(Appendix 1)
The present invention is a bone retainer that is connected to a main body reinforcing tool that reinforces the joining of fractured bones and holds the bone, and an annular connecting part that is connected to the main body reinforcing tool, and from the connecting part A support portion that is fixedly extended over a region in the axial direction of the connecting portion, and a holding portion that is rotatably provided to the support portion and holds the bone.

According to this invention, in addition to the main body reinforcing tool, the bone can also be held by the holding portion.
In addition, since the support portion is fixed to the connecting portion and the holding portion rotates with respect to the support portion, the osteosynthesis reinforcing tool can only be easily fixed to the bone while reducing skin incision. The support force of the support portion can be further reinforced.

(Appendix 2)
Further, a rotating shaft portion is provided at a distal end portion of the support portion, and the holding portion is rotatably connected to the rotating shaft portion, and a base end of the support portion from the rotation connecting portion. You may provide the extension part extended along the said support part toward the part side, and the nail | claw part which protrudes in the opposite side to the said support part from the front-end | tip part of the said extension part.

  According to the present invention, the bone can be held over the extending portion. Moreover, a bone can be effectively hold | maintained via a muscle by a nail | claw part.

(Appendix 3)
Further, a long groove extending from the base end portion of the extension portion to the tip end portion may be provided on the side of the extension portion facing the support portion.

  According to this invention, the rigidity of the extending portion can be increased, and the bone joint can be reinforced over a long period of time.

(Appendix 4)
Moreover, the protrusion part extended toward the said connection part from the said rotating shaft part and fitted in the said long groove may be provided in the side which opposes the said extension part among the said support parts.

  According to this invention, not only can the rigidity of the support portion be increased, but the holding portion can be closed compactly with respect to the support portion by fitting the protruding portion into the long groove.

(Appendix 5)
Further, the front end portion of the holding portion is a pair of holding front end portions provided across the long groove in the axial direction of the rotating shaft portion, and the claw portion is provided at the holding front end portion. Also good.

  According to this invention, the contact of the nail portion with the muscle can be made local, and the reinforcing force of the bone joint can be increased.

(Appendix 6)
The support portion may be curved outward from the connection portion to the rotation shaft portion, and the holding portion may be curved outward from the rotation connection portion to the tip of the extension portion. .

  According to this invention, the rigidity of the support part and the holding part can be increased.

(Appendix 7)
Moreover, the width dimension of the base end part of the said extension part may be larger than the width dimension of the front-end | tip part of the said extension part.

  According to this invention, the rigidity of the base end part of the extension part can be increased.

(Appendix 8)
The rotation shaft portion may be provided on the axis side of the connection portion in the tip portion of the support portion, and the rotation connection portion may be provided offset to the rotation shaft portion side. Good.

  According to this invention, a holding part can be closed compactly with respect to a support part.

(Appendix 9)
Moreover, the width dimension of the base end part of the said support part may be smaller than the width dimension of the front-end | tip part of the said support part.

  According to this invention, the rigidity of the front-end | tip part of a support part can be improved.

(Appendix 10)
In addition, an auxiliary holding unit that is connected to the main body reinforcing tool and holds a portion different from the bone portion held by the holding portion may be provided.

  According to this invention, it is possible to further reinforce the joining at a plurality of sites.

(Appendix 11)
The auxiliary holding portion is concentrically arranged with the connecting portion and fixed to the annular auxiliary connecting portion connected to the main body reinforcing tool, and from the auxiliary connecting portion to the axial region of the auxiliary connecting portion. An auxiliary support portion extended to the auxiliary connection portion, and the auxiliary connection portion includes a position adjusting portion capable of changing the rotational position of the auxiliary connection portion around the axis in a stepwise manner. You may provide the claw part isolate | separated into plurality in the direction where the auxiliary support part was extended.

  According to this invention, it is possible to more effectively reinforce the joining of a plurality of parts.

(Appendix 12)
Further, the bone holder according to any one of supplementary notes 1 to 11 and the main body reinforcing tool may be provided.

  According to the present invention, not only can the same effect as the bone retainer described in any one of Supplementary Notes 1 to 11 be exhibited, but also the joining of a plurality of parts can be reinforced together with the main body reinforcement. .

DESCRIPTION OF SYMBOLS 1 Osteosynthesis reinforcement 2 Main body reinforcement 3 Main holding part 31 Annular connection part (connection part)
32 Support part 32d Rotating shaft part 32g Rectangular protrusion (protrusion)
33 holding part 33a holding extension part (extension part)
33b Rotating connecting part 33c Claw part 33d Long groove 33e Holding tip part 4 Auxiliary holding part 41 Auxiliary connecting part 41a Position adjusting part 42 Auxiliary support part 42h Claw part 5 Bone holder A Axis line

Claims (5)

A bone retainer that is connected to a body reinforcement that reinforces the joint of the fractured bone and holds the bone,
A main holding part connected to the main body reinforcing tool and holding one part of the bone;
An auxiliary holding part that is connected to the main body reinforcing tool via the main holding part and holds other parts of the bone ;
The main holding part is
An annular coupling portion concentrically coupled to the annular fixing portion of the main body reinforcing tool;
The auxiliary holding part is
An annular auxiliary connecting portion connected concentrically to the other edge of the connecting portion;
One edge portion of the connecting portion has a complementary shape that allows the rotational position around the axis of the connecting portion to be changed stepwise with respect to the annular fixing portion,
The bone holder in which one edge portion of the auxiliary connecting portion has a complementary shape in which a rotational position around the axis can be changed stepwise with respect to the other edge portion of the connecting portion . One edge of the connecting portion is configured to be concavo-convexly fitted to the annular fixing portion so that a fitting position in the circumferential direction of the connecting portion can be changed , and one edge of the auxiliary connecting portion The bone retainer according to claim 1 , wherein the portion is configured to be concavo-convexly fitted to the other edge portion of the connecting portion so that the fitting position in the circumferential direction can be changed . Saw teeth that are concavo-convexly fitted to each other are formed on one edge of the connecting portion and the annular fixing portion, and the one edge of the auxiliary connecting portion and the other edge of the connecting portion are uneven. The bone retainer according to claim 2, wherein saw teeth to be fitted are formed . One edge of the connecting portion and the sawtooth of the annular fixing portion form a continuous mountain shape in the circumferential direction, and one edge of the auxiliary connecting portion and the other edge of the connecting portion. The bone retainer according to claim 3 , wherein the sawtooth has a mountain shape continuous in the circumferential direction . The bone holder according to any one of claims 1 to 4,
An osteosynthesis reinforcement comprising the main body reinforcement.

Images