JP2011189174A - Bone plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bone plate, finely adjusting the moving distance of a fractured part, quantifying the moving amount and being utilized for both bringing fractured parts apart from and closer to each other. <P>SOLUTION: This bone plate 1 includes a plate-like body extended in a direction over bone parts separated into two or more, and integrates the bone parts separated into two or more with each other by fixing at least both ends thereof. The body includes a slide mechanism 25, and the slide mechanism 25 includes: a slide oblong hole 3 formed extending in a slide direction at the position of one of the bone parts of the body, the interior thereof being provided with a cam receiver 32; and a pin 40 inserted in the slide oblong hole 3 and provided with a head part constituting a cam 42 engaged with the cam receiver 32 and a leg part 45 entering the bone part. The slide mechanism 25 slides the bone part where the pin 40 enters to slide in the sliding direction by the rotation of the pin 40. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  TECHNICAL FIELD The present invention relates to a bone plate used for fixing bones separated and facilitating osteosynthesis at the time of fracture or osteotomy of the diaphysis and epiphysis.

  When a part of the bone is separated due to the fracture, a treatment is performed in which the bone is reduced to the original state and then joined. In order to keep the bone in a reduced state, the bone part is integrated using a bone plate that extends over two or more separate bone parts. The separated bone part is held in an integrated state, so that the separated part is fused and the fracture is healed.

  A bone plate is known which includes a trunk plate portion having a through hole having a concave seat surface and a head plate portion having a concave seat surface and a through hole having a female screw (for example, Patent Document 1). . The bone plate is fixed to the bone by a bone screw inserted into the through hole. In particular, a male screw is formed on the head of the bone screw and is used by being screwed with a female screw in a through hole.

  As another bone plate, one having a first plate hole in which a screw thread is formed on the entire periphery and a second plate hole 38 having no screw thread is known (for example, Patent Document 2). This bone plate is used together with a lock screw inserted into the first plate hole 36 and a non-lock screw inserted into the second plate hole, and in particular, the lock screw meshes with its head, the thread of the first plate hole. Has a thread.

JP 2004-313514 A Special table 2003-509107 gazette

When using a bone plate, the fractured part must be fixed in the same state as before the fracture, but in reality, the tension of the tendon attached to the bone causes the fracture to overlap and the length of the bone to shrink ( Shortening dislocations) and, conversely, deviations (separation dislocations) may occur in which the fractures are separated and the gaps are opened. When there is a shift as described above, the surgeon pinches the fractured part with a finger and fixes the bone plate while pulling away or pulling the bone to correct the shift.
In such a method, there has been a problem that the deviation of the fracture portion cannot be reliably reduced with a finger, or fine adjustment of the deviation correction cannot be performed. Furthermore, in recent years, in order to reduce the invasiveness and reduce the psychological burden on the patient, an operation method that reduces the skin incision is preferred. However, a finger is inserted through a small incision hole to accurately reduce the deviation of the fracture. It is very difficult.
In addition, with this method, the distance of movement of the fracture cannot be quantitatively expressed, which may cause inaccuracy in information transmission between operators.

  In order to solve this problem, the bone plate of Patent Document 1 includes a slide mechanism in which the head of the bone screw slides in the elongated hole by tightening, and the amount of movement of the fracture portion can be finely adjusted. This slide mechanism is composed of a long hole formed in the trunk plate portion 1a and a bone screw for sliding, and this long hole has a concave seating surface with an inclined surface that gradually becomes deeper as the distance from the head plate portion increases. Have. When a bone screw is inserted into the elongated hole and tightened and fixed to the bone part, the bone screw head slides in a direction in which the inclined surface of the concave seat surface becomes deep, that is, away from the head plate part, by the fastening force of the bone screw. Thus, the diaphysis portion and the epiphysis portion can be pulled apart. With this separation mechanism, the amount of movement of the fractured part will be easily quantified, and the amount of movement may be finely adjusted by tightening control of the bone screw.

  However, Patent Document 1 discloses a separation mechanism that supports only shortened dislocations, and does not support release dislocations. In addition, in this separation mechanism, a large tightening stress is applied only to one slide bone screw after the slide mechanism starts moving the fractured part until the reduction is completed and another bone screw is fixed. In addition, a strong force is required for screwing the slide bone screw, and a strong tightening stress is applied to the portion of the bone portion into which the slide bone screw is screwed in, which may cause new damage to the bone portion. was there.

  Therefore, an object of the present invention is to provide a bone plate that can finely adjust the movement distance of the bone part, that can quantify the movement amount, and that can be used for both separation and drawing of the bone part. Another object of the present invention is to provide a bone plate that is not subject to specific bone screws and local bone overload during reduction.

The bone plate of the present invention comprises a plate-like body extending in a direction extending over two or more separated bone parts, and is a bone plate for integrating at least both ends and fixing the two or more separated bone parts. The main body includes a sliding mechanism, and the sliding mechanism is formed to extend in the sliding direction at the position of one of the bone portions of the main body, and includes a cam receiver inside. A sliding long hole, and a pin that is inserted into the sliding long hole and includes a head part that constitutes a cam that engages with the cam receiver and a foot part that enters the bone part. The sliding mechanism is characterized in that the bone portion into which the pin has entered slides in the sliding direction by the rotation of the pin.

  This bone plate can be easily pulled and pulled away between bone parts by utilizing a cam mechanism. In this bone plate, a cam mechanism having a relatively simple structure can be applied, so that the manufacturing cost of the bone plate can be kept low.

According to the bone plate of the present invention , the movement distance of the bone part can be easily finely adjusted by the amount of rotation of the pin, and the bone part can be determined from the positional change of the pin within the sliding long hole or the rotation speed. Can be quantified. And since the bone plate of this invention can change the moving direction of a bone part with the rotation direction of a pin, it can respond also to pulling apart of the separated bone part, or pulling apart.
Further, in the bone plate of the present invention, since the movement of the bone part can be achieved only by rotating the pin, it is not necessary to tighten a specific bone screw more than necessary, and a local overload of the bone can be avoided.

It is a perspective view of the bone plate which concerns on Embodiment 1 of this invention. It is an enlarged front view of the sliding mechanism of the bone plate which concerns on Embodiment 1 of this invention. It is a perspective view of the gear pin used for the sliding mechanism of the bone plate which concerns on Embodiment 1 of this invention. It is a perspective view of the bone pin which fixes the bone plate which concerns on this invention. It is a perspective view of the bone screw which fixes the bone plate which concerns on this invention. It is a perspective view of the bone screw which fixes the bone plate which concerns on this invention. It is a front view of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the fixation procedure of the bone plate which concerns on Embodiment 1 of this invention. It is a front view of the bone plate which concerns on Embodiment 2 of this invention. It is a front view of the bone plate which concerns on Embodiment 3 of this invention. It is a front view of the bone plate which concerns on Embodiment 4 of this invention. It is a front view of the bone plate which concerns on Embodiment 5 of this invention. It is a front view of the bone plate which concerns on Embodiment 6 of this invention. It is a front view of the bone plate which concerns on Embodiment 7 of this invention. It is a front view of the bone plate which concerns on Embodiment 8 of this invention. It is a front view of the bone plate which concerns on Embodiment 9 of this invention. It is a front view of the bone plate which concerns on Embodiment 10 of this invention. It is a front view of the bone plate which concerns on Embodiment 11 of this invention. It is an enlarged front view of the sliding mechanism of the bone plate which concerns on Embodiment 11 of this invention. It is a perspective view of the cam pin used for the sliding mechanism of the bone plate which concerns on Embodiment 11 of this invention.

<Embodiment 1>
FIG.1 and FIG.2 is the bone plate 1 used for the bone fixation of the distal part end of a radius among the bone plates with a gear concerning this invention. The main body 2 of the bone plate 1 is a substantially T-shaped plate-like body that extends long in one direction, and is an elongated diaphysis fixing portion 21 and an epiphysis fixing portion that is fixed substantially laterally to the upper end of the diaphysis fixing portion 21. 23.

The diaphyseal fixing part 21 includes a sliding long hole 3, an auxiliary sliding long hole 6, and a through hole 50 with a spherical seating surface.
The sliding elongated hole 3 extends along the longitudinal direction of the main body 2 of the bone plate 1, and has a rectangular counterbore portion 35 with curved corners on the surface 27 side of the bone plate 1, and the counterbore portion 3. A rack tooth 31 formed along one long side, and an oblong through portion 33 on the back side of the bone plate 1 are provided.

  The bone plate 1 of the present invention includes a sliding long hole 3 extending in a sliding direction for moving one bone portion during bone portion repair. The sliding long hole 3 includes rack teeth 31 extending in the sliding direction. Further, the bone plate 1 is inserted into the sliding long hole 3 and is provided with a gear-shaped head (gear 41) that engages with the rack teeth 31 and a foot (shaft 45) that enters the bone. (Gear pin 4) is included. A sliding mechanism 25 is configured by combining the sliding long hole 3 and the gear pin 4. The gear pin 4 is fixed to the bone portion by allowing the shaft 45 to enter one bone portion where the sliding long hole 3 is aligned. As shown in FIG. 3A, the gear pin 4 has a gear on its head and engages with the rack teeth 31 of the sliding long hole 3. Moreover, the lower part of the gear pin 4 is a cylindrical shaft 45, and the tip thereof is conical.

  The gear pin 4 and the sliding long hole 3 constituting the sliding mechanism 25 are shown in detail in FIG. The gear 41 of the gear pin 4 and the rack tooth 31 of the sliding long hole 3 are engaged with each other in the sliding long hole 3. The shaft 45 of the gear pin 4 has already been inserted into one of the separated bone parts (diaphysis 10). When the gear pin 4 is rotated, the gear 41 rotates and moves along the rack teeth 31, and the bone portion to which the gear pins 4 are fixed also slides in the sliding direction in which the rack teeth 31 are arranged. Thus, the sliding mechanism 25 can slide the bone part by the rotation of the gear pin 4. Since the gear pin 4 has a hexagonal hole 43 in the center of the head, the gear pin 4 is rotated by a hexagonal screwdriver that fits the hexagonal hole 43.

The sliding long hole 3 further includes a counterbore part 35 and a through part 33.
The counterbore part 35 maintains the position of the gear 41 in the depth direction so that the gear 41 and the rack teeth 31 are securely engaged with each other by the sliding long hole 3. The vertical and horizontal dimensions of the counterbore 35 are set so as not to prevent the rotation of the gear 41 and the movement in the sliding direction.
The penetration part 33 is a part through which the shaft 45 is inserted when the shaft 45 of the gear pin 4 is caused to enter the bone part. The dimension and shape of the penetrating portion 33 is set so as not to prevent the shaft 45 from moving in the sliding direction when the sliding mechanism 25 is operated.

The auxiliary sliding oblong hole 6 of the diaphyseal fixing portion 21 shown in FIG. 1 extends in parallel with the sliding oblong hole 3 and assists the sliding when the bone portion is slid by the sliding mechanism. belongs to.
As shown in FIG. 4, a bone screw 9 is inserted into the auxiliary sliding slot 6 and is screwed to the same bone portion 10 as the bone portion 10 to which the gear pin 4 is fixed among the separated bone portions. When the bone part 10 is slid by the sliding mechanism 25, the bone screw 9 screwed to the bone part 10 also slides in the auxiliary sliding long hole 6, and the movement of the bone screw 9 causes the sliding of the bone part 10. The direction is stable. That is, the auxiliary sliding long hole 6 has a function of guiding the sliding of the bone part 10.

  Further, the auxiliary sliding slot 6 can be used to securely fix the bone plate 1 and the bone portion 10 during the sliding operation. When the sliding mechanism 25 is operated, the diaphysis fixing portion 21 of the bone plate 1 is fixed to the skeleton portion 10 by the gear pin 4, but the gear pin 4 is not threaded to the shaft 45. The bone part 10 cannot be reliably fixed, and the diaphyseal fixing part 21 may be lifted from the bone part 10. Then, if the diaphyseal fixing part 21 and the bone part 10 are screw-fixed using the auxiliary sliding elongated hole 6, the lifting of the diaphyseal fixing part 21 can be suppressed.

A general bone screw 9 (for example, the bone screw 9 shown in FIG. 3C) is used for the auxiliary sliding slot 6. Alternatively, a self-tapping bone screw 9 can be used. The bone screw 9 is tightened to such an extent that it can slide in the sliding direction in the auxiliary sliding slot 6.
The auxiliary sliding oblong hole 6 is provided with an oval counterbore 65 for accommodating the head of the bone screw 9 and a through portion 63 for inserting the shaft 95 of the bone screw 9 on the surface 27 side of the bone plate 1. ing.

  The bone plate 1 holds the bone parts 10, 11, 12 separated into two or more after being reduced, and fixes the body 2 of the bone plate 1 to each of the bone parts 10, 11, 12. Used. The bone plate 1 in FIG. 1 has female screw holes 5 (four in this figure) having female screws 57 formed in the epiphysis fixing portion 23 as screw holes used for fixing to the bone portion, and a spherical curved surface. And a ball seat screw hole 50 (one in this figure) provided with a seating surface 56 comprising:

  The female screw hole 5 is formed in the epiphysis fixing portion 23 of the bone plate 1 as shown in FIG. The female screw hole 5 is fixed to the bone end using a special bone pin 8 as shown in FIG. 3B, for example. The bone pin 8 includes a male screw 81 that engages with the female screw 57 at the head, and a shaft 85 at the foot. When the female screw 57 of the female screw hole 5 and the male screw 81 of the bone pin 8 are screwed together, the bone pin 8 is fixed to the bone plate 1. Therefore, the bone portions 11 and 12 into which the shaft 85 of the bone pin 8 is inserted and the bone plate 1. Means that stable fixation can be obtained without swinging or turning.

  Instead of the special bone pin 8 that can be used for the female screw hole 5, a special bone screw having a male screw on the head and a shaft 85 threaded on the foot may be used. Also, a bone pin or bone screw shaft without a male screw on the head is a two-stage shaft with a small tip and a large diameter just below the head, and the female screw 57 of the female screw hole 5 and the screw are threaded on the large diameter portion of the shaft. It is also possible to prepare a special bone pin or a special bone screw formed with a mating male screw and use it instead of the bone pin 8.

  As shown in FIG. 1, the ball seat screw hole 50 is formed in the diaphysis fixing portion 21 of the bone plate 1, and the head of the bone screw inserted into the screw hole 50 is formed by the spherical seat surface 56. Can be swung. This is to make it possible to change the screwing angle when the shaft of the bone screw is screwed into the bone part and fixed. Therefore, a bone screw threaded on the shaft so that the ball seat screw hole 50 can be fixed to the bone portion can be used as the ball seat screw hole 50 so as to be able to swing in the spherical seat surface. . As an example of a suitable bone screw, the head 95 shown in FIG. 3D is a flat head 92 (a head having a flat upper surface and a tapered lower surface), and a shaft 95 having a threaded foot. There are bone screws 90. A bone screw having a spherical lower surface of the head is also suitable for fixing the ball seat screw hole 50.

  In the bone plate 1 shown in FIG. 1, the female screw holes 5 of the epiphysis fixing portion 23 are arranged in a row. However, the present invention is not limited to this, and can be changed to a two-row arrangement or a random arrangement. It can be optimized according to the size and shape of the bone end and the fracture state of the bone end.

  The body 2 of the bone plate 1 is integrally formed from a metal with high biological safety such as titanium alloy, cobalt-chromium alloy, and stainless steel. Further, the gear pin 4, the bone pin 8, and the bone screws 9, 90 are formed of a metal with high biological safety such as a titanium alloy and a cobalt-chromium alloy.

  Hexagonal holes 43, 83, 93 are provided on the upper surface of the heads of the gear pin 4, the bone pin 8, and the bone screws 9, 90, and can be turned by a hex driver. The hexagonal holes 43, 83, and 93 can be changed to holes having different shapes, and for example, a slot, a cross hole, a square hole, or a hexalobe-shaped hole can be adopted. In particular, it is preferable to use a hexagonal hole or a hexalobe hole because it is suitable for reliably transmitting a large torque.

Below, the procedure which fixes a fracture part using the bone plate 1 of this invention is demonstrated.
FIG. 4 shows a state in which the bone plate 1 is fixed to the fracture portion at the distal end of the radius, and before the fracture portion is reduced. This fracture is a case in which the diaphyseal part 10 and the two epiphyseal parts 11 and 12 are separated, and the diaphyseal part 10 and the epiphyseal part are dislocated and dislocated. There is a gap 15 between them.
The state shown in FIG. 4 is performed by the procedure of FIGS. 5A to 5C, and the subsequent repair and fixation of the fractured portion are performed by the procedure of FIGS. 5D to 5F.

  In FIG. 5A, four female screw holes 5 formed in the epiphysis fixing portion 21 of the bone plate 1 are fixed to the epiphysis portions 11 and 12 by a bone pin 8 having a male screw 81 on the head. As shown in the figure, the epiphysis fixing portion 23 of the bone plate 1 is connected to the diaphysis fixing portion 21 in accordance with the shape of the distal radius portion rising from the diaphyseal portion 10 toward the bone heads 11 and 12. Is warped against.

Next, as shown in FIG. 5B, the auxiliary sliding long hole 6 of the diaphysis fixing portion 21 is screwed to the diaphysis portion 10 with a bone screw 9. At this time, the bone screw 9 is tightened so that the main body 2 of the bone plate 1 does not rise from the diaphysis 10 and the bone screw 9 can slide in the auxiliary sliding long hole 6. In this case, since the fracture is a dislocation dislocation, the bone screw 9 is screwed into a position (proximal part) away from the bone end portions 11 and 12 in the auxiliary sliding slot 6.
Then, a pilot hole 14 for inserting the gear pin 4 is formed in the diaphysis 10 in accordance with the position of the through portion 33 of the sliding long hole 3 of the bone plate 1. Similarly to the bone screw 9, the pilot hole 14 is also formed at a position (proximal to the proximal portion) away from the bone end portions 11 and 12 in the sliding long hole 3.

  Then, as shown in FIG. 5C, the gear pin 4 is installed in the sliding long hole 3 to assemble the sliding mechanism 25. This is because the shaft 45 of the gear pin 4 is inserted into the prepared hole 14 of the diaphysis 10 through the through-hole 33 of the sliding slot 3, and the gear 41 at the head of the gear pin 4 is inserted into the rack teeth of the sliding slot 3. This is performed by meshing with 31.

  When the sliding mechanism 25 is assembled, as shown in FIG. 5D, the hexagon driver 7 is fitted into the hexagon hole 43 of the gear pin 4, and the gear pin 4 is rotated clockwise in the CR direction. The gear 41 of the gear pin 4 meshes with the rack teeth 31 and moves in the sliding long hole 3 in the direction of the bone ends 11 and 12. That is, the gear pin 4 and the bone plate 1 move relative to each other. Actually, since the gear pin 4 is fixed to the diaphysis 10, the bone plate 1 moves in the proximal direction of the diaphysis 10 (arrow Y). Then, the epiphysis portions 11 and 12 in which the epiphysis fixing portion 23 of the bone plate 1 is fixed by the bone pin 8 move together with the bone plate 1 in the direction of the diaphysis 10 (arrow X). The gear 41 is rotated until the bone ends 11 and 12 move and contact with the diaphysis 10 to eliminate the gap 15 or until the gap between the ossicles 11 and 12 and the diaphysis 10 becomes a predetermined interval. Let

  And the diaphysis fixing | fixed part 21 is fixed to the diaphyseal part 10 in the state from which the clearance gap 15 between the bone heads 11 and 12 and the diaphyseal part 10 was lose | eliminated like FIG. First, when the bone screw 9 in the auxiliary sliding long hole 6 is tightened and the bone plate 1 is temporarily fixed to the diaphysis 10, the subsequent fixing operation becomes easy. Next, a pilot hole is made in the diaphysis 10 in accordance with the ball seat screw hole 50 of the bone plate 1. The prepared hole is formed at a desired angle toward the diaphysis 10 (in this figure, approximately 90 ° with respect to the center line of the diaphysis). A countersunk bone screw 90 is screwed into the prepared hole to completely fix the diaphysis fixing portion 21 and the diaphysis portion 10. The pilot hole has a smaller diameter than the shaft 95 of the bone screw 90, and when the bone screw 90 is screwed into the shaft portion 10 by so-called self-tapping, the shaft screw 95 and the shaft portion 10 are connected to each other. This is preferable because the bond can be strengthened.

Thereafter, the gear pin 4 may be left in the body as it is, but more preferably, if the gear pin 4 is replaced with a bone screw 9 as shown in FIG. 5F, the fracture portion can be more firmly fixed by the bone plate. preferable. Since the hole into which the shaft 45 of the gear pin 4 has been inserted remains in the diaphysis 10, the bone screw 9 is screwed in using the hole as a pilot hole, and the sliding long hole 3, the diaphysis 10, It is good to fix.
Through these series of procedures, the bone plate 1 of the present invention can hold the bone end portions 11 and 12 and the diaphyseal portion 10 separated by the fracture in an integrated state.

  The gear pin 4 can be replaced with the bone screw 9 before the countersunk bone screw 90 is tightened in FIG. 5E. For example, when the bone screw 9 in the auxiliary sliding long hole 6 is tightened in FIG. 5E and the bone plate 1 is temporarily fixed to the diaphysis 10 and then the gear pin 4 and the bone screw 9 are replaced, the countersunk bone screw It is preferable because the fixing force for temporary fixation while the pilot hole for 90 is opened in the diaphysis can be increased.

FIGS. 5A to F show a procedure in the case of pulling a separated bone part in a fracture of a dislocation dislocation, but the present invention can also be used when the fracture part is a shortened dislocation.
In the shortened dislocation, the procedure for separating the separated bone part is as follows. (1) In FIG. 5B, the position of passing the bone screw 9 through the auxiliary sliding slot 6 in FIG. (2) A pilot hole for the gear pin 4 is formed in a position close to the bone end portions 11 and 12 in the sliding long hole 3 (3) in FIG. 5D. The rotational direction of the gear pin 4 is made counterclockwise, and the gear pin 4 in the sliding long hole 3 is moved in the direction away from the bone ends 11 and 12 only at three points. Thereby, the bone end parts 11 and 12 and the diaphyseal part 10 can be pulled apart using the same bone plate 1.

  According to the present invention, by providing the gear pin 4 and the sliding long hole 3, the reduction of the bone portion can be easily performed by reducing the bone portion that has been performed manually by the rotation of the gear pin 4. Furthermore, it is easy to quantify the amount of movement of the bone part. Further, since the rotation of the gear pin 4 can be performed by a driver, the rotation operation of the gear pin 4 can be easily performed even when the incision portion is small, and reduction of the bone portion can be reliably performed. There are advantages. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Embodiment 2>
The bone plate of the present invention is not only used for the ribs as in the first embodiment, but also the humerus, forearm bone (including ribs and ulna), spine, femur, crus (including tibia and ribs), and finger bones. And various forms of fractures such as toe ribs. Below, a part of form of the bone plate of this invention is demonstrated.

  FIG. 6A shows a bone plate 100A for the proximal portion of the humerus, where the epiphysis fixing portion 23 is fixed to the end portion of the humerus, and the diaphysis fixing portion 21 is fixed to the humeral shaft portion. The bone plate 100A includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (in this example, a 2 × 3 rectangular array), and a plurality of auxiliary sliding long holes 6 (3 in this example). And a ball seat screw hole 50 are formed.

  The bone plate 100A is used in the same manner as the rib bone plate 1 of the first embodiment. (1) First, the epiphysis fixing portion 23 is fixed to the epiphysis. (2) Next, the auxiliary sliding oblong hole 6 is fixed with a bone screw, and the sliding slot 3 is fixed with a gear pin 4 to the diaphysis part. (3) The gear pin 4 is rotated to draw or separate the bone end part and the diaphyseal part to remove the bone part. Reduction is performed by the procedure of (4) fixing the ball seat screw hole 50 to the diaphysis with the taper head bone screw 90.

  The bone plate of the present embodiment is suitable for fixing the fracture portion of the proximal portion of the humerus, and the bone length can be easily reduced by adjusting the bone length of the fracture portion by rotating the gear pin 4. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Embodiment 3>
FIG. 6B shows a bone plate 100B for the distal part of the femur. The epiphysis fixing part 23 is fixed to the end of the femur, and the diaphysis fixing part 21 is fixed to the femoral shaft. The bone plate 100B includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (in this example, six are arranged in a triangle), and a plurality of auxiliary sliding long holes 6 (in this example, 2 And a ball seat screw hole 50 are formed.

  The bone plate 100B is used in the same manner as in the first and second embodiments. (1) First, the epiphysis fixing portion 23 is fixed to the epiphysis, and (2) the auxiliary sliding slot 6 is then set to the bone screw. Then, the sliding long holes 3 are fixed to the diaphysis by the gear pins 4, respectively. (3) The gear pins 4 are rotated to draw or separate the epiphysis and diaphysis to reduce the bone, 4) The ball seat screw hole 50 is fixed to the diaphysis with a tapered head bone screw 90.

  The bone plate according to the present embodiment is suitable for fixing the fracture portion of the distal portion of the femur, and the bone length can be easily reduced by adjusting the bone length of the fracture portion by rotating the gear pin 4. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Embodiment 4>
FIG. 6C shows a bone plate 100C for the tibia, in which the epiphysis fixing portion 23 is fixed to the end portion of the tibia, and the diaphysis fixing portion 21 is fixed to the tibia shaft portion. The bone plate 100C includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (in this example, three are arranged in a line), an auxiliary sliding long hole 6, and a ball seat screw hole 50 ( In this example, a total of four pieces are formed on each side of the sliding long hole 3.

  The bone plate 100C is used in the same manner as in the first to third embodiments. (1) First, the epiphysis fixing portion 23 is fixed to the epiphysis, and (2) the auxiliary sliding slot 6 is then inserted into the bone screw. Then, the sliding long holes 3 are fixed to the diaphysis by the gear pins 4, respectively. (3) The gear pins 4 are rotated to draw or separate the epiphysis and diaphysis to reduce the bone, 4) The ball seat screw hole 50 is fixed to the diaphysis with a tapered head bone screw 90.

  The bone plate of the present embodiment is suitable for fixing the fracture portion of the tibia. By adjusting the bone length of the fracture portion by rotating the gear pin 4, the reduction of the bone portion can be easily performed. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Embodiments 5-7>
FIG. 6D shows a bone plate 100D for the humeral shaft, and both ends of the bone plate 100D are fixed to each of the two separated shafts. The bone plate 100D includes a sliding long hole 3, a gear pin 4, a plurality of female holes 5 (three in this example), an auxiliary sliding long hole 6, and a ball seat screw hole 50 (2 in this example). Are formed.

  FIG. 6E shows a bone plate 100E for the ulna shaft, and both ends of the bone plate 6E1 are fixed to each of the two separated shafts. The bone plate 100E includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (three in this example), an auxiliary sliding long hole 6, and a ball seat screw hole 50 (2 in this example). Are formed.

  Further, FIG. 6F shows a bone plate 100F for the humeral shaft, and each of both ends of the bone plate 6F1 is fixed to each of the two separated shafts. The bone plate 100F includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (in this example, five pieces), an auxiliary sliding long hole 6, and a ball seat screw hole 50 (in this example, 1 Are formed.

  The method of using the bone plates 100D, 100E, and 100F is the same as in the first to fourth embodiments. (1) First, the female screw hole 5 formed on one end side of the bone plate is fixed to one of the separated diaphyseal portions. (2) Next, the auxiliary sliding slot 6 is fixed with the bone screw, the sliding slot 3 is fixed with the gear pin 4 to the other of the separated diaphysis, and (3) the gear pin 4 is rotated to 2 One bone shaft is pulled or pulled away to reduce the bone, and (4) the ball seat screw hole 50 is fixed to the other bone shaft with the taper head bone screw 90.

  The bone plate of the present embodiment is suitable for fixing the fracture portions of the humeral shaft, the ulna shaft, and the humerus shaft, and by adjusting the bone length of the fracture portion by rotating the gear pin 4. Reduction of the bone part can be easily performed. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Eighth embodiment>
FIG. 6G shows a bone plate 100G used for the diaphysis, which can be used to draw three separated diaphysis. The bone plate 100G includes two sliding long holes 3, two gear pins 4 fitted in the respective sliding long holes 3, two female screw holes 5 formed between the sliding long holes 3, A ball seat screw hole 50 is formed at each of both ends of the bone plate 100G. This bone plate 100G fixes both ends of the bone plate 100G to the bone portions on both sides among the three separated bone portions, and fixes the female screw hole 5 to the middle bone portion.

  The method of using the bone plate 100G is similar to that of the first to seventh embodiments. (1) First, the bone in the middle of the diaphysis portion in which the female screw hole 5 formed in the vicinity of the center of the bone plate is divided into three. (2) Next, two sliding slots 3 are fixed to each of the diaphyseal parts on both sides with gear pins 4, and (3) the two gear pins 4 are appropriately rotated and separated into three. The bone portion is reduced by pulling or pulling the diaphyseal portion, and (4) the ball seat screw hole 50 is fixed to the diaphysis portion on both sides with the tapered head bone screw 90.

As described above, by changing the number of the gear pins 4 and the sliding long holes 3, bone pins suitable for reduction of various fracture states can be obtained.
The bone plate of the present embodiment can be suitably used for fixing the fracture portion of the diaphysis of various bone portions by changing the dimensions, and by adjusting the bone length of the fracture portion by rotating the gear pin 4, Reduction of bone can be performed easily. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Ninth Embodiment>
FIG. 6H shows a bone plate 100H used for the spine, and both ends of the bone plate 100H are fixed to each of the separated spines. The bone plate 100H includes a sliding long hole 3, a gear pin 4, a plurality of female screw holes 5 (two in this example), a ball seat screw hole 50 (two in this example), and a plurality of auxiliary slides. A dynamic slot 6 (two in parallel with the sliding slot 3 in this example) is formed.

The method of using the bone plate 100H is the same as in Embodiments 1 to 3. (1) First, the female screw hole 5 formed on one end of the bone plate is fixed to one of the separated vertebrae, and (2) Next, the auxiliary sliding long hole 6 is fixed to the other side of the spine by the bone screw and the sliding long hole 3 is fixed to the other side of the spine. (3) The gear pin 4 is rotated so that the two spines are drawn or pulled apart. The part is reduced, and (4) the ball seat screw hole 50 is fixed to the other spine with the taper head bone screw 90.
The bone plate of the present embodiment can be suitably used for fixing a fractured portion of the spine, and the bone length can be easily reduced by adjusting the bone length of the fractured portion by rotating the gear pin 4. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the gear pin 4.

<Embodiment 10>
FIG. 6I shows a bone plate 100I used for the epiphysis. The epiphysis fixing portion 23 is fixed to the epiphysis side, and the diaphysis fixing portion 21 is fixed to the humerus diaphysis. This bone plate 100I is greatly different from the first to ninth embodiments in that the sliding long hole 3 is formed in the epiphysis fixing portion 23. A gear pin 4 is disposed in the sliding long hole 3, and ball seat screw holes 50 are formed on both ends of the sliding long hole. The plurality of female screw holes 5 are formed in the diaphysis fixing portion 21.
This bone plate is used when the epiphysis is displaced laterally with respect to the diaphysis, and the epiphysis can move laterally with respect to the diaphysis by a sliding mechanism. it can.

  The bone plate 100I is used in the following manner: (1) First, the diaphysis fixing portion 21 is fixed to the diaphysis portion; (2) Next, the sliding long hole 3 is fixed to the end of the bone with the gear pin 4, The gear pin 4 is rotated to move the end of the bone laterally with respect to the diaphysis to reduce the bone, and (4) the ball seat screw hole 50 is fixed to the end of the bone with the taper head bone screw 90. It is performed in the procedure.

  The bone plate according to the present embodiment is suitable for fixing a fracture portion where the bone end portion has caused a lateral deviation, and the bone portion is reduced and fixed by moving the lateral deviation of the fracture portion to a predetermined position by the rotation of the gear pin 4. Can be advanced at the same time. Furthermore, it is easy to digitize the amount of movement of the bone part, and the gear pin 4 is rotated by a screwdriver, so that the rotation operation of the gear pin 4 is easy even when the incised part is small.

(Modification)
As a modification of the tenth embodiment, a bone plate in which the sliding long holes 3 are formed in an arc shape can be used. Such a bone plate not only shifts the end of the bone laterally with respect to the diaphysis, but also shifts in which the length of the bone shrinks (shortening dislocation), or shifts that cause the fracture to separate and open the gap (separation dislocation). It is effective when these occur simultaneously. For example, in a fracture in which a shortened dislocation and a lateral shift occur simultaneously, the sliding long hole 3 can be formed in an arc shape with the diaphysis as a center. Such a sliding long hole 3 moves the bone end portion in an arc along the shape of the sliding long hole 3, so that the bone end portion is moved laterally while being pulled away from the diaphyseal portion and repaired. can do. Further, in the case of a fracture in which the dislocation dislocation and the lateral displacement occur at the same time, the sliding slot 3 can be formed in an arc shape with the bone end portion as the center. Such a sliding long hole 3 moves the bone end portion in an arc along the shape of the sliding long hole 3, so that the bone end portion is moved laterally while being brought close to the diaphyseal portion to be repaired. can do.

<Embodiment 11>
As shown in FIGS. 7 and 8, the present embodiment is a bone plate 1 for a radius end using a cam mechanism as a sliding mechanism 25. The other parts are the same as in the first embodiment.
The sliding elongated hole 3 is formed with a concave cam receiver 32 on the side extending in the sliding direction. Further, the bone plate 1 is inserted into the sliding long hole 3, and an eccentric head (cam portion 42) that fits slidably with the cam receiver 32 and a foot portion (shaft 45) that enters the bone portion. The pin (cam pin 40) is provided. The sliding mechanism 25 is configured by combining the sliding long hole 3 and the cam pin 40. The cam pin 40 is fixed to the bone part by allowing the shaft 45 to enter one bone part in which the sliding long hole 3 is aligned. As shown in FIG. 9, the cam pin 40 includes an eccentric cam portion 42 at the head, and the convex portion of the cam portion 42 is slidably engaged with the cam receiver 32 of the sliding long hole 3. The lower portion of the cam pin 40 is a cylindrical shaft 85, and the tip thereof is conical.

The cam pin 40 and the sliding long hole 3 constituting the sliding mechanism 25 are shown in detail in FIG. The cam portion 42 of the cam pin 40 and the cam receiver 32 of the sliding long hole 3 are engaged with each other inside the sliding long hole 3. The shaft 45 of the cam pin 40 has been inserted into one of the separated bone parts (diaphysis). Rotating the cam pin 40 in the direction of arrow r _a convex-shaped portion of the cam portion 42 rotates in the direction of arrow R _a while sliding in the recessed portion of the cam receiver 32, the convex cam portion 42a The shape portion rotates and moves to the position of the broken line in the figure. Thereby, the cam receiver 32 is pushed in the direction of arrow A (downward in the figure), and accordingly, the diaphyseal fixing portion 21 of the bone plate 1 also moves in the direction of arrow A. The rotation in the bone plate 1, by rotating the cam pin 40 in the direction of arrow r _b, the convex portion of the cam portion 42, in the direction of arrow R _b while sliding in the recessed portion of the cam receiver 32 Then, the convex portion of the cam portion 42b rotates and moves to the position of the dashed line in the figure. Thereby, the cam receiver 32 is pushed in the direction of arrow B (upward in the figure), and accordingly, the diaphyseal fixing portion 21 of the bone plate 1 also moves in the direction of arrow B.
As described above, the fracture portion can be reduced by the bone plate 1 using the cam mechanism as the sliding mechanism 25.
Since the cam pin 40 has a hexagonal hole 43 in the center of the head, the cam pin 40 is rotated by a hexagonal screwdriver that fits the hexagonal hole 43.

  By providing the cam pin 40 and the sliding long hole 3, the present invention can easily reduce the bone part by reducing the bone part by rotation of the cam pin 40. it can. Furthermore, it is easy to quantify the amount of movement of the bone. Further, since the cam pin 40 can be rotated by a driver, the cam pin 40 can be easily rotated even when the incision portion is small, which is preferable, and there is an advantage that the reduction of the bone portion can be performed reliably. is there. In addition, the present invention can be applied to either pulling or pulling away bone by simply changing the rotation direction of the cam pin 40.

DESCRIPTION OF SYMBOLS 1 Bone plate 10-12 Separated bone part 2 Main body 21 Stem fixation part 23 End of bone fixation part 25 Sliding mechanism 3 Sliding long hole 31 Rack tooth 32 Cam receiver 4 Gear pin 41 Gear 40 Cam pin 42 Cam part 45 Shaft 5 Female screw Hole 57 Female screw 50 Ball seat screw hole 56 Spherical seat surface 6 Auxiliary sliding long hole 8 Bone pin 81 Bone pin head male screw 9, 90 Bone screw 92 Countersunk head

Claims (6)

A bone plate comprising a plate-like main body extending in a direction extending over two or more separated bone parts, at least both ends fixed to integrate the two or more separated bone parts,
The main body includes a sliding mechanism,
The sliding mechanism is
A sliding slot that is formed extending in the sliding direction at the position of one of the bone parts of the main body, and has a cam receiver inside;
It is composed of a pin that is inserted into the sliding long hole and includes a head portion that constitutes a cam that engages with the cam receiver and a foot portion that enters the bone portion,
The bone plate characterized in that the sliding mechanism slides a bone part into which the pin has entered in a sliding direction by rotation of the pin. The bone plate includes a metaphysis fixing portion fixed to the epiphysis portion, and a diaphysis fixing portion fixed to the diaphysis portion,
  The bone plate according to claim 1, wherein the sliding long hole is formed in the epiphysis fixing portion and extends in a direction different from a longitudinal direction of the diaphysis portion.   3. The bone plate according to claim 1, wherein the main body includes an auxiliary sliding elongated hole that extends parallel to the sliding elongated hole and assists sliding of the sliding mechanism. The main body has a female screw hole with a female screw,
The female screw hole is inserted into a bone pin or a bone screw having a head having a male screw screwed into the female screw and a foot part that enters the bone part, and is fixed to the bone part. The bone plate according to any one of claims 1 to 3. The main body has a spherical seat screw hole with a spherical seating surface,
The ball seat screw hole is inserted into a bone screw having a head that can swing within the spherical seat surface and a foot that enters the bone portion, and is screwed to the bone portion. The bone plate according to any one of claims 1 to 4.   6. The bone plate according to any one of claims 1 to 5, wherein the bone plate is used for any one of a humerus, a radius, an ulna, a spine, a femur, a tibia, a radius, a finger bone, and a foot radius. The bone plate according to item 1.

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