JP3174242U - Artificial bone - Google Patents

Abstract

To provide an artificial bone capable of quickly and accurately determining an attachment position with respect to a skull when attaching so as to cover a defect of a skull.
An artificial bone is provided in a region corresponding to a defect portion of a skull, a mesh portion having a plurality of openings, and a fixing portion provided outside the mesh portion and fixed to the skull. 18. Further, the artificial bone 10 is provided on the outer side of the mesh portion 16, and coincides with at least one line between the suture line of the skull and the edge of the defect portion, and the through-hole capable of determining the position of the artificial bone 10 with respect to the skull It has the positioning part 22 in which 24 was formed.
[Selection] Figure 1

Description

  The present invention relates to an artificial bone attached to a skull so as to cover a defect of a skull.

  In neurosurgery, craniotomy is sometimes performed for the treatment of acoustic nerve tumors, facial spasms, or trigeminal neuralgia. In this craniotomy, for example, a scalp and a muscle layer are incised, a part of the skull is opened in a hole shape, and treatment such as drainage of cerebrospinal fluid is performed by internal operation through this hole. This is done by closing the scalp wound and stitching the scalp wound.

  Patent Document 1 below discloses a skull substitute having a fixing portion fixed to the skull and a mesh portion having a plurality of holes. In this skull substitute, it is easy to form into a shape corresponding to the defect due to the flexibility of the mesh portion. In addition, this document describes that the affinity between the mesh portion and the skin is increased by setting the mesh portion so as to cover the defect portion, so that the subcutaneous tissue enters the hole portion of the defect portion. . Further, this document describes that the fixing portion is formed on the peripheral portion of the mesh portion and is fixed to the skull via a screw screw or the like.

  Patent Document 2 below also discloses a skull auxiliary plate that covers the defect of the skull. The skull auxiliary plate is a honeycomb-like plate in which a plurality of hexagonal holes are uniformly formed, and a fixing tool is passed through the hexagonal holes to fix the plate to the skull.

Utility model registration No. 3136883 Utility model registration No. 3117059

  The above-described conventional artificial bone is usually pre-shaped into a shape corresponding to the defect, and the molded artificial bone is attached to the skull during the operation. At this time, there is a problem that it takes time to align the artificial bone and the skull, or the attachment position of the artificial bone is shifted.

  An object of the present invention is to provide an artificial bone that can quickly and accurately determine the attachment position with respect to the skull when it is attached so as to cover the defect of the skull.

  The present invention provides an artificial bone attached to a skull so as to cover a defect portion of a skull, provided in a region corresponding to the defect portion of the skull, and a net-like portion having a plurality of openings formed on the outside of the mesh-like portion. A fixed portion that is provided and fixed to the skull; provided outside the mesh-like portion; and coincides with at least one line between the suture line of the skull and the edge of the defect portion, and determines the position of the artificial bone relative to the skull And a positioning portion in which possible through holes are formed.

  Further, it is preferable that the through holes are formed so as to coincide with each other on lines having different extending directions.

  Further, it is preferable that the through holes are formed so as to coincide with different suture lines.

  Further, it is preferable that the through holes are formed so as to coincide with the edges of the defect portions having different tangential directions.

  The through hole is preferably formed so as to coincide with the suture line and the edge of the defect portion.

  Further, it is preferable that the positioning portion further has a through hole formed so as to coincide with the line of the bar hole formed at the edge of the defect portion.

  According to the artificial bone of the present invention, the attachment position with respect to the skull can be quickly and accurately determined when attaching so as to cover the defect of the skull.

It is a figure which shows the structure of the artificial bone which concerns on this embodiment. It is a figure which shows the artificial bone attached to the skull. It is a figure which shows the artificial bone of another aspect attached to the skull. It is a figure which shows the artificial bone of another aspect attached to the skull. It is a figure which shows the through-hole of various shapes. It is a figure which shows the through-hole of various shapes. It is a figure which shows the through-hole of various shapes.

  Hereinafter, an embodiment of an artificial bone according to the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating a configuration of an artificial bone according to the present embodiment, and FIG. 2 is a diagram illustrating an artificial bone attached to a skull.

  The artificial bone 10 is a thin plate plate made of a titanium alloy and has a thickness of 0.8 mm, for example. Although the case where the artificial bone 10 is made of a titanium alloy has been described, the present invention is not limited to this configuration, and the artificial bone 10 is made of ceramic, pure titanium, stainless steel, or the like as long as the material is biocompatible. There may be.

  The artificial bone 10 shown in FIGS. 1 and 2 closes a hole of the skull 12, that is, a defect portion, and is formed to correspond to the size and shape of the defect portion. The size of the artificial bone 10 shown in FIG. 1 is, for example, 130 mm × 115 mm. In addition, the magnitude | size and shape of the artificial bone 10 are an example, Comprising: If a defect | deletion part can be covered, this invention is not limited to the magnitude | size and shape of the artificial bone 10 shown by FIG.

  The artificial bone 10 includes a mesh portion 16 in which a plurality of openings 14 are formed, and a fixing portion 18 that is provided outside the mesh portion 16 and is fixed to the skull 12.

  The mesh portion 16 is provided in a region corresponding to the defect portion of the skull 12. The mesh portion 16 is a mesh (mesh) shape in which a plurality of openings 14 are formed as described above, and is flexible. Therefore, the mesh portion 16 changes from the planar shape of FIG. 1 to a three-dimensional shape as shown in FIG. Can be deformed. Therefore, the artificial bone 10 can be deformed into a three-dimensional shape corresponding to the curved surface of the skull 12, particularly the curved surface near the defect. In addition, by providing the mesh portion 16 in a region corresponding to the defect portion of the skull 12, the subcutaneous tissue can enter the opening 14 of the mesh portion 16 after the operation, and the affinity between the mesh portion 16 and the skin can be increased. .

  The openings 14 are circular and are evenly arranged. However, the opening 14 of the present invention is not limited to this configuration, and the shape, arrangement, or size can be appropriately selected according to the purpose. For example, as shown by reference numeral 14a shown in FIG.

  Fourteen fixing portions 18 are arranged on the outer edge of the artificial bone 10. The number of fixing portions 18 is an example, and the present invention is not limited to the number 14 of fixing portions 18.

  The fixing part 18 has a fixing member 20 for fixing the artificial bone 10 to the skull 12, for example, a fixing hole 20 through which a screw passes. The fixing hole 20 is preferably a countersink so as to correspond to a countersunk screw used as a fixing member. The diameter of the fixing hole 20 of the present embodiment is 3.6 mm, but the present invention is not limited to this diameter, and may be larger or smaller than 3.6 mm.

  The artificial bone 10 of the present invention further includes a positioning portion 22 that can determine the position of the artificial bone 10 with respect to the skull 12. The positioning part 22 is provided outside the mesh part 16. A through hole 24 is formed in the positioning portion 22. The through-hole 24 coincides with at least one line between the suture line 26 of the skull 12 and the edge 28 of the defect, and is formed so that the position of the artificial bone 10 with respect to the skull 12 can be determined. That is, the through-hole 24 is formed so that the position of the artificial bone 10 is uniquely determined by attaching the artificial bone 10 to the skull 12 so that the line and the through-hole 24 coincide. . With such a configuration of the positioning portion 22, when the artificial bone 10 that has been molded in advance so as to cover the defect portion of the skull 12 during the operation, the attachment position of the artificial bone 10 with respect to the skull 12 can be quickly and accurately attached. Can be determined.

  The positioning portion 22 shown in FIG. 2 is provided at a portion where the suture line 26 of the skull 12 and the edge 28 of the defect portion intersect. The suture line 26 used for positioning is preferably a coronal suture with a relatively clear line (line), but the present invention is not limited to this, and the suture line is located near the defect and can be seen. If so, lambda stitching or human character stitching may be used. The edge 28 of the defect portion is an outer peripheral edge of the defect portion, and in this embodiment, a partial region of the edge 28 used for positioning is referred to as a line as described above. The defect edge 28 also includes a bar hole formed when the skull 12 is opened.

  The through hole 24 of the positioning portion 22 is formed in a convex shape so as to coincide with the suture line 26 and the edge 28, respectively. Therefore, when attaching the artificial bone 10 to the skull 12, the convex bottom portion of the through hole 24 is aligned with the edge 28, and the convex protrusion is aligned with the suture line 26, so that the artificial bone 10 with respect to the skull 12 is aligned. The position can be determined quickly and accurately.

  Returning to FIG. 1, the artificial bone 10 is formed with a rectangular through hole 24 in addition to the convex through hole 24. These rectangular through holes 24 are formed so that the longitudinal directions thereof coincide with the edges 28. Accordingly, when the artificial bone 10 is attached to the skull 12, the positioning of the convex through hole 24 and the longitudinal direction of the rectangle in the through hole 24 are aligned with the respective edges 28, thereby further increasing the accuracy of positioning. improves.

  Next, another embodiment of the artificial bone 10 will be described with reference to FIGS. 3 and 4 are views showing another embodiment of the artificial bone attached to the skull. 4 shows an enlarged view of the positioning portion 22 of the artificial bone 10 shown in FIG. Note that a detailed description of the same configuration as that of the above-described embodiment is omitted.

  This artificial bone 10 also has three positioning portions 22. One positioning part 22 has an L-shaped through hole 24, and the two positioning parts 22 each have a rectangular through hole 24.

  When attaching the artificial bone 10 to the skull 12, as shown in FIG. 4, the right angle portion of the L-shaped through-hole 24 is aligned with the intersection of the suture line 26 and the edge 28. By combining the two straight portions with the suture line 26 and the edge 28, the position of the artificial bone 10 with respect to the skull 12 can be determined quickly and accurately.

  The positioning accuracy of the two rectangular through holes 24 is further improved by aligning the longitudinal direction of the two rectangular through holes 24 with the respective edges 28 together with the alignment of the L-shaped through holes 24.

  In the above-described two embodiments, the case where the positioning portion 22 has at least the shape that matches the suture line 26 and the edge 28, that is, the convex or L-shaped through hole 24 has been described. It is not limited to this configuration. If the position of the artificial bone 10 with respect to the skull 12 is uniquely determined, the positioning part 22 can also have through holes 24 having other shapes.

  The through holes 24 formed in various shapes so as to coincide with the suture line 26 and the edge 28 will be described with reference to FIG. In FIG. 5, four types of through-holes 24 are shown. The uppermost through hole 24 has a triangular shape and can be positioned by aligning each vertex with a line. The through-holes 24 thereunder are four circular shapes, and positioning is possible by aligning one hole with the intersection of the suture line 26 and the edge 28 and aligning the other three holes on the line. Further, the two types of through-holes 24 depicted below are similar shapes of the convex shape and the L-shape described above, and each end is processed into a curved shape.

  Moreover, as another aspect, the positioning part 22 can have the through-hole 24 formed so that it might respectively correspond on the line from which an extending direction differs. In this way, when there are at least two lines to be the target of the through hole 24 and they are in different extending directions, the position of the artificial bone 10 with respect to the skull 12 can be uniquely determined.

  Specifically, the through holes 24 may be formed so as to correspond to different suture lines 26, respectively. When the suture lines 26 are different as described above, the extending directions of the respective suture lines 26 are different, so that the position of the artificial bone 10 is uniquely determined.

  Further, the through holes 24 may be formed so as to coincide with the edges 28 of the defect portions having different tangential directions. Since the edge 28 is the outer peripheral edge of the defect portion, the tangential direction varies depending on the location. If the edge 28 of this different predetermined area | region and the through-hole 24 are respectively corresponded, the position of the artificial bone 10 will be decided uniquely.

  The through holes 24 formed so that the extending directions coincide with each other on different lines will be described with reference to FIG. In FIG. 6, four types of through-holes 24 are shown. The uppermost through hole 24 is rectangular, and the longitudinal direction of the rectangle can be aligned with the line. The lower through hole 24 is obtained by processing an end portion in a longitudinal direction of a rectangle into a curved shape. Further, the lower through-hole 24 has one end in the longitudinal direction tapered, and the lowermost through-hole 24 has both ends in the longitudinal direction tapered.

  Further, a bar hole is formed in the edge 28 of the defect portion as described above. Usually, there is only one bar hole, and the place can be easily visually recognized, so that it becomes a good mark. Therefore, as shown in FIG. 7, it is also preferable to form the through hole 24 so as to coincide with the line of the bar hole.

  10 artificial bones, 12 skulls, 14 openings, 16 mesh parts, 18 fixing parts, 20 fixing holes, 22 positioning parts, 24 through holes, 26 suture lines, 28 edges.

Claims (6)

In the artificial bone attached to the skull so as to cover the defect part of the skull,
A net-like portion provided in a region corresponding to the defect of the skull and having a plurality of openings;
A fixing portion provided outside the mesh-like portion and fixed to the skull;
A positioning part that is provided outside the mesh-like part and coincides with at least one line of the suture line of the skull and the edge of the defect part, and is formed with a through-hole capable of determining the position of the artificial bone with respect to the skull;
An artificial bone characterized by comprising: The artificial bone according to claim 1,
The through holes are formed so that the extending directions coincide with each other on different lines,
An artificial bone characterized by that. The artificial bone according to claim 2,
The through-holes are formed to match different suture lines,
An artificial bone characterized by that. The artificial bone according to claim 2,
The through-holes are formed so as to coincide with the edges of the defect portions with different tangential directions,
An artificial bone characterized by that. The artificial bone according to claim 2,
The through hole is formed so as to coincide with the suture line and the edge of the defect part,
An artificial bone characterized by that. The artificial bone according to claim 1,
The positioning part further has a through hole formed so as to coincide with the line of the bar hole formed at the edge of the defect part,
An artificial bone characterized by that.