KR102055795B1 - Scaffold for bone reconstruction, manufacturing method and system therefor - Google Patents

Abstract

The present invention relates to a bone support for bone reconstruction, a method and a system for producing the same. Specifically, according to one aspect of the invention, in the bone support implanted in the bone defect site for bone reconstruction of the patient, is provided to receive a load applied to the bone defect site connected to the defect cross section of the bone defect site Main support; And a coupling member connected to both ends of the main support and coupling the bone defect site with the main support, a bone support for bone reconstruction, a method and system for manufacturing the same.

Description

Bone scaffold for bone reconstruction, method and system for manufacturing thereof {SCAFFOLD FOR BONE RECONSTRUCTION, MANUFACTURING METHOD AND SYSTEM THEREFOR}

The present invention relates to a bone support for bone reconstruction, a method and a system for producing the same.

Bone support is a member that is buried in the body in the field of dentistry or orthopedics to replace the bones of the human body damaged by disease or accident. The bone support is implanted in the bone defect site and serves to compensate for the bone defect, and there are two methods for the bone support implantation. One is to implant bones from other parts of the patient into the affected area, and the other is to implant artificially produced scaffolds.

Of these, the bone graft of the patient's own bone inevitably occurs in another part of the bone extraction process for transplantation, so there is a risk of unexpected sequelae, which is only possible in very limited cases. In general, a method of implanting an artificially produced scaffold into a defect site is mainly used. In the conventional method of artificially producing and implanting a bone support, a material such as titanium or ceramic is mainly used.

By the way, in the conventional bone support manufacturing technology, the material used to manufacture the bone support has a very different physical characteristics from the bones of the human body, and it is difficult to properly consider various load states that the bone support implanted in the affected area will receive. , Physical defects in the affected area after transplantation, or in case of discomfort and severe discomfort in the surrounding tissues, due to external incompatibility as bone structures, incompatibility of materials, mechanical incompatibility, thermal incompatibility, surface incompatibility, etc. There are many problems in that it can cause secondary damage.

Accordingly, there is a need for a technique for preparing a bone support in which the physical characteristics of the missing bone of the patient are similarly imitated within an error range.

Republic of Korea Patent No. 10-1070341

Embodiments of the present invention have been made to solve the problems of the prior art as described above, to provide a bone support, a method and system for manufacturing the same, the physical characteristics of the patient's missing bones similarly mimicked within the margin of error do.

According to an aspect of the present invention, a bone support implanted into a bone defect site for bone reconstruction of a patient, the bone support comprising: a main support provided to receive a load applied to the bone defect site of the bone defect site; And a coupling member connected to both ends of the main support and including a coupling member for coupling the bone defect site and the main support to the bone support for bone reconstruction.

In addition, a fastening hole is formed in the coupling member, a screw passing through the fastening hole is inserted into the remaining bone of the bone defect site, the coupling member is coupled to the bone can be provided a bone support for bone reconstruction. have.

In addition, the main support may have a hollow therein, and a bone support for bone reconstruction having a circumferential surface surrounding the hollow may be provided.

In addition, the main support portion, a plurality of longitudinal supports for interconnecting the two coupling members connected to both ends; And a horizontal support connecting the plurality of longitudinal supports to each other, a bone support for bone reconstruction may be provided.

The main support may include a first support member; And a second support member engaged with the first support member, a bone support for bone reconstruction.

The first support member may include an assembly frame having a first assembly hole formed therein for engagement with the second support member, and the second support member may be disposed at a position corresponding to the first assembly hole formed in the assembly frame. 2 is formed, the bone assembly for bone reconstruction, wherein the first assembly hole and the second assembly hole is fastened to each other by inserting a screw into the first assembly hole and the second assembly hole.

The main support may include an outer support member having a hollow formed therein; And an inner support member provided inside the outer support member, a bone support for bone reconstruction may be provided.

And a connecting frame connecting the outer supporting member and the inner supporting member, wherein the connecting frame is provided to be formed along a circumference of the inner supporting member and is connected to the inner supporting member and the outer supporting member. frame; And a vertical frame connected to the horizontal frame, the vertical frame extending from a circumference of the inner support member in a direction deviating from the direction in which the horizontal frame extends.

Further, the horizontal frame may be provided in plurality, and the vertical frame may be provided to interconnect the plurality of horizontal frames, a bone support for bone reconstruction may be provided.

The main support may include a plurality of connecting pillars connecting the two coupling members and supporting a load applied to the bone defect site; A bone support for bone reconstruction may be provided, comprising a first frame and a second frame provided at both ends of a plurality of said connecting pillars.

In addition, the main support may further include a bone support for bone reconstruction, which further includes a reinforcement formed to surround the plurality of connection pillars.

On the other hand, according to another embodiment of the present invention, a method for manufacturing a bone support implanted in the bone defect site for bone reconstruction of the patient, comprising the steps of measuring the physical property data for each part of the human body in the storage unit; Obtaining scan data of the bone defect site; Obtaining a regenerated image of the bone defect site using the scan data; Generating cross-sectional data from the regenerated image; Generating data on the cross-sectional shape of the bone support using the cross-sectional data; Generating data on the overall shape of the bone support using the cross-sectional shape data of the bone support; And manufacturing the bone support based on the overall shape data of the bone support, there may be provided a method for producing a bone support for bone reconstruction.

In addition, the step of generating data on the cross-sectional shape, selecting the design parameters for the physical properties of the bone support and the bone defect site; And setting a value of the design variable of the bone support so as to fall within a preset error range of the value of the design variable for the bone defect site. A method of manufacturing a bone support for bone reconstruction may be provided. have.

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On the other hand, according to another embodiment of the present invention, in the system for producing a bone support implanted in the bone defect site for bone reconstruction of the patient, the physical property data and the scan of the bone defect site measured for each part of the human body A data collection unit for obtaining data; A storage unit which stores data collected by the data collection unit; A cross-sectional data generator which obtains a regenerated image of the bone defect area using the scan data and generates cross-sectional data through the regenerated image; A shape generating unit generating data on the cross-sectional shape of the bone support by using the cross-sectional data and generating data on the overall shape of the bone support by using the cross-sectional shape data; And a manufacturing unit for manufacturing the bone support based on the overall shape data of the bone support, a system for manufacturing a bone support for bone reconstruction may be provided.

The apparatus may further include a variable selecting unit configured to select a design variable for a physical property of the bone support and the bone defect site, wherein the shape generating unit is within a preset error range of the value of the design variable for the bone defect site. A system for making a bone support for bone reconstruction can be provided that sets the value of the design parameter of the bone support to produce the cross-sectional shape data.

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According to embodiments of the present invention, a bone support in which the physical characteristics of the missing bone of the patient can be similarly simulated within the margin of error can be manufactured and implanted, so that the patient can be affected by the load that the bone support will receive in everyday life. Nevertheless, there is an effect that results similar to those before the bone defect can be obtained.

1 is a view showing a bone support according to a first embodiment of the present invention.
2 is a view showing a bone support according to a second embodiment of the present invention.
3 is a view showing a bone support according to a third embodiment of the present invention.
4 is a view showing a bone support according to a fourth embodiment of the present invention.
5 is a view showing a bone support according to a fifth embodiment of the present invention.
FIG. 6 is a block diagram illustrating a manufacturing system for manufacturing the bone support shown in FIGS. 1 to 5.
FIG. 7 is a flow chart illustrating a method of making a bone support using the manufacturing system of FIG. 6.
FIG. 8 is a conceptual diagram illustrating a process of obtaining a regenerated image using a scanned image of a bone defect part in the manufacturing method of FIG. 7.
FIG. 9 is a conceptual diagram illustrating a process of generating data on a cross-sectional shape of a bone support in the manufacturing method of FIG. 7.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation according to the embodiment of the present invention. The following description is one of several aspects of the invention that can be claimed, and the following description may form part of the detailed description of the invention. However, in describing the present invention, a detailed description of known configurations or functions may be omitted to clarify the present invention.

As the present invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. These terms are only used to distinguish one component from another. When a component is said to be 'connected' or 'connected' to another component, it may be directly connected to or connected to that other component, but it may be understood that another component may exist in between Should be. The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Bone scaffold according to embodiments of the present invention is provided to help to reconstruct the bone defect and at the same time to compensate for the bone defect is implanted in the bone defect site of a patient suffering from a bone defect due to factors such as fracture accidents, surgery, etc. . In addition, the system and method for producing a bone support according to embodiments of the present invention is a variety of loads such as compression, tension, shear, bending, buckling, etc. resulting from the bone-defective body characteristics of the patient and the activities in everyday life after recovery It is provided for designing and manufacturing a bone support capable of withstanding.

To this end, the system and method for producing a bone support according to embodiments of the present invention define the main mechanical strength parameters and to have similar structural strength parameters within the margin of error depending on the physical characteristics of the bone defect site of the patient. It can be used to design a specific shape and material of, and to create a patient-specific bone support based on this. The bone support thus produced may have a variety of shapes, and this shape may be determined by whether or not to which site is implanted, the amount of the missing bone, the shape of the missing site, and the like. Hereinafter, various embodiments of the bone support thus produced will be described, and then a detailed system and method for manufacturing the same will be described.

1 to 5 show various shapes of bone supports produced by the manufacturing method according to the invention. The shape of the bone support shown in each drawing is a shape having a predetermined thickness derived according to the design result, but for simplicity, the thickness is omitted and represented by a solid line. Shapes of the bone support shown in Figures 1 to 5 are examples of shapes designed and manufactured by the manufacturing method according to the present invention, the shape of the bone support is a variety of factors, such as the situation of the patient, bone defects, the requirements of the doctor Depending on the design can be manufactured.

Referring to FIG. 1, the bone support 10 according to the first embodiment of the present invention may include a main support part 100 and a coupling member 200. The main support part 100 may be manufactured by simulating the bone shape of the bone defect site, thereby supplementing the bone defect of the bone defect site. To this end, the main support 100 is provided to be connected to the defect cross section of the bone defect site to receive a load applied to the bone defect site. In addition, the main support portion 100 may have a hollow therein, and may be provided in a shape having a circumferential surface surrounding the hollow, and the circumferential surface may be formed in a shape extending smoothly from the remaining bone shape of the bone defect site. have.

The coupling member 200 is connected to both ends of the main support part 100, and is provided to couple the bone defect site with the main support part 100. At this time, the coupling member 200 is formed with a receiving space in which the end portion of the bone defect portion can be accommodated, the periphery of the receiving space may be provided in a shape surrounding the wall. In addition, a fastening hole 202 for screwing into the remaining bone of the bone defect site may be formed.

The coupling member 200 may be provided extending from both ends of the main support part 100, may be formed integrally with the main support part 100, and may be manufactured separately from the main support part 100 to be provided as a main support part ( It may be provided in a manner combined with 100).

The first embodiment described above may be provided as a basic shape of the bone support 10, but the shape of the bone support may be variously modified. For example, as shown in FIG. 2, a bone support 11 according to a second embodiment of the present invention may be provided. The second embodiment is different from the first embodiment in the shape of the main support part 100, and the difference will be mainly described, and the same parts will use the first embodiment.

The main support portion 100 of the bone support 11 according to the second embodiment is a plurality of longitudinal supports 110 and a plurality of longitudinal supports 110 interconnecting two coupling members 200 connected to both ends of each other. It may include a horizontal support 120 for connecting. The load applied to the bone defect may be primarily applied to the vertical support 110, and the vertical support 110 may be supported by the horizontal support 120. As shown in FIG. 2, the horizontal support 120 may be provided in one layer or may be provided in a plurality of layers. In addition, the vertical support 110 and the horizontal support 120 may be formed integrally, or may be provided in a manner that is combined after being manufactured separately from each other.

Meanwhile, FIG. 3 shows bone supports 12a and 12b according to the third embodiment of the present invention. In the bone supports 12a and 12b according to the third embodiment, the main support part 100 may be made of two or more members so that each member may be fastened to each other by screwing or the like. Specifically, the bone support 12a illustrated in FIG. 3A may include a first support member 102 and a second support member 104 fastened to the first support member 102.

At this time, the first support member 102 includes an assembly frame 108 in which a first assembly hole 106 for fastening with the second support member 104 is formed, and the second support member 104 includes an assembly frame ( The second assembly hole 107 may be formed at a position corresponding to the first assembly hole 106 formed in the 108. Accordingly, a screw is inserted into the first assembly hole 106 and the second assembly hole 107 so that the first support member 102 and the second support member 104 are coupled to each other. As a result, the main support part 100 may be formed.

In addition, the coupling member 200 may also be provided divided into two members, the first assembly 204 and the second assembly 206, the first assembly 204 is provided at both ends of the first support member 102 Extending from the second assembly 206 may extend from both ends of the second support member 104. In this case, the first assembly 204 and the second assembly 206 may not be fastened to each other, or may be fastened to each other through a separate fastening member. In the former case, as shown in FIG. 3A, the main assembly 204 is connected to the first and second support members 104 and 106, respectively. Positions relative to 100 may be maintained respectively.

The assembly frame 108 may be formed on the first support member 102 or on the second support member 104, and as shown in FIG. 3, the first support member 102 and the second support. All of the members 104 may be formed. In addition, the assembly frame 108 may be formed at one end of the first support member 102 and / or the second support member 104, and may have a step shape to have two corners.

In addition, in the case of the bone support 12b shown in Fig. 3 (b), instead of the coupling member 200, the assembly protrusion protruding in the vertical direction from the first support member 102 and / or the second support member 104. 109 may be engaged with the remaining bone of the bone defect site. To this end, a second assembly hole 107 is formed in the assembly protrusion 109, and the first assembly hole 106 may be formed at a position on the assembly frame 108 corresponding to the position of the second assembly hole 107. . Accordingly, the screw inserted into the first assembly hole 106 and the second assembly hole 107 is inserted into the remaining bone so that the main support part 100 may be implanted and fixed to the bone defect site.

In this embodiment, the main support 100 and the coupling member 200 is shown as an example divided into two members, but the spirit of the present invention is not limited to this, the main support 100 is three or more members It is also possible to be divided and formed by combining each member.

Meanwhile, FIG. 4 shows a bone support 13 according to the fourth embodiment of the present invention. In the bone support 13 according to the fourth embodiment, the main support part 100 may include an outer support member 135, an inner support member 130, and a connection frame 140.

The outer support member 135 may have a hollow formed therein, and the inner support member 130 may be provided in the hollow of the outer support member 135. In addition, the connection frame 140 may be provided to connect the outer support member 135 and the inner support member 130. In this case, the connecting frame 140 is provided to be formed along the circumference of the inner support member 130 to the horizontal frame 142 and the horizontal frame 142 connected to the inner support member 130 and the outer support member 135. It may include a vertical frame 144 connected to extend in a direction deviating from the direction in which the horizontal frame 142 extends from the circumference of the inner support member 130.

The horizontal frame 142 may be provided in plurality, and the vertical frame 144 may be provided to interconnect the plurality of horizontal frames 142. Accordingly, the outer support member 135 and the inner support member 130 are connected by the horizontal frame 142 and the vertical frame 144 are fixed to each other.

The outer support member 135, the inner support member 130 and the connecting frame 140 may be formed integrally, or each may be manufactured separately and fastened to each other.

Meanwhile, FIG. 5 shows a bone support 14 according to a fifth embodiment of the present invention. The main support part 100 of the bone support 14 according to the fifth embodiment may include a connection pillar 150, a reinforcing rod 160, a first frame 162, and a second frame 164.

The connection pillars 150 may be provided in plural to connect two coupling members 200 provided at both ends of the main support part 100, and may be provided to support a load applied to a bone defect site of the patient. The connection column 150 may be formed in a curved bar shape as a cross-section of a square, or may be formed in a pipe shape having a hollow therein. In addition, first and second frames 162 and 164 may be provided at both ends of the plurality of connection pillars 150. In this case, the first frame 162 and the second frame 164 may be provided to connect the plurality of connection pillars 150 and the coupling member 200. In addition, the reinforcing table 160 may be formed to surround the plurality of connection columns 150 may be provided to reinforce the rigidity of the main support portion (100).

The connecting pillar 150, the reinforcing rod 160, the first frame 162 and the second frame 164 may be integrally formed, or may be separately manufactured and fastened to each other.

Hereinafter, a manufacturing system for manufacturing a bone support as described above and a method for manufacturing a bone support using the same will be described.

Referring to FIG. 6, the system 20 for preparing a bone support according to an embodiment of the present invention includes a data collector 22, an input unit 23, a storage unit 24, and a cross-sectional data generator 25. The selection unit 26, the shape generating unit 28 and the manufacturing unit 29 may be included.

The data collection unit 22 may obtain physical property data measured for each part of the human body and scan data of the bone defect site. The physical data measured for each part of the human body is provided by separate test equipment, which is applied to people of various heights and weights according to their daily movements, ie compression, tension, bending, buckling, Data obtained by measuring fatigue loads. In addition, the data collection unit 22 may obtain scan data obtained through CT imaging of a bone defect site of a patient in which a bone defect has occurred. The data collected by the data collector 22 may be transferred to and stored in the storage 24.

The input unit 23 may be provided to receive a necessary specification and design constraints of the bone support from a user such as a doctor. At this time, the necessary specification and design constraints to be input may be, for example, the shape of a hole formed in a specific site, the spacing of each member in a specific cross section, and the like. To this end, the input unit 23 may include an interface such as a keypad. The necessary specifications and design constraints input through the input unit 23 may be stored in the storage unit 24 and may be reflected in generating the cross-sectional data of the bone support in the shape generating unit 28.

The cross-sectional data generator 25 is obtained through the data collector 22 to obtain a regenerated image (Figs. 8 and 3) of the bone defect site by using scan data of the bone defect site stored in the storage unit 24. The obtained regenerated image 3 can generate cross-sectional data of the bone defect site. In this case, each cross section of the regenerated image 3 may be indexed and displayed from S ₀ to S _n .

The variable selector 26 may select design variables for physical properties of the bone support and the bone defect site. At this time, the variable selector 26 selects the necessary parameters for the design of the bone support by using the physical property data corresponding to the bone defect site and the scan data of the bone defect site among the physical property data of the human body stored in the storage unit 24. can do. The design variables selected by the variable selector 26 include at least one of a cross-sectional area, an allowable strength, a center of gravity, a principal axis of moment of inertia, and a moment of inertia of the center of gravity and the center of gravity. It may include one or more.

The shape generating unit 28 generates data on the cross-sectional shape of the bone support by using the cross-sectional data of the generated regenerated image 3, and generates data on the overall shape of the bone support by using the generated cross-sectional shape data. can do. In this case, the shape generator 28 may generate cross-sectional shape data of the bone support so as to correspond to each cross-section of the regenerated image 3. The cross-sectional shape data of the bone support thus generated may be matched one-to-one with each cross-sectional data of the regenerated image 3 generated by the cross-sectional data generator 25, and S ₀ , like the cross-sectional data of the regenerated image 3. To S _n can be indexed and displayed.

In addition, the shape generating unit 28 sets the value of the design variable of the bone support so as to fall within the preset error range of the value of the design variable for the bone defect site selected by the variable selecting unit 26 to obtain the cross-sectional shape data. Can be generated.

In addition, the shape generating unit 28 may generate the cross-sectional shape data of the bone support by reflecting the necessary specifications and design constraints input through the input unit 23. In other words, the shape generator 28 may generate the cross-sectional shape data of the bone support by reflecting not only each design variable value but also input requirements and design constraints.

The cross-sectional shape data of the bone support generated through the shape generating unit 28 may be generated in a single shape, or may be generated in a plurality of possible shapes satisfying necessary conditions. In this case, the shape generating unit 28 may receive an input from a user so that one of the plurality of possible shapes of the corresponding cross section is selected or arbitrarily selected.

In addition, any of the cross-sectional shape data (S _i) of the cross-sectional position of the shape generator 28 is a cross-sectional shape data of the bone support that is generated by may have a predetermined thickness and may have a constant thickness along the circumference The thickness may vary along the perimeter and may have a shape cut along the perimeter. This is a function of the shape and thickness of the dense bone at the bone defect site.

The manufacturing unit 29 may manufacture the bone support based on the overall shape data of the generated bone support. In this case, the manufacturing unit 29 may produce a bone support by, for example, 3D printing, insert / injection molding.

Hereinafter, the method of manufacturing a bone support using the manufacturing system 20 which has the structure as mentioned above is demonstrated.

Referring to FIG. 7, in the method of manufacturing a bone support according to an embodiment of the present invention, measuring physical property data of each part of the human body and storing it in the storage unit 24 (S10), scanning the bone defect site Acquiring the data (S20), obtaining a regenerated image of the bone defect site using the scan data (S30), generating a cross-sectional data through the regenerated image (S40), cross-section of the bone support using the cross-sectional data Generating data on the shape (S50), generating data on the overall shape of the bone support using the cross-sectional shape data of the bone support (S60) and the bone support based on the overall shape data of the bone support It may include the step of producing (S70).

In addition, the method for manufacturing a bone support according to the present embodiment may further include receiving input requirements and design constraints of the bone support from a user such as a doctor through the input unit 23. At this time, the necessary specification and design constraints to be input may be, for example, the shape of a hole formed in a specific site, the spacing of each member in a specific cross section, and the like. The necessary specifications and design constraints thus input may be stored in the storage unit 24. Each cross-sectional data of the bone support is generated in step S50 of generating data on the cross-sectional shape of the bone support using the cross-sectional data. Can be reflected.

8 and 9, in the step S40 of generating the cross-sectional data through the regenerated image, the cross-sectional shape obtained by cutting the regenerated image 3 of the bone defect site at predetermined intervals may be generated as data. In this case, each cross section of the regenerated image 3 may be indexed and displayed from S ₀ to S _n .

In addition, generating data on the cross-sectional shape of the bone support using the cross-sectional data (S50), the step of selecting the design parameters for the physical properties of the bone support and bone defect site (S52) and design for the bone defect site It may include the step (S54) of setting the value of the design variable of the bone support to fall within the predetermined error range of the value of the variable. In this case, the regenerated image 3 may be generated by a pre-stored algorithm from the shape of the missing cross section 2 of the remaining bone 1 of the bone missing part.

In addition, the primary support of the bone support so as to correspond to the appearance of each cross-sectional shape (Figs. 9 (a-1), 9 (b-1), 9 (c-1)) of the regenerated image 3 of the bone defect site. 9 (a-2), 9 (b-2), 9 (c-2) are generated, and the final design of the bone support using the design variables selected by the variable selector 26. Cross-sectional shapes (Figs. 9 (a-3), 9 (b-3) and 9 (c-3)) can be generated. As shown in Figure 9, the shape of the bone support according to each cross section may be different from each other.

Accordingly, the cross-sectional shape data of the bone support may be generated to have a one-to-one matching with respect to the cross-sectional shape of S ₀ to S _n of the regenerated image 3, and each cross-sectional shape data of the bone support is one-to-one matching regenerated image It may have a cross-sectional shape having a physical property similar to the physical property according to each design variable value of the cross-sectional shape data of (3).

In addition, it is possible to generate the cross-sectional shape data of the bone support by reflecting the necessary specifications and design constraints input through the input unit 23. In other words, the cross-sectional shape data of the bone support may be generated by reflecting not only the values of each design variable selected in the step S52 of selecting the design variable, but also input requirements and design constraints.

The cross-sectional shape data of the bone support thus generated may be generated in a single shape, or may be generated in a plurality of possible shapes satisfying necessary conditions. When generated in a plurality of shapes, the cross-sectional shape data of the bone support may be selected by the user from one of a plurality of possible shapes of the corresponding cross section, or may be arbitrarily selected.

The cross-sectional shape data, either one of the cross-sectional shape data (S _i) of the cross-sectional position of the bone support may have a predetermined thickness and may have a constant thickness along the periphery, it may be varied in thickness along the periphery It may have a shape cut along the circumference. This is a function of the shape and thickness of the dense bone at the bone defect site.

In this way, the final cross-sectional shape of the bone support generated from S ₀ to S _n may be smoothly connected to generate data on the overall shape of the bone support.

According to the bone support according to the embodiments of the present invention, a method and a system for manufacturing the same as described above, it is possible to produce and implant a bone support in which the physical characteristics of the missing bone of the patient are similarly mimicked within an error range. In addition, despite the effect of the load that the bone support will receive in everyday life, there is an effect that results similar to those before the bone defect can be obtained.

As described above as a specific embodiment of a bone support for bone reconstruction, a method of manufacturing and a system thereof according to an embodiment of the present invention, but this is only an example, the present invention is not limited thereto, and the basic spirit disclosed in the present specification It should be construed as having the broadest range to follow. Those skilled in the art can combine / substitute the disclosed embodiments to implement a pattern of a timeless shape, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, it is apparent that such changes or modifications belong to the scope of the present invention.

10, 11, 12a, 12b, 13, 14: bone support
100: main support
102: first support member 104: second support member
106: first assembly hole 107: second assembly hole
108: assembly frame 109: assembly protrusion
110: vertical support 120: horizontal support
130: inner support member 135: outer support member
140: connecting frame 150: connecting pillar
160: reinforcement 200: coupling member
202: fastening hole 204: first assembly
206: second binder 20: bone support production system
22: data collection unit 23: input unit
24: storage unit 25: section data generation unit
26: variable selection unit 28: shape generating unit
29: Production Department

Claims (17)

A bone support implanted into a bone defect site for bone reconstruction of a patient,
A main support part connected to a defect section of the bone defect site and provided to receive a load applied to the bone defect site; And
It is connected to both ends of the main support, including a coupling member for coupling the bone defect site and the main support,
The design variable of the bone support is formed to fall within a preset error range of the value of the design variable for the bone defect site,
The design variable of the bone support includes at least one or more of a cross-sectional area, an allowable strength, a center of gravity, a major axis of the cross-sectional secondary moment and a cross-sectional secondary moment in the major axis,
The design variable for the bone defect site includes at least one or more of a cross-sectional area, an allowable strength, a center of gravity, a major axis of the cross-sectional secondary moment, and a cross-sectional secondary moment in the major axis,
The coupling member extends along the circumferential surface of the main support to form a receiving space in which an end portion of the bone defect portion may be accommodated.
Fastening holes are formed at both sides of the coupling member,
A screw passing through the fastening hole is inserted into a portion accommodated in the accommodation space among the remaining bones of the bone defect site, so that the coupling member is coupled to the bone.
Bone support for bone reconstruction. delete The method of claim 1,
The main support has a hollow therein, and has a circumferential surface surrounding the hollow,
Bone support for bone reconstruction. The method of claim 1,
The main support portion,
A plurality of longitudinal supports interconnecting the two coupling members connected at both ends; And
Including a horizontal support connecting the plurality of vertical supports to each other,
Bone support for bone reconstruction. The method of claim 1,
The main support portion,
A first support member; And
A second support member engaged with the first support member,
Bone support for bone reconstruction. The method of claim 5,
The first support member,
An assembly frame having a first assembly hole formed therein for engagement with the second support member;
A second assembly hole is formed in the second support member at a position corresponding to the first assembly hole formed in the assembly frame,
When the screw is inserted into the first assembly hole and the second assembly hole, the first assembly hole and the second assembly hole are fastened to each other.
Bone support for bone reconstruction. The method of claim 1,
The main support portion,
An outer support member having a hollow formed therein; And
Further comprising an inner support member provided inside the outer support member,
Bone support for bone reconstruction. The method of claim 7, wherein
A connection frame connecting the outer support member and the inner support member;
The connecting frame,
A horizontal frame provided to be formed along a circumference of the inner support member and connected to the inner support member and the outer support member; And
A vertical frame connected to the horizontal frame, the vertical frame extending from a circumference of the inner support member in a direction deviating from the direction in which the horizontal frame extends;
Bone support for bone reconstruction. The method of claim 8,
The horizontal frame is provided in plurality,
The vertical frame is provided to interconnect a plurality of the horizontal frames,
Bone support for bone reconstruction. According to claim 1,
The main support portion,
A plurality of connecting pillars connecting the two coupling members and supporting a load applied to the bone defect site;
Including a first frame and a second frame provided at both ends of the plurality of connecting pillars,
Bone support for bone reconstruction. The method of claim 10,
The main support portion,
Further comprising a reinforcing rod formed to surround a plurality of the connecting pillar,
Bone support for bone reconstruction. In the method for producing a bone support according to claim 1,
Measuring physical property data of each part of the human body and storing the measured data in a storage unit;
Obtaining scan data of the bone defect site;
Obtaining a regenerated image of the bone defect site using the scan data;
Generating cross-sectional data from the regenerated image;
Generating data on the cross-sectional shape of the bone support using the cross-sectional data;
Generating data on the overall shape of the bone support using the cross-sectional shape data of the bone support; And
Producing the bone support based on the overall shape data of the bone support,
Method of making a bone support for bone reconstruction. The method of claim 12,
Generating data about the cross-sectional shape,
Selecting the design parameters of the bone support and the design parameters for the bone defect site; And
Setting a value of the design variable of the bone support to fall within a preset error range of the value of the design variable for the bone defect site,
Method of making a bone support for bone reconstruction. delete In the system for producing a bone support according to claim 1,
A data collection unit for obtaining physical data measured for each part of the human body and scan data of the bone defect area;
A storage unit which stores data collected by the data collection unit;
A cross-sectional data generator which obtains a regenerated image of the bone defect area using the scan data and generates cross-sectional data through the regenerated image;
A shape generating unit generating data on the cross-sectional shape of the bone support by using the cross-sectional data and generating data on the overall shape of the bone support by using the cross-sectional shape data; And
It includes a manufacturing unit for manufacturing the bone support based on the overall shape data of the bone support,
System for the production of bone supports for bone reconstruction. The method of claim 15,
And a variable selecting unit that selects the design variable of the bone support and the design variable for the bone defect site.
The shape generating unit generates the cross-sectional shape data by setting the value of the design variable of the bone support so as to fall within a preset error range of the value of the design variable for the bone defect site,
System for the production of bone supports for bone reconstruction.
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