KR102014166B1 - Porous Augment With Solid Surface - Google Patents

Abstract

The present invention relates to a porous face with a solid face, and more particularly, to a bone growth portion having a shape complementary to the shape of the missing bone portion and including pores, and to reinforce the bone growth strength of the bone growth portion. It is configured to include a shell portion coupled to the growth portion to form a solid surface, to reinforce the mechanical strength of the bone growth portion made of a porous material, relates to a porous face formed solid solid.

Description

Porous Augment With Solid Surface

The present invention relates to a porous face with a solid face, and more particularly, to a bone growth portion having a shape complementary to the shape of the missing bone portion and including pores, and to reinforce the bone growth strength of the bone growth portion. It is configured to include a shell portion coupled to the growth portion to form a solid surface, to reinforce the mechanical strength of the bone growth portion made of a porous material, relates to a porous face formed solid solid.

A joint is a part of the body that is in contact with a structure in which two or more bones can move. Human joints can cause various problems due to repetitive damage, arthritis, and aging. If a joint is damaged enough to lose its proper function, a joint replacement may be performed to replace the damaged joint with an implant. .

Artificial arthroplasty is performed by making an implant having a shape complementary to the anatomical shape of the damaged joint, cutting the bone of the damaged joint within a predetermined range, and implanting the implant into the incision.

Compensate for the missing bone area by cutting, when the damaged joint area is extensively wide, when the local severe injury is incurred, and when the bone cutting site needs to be grasped in whole or in part. Augment may be used for this purpose.

The augment is configured to compensate for the missing bone, and is configured to have a shape complementary to the shape of the missing bone, and thus is seated on an empty space made by the cut bone.

In general, the augment may be formed in a solid form using a biomaterial (biometal, bioceramic, biopolymer) or the like as a material. However, when the augment is formed in a solid shape with a solid inside, the bone may not be grown in an area corresponding to the space occupied by the augment.

In the field of arthroplasty, there has been a continuous effort to solve osteolysis occurring in the area where the bone of the implant and the patient are in contact. The bone lysis phenomenon refers to a phenomenon in which the bones of the implant and the patient are not completely fused and the bone melts at the contact area between the implant and the patient.

This problem is caused by the fact that the joint surface of the implant has a different property from the patient's bone. When the augment coming into contact with the patient's bone has a solid shape as described above, the bone joint surface of the implant It may not coalesce with the patient's bones and may cause osteolysis problems.

Therefore, in order to prevent such a problem, a method of promoting spontaneous bone growth between the bone joint surface of the implant or the bone joint surface of the implant and the patient's bone, so that the bone of the patient or implant and the patient can be strongly bonded. Is considered.

To this end, conventionally, there has been an effort to promote autogenous bone growth of a patient through a porous material by constructing the bone joint surface of the implant or the augment with a porous material.

1 is a view of a conventional porous agglomeration, the prior art 90 is disclosed in US Patent No. 9,707,080 (July 18, 2017).

Referring to the contents shown in FIG. 1, the prior art 90 constitutes a porous layer 93 in which a plurality of pores are formed on a bone joint surface of an implant 91 used for knee arthroplasty, and the missing bone is lost. The augment 95 for supplementing is also characterized by a porous material. As shown in FIG. 1, the augment 95 may be coupled to the porous layer 93 of the implant 91 through a fastening means.

According to the prior art 90, as the porous layer 93 is formed on the bone bonding surface, it is possible to promote the autogenous bone growth of the patient from the porous layer 93 formed with a plurality of pores and implants Strong coalescence can be made between the bones of the patient.

In addition, the augment 95 for compensating for the missing bone is also made of a porous material, so that the empty space from which the bone is removed is filled with the augment 95, and the patient 95 through the augment 95 made of the porous material. Autogenous bone growth was also promoted.

As shown in the prior art 90, there is no question that when the augment 95 is composed only of a porous material having a plurality of pores, it can promote autogenous bone growth of the patient. However, in the case of such porous fragments 95, there are other problems that their mechanical strength is lowered due to the numerous voids formed inside and outside.

In general, augmentation causes a lot of local loss when dismantling an existing implant when removing an implant that has been implanted through a joint replacement surgery and reoperating it. .

As the augment is mainly used for local compensation of the bone, the implant to which the augment is combined may have an asymmetrical shape of the implant as a whole. As a result, the asymmetric shape of the implant may cause deformation of the porous fragment 95, which is relatively stiff, due to the load applied to the implant. The porous material may promote bone growth of the patient, but since it lowers the mechanical strength of the augment 95, it would be required to provide a separate means to supplement the mechanical strength of the augment.

FIG. 2 is a view illustrating that the porous segment and the implant of FIG. 1 are coupled by a fastening means. Referring to Figure 2, the porous augment can be combined as shown in Figure 2 through a separate fastening means (L) with the implant. The fastening means (L) by applying a force to strongly adhere the porous augment and the implant, so that the two members can be strongly bonded to each other.

However, due to the strong pressing force of the fastening means (L), the relatively low mechanical strength of the porous augment (95) may not be able to overcome the force by the fastening means (L) may be damaged or crushed or broken. This damage does not simply end with the problem of the porous segment 95.

Damaged augment (95) can be precisely matched on the cut bones and can be seated to form a fine separation space, which is to continue the microscopic movement of the implant during the life of the patient after a joint replacement surgery Repeated movements of the implant can cause severe sequelae in the patient, such as causing the implant to loosen from the patient's bone and cause it to dislodge or to dissolve the bone.

Therefore, the coupling means (L) when forming the through hole (951) in the porous segment (95) to connect the two members through the fastening means (L) in order to couple the porous segment (95) to the implant (91) It is necessary to provide a separate configuration to complement the mechanical stiffness around the through hole in contact with.

Various methods may be used to construct the augment 95 entirely with a porous material, but it may be preferable to use a 3D printing method in order to accurately and easily implement a plurality of fine pores.

Since the 3D printer mainly uses a method of stacking materials, there is a need for a means for supporting an empty space in the output printed by the 3D printer. Without such support means, the 3D printer may stack materials in the air, and sagging or the like may occur in the printed output.

As described above, the augment has a shape complementary to the anatomical shape of the patient, and together with the supporter supporting the atypical augment in order to implement the atypical augment in a previously planned shape by a 3D printing method. You need to do it.

3 is a view illustrating a supporter coupled to an output during 3D printing. Referring to FIG. 3, when performing 3D printing, not only the output P is printed, but the supporter S supporting the output P. ) Is also displayed.

After all, in order to obtain the final output (P) it is necessary to remove the supporter (S) bonded to the output (P), if the output (P) is a weak mechanical rigidity, such as the porous segment 95 described above, It is never easy to remove the supporter S from the output P. FIG. For example, the porous material may fall off together with the supporter S by an external force applied in the process of removing the supporter S, or the porous material may be damaged first.

Therefore, when the augment 95 is entirely made of a porous material as in the prior art 90, the supporter is inevitably supported on the augment 95 in order to output the augment 95 complementary to the anatomical shape of the patient. (S) is bound to be outputted, and the supporter (S) outputted together attached to the augment (95) should be separated from the augment (95). In this process, a relatively rigid porous augment (95) ) May cause damage.

Therefore, it is necessary to solve the above problems caused by the supporter S when the porous fragment 95 is to be output using the 3D printer.

In addition, the particles may be attached to the output of the porous fragment (95), these particles are separated from the fragment (95) after the implant (95) is implanted in the body of the patient's body May cause adverse reactions in vivo.

Porous augment (95) output by the 3D printing is subjected to a cleaning process, but has a number of micropores in and out, bar virtually impossible to remove the fine particles. In particular, in the case of the microparticles located deep inside the porous segment 95, the removal is not easy.

When the porous augment 95 where the microparticles have not been completely removed is implanted into the patient's body as it is, the microparticles can act as a causative agent of potential biological adverse reactions. Breaking away from blood vessels can cause more serious problems such as inflammation and tissue necrosis.

Therefore, when constructing a porous augment to be implanted in the body, it is necessary to provide a separate means on the porous augment to prevent the diffusion of the microparticles so that the microparticles do not cause an adverse reaction in vivo in the patient. something to do.

The present invention has been made to solve the above problems,

An object of the present invention includes a bone growth portion having a shape complementary to the shape of the missing bone portion and a shell portion coupled to the bone growth portion to reinforce the strength of the bone growth portion to form a solid surface to reinforce the strength of the bone growth portion. It is configured to provide a porous face formed with a solid face, reinforcing the mechanical strength of the bone growth portion made of a porous material.

Another object of the present invention, the shell portion is configured to be formed on the outer surface of the bone growth portion, to complement the mechanical strength of the bone growth portion composed of a porous material by the shell portion, so that the fine particles do not fall from the bone growth portion, It is to provide a porous surface with a solid face formed.

Another object of the present invention, the shell portion is configured to be formed on the outer surface of the bone growth portion that is not in contact with the bone of the outer surface of the bone growth portion, the shell portion is formed in the place where there is no fear of fine particles falling Instead, the present invention provides a porous face formed with a solid face having a shell portion only at a point where the microparticles may be exposed to the living body of the patient without being exposed to the bone.

Still another object of the present invention is that the shell portion is formed on the outer surface of the bone growth portion that is not in contact with the implant of the outer surface of the bone growth portion, the shell portion is formed in the place where there is no fear of falling fine particles in contact with the implant Instead, the present invention provides a porous face formed with a solid face having a shell portion only at a point where the microparticles may be exposed to the living body of the patient without being exposed to the implant.

Still another object of the present invention is that the shell portion is formed so as to cover the entire exposed surface that is not bonded to the bone without contacting the implant in the outer surface of the bone growth portion, so that the fine particles are separated from the bone growth portion in vivo It is to provide a porous face formed with a solid face, which prevents inducing an adverse reaction in advance.

Still another object of the present invention is that the shell portion further includes a through hole on a position corresponding to one end of the hole portion formed on the exposed surface, and the through hole is configured to communicate with the hole portion, so that one end of the hole portion is exposed. When formed on the surface is to provide a porous surface with a solid surface formed so that one end of the hole portion is not blocked by the shell portion in the process of forming the shell portion on the exposed surface.

Still another object of the present invention is to configure the shell part to have a greater strength than the bone growth part, so that the bone growth part that can be easily deformed due to its relatively low rigidity can be protected by the strong shell part. To provide a porous surface with a solid face formed.

Still another object of the present invention is to allow the supporter to be coupled to the shell portion to facilitate removal of the supporter generated in the process of outputting the porous fragment by 3D printing. It is to provide a porous fragment, so that the porous portion on which the solid face is formed is not damaged.

Still another object of the present invention is that the augment is configured such that the coupling force of the shell portion and the bone growth portion is greater than the coupling force of the shell portion and the supporter, so that the fragments are not damaged in the process of removing the supporter from the shell portion. To provide a porous face formed with a solid face.

Still another object of the present invention is to configure the augmented to be manufactured by 3D printing, so that it is possible to accurately implement the augment formed with a plurality of voids.

The present invention is implemented by the embodiment having the following configuration to achieve the above object.

According to an embodiment of the present invention, the present invention has a shape complementary to the shape of the missing bone site, the bone growth portion comprising a void, and solid to combine with the bone growth portion to reinforce the strength of the bone growth portion And a shell portion forming a surface.

According to another embodiment of the present invention, the shell portion, characterized in that formed on the outer surface of the bone growth portion.

According to another embodiment of the present invention, the shell portion, characterized in that formed on the outer surface of the bone growth portion that is not in contact with the bone of the outer surface of the bone growth portion.

According to another embodiment of the present invention, the shell portion, characterized in that formed on the outer surface of the bone growth portion that is not in contact with the implant of the outer surface of the bone growth portion.

According to another embodiment of the present invention, the shell portion is characterized in that it is formed so as to cover the entire exposed surface that is not in contact with the bone without contacting the implant of the outer surface of the bone growth portion.

According to another embodiment of the present invention, the shell portion further comprises a through hole on a position corresponding to one end of the hole portion formed on the exposed surface, wherein the through hole is in communication with the hole portion. It is done.

According to another embodiment of the present invention, the shell portion, characterized in that having a greater strength than the bone growth portion.

According to a further embodiment of the present invention, the object is characterized in that the supporter is coupled to the shell portion.

According to a further embodiment of the present invention, the augment is characterized in that the coupling force of the shell portion and the bone growth portion is greater than the coupling force of the shell portion and the supporter.

According to another embodiment of the invention, the invention is characterized in that the augment is produced by 3D printing.

The present invention can obtain the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention is configured to include a bone growth portion having a shape complementary to the shape of the missing bone portion and a shell portion coupled to the bone growth portion so as to reinforce the strength of the bone growth portion to form a solid surface. By reinforcing the mechanical strength of the bone growth portion made of a porous material, it has the effect of providing a porous surface formed solid surface.

The present invention, the shell portion is configured to be formed on the outer surface of the bone growth portion, to complement the mechanical strength of the bone growth portion composed of a porous material by the shell portion, the solid surface, so that the fine particles do not fall from the bone growth portion Eliciting the effect of providing the formed porous segment.

The present invention is configured so that the shell portion is formed on the outer surface of the bone growth portion that is not in contact with the bone of the outer surface of the bone growth portion, and does not constitute a shell portion in a place where there is no fear that the fine particles fall by bonding to the bone. There is an effect of providing a porous face formed with a solid face, which constitutes a shell only at a point where the particles are exposed without being bonded to the microparticles and may be introduced into the patient's living body.

The present invention, the shell portion is formed on the outer surface of the bone growth portion that is not in contact with the implant of the outer surface of the bone growth portion, it is not formed a shell portion in the place where there is no fear that the fine particles fall in contact with the implant, It has an effect of providing a porous face formed with a solid face, which constitutes a shell only at the point where the microparticles are exposed without being bonded to the microparticles and enter the living body of the patient.

The present invention, the shell portion is formed so as to cover the entire exposed surface of the outer surface of the bone growth portion, which is not bonded to the bone without contacting the implant, causing microparticles to fall off the bone growth portion and cause an abnormal reaction in vivo. The effect of providing a porous face with a solid face formed is prevented in advance.

The shell portion may further include a through hole on a position corresponding to one end of the hole formed on the exposed surface, and the through hole is configured to communicate with the hole so that one end of the hole is formed on the exposed surface. In the process of constructing the shell portion on the exposed surface, there is an effect of providing a porous face with a solid surface formed so that one end of the hole portion is not blocked by the shell portion.

According to the present invention, the shell portion is configured to have a greater strength than the bone growth portion, so that the bone growth portion that can be easily deformed due to its relatively weak rigidity, so that the solid surface is protected by the strong shell portion, It has the effect of providing the formed porous segment.

The present invention, the augment, the supporter is configured to be coupled to the shell portion, to facilitate the removal in the process of removing the supporter generated in the process of outputting the porous by the 3D printing, the porous portion is This results in the effect of providing a porous face with a solid face formed so as not to be damaged.

The present invention is a solid, wherein the augment, the coupling force of the shell portion and the bone growth portion is configured to be greater than the coupling force of the shell portion and the supporter, so that the augment is not damaged in the process of removing the supporter from the shell portion There is an effect of providing a surface-formed porous fragment.

The present invention is configured to be manufactured by 3D printing, it has an effect that can accurately implement the augment formed a plurality of voids.

1 is a view of a conventional porous augment.
2 is a view showing that the porous segment and the implant of Figure 1 is coupled by a fastening means.
3 is a view showing a supporter coupled to an output during 3D printing;
4 is a view showing a porous segment according to an embodiment of the present invention.
5 is an exploded perspective view of FIG. 4;
6 is a view showing a bone growth unit according to an embodiment of the present invention.
7 is a view showing a bone growth unit according to another embodiment of the present invention.
8 is a view showing a bone growth unit according to another embodiment of the present invention.
9 is a view of the augment coupled to the acetabular cup during hip replacement surgery.
10 is a view showing that the shell portion is formed on the bone growth portion of FIG.
FIG. 11 is a view illustrating a shell portion formed on the bone growth portion of FIG. 7; FIG.
12 is a view showing that the shell portion is formed on the bone growth portion of FIG.
13 is a view showing a shell portion having an inner and an outer surface of a shape complementary to the exposed surface shape of the bone growth portion.
14 is a view showing that the through-hole of the bone growth portion and the shell portion communicate with each other.
15 is a view showing a shell portion to which the supporter is coupled;
16 is a view showing that the fastening portion is formed on the hole of the bone growth portion.
17 is a view showing that the fastening portion is formed on the hole portion of the bone growth portion and the inner surface of the fastening portion is in communication with the through hole, and the shell portion is coupled on the exposed surface of the bone growth portion.
18 is a use state diagram of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the porous surface formed solid surface according to the present invention will be described in detail. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Unless otherwise defined, all terms in this specification are equivalent to the general meaning of the terms understood by those of ordinary skill in the art to which the present invention pertains, and in case of conflict with the meaning of the terms used herein Follow the definitions used in the specification.

4 is a view showing a porous segment according to an embodiment of the present invention, Figure 5 is an exploded perspective view of FIG. Referring to FIGS. 4 and 5, the porous fragment 1 of the present invention is a porous fragment used for compensating for a missing bone area, which can promote autogenous bone growth of a patient. The material allows the augment to be well integrated with the patient's original bone without causing any adverse reactions in vivo even when implanted in the patient's body.

However, when the augment is composed only of a porous material having a plurality of voids, mechanical strength may be weakened, causing problems such as being easily crushed or broken by external force. Therefore, the present invention porous augment (1) is to form an aggregate with a porous material as a whole, to provide additional strength reinforcement means. The porous augment 1 includes a bone growth part 10, a shell part 30, and a fastening part 50.

The bone growth portion 10, the configuration having a shape complementary to the shape of the missing bone portion, preferably the bone growth portion 10 may be composed entirely of a porous material. Comprising a shape complementary to the bone loss portion of the patient, in order to implement the bone growth portion 10 made of a porous material accurately and easily, it is preferable to output the porous bone growth portion 10 by 3D printing Can be. The bone growth portion 10 may be formed by patient tailoring through reconstructing a medical image such as an MRI or a CT, measuring a missing bone part of the patient, modeling, and a 3D printing process.

6 to 8 illustrate various embodiments of the bone growth unit 10. As described above, the bone growth portion 10 has a shape complementary to the missing bone of the patient, as shown in FIGS. 6 to 8 depending on what the missing bone shape is. Can be made.

The augment 1 replaces the missing bone and is configured to couple to the implant I. Referring to FIG. 9, the outer surface of the bone growth part 10 constituting the body of the augment 1 is a bone ( It may be in contact with B) or the implant (I), it may be exposed as it is without contact with any of the bone (B) and the implant (I).

For convenience of explanation, the bone contact surface 101 of the outer surface of the bone growth portion 10 is in contact with the bone 101, the surface of the bone growth portion 10 in contact with the implant (I) implant implant The surface 103 and the outer surface of the bone growth portion 10 are defined as the exposed surface 105 without contact with the bone B and without contact with the implant I.

FIG. 9 is a view of an augment coupled to an acetabular cup during hip arthroplasty. Referring to FIG. 9, an augment 1 is used to compensate for a bone injury near an acetabular during hip arthroplasty. In this case, the outer surface of the augment 1 is a bone bonding surface 101 in contact with the bone around the acetabular, the implant bonding surface 103 in contact with the acetabular cup, the exposed surface 105 exposed to the outside without contacting the bone or implant ).

As will be described later, the bone growth portion 10 is formed by forming a plurality of pores 11 of the porous material, the surface is roughened, such a rough surface and the porous body may be attached to the fine particles. Preferably, the augment 1 is manufactured by 3D printing, and then a washing process for removing the fine particles is performed, but in the case of fine particles embedded deep inside the bone growth unit 10, complete removal through washing Is virtually difficult.

If the fine particles located inside the bone growth portion 10 is left as it is without leaving the initial position, there is no big problem, but may be a problem when such fine particles fall out through the pores 11 to the outside.

In the bone growth portion 10, the bone bonding surface 101 and the implant bonding surface 103 is blocked by the surface of the bone (B) and implant (I) there is no fear of external leakage of fine particles In the case of the exposed surface 105, the bar is exposed to the outside as it is, and fine particles may flow out through the exposed surface 105. This will be described in more detail in the shell unit 30 to be described later.

The bone growth portion 10 includes a void 11, a hole 13.

The voids 11 refer to a plurality of holes formed in the bone growth portion 10 due to the porous material when the bone growth portion 10 is formed of the porous material. The pore 11 may be configured in various ways according to the porous material constituting the bone growth portion 10 and is not limited thereto.

The hole portion 13 is configured to penetrate the other side from one side of the bone growth portion 10, and the shape thereof is not limited to any specific concept, but preferably, the screw through the hole portion 13 In that the fastening means (L) can be inserted, it can be a long cylindrical shape with the other direction in the longitudinal direction from one side. The fastening means (L) can be inserted through the hole 13, the porous segment 1 can be strongly coupled to the surface of the bone (B).

The hole portion 13 may be determined in size, number, shape, direction, etc. during the modeling process for outputting the porous fragment 1. When the hole portion 13 is output as previously planned, the surgeon easily inserts the fastening means L along the hole portion 13 without incurring additional effort, thereby making it easy to corrugate the porous segment 1. B) can be bonded to the surface or the like. A plurality of holes 13 may be formed on the bone growth part 10 for tight coupling of the porous segment 1.

FIG. 10 is a view illustrating a shell portion formed on the bone growth portion of FIG. 6, FIG. 11 is a view illustrating a shell portion formed on the bone growth portion of FIG. 7, and FIG. 12 is on the bone growth portion of FIG. 8. It is a figure which shows that the shell part was formed in the. Hereinafter, the shell part 30 will be described with reference to FIGS. 10 to 12.

The shell portion 30 is formed on the outer surface of the bone growth portion 10, is coupled to the bone growth portion 10 to form a solid surface. Preferably, the shell portion 30 may be configured in a plate shape, as shown in FIGS. 10 to 12. As described above, the bone growth portion 10 made of a porous material can be divided into the outer surface of the bone bonding surface 101, the implant bonding surface 103, the exposed surface 105, the shell portion 30 In order to prevent external leakage of the fine particles through the exposed surface 105, the bar is preferably configured on the exposed surface 105.

That is, the shell portion 30 is the outer surface of the bone growth portion that does not contact the bone of the outer surface of the bone growth portion 10 and the outer surface of the bone growth portion that does not contact the implant of the outer surface of the bone growth portion 10 It can be seen that formed on the exposed surface 105 that satisfies the requirements.

In addition, the shell portion 30 in order to more securely prevent the external leakage of the fine particles, as shown in Figure 10 to 12, without contacting the implant (I) of the outer surface of the bone growth portion (10) It may be formed to cover the entire outer surface, that is, the exposed surface 105 that is not bonded to the bone (B). To this end, the inner surface 301 of the shell portion 30 in contact with the exposed surface 105 of the shell portion 30 is preferably configured to have a shape complementary to the shape of the exposed surface 105.

FIG. 13 is a view illustrating a shell part having inner and outer surfaces having a shape complementary to an exposed surface shape of the bone growth part. Referring to FIG. 13, the shell part 30 may be configured in a plate shape. However, in order to prevent waste of unnecessary material and enlargement of the augment 1, the outer surface 303 of the shell portion 30 is also configured to have a shape complementary to that of the exposed surface 105, FIG. As shown in 13, the width of the shell portion 30 is preferably configured to be substantially constant.

FIG. 14 is a view illustrating communication between the hole of the bone growth portion and the through hole of the shell portion. Referring to FIG. 14, the hole portion 13 for receiving the fastening means L is provided on the bone growth portion 10. If one end of the hole portion 13 is formed on the exposed surface 105, the shell portion 30 covers the exposed surface 105, the hole portion 13 is the shell portion It will result in the blockage of (30).

Therefore, in order to prevent such a problem, if one end of the hole portion 13 is formed on the exposed surface 105, the shell portion 30 is seated on the exposed surface 105 and the hole portion 13 and A through hole 31 penetrating the other surface from one surface of the shell portion 30 may be formed on the corresponding position. In addition, when there are a plurality of such holes 13, the through holes 31 may also be configured in plural numbers.

The shell portion 30 is configured to be coupled to the bone growth portion 10, according to the above description, the bone growth portion 10 has a problem that the mechanical strength is weak due to the plurality of voids (11). . Therefore, by coupling the shell portion 30 to the bone growth portion 10, the shell portion 30 can be utilized as a configuration to complement the mechanical rigidity of the bone growth portion 10. To this end, the shell portion 30 is preferably configured to have a greater strength than the bone growth portion 10 including the voids.

FIG. 15 is a view illustrating a shell unit to which supporters are coupled. Since 3D printing mainly uses a method of stacking materials, there is a need for a means for supporting an empty space in the output printed by a 3D printer. Without such support means, the 3D printer may eject material into the air, and sagging may occur in the printed output.

The augment 1 has a shape complementary to the anatomical shape of the patient. In order to implement the atypical augment 1 in a previously planned shape by a 3D printing method, the augment 1 is supported. It is necessary to output the supporter S together.

The supporter S is eventually removed on the completed augment 1. When the supporter S is coupled to the bone growth part 10 made of a porous material, the supporter S is removed. , The relatively weak bone growth portion 10 can fall off with the supporter (S). In this case, the trouble of having to re-output the porous segment 1, waste of cost and time, etc. occur.

Therefore, the present invention, as shown in Figure 15, by allowing the supporter (S) is coupled to the shell portion 30, even if the supporter (S) is attached to the augment (1), the strength is relatively strong It may be easier to remove the supporter S from the shell portion 30 having the smooth surface.

More preferably, the coupling force between the shell portion 30 and the bone growth portion 10 is greater than the coupling force between the shell portion 30 and the supporter S, so that the bone growth portion when removing the supporter S ( 10) it is preferable not to affect the coupling state of the shell portion 30.

16 is a view showing that the fastening portion is formed on the hole of the bone growth portion. Hereinafter, a description will be given with reference to FIG. 16.

The fastening part 50 is formed to penetrate the bone growth part 10 refers to a configuration for receiving the fastening means inside. As described above, the bone growth portion 10 may be formed with a hole portion 13 formed to penetrate the other side from one side to the inside, and the fastening means L introduced into the inner portion through the hole portion 13 may eventually be formed. The bone growth portion 10 of the porous material is in contact. The fastening means (L) is strongly pressed with the augment (1) functions to couple to the surface of the bone (B), etc., the bone growth portion around the hole portion 13 is relatively weak in the process of the pressing force is applied 10 may cause deformation such as being broken or damaged. In addition, even if a thread is formed on the outer circumferential surface of the fastening means (L), it may be difficult to induce a strong screw coupling into the bone growth portion 10 in which a plurality of voids are formed.

Therefore, in order to solve this problem, the fastening part 50 may be seated on the hole part 13. In order for the fastening part 50 to be seated on the hole part 13 without being spaced apart, the fastening part 50 is configured to have an inner side surface 51 having a shape complementary to the outer side surface of the fastening means L. This is preferable.

In addition, the inner surface 51 is preferably configured to be solid so that the inner surface 51 can maintain a strong bonding force by forming a wide contact area with the outer surface of the fastening means (L). For example, if the thread is formed on the outer surface of the fastening means (L), the solid inner surface 51 of the fastening portion 50 also has a solid surface having a complementary shape to it, thereby forming a strong screw between the two Combination can be possible. Herein, the inner surface 51 of the fastening part 50 forms a solid surface, which is preferably interpreted to mean that the porous layer is formed with a plurality of voids, and is not limited to a flat surface. The outer side surface 53 of the fastening portion 50 may be configured to have a shape complementary to the shape of the hole portion 13 formed to penetrate the other side from one side of the bone growth portion 10.

17 is a view showing that the fastening portion is formed on the hole portion of the bone growth portion and the inner surface of the fastening portion is in communication with the through hole, so that the shell portion is coupled on the exposed surface of the bone growth portion. Referring to FIG. 17, when one end of the hole part 13 is formed on the exposed surface 105 of the bone growth part 10, the shell part 30 configured to cover the exposed surface 105 may be formed. The through hole 31 may be configured to correspond to one end of the hole 13. However, in the case where the fastening part 50 is formed on the hole part 13, in order for the inner space of the through hole 31 and the fastening part 50 of the shell part 30 to communicate with each other without forming a step, The through hole 31 of the shell portion 30 is preferably configured to correspond to the inner surface 51 of the fastening portion 50.

18 is a state diagram used in the present invention. Referring to FIG. 18, the illustrated figure illustrates a joint state of a patient implanted with an implant and an implant 1 after a hip arthroplasty. The patient's Acetabular and Femur were implanted with an implant (I), and an augment (1) adjacent to the implant (I) was coupled to compensate for the missing bone.

The augment (1) is composed of a bone growth portion 10 of the porous material is able to promote autogenous bone growth through the pores 11 of the bone growth portion (10). The outer surface of the bone growth portion 10 may be divided into the bone bonding surface 101 in contact with the bone (B) and the implant bonding surface 103 in contact with the implant (I) and the exposed surface 105 does not touch anywhere. In addition, the particles may be separated through the exposed surface 105 to cause a biological abnormality reaction, and the shell portion 30 may be formed at a portion corresponding to the exposed surface 105 of the bone growth part 10. By covering it, it becomes possible to prevent the fall of the fine particles.

The rigidity of the segment 1 composed of a porous material may be supplemented by the shell part 30, and the fastening part 50 is configured to prevent deformation of the hole part 13 into which the fastening means L is introduced. Can be. The through hole 31 is formed on the shell part 30 so that the empty space formed by the hole part 13 is not blocked. The through hole 31 does not form a step with the inner surface 51 of the fastening part 50. Can be communicated.

Damage to the hole part 13 can be prevented through the fastening part 50, and by allowing the fastening means L and the fastening part 50 to be coupled to each other, a greater coupling force can be generated.

In addition, the shell part 30 provides a space in which the supporter S may be coupled when the porous segment 1 is output, thereby easily removing the supporter S from the outputted porous element 1. To be able.

The foregoing detailed description illustrates the present invention. In addition, the above-mentioned content shows and describes preferred embodiment of this invention, and this invention can be used in various other combinations, changes, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosures described above, and / or the skill or knowledge in the art. The described embodiments illustrate the best state for implementing the technical idea of the present invention, and various modifications required in the specific application field and use of the present invention are possible. Thus, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

1: porous augment
10: bone growth portion 101: bone joint surface
103: implant bonding surface 105: exposed surface
11: void 13: hole
30: shell portion 301: inner surface
303: outer side 31: through hole
50: fastening portion 51: the inner surface
53: outer side S: supporter
L: Fastener I: Implant
B: Goal

Claims (10)

Is made by 3D printing,
The bone growth portion having a shape complementary to the shape of the missing bone portion and the void growth portion, while reinforcing the strength of the bone growth portion to prevent microparticles from falling off the bone growth portion to cause an abnormal reaction in vivo A shell portion coupled to the bone growth portion to form a solid face,
The supporter is coupled to the shell portion, characterized in that the porous surface formed solid surface. According to claim 1, The shell portion, characterized in that formed on the outer surface of the bone growth portion, a solid surface formed porous augment. According to claim 2, The shell portion, characterized in that formed on the outer surface of the bone growth portion that is not in contact with the bone of the outer surface of the bone growth portion, porous face formed with a solid surface. According to claim 3, The shell portion, characterized in that formed on the outer surface of the bone growth portion that is not in contact with the implant of the outer surface of the bone growth portion, a porous surface formed with a solid surface. According to claim 4, The shell portion, the outer surface of the bone growth portion is formed so as to cover the entire exposed surface that is not in contact with the bone without contacting the implant, the porous face formed with a solid surface. The porous surface with a solid surface according to claim 5, wherein the shell portion further includes a through hole on a position corresponding to one end of the hole portion formed on the exposed surface, and the through hole communicates with the hole portion. Augment. According to claim 6, The shell portion, characterized in that having a greater strength than the bone growth portion, solid face formed porous augment. delete The porous fragment with a solid surface according to claim 1, wherein the augment has a greater coupling force between the shell portion and the bone growth portion than a coupling force between the shell portion and the supporter. delete

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