KR102168608B1 - Porous Cervical Vertebra Cage to Promote Bone Fusion - Google Patents

Abstract

The present invention relates to a porous cervical vertebral cage that promotes bone fusion, and more particularly, by increasing the porosity of the cervical vertebral cage to promote the union between adjacent cervical vertebrae in contact with the cage, and as the porosity of the cervical vertebral cage increases It relates to a porous cervical vertebral cage that promotes bone fusion, which reinforces the strength by constructing a frame part supporting the bone growth part to solve the problem of decreasing strength.

Description

Porous Cervical Vertebra Cage to Promote Bone Fusion}

The present invention relates to a porous cervical vertebral cage that promotes bone fusion, and more particularly, by increasing the porosity of the cervical vertebral cage to promote the union between adjacent cervical vertebrae in contact with the cage, and as the porosity of the cervical vertebral cage increases It relates to a porous cervical vertebral cage that promotes bone fusion, which reinforces the strength by constructing a frame part supporting the bone growth part to solve the problem of decreasing strength.

In general, the cervical spine is located at the top of the spine consisting of 7 spines, and it is located between the skull and spine. Most of them are small and flat in shape, and vertebral arteries (except for the 7th cervical spine), veins, and sympathetic nerves in the horizontal transverse process. There is a hole through which the gun passes.

The first cervical vertebrae are round and have a joint surface that supports the skull, but there are no vertebrae and spinous processes, and the second cervical vertebrae are called chukchu and have tooth protrusions rising upward from the vertebrae. In the hwanchu and shaft vertebrae, a lot of rotational motion occurs. From the third to the sixth cervical vertebrae, there are small, wide vertebrae and triangular vertebrae, and spinous processes with the ends divided into two are formed. The 7th cervical vertebra is called Jungchu and has spinous processes that are long and not split at the end.

On the other hand, into the spinal cord in the cervical spine, motor nerves transmitted from the brain to the limbs and sensory nerves transmitted from the limbs and trunk organs to the brain pass through the spinal cord. In front of the cervical spine, the autonomic nerves that control the heart rate, breathing, and digestive functions pass through the arteries that supply blood to the cerebrum.

The cervical vertebrae having the above structure and function are damaged or deformed in a bent state as an external shock or twisted posture due to an accident lasts for a long time, and at this time, the gap between the cervical vertebrae narrows or the cervical disc escapes and presses As a result, you will feel light pain in the early stages, and severe pain in the middle and late stages and symptoms of paralysis are also accompanied.

In order to relieve this pain, the cervical disc was removed to remove pressure on the nerve, and then the cervical cage was inserted into the cervical disc removal site, thereby fusion of the adjacent cervical vertebrae was performed.

1 is a view showing a conventional cervical vertebral cage, which is disclosed in Korean Patent Application Publication No. 10-2009-0112284 (2009.10.28). Referring to Figure 1, the conventional cervical cage 9 is composed of a trapezoidal frame 91 in which each corner portion is formed to be round, and a partition wall 92 crossing the center portion is formed. In addition, between the frame 91 and the partition wall 92, a pair of cavities 93 for filling the bone-generating material are provided, and the partition wall 92 includes a marker 95 and a marker for positioning during surgery. Spikes 94 for preventing slipping were formed, and concave portions 96 formed parallel to each other by being depressed at a predetermined depth over the entire surface were formed.

However, according to the conventional cervical cage 9, due to the partition wall 92, a space for filling the bone-generating material was not sufficiently secured, and the cervical vertebral cage 9 itself is formed to be solid, so that the cervical vertebral cage 9 ), the bone cannot be fused as much as the volume occupied, so there is a problem that the bone fusion period is prolonged and recovery is delayed. In addition, since the frame 91 is formed thicker than necessary, the portion that promotes bone growth is reduced, and the volume of the cage 9 itself is increased and the weight is increased.

Therefore, in the related industry, while promoting the union of adjacent bones in contact with the cervical vertebral cage, the volume and weight of the cage can be reduced, while maintaining a predetermined strength, and complete bone union is achieved when inserted between adjacent bones. There is a demand for the development of a cervical vertebral cage that can secure a fixing force so that the cage does not move before losing.

Korean Patent Application Publication No. 10-2009-0112284 (2009.10.28)

The present invention was drawn to solve the above problems,

An object of the present invention is to increase the porosity of the cervical vertebrae cage to promote the union between the adjacent cervical vertebrae in contact with the cage, to provide a porous cervical vertebral cage.

Another object of the present invention is to provide a porous cervical vertebral cage to reinforce the strength by constructing a frame portion supporting a bone growth portion to solve the problem that the strength of the cage decreases as the porosity of the cervical vertebral cage increases.

Another object of the present invention is to configure the frame portion to be located inside the bone growth portion, reinforcing the strength of the bone growth portion, which is relatively weak, while allowing the outside of the cage to be surrounded by the bone growth portion, thereby allowing autogenous bone growth. To maximize, is to provide a porous cervical vertebral cage.

Another object of the present invention is to provide a porous cervical vertebral cage, which is capable of reinforcing the strength of the cage without lowering the bone growth efficiency of the cage by configuring a frame portion formed in a cross shape.

Another object of the present invention is to provide a porous cervical vertebral cage that is capable of promoting strength reinforcement through the frame portion and spontaneous growth of bone through the frame portion by configuring a plurality of through holes in the frame portion. .

Another object of the present invention is to configure the frame part with a plurality of annular rims, to reinforce the strength of the bone growth part, insert a bone graft through the empty inner space of the rim, or to observe bone growth, porosity It is to provide a cervical vertebral cage.

Another object of the present invention is to configure a connection, connect the upper and lower rims, and allow a plurality of connection parts to be spaced apart at regular intervals to form a space, so that bone growth can be promoted in the space between them. , To provide a porous cervical spine cage.

Another object of the present invention is to configure a protruding tooth protruding at the upper end of the upper rim and the lower end of the lower rim to facilitate propulsion of the cage into the space between the cervical vertebrae, while the cage is positioned on a pre-planned position It is to provide a porous cervical vertebral cage that allows a predetermined fixation force to be expressed until complete fusion of neighboring cervical bones is achieved.

Another object of the present invention is to expose the end of the rim part forming the frame to the outside of the bone growth part, so that the surgeon is wounded by the end of the bone growth part on a somewhat rough surface, or the stiffness is relatively weak due to various causes. It is to provide a porous cervical vertebral cage that prevents the end of the bone growth part from being damaged by bending or cracking, or from generating porous particles from the bone growth part.

Another object of the present invention is to configure a coupling part protruding anteriorly on the frame part, so that the surgical instruments can be connected through the coupling part, so that the surgeon can easily insert the cage between the cervical spine bones, and in a predetermined position It is to provide a porous cervical vertebral cage that allows easy positioning.

Another object of the present invention is to provide a porous cervical vertebral cage, which constitutes a convex coupling portion in the anterior direction, so that the coupling portion is coupled while forming a wider contact surface with neighboring bone growth portions.

Another object of the present invention is to expose the front surface of the coupling portion to the outside of the bone growth portion, and constitute a connection hole on the front surface of the coupling portion, so that the surgical instrument can be seated on the coupling hole of the coupling portion and securely fixed. , To provide a porous cervical spine cage.

Another object of the present invention is to configure a fixed portion protruding obliquely in the posterior direction on the upper and lower surfaces of the bone growth unit, facilitating the propulsion of the cage into the space between the cervical vertebrae, while the cage is positioned on the pre-planned position. When set, it is to provide a porous cervical vertebral cage that allows a predetermined fixation force to be expressed until complete fusion of neighboring cervical vertebrae is achieved.

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

According to an embodiment of the present invention, the present invention includes a bone growth part inserted into a space between adjacent cervical vertebrae to promote bone growth, and a frame part formed to support the bone growth part, and the frame part, the It is formed to support the inside of the bone growth part and is characterized in that the area of the bone growth part is widened.

According to another embodiment of the present invention, the frame portion is formed in a cross shape, wherein the frame portion is symmetrical up and down with respect to a central horizontal plane, and symmetrical left and right with respect to a central vertical surface.

According to another embodiment of the present invention, the frame portion is characterized in that it includes a through hole penetrating from one surface to the other.

According to another embodiment of the present invention, the frame portion includes an annular upper rim portion supporting an upper side of the bone growth portion, and an annular lower side rim portion supporting an inner lower side of the bone growth portion, It characterized in that it comprises an annular left rim portion for supporting the left side of the bone growth portion, and an annular right rim portion for supporting the right side of the bone growth portion.

According to another embodiment of the present invention, the frame portion is characterized in that it further comprises a connection portion connecting the rear surface of the upper rim portion and the rear upper surface of the lower rim portion.

According to another embodiment of the present invention, in the present invention, a plurality of the connecting portions are formed at regular intervals parallel to the central vertical surface.

According to another embodiment of the present invention, in the present invention, the upper rim part includes a first protrusion formed on the left and right upper ends obliquely protruding in the rearward direction, and the lower rim protrudes obliquely rearward on the left and right lower ends. It characterized in that it comprises a formed second protrusion.

According to another embodiment of the present invention, in the present invention, the upper rim part is exposed to the outside of the bone growth part, the lower rim part is exposed to the outside of the bone growth part, and the left rim part is The bone growth portion is exposed to the outside, and the right rim portion is characterized in that the right end is exposed to the outside of the bone growth portion.

According to another embodiment of the present invention, the porous cervical vertebra cage is characterized in that it further comprises a coupling portion protruding from the frame portion in the anterior direction.

According to another embodiment of the present invention, the coupling portion is characterized in that it is formed to be convex in the anterior direction to widen the contact surface with the bone growth portion.

According to another embodiment of the present invention, the coupling portion is characterized in that the front surface is exposed to the outside of the bone growth portion, and includes a connection hole recessed on the front surface.

According to another embodiment of the present invention, the bone growth portion is characterized in that the fixing portion is formed on the upper surface and the lower surface obliquely protruding in the rearward direction.

The present invention can obtain the following effects by the configuration, combination, and use relationship that will be described below with the present embodiment.

The present invention has the effect of promoting the union between adjacent cervical bones in contact with the cage by increasing the porosity of the cervical vertebral cage.

In the present invention, as the porosity of the cervical vertebral cage increases, the strength of the cage decreases, and the effect of reinforcing the strength by configuring the frame portion supporting the bone growth portion is derived.

In the present invention, the frame part is configured to be located inside the bone growth part, reinforcing the strength of the bone growth part, which is relatively weak, while the outer side of the cage is surrounded by the bone growth part, thereby maximizing autogenous bone growth. There is.

The present invention has an effect of configuring a frame portion formed in a cross shape to reinforce the strength of the cage without deteriorating the bone growth efficiency of the cage.

The present invention, by configuring a plurality of through-holes in the frame portion, the strength reinforcement through the frame portion, and the effect of promoting the spontaneous growth of bone through the through-holes.

The present invention has the effect of constructing the frame part with a plurality of annular rims, reinforcing the strength of the bone growth part, inserting a bone graft through the empty inner space of the rim part, or observing bone growth.

The present invention has an effect of configuring a connection part to connect the upper and lower rim parts, and allowing a plurality of connection parts to form a space spaced apart at regular intervals, thereby facilitating bone growth in the space between them.

The present invention comprises a protruding tooth protruding at the upper end of the upper rim and the lower end of the lower rim to facilitate propulsion of the cage into the space between the cervical vertebrae, while the adjacent cervical vertebrae when the cage is positioned on a pre-planned position It derives the effect of allowing a predetermined fixing force to be expressed until complete fusion of

In the present invention, the end of the rim part forming the frame part is exposed to the outside of the bone growth part, so that the surgeon is wounded by the end of the bone growth part on a somewhat rough surface, or the end of the bone growth part which is relatively weak due to various causes It has the effect of preventing the formation of porous particles from the bone growth area or damage by bending or cracking.

The present invention constitutes a coupling part protruding anteriorly on the frame part, so that the surgical instruments can be connected through the coupling part, so that the surgeon easily inserts the cage between the cervical spine bones, and is easily positioned on a previously planned position. It has the effect of being able to set.

The present invention, by constituting a convex coupling portion in the anterior direction, the coupling portion to form a wider contact surface with the neighboring bone growth portion to derive the effect of being coupled.

In the present invention, the front surface of the coupling part is exposed to the outside of the bone growth part, and a connection hole is formed on the front surface of the coupling part, so that the surgical instrument can be seated on the connection hole of the coupling part and securely fixed.

The present invention comprises a fixed portion formed obliquely protruding in the posterior direction on the upper and lower surfaces of the bone growth unit, facilitating the propulsion of the cage into the space between the cervical vertebrae, and when the cage is positioned on a pre-planned position, the neighboring It has the effect of allowing a predetermined fixation force to be expressed until complete fusion of the cervical spine bones is achieved.

1 is a view showing a conventional cervical vertebrae cage.
Figure 2 is a perspective view as viewed from the rear side of the porous cervical vertebral cage according to an embodiment of the present invention.
Figure 3 is a perspective view of the cervical vertebral cage of Figure 2 viewed from the front side.
4 is a view showing a bone growth unit according to an embodiment of the present invention.
5 is a view showing a frame unit according to an embodiment of the present invention.
6 is a view showing a coupling part according to an embodiment of the present invention.
Figure 7 is a state of use of the porous cervical vertebral cage according to an embodiment of the present invention.

Hereinafter, preferred embodiments of a porous cervical vertebral cage for promoting bone fusion according to the present invention will be described in detail with reference to the accompanying drawings. 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, a detailed description thereof will be omitted. Unless otherwise defined, all terms in this specification are the same as the general meanings of the terms understood by those of ordinary skill in the art to which the present invention belongs, and in case of conflict with the meanings of terms used in the present specification, the present disclosure According to the definitions used in the specification.

2 is a perspective view of a porous cervical vertebral cage according to an embodiment of the present invention as viewed from the rear side, and FIG. 3 is a perspective view of the cervical vertebral cage of FIG. 2 viewed from the front side. 2 and 3, the porous cervical vertebral cage 1 according to the present invention is used to remove the damaged cervical vertebral disc and insert it into the space between the neighboring cervical vertebrae, and to fuse the neighboring cervical vertebrae. It becomes. With respect to the method of manufacturing the porous cervical vertebral cage 1, this is not limited to any specific concept, but preferably, the cervical bone of the patient in question is scanned based on a medical image such as CT or MRI, and scanning The cage modeling work is performed based on the patient data acquired through the process, and the modeling work can be printed out through a 3D printing method, etc., so that the patient can be customized. The porous cervical spine cage (1) includes a bone growth part (10), a frame part (30), and a coupling part (50).

4 is a view showing a bone growth unit according to an embodiment of the present invention. Hereinafter, the bone growth unit 10 will be described with reference to FIG. 4.

The bone growth unit 10 is inserted into a space between adjacent cervical vertebrae to promote bone growth, and preferably has a porous structure. The cervical vertebrae cage (1) having a porous structure is inserted into the space between the cervical vertebrae from which the cervical vertebrae are removed and fixed, so that it can be tightly fixed between the vertebral bones without a separation phenomenon. It may be desirable to have a shape that is complementary to the shape of the space.

Young's Modulus (Elastic Modulus) refers to a proportional constant at this time, as stress and deformation are directly proportional (Hook's Law) within the elastic limit. Therefore, a large modulus of elasticity means that the deformation is small, and a small deformation means that the strength of the material is strong. Conversely, a small modulus of elasticity means that there is a lot of deformation, and a lot of deformation means that the strength of the material is weak.

When a porous cervical vertebral cage (1) having a larger elastic modulus than that of a patient's bone is inserted between the cervical vertebrae bones, a stress shield phenomenon in which the patient's bone density is reduced by the strong porous cervical vertebrae cage (1) ( Stress Shielding), bone sedimentation (Sinking Down), etc. may occur, and the elastic modulus of the porous cervical cage 1 is preferably configured to be close to that of the patient's bone.

The bone growth unit 10 may be supported by the frame unit 30 to be described later, and at least a portion of the bone growth unit 10 refers to a porous structure through which radiation is transmitted. As will be described later, the frame portion 30 is opaque to radiation, and the bone growth portion 10 is transmitted through the void portion 10a to be described later, so that the transmission and non-transmission portions of the radiation are clearly distinguished. The location of the porous cervical vertebral cage (1) becomes easy. This bone growth part 10, as shown in Figure 4, is composed of a void (10a) and a structure (10b).

The void portion 10a is a concept collectively referred to as empty spaces Pore of the bone growth portion 10 having a porous structure through which irradiated radiation is transmitted as it is. These voids (10a) may be configured to be formed disorderly at any position of the bone growth portion (10), but preferably may be configured in an orderly form in a certain form. Regarding the shape of the void portion 10a, this is not limited to a specific concept, and any shape may be configured as long as it is capable of transmitting radiation as it is.

The structural portion 10b refers to a configuration that forms the void portion 10a and forms the overall appearance of the bone growth portion 10, and the void portion 10a can be seen as being provided through the structural portion 10b. . The bone growth portion 10 transmits radiation through the void portion 10a. When the structural portion 10b is also made of a material having a high radiation transmittance, the void portion 10a and the structural portion 10b are separated As this becomes unclear, preferably, the structural portion 10b may be made of a material through which radiation is not transmitted.

The bone growth part 1 includes a receiving part 11 and a fixing part 13.

The receiving part 11 refers to a part providing a space on the bone growth part 1 in which the frame part 30 to be described later is seated. As will be described later, the frame part 30 is preferably formed in a cross shape, and the receiving part 11 is on the upper, lower, left, and right surfaces of the bone growth part 1 to accommodate the frame part 30. It may be formed and configured to communicate with each other. Through the receiving portion 11, a bone graft for promoting bone growth of the patient may be inserted into the inner side of the bone growth part 1, and the growth of spontaneous bone may be observed.

The fixing part 13 refers to a configuration in which the bone growth part 10 is protruded obliquely in the rearward direction on the upper and lower surfaces of the bone growth part 10. When the porous cervical vertebral cage (1) is inserted between the cervical vertebrae of the patient, it must be seated on the original position planned during surgery until the bone grows. By configuring the protrusion 13, a strong fixing force between the cage 1 and the cervical vertebrae is secured, thereby preventing a problem in which the cage 1 moves out of the correct position due to movement of the patient or impact from the outside. At this time, the fixing part 13 is preferably configured to be inclined in the posterior direction so that the cage 1 can be easily propelled in the space between adjacent cervical vertebrae.

As shown in FIG. 4, the fixing part 13 has a fixed part inclined surface 131 inclined in the rearward direction, and an approximately horizontal fixed part horizontal surface 133 is configured at the apex of the fixed part inclined surface 131 In addition, a substantially vertical fixing part vertical surface 135 may be formed at an end of the fixing part horizontal surface 133. This means that when the end of the fixing part 13 is sharpened, a strong fixing force can be secured between the cervical vertebrae, but the extent of damage to the cervical vertebrae of the patient increases, and the process of pushing the cage 1 is not easy. As can be seen, the fixing part 13 is preferably configured as shown in FIG. 4.

The frame part 30 refers to a configuration formed to support the bone growth part 10. The frame part 30 is formed to support the bone growth part 10 to express the strength of the cage 1. The cage (1) is composed of only the bone growth portion (10) consisting of a void portion (10a) and a structure portion (10b) to maximize the growth rate of bone, but it does not have sufficient rigidity to withstand the load transmitted from the cervical spine. It may not be possible. This problem is solved by configuring the frame part 30 capable of expressing strength in the bone growth part 10. Preferably, the frame part 30 may be made of a biometal (titanium, titanium alloy, cobalt chromium, magnesium) for expressing a predetermined strength. The frame part 30 is composed of a non-porous material through which radiation is opaque, so that the bone growth part 10 made of a porous material transmits radiation as it is through the void part 10a when irradiated with radiation, so that the bone growth part ( 10), and the portion where the radiation is opaque and dark is distinguished by the frame unit 30 so that it can be recognized. This makes it easier to check the position of the cage (1).

5 is a view showing a frame unit according to an embodiment of the present invention, which will be described below with reference to FIG. 5.

The frame part 30 refers to a configuration for supporting the inside of the bone growth part 10. The frame part 30 may be formed in a cross shape, preferably vertically symmetrical with respect to the central horizontal plane H, and symmetrical horizontally with respect to the central vertical surface P. A plurality of through holes 30a penetrating from one surface to the other surface may be formed on the frame unit 30 as shown in FIG. 5. Through this through hole (30a), it is possible to reduce the weight of the frame unit 30 itself, and it is possible to further promote the patient's spontaneous bone growth. The frame part 30 includes an upper rim part 31, a lower rim part 32, a left rim part 33, a right rim part 34, and a connection part 35.

The upper rim part 31 is a ring-shaped configuration that supports the upper side of the bone growth part 10, and as shown in FIG. 5, a plurality of empty spaces are formed on the inside and penetrated from one side to the other. It includes a through hole (30a). The upper rim part 31 is configured to have a shape complementary to the receiving part 11 formed on the corresponding position of the bone growth part 10, and may be configured to be seated in the space created by the receiving part 11 have. The upper rim part 31 is preferably configured such that its upper end is exposed to the outside of the bone growth part 10. Through the inner space of the upper rim part 31, the surgeon can insert the bone graft into the cage 1, and in this process, the surgeon may be wounded by the end of the bone growth part 10 on a somewhat rough surface. It may be damaged by bending or cracking the end of the bone growth part 10, which is relatively weak due to various causes, and the upper rim part 31 is the receiving part 11 of the bone growth part 10. ) By surrounding the inner circumferential surface and allowing the upper end to be exposed to the outside of the bone growth unit 10, it is possible to prevent the occurrence of the above-described problem. The upper rim part 31 includes a first protruding tooth 311.

The first protrusion 311 refers to a configuration protruding obliquely in the rearward direction on the left and right upper ends of the upper rim part 31. Preferably, the shape of the first protrusion 311 may be configured to have a shape complementary to the shape of the fixing portion 13 of the adjacent bone growth portion 10. That is, as shown in FIG. 5, the first protrusion 311 has a first protrusion inclined surface 3111 inclined in the rearward direction, and is approximately horizontal at the apex of the first protrusion inclined surface 3111. A first protrusion dimension plane 3113 may be configured, and a first protrusion dimension vertical surface 3115 may be formed at an end of the first protrusion dimension plane 3113. Through this, even if the upper end of the upper rim part 31 is exposed to the outside of the bone growth part 10, a fixed part configured to minimize damage to the cervical spine bones while securing a predetermined fixing force, and to easily propel the cage 1 (13) will be able to achieve a continuous shape.

The lower rim part 32 is a ring-shaped configuration that supports the lower inner side of the bone growth part 10, and as shown in FIG. 5, a plurality of empty spaces are formed on the inside and penetrated from one side to the other. It includes a through hole (30a). The lower rim part 32 is configured to have a shape complementary to the receiving part 11 formed on the corresponding position of the bone growth part 10, and may be configured to be seated in the space created by the receiving part 11 have. The lower rim part 32 is preferably configured such that its lower end is exposed to the outside of the bone growth part 10. Through the inner space of the lower rim part 32, the surgeon can insert the bone graft into the cage 1, and in this process, the surgeon may be wounded by the end of the bone growth part 10 on a somewhat rough surface. It may be damaged by bending or cracking the end of the bone growth part 10, which is relatively weak due to various causes, and the lower rim part 32 is the receiving part 11 of the bone growth part 10. ) Surrounding the inner circumferential surface, and the lower end of which is exposed to the outside of the bone growth unit 10, it is possible to prevent the occurrence of the above-described problem. The lower rim part 32 includes a second protruding tooth 321.

The second protrusion 321 refers to a configuration in which the lower rim part 32 protrudes obliquely in the rearward direction on the left and right lower ends of the lower rim part 32. Preferably, the shape of the second protrusion 321 may be configured to have a shape complementary to the shape of the fixing portion 13 of the adjacent bone growth portion 10. That is, as shown in FIG. 5, the second protrusion 321 has a second protrusion inclined surface 3211 inclined in the rearward direction, and is approximately horizontal at the apex of the second protrusion inclined surface 3211 A second protrusion dimension plane 3213 may be configured, and a second protrusion dimension vertical surface 3215 may be formed at an end of the second protrusion dimension plane 3213. Through this, even if the lower end of the lower rim part 32 is exposed to the outside of the bone growth part 10, a fixed part configured to minimize damage to the cervical spine bone while securing a predetermined fixing force, and to easily propel the cage 1 (13) will be able to achieve a continuous shape.

The left rim part 33 is a ring-shaped configuration supporting the left side of the bone growth part 10, and as shown in FIG. 5, a plurality of empty spaces are formed on the inside and penetrated from one side to the other. It includes a through hole (30a). The left rim part 33 may be configured to have a shape complementary to the receiving part 11 formed on the corresponding position of the bone growth part 10, and be configured to be seated in the space created by the receiving part 11 have. In addition, for the same reason as described above, it is preferable that the left rim part 33 is configured such that its left end is exposed to the outside of the bone growth part 10.

The right rim part 34 is a ring-shaped configuration that supports the right inside of the bone growth part 10, and as shown in FIG. 5, a plurality of empty spaces are formed on the inside and penetrated from one side to the other. It includes a through hole (30a). The right rim part 34 may be configured to have a shape complementary to the receiving part 11 formed on the corresponding position of the bone growth part 10 so as to be seated in the space created by the receiving part 11. have. Likewise, the right rim part 34 is also preferably configured such that its right end is exposed to the outside of the bone growth part 10.

The connection part 35 refers to a configuration connecting the rear surface of the upper rim part 31 and the rear upper surface of the lower rim part 32. In order to connect the upper rim part 31, the lower rim part 32, the left rim part 33, and the right rim part 34 in a cross-shape, a connection means for them must be provided at the center of the frame part 30. , When it is configured to be solid, bone growth is not promoted as much as the part configured to be solid. As shown in FIG. 5, the connection part 35 of the elongated shape is Will be configured. More preferably, as shown in FIG. 5, a plurality of connection portions 35 may be formed in parallel with the central vertical surface P at regular intervals.

The coupling part 50 is configured to connect the upper rim part 31 and the lower rim part 32, connect the left rim part 33 and the right rim part 34, and protrude in the front direction, Surgical instruments used for manipulation of the cage 1 may be connected to the coupling part 50. The shape of the coupling part 50 is not limited to a specific concept, and may be variously determined in relation to the surgical instrument to be used to insert the cage 1 between the cervical spine bones of the patient. However, preferably, as shown in FIG. 6, the coupling part 50 is preferably configured to be convex in the anterior direction to widen the contact surface with the bone growth part 10. In addition, on the coupling part 50, as shown in Fig. ?, a connection hole 51 recessed on the front surface 50a of the coupling part 50 to be coupled to the surgical instrument may be configured, and the surgical instrument and For the coupling of the front surface (50a) of the coupling portion 50 is preferably exposed to the outside of the bone growth portion (10).

Figure 7 is a state diagram of use of a porous cervical vertebral cage according to an embodiment of the present invention. Referring to FIG. 7, a bone graft (B) for promoting bone growth of the patient is inserted into the empty space inside the cage (1), and the cervical spine adjacent to the cage (1) is on the front side of the cage (1). Surgical instruments (S) for easily positioning into the space between the bones (C) are connected. The surgeon manipulates the surgical instrument (S) to proceed with the process of positioning the porous cervical vertebral cage (1) containing the bone graft (B) at the point planned before the operation, and the positioning of the cage (1) is completed. When the cage (1) is separated from the cage (1) only the surgical instrument (S) while leaving. Thereafter, the cage (1) inserted between the cervical spine bones (C) induces the patient's spontaneous bone growth, and when a predetermined time elapses, the adjacent cervical spine bone (C) in contact with the inserted cage (1) Become united with each other.

The detailed description above is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications 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 disclosed contents, and/or the skill or knowledge of the art. The above-described embodiments describe the best state for implementing the technical idea of the present invention, and various changes required in the specific application fields and uses of the present invention are possible. Therefore, the detailed description of the invention is not intended to limit the invention to the disclosed embodiment. In addition, the appended claims should be construed as including other embodiments.

1: porous cervical cage
10: bone growth
10a: void
10b: structural part
11: Receptacle
13: fixed part
131: fixed part slope
133: fixed part horizontal plane
135: fixed part vertical surface
30: frame part
30a: through hole
31: upper limb
311: first protrusion
3111: first protrusion slope
3113: first protrusion dimension plane
3115: first protruding dimension perpendicular surface
32: lower rim
321: second protrusion
3211: second protrusion slope
3213: second protruding dimension plane
3215: 2nd protruding dimension perpendicular surface
33: left rim
34: right rim
35: connection
50: coupling portion
50a: front
51: connection hole
B: bone graft
C: cervical bone
H: central horizontal plane
P: central vertical surface
S: surgical instruments

Claims (12)

It includes a bone growth portion inserted into the space between adjacent cervical spine bones to promote bone growth, and a frame portion formed to support the bone growth portion,
The frame part is formed to support the inside of the bone growth part to widen the area of the bone growth part, and the frame part is formed in a cross shape, which is symmetrical up and down with respect to a central horizontal plane, and symmetrical left and right with respect to a central vertical plane, and It includes a through hole penetrating through,
The frame portion, an annular upper rim portion supporting an upper side of the bone growth portion, an annular lower side rim portion supporting the lower side of the bone growth portion, and an annular left rim portion supporting the left side of the bone growth portion And, a porous cervical vertebral cage for promoting bone fusion, characterized in that it comprises a ring-shaped right rim that supports the inside of the right side of the bone growth part. delete delete delete The porous cervical vertebrae cage according to claim 1, wherein the frame part further comprises a connection part connecting the rear surface of the upper rim and the rear upper surface of the lower rim. [6] The porous cervical vertebrae cage according to claim 5, wherein a plurality of the connecting portions are formed at regular intervals parallel to the central vertical surface. The method of claim 1, wherein the upper rim part comprises a first protrusion protruding obliquely rearwardly on the left and right upper ends, and the lower rim comprises a second protrusion protruding obliquely rearwardly on the left and right lower ends. Characterized in that, a porous cervical vertebral cage to promote bone fusion. The method of claim 7, wherein the upper rim part is exposed to the outside of the bone growth part, the lower part is exposed to the outside of the bone growth part, and the left rim part is exposed to the outside of the bone growth part. , The right rim portion, characterized in that the right end is exposed to the outside of the bone growth portion, the porous cervical vertebrae cage to promote bone union. The porous cervical vertebrae cage according to claim 1, wherein the porous cervical vertebral cage further comprises a coupling part protruding anteriorly on the frame part. The porous cervical vertebrae cage according to claim 9, wherein the coupling portion is formed to be convex in an anterior direction to widen a contact surface with the bone growth portion. The porous cervical vertebral cage according to claim 10, wherein the coupling part includes a connection hole having a front surface exposed to the outside of the bone growth part and recessed on the front surface. The porous cervical vertebrae cage according to claim 1, wherein the bone growth part is formed with a fixed part protruding obliquely in the posterior direction on the upper surface and the lower surface.

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