CN211797048U

CN211797048U - Manufacturing system of fusion cage

Info

Publication number: CN211797048U
Application number: CN201921379698.7U
Authority: CN
Inventors: 徐凯; 文晓宇; 张靖; 孙陆; 刘也
Original assignee: Beijing Zhisu Health Technology Co ltd
Current assignee: Beijing Zhisu Health Technology Co ltd
Priority date: 2019-08-23
Filing date: 2019-08-23
Publication date: 2020-10-30
Anticipated expiration: 2029-08-23

Abstract

The utility model discloses a fuse ware manufacturing system, this system includes: a human body scanning apparatus and an arithmetic processing apparatus, and a manufacturing apparatus; the human body scanning equipment is used for scanning a target bone to obtain a bone image, wherein the target bone is a bone used as a reference for manufacturing parameters of the fusion cage; the operation processing equipment is used for calculating and obtaining a corresponding bone elastic modulus according to the bone image; the manufacturing equipment is used for manufacturing the fusion cage according to preset structural characteristics corresponding to different bone elasticity moduli. The cage designed according to the preset structural characteristics can be well matched with the bone characteristics of different people, and the technical problems that the stress shielding effect of the cage is caused due to the fact that the elasticity modulus of the cage is not matched with the actual bone characteristics of different patients, bone absorption is caused, the cage is loosened, and the cage is failed to be planted are solved.

Description

Manufacturing system of fusion cage

Technical Field

The utility model relates to a fuse ware field of making especially indicates a manufacturing system of fuse ware.

Background

Currently, a fusion cage is a device used in bones for supporting and equally dividing supporting loads, and mainly used for simulating the bone structure of a human body, for example, a vertebral fusion cage is used for adjusting the bone gap height and the physiological curvature of a spine of the human body.

It has been found clinically that the modulus of elasticity of the cage needs to be matched to the actual characteristics of the bone of different patients. If the elasticity modulus of the fusion cage is not matched with the actual characteristics of bones of different patients, the stress shielding effect of the fusion cage can be caused, so that the bone absorption is caused, the fusion cage is loosened, and the implantation of the fusion cage fails.

So utility model people discover to have following problem among the prior art at least, because the elastic modulus of fusion ware and different patients' skeleton actual characteristics mismatch, appear the stress that leads to the fusion ware and shield the effect, cause the bone to absorb, and then make the fusion ware not hard up, fuse the technical problem that the ware was planted and is failed.

SUMMERY OF THE UTILITY MODEL

The application provides a manufacturing system of a fusion cage, which aims to solve the technical problems that stress shielding effect of the fusion cage is caused due to mismatching of the elastic modulus of the fusion cage and actual characteristics of bones of different patients, so that bone absorption is caused, the fusion cage is loosened, and the fusion cage is failed to be planted;

the system comprises: a human body scanning apparatus and an arithmetic processing apparatus, and a manufacturing apparatus;

the human body scanning equipment is used for scanning a target bone to obtain a bone image, wherein the target bone is a bone used as a reference for manufacturing parameters of the fusion cage;

the operation processing equipment is used for calculating and obtaining a corresponding bone elastic modulus according to the bone image;

the manufacturing equipment is used for manufacturing the fusion cage according to preset structural characteristics corresponding to different bone elasticity moduli.

Optionally, the human body scanning device is further configured to scan a plurality of layers of cross sections of the target bone to obtain a bone image corresponding to each layer of cross section;

the operation processing equipment is further used for calculating a gray value corresponding to each layer of the skeleton image according to the skeleton images of the multilayer cross section, and calculating a comprehensive gray value according to the gray value corresponding to each layer of the skeleton image in a preset mode, wherein the comprehensive gray value is a gray value used for describing the whole skeleton image; and obtaining the bone elastic modulus corresponding to the target bone according to the comprehensive gray value and the corresponding relation between the preset gray value and the bone elastic modulus.

Optionally, the operation processing device is further configured to configure preset structural features corresponding to different bone elastic moduli on a preset fusion cage model to obtain three-dimensional data of the fusion cage model;

and the manufacturing equipment is used for carrying out three-dimensional printing according to the three-dimensional data to obtain the fusion cage.

Optionally, the operation processing device is further configured to calculate, according to the bone elastic modulus and according to a predetermined rule, to obtain corresponding lattice structure levels, where the lattice structure levels represent combination manners of the preset structural features at different levels, and the different levels of the preset structural features are levels divided according to structural parameters corresponding to the preset structural features;

and the three-dimensional data of the fusion device model is obtained by configuring a preset fusion device model according to the lattice structure grade.

Optionally, the fusion cage is provided with a lattice structure supported by space bars, and through holes are formed in gaps between the space bars and arranged in layers.

Optionally, the fusion device has a lumen, and the through-hole extends through the exterior of the fusion device and the lumen.

Optionally, a lattice structure is disposed on a side of the cage.

Optionally, a plurality of protrusions are distributed at two ends of the fusion cage.

Optionally, one side of the fusion cage is provided with an instrument hole communicating the inner cavity with the outside of the fusion cage.

Optionally, the cage is an integrally formed support structure.

As can be seen, based on the above embodiment, a bone image is obtained by scanning a bone, and then a corresponding bone elastic modulus is obtained through the bone image, so as to obtain a preset structural feature, and a fusion cage designed according to the preset structural feature can be well matched with bone features of different people, so that the technical problems that the elastic modulus of the fusion cage is not matched with actual bone features of different patients, stress shielding effect of the fusion cage occurs, bone absorption is caused, the fusion cage becomes loose, and the fusion cage is failed to be planted are solved.

Drawings

FIG. 1 is a schematic diagram of a process 100 of a method of making a cage according to the present invention;

FIG. 2 is a schematic diagram of a process 200 of a method of manufacturing a cage according to the present invention;

FIG. 3 is a schematic diagram of a process 300 of a method of manufacturing a cage according to the present invention;

FIG. 4 is a schematic diagram of a process 400 of a method of making a cage according to the present invention;

FIG. 5 is a schematic view of the external structure of the fusion cage of the present invention;

FIG. 6 is a schematic diagram of a manufacturing system of the present invention;

FIG. 7 is a schematic diagram of the manufacturing apparatus of the fusion cage of the present invention.

Description of the labeling:

10 fusion device

1 lattice structure

11 space rod

12 through hole

13 projection

14 mechanical hole

101 human body scanning device

102 arithmetic processing device

103 manufacturing equipment

201 scanning module

202 computing module

203 manufacturing module

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and examples.

Fig. 1 is a schematic diagram of a process 100 of a method for manufacturing a fusion cage according to the present invention. In one embodiment, as shown in fig. 1, the present application provides a method of manufacturing a cage, the method comprising:

s101, scanning a target bone to obtain a bone image, wherein the target bone is a bone used as a reference for manufacturing parameters of the fusion cage;

in this step, the target bone of the human body needs to be scanned first, and a bone image is obtained. The scanning may be performed by a CT machine, wherein the target bone may be understood as the bone to which the bone elastic modulus reference is made at the time of fabrication of the fusion device, i.e. the bone to which the lesion needs to be replaced.

S102, calculating to obtain a corresponding bone elastic modulus according to the bone image;

the bone elastic modulus is calculated in this step from the bone image obtained in the previous step.

S103, manufacturing the fusion cage according to the preset structural characteristics corresponding to the different bone elastic moduli.

The modulus of elasticity of the bone obtained according to the previous step will correspond to different predetermined structural characteristics, i.e. the rodDiameter, pore size, porosity, number of layers, and the like. By means of special measures, e.g. dividing the structural parameters of the rod diameter into n₁The characteristic parameters of the rod diameter of the grades, i.e. 1 to 3 mm into a first grade and 5 to 8mm into a second grade, are equivalent to establishing two grades. Similarly, the aperture is divided into n₂Individual grade, porosity divided by n₃Number of layers divided into n₄Level, finally forming a level of n₁、n₂、n₃、n₄A set or matrix of, different n₁、n₂、n₃、n₄Corresponding to different bone elastic moduli E (the bone elastic moduli are denoted by E).

Otherwise, different bone elastic moduli correspond to different grades of rod diameter, pore diameter, porosity and layer number, different grades corresponding to preset structural characteristics can be obtained according to the bone elastic moduli, and different structural parameters corresponding to the preset structural characteristics are obtained according to the different grades. Then, the structural parameters are finally set on a preset fuser model to be manufactured, and a fuser is manufactured by the fuser model.

In this embodiment, a method for manufacturing a fusion cage is provided, which includes scanning a human bone to obtain a bone image, calculating a corresponding bone elastic modulus according to the bone image, and manufacturing the fusion cage according to a preset structural feature corresponding to the bone elastic modulus. It should be noted that the above examples of the preset structural features are only for better illustrating the embodiment and are not specific limitations to the embodiment.

Fig. 2 is a schematic diagram of a process 200 of the method for manufacturing the fusion cage according to the present invention. As shown in fig. 2, in an embodiment, the scanning the target bone to obtain the bone image includes:

s201, scanning the multilayer cross section of the target skeleton to obtain a skeleton image corresponding to each layer of cross section;

in the step, the target bone can be scanned by multiple layers of cross sections to obtain a bone image corresponding to each layer of cross section, such as a CT (computed tomography) machine, so that the purpose of the step can be realized.

The step of calculating the corresponding bone elastic modulus according to the bone image comprises:

s202, calculating a gray value corresponding to each layer of the bone image according to the bone images of the multilayer cross sections;

in the step, the gray value of each layer of bone image is calculated according to the bone image of each layer. For example, if the slice of CT is a bone image that has been visualized, the gray scale of the bone image is calculated.

S203, calculating according to the gray value corresponding to each layer of the bone image in a preset mode to obtain a comprehensive gray value, wherein the comprehensive gray value is used for describing the whole bone image;

in this step, a comprehensive gray value may be calculated in a predetermined manner, such as weighting or averaging each layer of the bone image, and the comprehensive gray value is used to describe a gray value of the entire bone image, which may actually be understood as a gray value of the three-dimensional model if the entire target bone generates the three-dimensional model from each layer of the bone image. Therefore, the superposition of the multi-layer cross sections can be understood as a three-dimensional model image of the target skeleton.

And S204, obtaining the bone elastic modulus corresponding to the target bone according to the corresponding relation between the comprehensive gray value and the bone elastic modulus according to the preset gray value.

In this step, a corresponding relationship between a gray value and the bone elastic modulus is first established, because the bone elastic modulus can be understood as the brightness of the bone density, then the gray value of the bone image can be understood as an embodiment of the bone density on the image visualization level. Therefore, there is a corresponding relationship between the gray scale value and the bone elastic modulus, so that the corresponding bone elastic modulus can be obtained through the gray scale value.

In this embodiment, the bone may be scanned by a scanning device such as a CT scanner. The essence of the method lies in obtaining the density of the bone, and the specific technical means is to obtain the gray value of the bone image and calculate the bone elastic modulus correspondingly according to the gray value.

In one embodiment, the predetermined structural features include pore size, and/or porosity, and/or number of layers, and/or rod diameter.

Specific aspects of one predetermined structural feature, including, but not limited to, pore size, and/or porosity, and/or number of layers, and/or rod diameter, are provided in this embodiment.

Fig. 3 is a schematic diagram of a process 300 of the method for manufacturing the fusion cage according to the present invention. As shown in fig. 3, in an embodiment, the manufacturing of the fusion cage according to the preset structural characteristics corresponding to different elastic moduli of bone comprises:

s301, configuring preset structural features corresponding to different bone elastic moduli on a preset fusion cage model to obtain three-dimensional data of the fusion cage model;

in this step, a method for designing the fusion cage according to different configurations of preset structural features to obtain corresponding three-dimensional data after design is provided. It should be noted that the cage model is a three-dimensional cage model having other characteristics than the preset structural characteristics, and since the cage has many other characteristics besides the characteristics affecting the elastic modulus of the bone, such as the external contour size, etc., the other characteristics need to be set to obtain the preset cage model.

And S302, performing three-dimensional printing according to the three-dimensional data to obtain the fusion device.

And in the step, three-dimensional printing is carried out on the three-dimensional data obtained in the previous step, and finally the fusion cage is obtained.

In this embodiment, a specific method for manufacturing a fusion cage according to a bone elastic modulus is provided, that is, configuring preset structural features corresponding to different bone elastic moduli on a preset fusion cage model to obtain three-dimensional data of the fusion cage model, and performing three-dimensional printing according to the three-dimensional data to obtain the fusion cage.

Fig. 4 is a schematic diagram of a process 400 of a method for manufacturing a cage according to the present invention. As shown in fig. 4, in an embodiment, the configuring preset structural features corresponding to different bone elastic moduli on a preset cage model to obtain three-dimensional data of the cage model includes:

s401, calculating according to the bone elastic modulus and a preset rule to obtain corresponding lattice structure grades, wherein the lattice structure grades represent a combination mode of different grades of the preset structural features, and the different grades of the preset structural features are grades divided according to structural parameters corresponding to the preset structural features;

the different bone elastic moduli correspond to different lattice structure levels in this step, and the predetermined rule here is the correspondence of the bone elastic moduli with the different lattice structure levels obtained through a large number of experiments. The specific grading method has been introduced above, and is not described herein again.

S402, configuring a preset fusion device model according to the lattice structure grade to obtain three-dimensional data of the fusion device model.

In the step, the lattice structure grade, the combination mode of the preset structure characteristics and the corresponding relation between different grades of the preset structure characteristics are provided.

In the embodiment, the corresponding lattice structure grade is obtained by calculation according to the elastic modulus of the bone and a preset rule; obtaining a combination mode corresponding to the preset structural feature according to the lattice structure grade, wherein the combination mode is a data set or a matrix obtained by combining different grades of the preset structural feature according to a preset mode, and the different grades of the preset structural feature represent corresponding characteristic values of the preset structural feature; and designing the fusion cage according to the manner of determining the three-dimensional data of the fusion cage according to the feature numerical configuration of the corresponding preset structural feature in the combination manner, so as to obtain the three-dimensional data of the fusion cage, wherein a specific data relationship will be described in detail later, and will not be described herein again.

The working process and the basic principle are as follows:

the present application is essentially a method for manufacturing a medical device, and the following further description will be given by taking a specific embodiment of a clinical fusion device as an example, and it should be noted that the following is only an example of the present application and is not a specific limitation of the present application.

Scanning a target bone to obtain a bone image, wherein the target bone is a bone used as a reference of a fusion device manufacturing parameter;

in this step, the target bone is first scanned. The scan may be a CT scan, although other methods of acquiring scan data are possible. In addition, it should be noted that, according to the foregoing description, it can be known that the obtained scan data may be a cross-sectional view obtained by CT scanning, or spatial point scan data corresponding to a bone may also be obtained.

Calculating a gray value corresponding to each layer of the bone image according to the bone images of the multilayer cross section;

calculating according to the gray value corresponding to each layer of the bone image in a preset mode to obtain a comprehensive gray value, wherein the comprehensive gray value is used for describing the whole bone image; and obtaining the bone elastic modulus corresponding to the target bone according to the comprehensive gray value and the corresponding relation between the preset gray value and the bone elastic modulus.

The method comprises the steps of calculating a multi-layer cross section bone image scanned by a CT machine to obtain a bone elastic modulus, and acquiring a gray value of the bone image in a manner of utilizing rectangular region identifiers corresponding to different fusion device specifications on the cross section image and acquiring a rectangular region CT image gray value.

And then calculating to obtain the corresponding bone elastic modulus according to the gray value, wherein the essence of the method is to obtain the corresponding bone elastic modulus according to the gray value corresponding to different human bone densities and aiming at different human bone densities. The corresponding relation of the step is preset in corresponding equipment, and specific data come from long-term clinical experience accumulation.

Calculating according to the bone elastic modulus and a preset rule to obtain corresponding lattice structure grades, wherein the lattice structure grades represent the combination mode of the preset structure characteristics at different grades, and the different grades of the preset structure characteristics are grades divided according to the structure parameters corresponding to the preset structure characteristics;

and configuring a preset fusion device model according to the lattice structure grade to obtain the three-dimensional data of the fusion device model.

Fig. 5 is a schematic view of the external structure of the fusion cage of the present invention. As shown in fig. 5, the preset structural features corresponding to the different bone elastic moduli calculated above are configured in this step, and the specific configuration method has been described in the previous embodiment, and the structural features of the fusion device itself are further described herein. Firstly, the fusion cage is made of titanium alloy materials, because the difference between the elastic modulus of titanium and the elastic modulus of bones is large, if the titanium and the bone are not matched with each other, the stress shielding effect of the fusion cage can be caused, the bones are absorbed, and then the fusion cage is loosened, and the planting fails.

In order to solve the above problems, lattice structures with different structures are arranged on the fusion device, and the lattice results mainly comprise structural characteristics such as rod diameter, pore diameter, porosity and layer number.

As shown in fig. 5, the present application also provides a fusion cage, wherein a lattice structure 1 is provided on the fusion cage 10, the lattice structure 1 is supported by space bars 11, through holes 12 are formed in the gaps between the space bars 11, and the through holes 12 are arranged in layers.

In one embodiment, the fusion cage 10 has a lumen 2, and the through-hole 12 extends through the exterior of the fusion cage 10 and the lumen 2.

In one embodiment, lattice structure 1 is disposed on a side of cage 10.

In one embodiment, a plurality of protrusions 13 are distributed at both ends of the cage 10.

In one embodiment, one side of the cage 10 is provided with an instrument hole 14 communicating the lumen 2 with the outside of the cage 10.

In one embodiment, cage 10 is an integrally formed support structure.

According to the previous description: dividing the rod diameter into n₁In one order, the aperture is divided into n₂Individual grade, porosity divided by n₃Number of layers divided into n₄Grade, finalForm an angle with respect to n₁、n₂、n₃、n₄A set or matrix of, different n₁、n₂、n₃、 n₄Corresponding to different lattice levels, and different lattice structure levels corresponding to different bone elastic moduli E (the bone elastic moduli are denoted by E). Here, the rod diameter may be understood as the diameter of the space rod 11, the hole diameter may be understood as the diameter of the through-hole 12, and the number of layers may be understood as the number of layers after the through-holes 12 are arranged in layers.

Through a large number of experiments, we distributed the design value ranges and grades of rod diameter, pore diameter, porosity and number of layers as follows:

the rod diameter ranges from 300 μm to 800 μm, the porosity is from 5% to 90%, the pore diameter is from 50 to 1500 μm, and the number of layers is from 3 to 6.

The rod diameters are classified into 3 grades, 0.3 to 0.5mm, 0.5 to 0.7mm, 0.7 to 0.8 mm.

The porosity is graded as 8, in order of 5 to 20%, 20 to 30%, 30 to 40%, 40 to 50%, 50 to 60%, 60 to 70%, 70 to 80%, 80 to 90%.

The pore diameter is 7 grades, and is 50-200 μm, 200-400 μm, 400-600 μm, 600-800 μm, 800-1000 μm, 1000-1200 μm and 1200-1500 μm in sequence.

The number of layers is divided into 3 grades, 3 to 4, 4 to 5, 5 to 6 layers.

Then for n₁、n₂、n₃、n₄The different combinations can be understood as different levels of crystal structure, obviously the arrangement of the lattice structures of different levels with respect to the above predetermined structural characteristics is different, and the difference of the levels of the lattice structures can lead to the difference of the bone elastic modulus of the fusion device.

In the clinical process, firstly, the doctor can perform integral shaping on the external dimension of the fusion device according to the actual condition of the patient, the shaping can be configured with a plurality of standard shapes in advance, the manual selection can be performed, the pre-configuration can be directly selected from the system, and the shaping can be understood as the selection and the shaping of the external dimension of the support structureAfter molding, a lattice structure mode corresponding to the elastic modulus of the bone is only needed to be configured on the molding. Then the elastic modulus of the bone of the patient can be obtained according to the method of the application, and then the corresponding lattice structure grade is obtained, and finally n is obtained₁、n₂、n₃、n₄Of course, it is not difficult to find that even if the obtained grade is a data range, the specific value can be selected according to some other predetermined configuration mode, and even the same lattice structure grade is found to correspond to different n₁、n₂、n₃、n₄The combinations of (a) and (b) may also be chosen in predetermined configurations, since they are equivalent to each other and may even be chosen in a random manner.

And performing three-dimensional printing according to the three-dimensional data to obtain the fusion device.

In the step, the three-dimensional data are configured according to the description of the structural characteristics, and the fusion cage which conforms to different bone elastic moduli can be obtained by performing 3D on the three-dimensional data.

The crystal structure on the cage at this time can provide a matched bone elastic modulus and be applied to the corresponding patient. The technical problems that the stress shielding effect of the fusion cage is caused due to the fact that the elasticity modulus of the fusion cage is not matched with the actual characteristics of bones of different patients, bone absorption is caused, the fusion cage is loosened, and the fusion cage is failed to be planted are solved.

Fig. 6 is a schematic diagram of the manufacturing system of the fusion cage of the present invention. As shown in fig. 6, the present embodiment provides a specific implementation method for manufacturing a fuser by 3D printing technology.

In one embodiment, the present application further provides a system for manufacturing a fusion cage, the system comprising: a human body scanning device 101 and an arithmetic processing device 102, and a manufacturing device 103;

the human body scanning device 101 is configured to scan a target bone to obtain a bone image, where the target bone is a bone used as a reference for a fusion device manufacturing parameter;

the operation processing device 102 is configured to calculate a corresponding bone elastic modulus according to the bone image;

the manufacturing device 103 is used for manufacturing the fusion cage according to preset structural features corresponding to different bone elastic moduli.

In an embodiment, the human body scanning device is further configured to scan a plurality of layers of cross sections of the target bone to obtain a bone image corresponding to each layer of cross section;

the operation processing device 102 is further configured to calculate a gray value corresponding to each layer of the bone image according to the bone images of the multi-layer cross section, and calculate a comprehensive gray value according to the gray value corresponding to each layer of the bone image in a predetermined manner, where the comprehensive gray value is a gray value used for describing the whole bone image; and obtaining the bone elastic modulus corresponding to the target bone according to the comprehensive gray value and the corresponding relation between the preset gray value and the bone elastic modulus.

In an embodiment, the arithmetic processing device 102 is further configured to configure preset structural features corresponding to different bone elastic moduli on a preset fusion cage model to obtain three-dimensional data of the fusion cage model;

the manufacturing device 103 is configured to perform three-dimensional printing according to the three-dimensional data to obtain the fusion cage.

In an embodiment, the arithmetic processing device 102 is further configured to obtain corresponding lattice structure levels according to the bone elastic modulus and a predetermined rule, where the lattice structure levels represent combination manners of the preset structural features at different levels, and the different levels of the preset structural features are levels classified according to structural parameters corresponding to the preset structural features;

Fig. 7 is a schematic diagram of the framework of the manufacturing device of the fusion cage of the present invention. As shown in fig. 7, in one embodiment, the present application also provides a device for manufacturing a fusion cage, the device including:

the scanning module 201 is configured to scan a target bone to obtain a bone image, where the target bone is a bone used as a reference for a fusion device manufacturing parameter;

a calculating module 202, configured to calculate a corresponding bone elastic modulus according to the bone image;

a manufacturing module 203, configured to manufacture the fusion cage according to preset structural features corresponding to different bone elastic moduli.

In one embodiment, the present application also provides an apparatus for manufacturing a fusion cage, the apparatus including: a processor and a memory;

the memory stores an application program executable by the processor for causing the processor to perform any of the steps of the method for manufacturing a cage.

In an embodiment, the present application further provides a computer readable storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of any of the methods of manufacturing a cage.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A manufacturing system for a fusion cage, the system comprising: a human body scanning device (101) and an arithmetic processing device (102), and a manufacturing device (103);

the human body scanning device (101) is used for scanning a target bone to obtain a bone image, wherein the target bone is a bone used as a reference of a fusion device manufacturing parameter;

the operation processing equipment (102) is used for calculating and obtaining a corresponding bone elastic modulus according to the bone image;

the manufacturing equipment (103) is used for manufacturing the fusion cage according to preset structural characteristics corresponding to different bone elasticity moduli.

2. The manufacturing system of the cage according to claim 1,

the human body scanning equipment (101) is further used for scanning the multi-layer cross section of the target skeleton to obtain a skeleton image corresponding to each layer of cross section;

the operation processing equipment (102) is further used for calculating a gray value corresponding to each layer of the bone image according to the bone images of the multi-layer cross section, and calculating a comprehensive gray value according to the gray value corresponding to each layer of the bone image in a preset mode, wherein the comprehensive gray value is a gray value used for describing the whole bone image; and obtaining the bone elastic modulus corresponding to the target bone according to the comprehensive gray value and the corresponding relation between the preset gray value and the bone elastic modulus.

3. The manufacturing system of the cage according to claim 2,

the operation processing equipment (102) is further used for configuring preset structural features corresponding to different bone elasticity moduli on a preset fusion cage model to obtain three-dimensional data of the fusion cage model;

the manufacturing equipment (103) is used for carrying out three-dimensional printing according to the three-dimensional data to obtain the fusion device.

4. The manufacturing system of the cage according to claim 3,

the operation processing equipment (102) is further configured to calculate according to the bone elastic modulus and a predetermined rule to obtain corresponding lattice structure grades, wherein the lattice structure grades represent combination modes of the preset structural features of different grades, and the different grades of the preset structural features are grades divided according to structural parameters corresponding to the preset structural features;

5. The manufacturing system of the cage according to any of claims 1 to 4, wherein the cage (10) is provided with a lattice structure (1), the lattice structure (1) being a lattice structure supported by space bars (11), gaps between the space bars (11) forming through holes (12), the through holes (12) being arranged in layers.

6. The manufacturing system of the cage according to claim 5, wherein the cage (10) has an inner cavity (2), and the through-hole (12) penetrates through the outer portion of the cage (10) and the inner cavity (2).

7. Manufacturing system of a cage according to claim 5, characterized in that a lattice structure (1) is provided at the side of the cage (10).

8. Manufacturing system of a cage according to claim 5, characterized in that a plurality of protrusions (13) are distributed on both ends of the cage (10).

9. Manufacturing system of a cage according to claim 6, characterized in that one side of the cage (10) is provided with an instrument hole (14) communicating the inner chamber (2) with the outside of the cage (10).

10. Manufacturing system of a cage according to claim 5, characterized in that the cage (10) is an integrally formed support structure.