TR201819753A2 - ANKLE ANKLE PROSTHESIS - Google Patents

Abstract

The invention is an ankle prosthesis (1) that can be applied to patients with ankle joint damage and enables the ankle joint range of motion to be close to normal ankle functions. The tibial stem (10) having a component junction (14) that fits into the stem stabilization groove (21) and provides it to be associated with the tibial component (20) on its lower surface, the component junction place (14) in the said tibial stem (10) is placed in the stem stabilization groove. (21) comprising a tibial component (20), the lower surface of the said tibial component (20), the sphere (23) that is seated on the sphere bearing (44) in the talar component (40) and that performs anterior-posterior linear movement within the sphere bearing (44). comprising an insert (30) with a sphere motion cavity (36) consisting of an anterior sphere motion groove (33) and a sphere motion groove (36) in which the sphere (23) in the tibial component (20) can move, The talar component housing that provides the connection between the insert (30) and the talar component (40) by sitting on the insert talar component channels (45) located on the talar component (40) at the lower part of the said insert (30). a canals (35), on its upper surface, the sphere (23) located in the lower part of the tibial component (20) includes a talar component (40) with a sphere bearing (44) where it can perform anterior-posterior linear movement, said talar component (40) characterized in that it comprises insert talar component channels (45) that fit into the talar component housing channels (35) located on the lower part of the insert (30) side surface (37) on its upper surface.

Description

DESCRIPTION AN ANKLE PROSTHESIS Technological Field: The invention can be applied to patients with ankle joint damage, ankle so that the range of motion of the joint is close to normal ankle function relates to a new ankle prosthesis that can function.

The invention is better suited to the anatomical features of the talus and tibia. more suitable for ankle mechanics and kinematics, allowing fixation relates to a new ankle replacement.

State of the Art: Total ankle prosthesis application was first introduced in the early 1970s. has been tried; However, due to insufficient early results, this The application of the method was stopped after a while. This is known as the first generation. The ankle prosthesis was implanted by Lord and Marotte. design, total a tibial bone with an elongated body resembling the femoral component in a knee replacement contains the component. The talar component includes almost the entire talus. It consists of a piece of polyethylene. After 10 years, only 7 out of 25 patients success was achieved and 12 of the implants were damaged.

New Jersey Cylindrical prosthesis, talar with a metal tibial component and a polyethylene dome It was designed in 1976 as a two-piece prosthesis consisting of two components.

The harmonious spherical surfaces create a contact area of 5.2 cm2. Prosthesis 20 65 degrees of dorsalflexion and 45 degrees of plantarflexion Allows a range of motion. This design is later to the design of Buechel Pappas, which is edited and used today. has been converted.

DESCRIPTION AN ANKLE PROSTHESIS Technological Field: The invention can be applied to patients with ankle joint damage, ankle so that the range of motion of the joint is close to normal ankle function relates to a new ankle prosthesis that can function.

The invention is better suited to the anatomical features of the talus and tibia. more suitable for ankle mechanics and kinematics, allowing fixation relates to a new ankle replacement.

State of the Art: Total ankle prosthesis application was first introduced in the early 1970s. has been tried; However, due to insufficient early results, this The application of the method was stopped after a while. This is known as the first generation. The ankle prosthesis was implanted by Lord and Marotte. design, total a tibial bone with an elongated body resembling the femoral component in a knee replacement contains the component. The talar component includes almost the entire talus. It consists of a piece of polyethylene. After 10 years, only 7 out of 25 patients success was achieved and 12 of the implants were damaged.

New Jersey Cylindrical prosthesis, talar with a metal tibial component and a polyethylene dome It was designed in 1976 as a two-piece prosthesis consisting of two components.

The harmonious spherical surfaces create a contact area of 5.2 cm2. Prosthesis 20 65 degrees of dorsalflexion and 45 degrees of plantarflexion Allows a range of motion. This design is later to the design of Buechel Pappas, which is edited and used today. has been converted.

Many clinical results of the first period designs total ankle prosthesis recommended to continue its use. Total ankle replacement in general implantations only due to high complication rates and damage. Restriction to use in elderly patients with limited physical demands has been suggested. However, important lessons have been drawn from the early designs. First greater amount of bone resection of the use of bone cement It has been understood that this causes the metal component to collapse.

There is a relationship between the stability of the prosthesis and a wider range of motion. It was concluded that a balance should be created. Clinically, the prosthesis Complications of relaxation, constant pain, delayed wound healing time has been seen.

Afterwards, second generation ankle prosthesis applications were started in the late 1980s. has been put into use since. Natural anatomy of the ankle and promising with ankle prostheses designed considering biomechanics As results begin to appear, ankle prosthesis use becomes more common. has become. According to the results of gait and electromyography analysis, second generation activities of daily living in patients who underwent ankle prosthesis application. Although the range of motion is within normal limits, various It was observed that the range of motion was abnormal in the stages of

Use of second generation cementless, minimally constrained, three-piece implants Prosthesis use is ideal in individuals with ankle joint damage due to the prevalence of started to be accepted as a treatment method. second generation ankle prostheses: Star, Hintegra, Salto, BuecheI-Pappas, Mobility and Box prostheses.

Today, the third generation cementless, unrestricted, mobile carrier (mobile bearing) ankle prostheses are widely used. With these designs Many complications have been eliminated. These designs are more successful reasons why: Many clinical results of the first period designs total ankle prosthesis recommended to continue its use. Total ankle replacement in general implantations only due to high complication rates and damage. Restriction to use in elderly patients with limited physical demands has been suggested. However, important lessons have been drawn from the early designs. First greater amount of bone resection of the use of bone cement It has been understood that this causes the metal component to collapse.

There is a relationship between the stability of the prosthesis and a wider range of motion. It was concluded that a balance should be created. Clinically, the prosthesis Complications of relaxation, constant pain, delayed wound healing time has been seen.

Afterwards, second generation ankle prosthesis applications were started in the late 1980s. has been put into use since. Natural anatomy of the ankle and promising with ankle prostheses designed considering biomechanics As results begin to appear, ankle prosthesis use becomes more common. has become. According to the results of gait and electromyography analysis, second generation activities of daily living in patients who underwent ankle prosthesis application. Although the range of motion is within normal limits, various It was observed that the range of motion was abnormal in the stages of

Use of second generation cementless, minimally constrained, three-piece implants Prosthesis use is ideal in individuals with ankle joint damage due to the prevalence of started to be accepted as a treatment method. second generation ankle prostheses: Star, Hintegra, Salto, Buechel-Pappas, Mobility and Box prostheses.

Today, the third generation cementless, unrestricted, mobile carrier (mobile bearing) ankle prostheses are widely used. With these designs Many complications have been eliminated. These designs are more successful reasons why: a) Correct patient selection b) Recognizing ankle biomechanics c) Use of less constrained designs with low bone resection d) The importance of soft tissue balance and the compatibility of the components that make up the prosthesis e) Biocompatibility of ankle prostheses Considering the results in general, we are told that during the surgical application The need to create a design that minimizes soft tissue damage it is understood. The most important lesson about previous designs is that the polyethylene used relates to its components. Mutually incompatible articular surfaces, It allows dorsalflexion/plantarflexion and axial rotation, but this movements that cause excessive wear on the polyethylene component. results in high local stresses. Therefore, greater stability and For wear resistance, designs with mutually matching surfaces are needed. has been heard.

Presence of soft tissue limitation in the ankle, talus persistence of problems in fixation of ankle mechanics and kinematics A new ankle prosthesis design was made taking into account the insufficiency of the ankle. This For this purpose, less bone resection and better talus fixation are included in the system. has been made. In addition to these, the mobility and limitation of the system are controlled. has been provided.

In most finite element models, the biomechanics of the ankle are created. loads and boundary conditions are simplified. Some finite element studies However, none of them have bone structure belonging to the foot-ankle complex, All ligaments, fascia and soft tissue components are absent.

In the states patent document, 3 fixation is used in the fixation to the talus and polyethylene is positioned in a bed. In the tibial component it is seen that there is a fixation with a single stem in the middle. a) Correct patient selection b) Recognizing ankle biomechanics 0) Use of less constrained designs with low bone resection d) The importance of soft tissue balance and the compatibility of the components that make up the prosthesis e) Biocompatibility of ankle prostheses Considering the results in general, we are told that during the surgical application The need to create a design that minimizes soft tissue damage it is understood. The most important lesson about previous designs is that the polyethylene used relates to components. Mutually incompatible articular surfaces, It allows dorsalflexion/plantarflexion and axial rotation, but this movements that cause excessive wear on the polyethylene component. results in high local stresses. Therefore, greater stability and For wear resistance, designs with mutually matching surfaces are needed. has been heard.

Presence of soft tissue limitation in the ankle, talus persistence of problems in fixation of ankle mechanics and kinematics A new ankle prosthesis design was made taking into account the insufficiency of the ankle. This For this purpose, less bone resection and better talus fixation are included in the system. has been made. In addition to these, the mobility and limitation of the system are controlled. has been provided.

In most finite element models, the biomechanics of the ankle are created. loads and boundary conditions are simplified. Some finite element studies However, none of them have bone structure belonging to the foot-ankle complex, All ligaments, fascia and soft tissue components are absent.

In the states patent document, 3 fixation is used in the fixation to the talus and polyethylene is positioned in a bed. In the tibial component it is seen that there is a fixation with a single stem in the middle.

US 9,610,168 B2, which was encountered in another literature search. In the United States patent document, with 3 fixations at a 45 degree angle on the tibia Together, 3 stems were used for fixation to the talus.

In the states patent document, 5 protrusions of different sizes for tibial fixation used.

Frontal and lateral fixation in talus fixation in Australian patent document It has holes and it is also possible to place screws from the talus lateral. It has been designed in such a way.

In the United States patent document, 3 holes for fixation of the tibial component available. In the United States patent document no. is a fixed one. There is a structure including the floor of the calcaneus. In the United States patent document no. screws fix the talus and calcaneus, and the tibial component stem It is fixed intramedullary to the tibia. In the United States patent document no., the tibial component anatomical It is designed in accordance with the structure, but the stone component is a funnel-shaped has a stem.

US 9,610,168 82, which was encountered in another literature search. In the United States patent document, with 3 fixations at a 45 degree angle on the tibia Together, 3 stems were used for fixation to the talus.

In the states patent document, 5 protrusions of different sizes for tibial fixation used.

Frontal and lateral fixation in talus fixation in Australian patent document It has holes and it is also possible to place screws from the talus lateral. It has been designed in such a way.

In the United States patent document, 3 holes for fixation of the tibial component available. In the United States patent document no. is a fixed one. There is a structure including the floor of the calcaneus. In the United States patent document no. screws fix the talus and calcaneus, and the tibial component stem It is fixed intramedullary to the tibia. In the United States patent document no., the tibial component anatomical It is designed in accordance with the structure, but the stone component is a funnel-shaped has a stem.

US 4069518A, which was encountered in another literature search. In the United States patent document, the tibial and talar components are intertwined. It is an involuntary structure that can pass. It also provides stability in the tibial component. channels are available.

U83987500A, which was encountered in another literature search. In the United States patent document, the Tibial component stem is square. is in the structure.

U83872519A, which was encountered in another literature search. In the United States patent document, a multilayered pyramidal tibial contains components.

As a result, the known state of the technique has been overcome, its disadvantages have been eliminated, a new ankle prosthesis is needed.

Brief Description of the Invention: The invention shows that the known state of the art is overcome, its disadvantages are eliminated, additional It is a new ankle prosthesis with extra advantages.

The purpose of the invention; represent the ankle joint as closely as possible is to do. In particular, it will allow walking phases and other daily activities. An ankle prosthesis with an appropriate range of motion is to put.

Another aim of the invention is that it can be used in total ankle replacement, a reproducible surgical technique, minimal bone resection, rapid and adequate bone growth, minimal restriction, and physiological ankle movements. To present an ankle prosthesis with continuation and pain relief properties.

US 4069518A, which was encountered in another literature search. In the United States patent document, the tibial and talar components are intertwined. It is an involuntary structure that can pass. It also provides stability in the tibial component. channels are available.

U83987500A, which was encountered in another literature search. In the United States patent document, the Tibial component stem is square. is in the structure.

U83872519A, which was encountered in another literature search. In the United States patent document, a multilayered pyramidal tibial contains components.

As a result, the known state of the technique has been overcome, its disadvantages have been eliminated, a new ankle prosthesis is needed.

Brief Description of the Invention: The invention shows that the known state of the art is overcome, its disadvantages are eliminated, additional It is a new ankle prosthesis with extra advantages.

The purpose of the invention; represent the ankle joint as closely as possible is to do. In particular, it will allow walking phases and other daily activities. An ankle prosthesis with an appropriate range of motion is to put.

Another aim of the invention is that it can be used in total ankle replacement, a reproducible surgical technique, minimal bone resection, rapid and adequate bone growth, minimal restriction, and physiological ankle movements. To present an ankle prosthesis with continuation and pain relief properties.

Another object of the invention is long-term complications and early revision. An ankle prosthesis with a design that will minimize the need for is to put.

Another object of the invention is the load of the contact area between prosthetic components. balanced distribution and suitable for preventing contact forces.

All the above-mentioned and the following will emerge from the detailed explanation. present invention to achieve the objectives of ankle joint damage normal ankle range of motion of the ankle joint, applicable to patients It is an ankle prosthesis that allows it to be close to its functions, and its feature is; on the lower surface, the stem is seated in the stabilization groove with the tibial component. A tibial stem with a component junction that allows the stem in which the component junction in the said tibial stem is seated. containing a tibial component with a stabilization groove, said tibial on the bottom surface of the component, the ball is seated in the ball bearing in the talar component and the ball containing a sphere that performs anterior-posterior linear movement in its bed, An anterior sphere, in which the sphere in the tibial component can move from the area delimited by the motion groove and a posterior globe motion groove comprising an insert with a sphere motion space formed, said insert talar component located on the talar component in the lower part of the insert It sits on the grooves and makes the connection between the insert and the talar component. It contains talar component socket canals that provide anterior-posterior linear movement of the sphere in the lower part of the component by sitting It contains a talar component with a ball bearing that it can perform, on the upper surface of said talar component, on the lower part of the insert side surface insert talar component that fits into talar component slot channels It is characterized by containing channels.

Another preferred embodiment of the invention is characterized by; tibial stem whole Made of bio materials to ensure biocompatibility of surfaces is a coated surface.

Another object of the invention is long-term complications and early revision. An ankle prosthesis with a design that will minimize the need for is to put.

Another object of the invention is the load of the contact area between prosthetic components. balanced distribution and suitable for preventing contact forces.

All the above-mentioned and the following will emerge from the detailed explanation. present invention to achieve the objectives of ankle joint damage normal ankle range of motion of the ankle joint, applicable to patients It is an ankle prosthesis that allows it to be close to its functions, and its feature is; on the lower surface, the stem is seated in the stabilization groove with the tibial component. A tibial stem with a component junction that allows the stem in which the component junction in the said tibial stem is seated. containing a tibial component with a stabilization groove, said tibial on the bottom surface of the component, the ball is seated in the ball bearing in the talar component and the ball containing a sphere that performs anterior-posterior linear movement in its bed, An anterior sphere, in which the sphere in the tibial component can move from the area delimited by the motion groove and a posterior globe motion groove comprising an insert with a sphere motion space formed, said insert talar component located on the talar component in the lower part of the insert It sits on the grooves and makes the connection between the insert and the talar component. It contains talar component socket canals that provide anterior-posterior linear movement of the sphere in the lower part of the component by sitting It contains a talar component with a ball bearing that it can perform, on the upper surface of said talar component, on the lower part of the insert side surface insert talar component that fits into talar component slot channels It is characterized by containing channels.

Another preferred embodiment of the invention is characterized by; tibial stem whole Made of bio materials to ensure biocompatibility of surfaces is a coated surface.

Another preferred embodiment of the invention is characterized by; on the tibial stem It contains a posterior end and an inclined front end to provide anatomical compatibility.

Another preferred embodiment of the invention is characterized by; tibial component on the tibial fixation screw, which provides fixation with the tibial part of the foot. contains holes.

Another preferred embodiment of the invention is characterized by; sphere, ball bearing linear anterior posterior movement by limiting lateral movements in is that it contains the spherical side surfaces that enable it to be realized.

Another preferred embodiment of the invention is characterized by; spherical tibial component It contains a spherical handle that connects it with the lower part.

Another preferred embodiment of the invention is characterized by; anatomical structure of the insert a properly configured insert with a wide anterior section and an insert narrow anterior section.

Another preferred embodiment of the invention is characterized by; talar component A large talar component structured in accordance with the anatomical structure anterior section and a talar component, narrow anterior section.

Another preferred embodiment of the invention is characterized by; talar component on the talar fixation screw, which provides fixation with the talar part of the foot. contains holes.

Explanation of Figures: The invention will be described with reference to the accompanying figures, so that the invention features will become clearer. However, the purpose of this is clear It's not about limiting yourself with regulations. On the contrary, the appended claims of the invention All alternatives, amendments, which may be included in the area in which it is defined by Another preferred embodiment of the invention is characterized by; on the tibial stem It contains a posterior end and an inclined front end to provide anatomical compatibility.

Another preferred embodiment of the invention is characterized by; tibial component on the tibial fixation screw, which provides fixation with the tibial part of the foot. contains holes.

Another preferred embodiment of the invention is characterized by; sphere, ball bearing linear anterior posterior movement by limiting lateral movements in is that it contains the spherical side surfaces that enable it to be realized.

Another preferred embodiment of the invention is characterized by; spherical tibial component It contains a spherical handle that connects it with the lower part.

Another preferred embodiment of the invention is characterized by; anatomical structure of the insert a properly configured insert with a wide anterior section and an insert narrow anterior section.

Another preferred embodiment of the invention is characterized by; talar component A large talar component structured in accordance with the anatomical structure anterior section and a talar component, narrow anterior section.

Another preferred embodiment of the invention is characterized by; talar component on the talar fixation screw, which provides fixation with the talar part of the foot. contains holes.

Explanation of Figures: The invention will be described with reference to the accompanying figures, so that the invention features will become clearer. However, the purpose of this is clear It's not about limiting yourself with regulations. On the contrary, the appended claims of the invention All alternatives, amendments, which may be included in the area in which it is defined by and equivalences are also intended to be covered. Details shown are only illustrated for illustration of preferred embodiments of the present invention, and both the shaping of the methods and the rules of the invention and the conceptual in order to provide the most useful and easy-to-understand description of its properties. presented must be understood. In these drawings; Figure - 3A Figure - 4A Figure - 4D Figure - 5A The subject of the invention is the perspective view of the ankle prosthesis.

Perspective of the tibial stem in the ankle prosthesis, which is the subject of the invention. is the view.

The upper tibial component of the ankle prosthesis, which is the subject of the invention, is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention, is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention, is anterior. is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention perspective view.

The insert in the ankle prosthesis, which is the subject of the invention, is the view.

The insert perspective in the ankle prosthesis, which is the subject of the invention is the view.

The upper talar component in the ankle prosthesis, which is the subject of the invention, is the view.

The talar component in the ankle prosthesis, which is the subject of the invention, perspective view.

Figures to assist in understanding this invention are as indicated in the attached picture. are numbered and given below with their names.

Explanation of References: 1. Ankle prosthesis and equivalences are also intended to be covered. Details shown are only illustrated for illustration of preferred embodiments of the present invention, and both the shaping of the methods and the rules of the invention and the conceptual in order to provide the most useful and easy-to-understand description of its properties. presented must be understood. In these drawings; Figure - 3A Figure - 3i3 Figure - 4A Figure - 4D Figure - 5A The subject of the invention is the perspective view of the ankle prosthesis.

Perspective of the tibial stem in the ankle prosthesis, which is the subject of the invention. is the view.

The upper tibial component of the ankle prosthesis, which is the subject of the invention, is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention, is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention, is anterior. is the view.

The tibial component in the ankle prosthesis, which is the subject of the invention perspective view.

The insert in the ankle prosthesis, which is the subject of the invention, is the view.

The insert perspective in the ankle prosthesis, which is the subject of the invention is the view.

The upper talar component in the ankle prosthesis, which is the subject of the invention, is the view.

The talar component in the ankle prosthesis, which is the subject of the invention, perspective view.

Figures to assist in understanding this invention are as indicated in the attached picture. are numbered and given below with their names.

Explanation of References: 1. Ankle prosthesis .Tibial stem 11. Coated surface 12. Rear end 13. Curved front end 14.Comp0nent junction place .Tibial component 21. Stem stabilization groove 22. Tibial fixation screw hole 23.Sphere 24.Sphere side surface . globe handle 30Jnsen 32.Insert narrow posterior section 34. Posterior ball movement groove 36.Sphere motion space 37.Insert side surface 40.Talar component 41 .Talar component large anterior part 42.Talar component narrow pesteriot section 44. Sphere bearing 45.Insert talar component canal .Tibial stem 11. Coated surface 12. Rear end 13. Curved front end 14.Comp0nent junction place .Tibial component 21. Stem stabilization groove 22. Tibial fixation screw hole 23.Sphere 24.Sphere side surface .Sphere handle 30Jnsen 32.Insert narrow posterior section 34. Posterior ball movement groove 36.Sphere motion space 37.Insert side surface 40.Talar component 41 .Talar component large anterior part 42.Talar component narrow pesteriot section 44. Sphere bearing 45.Insert talar component canal Description of the Invention: In this detailed description, the subject of the invention is the ankle prosthesis (1) only for better understanding, it will not have any limiting effect explained with examples. In the description, those with ankle joint damage normal ankle range of motion of the ankle joint, which can be applied to patients An ankle prosthesis that can function close to its function (1) is explained.

Perspective view of the ankle prosthesis (1), which is the subject of the invention, in Figure 1 are given. Accordingly, ankle prosthesis (1), tibial stem (10), tibial Component (20), insert (30) and talar component (40) consists of parts.

In Figure 2, the tibial stem (10) element of the ankle prosthesis (1) is the subject of the invention. showing view. Accordingly, on the stem (10); a backend (12), an inclined anterior end (13), connecting the stem (10) with the tibial component (20) There is a component junction place (14) that provides it. Tibial stem (10) surface, It consists of a coated surface (11) to ensure biocompatibility. is coming.

In Figure 3A, the tibial component (20) of the ankle prosthesis (1), which is the subject of the invention, The top view is shown. Accordingly, the tibial component (20) a stem stabilization groove (21) on its surface to accommodate the tibial stem (10) and tibial fixation screw holes (22) providing tibial fixation of the prosthesis (1). takes. Side and anterior views of the tibial component (20) in Figures SB and 3C are given. Accordingly, a sphere (23) is located in the lower part of the tibial component (20). takes. In the figures, the spherical side surfaces 24 are shown. globe side Thanks to its flat surface (24) the talar component (40) is attached to the ball bearing (44) that the seated sphere (23) can perform anteroposterior linear movement has been provided. In Figure 3D, a ball stem (25) is attached to the lower part of the tibial component (20). The view of the sphere (23) attached with the can be seen more clearly.

Description of the Invention: In this detailed description, the subject of the invention is the ankle prosthesis (1) only for better understanding, it will not have any limiting effect explained with examples. In the description, those with ankle joint damage normal ankle range of motion of the ankle joint, which can be applied to patients An ankle prosthesis that can function close to its function (1) is explained.

Perspective view of the ankle prosthesis (1), which is the subject of the invention, in Figure 1 are given. Accordingly, ankle prosthesis (1), tibial stem (10), tibial Component (20), insert (30) and talar component (40) consists of parts.

In Figure 2, the tibial stem (10) element of the ankle prosthesis (1) is the subject of the invention. showing view. Accordingly, on the stem (10); a backend (12), an inclined anterior end (13), connecting the stem (10) with the tibial component (20) There is a component junction place (14) that provides it. Tibial stem (10) surface, It consists of a coated surface (11) to ensure biocompatibility. is coming.

In Figure 3A, the tibial component (20) of the ankle prosthesis (1) The top view is shown. Accordingly, the tibial component (20) a stem stabilization groove (21) on its surface to accommodate the tibial stem (10) and tibial fixation screw holes (22) providing tibial fixation of the prosthesis (1). takes. Fig. Side and anterior views of the tibial component (20) in SB and SC are given. Accordingly, a sphere (23) is located in the lower part of the tibial component (20). takes. In the figures, the spherical side surfaces 24 are shown. globe side Thanks to its flat surface (24) the talar component (40) is attached to the ball bearing (44) that the seated sphere (23) can perform anteroposterior linear movement has been provided. In Figure 3D, a ball stem (25) is attached to the lower part of the tibial component (20). The view of the sphere (23) attached with the can be seen more clearly.

In Figure 4A, the upper part of the insert (30) element of the ankle prosthesis (1) is the subject of the invention. view is given. Accordingly, the insert (30) contains the tibial component. anterior ball motion groove (33) and posterior sphere a sphere motion cavity (36) formed by the motion groove (33) contains. insert (30) body, insert wide anterior part (31), insert narrow the posterior part (32) consists of the lateral surfaces (37) of the insert.

In Figure 4B, the upper part of the insert (30) element of the ankle prosthesis (1) of the invention. view is given. Accordingly, the two side surfaces (37) of the insert (30) The talar component socket, which provides the connection with the talar component (40) on the channels (35).

In Figure 5A, the talar component (40) of the ankle prosthesis (1) is the subject of the invention. The top view showing the element is given. Accordingly, the talar component (40) body, talar component wide anterior part (41), talar component narrow It consists of the posterior part (42) and its lateral surfaces. Talar component (40); talar fixation screw holes that provide talar fixation (43) are available. In addition, in the middle part of the talar component (40), in the tibial component There is a ball bearing (44) in which the sphere (23) in (20) moves. Sphere (23) allows linear anteroposterior movement (natural wrist) in the ball bearing (44). movement) can be performed. The subject of the invention in Fig. SB is the ankle perspective view showing the talar component (40) of the prosthesis (1) are given. Accordingly, the talar component (40) is located on its two side sections, in the insert (30). The talar component fits into the slot channels (35) and the insert (30) and the talar component (40) insert talar component channels (45) that provide the connection between are available.

In the invention, first of all, the insert (30), the slot located on the lower part of the side surface (37) from their blood (35) insert talar component channels (45) associated with component (40). Subsequently, the tibial component (20) is placed on it. to the sphere bed (44) located in the talar component (40) through the field sphere (23) is seated. Finally, the tibial stem (10), the junction (14), the tibial component The assembly is completed by placing the stem on the stabilization groove (21) on the (20).

In Figure 4A, the upper part of the insert (30) element of the ankle prosthesis (1) is the subject of the invention. view is given. Accordingly, the insert (30) contains the tibial component. anterior ball motion groove (33) and posterior sphere a sphere motion cavity (36) formed by the motion groove (33) contains. insert (30) body, insert wide anterior part (31), insert narrow the posterior part (32) consists of the lateral surfaces (37) of the insert.

In Figure 4B, the upper part of the insert (30) element of the ankle prosthesis (1) of the invention. view is given. Accordingly, the two side surfaces (37) of the insert (30) The talar component socket, which provides the connection with the talar component (40) on the channels (35).

In Figure 5A, the talar component (40) of the ankle prosthesis (1) is the subject of the invention. The top view showing the element is given. Accordingly, the talar component (40) body, talar component wide anterior part (41), talar component narrow It consists of the posterior part (42) and its lateral surfaces. Talar component (40); talar fixation screw holes that provide talar fixation (43) are available. In addition, in the middle part of the talar component (40), in the tibial component There is a ball bearing (44) in which the sphere (23) in (20) moves. Sphere (23) allows linear anteroposterior movement (natural wrist) in the ball bearing (44). movement) can be performed. The subject of the invention in Figure SB is the ankle perspective view showing the talar component (40) of the prosthesis (1) are given. Accordingly, the talar component (40) is located on its two side sections, in the insert (30). The talar component fits into the slot channels (35) and the insert (30) and the talar component (40) insert talar component channels (45) that provide the connection between are available.

In the invention, first of all, the insert (30), the slot located on the lower part of the side surface (37) from their blood (35) insert talar component channels (45) associated with component (40). Subsequently, the tibial component (20) is placed on it. to the sphere bed (44) located in the talar component (40) through the field sphere (23) is seated. Finally, the tibial stem (10), the junction (14), the tibial component The assembly is completed by placing the stem on the stabilization groove (21) on the (20).

As it can be understood, the design and assembly of the parts that make up the foot prosthesis (1) it is not complicated.

As it can be understood, the design and assembly of the parts that make up the foot prosthesis (1) it is not complicated.

Claims (1)

REQUIREMENTS 1- Invention is an ankle prosthesis (1) that can be applied to patients with ankle joint damage, enabling the range of motion of the ankle joint to be close to normal ankle functions. It contains a tibial stem (10) on its lower surface, which has a component junction (14) that sits on the stem stabilization groove (21) and enables it to be associated with the tibial component (20). It contains a tibial component (20) with (21) and includes a sphere (23) on the lower surface of the said tibial component (20), which is placed on the ball bearing (44) in the talar component (40) and performs anterior-posterior linear movement within the ball bearing (44) includes an insert (30) with a sphere motion space (36) consisting of an anterior sphere motion groove (33) and a posterior sphere motion groove (34) within which the sphere (23) in the tibial component (20) can move, talar component groove that sits on the insert talar component channels (45) located on the talar component (40) in the lower part of the said insert (30) and provides the connection between the insert (30) and the talar component (40). It contains a channels (35), it contains a talar component (40) with a ball bearing (44) on its upper surface, where the ball (23) located in the lower part of the tibial component (20) can sit and perform anterior-posterior linear movement, said talar component (40) It is characterized by that it contains insert talar component channels (45) on its upper surface, which fit into the talar component slot channels (35) located on the lower part of the insert (30) side surface (37). 2- It is an ankle prosthesis (1) according to claim 1, its feature is; All surfaces of the tibial stem (10) are coated surfaces (11) made of bio materials to ensure biocompatibility. REQUIREMENTS 1- Invention is an ankle prosthesis (1) that can be applied to patients with ankle joint damage, enabling the range of motion of the ankle joint to be close to normal ankle functions. It contains a tibial stem (10) on its lower surface, which has a component junction (14) that sits on the stem stabilization groove (21) and enables it to be associated with the tibial component (20). It contains a tibial component (20) with (21) and includes a sphere (23) on the lower surface of the said tibial component (20), which is placed on the ball bearing (44) in the talar component (40) and performs anterior-posterior linear movement within the ball bearing (44) includes an insert (30) with a sphere motion space (36) consisting of an anterior sphere motion groove (33) and a posterior sphere motion groove (34) within which the sphere (23) in the tibial component (20) can move, talar component groove that sits on the insert talar component channels (45) located on the talar component (40) in the lower part of the said insert (30) and provides the connection between the insert (30) and the talar component (40). It contains a channels (35), it contains a talar component (40) with a ball bearing (44) on its upper surface, where the ball (23) located in the lower part of the tibial component (20) can sit and perform anterior-posterior linear movement, said talar component (40) It is characterized by that it contains insert talar component channels (45) on its upper surface, which fit into the talar component slot channels (35) located on the lower part of the insert (30) side surface (37). 2- It is an ankle prosthesis (1) according to claim 1, its feature is; All surfaces of the tibial stem (10) are coated surfaces (11) made of bio materials to ensure biocompatibility. 3- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains a posterior end (12) and an inclined anterior end (13) to provide anatomical compatibility on the tibial stem (10). 4- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains tibial fixation screw holes (22) on the tibial component (20) that provides fixation with the tibial part of the foot. 5- It is an ankle prosthesis (1) according to claim 1, its feature is; the sphere (23) includes sphere lateral surfaces (24) that enable it to perform linear front-to-back movement by limiting its lateral movements within the ball bearing (44). 6- It is an ankle prosthesis (1) according to claim 1, its feature is; the ball (23) includes a ball handle (25) that connects it with the lower part of the tibial component (20). it includes an insert wide anterior section (31) and an insert narrow anterior section (32) configured to fit the structure. 8- It is an ankle prosthesis (1) according to claim 1, and its feature is; The talar component (40) consists of a talar component, a wide anterior section (41) and a talar component, a narrow anterior section (42), structured in accordance with the anatomical structure. 9- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains talar fixation screw holes (43) on the talar component (40), which provides fixation with the foot talar part. 3- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains a posterior end (12) and an inclined anterior end (13) to provide anatomical compatibility on the tibial stem (10). 4- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains tibial fixation screw holes (22) on the tibial component (20) that provides fixation with the tibial part of the foot. 5- It is an ankle prosthesis (1) according to claim 1, its feature is; the sphere (23) includes sphere lateral surfaces (24) that enable it to perform linear front-to-back movement by limiting its lateral movements within the ball bearing (44). 6- It is an ankle prosthesis (1) according to claim 1, and its feature is; the ball (23) includes a ball handle (25) that connects it with the lower part of the tibial component (20). it includes an insert wide anterior section (31) and an insert narrow anterior section (32) configured to fit the structure. 8- It is an ankle prosthesis (1) according to claim 1, and its feature is; The talar component (40) consists of a talar component, a wide anterior section (41) and a talar component, a narrow anterior section (42), structured in accordance with the anatomical structure. 9- It is an ankle prosthesis (1) according to claim 1, and its feature is; It contains talar fixation screw holes (43) on the talar component (40) that provide fixation with the foot talar part.