RU2766553C1 - Hip joint endoprosthesis and method of producing modified polytetrafluoroethylene for hip joint endoprosthesis - Google Patents

Abstract

FIELD: medicine; orthopedic equipment.

SUBSTANCE: first invention of the group relates to a method of producing a modified polytetrafluoroethylene for a hip joint endoprosthesis, according to which the workpiece from the polymer material is placed in a thermoradiation chamber with an inert gas, heated to a temperature higher than the melting point of the crystalline phase at a rate of not more than 60 °C/hour and thermostating is carried out at temperature higher than crystalline phase melting point, then the workpiece from the polymer material is treated with high-energy ionizing radiation to an absorbed dose of 0.5–500 kGy, wherein during the irradiation the temperature is lowered to no more than 0.5 °C/10 kGy and the workpiece is cooled to room temperature at a rate of not more than 60 °C/hour, and then subjected to heat treatment, wherein in the thermo-radiation chamber the workpieces from the polymer material are heated to a temperature higher than the melting point of the crystalline phase from 327 °C and not more than 380 °C. Also, the group of inventions relates to a head, an insert-head friction pair and an acetabular component of the hip joint endoprosthesis, made of said modified polytetrafluoroethylene.

EFFECT: group of inventions provides a reduction in the friction coefficient during sliding friction of elements, stabilization of the structure of the surface layer of parts, reduced wear and increased service life of the hip joint endoprosthesis.

11 cl, 1 dwg

Description

The field of technology.

The invention relates to the field of medicine, in particular to orthopedic technology, namely to anti-friction inserts of modified polytetrafluoroethylene for artificial joint endoprostheses in hip joint arthroplasty after injuries or diseases.

The level of technology.

Analysis of the prior art in this area showed the following.

From the prior art (RU 2138227 C1, A61F 2/36, publ. 27.09.1999) is known endoprosthesis of the head of the hip joint, containing an artificial acetabulum, a ball with a skirt and a socket under the leg of the endoprosthesis of the hip joint, a reservoir of lubricating fluid and channels for its transportation. In the lower part of the ball, on the side of the skirt, there is a collector for collecting lubricating fluid, from which supply channels with extended inlets at the collector are led into the cavity of the lubricating fluid accumulator through the ball body. From the lubricating fluid reservoir, discharge channels are also brought out to its spherical surface through the ball body, also equipped with lead-in sockets from the side of the lubricating fluid reservoir. The inner spherical surface of the artificial acetabulum is equipped with a cylindrical belt. When this ball is made of elastic material, such as fluorine-containing plastics, in particular PTFE.

However, the endoprosthesis of the head of the hip joint described in this patent has a number of disadvantages, since polymer sliding friction parts made of polytetrafluoroethylene made in a known way have a low wear resistance index (3500-5000 microns/km, at 2.5 MPa. 1 m/s).

The closest to the claimed invention, in terms of the technical result and the problem to be solved, is the technical solution disclosed in the patent - an insert for an endoprosthesis (RU 169887 U1, A61F 2/30, publ. 04/05/2017) made in the form of a part with a curved surface of radiation- modified polytetrafluoroethylene with a spherulite structure obtained by irradiating a workpiece made of polytetrafluoroethylene with ionizing radiation to an absorbed dose of 60-800 kGy at an irradiation rate of more than 1 Gy/sec while lowering the temperature of the workpiece during irradiation by 0.9-2 deg/10 kGy while maintaining the temperature below the melting temperature of polytetrafluoroethylene and above its crystallization temperature.

The disadvantages of this technical solution include the variability of the physicomechanical characteristics of the polymer during irradiation, in particular, under the specified mode of thermoradiation irradiation (“.... at the same time, the temperature of the workpieces is maintained below the melting temperature of polytetrafluoroethylene, but above the temperature of its crystallization.”, which corresponds to temperatures =< 327°C) the development of degradation of polymer sites is possible due to the presence of solid crystalline areas subject to strong degradation during irradiation. In addition, the variability of properties, in addition to thermoradiation destruction, can be explained by an incorrect cooling regime (speed and time). This technical solution was chosen as a prototype.

Disclosure of the essence of the invention.

The technical result to be solved by the present invention is to reduce the coefficient of friction during sliding friction of the elements of the hip joint endoprosthesis, stabilize the structure of the surface layer of the parts, reduce wear as a material of the endoprosthesis part and, as a result, increase the service life of the hip joint endoprosthesis,

The specified technical result is achieved due to the fact that the method of obtaining a modified polytetrafluoroethylene for a hip joint endoprosthesis consists in placing a workpiece made of polymeric material into a thermoradiation chamber, from which oxygen is pumped out to a residual pressure, followed by filling the thermoradiation chamber with an inert gas to an excess pressure. Then the workpiece made of polymeric material is heated to a temperature above the melting point of the crystalline phase, while heating is carried out at a rate of not more than 60°C/h and temperature control is carried out at a temperature significantly higher than the melting point of the crystalline phase. After that, the workpiece made of polymeric material is treated with high-energy ionizing radiation at a temperature strictly above the melting point of the crystalline phase of the polymeric material in an oxygen-free - inert environment. Processing of the polymeric material is carried out with a pulsed linear electron accelerator generating bremsstrahlung gamma radiation, irradiating the workpiece made of polymeric material with ionizing radiation up to an absorbed dose of 0.5-500 kGy or an energy-equivalent high-energy coherent radiation. During irradiation, the temperature of the polymer material is lowered by no more than 0.5°C/10 kGy and the workpieces are cooled to room temperature at a rate of no more than 60°C/hour, and to adjust the ratio of hardness/elasticity of the polymer material, after treatment with ionizing radiation, the polymer material subjected to heat treatment to normalize the properties and achieve maximum homogeneity of the material and programmability of physical and mechanical characteristics. To do this, in a thermoradiation chamber, workpieces made of polymeric material are heated to a temperature above the melting point of the crystalline phase from 327°C and not more than 380°C. As high-energy ionizing radiation, alpha radiation or gamma radiation, or electron radiation, or irradiation with high-energy protons and neutrons, or radiation from natural sources can be used.

The endoprosthesis of the hip joint contains the head of the endoprosthesis and the acetabular component of the endoprosthesis, made of modified polytetrafluoroethylene. The endoprosthesis head contains a metal insert under the endoprosthesis leg. The endoprosthesis of the hip joint may contain an insert made of modified polytetrafluoroethylene. The insert is made in the form of a semi-ellipsoid, or a hemisphere, or a lodgment with a groove for inserting the counterpart.

Description of drawings.

In FIG. 1 shows the general scheme of the proposed hip joint endoprosthesis.

1 - acetabular component (cup) of the endoprosthesis;

2 – endoprosthesis insert;

3 - head (ball) of the endoprosthesis;

4 - leg of the endoprosthesis.

Implementation of the invention.

The endoprosthesis of the hip joint contains the head (ball) 3 of the endoprosthesis and the acetabular component (cup) 1 of the endoprosthesis, made of modified polytetrafluoroethylene. The head 3 of the endoprosthesis contains a metal insert under the leg 4 of the endoprosthesis. The endoprosthesis of the hip joint may contain an insert 2, also made of modified polytetrafluoroethylene. The insert 2 can be made in the form of a semi-ellipsoid, or a hemisphere, or a lodgment with a groove for inserting the counterpart.

The method for producing a modified polytetrafluoroethylene for a hip joint endoprosthesis includes the following steps.

The polymer material is prepared according to standard specifications for the processing of fluoropolymer materials (extrusion, casting, powder pressing).

Then, the resulting polymer material blanks are sent to the preparation zone and placed in a thermoradiation chamber. In the thermoradiation chamber, oxygen is pumped out to a residual pressure, then it is filled with an inert gas (argon, nitrogen) to an overpressure.

In the thermoradiation chamber, workpieces made of polymeric material are heated to a temperature above the melting point of the crystalline phase from 327°C and not more than 380°C at a rate of not more than 60°C/hour, and thermostating is carried out at a temperature significantly higher than the melting point of the crystalline phase (not more than 380°C), which makes it possible to carry out the process of complete melting of the crystalline phase of the polymer and, at the same time, to exclude the possible development of the destruction of polymer regions due to the presence of solid crystalline regions that are subject to strong destruction during irradiation.

After that, the workpiece made of polymeric material is treated with high-energy ionizing radiation at a temperature strictly above the melting point of the crystalline phase of the polymeric material in an oxygen-free - inert environment.

In the irradiation zone, processing of workpieces made of polymeric material is carried out, in particular, by ionizing bremsstrahlung radiation from a pulsed linear accelerator, or energy-equivalent high-energy coherent radiation, with an irradiation rate of 0-1000 Gy/sec. Irradiation takes place up to an absorbed dose of 0.5-500 kGy with a decrease in the temperature of the product during processing by no more than 0.5 deg/10 kGy. After the cessation of irradiation, due to the possible rapid increase in the required dose of irradiation and the peculiarities of the mechanism for changing the structure and, as a result, the physical and mechanical characteristics of the polymer material blanks, it is necessary to carry out additional heat treatment in the heating/cooling mode in the temperature range from the beginning of crystallization of the treated polymer to 380 °C to normalize and stabilize properties. To adjust the ratio of hardness/elasticity of the polymer material, after treatment with ionizing radiation, the polymer material is subjected to heat treatment to normalize properties and achieve maximum material uniformity and programmability of physical and mechanical characteristics.

The next stage of the processing process is that the processed blanks made of polymeric material are cooled to room temperature at a rate of not more than 60°C/hour.

The processing of material blanks for the friction pair of the liner and the head (ball), in addition to the above-mentioned bremsstrahlung radiation, can be performed by alpha radiation, gamma radiation, electron radiation, high-energy protons and neutrons, radiation from natural sources.

The final stage of the process - the head (ball) or the liner and the head (ball) or the acetabulum of endoprostheses is made from blanks of modified polytetrafluoroethylene, obtained by the method described above, by turning with the sequential use of turning and milling machines with numerical control. Preforms from modified polytetrafluoroethylene are processed by mechanical processing of polytetrafluoroethylene.

The claimed invention provides a significant reduction in the amount of wear products and an increase in the service life of the elements of the endoprosthesis and, as a result, the entire endoprosthesis of the hip joint.

Claims (11)

1. A method for producing a modified polytetrafluoroethylene for a hip joint endoprosthesis, which consists in placing a polymer material blank into a thermoradiation chamber, from which oxygen is evacuated to a residual pressure, followed by filling the thermoradiation chamber with an inert gas to an excess pressure, after which the polymeric material blank is heated to temperatures above the melting temperature of the crystalline phase, while heating is carried out at a rate of not more than 60 ° C / h and thermostating is carried out at a temperature significantly higher than the melting point of the crystalline phase, then the workpiece from the polymer material is treated with high-energy ionizing radiation at a temperature strictly above the melting temperature of the crystalline phase of the polymer material in an oxygen-free - inert environment, while the processing of the polymer material is carried out by a pulsed linear electron accelerator that generates bremsstrahlung gamma radiation, about irradiating a workpiece made of polymer material with ionizing radiation up to an absorbed dose of 0.5-500 kGy or an energy-equivalent high-energy coherent radiation, while during irradiation the temperature of the polymer material is reduced by no more than 0.5 °C/10 kGy and the workpiece is cooled to room temperature temperature at a rate of not more than 60 °C/hour, and to adjust the ratio of hardness/elasticity of the polymer material, after treatment with ionizing radiation, workpieces made of polymer material are subjected to heat treatment to normalize properties and achieve maximum uniformity of the material and programmability of physical and mechanical characteristics, while in a thermoradiation chamber workpieces made of polymeric material are heated to a temperature above the melting point of the crystalline phase from 327 °C and not more than 380 °C. 2. The method according to claim 1, characterized in that alpha radiation is used as high-energy ionizing radiation. 3. The method according to claim 1, characterized in that gamma radiation is used as high-energy ionizing radiation. 4. The method according to claim 1, characterized in that electron radiation is used as high-energy ionizing radiation. 5. The method according to claim 1, characterized in that irradiation with high-energy protons and neutrons is used as high-energy ionizing radiation. 6. The method according to claim 1, characterized in that radiation from natural sources is used as high-energy ionizing radiation. 7. The head of the hip endoprosthesis, characterized in that it is made of modified polytetrafluoroethylene according to claim 1. 8. The head according to claim 7, characterized in that it contains a metal insert under the leg of the endoprosthesis. 9. Friction pair liner - head of the hip endoprosthesis, characterized in that it is made of modified polytetrafluoroethylene according to claim 1. 10. Friction pair according to claim 9, characterized in that the insert is made in the form of a semi-ellipsoid, or a hemisphere, or a lodgment with a groove for inserting the counterpart. 11. The acetabular component of the endoprosthesis, the hip joint, characterized in that it is made of modified polytetrafluoroethylene according to claim 1.

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