RU2632761C1 - Orthopedic implant from titanium and stainless steel with antiadhesive antibacterial coating - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: orthopedic implant made of titanium and stainless steel with antiadhesive antimicrobial coating, made of titanium and stainless steel in the form of an intraosseous implant for large and small joints, as well as elements of fastening for the spine and long bones of patient's skeleton. The surface of an orthopedic implant of titanium and stainless steel, preliminarily ion-etched by argon ions is coated (by plasma spraying) by a two-component antiadhesive antibacterial biocompatible nanocoating with a thickness of 9 to 1180 nm containing spherical nanoparticles made of high-purity silver with a size of 4.5-9.5 nm with continuous protective carbon nanocoating from tetrahedral ta-C type diamond with a thickness of 0.4-1.2 nm deposited on their surface.

EFFECT: reliable high antiadhesive antibacterial properties, reliable barrier for bacterial biofilm formation on the surface of the metal orthopedic implant during its operation, high biological compatibility in various physiological environments of the patient's body, reliable protection of the implanted metal orthopedic implant surface against periprosthetic infection.

2 cl, 5 ex

Description

The invention relates to medicine, namely to traumatology, orthopedics and general surgery, namely to orthopedic implants made of titanium and stainless steel with anti-adhesive antibacterial coating, including intraosseous implants for large and small joints, as well as fastening elements of the spine and long bones the patient’s skeleton, and can be used in the surgical treatment of patients in traumatological and orthopedic, surgical and other hospitals.

There are various designs of orthopedic implants made of titanium and stainless steel, including those with coatings with an antibacterial effect (see RF patent No. 2582980, IPC A61B 17/74, 04/27/2016, RF patent No. 2580978, IPC A61B 17/76, 04/10/2016, RF patent No. 2361623, IPC A61L 27/06, 07/20/2009, RF patent No. 2472532, IPC A61L 27/30, 01/20/2013).

However, well-known orthopedic implants in their use have the following disadvantages:

- do not provide high anti-adhesive properties prepared for use with a metal orthopedic implant,

- do not interfere with the formation of a bacterial biofilm on the surface of a metal orthopedic implant,

- do not provide high antibacterial properties of a metal orthopedic implant prepared for use,

- do not provide high biological compatibility in various physiological environments of the patient’s body,

- do not provide reliable protection of the surface of the implanted metal orthopedic implant from the occurrence of periprosthetic infection processes.

The objective of the invention is the creation of an orthopedic implant made of titanium and stainless steel with anti-adhesive antibacterial coating.

The technical result is a reliable provision of high anti-adhesive properties of a metal orthopedic implant prepared for use, a reliable obstacle to the formation of a bacterial biofilm on the surface of a metal orthopedic implant during its operation, high antibacterial properties of a metal orthopedic implant prepared for use, reliable ensuring high biological compatibility in various physiological environments the body of the patient that, as well as providing reliable protection of the surface of the implanted metallic orthopedic implant from the processes of emergence of periprosthetic infection.

The technical result is achieved by the fact that an orthopedic implant of titanium and stainless steel with anti-adhesive antimicrobial coating is proposed, made of titanium and stainless steel in the form of an intraosseous implant for large and small joints, as well as in the form of fastening elements of the spine and long bones of the patient’s skeleton, while on the surface of an orthopedic implant made of titanium and stainless steel that has been previously purified by ion etching by argon ions, a two-component an tiadhesive antibacterial biocompatible nanocoating from 9 to 1180 nm thick, containing spherical nanogranules of high-purity silver with a size of 4.5-9.5 nm with a continuous protective carbon nanocoating made of ta-C type 0.4-1 thickness tetrahedral diamond deposited on their surface, 2 nm. At the same time, silver of at least 99.9% purity is used as high-purity silver nano-granules of the coating.

Among the essential features characterizing the proposed orthopedic implant made of titanium and stainless steel with anti-adhesive antimicrobial coating, the following are distinguishing:

- applying to the surface previously purified by ion etching by argon ions used for implantation of an orthopedic implant made of titanium and stainless steel by plasma spraying a two-component anti-adhesive antibacterial biocompatible nanocoating with a thickness of 9 to 1180 nm, containing spherical nanogranules made of high-purity silver with a size of 4.5–9.5 nm with a continuous protective carbon nanocoating made of ta-C type tetrahedral diamond 0.4-1.2 nm thick deposited on their surface,

- use as a high-purity silver nanogranules silver coatings of not less than 99.9% purity.

Experimental studies of the proposed orthopedic implant made of titanium and stainless steel with anti-adhesive antimicrobial coating showed its high efficiency. The experimental anti-microbial anti-microbial coating of an orthopedic implant made of titanium and stainless steel reliably provided high anti-adhesive properties of the surface of a metal orthopedic implant prepared for use, provided a reliable barrier to the formation of a bacterial biofilm on the surface of a metal orthopedic implant during its operation, and ensured high antibacterial properties of the prepared for use metal orthopedic Skogen implant reliably provide high biocompatibility in various physiological environments of the patient, as well as possible to achieve reliable protection of surface prepared for use for implantation of metallic orthopedic implant from the processes of emergence of periprosthetic infection.

The implementation of the proposed orthopedic implant of titanium and stainless steel with anti-adhesive antimicrobial coating is illustrated by the following practical examples.

Example 1. On the surface of three flat samples of titanium VT-6 grade used for the manufacture of orthopedic implants, the proposed anti-adhesive antibacterial coating was applied.

In this case, samples preliminarily purified by ion etching by argon ions were used, on the surface of which a two-component anti-adhesive antibacterial biocompatible nanocoating with a thickness of 9 nm was deposited by plasma spraying, containing spherical nanogranules of high-purity silver with a size of 4.5 nm with a continuous protective carbon nanocoating on their surface ta-C type diamond 0.4 nm thick. At the same time, silver of not less than 99.9% purity was used as high-purity silver nano-granules of the coating.

Then, on the surface of the anti-adhesive antibacterial coating of each flat sample of titanium grade VT-6 in the laboratory of FSBI “CITO them. N.N. Priorov was applied 1 ml of physiological saline with test cultures of microorganisms isolated from patients with infectious complications after arthroplasty of large joints and belonging to the species Staphylococcus aureus MRS A, E. Coli and Pseudomonas aeruginosa, in concentrations containing 10 ⁷ cells of each test culture complying with a turbidity standard of 0.5 Mack Farland. The applied solutions of each test culture were uniformly distributed on the surface of one sample, the surface was dried identically to the method for determining the antibiotic resistance of microorganisms by the disk diffusion method. Samples were incubated in an incubator at 36 ° C for 24 hours.

As a result of electron microscopic examination of the coating surface of each sample after incubation, the high anti-adhesive properties of the proposed anti-adhesive antibacterial coating for orthopedic implants were established. In this case, the absence of the formation of a bacterial biofilm of the strains of Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa in the absence of growth of their colonies with their simultaneous suppression to single colonies or to their complete absence was found to be absent on the surface of each of three flat VT-6 titanium samples testifies to the high efficiency of the proposed anti-adhesive antibacterial coating for orthopedic implants made of titanium and stainless steel.

Example 2. On the surface of three flat samples of stainless steel for medical purposes used for the manufacture of orthopedic implants, the proposed anti-adhesive antibacterial coating was applied.

In this case, samples preliminarily purified by ion etching by argon ions were used, on the surface of which a two-component anti-adhesive antibacterial biocompatible nanocoating with a thickness of 480 nm was deposited by plasma spraying, containing spherical nanogranules of high-purity silver with a size of 9.5 nm with a continuous protective carbon nanocoat coated on their surface ta-C type diamond with a thickness of 0.9 nm. At the same time, silver of not less than 99.9% purity was used as high-purity silver nano-granules of the coating.

Then on the surface of the anti-adhesive antibacterial coating of each flat sample of stainless steel for medical purposes in the laboratory of FSBI “CITO named after N.N. Priorov was applied with 1 ml of physiological saline with test cultures of microorganisms isolated from patients with infectious complications after arthroplasty of large joints and belonging to the species Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa, in concentrations containing 10 ⁷ cells of each test culture, turbidity standard 0.5 Mack Farland. The applied solutions of each test culture were uniformly distributed on the surface of one sample, the surface was dried identically to the method for determining the antibiotic resistance of microorganisms by the disk diffusion method. Samples were incubated in an incubator at 36 ° C for 24 hours.

As a result of electron microscopic examination of the coating surface of each sample after incubation, the high anti-adhesive properties of the proposed anti-adhesive antibacterial coating for orthopedic implants were established. At the same time, the absence of the formation of a bacterial biofilm of the strains of Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa in the absence of growth of their colonies with their simultaneous suppression to single colonies or to their complete absence was found to be absent on the surface of each of three flat samples of titanium of grade VT 1-0 which indicates the high efficiency of the proposed anti-adhesive antibacterial coating for orthopedic implants made of titanium and stainless steel.

Example 3. On the surface of three flat samples of titanium grade VT1-0 used for the manufacture of orthopedic implants, the proposed anti-adhesive antibacterial coating was applied.

In this case, samples preliminarily purified by ion etching by argon ions were used, on the surface of which a two-component biocompatible biocompatible biocompatible nanocoating 720 nm thick was deposited by plasma spraying, which contained spherical nanogranules made of high-purity silver 6.0 nm in size with a continuous protective carbon nanocoat coated on their surface ta-C type diamond 1.2 nm thick. At the same time, silver of not less than 99.9% purity was used as high-purity silver nano-granules of the coating.

Then, on the surface of the anti-adhesive antibacterial coating of each flat sample of titanium VT1-0 grade in the laboratory of FSBI “CITO named after N.N. Priorov was applied with 1 ml of physiological saline with test cultures of microorganisms isolated from patients with infectious complications after arthroplasty of large joints and belonging to the species Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa, in concentrations containing 10 ⁷ cells of each test culture, turbidity standard 0.5 Mack Farland. The applied solutions of each test culture were uniformly distributed on the surface of one sample, the surface was dried identically to the method for determining the antibiotic resistance of microorganisms by the disk diffusion method. Samples were incubated in an incubator at 36 ° C for 24 hours.

As a result of electron microscopic examination of the coating surface of each sample after incubation, the high anti-adhesive properties of the proposed anti-adhesive antibacterial coating for orthopedic implants were established. In this case, the absence of the formation of a bacterial biofilm of the strains of Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa on the surface of each of three flat samples of VT1-0 grade titanium in the absence of growth of their colonies with their simultaneous suppression to single colonies or to their complete absence, which testifies to the high efficiency of the proposed anti-adhesive antibacterial coating for orthopedic implants made of titanium and stainless steel.

Example 4. On the surface of three flat samples of titanium grade VT1-00 used for the manufacture of orthopedic implants, the proposed anti-adhesive antibacterial coating was applied.

In this case, samples preliminarily purified by ion etching by argon ions were used, on the surface of which a two-component anti-adhesive antibacterial biocompatible nanocoating with a thickness of 1180 nm was applied by plasma spraying, containing spherical nanogranules made of high-purity silver with a size of 9.5 nm with a continuous protective carbon nanocoop coating on their surface -a ta-C type diamond with a thickness of 0.6 nm. At the same time, silver of not less than 99.9% purity was used as high-purity silver nano-granules of the coating.

Then, on the surface of the anti-adhesive antibacterial coating of each flat sample of titanium VT1-00 grade in the laboratory of FSBI “CITO named after N.N. Priorov was applied with 1 ml of physiological saline with test cultures of microorganisms isolated from patients with infectious complications after arthroplasty of large joints and belonging to the species Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa, in concentrations containing 10 ⁷ cells of each test culture, turbidity standard 0.5 Mack Farland. The applied solutions of each test culture were uniformly distributed on the surface of one sample, the surface was dried identically to the method for determining the antibiotic resistance of microorganisms by the disk diffusion method. Samples were incubated in an incubator at 36 ° C for 24 hours.

As a result of electron microscopic examination of the coating surface of each sample after incubation, the high anti-adhesive properties of the proposed anti-adhesive antibacterial coating for orthopedic implants were established. At the same time, the absence of the formation of a bacterial biofilm of the strains of Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa in the absence of growth of their colonies with their simultaneous suppression to single colonies or to their complete absence was found to be absent on the surface of each of three flat VT1-00 titanium samples testifies to the high efficiency of the proposed anti-adhesive antibacterial coating for orthopedic implants made of titanium and stainless steel.

Example 5. On the surface of three flat samples of titanium grade VT-16, used for the manufacture of orthopedic implants, the proposed anti-adhesive antibacterial coating was applied.

In this case, samples preliminarily purified by ion etching by argon ions were used, on the surface of which plasma spraying was applied to a two-component anti-adhesive antibacterial biocompatible nanocoating 980 nm thick containing spherical nanogranules made of high-purity silver with a size of 8.4 nm with a continuous protective carbon nanocoop coating on their surface ta-C type hedron diamond 1.2 nm thick. At the same time, silver of not less than 99.9% purity was used as high-purity silver nano-granules of the coating.

Then, on the surface of the anti-adhesive antibacterial coating of each flat sample of titanium VT-16 brand in the laboratory of FSBI “CITO named after N.N. Priorov was applied with 1 ml of physiological saline with test cultures of microorganisms isolated from patients with infectious complications after arthroplasty of large joints and belonging to the species Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa, in concentrations containing 10 ⁷ cells of each test culture, turbidity standard 0.5 Mack Farland. The applied solutions of each test culture were uniformly distributed on the surface of one sample, the surface was dried identically to the method for determining the antibiotic resistance of microorganisms by the disk diffusion method. Samples were incubated in an incubator at 36 ° C for 24 hours.

As a result of electron microscopic examination of the coating surface of each sample after incubation, the high anti-adhesive properties of the proposed anti-adhesive antibacterial coating for orthopedic implants were established. At the same time, the absence of the formation of a bacterial biofilm of the strains of Staphylococcus aureus MRSA, E. Coli and Pseudomonas aeruginosa in the absence of growth of their colonies with their inhibition to single colonies or to their complete absence was found on the surface of each of three flat VT-16 titanium samples testifies to the high efficiency of the proposed anti-adhesive antibacterial coating for orthopedic implants made of titanium and stainless steel.

Claims (2)

1. Orthopedic implant made of titanium and stainless steel with anti-adhesive antimicrobial coating, made of titanium and stainless steel in the form of an intraosseous implant for large and small joints, as well as in the form of fastening elements of the spine and long bones of the patient’s skeleton, characterized in that the surface is previously of an orthopedic implant made of titanium and stainless steel purified by ion etching by argon ions is applied by plasma spraying a two-component anti-adhesive antibacterial bios a local nanocoating with a thickness of 9 to 1180 nm, containing spherical nanogranules of high-purity silver with a size of 4.5–9.5 nm with a continuous protective carbon nanocoating made of a ta-C tetrahedral diamond of 0.4–1.2 nm thickness deposited on their surface . 2. The implant according to claim 1, characterized in that silver of at least 99.9% purity is used as high-purity silver nano-granules of the coating.