RU2754428C2 - Bone implant - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: bone implant, at least in part, consists of pectolite jelly.

EFFECT: invention provides an expansion of the arsenal of bone tissue implants with high mechanical characteristics, high hydrophilicity and biological compatibility, osseointegration ability and dielectric properties.

4 cl, 2 tbl, 10 ex

Description

The invention relates to the field of medicine and medical technology, namely to bone implants. These are implants that replace or supplement bone tissue, are fully or partially anchored in bone tissue, or connect parts of bones. The most important properties of bone implants taken into account in their application are mechanical strength, chemical resistance, biological compatibility, and the ability to integrate into bone tissue (osseointegration). Optimization of the use of bone tissue implants, taking into account their properties, is an important task of modern medicine in surgery, orthopedics, traumatology, and dentistry.

Implants made from inorganic materials, which are most often used as bone tissue implants, can be divided into two large groups - metal implants and implants made from oxide-based materials, in particular, aluminum oxide, zirconium oxide, silicon oxide.

Metal implants became widespread after the discovery of the phenomenon of osseointegration of titanium [Branemark, 1969, Scand. J. Plast. Reconstr. Surg., 3, 81-100]. Pure titanium and its alloys (Ti with additions of V, Al, Nb, Zr) are still used most often as a basis for implants. The advantages of titanium implants are strength, osseointegration ability, proven medical protocols, long-term experience of use. The disadvantage of titanium implants is the electrochemical activity of metals, which can cause various complications when using implants made of titanium and its alloys [Pozhitkov, 2015, Plos One, 10 (10): e0140393].

To improve biocompatibility, the surface of titanium implants is often modified. Sandblasting, etching and oxidation increase the microroughness and hydrophilicity of the titanium implant surface and lead to an increase in the rate of integration of the implant with the bone tissue. Other options for surface modification include applying to the surface of titanium implants compositions with hydroxyapatite or bioglass, which improve the osteoplastic properties of the implant, but this effect is short-lived due to resorption of the applied surface layer.

Implants made from oxide-based materials have the advantage of being resistant to chemical attack. In the manufacture of implants, polycrystalline, in particular ceramic, as well as monocrystalline and glassy oxide materials are used. Known is a ceramic implant containing polycrystalline alumina [Heimke, 1975, US Patent 3919723]. Also known is an implant made of monocrystalline aluminum oxide [Hirabayashi, 1978, US Patent 4122605], which is the prototype of this invention. The compressive and tensile strength and chemical resistance of monocrystalline alumina are very high. However, alumina is biologically inert, has a high Young's modulus and a positive zeta potential at physiological pH. This can lead to difficulties in osseointegration and to bone resorption over time with prolonged use of the implant.

Implants made of oxide ceramics based on ZrO ₂ have high aesthetic qualities; they are the second most frequently used after titanium implants. Materials based on yttrium-stabilized zirconium dioxide have high chemical and biological stability, high strength, relatively low Young's modulus [Yilmaz, 2007, J. Prosth. Dent., 98, 120-12]. However, the possible aging of zirconium ceramics in an aqueous environment makes it unreliable to predict the stability of zirconium implants with long-term use.

Bone tissue implants based on silicon oxide have been known since the use of bioglass 45S5 with the composition SiO ₂ -P ₂ O ₅ -CaO-Na ₂ O [Hench, 1971, J. Biomed. Mater. Res. Symposium No. 2 (Part 1), 117-141]. Bioglass can be used in powder form as a filler for bone grafting when filling bone defects. In the future, the osseointegrated bioglass is replaced by living bone tissue. Initially, it was assumed that osseointegration is induced by the presence of P ₂ O ₅ and CaO in the composition of bioglass, which brings the composition of bioglass closer to the composition of bone hydroxyapatite, but later it was found that both phosphorus-free and calcium-free silicate glasses also have high osteoinductive properties [Hench, 1979, US Patent 4171544].

Biocompatibility and the possibility of osseointegration in silicate-containing implants, as in titanium implants, depend on the surface structure. Experiments were carried out [Li, 1992, J. Am. Ceram. Soc., 75 (S) 2094-2097] to determine the formation of crystals of hydroxyapatite on various surfaces of silicon oxide when samples are placed in an SBF solution (SBF - simulated body fluid, imitation of extracellular fluid). This SBF test is often used to assess the possibility of osseointegration and as an indicator of the biocompatibility of materials. It was found that a layer of hydroxyapatite is formed on the surface of silicon oxide in the case of soaking in an SBF solution of silica gel with a developed rough surface, but this does not happen in the case of silicate glass with a smooth surface.

Silicate bioglass possesses high osteoinduction and osteoconductivity, however, they have low strength, fragility and are susceptible to resorption during prolonged exposure to bone tissue. These properties make them difficult to use as a base for non-resorbable bone implants. Increasing the strength and reducing the resorption of silicate materials is known for artificial teeth made of lithium disilicate glass ceramics [Barrett, 1980, US Patent 4189325] and apatite-wollastonite glass ceramics [Yoshida, 1985, US Patent 4560666]. Silicate bioceramics of such compositions have excellent compatibility with surrounding tissues and higher strength than bioglass, but at the same time have a reduced ability to osseointegration.

The data presented show the promise of using bone implants made of silicate materials in medicine; however, the properties of implants made from many of these materials limit their field of application.

In the present invention, in order to expand the range of medical devices for implantation into bone tissue and obtain high-strength implants capable of osseointegration, bone implants are made from silicate mineral aggregates and rocks with a dense entangled fibrous or fine-crystalline structure, known collectively as "jade" ( jade). Among many, the following aggregates and rocks are called jades: jadeite jade and jade jade related to true jades, as well as other jades - xonotlite jade, vesuvianite jade, bovenite jade, pectolite jade, hydrogrossular jade.

Many jads have names and synonyms based on the properties of the breed or the name of the area. For example, jadeite jades are known in different places depending on the places of extraction, some changes in color, properties and composition under the following names: albite jade, white jade, Burmese jade, pink jade, kingfisher jade, emerald jade, Inca jade, imperial jade, Itoigawa jade, Chinese jade, royal jade, omphacite jade, purple jade, Taumav jade, jad feits-yu, chiung-yu jade, mau-sit-sit jade, Yunnan jade, Japanese jade. Numerous names are also known for jade jades, including the following: American, Wyoming, Oriental, Volcanic, Cluster, Camphor, Canadian, Kan, Cantonese, Kanchin, Kan Yuan, Kashgar, Korean, Bone, Lao Kanqing, Lao Kanyuan, leopard, Liu, Maori, Monterey, New Guinean, New Zealand, New Caledonian, Peking, Sevan, rice, Russian, fishing, Siberian, Xinjiang, snowy, Turkestan, Hortun, Khotan, Chungcheong, Shanghai, Yarqiang. Bovenite jades are known, inter alia, under the following names: new, Afghan, Kunlun, Suzhou. Hydrogrossular jades are also known under the following names: African, Transvaal, South African. Vesuvianite jades are known, inter alia, under the following names: American, Californian, Pakistani. Pectolite jades are also known as larimar and Alaskan jade.

Like many minerals, and especially mineral aggregates and rocks, jades have a slightly different composition depending on the deposit or the conditions of formation, due to the phenomenon of isomorphism - the variability of composition while maintaining the crystal structure and essential properties. These are massive and durable silicate mineral aggregates and rocks naturally occurring in nature, or synthetic materials of similar structure and composition. Surprisingly, it turned out that implants made from these materials have optimal characteristics for integration into bone tissue.

These mineral aggregates and rocks are resistant to cracking and have a dense viscous structure that provides high strength in combination with a relatively low modulus of elasticity. With the exception of jade jade, jades are hydrosilicates. They are translucent, translucent in a thin layer, and during processing acquire a characteristic rough matte surface. Since ancient times, jades have been highly valued in stone-cutting, they were used to make tools (knives, axes) and objects of art (cameos, figurines, jewelry). In terms of mechanical properties, these mineral aggregates can compete with titanium and steel, and surpass many alloys in compressive strength. However, the properties of jades related to the possibility of integration into bone tissue did not attract the attention of researchers.

The jade contains silicon oxide, which makes them promising in terms of biological compatibility and the ability to osseointegration. The fibrous structure of these silicates provides the elasticity and microrough surface needed to form a strong bond with bone tissue. Jades are dielectrics, do not participate in electrochemical reactions, and are hydrophilic. It is the complex of properties that made it possible to hope for the high quality of the jade bone implants according to the present invention.

When assessing the possibility of using jades as materials for the manufacture of bone implants, their high strength was confirmed experimentally. The tests used cylindrical polished jade samples without cracks, inclusions and other defects. The measurement results are shown in Table 1.

It was shown that jades have high compressive strength, bending strength, high impact strength, high fracture toughness (table 1). The elastic modulus of jade is relatively low and is comparable to that of titanium (Table 1).

Table 1

Jada name jade jade jade jade xonotlite jade vesuvianite jade bovenite jade pectolite jade hydrogrossular jade Basic mineral jade nephritis xonotlite vesuvianitis bowenite pectolite hydrogrossular Main mineral composition Na (Al, Fe) Si ₂ O ₆ Ca ₂ (Mg, Fe) ₅ Si ₈ O ₂₂ (OH) ₂ Ca ₆ [Si ₆ O ₁₇ (OH) ₂ ] Ca ₁₀ (Mg, Fe) ₂ Al ₄ [(OH) ₄ (SiO ₄ ) ₅ (Si ₂ O ₇ ) ₂ ] (Mg, Fe) ₃ (OH) ₄ Si ₂ O ₅ NaCa ₂ [Si ₃ O ₈ (OH)] Ca ₃ Al ₂ [SiO4] ₂ (OH) ₄ Density 3.3 2.9 2.7 3.3 2.6 2.9 3.5 Mohs hardness 6.5 - 7.0 6.0 - 6.5 6.5 6.5 - 7.0 4 5 6.5 - 7.0 Compressive strength, MPa > 400 > 400 > 400 > 400 > 400 > 400 > 400 Flexural strength, MPa > 100 > 100 > 50 > 50 > 50 > 50 > 50 Young's modulus, GPa 150-250 100-150 100-200 100-200 100-200 100-200 100-200 Crack resistance, MPa * m ^1/2 > 5 > 6 > 4 > 2 > 2 > 2 > 2

table 2

Jada name jade jade jade jade xonotlite jade vesuvianite jade bovenite jade pectolite jade hydrogrossular jade Contact angle, degrees <90 <90 <90 <90 <90 <90 <90 Zeta potential in aqueous solution, mV <0 <0 <0 <0 <0 <0 <0 SBF test, hydroxyapatite formation + ++ +++ ++ + ++ ++ Cytotoxicity - - - - - - - In vitro attachment of osteoblasts + + + + + + + Osteoblast proliferation in vitro + + + + + + + Breakaway torque, N * cm > 2 > 2 > 2 > 2 > 2 > 2 > 2

Checking the properties of materials in aqueous solutions showed that the jades are hydrophilic, the wetting angle of all jades is less than 90 degrees (Table 2). The zeta potential of jades is negative (table 2), which is typical for materials capable of osseointegration.

The results obtained show that the use of jades is promising for the production of implants. However, the interaction of these silicates with bone tissue has not previously been studied. The following test results show that the jade implants according to the present invention have surprisingly good biocompatibility and osseointegration properties.

For an initial assessment of biocompatibility, jade implants were placed in SBF solution according to the methodology [Li, 1992, J. Am. Ceram. Soc., 75 (S) 2094-2097]. In 1-4 weeks after the start of the experiment, crystals of hydroxyapatite formed on the surface of all investigated implants (table 2), which confirms the prospect of biological compatibility and the possibility of osseointegration of jade implants according to the present invention.

To test the biocompatibility of the jade implants according to the present invention, their in vitro interaction with mouse osteoblast cells was studied. Determined the toxicity of the implants according to the present invention for cells, checked the attachment of cells to the surface of the implants and the proliferation of cells in their presence. Standard methods were used with staining 3- (4,5-dimethylthiazol-2-yl) -2,5-diphenyltetrazolium bromide (MTT test), the activity of alkaline phosphatase was measured. It was found that the jade implants according to the present invention do not have a toxic effect on cells, cause attachment and proliferation of osteoblasts (Table 2).

To check osseointegration, the implants were implanted into the bone tissue. For this, cylindrical jade implants were placed into holes in the shin bones of guinea pigs. Chamfers were chosen at the ends of the implants to transmit the torque. Six weeks after implantation, the torque required to break the attachment of the implants to the bone tissue was measured and it was found that the breakaway moment after implant engraftment was greater than the breakaway moment when the implant was inserted into the bone tissue (Table 2). The data obtained confirm the osseointegration ability of the implants according to the present invention.

Thus, the jade bone implants according to the present invention, in addition to high mechanical characteristics and high hydrophilicity, have high biocompatibility and osseointegration capacity. An additional advantage of jade implants is their dielectric properties. The absence of electrical conductivity allows the use of MRI, CT and other medical procedures associated with the transmission of electrical signals. The complex of properties allows the use of jade bone implants in surgery, orthopedics, dentistry. The technical result of the invention is to expand the arsenal of medical devices for implantation into bone tissue and obtain high-strength implants capable of osseointegration.

An exemplary and non-exhaustive list of implants of the present invention made from jade include bone replacement implants, bulk bulk fillers in the form of granules for inclusion in a composition for filling bone defects, bone screws, bone fusion implants, implant anchoring posts or for implants, implants for skull reconstruction, as well as orthopedic implants, percutaneous osseointegrated implants, dental implants.

For orthopedic implants, the high strength of jads is of particular importance, which allows them to be used in joint implants and in highly loaded parts of endoprostheses. The orthopedic implants group includes hip implants, knee implants, shoulder implants, elbow implants, wrist implants, ankle implants, subtalar implants, metatarsal implants, whole toe or implants spine, including vertebral and intervertebral disc implants, radial head implants, thumb implants, osteotomy (high tibial osteotomy) implants. Particularly preferred orthopedic implants are joint implants, in particular a hip implant and a knee implant. The hip implant may be a head prosthesis and a shaft prosthesis (stem of the endoprosthesis or femoral shaft) and an acetabular prosthesis. A knee implant may include the tibial and femoral components of the knee joint.

The next group of jade implants according to the present invention are percutaneous osseointegrated implants (endo-exoprostheses), which are integrated on the one hand into the bone of the distal part of the joint, their extraosseous part extends beyond the body through the tissues and skin of the patient, and the external part of the implant is used to attach external exoprostheses. For endoexoprostheses, as well as for orthopedic implants, the high strength of jade implants is of decisive importance. The group of percutaneous osseointegrated implants includes endo-exoprostheses for legs, endo-exoprostheses for hands, endo-exoprostheses for fingers, endo-exoprostheses for cosmetic operations.

The group of medical devices related to dental implants includes a dental implant (screw, cylindrical, conical or plate), a dental implant with an integrated abutment, a dental implant with an integrated abutment and crown, and a dental bar.

For dental implants for the smile area, the appearance, structure and color of the restoration are extremely important. It should be noted that the type of jade implants according to the present invention can vary significantly depending on the composition of the jade, its conditions of formation, its deposit. Classic jade green tones, but almost the entire color palette is found. White jades are also widespread, and are often valued at least as much as green jades. For example, natural white jade jade, or lamb-colored jade, is well known and highly valued in a number of countries, and is widely used in the production of high-end jewelry. In nature, there are also white jade jade, xonotlite jade, vesuvianite jade, bovenite jade, and pectolite jade. Synthetic jades can also be of any color, including white. It is the implants made of jade of white and similar tones that are most preferable for use in the smile zone.

A jade dental implant can be screw, cylindrical, tapered or plate-shaped, collapsible or combined with an abutment. In a collapsible implant, the attachment of the dental abutment to the implant can be done with a screw or cement. The dielectric and mechanical properties of the jade implant ensure the electrochemical isolation of the internal retaining screw from body fluids. This allows the use of various materials, not only titanium, but also steel and other alloys, for fastening parts of a collapsible dental implant. Both the root implant, the abutment and the crown can be made of white jade or matched to the patient's teeth. The consumer, in particular cosmetic, characteristics of such implants for the smile zone are superior to the consumer characteristics of metal implants, all other things being equal.

The preferred dental implant is an osseointegrable bar made of jade for attachment to the alveolar ridge. The shape and dimensions of the bar are selected for the patient, a platform is prepared on the alveolar ridge for contact of the bar with the bone tissue, a depression can be made corresponding to the shape of the lower part of the bar. The bar, which has holes for attachment, can be attached to the bone through the holes provided using a prepared set of one or more endosseous screw implants or bone screws. The osseointegration that occurs leads to subperiosteal or endosseous-subperiosteal implantation of a combined beam-screw implant or bone screw complex. In this case, the combined implant is securely attached to the alveolar ridge, and bone grafting can be minimized. This implant is further used as a base for fixing dentures, evenly distributes the chewing load on the contact area of the bar with the bone. The use of such constructions is justified for the case of implantation in the area of molars, or for the case of bone tissue of type 3 or 4, or for the case of insufficient volume of the alveolar process for endosseous implantation.

A particularly preferred dental implant is an abutment-integrated dental implant that can be used in a one-step implantation protocol. The crown is fixed immediately after implantation or after successful engraftment of the implant. The use of an integrated implant increases the convenience of work for the doctor and the reliability of the denture for the patient. Further simplifying the implant design - a single monobloc artificial tooth made of white jade, in which the endosseous implant, abutment and dental crown are combined into a single medical device. It can be from a range of standard sizes for on-site turning, or it can be custom made to fit the patient's size.

Examples.

Example 1. Granules of bulk bulk filler for osteoplasty made of pectolite jade. A mixture of granules with autologous bone chips is implanted into the bone defect.

Example 2. An implant of an intervertebral disc made of pectolite jade.

Example 3. An implant for skull reconstruction made of pectolite jade using CAD / CAM technology.

Example 4. Endoprosthesis of the acetabulum of the hip joint from pectolite jade.

Example 5. A combined head and stem of a hip joint endoprosthesis made of pectolite jade.

Example 6. Femoral component of a knee joint endoprosthesis made of pectolite jade.

Example 7. Screw subgingival endosseous dental implant made of pectolite jade. It is used as an artificial tooth root for implantation into the alveolar bone according to the 2-stage protocol.

Example 8. Dental screw endosseous implant made of white pectolite jade with integrated abutment for use in one-stage dental implantation in the smile area.

Example 9. A single monobloc artificial tooth, a white pectolite jade incisor, in which an endosseous screw implant, an abutment and a dental crown are combined. The crown is turned in place.

Example 10. An osseointegrated bar made of white pectolite jade is attached to the alveolar ridge through the holes in the bar using a screw implant made of pectolite jade. The bar is attached endosseously-subperiosteally, to a seat in the bone tissue, prepared according to the shape of the lower part of the bar. The bar compensates for the lack of bone tissue in the smile zone and serves as the basis for dentures.

It is proposed to use jade bone implants according to the claims.

Claims (4)

1. Bone tissue implant, characterized in that the implant or at least part of the implant consists of pectolite jelly. 2. Bone implant according to claim 1, characterized in that the implant is selected from the group consisting of implants for replacing bone tissue, implants for filling bone defects, wedge-shaped bone implants, bone screws, implants for bone fusion, fixing pins for implants or for implants , Skull Reconstruction Implants, Hip Implants, Knee Implants, Shoulder Implants, Elbow Implants, Wrist Implants, Ankle Implants, Subtalar Implants, Metatarsophalangeal Toe Implants, Intra-metatarsal or Toe Implants spine, radial head implants, thumb implants, osteotomy implants. 3. Bone implant according to claim 1, characterized in that the implant is selected from the group of percutaneous osseointegrated implants (endoexoprostheses), including endoexoprostheses for legs, endoexoprostheses for hands, endoexoprostheses for fingers, endoexoprostheses for cosmetic operations. 4. Bone implant according to claim 1, characterized in that the implant is selected from the following group of dental products: dental implants, dental implants with an integrated abutment, dental implants with an integrated abutment and crown, dental bars, dental posts.