WO2010121341A2 - Bioactive composite for bone repair - Google Patents

Abstract

The present invention has applications in the fields of medicine, pharmaceutics and biological tissue engineering. The invention relates to the development of a bioactive composite for bone repair with a polymer matrix composed of a polysaccharide, and strengthened with calcium derivatives, such as calcium hydroxide, hydroxylapatite, or calcium phosphate, in order to produce bioactive composites specific to bone tissue. The strengthening material is used at different concentrations relative to the matrix in order to produce mouldable composites machined into fracture-resistant screws, pins and plates with various elastic deformation values suitable for specific uses in bone fixation, bone repair, bone induction and bone conduction for the treatment of lesions of bone tissue accompanied by loss of substance, including critical defects.

Description

 BIOACTIVE COMPOSITE FOR BONE REPAIR

Field

 The present invention applies to the fields of health sciences, pharmacotechnics and biological tissue engineering.

In particular, with regard to the health sciences area, the invention relates to bone tissue fixation, filling of critical bone tissue defects, osteoconduction and osteoinduction. Regarding the field of pharmacotechnics the invention applies to the controlled release of drugs and nanodevices. Regarding the area of engineering of biological tissues, it can be highlighted the use as bone substitutes with function of conduction and tissue induction.

The composite was also developed with the purpose of being used as fixation pins of bone tissue lesions or machined in the screw model with the same function and application. Another application is in the form of laminates to correct critical flat bone defects and also as fixation plates.

Priorities

The state-of-the-art application has broad specifications, particularly for industrial applications. Composites are among the most commonly used materials for bioactive function bone repair in order to accelerate the process of osteoconduction and osteoinduction in the treatment of critical bone tissue defects. They may be derived from organic or inorganic matrices and reinforcements.

For matrix and reinforcement composites of inorganic origin, there are no systematic studies of cytotoxicity and biococompatibility. Its usual industrial application is used as packaging materials and components for machines and engines. Among inorganic composites are bioactive and biocompatible products, specifically bioceramics and glass and titanium derivatives used particularly in dentistry, traumatology and orthopedics. Despite bioactivity and biocompatibility are inorganic derivatives that do not allow remodeling of organic tissues. The organic matrix composites used for biological applications are mostly protein derivatives such as collagen from different animal sources. These products are biologically active and may lead to immune rejection responses.

Numerous composites are presented as functionally active for the practice of tissue replacement particularly in the areas of dentistry, traumatology and orthopedics. However, there are no materials available that combine physical and chemical characteristics (strength, flexibility and elastic deformation appropriate to different fabrics) indispensable to meet the requirements of a fabric substitute. Moreover, such composites exhibit neither biocompatibility, low cytotoxicity, biointegration, nor implant area remodeling.

Besides the composites are also the alloys that present resistance and biointegration and are used as fixators and implants. Metal alloys remain in the tissues, are stable but do not allow remodeling.

In short, materials for biological application should preferably be non-toxic, biocompatible, with adequate physical and chemical characteristics (good strength, flexibility, elastic deformation and purity) to different tissues and biointegrable inducing remodeling of the implant area. To the best of your knowledge, you will not find materials that meet all the specifications of an ideal fabric substitute. Previous innovations for the same purpose, utilizing microbial polysaccharides such as bacterial cellulose, carry out chemical processes by chemical modifications of the cellulose chain by adding functional groups (WO / 2009/039238). The bioactive composite for bone repair presented here differs from what is currently known to be characterized as a product consisting entirely of organic, matrix and inorganic components, reinforcement, which together is bioactive, nontoxic, biocompatible, moldable, resistant, flexible and its obtaining process do not use chemical reactions or baths in solutions. It combines in one product properties of biocompatibility, biointegration and fixation of bone tissue.

Problems and Limitations

Numerous composites are presented as functionally active for tissue replacement practice particularly in the areas of dentistry, traumatology and orthopedics.

However, there are no materials available that combine physical and chemical characteristics indispensable to meet the requirements of a fabric substitute: resistance, flexibility and elastic deformation suitable for different fabrics, besides presenting biocompatibility, low cytotoxicity, or even, nontoxic and present. biointegration, reshaping the implant area. Besides the composites are also the alloys that present resistance and biointegration and are used as fixators and implants. Metal alloys remain in the tissues, are stable and do not allow their remodeling. Materials for biological application are expected to be non-toxic, biocompatible and meet physical and chemical characteristics such as strength, flexibility, elastic deformation and purity, suitable for different tissues, undergo biointegration inducing remodeling of the implant area. There are no materials that meet all the specifications of an ideal fabric substitute. The organic matrix composites used for biological applications are mostly protein derivatives such as collagen from different animal sources. These products are biologically active and can lead to immune rejection responses. Solution

The invention is a composite whose matrix is a polysaccharide and the reinforcement is a compound of inorganic origin (calcium hydroxide, hydroxyapatite and calcium phosphate). The reinforcement was used to associate a bioactive induction in the composite, specific to bone tissue. The reinforcement was used in different concentrations in relation to the matrix, to obtain composites with rupture resistance and different elastic deformation indices suitable to the specific applications of osteofixation, critical defects filling, osteoinduction, osteoconduction and osteorepation. The reinforcement may be calcium hydroxide, hydroxyapatite or calcium phosphate, or a two to two combination of these in different proportions, or the three reinforcements combined in different proportions may be used.

The biopolymer must be emulsified to form the basic matrix at different concentrations for the addition of one of the reinforcements. Dispersion of components should be by agitation. Excess water should be removed which will result in a paste that can be shaped and dehydrated. The resulting mass is a resilient, resilient and elastically deformable composite. As an example of application of the invention the following experiments were performed: The matrix relating to these experiments was of biological origin, composed entirely of sugars and glucuronic acid, organic components found as metabolic actives in living beings, including man. Organic matrix is a polysaccharide consisting of sugars from natural sources that does not elicit an immune response of rejection like protein derivatives. Bacterial expolysaccharide was obtained based on the production process described in PI9603700-8; PI0301912-8 and PI0504376-0. The biopolymer was emulsified from a 1g volume weight suspensions of the biopolymer to 50 to 150mL of water, forming the base matrix at different concentrations for the specific addition of one or combination of reinforcement at concentrations of 0.01 to 3%. relative to the matrix. At the In this case, experiments were performed with calcium hydroxide and calcium phosphate. Dispersion of the components was by continuous stirring for 30 minutes. Excess water was removed by filtration. The resulting paste was modeled by cold extrusion and compression between plates. Then the dough was dehydrated in a particle free environment. The resulting mass is a non-toxic, bioactive, biocompatible, moldable, tear-resistant and elastically deformable composite. In an "in vitro" study, the product to which the present invention relates exhibited calcium phosphate deposition on its surface, which is a precursor of hydroxyapatite, an organic material present in 90% of bone tissue. Thus, the use of a biodegradable natural product obtained from raw material from renewable sources as apatite-organic polymer composites is an attraction of various methods of manufacturing biomaterials as bone remodeling.

summary

The invention relates to the development of a bioactive composite whose polymeric matrix is composed of polysaccharide. As reinforcement, calcium derivatives such as calcium hydroxide, apatite hydroxide, calcium phosphate are used to obtain bioactive composites with specificity for bone tissue. The reinforcement was used at different concentrations in relation to the matrix to obtain modelable composites, with resistance to rupture and with different elastic deformation indices suitable to the specific applications of osteofixation, osteorepation, osteoinduction and osteoconduction for the treatment of bone tissue injuries. loss of substance including critical defects.

Detailed Description The invention is a composite whose matrix is a polysaccharide and the reinforcement is a compound of inorganic origin (calcium hydroxide, hydroxyapatite and calcium phosphate). The reinforcement was used to associate a bioactive induction in the composite, specific to for bone tissue. The reinforcement was used in different concentrations in relation to the matrix, to obtain composites with rupture resistance and different elastic deformation indices suitable to the specific applications of osteofixation, critical defects filling, osteoinduction, osteoconduction and osteorepation.

The biopolymer must be emulsified to form the basic matrix at different concentrations for the addition of one of the reinforcements. Dispersion of components should be by agitation. Excess water should be removed which will result in a paste that can be shaped and dehydrated. The resulting mass is a resilient, resilient and elastically deformable composite.

As an example of application of the invention the following experiments were made: The matrix of these experiments is of biological origin, composed entirely of sugars and glucuronic acid, organic components found as metabolic actives in living beings, including man. Organic matrix is a polysaccharide consisting of sugars from natural sources that does not elicit an immune response of rejection like protein derivatives. Bacterial expolysaccharide was obtained based on the production process described in PI9603700-8; PI0301912-8 and PI0504376-0. The biopolymer was emulsified from a 1g volume weight suspensions of the biopolymer to 50 to 150mL of water, forming the base matrix at different concentrations and the addition of one or the reinforcements or their association at a concentration of 0.01 to 3. , 0% of the matrix. In this case, experiments were performed with calcium hydroxide and calcium phosphate. Dispersion of the components was by continuous stirring for 30 minutes. Excess water was removed by filtration. The resulting paste was modeled by cold extrusion and compression between plates. Then the dough was dehydrated in a safe environment with low level of particulate matter. The resulting mass is a non-toxic, bioactive, biocompatible, moldable, tear-resistant and elastically deformable composite. In a ^non- in vitro study, "the product to which the present invention relates exhibited calcium phosphate deposition on its surface, which is a precursor of hydroxyapatite, an organic material present in 90% of bone tissue. A natural, biodegradable product obtained from raw materials from renewable sources such as apatite-organic polymer composites is an attraction of various methods of manufacturing biomaterials as bone remodeling.

Claims

1. BIOACTIVE BONE REPAIR COMPOSITE consisting of an organic matrix and inorganic reinforcements characterized in that the matrix is polymeric is added reinforcement and the reinforcement is a calcium derivative. BIOACTIVE BONE REPAIR COMPOSITE according to claim 1, characterized in that said matrix is a polysaccharide. BIOACTIVE BONE REPAIR COMPOSITE according to claim 2, characterized in that said polysaccharide is an expolysaccharide. BIOACTIVE BONE REPAIR COMPOSITE according to claim 1, 2 or 3, characterized in that said reinforcement is calcium hydroxide or calcium phosphate or hydroxyapatite. BIOACTIVE BONE REPAIR COMPOSITE according to Claim 1, 2 or 3, characterized in that said reinforcement is any mixture of calcium hydroxide, calcium phosphate and hydroxyapatite, combined two by two or all three together. BIOACTIVE BONE REPAIR COMPOSITE according to claim 1, 2, 3, 4 or 5 characterized in that said reinforcement associates a bone tissue specific bioactive induction in said matrix. 7. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR to obtain the composite according to claims 1, 2, 3. 4, 5 or 6 characterized in that the organic matrix is emulsified with different concentrations of inorganic reinforcements, dispersion of the components is by agitation, excess water is removed and finally the paste is shaped and dehydrated for use. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7, characterized in that said organic matrix is obtained based on the production process described in PI9603700-8; PI0301912-8 and PI0504376-0. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7 or 8, characterized in that The matrix is emulsified from a 1 g volume by weight suspensions of biopolymer to 50 to 150 ml of water. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7, 8 or 9 characterized in that the composite is formed by adding the reinforcement to the matrix at different concentrations ranging from 0.01 to 3%. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7, 8, 9 or 10, characterized in that the reinforcement is calcium hydroxide or calcium phosphate or hydroxyapatite used alone or in combination. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7, 8, 9, 10 or 11 characterized in that the dispersion of the components is by continuous stirring for 30 minutes. BIOACTIVE COMPOSITE PROCESS FOR BONE REPAIR according to claim 7, 8, 9, 10, 11 or 12 characterized in that the resulting mass is dehydrated in an environment free of particulate matter. Use of the BIOACTIVE COMPOSITE FOR BONE REPAIR according to claim 1, 2, 3, 4, 5, 6 or obtained from the process according to claim 7, 8, 9, 10, 11, 13 or 13 as a bone tissue fixative, filler critical bone tissue defects, osteoconduction or osteoinduction. Use of the BIOACTIVE COMPOSITE FOR BONE REPAIR according to claim 1, 2, 3, 4, 5, 6 or obtained from the process according to claim 7, 8, 9, 10, 1 1, 12 or 13 as a basis for controlled release of drugs and nanodevices. Use of the BIOACTIVE COMPOSITE FOR BONE REPAIR according to claim 1, 2, 3, 4, 5, 6 or obtained from the process according to claim 7, 8, 9, 10, 1 1, 12 or 13 bone substitutes with conduction and induction function of fabric. Use of the BIOACTIVE COMPOSITE FOR BONE REPAIR according to claim 1, 2, 3, 4, 5, 6 or obtained from the process according to claim 7, 8, 9, 10, 1 1, 12 or 13 as bone tissue injury fixation pins or machined on the bolt model with the same function and application. Use of the BIOACTIVE COMPOSITE FOR BONE REPAIR according to claim 1, 2, 3, 4, 5, 6 or obtained from the process according to claim 7, 8, 9, 10, 11, 12 or 13 in the form of correction laminates critical defects of flat bones or as fixation plates.