COMPOSITE CONTAINING POLYMER AND ADDITIVE AS WELL AS ITS USE
Background of the Invention
Field of the Invention
The present invention concerns biocompatible and bioabsorbable composite materials containing multimonomer-polymers and/or their blends together with one or more additive, as well as a method for manufacturing said composites. These composite materials have the required properties tailored to be suitable for use in implantable surgical devices.
Description of Related Art
In orthopaedic surgery, either biostable or biodegradable devices, such as pins, fixation screws, plates, tacks, bolts, intramedullary nails, interference screws, suture anchors, or staples, are used in various applications.
Most biostable devices are made of metallic alloys. However, there are several disadvantages in the use of metallic implants, such as the bone resorption caused by the bone plates and screws (Wolffs law), which carry most of the external loads, as well as debris formation and the possibility of corrosion. Therefore, surgeons are recommended to remove metallic implants in a second operation to be carried out once the fracture has healed.
Therefore, bioabsorbable (i.e. biodegradable and resorbable) surgical devices, generally made from polymers, are commonly used in surgical fixation. The advantages of these devices include that the materials are absorbed in the body and the degradation products exerted via metabolic routes. Hence, a further implant removal operation is not required. Additionally, the strength of the bioabsorbable polymeric devices decreases gradually as the device is degraded, whereby the bone is progressively loaded. This, in turn, promotes bone regeneration.
Synthetic biodegradable polymers have many advantages in the medical applications. They can be tailored to fulfill specific needs of a particular application. The hydrophobicity, crystallinity, degradability, solubility and thermal properties (glass transition and melting temperature) of polymer can be easily modified by copolymerization or by changing polymerization conditions. Another feasible route to modify polymer properties is physical blending.
Biodegradable polymers are typically synthetic aliphatic polyesters. Most commonly used aliphatic polyesters are poly-a-hydroxy acids such as polyglycolides (PGA), polylactides (PLA) and their copolymers produced by polycondensation or ring-opening polymerization. Biocompatible and bioabsorbable surgical devices are normally made of these polymers. Glycolide/L-lactide copolymers (PLGA) and glycolide trimethylene carbonate copolymers (PGA/TMC) are examples of glycolide based copolymers. Lactide based copolymers may comprise lactones (acid dimers) such as L-lactide (L), D-lactide (D), D,L-lactide (DL), glycolide (G), ε-caprolactone (CL), trimethylene carbonates (TMC), /7-dioxanone (PD), 2-methyl glycolide (MG), 2,2-dimethyl glycolide (DMG), 1,5-dioxapane-2-one (DOX-5), para-dioxapane-2-one (DOX-4), 3,3-dimethyltrimethylene carbonate (DMTMC), glycosalicylate (GS), and morpholine-2,5-dione (MD) as comonomer. In these aliphatic polyesters described, n-alkylene, alkylene oxide or alkylene carbonate linking groups may consist more than 5 carbon atoms in backbone (-CH2-). n-Alkylene may also be substituted (side-chain polymers) or branched (star polymers). Copolymers of L-lactide and D-lactide are also able to form stereocomplexes (stereopolymers), which behavior is resulting from the enantiomer character of a single lactic acid. Polyhydroxyalkanoates (PHA), polyhydroxybutyrates (PHB), polyhydroxyvalerate (PHV) and poly(hydroxybutyrate-co hydroxyvalerate) (PHBV) are belonging to polyhydroxyalkanoates (bacterial polyesters) produced by bacterial biosynthesis. Other possible biodegradable polymers are poly(ortho esters), polyanhydrides, polyamides, polydioxanones, polyoxylates, polyoxamates, polyacetals, “pseudo”-poly(amino acids) such as tyrosine-derived polycarbonate, polypropylene fumarates), poly(butylenes adipate-co-terephthalate), polyesteramides, pocarboantes, polyiminocarbonates, polyurethanes, poly(alkyl cyanoacrylates), polyphosphazenes, polyphosphoesters.
Copolymers of lactides have been chemically prepared to modify the properties of homopolymer. For instance co-monomers such as L-lactide (L), D-lactide (D) or racemic D,L-lactide (DL) disrupt the crystallinity of L-lactide block, which is resulting to reduced crystallinity and also sometimes to accelerated degradation process. The semi-crystalline homopolymer poly(L-lactide) has a modulus about 25% higher than copolymer poly(D,L-lactide). The amorphous copolymer poly(L-lactide-co-D,L-lactide) may have higher elasticity due to lack of crystallinity.
Biodegradable polyesters decompose mostly by hydrolysis after having been exposed to moisture. Normally, there exists a sequence of phenomena; a decrease in molecular weight, strength, and mass during the hydrolysis of biodegradable polymers. Crystalline blocks of semi-crystalline polylactide are more resistant to hydrolytic degradation than the amorphous phase. Time required for certain polylactide implants to be totally absorbed is relatively long and depends on polymer quality, processing conditions, implant site, and physical dimensions of the implant. For instance PL A degrades in vivo to form lactic acid which is normally present in the body. This acid enters tricarboxylic acid cycle and is exerted as water and carbon dioxide.
Bioceramics are attractive as biological implants because of their biocompatibility. During the last three decades ceramic materials have become widely used in many medical applications such as hip prosthesis, cardiac valves and dental implants. Among the biomaterials available, medical ceramics or bioceramics, exhibit some of the most interesting properties. Calcium phosphates have been used in the form of artificial bone. Calcium phosphate ceramics (CPC) have been synthesized and manufactured to various forms of implants and coatings. Calcium phosphate ceramics exhibit non-toxicity to tissues (biocompatibility), bioreseption and osteoinductive property. Calcium hydroxyapatite (HA) and tricalcium phosphates (TCP) are the most typical bioceramics used in medical devices. Tricalcium phosphate exits in two different whitlockite crystallographic configurations, namely as α-TCP and as the more stable β-TCP. The biodegradation rate of TCP is greater than that of HA, because the differences in the crystalline structures. Glass-ceramics (A/W glasses) were developed in the early 1960s. The basic components in most bioactive glasses are S1O2, Na20, CaO and P2O5. Bioglass and glass-ceramics are nontoxic and are able chemically bond to bone. The primary advantage of bioactive glasses is their quick rate of surface reaction resulting in fast bonding.
In its most basic form a composite material is one, which is composed of at least two elements working together to produce material properties that are different to the properties of those elements on their own. The mechanical properties of polymers can be improved by the addition of the particulate or fiber reinforcement. A wide variety of bioabsorbable homo- and copolymers containing implantable prior art materials and devices have been made and described for instance in the following publications:
Eur.Pat.No. 0011528 and U.S. Pat.No. 4,279,249 describe osteosynthesis parts made of absorbable polymer composition consisting of a matrix of lactic acid homopolymer, or copolymer very high in lactic acid units, having discrete reinforcement element embedded therein. The reinforcement elements are made of glycolic acid homopolymers or copolymers predominant in glycolic acid units. Osteosynthesis part made of said polymer compositions containing a charge constituted by a material containing at least one ion selected from: calcium, magnesium, sodium, potassium, phosphate, borate, carbonate and silicate. Such a composition may be shaped with minimum of polymer degradation into osteosynthesis parts exhibiting good resilience, shock resistance, and tensile strength. One mentioned example is a composite part prepared by compression-molding employing as the polymer the PLA charged with tricalcium phosphate.
Eur.Pat. No. 0204931 and Ei.S. Pat. No. 4,743,257 describe surgical osteosynthesis composite material, which is self-reinforced. This material is formed about the absorbable polymer or copolymer matrix which is reinforced with absorbable reinforcements units which have the same chemical element percentage composition as the matrix has. Osteosynthesis material is characterized in that the absorbable matrix and reinforcement units are manufactured of polylactide or a lactide copolymer. Other main material combination is the one, where the absorbable matrix and reinforcement units are manufactured of polyglycolide or a glycolide copolymer. The absorbable matrix and reinforcement units can be also manufactured of glycolide/lactide copolymer. Selfreinforcement in these patents means that the polymeric matrix with the reinforcement element or materials (such as fibers) which the same chemical element composition as does the matrix, and then preferred processing method is compression-molding. EI.S. Pat. No. 4,968,317 and Eur.Pat. No.0854734 describes surgical material of resorbable polymer, copolymer, or polymer mixture containing at least partially fibrillated structural units, and use thereof. Homopolymer and copolymer materials are typically composed of the absorbable matrix and reinforcement units are manufactured of polylactide or a lactide copolymer. Self-reinforcing in these patents means orientation of the molecular structure of absorbable polymeric materials in such a way that they are at least partially fibrillated. U.S. Pat. No. 6,406,498, and Eur.Pat. No. 1109585 describe a bioactive, biocompatible, bioabsorbable surgical composite that is fabricated bioabsorbable polymers, copolymers or polymer alloys that are self-reinforced and contain ceramic particles or reinforcement fibers, and also can be porous. Polymers matrix is typically composed of poly-a-hydroxy acid based absorbable polymers or copolymers such as polylactide or a lactide copolymer. Typical ceramic additive is belonging to calcium phosphate ceramic family, and then the most typical additive is beta-tricalcium phosphate (β-TCP). The composite of the invention can be formed into devices with the suitable property profile depending on the indication.
Eur.Pat. No. 1009448 and U.S.Pat.No. 7,541,049 describe surgical osteosynthesis composite materials which has three components, namely biodegradable polymer reinforcement, bioceramic or bioglass filler reinforcement and biodegradable polymer matrix. The invention introduces the composites that have two different reinforcing phases and one matrix phase. One reinforcing element is referred as the polymeric reinforcing element and the other as the ceramic reinforcing element. Typical matrix polymers are poly-a-hydroxy acid based absorbable polymers or copolymers such as polylactide or a lactide copolymer. U.S.Pat. No. 6,206,883 and U.S.Pat.No. 6,716,957 describe a bioabsorbable material such as a terpolymer of poly-(L-lactide/D-lactide/glycolide). The claims of the former patent is relating to an implantable medical device and the ones of the latter to a material comprising terpolymer. The material may consist of 85 molar percent L-lactide, 5 molar percent D-lactide, and 10 molar percent glycolide. The material may hay tensile strength retention at 26 weeks of incubation at least 50%, and tensile strength retention at 52 weeks of incubation of at most about 25%. The material may be used in implantable devices such as bone fixation devices. U.S.Pat.No. 6,747,121 describes implantable, resorbable copolymers containing L-lactide and glycolide repeat units, and in particular to terpolymers containing L-lactide, glycolide, and one other type of repeat unit selected from the group consisting of D-lactide, D,L-lactide, and ε-caprolactone. Medical devices for in vivo implantation applications containing such implantable, resorbable copolymers have also been described, as well as methods for making such co- and terpolymers and devices.
Surgeons prefer using devices that eventually are resorbed and disappear from the body after they have served their purpose. However, in many cases sufficient strength properties are difficult to achieve using bioabsorbable polymeric devices, particularly since the strength must be maintained for a sufficient period of time, even after the absorption of the material has started. A common way to overcome this challenge is to manufacture bioabsorbable medical implants with as high initial molecular weight as possible. Another commonly used route is to choose materials having long degradation time. The result in both cases is unfortunately prolonged total bioabsorption time, which can be in certain cases 5-10 years. Therefore the optimized biodegradation kinetics is needed. The optimized kinetics means here long enough strength retention time to guarantee tissue healing while biodegradation occurs in reasonable time scale to guarantee the lack of negative tissue responses caused by degradation products of polymeric or composite device.
For some surgical applications there are challenges to achieve sufficient strength properties by using non-reinforced bioabsorbable polymers and composites. For those cases the use of various reinforcing techniques is a feasible way to guarantee required initial strength properties. Self-reinforced polymeric composites have been developed that show enhanced strength compared to conventional polymeric surgical materials (see e.g. EP 1109585). However, even these do not provide the preferred advantageous properties bioabsorption kinetics of the materials of the present invention.
Several publications describe the use of composite materials in surgical devices, such as EP 0011528, EP 1009448and EP 1109585. However, none of these solutions describe the use of preferred terpolymers of this invention in these materials and devices.
Copolymers have been described extensively as polymer materials examples (e.g. in EP 0423155). U.S.Pat. No. 6,206,883, U.S.Pat.No. 6,716,957 and U.S.Pat.No. 6,747,121 are depicting bioabsorbable polymers such as terpolymer of poly-(L-lactide/D-lactide/glycolide), which is used in implantable devices such as bone fixation devices. These three patents are not claiming any absorbable composite materials or medical devices made of said composite materials.
It has been attempted to mix various additives into the bioabsorbable polymers to modify their properties and to yield devices having useful properties. The initial mechanical strength of surgical materials has been improved by applying reinforcement units having the same chemical composition as matrix such as absorbable fibers by mixing mechanically together and then compression-molded (see e.g. Example 5 in EP 0204931). The reinforcement fibers typically have a fiber length of 1 pm to 10mm. However, if the chemical structure or the element composition of the reinforcement units differ from that of the matrix material (e.g., EP 0011528), the resulted structures cannot generally form strong bonds between each other, which, in turn, leads to poor adhesion. Adhesion promoters, such as silanes or titanates, cannot be applied in surgical materials due to their toxicity. The poor interface adhesion has been solved by orientation of the molecular structure of absorbable polymeric material in such a way that it is at least partially fibrillated because of molecular orientation of polymer by means of self-reinforcing process (EP 0854734 and EP 1109585).
The self-reinforced materials described in EP 0204931 and EP 0854734 are composed of plain polymer/polymers, and therefore they lack direct bone-bonding properties. To overcome this challenge the composite properties have been modified by additives including bioceramics, which optionally can be bioactive (such as in EP 1009448). These additives can be in various forms including particle fillers, fibers, etc., and these additives can promote osteoconductivity, i.e. such bioabsorbable bone fracture fixation devices can create direct contact with the bone tissue. A general problem with addition of said ceramic particles has been the brittleness of the formed composites, since the addition of ceramic fillers into the polymeric matrix changes most thermoplastic polymers from tough and ductile to brittle in nature. This is a consequence of lack of adhesion between said ceramic particles and polymer matrix. This is evidenced by a significant reduction in both the elongation at break and the impact strength. Moreover, even non-filled bioabsorbable thermoplastic polymer devices can be brittle in their mechanical behavior. The brittleness can be a severe limitation on bioabsorbable devices, leading to premature breaking or other adverse behavior.
Thus, there remains a need for non-toxic bioabsorbable composite materials having sufficient strength retention properties during the degradation, reasonable estimated total bioabsorption time and osteoconductive potential. The osteoconductive potential means here a good adhesion particularly to solid contact with bone tissue.
Any discussion of documents, acts, materials, devices, articles or the like which has been included in the present specification is not to be taken as an admission that any or all of these matters form part of the prior art base or were common general knowledge in the field relevant to the present disclosure as it existed before the priority date of each claim of this application.
Throughout this specification the word "comprise", or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated element, integer or step, or group of elements, integers or steps, but not the exclusion of any other element, integer or step, or group of elements, integers or steps.
Summary of the Invention
In a first aspect, provided herein is a biocompatible, bioabsorbable composite material when used in surgical devices, characterized in that it comprises a bioabsorbable polymer composed of a terpolymer of 60-90 mol% L-lactide (L), 1-20 mol% D-lactide (D) and 1-20 mol% glycolide (G) PLDGA with 1-99 wt-% biocompatible additive, calculated from the weight of the composite, wherein the biocompatible additive is selected from the group consisting of one or more biocompatible ceramics, which are dispersed as one or more additive components.
In a second aspect, provided herein is a surgical device, which is at least partially absorbable in tissue conditions, characterized in that it contains the bioabsorbable composite material according to the first aspect.
In a third aspect, provided herein is a process for manufacturing the surgical device of according to the second aspect, wherein one or more biocompatible additives according to the first aspect or one or more functional additives selected from the group consisting of: - organic or inorganic additives, which are bioactive, or which activate the healing of wounds, facilitate processing of the material or alter its properties, or which facilitate its handling; - osteoconductive agents, antibiotics, chemotherapeutic agents, growth factors, bone morphogenic proteins and anticoagulants; - stabilizers, antioxidants and plasticizers; or - colorants, or both are added to a composite material composition, mixed and subjected to mechanical treatment, characterized by - selecting a polymer matrix composition containing one or more terpolymers, - heating the polymer matrix composition to a molten state or dissolving it in a solvent, - mixing the polymer matrix composition with one or more biocompatible additives according to the first aspect or one or more functional additivestional additives selected from the group consisting of: - organic or inorganic additives, which are bioactive, or which activate the healing of wounds, facilitate processing of the material or alter its properties, or which facilitate its handling; - osteoconductive agents, antibiotics, chemotherapeutic agents, growth factors, bone morphogenic proteins and anticoagulants; - stabilizers, antioxidants and plasticizers; or - colorants, or both. - subjecting the formed composite material mixture to a mechanical deformational treatment using heat or pressure or both, to form the final structure of the surgical device, and - finishing, cleaning and drying the formed structure.
It is a preferred aim of the present invention to provide a biocompatible, bioabsorbable polymer composite material suitable for use in surgical devices.
Particularly, it is a preferred aim of the present invention to provide such bioabsorbable polymer composites for surgical devices, which provide these devices with an improved bioabsorption kinetics at the same time maintaining equivalent strength compared to the prior art. The improved bioabsorption kinetics means here long enough strength retention time to ensure mechanical support during the required healing period and short enough degradation in terms of decline of molecular weight (or inherent viscosity) to guarantee faster total bioabsorption than plain PLLA polymer.
Further, it is a preferred aim of the invention to provide said surgical devices, the strength of which can be maintained on a sufficiently high level for a required healing time compared to the prior art.
Likewise, it is a particular preferred aim of the invention to provide said improved and prolonged strength retention without significantly impairing the adhesion of the surgical devices to bone and without prolonged total mass loss time.
These and other preferred aims, together with the advantages thereof over known polymer composites (as well as compositions, devices and manufacturing processes), are achieved by the present invention, as hereinafter described and claimed.
Thus, the present invention concerns a biodegradable composite material for use in surgical devices, which composite contains a biocompatible polymer matrix composition and one or more biocompatible additives, preferably in the form of bioceramics. Further, the invention concerns a surgical device containing said composite, and a process for its manufacture.
The preferred embodiments of the invention relating to bioabsorbable composite materials and medical devices made of them, as well as methods for manufacturing said devices, comprise: (a) compositions of multimonomer-polymer and/or their blends as matrix, wherein one or more additives are dispersed; (b) multimonomer-polymer matrix encompasses repeat units, which are derived from lactone-based monomers as a primary matrix component; (c) multimonomer-polymer matrix consists the lactone-based repeat unit compositions, which are composed of more than two co-monomers (biopolymers), namely the ones of three monomers (terpolymers), or the ones of four monomers (quaterpolymers), or the ones of five monomers (quinterpolymers), etc. as a secondary matrix components; (d) multimonomer-polymer matrix consists of the blends of polymers, which are composed of more than two co-monomers (biopolymers), namely the ones of three monomers (terpolymers), or the ones of four monomers (quaterpolymers), or the ones of five monomers quinterpolymers, etc. as a tertiary matrix components; (e) additive component encompasses bioceramics, which are selected from calcium phosphate ceramics and/or bioactive glasses and glass-ceramics as one or more primary additives; (f) additive component encompasses one or more assistive additives in addition to one or more primary additive; (g) said composite materials are manufactured by mixing (molten or solution) selected one or more bioabsorbable matrix and selected one or more additive components with each other in molten or solution phase, the preferred manufacturing process is molten; (h) bioabsorbable medical devices are manufactured from said preferred one or more composite compositions by means of one or more continuous or non-continuous processes depending on the product application; (i) medical devices made of said composite materials are used in selected indications.
Considerable advantages are obtained by means of the invention. Among others, the present invention provides an optimized bioabsorption profile, i.e. the material exhibits a fast enough rate of absorption (i.e. reduced total mass loss time) while maintaining its strength for a sufficiently long time. Particularly the shear strength provides the advantages that are significant in manufacturing surgical devices.
The composite materials of this invention can be further processed by means of various orientation techniques such as self-reinforcing. By orientating preferred polymer matrix components of this invention, high ceramic contents can be added to matrix polymer matrix without resulting to brittle composite material. Such high ceramic contents as 50wt-% can lead to composite structures which are hand malleable at room temperature.
Next, the invention will be described more closely with reference to the attached drawings and a detailed description.
Brief Description of the Drawings
Figure 1 shows the bending of self-reinforced 50-wt-% beta-TCP containing terpolymer composite without breakage.
Figure 2 shows the bending of injection molded terpolymer composites without breakage.
Figure 3 shows the eyelet strength of self-reinforced terpolymer (85L/5D/10GPLDGA) and terpolymer composite (85L/5D/10G PLDGA + TCP) suture anchors
Figure 4 shows the torsion strength of self-reinforced terpolymer (85L/5D/10GPLDGA) and terpolymer composite (85L/5D/10G PLDGA + TCP) suture anchors.
Figure 5 shows the eyelet strength of various injection molded terpolymer and terpolymer composite suture anchors
Figure 6 shows the torsion strength of various injection molded terpolymer and terpolymer composite suture anchors
Figure 7 shows the estimated total biodegradation time for composites of this invention.
Detailed Description of the Preferred Embodiments of the Invention
The present invention concerns a biocompatible, bioabsorbable composite material for use in surgical devices, containing one and more multimonomer-polymers and/or their blends together with one or more additives, as well as a method for manufacturing said composites. Particularly, the composite material comprises a bioabsorbable polymer composed of three or more lactone-based repeat units as a matrix, wherein one or more biocompatible ceramics are dispersed as said one or more additive components.
These bioabsorbable composite materials include a bioabsorbable matrix polymer, which preferably is composed of three chemically differing repeat units, i.e. it is a terpolymer, and where the ceramic is bioabsorbable and bone adhesion promoting as well as, preferably, bone growth promoting, bioceramic additive.
Tailor-made medical devices, such as interference screws and suture anchors, may be manufactured of said bioabsorbable composite materials.
The bioabsorbable polymeric matrix of the invention may be selected from a diversity of synthetic bioabsorbable polymers. Such synthetic biocompatible, bioabsorbable polymers are preferably aliphatic polyesters such as poly-a-hydroxy acids. These multimonomer based polymers as a matrix contain preferably one or more repeat units selected from lactones (cyclic acid dimers) such as L-lactide (L), D-lactide (D), D,L-lactide, glycolide (G), s-caprolactone (CL), trimethylene carbonates (TMC), />dioxanone (PD), 2-methyl glycolide (MG), 2,2-dimethyl glycolide (DMG), l,5-dioxapane-2-one (DOX-5), para-dioxapane-2-one (DOX-4), 3,3-dimethyltrimethylene carbonate (DMTMC), glycosalicylate (GS), and morpholine-2,5-dione (MD). However, in the primary embodiment of the invention terpolymer matrix consists of lactide and glycolide repeat units, most preferable terpolymers of a L-lactide repeat unit (L), a D-lactide repeat unit (D), and/or a racemic D,L-lactide repeat unit (D,L) and glycolide (G). The bioabsorbable composite contains preferably only one terpolymer as a matrix component.
The additive component of the invention can be selected from bioceramic and glass groups such as hydroxyapatite (HA) and tricalcium phosphates (a- and β-TCPs), but also from other calcium phosphates such as monocalcium phosphate monohydrate (MCPM), monocalcium phosphate anhydrate (MCPA), dicalcium phosphate dehydrate (DCPD, i.e., brushite), dicalcium phosphate anhydrate (DCPA, i.e., monenite), octacalcium phosphate (OCP), amorphous calcium phosphate (ACP), calcium-deficient hydroxyapatite (CDHA) and tetracalcium phosphate (TTCP), Bioglass, Cerevital bioactive glass-ceramics, alumina, zirconia, bioactive gel-glass, bioactive glasses and glass ceramics. However, the bioceramic additive material component of the composite is preferably beta-tricalcium phosphate (beta-TCP) or a mixture of hydroxyapatite and beta-tricalcium phosphate (HA/TCP) in the primary embodiment of the invention. Particularly, at least a portion of the additives are always selected from biominerals, providing a composite structure at least partially to resemble the bone matrix.
The optimized biodegradation kinetics of the composite materials of this invention comprises long enough strength retention time typically 6-26 weeks to guarantee tissue healing depending on the application and reasonable total bioabsorption time 1.5-4 years. Too quick bioabsorption may cause negative tissue responses because of high concentration of degradation products. Therefore, in this invention preferable composite compositions are introduced to avoid too quick degradation and not compromise mechanical performance.
According to a preferred primary embodiment of the invention, the composite material is composed of polymer matrix, preferably a terpolymer PLDGA of L-lactide, D-lactide and glycolide (G), particularly of the type 70-90 mol% L / 1-20 mol% D / 1-20 mol% G PLDGA, or a blend thereof, mixed with 1-90 wt% biocompatible ceramic additive. More preferably, the composite material is formed from 80mol% L /5-15 mol% D / 5-10 mol% G PLDGA, or a blend thereof, and 10-60 wt% biocompatible additives.
According to a preferred primary embodiment of the invention, the additive is a bioceramic material, which may be selected from any biocompatible ceramic material such as a calcium phosphate and bioactive glass. Most suitably, the ceramic material is beta-tricalcium phosphate (beta-TCP) or a mixture of HA/TCP. Ceramic additive is mainly inducing osteoconductivity to composite.
In another embodiment of the invention, the polymer matrix consists of more than three lactone-based repeat units in addition to L-lactide, D-lactide and glycolide (PLDGA) such as trimethylene carbonate (TMC), ε-caprolactone (CL) and/or />dioxanone (PD) or a blend thereof, mixed with 1-90 wt% biocompatible ceramic additive.
In still another embodiment of the invention, the composite material is composed of colorant containing polymer matrix, preferably a terpolymer PLDGA of L-lactide, D-lactide and glycolide (G), particularly of the type 70-90 mol% L / 1-20 mol% D / 1-20 mol% G PLDGA, or a blend thereof, mixed with 1-90 wt% biocompatible ceramic additive and with 0.01-0.3 wt-% colorant such as 1-hydroxy-4-[(4-methylfenyl)amino]-9,10-antrasenedione (D&C Violet #2) or 9,10-anthracenedione, l,4-bis[(4-methylphenyl)amino] (D&C Green 6). More preferably, the composite material is formed from 80 mol% L /5-15 mol% D / 5-10 mol% G PLDGA, or a blend thereof, and 10-60 wt% biocompatible additive with 0.01-0.3 wt-% colorant such as 1-hydroxy-4-[(4-methylfenyl)amino]-9,10-antrasenedione (D&C Violet #2) or 9,10-anthracenedione, 1,4-bis[(4-methylphenyl)amino] (D&C Green 6).
In further another embodiment of the invention the composite matrix may contain a physical blend of two or more terpolymers, or a physical blend of one or more terpolymer with one or more copolymer or homopolymer or both. Most suitable, the terpolymer composition consists of a single terpolymer mixed with said one or more biocompatible preferred ceramic additives.
In a further embodiment of the invention the bioactive glasses optionally employed as primary ceramic additives are based on a network former and at least one additional additive component. The network former can, for example, be P2O5. The additional components typically provide the resulting composite with a further advantageous function, such as change its rate of solubility, whereby these are also called functional additives.
One group of additional additives include alkali and alkaline earth metal oxides, such as sodium oxide, potassium oxide, calcium oxide and magnesium oxide, and their respective carbonates and phosphates.
Particularly, the bioactive glasses of this embodiment include both alkali metal oxides (or their respective carbonates or phosphates, or a mixture thereof) and alkaline earth metal oxides (or their respective carbonates or phosphates, or a mixture thereof). As a general rule, the rate of solubility is increased by increasing the proportion of alkali metal oxides, and is decreased by increasing the proportion of alkaline earth metal oxides.
The second group of the additional additives, i.e., functional additives can be selected from organic or inorganic bioactive substances such as osteoconductive agents, antibiotics, chemotherapeutic agents, agents activating the healing of wounds, growth factors, bone morphogenic proteins and anticoagulants. Such agents provide the additional advantage of promoting tissue healing.
The third group of additional additives can be, for example, additives for facilitating processing of the material or for altering its properties, such as adhesion promoters, stabilizers, antioxidants and plasticizers, or for facilitating its handling, such as colorants.
Some preferred exemplary composite compositions include: - 78 wt-% or 50 wt-%(85 mol%L / 5 mol%D / 10 mol%G) PLDGA+ 22 wt-%TCP or 50 wt-%TCP, - 78 wt-% or 50 wt-%(85 mol%L / 10 mol%D / 5 mol%G)PLDGA + 22 wt-%TCP or 50 wt-%TCP, and - 78 wt-% or 50 wt-%(90mol%L / 5 mol%D / 5 mol%G)PLDGA + 22 wt-t%TCP or 50 wt-%TCP).
The composite is manufactured by mixing the ceramic additive with the composite matrix component. The additive can be used in any form, preferably as a powder, flakes, granules, cut-off fibers or continuous fibers. However, the addition of additive to the composite matrix component is preferably carried out with the components heated to a molten state (melt processing) or dissolved in a suitable solvent, such as an aqueous solution, more preferably with the polymeric matrix components in molten state.
After the addition of the additive to the composite polymer matrix component, the composite material is subjected to mechanical treatment step to form the final composite structure. This treatment step preferably includes injection molding, extrusion followed by machining and/or the use of some orientation technique, such as self-reinforcing.
The addition of the primary and/ or secondary additive components to the polymer matrix component can be carried out gradually, in several steps. However, the final content of additive in the composite, after addition of the final portion of additive, is 1 to 90 wt-%. Additional additives may be added in a selected step suitable for process methods used.
The mechanical treatment can be divided into two parts, whereby, in the first part, the polymer raw material, with additives, is melted with a continuous process, such as extrusion, or with a noncontinuous process, such as injection or compression molding, or maintained in a molten state after mixing its components. The melted material is cooled so that it solidifies to an amorphous or partially crystalline (crystallinity typically 0-60%) perform. The cooling is carried out, for example, inside a mold, on a cooling belt or in a cooling solution. A feasible way of carrying out the second part of the mechanical deformational treatment is by orientation. This optional orientation can be carried out using a temperature (T) that is above the glass transition temperature (Tg) of the polymer matrix material, but below its melting temperature, particularly if it is partially crystalline (semi-crystalline), and by drawing the above melt-processed, non-oriented billet or preform (such as a rod, a plate or a film) to a typical drawing ratio of 1.1 to 7 in the direction of the longitudinal axis of the preform, such as billet.
The drawing can be done freely by fixing the ends of the preform into fixing clamps of a drawing machine, tempering the system to the desired drawing temperature, and increasing the distance between the fixing clamps so that the preform is stretched and oriented structurally. This type of orientation is mainly uniaxial.
The drawing can also be done through a conical die, which can have, e.g., a circular, an ellipsoidal, a square, a star-like, a rectangular or other suitably shaped cross-section. When the cross-sectional area is circular like in the polymer billet, which is to be drawn through the die, is bigger than the cross-sectional area of the die outlet, the billet is deformed and oriented uni- or biaxially (or both) during drawing, depending on the geometries of the die and the billet. The ratio of the cross-sectional areas of the undrawn and drawn billet defines the draw ratio (DR or λ).
Also pushing deformation can be carried out, e.g. using a piston as an effective force. Further, it is possible to create orientation by shearing the flat billet between two flat plates, which glide in relation to each other, or by rolling a rod-like or plate-like preform between rollers, which flatten the preform to a desired thickness, simultaneously orienting the material biaxially. Heating can be used in all these methods.
As a result of the drawing, the molecular chains or parts thereof are directed increasingly to the draw direction, wherein the strength and toughness of the material are growing in the draw direction. After the drawing, the drawn billet is cooled under stress to room temperature, and can be further shaped into various surgical implants or other structures. Suitable processes for further shaping include machining, stamping, turning, milling, shearing, compression molding and thermoforming.
Toughening of composite materials described in the invention can be also attained, when the final products of this invention are manufactured by injection molding after which they may also contain flow induced orientation of polymer chains. This will result in more ductile mechanical behavior as described in Example 3 and Figure 2 of the invention.
The composites of the invention can be treated also by using so called solvent methods, wherein at least a part of the polymer matrix material is dissolved or dispersed into a suitable solvent and/or mixed with additives, or softened by the solvent and/or mixed with additives, whereafter the formed dispersion or paste is compressed into a suitably shaped object using pressure and, optionally, heat. The dispersed or softened composite and/or polymer matrix material then functions as a glue to maintain the given shape of the object, from which the solvent can be removed, e.g., by evaporating.
After finishing, cleaning and drying, the surgical devices of the present invention are ready for transportation and use. Thus, they can be packed, and the packages sealed. Since these products are to be used in surgery, they are also required to be sterilized before use.
The following non-limiting examples are intended to merely illustrate the properties of certain preferred embodiments of the invention.
Examples
Example 1
Various samples were prepared using the terpolymer 85 mol%L/5 mol%D/10 mol%G and from composites of said terpolymer and beta TCP. Mechanical properties of such composites are shown in the following Table 1.
Table 1
Example 2 A self-reinforced rod containing the terpolymer 85L/5D/10G PLDGA of Example 1 and 50 wt-% beta-TCP was subjected to manual bending in room temperature. This composite material of the invention could be shaped in room temperature without any additional equipment such a way without showing any signs of breaking or tearing (as shown in Figure 1).
Example 3
Injection molded composite samples composed of three different terpolymers (85L/10D,L/5G PLDGA, 75L/20D,L/5G PLDGA and 85L/5D/10G PLDGA) and 22-50 wt-% TCP was subjected to manual bending. The material could be shaped in such a way without showing any signs of breaking or tearing (as shown in Figure 2). 22 wt-% beta-TCP containing specimens could be bent to sharp angle and 50 wt-% beta-TCP containing specimens could be bent to mellow angle without any signs of breakage. After heating above glass transition temperature the test samples shrank, which indicate molecular orientation relaxation.
Example 4
Various composites were prepared by means of self-reinforcement and they were further shaped into suture anchors. The terpolymer used was 85L/5D/10G PLDGA and it was mixed with 0 wt-%, 22 wt-% and 50 wt-% TCP. The eyelet strength and the torsion yield strength of the resulting composites are shown in Figures 3 and 4.
Example 5
Various composites were prepared by means of injection molding into suture anchors. The terpolymers used were PLDGA, 75L/20D,L/5G PLDGA and 85L/5D/10G PLDGA and was mixed with 22 wt-% and 50 wt-% beta-TCP. The eyelet strength and the torsion yield strength of the resulting composites are shown in Figures 5 and 6.
Example 6 A terpolymer of the invention (85L/5D/10G PLDGA) was self-reinforced (DR=4.5). The biodegradation (particularly the rate of biodegradation) of the formed terpolymer structures was monitored. The degradation study was made in 37°C in phosphate buffer saline (PBS). During the degradation the shear strength and inherent viscosity of the structures was measured at different points of time. These formed structures of the invention showed strength retention over 18 weeks without remarkable strength loss. Results of shear strength and inherent viscosity during the degradation are presented in Tables 2 and 3.
Example 7 A terpolymer of the invention (85L/5D/10G PLDGA) was mixed with 22% ceramic (TCP) and self-reinforced (DR=4.5) into composite structures.
The same tests were carried out as in Example 6. These composite structures of the invention showed strength retention over 16 weeks without grammatical strength loss.
These composite structures of the invention showed strength retention over 16 weeks without remarkable strength loss. Results of shear strength and inherent viscosity during the degradation are presented in Tables 2 and 3.
Example 8 A terpolymer of the invention (85L/5D/10G PLDGA) was mixed with 22 wt-% ceramic (TCP) and self-reinforced (DR=4.4) into composite structures.
The same tests were carried out as in Examples 6 and 7. These composite structures of the invention showed strength retention over 20 weeks without grammatical strength loss.
These composite structures of the invention showed strength retention over 20 weeks without remarkable strength loss. Results of shear strength and inherent viscosity during the degradation are presented in Tables 2 and 3.
Example 9 A terpolymer of the invention (85L/5D/10G PLDGA) was mixed with 22 wt-% ceramic (TCP) and the resulting composite was self-reinforced (DR=2.5) into surgical structures.
The same tests were carried out as in Examples 6-8.These composite structures of the invention showed strength retention over 18 weeks without remarkable strength loss.
Example 10 A terpolymer of the invention (85L/5D/10G PLDGA) was mixed with 22% ceramic (TCP) and the resulting composite was self-reinforced (DR=2.5) into surgical structures.
The same tests were carried out as in examples 6-9. These composite structures of the invention showed strength retention over 22 weeks without remarkable strength loss.
Example 11 A terpolymer of the invention (85L/5D/10G PLDGA) was mixed with 50 wt-% ceramic (TCP) and the resulting composite was self-reinforced (DR=2.2) into surgical structures.
The same tests were carried out as in examples 6-10. These composite structures of the invention showed strength retention over 20 weeks without remarkable strength loss.
Example 12 A terpolymer of the invention (85L/10D,L/5G PLDGA) was mixed with 22 wt-% ceramic (TCP) and the resulting composite was injection molded into surgical structures.
The same tests were carried out as in examples 6-11. These composite structures of the invention showed strength retention over 6 weeks without remarkable strength loss.
Example 13 A terpolymer of the invention (85L/10D,L/5G PLDGA) was mixed with 22 wt-% ceramic (TCP) and the resulting composite was injection molded into surgical structures.
The same tests were carried out as in examples 6-12 .These composite structures of the invention showed strength retention over 6 weeks without remarkable strength loss.
Example 14 A terpolymer of the invention (75L/20D,L/5G PLDGA) was mixed with 22 wt-% ceramic (TCP) and the resulting composite was injection molded into surgical structures.
The same tests were carried out as in examples 6-13 .These composite structures of the invention showed strength retention over 6 weeks without remarkable strength loss.
Example 15 A terpolymer of the invention (75L/20D,L/5G PLDGA) was mixed with 22 wt-% ceramic (TCP) and the resulting composite was injection molded into surgical structures.
The same tests were carried out as in examples 6-14 .These composite structures of the invention showed strength retention over 6 weeks without remarkable strength loss.
Example 16 A terpolymer composite of this invention will demonstrate total biodegradation (i.e. total mass loss) within 1.5-4 years biodegradation in physiological conditions (Figure 7). The total biodegradation time depends on terpolymers chemical structure, amount of additive material, type of additive, temperature, moisture, patient related factors, etc.
Table 2. Shear strength of terpolymer composites during the degradation process_
Table 3. inherent viscosity of terpolymer composites during the degradation process_