Bioresorbable Nanocomposite Foams for Bone Tissue Engineering

Claire Diane Delabarde
EPFL, 2011
EPFL thesis

Abstract

The present work forms part of an ongoing effort at the Laboratory of Polymer and Composite Technology (LTC) to develop novel solvent-free processing methods for next generation resorbable porous scaffolds for bone replacement, based on supercritical carbon dioxide (CO2) foaming. Although adequate mechanical performance and in vitro biocompatibility have been demonstrated for such scaffolds and results from in vivo testing have been promising, osteoconduction and osteogeneration remain inadequate. The approach proposed here is to use highly dispersed synthetic poly-L-lactide (PLLA)/bioceramic nanocomposites, in which the modifier particles are comparable in size and composition to those in natural bone, combined with targeted surface treatments, as a means of enhancing the osteoconductivity of the scaffolds. The investigation has covered: (i) the preparation, basic structure-property relationships and resorption behavior of the nanocomposites; (ii) the optimization of processing parameters for the production of porous nanocomposite scaffolds by supercritical CO2 foaming; (iii) the in vitro and in vivo response of the scaffolds with emphasis on the influence of selected surface treatments. The bulk of the work involved hydroxyapatite nanoparticle fillers (nHA), although some attention was also given to nanoparticles prepared from Bioglass® (nBG), which has been reported to show superior osteoconduction and osteinduction to hydroxyapatite. Mechanical mixing with a miniature twin screw extruder was found to give excellent dispersions of certain grades of nHA in the PLLA matrix without the need for an organic solvent or surfactants. Initial studies of the crystallization behavior of the resulting PLLA/nHA nanocomposites showed nHA addition to result in a decrease in spherulite growth rates but an increase in nucleation density, leading to a significant increase in the global crystallization rates. Addition of nHA particles also resulted in increases in the rate of mass loss during in vitro ageing of bulk films, identified with accelerated resorption at the matrix/particle interfaces. However, the tensile strengths and strains to fail were significantly higher in the aged films in the presence of nHA, which indicated the nHA to act as an effective toughener of the bulk material and hence to retard the loss in tensile strength during resorption. It was also shown that the initial presence of a coarse spherulitic morphology may be deleterious to mechanical performance during ageing, owing to large scale internal cracking associated with the spherulite radii. Finally, the accelerated ageing treatments used for the resorption tests were found to result in significantly increased hydrophilicity and, in the case of the PLLA/nHA nanocomposites, significant pitting at the scale of the nanoparticles and increased nanoparticle concentrations at the film surfaces, suggesting that such treatments may also be beneficial for the interactions between the nanocomposites and bone cells during implantation. In foams prepared by supercritical CO2 processing using a new dedicated autoclave designed specifically for this purpose, the addition of nHA resulted in reduced foam cell sizes and improved homogeneity in the cell size distribution, but did not significantly affect the degree of crystallinity, which remained of the order of 50 wt% in all the foams. Indeed, the compressive modulus and strength were found to be primarily influenced by the porosity of the foams regardless of the nHA content. Even so, the mechanical properties of the foams were comparable with those of trabecular bone, and by adjusting the saturation pressure and depressurization rate it was possible to generate porosities of about 76 %, an interconnected morphology and cell diameters in the range 200-400 µm from PLLA containing 10 wt% nHA, satisfying established geometrical requirements for bone replacement scaffolds. On the basis of the resorption studies and comparison with other potential surface treatments, selected scaffolds were also aged in aqueous NaOH in an attempt to improve cell-scaffold affinity. After 8 weeks of implantation in vivo in rat femoral condyles, growth of new bone was confirmed to be significantly enhanced in the NaOH treated PLLA/10 wt% nHA scaffolds, as compared with untreated controls and previous generation scaffolds containing βTCP microparticles. The results of these pre-clinical studies are considered to be highly promising, although they remain to be completed and extended to large animal models.

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Claire Diane Delabarde
EPFL, 2011
EPFL thesis

Abstract

Official source

https://infoscience.epfl.ch/record/166130?ln=en

About this result

Related concepts (31)

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Related publications

Articular cartilage is a soft tissue that covers the ends of articulating bones, and is essential for maintaining joint motion, i.e. translation and rotation between the bones. Articular cartilage nevertheless has a limited capacity for self-repair, and cartilage lesions following traumatic injury may consequently initiate an irreversible degenerative process. This ultimately leads to progressive loss of joint function, pain and medical costs. Many different clinical treatments have been investigated, but these have not so far led to satisfactory long-term solutions. Tissue engineering research has therefore focused on the preparation of synthetic bioresorbable scaffolds that provide a template for cells and guide the process of tissue regeneration. In the present study, it is proposed to develop an osteochondral scaffold using novel solvent-free processing methods based on supercritical carbon dioxide (CO2) foaming. The approach is first to tailor the mechanical properties of medical grade polylactides (PLA), using poly(ethylene glycol) (PEG) as a plasticizer, to produce scaffolds with reduced elastic moduli intended for cartilage repair. These polymer scaffolds are then combined with an existing biocomposite scaffold (PLLA/bioceramic), developed for bone repair, to give a bilayered scaffold suitable for osteochondral repair. The investigation thus covers: (I) the preparation of plasticized polylactide and the dependence of its properties on composition; (II) the design of processing windows for the production of porous plasticized polylactide scaffolds by supercritical CO2 foaming; (III) the preparation of hybrid structures with gradients in composition and properties, and tailored interfaces; (IV)the properties and in vitro response of sterilized scaffolds. Plasticization of semicrystalline poly-L-lactide (PLLA) with PEG reduces Tg to below 37 °C, depending on the composition, implying the amorphous regions to be in the rubbery state at body temperature. While immersion in an aqueous medium tends to promote phase separation in blends containing low molar mass PEG, relatively good stability is observed with PEG with a molar mass of 35,000 g/mol. It has thus been possible to prepare interconnected, open-pore foams with porosities of more than 75 %, cell diameters in the range 200 to 700 pm and compression moduli of a few MPa. It was also observed that addition of PEG resulted in foams with increased pore diameters and lower foam densities than the neat polylactide, but also increased pore coalescence at high saturation pressures, effects that were accounted for by the large decrease in melt viscosity on addition of PEG. Furthermore, the compression moduli of the foams were shown to be strongly reduced on addition of PEG, which was assumed to be a direct consequence of the plasticization of the polylactide by PEG and the accompanying decrease in glass transition temperature, implying the amorphous content to be in the rubbery state at in vivo temperature, as required. Thus, foams with moduli ranging from 0.3 to 15 MPa could be prepared from the different PLA/PEG blends and copolymers studied. Bilayered scaffolds were produced by assembling the plasticized foams with a biocomposite foam using an adapted fusion bonding method. This allowed control of interfacial properties such as the bonding strength, and the interface density and permeability. These hybrid scaffolds exhibited well-defined layers with suitable properties for the repair of bone and cartilage, respectively. Finally, X-ray and y irradiation was shown to strongly degrade the polymer matrix. However, it was found that treatment with ethylene oxide gas could be used to sterilize the scaffolds without significantly modifying their properties, or compromising their biocompatibility, as borne out by in vitro tests. The approach proposed in this work was hence concluded to be highly promising for cartilage repair, and the resulting hybrid osteochondral scaffolds are ready for the next stage of the developmental work, which will consist of extended in vivo studies.

EPFL2012

The aim of this study has been to develop processing techniques for novel bioresorbable thermoplastic cellular composites, reinforced with continuous inorganic fibres, for use as biodegradable scaffolds for bone tissue engineering. As the implanted composite scaffold starts to degrade, it should be progressively replaced by natural bone tissue, which should consequently support increasing proportions of the applied mechanical loads. In order to simulate natural high performance porous structures such as bone or light wood, composites with simultaneous gradients in fibre content and porosity were studied. In order to carry out investigations over wide ranges of fibre content and porosity and to ensure biocompatibility and bioresorbability, it was decided to focus on foamable poly(L-lactic acid) (PLA) and continuous glass fibres. As well as improved mechanical reinforcement due to the high aspect ratio, the use of continuous glass fibres offers the possibility of achieving higher loadings than with short fibres or particles, increasing the potential range of mechanical properties. For processing the composites, a fibre winding technique developed in house was used to prepare unidirectional preforms with gradient structures tailored at the fibre bundle level. PLA fibre bundles, containing 36 monofilaments were prepared on a spinning line, and mingled with glass fibre bundles comprising 250 or 1000 monofilaments. During the winding process, the PLA fibres were intimately mixed with the reinforcing fibres, to ensure a good impregnation during subsequent processing steps. Moreover it was possible to maintain the relative positions of the fibres during pre-consolidation of graded composites. The resulting preforms had a porosity of 25% and could be further consolidated to decrease the porosity, or foamed in an autoclave to obtain cellular composites (foams) with porosities of up to 90%. It was observed that, independently of the applied foaming conditions, the presence of continuous fibres reduced the porosity by an amount equivalent to twice the fibre volume fraction. This processing method provided composites with a simultaneous gradient in fibre content and porosity. In order to predict the Young's modulus and the collapse strength of the cellular composites a model was proposed, which combines the buckling of composite columns within a porous structure with the property predictions for neat polymer foams. In neat foams with a porosity of 60%, the Young's modulus was calculated to be 0.25 GPa. By adding a fibre volume fraction of 14% the modulus reached 1.2 GPa. The respective collapse strengths were 5 MPa and 16 MPa. Experimental results were consistent with the predictions and validated the model. The model determines the fibre content required for composites with a given porosity and stiffness. Gradient cellular composites were obtained with a range of porosity between 50% to 90% and a range of stiffness between 100 and 1500 MPa. Furthermore the processing parameters can be adjusted to maintain a desired porosity when fibres are added. Thus, composites that fulfill the mechanical requirements for bone scaffolds can be achieved in a rational manner. The long term behaviour of the foams was tested under physiological conditions. Viscoelasticity tests provided evidence for the important role of the unidirectionally oriented fibres. Whereas the cells in neat foams collapsed after at most two days when loaded at 0.69 MPa, the fibre reinforced foams resisted longer and their creep strain was well described by a power law. The fatigue properties were compared to reported values of natural trabecular bone. None of the neat foams with a porosity of 74% resisted to the first load cycle of 7.3 MPa. With a fibre volume fraction of 11% and a comparable porosity of 72%, the composite scaffolds resisted for at least 11'000 loading cycles. To compare, trabecular human bone failed after 1909 cycles, when loaded with 8.5 MPa. It was concluded that the reinforced composites have the potential to replace natural bone. Preliminary in vitro results with human foetal osteoblasts and in vivo tests on femurs of rats were promising because the cells proliferated well on the composite substrates. Further investigations for applications in bone tissue engineering can be planned. Furthermore, the studied process and the obtained results are envisaged for other material systems to prepare cellular composites for novel lightweight applications in transportation and building industry.

EPFL2008

Fiber reinforced polypropylene nanocomposites

Chrystèle Houphouet-Boigny Favre

The aim of this thesis is to assess the feasibility of integrating nanoparticles into glass fiber (GF) reinforced isotactic polypropylene (iPP) composites via existing thermoplastic processing routes, and to investigate whether this results in significant improvements in the mechanical properties of the final composites. A longer term aim will be to extend the approach to the preparation of hybrid composites with added non-structural functionality. However, the nanoparticles that have provided the focus for the present project, montmorillonite layered silicates (MMT) and nanocarbons, were chosen for their potential as structural reinforcing elements. A melt-spinning grade and a film grade of iPP were used to prepare iPP-based nanocomposite precursors in the form of melt-spun fibers and extrusion-calendered films respectively. Long glass fiber (LGF) and glass mat thermoplastic (GMT) composites were then compression-molded from co-woven, co-wound and intercalated semi-finished products. The processing behavior and structural performance of the resulting composites are discussed in terms of the matrix morphology and its influence on the matrix rheological and mechanical properties, and interactions between the matrix and the reinforcing fibers. The nanocomposites were prepared by either (i) combined solvent and melt-mixing or (ii) direct melt-mixing. Combined solvent and melt-mixing was more suitable for dispersing carbon nanofibers (CNF), which tended to agglomerate. With iPP/MMT, both routes gave a mixed intercalated-exfoliated morphology with an MMT interlayer spacing up to 57 % greater than in the as-received MMT. However, direct melt-mixing was considered to be better suited to industrial requirements, and also more convenient for laboratory scale preparation. Melt-compounded iPP/MMT injection moldings showed a monotonic increase in stiffness with increasing MMT content, a 40 % increase in tensile modulus being measured at 13.5 wt% MMT, for example. The tensile strength, on the other hand, reached a maximum 10 % increase over that of the pure iPP at about 3 wt% MMT, but fell off at higher MMT contents. iPP/MMT and iPP/CNF fibers were melt-spun using a laboratory-scale industrial spinning line. Processability was consistent with the melt rheology, the maximum MMT content for which fiber spinning was possible being about 5 wt%. The MMT platelets were aligned with the fiber axis over the whole range of MMT loadings and fiber draw ratios. MMT particle aspect ratios of about 150 were observed by TEM in this case, i.e. greater than in the as-compounded iPP/MMT, for which the particle aspect ratios were about 50. An aspect ratio of 150 was found to be consistent with micromechanical modeling of the observed increases in fiber stiffness with MMT content, which reached 170 % for iPP/2 wt% MMT fibers melt-spun with a draw ratio of 1 and a drive-roll velocity of 360 m/min. The tensile strength again reached a maximum at about 3 wt% MMT. The thermal stability of the fibers, determined by thermal mechanical analysis, also increased on MMT addition, the onset of extensive fiber creep shifting from 90 °C for pure iPP fibers to about 110 °C for iPP/1.1 wt% MMT fibers. Moreover, significantly reduced shrinkage was observed in the presence of MMT, which is a potential advantage for textile based composite processing. In the case of iPP/CNF fibers, limited particle orientation and the presence of aggregates in all the formulations led to relatively poor tensile properties, about 50 % lower than those obtained with iPP/MMT fibers melt-spun with the same filler content (4 wt%) and processing conditions. iPP/MMT therefore provided the main focus for subsequent work. iPP/MMT films were produced by extrusion-calendering. Partial orientation of MMT platelets in the melt flow direction resulted in anisotropic stiffness and strength. However, both the tranverse and axial stiffnesses increased with MMT content, with improvements of up to 75 % at 5.9 wt% MMT with respect to those of the pure iPP films, consistent with Halpin-Tsai predictions for composites containing oriented platelets with the observed aspect ratio of 50. The fracture resistance of the films, determined using modified essential work of fracture (EWF) tests, was likewise strongly dependent on the testing direction. For axial crack propagation, the EWF decreased monotonically with MMT content, but for transverse crack propagation, it reached a maximum at about 3 wt% MMT. This was attributed to orientation dependent cavitation and crack deviation in the presence of the MMT particles. Rheological measurements indicated increases in the low shear rate melt viscosity by up to two orders of magnitude on MMT addition to the iPP, with a potentially significant influence on the impregnation behavior of composite preforms. For co-woven and co-wound LGF-matrix fiber preforms, impregnation was highly dependent on the fiber bed geometry. For 40 vol% glass fiber co-wound composites, the porosity increased from about 7 vol% for a pure iPP matrix compression molded at 0.6 MPa, to 14 vol% for a iPP/3.4 wt% MMT matrix compression molded at 1.8 MPa. However, the more intimate mixing between the fibers obtained in co-woven preforms led to more consolidated composites in each case (below 2 vol% porosity) with no filtering of the MMT particles. In modeling the impregnation kinetics of glass mat thermoplastic composites (GMT) based on iPP/MMT, the matrix was therefore considered to behave as a continuum and, for simplicity, to show Newtonian behavior. Consistent results were obtained, but in the presence of MMT, higher impregnation times were predicted than observed experimentally in model GMT preforms, owing to the nonlinear response of the nanocomposites. Moreover, under experimental conditions corresponding to the industrial process (0.2 MPa at 200 °C), iPP/5.9 wt% MMT-based hybrid composites were fully impregnated (porosity between 11 and 17 vol%) and the glass mat completely relaxed after about 30 s of compression molding, which is consistent with typical GMT industrial process cycle times (20 - 60 s). Fully consolidated 30 wt% GF - hybrid GMT specimens were prepared for mechanical testing by compression molding at 2 MPa and 200 °C for 10 min, resulting in a porosity of about 2 vol%. At room temperature, the flexural modulus and strength of iPP/MMT-based GMTs increased monotonically with MMT addition, the increases reaching about 45 % and 33 % respectively at 5.9 wt% MMT. The increase in the flexural modulus on MMT addition was greater than predicted on the basis of a conventional rule of mixtures taking into account glass fiber orientation and aspect ratio, and the measured Young's moduli of the matrix. This was tentatively attributed to improvements in the flexural properties of the matrix in the presence of the MMT higher than those observed in tension. Increases in the flexural modulus and strength were also observed at 50 °C and 90 °C, but were less marked than at room temperature. The impact strength of the hybrid composites decreased with increasing MMT content at room temperature owing both to the decrease in matrix fracture resistance inferred from the data for the precursor films, and to an improved fiber-matrix interface as reflected by SEM observations, and argued to be due to the presence of coupling agents. Given that the presence of MMT was shown not to have serious consequences for impregnation, taken as a whole these results are considered highly promising for the implementation of nanocomposite matrices in GMT, and to establish the general feasibility of producing hybrid fiber reinforced thermoplastic nanocomposites by conventional processing routes.

EPFL2007

EPFL2008

EPFL2012

Fiber reinforced polypropylene nanocomposites

Chrystèle Houphouet-Boigny Favre

EPFL2007