Liquid CO2 processing of solid polylactide foam precursors

Diffusion of CO2 in polylactide was modelled by assuming the diffusion coefficient to depend on CO2 concentration, c, according to D[c]=D[0]exp[Ac], where D[0] and A are empirical constants, with the aim of optimizing impregnation of nominally amorphous and semicrystalline polylactide/CO2-based precursors for physical foaming. Numerical simulations provided a consistent description of desorption at different temperatures, T, from polylactide impregnated with liquid CO2 at 10? and 5MPa, and D[0,T] could be represented analytically using Arrhenius or Williams-Landel-Ferry-type expressions, allowing interpolation and extrapolation. Sorption was argued on this basis to involve a step-like diffusion front, such that the CO2 content of a plate of thickness l increased as (D[0]t)(1/2)l(-1)F[Ac-o], where c(o) is the value of c at saturation and F is a function of Ac-o only. A major practical concern with polylactide/CO2 precursors is that the glass transition temperature, T-g, decreases strongly with c, so that amorphous polylactide saturated with CO2 at 10? and 5MPa degasses spontaneously at room temperature and pressure. However, it was inferred from the models and confirmed experimentally that partial impregnation in liquid CO2 for relatively short times could provide a relatively rapid means of preparing precursors with a roughly uniform CO2 content of around 0.1g/g that were stable with respect to rapid CO2 loss on heating to room temperature. The resulting precursors gave satisfactory foam morphologies and densities on foaming at 100?. Moreover, it was also possible to adapt the impregnation conditions so as to obtain partially foamed structures from semicrystalline polylactide under these conditions, in spite of its tendency to undergo cold crystallization during impregnation in liquid CO2, which suppressed expansion of saturated specimens at 100?.

Hybrid Polymer Foams for Osteochondral Tissue Engineering

Matthieu Cuénoud

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

Processing of Sustainable Cellular Biocomposites

Carole Boissard

Petroleum-based polymers and composites are commonly used in a wide variety of application fields. However ecological concerns, increasing oil prices and dwindling natural resources explain why nowadays industrial and public interest is more than ever focused on new bio-based – “greener”- products. In order to find viable substitutes for petroleum-based materials, major efforts are devoted to the development of sustainable solutions combining fully compostable matrices and fibres from renewable resources. Polylactide (or polylactic acid) (PLA) is currently one of the most versatile biodegradable polymers derived from renewable resources such as non-food crops of corn or sugar cane. Its transformation into foamed cellular structures would decrease its density and at the same time may improve its specific mechanical properties. This could provide cost-effective and sustainable products for packaging and construction. In the context of developing “green” foams, the focus in the present work has been on a solvent-free process based on physical foaming with supercritical carbon dioxide (ScCO2) as a foaming agent. This foaming process includes thermally driven but kinetically controlled phenomenon. Solubility and diffusion of the gas in the molten polymer, cell nucleation and growth, as well as stabilization of the final foam structures were studied for neat and composite materials. At low processing temperatures and low depressurization rates, homogeneous structures were obtained thanks to a balance between cell growth mechanisms and cell stabilization, thus limiting uncontrolled cell coalescence. The density of the resulting polylactide foams ranged from 0.12 to 0.3 g/cm3 with corresponding compression moduli of 6 to 73 MPa respectively. The processing windows were strongly dependent on the rheological melt properties of the PLAs. PLA is generally considered to be a high strength, high modulus thermoplastic but its brittleness has limited its industrial use. PLA was therefore combined with wood fibres (WF) and microfibrillated cellulose (MFC) in order to improve its mechanical performance without compromising its environmental impact. Two compounding methods, a wet mixing papermaking-like process and a solvent casting process were investigated for the production of WF/PLA and MFC/PLA biocomposites. Degradation of PLA occured during wet-mixing, due to the water used as a dispersant, and to several heating steps applied during compounding. Improvement of the drying and processing conditions and/or the replacement of water by isopropanol limited this degradation. The presence of cellulose fibres considerably modified foaming mechanisms; gas solubility was decreased and the coefficient of diffusion increased, leading to lower quantities of CO2 available for foaming. In addition, stiffness of the fibre network impeded full expansion of the polymer matrix. Thus smaller cells were created. Densities from 0.15 (neat PLA) to 0.37 and 0.55 g/cm3 and moduli ranging from 35 (neat PLA) to 125.5 and 373 MPa were obtained by the addition of 5wt% WF and MFC respectively. Addition of a chain extender enabled viscosity of the matrix to be increased causing increased orientation of the fibre network during flow and hence fibre alignment in the cell walls. Density was thus decreased by 95 % to 0.017 g/cm3 and compression modulus decreased to 0.32 MPa for 5wt% WF composite. Cell wall shrinkage was observed in the neat PLA foams obtained with the chain extender. This was reduced by adding wood fibres while maintaining similar density and modulus. Cellulose fibres act as an extra scaffold in the cellular structures. Industries are currently considering the use of these materials for applications in packaging e.g. as cushioning materials, or in architecture as display panels, or as sandwich core materials for the replacement of expanded polystyrene, polyvinyl chloride or polyurethane foams.

EPFL2012

Plasticization of polylactide foams for tissue engineering

Pierre-Etienne Bourban, Matthieu Cuénoud, Jan-Anders Månson, John Christopher Plummer

Supercritical CO2 foaming of amorphous and semicrystalline polylactides plasticized by blending with 20 wt% polyethylene glycol has been investigated as a means of producing low-stiffness bioresorbable scaffolds for tissue engineering. For a given set of foaming parameters, the presence of polyethylene glycol generally resulted in a significant reduction in foam density and increased cell diameters, effects that could be accounted for by a large decrease in melt viscosity with respect to that of the pure polylactides. The compression moduli of plasticized foams under simulated physiological conditions (immersion in deionized water at 37 degrees C)were also substantially lower than those of the neat foams. This was attributed primarily to a decrease in the glass transition temperature from about 60 degrees C for the pure polylactides to about 30 degrees C on addition of the polyethylene glycol, implying the blends to be in the rubbery state at the test temperature of 37 degrees C. Under the conditions investigated, the processing window for homogeneous foams was found to be wider for blends based on semicrystalline polylactides than for blends based on amorphous polylactides. However, by tailoring the processing parameters, open cell architectures with porosities of more than 75% and cell diameters in the range 200 to 700 mu m could be achieved in both types of blend. Such morphologies have already been shown to be suitable for bone repair and, when combined with a low-stiffness matrix, may offer exciting new possibilities for applications in soft tissue engineering, such as cartilage repair.

SAGE Publications2012

Hybrid Polymer Foams for Osteochondral Tissue Engineering

Matthieu Cuénoud

EPFL2012

Processing of Sustainable Cellular Biocomposites

Carole Boissard

EPFL2012