Abstract
Porosity is recognized to play a key role in dictating the functional properties of bioactive scaffolds, especially the mechanical performance of the material. The mechanical suitability of brittle ceramic and glass scaffolds for bone tissue engineering applications is usually evaluated on the basis of the compressive strength alone, which is relatively easy to assess. This work aims to investigate the porosity dependence of the elastic properties of silicate scaffolds based on the 45S5 composition. Highly porous glass–ceramic foams were fabricated by the sponge replica method and their elastic modulus, shear modulus, and Poisson’s ratio were experimentally determined by the impulse excitation technique; furthermore, the failure strength was quantified by compressive tests. As the total fractional porosity increased from 0.52 to 0.86, the elastic and shear moduli decreased from 16.5 to 1.2 GPa and from 6.5 to 0.43 GPa, respectively; the compressive strength was also found to decrease from 3.4 to 0.58 MPa, whereas the Poisson’s ratio increased from 0.2692 to 0.3953. The porosity dependences of elastic modulus, shear modulus and compressive strength obeys power-law models, whereas the relationship between Poisson’s ratio and porosity can be described by a linear approximation. These relations can be useful to optimize the design and fabrication of porous biomaterials as well as to predict the mechanical properties of the scaffolds.
Highlights
IntroductionBioactive man-made materials show great promise in bone tissue engineering strategies as valuable and versatile options to replace transplant substances (autografts, allografts, and xenografts) for grafting [1]
Bioactive man-made materials show great promise in bone tissue engineering strategies as valuable and versatile options to replace transplant substances for grafting [1]
Scaffolds for bone repair should fulfill a set of physico-chemical and biological properties, including the high biocompatibility and the release of non-toxic by-products during dissolution or degradation in vivo, the capability to bond to living bone through a stable interface, and the similarity to host bone in terms of pore-strut architecture and mechanical characteristics [3]
Summary
Bioactive man-made materials show great promise in bone tissue engineering strategies as valuable and versatile options to replace transplant substances (autografts, allografts, and xenografts) for grafting [1]. These biomaterials are often produced 3D scaffolds, which act as templates to support and guide the regeneration of healthy tissue at the injured site [2]. Bioactive glasses are excellent candidates for making 3D scaffolds due to the fact of their versatility and exceptional capability of stimulating osteointegration and osteogenesis via the release of ionic dissolution products (primarily silicate and Ca2+ ions) that promote bone cell responses towards a path of regeneration and self-repair [5,6,7].
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