Abstract
The emergence of polylactide composites reinforced with bioresorbable silicate glass fibers has allowed for the long-term success of biodegradable polymers in load-bearing orthopedic applications. However, few studies have reported on the degradation behavior and bioactivity of such biocomposites. The aim of this work was to investigate the degradation behavior and in vitro bioactivity of a novel biocomposite pin composed of bioresorbable continuous glass fibers and poly-L-D-lactide in simulated body fluid for 78 weeks. As the materials degraded, periodic spiral delamination formed microtubes and funnel-shaped structures in the biocomposite pins. It was speculated that the direction of degradation, from both ends towards the middle of the fibers and from the surface through to the bulk of the polymer matrix, could facilitate bone healing. Following immersion in simulated body fluid, a bone-like apatite layer formed on the biocomposite pins which had a similar composition and structure to natural bone. The sheet- and needle-like apatite nanostructure was doped with sodium, magnesium, and carbonate ions, which acted to lower the Ca/P atomic ratio to less than the stoichiometric apatite and presented a calcium-deficient apatite with low crystallinity. These findings demonstrated the bioactivity of the new biocomposite pins in vitro and their excellent potential for load-bearing applications.
Highlights
IntroductionPrevious studies [2,3,4,5,6,7,8,9,10,11,12] introduced biomimetic composites for orthopedic applications which used biodegradable polymers blended with β-tricalcium phosphate (TCP), hydroxyapatite (HA), or bioactive glass
The mechanical behavior of such composites reinforced with silicate glass fibers [1] may be more suitable for load-bearing applications than similar polylactide composites reinforced with phosphate glass fibers [17,18] or 13–93 bioglass fibers [3], and poly(butylene succinate) reinforced with basalt fibers [19]
The objective of this study was to investigate the degradation mechanism and apatite formation of novel biocomposite pins made of poly-L -co-D -lactide (PLDLA) reinforced with bioresorbable continuous glass fibers in simulated body fluid for 78 weeks
Summary
Previous studies [2,3,4,5,6,7,8,9,10,11,12] introduced biomimetic composites for orthopedic applications which used biodegradable polymers blended with β-tricalcium phosphate (TCP), hydroxyapatite (HA), or bioactive glass. Totally bioresorbable composites consisting of silicate glass fibers in a biodegradable polylactide matrix have been introduced as novel orthopedic materials due to their advanced. Any successful resorbable orthopedic material should have sufficient mechanical properties to support the fracture, a degradation behavior matched to the healing rate of bone, and advanced bioactivity to promote the generation of new bone [20]
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