Fused Filament Fabrication (FFF), a commonly used additive manufacturing technology, is now employed widely in biomedical fields for fabricating geometrically complex biodegradable devices. Structural voids arising from the printing process exist within the objects manufactured by FFF. This paper reveals the underlying mechanism of how the printing parameters and voids affect the degradation behaviours of devices made of biodegradable polyesters. It was found that both voids and internal architecture (layer height, for instance) affect the degradation rate by interacting with the reaction-diffusion process. Large suppression of the degradation rate was found when auto-catalytic hydrolysis and diffusion are significant. Degradation rate reduced in an approximately logarithmic manner as void size increased. The extent this effect depended on the strength of auto-catalytic hydrolysis and diffusion, void size and overall device size. The internal architecture of FFF products (regulated by printing parameters) influences the degradation rate by altering the diffusion speed of acid catalysts (regulated by diffusion path length). Both void size and internal architecture should be considered in fabricating biodegradable devices using FFF. STATEMENT OF SIGNIFICANCE: A geometric model that relates printing parameters with voids of FFF is developed to characterise the structure of FFF components. Such a model, when coupled with a degradation model, offers end-to-end simulation capability (e.g. from printing parameters to degradation rate) for predicting degradation properties. The model is validated against the in vitro degradation data obtained in this study. To our knowledge, the impact of printing parameters and voids on degradation is investigated here for the first time. It is found that both the void size and the internal architecture determined by the printing parameters play an essential role in regulating degradation behaviours.
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| http://dx.doi.org/10.1016/j.actbio.2021.09.020 | DOI Listing |
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