posted on 2016-05-05, 11:28authored byAndrew Gleadall, Jingzhe Pan, Marc-Anton Kruft
Atomic simulations were undertaken to analyse the effect of polymer chain scission on amorphous poly(lactide) during degradation. Many experimental studies have analysed mechanical properties degradation but relatively few computation studies have been conducted. Such studies are valuable for supporting the design of bioresorbable medical devices. Hence in this paper, an Effective Cavity Theory for the degradation of Young's modulus was developed. Atomic simulations indicated that a volume of reduced-stiffness polymer may exist around chain scissions. In the Effective Cavity Theory, each chain scission is considered to instantiate an effective cavity. Finite Element Analysis simulations were conducted to model the effect of the cavities on Young's modulus. Since polymer crystallinity affects mechanical properties, the effect of increases in crystallinity during degradation on Young's modulus is also considered. To demonstrate the ability of the Effective Cavity Theory, it was fitted to several sets of experimental data for Young's modulus in the literature.
Funding
Andrew Gleadall acknowledges an EPSRC PhD studentship and a partial PhD studentship from the University of Leicester.
History
Citation
Journal of the Mechanical Behavior of Biomedical Materials, 2015, 51, pp. 237–247
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Engineering
Version
AM (Accepted Manuscript)
Published in
Journal of the Mechanical Behavior of Biomedical Materials
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