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Driving macro-scale transformations in three-dimensional-printed biopolymers through controlled induction of molecular anisotropy at the nanoscale.

Laia Mogas-SoldevilaJorge Duro-RoyoDaniel LizardoGeorge G HollyerCharles M SettensJordan M CoxJohannes T B OverveldeElaine DiMasiKatia BertoldiJames C WeaverNeri Oxman
Published in: Interface focus (2024)
Motivated by the need to harness the properties of renewable and biodegradable polymers for the design and manufacturing of multi-scale structures with complex geometries, we have employed our additive manufacturing platform that leverages molecular self-assembly for the production of metre-scale structures characterized by complex geometries and heterogeneous material composition. As a precursor material, we used chitosan, a chemically modified form of chitin, an abundant and sustainable structural polysaccharide. We demonstrate the ability to control concentration-dependent crystallization as well as the induction of the preferred orientation of the polymer chains through the combination of extrusion-based robotic fabrication and directional toolpathing. Anisotropy is demonstrated and assessed through high-resolution micro-X-ray diffraction in conjunction with finite element simulations. Using this approach, we can leverage controlled and user-defined small-scale propagation of residual stresses to induce large-scale folding of the resulting structures.
Keyphrases
  • high resolution
  • drug delivery
  • single molecule
  • finite element
  • mass spectrometry
  • magnetic resonance imaging
  • high speed
  • atomic force microscopy
  • tandem mass spectrometry
  • monte carlo
  • dual energy