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Renewable and degradable materials, formed using biopolymers as material precursors, are sought after in pharmaceutical, biomedical, and industrial fields. Silk-based biomaterials, primarily derived from the silk fibroin protein of the Bombyx mori (B. mori) silkworm, have advantageous mechanical properties, biocompatibility, and commercial availability. Recent efforts aim to expand the range of achievable silk-based biomaterial properties via alternative sources of silk proteins with different sequences and structures. These structural distinctions drive differences in physical and chemical properties of silk fibers, primarily due to the varying degree of crystallinity in the polymers. For the development of alternative silk-based materials, silk from Plodia interpunctella (P. interpunctella), a small agricultural pest that infests and damages food products via silk production, is evaluated. Early investigations have highlighted differences between P. interpunctella and B. mori silk fibroin proteins, however P. interpunctella silk still largely lacks characterization and optimization on both the silk fiber and bulk material level. This work evaluates the structural, thermal, mechanical, and cell-material properties of non-degummed and degummed P. interpunctella silk as a raw material for biomaterial fabrication and discusses the benefits and limitations of these proteins as new biopolymers. Observed properties are used to identify links between silk fibroin protein sequence and fiber function in addition to forming hypotheses in how P. interpunctella silk-based biomaterials will perform in comparison to other natural biopolymers. Future work aims to develop methods to process P. interpunctella silk into material formats, utilizing the material characteristics determined here as a baseline for shifts in material performance.
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This content will become publicly available on March 7, 2026
Charting the envelope of mechanical properties of synthetic silk fibers through predictive modeling of the drawing process
A major challenge in synthesizing strong and tough protein fibers based on spider silk motifs is understanding the coupling between protein sequence and the postspin drawing process. We clarify how drawing-induced elongational force affects ordering, chain extension, interchain contacts, and molecular mobility through mesoscale simulations of silk-based fibers. We show that these emergent features can be used to predict mechanical property enhancements arising from postspin drawing. Simulations recapitulate a purely process-dependent mechanical property envelope in which order enhances fiber strength while preserving toughness. The relationship between chain extension and crystalline domain alignment observed in simulations is validated by Raman spectroscopy of wet-spun fibers. Property enhancements attributed to the progression of anisotropic extension are verified by mechanical tests of drawn silk fibers and justified by theory. These findings elucidate how drawing enhances properties of protein-based fibers and shed light on how to incorporate this effect into predictive models.
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- PAR ID:
- 10618375
- Publisher / Repository:
- PubMed
- Date Published:
- Journal Name:
- Science Advances
- Volume:
- 11
- Issue:
- 10
- ISSN:
- 2375-2548
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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