Comparative Analysis of Various Spider Silks in Regard to Nerve Regeneration: Material Properties and Schwann Cell Response

• Published in: Advanced healthcare materials Vol. 13; no. 8; pp. e2302968 - n/a
• Main Authors: Stadlmayr, Sarah, Peter, Karolina, Millesi, Flavia, Rad, Anda, Wolf, Sonja, Mero, Sascha, Zehl, Martin, Mentler, Axel, Gusenbauer, Claudia, Konnerth, Johannes, Schniepp, Hannes C., Lichtenegger, Helga, Naghilou, Aida, Radtke, Christine
• Format: Journal Article
• Language: English
• Published: Germany 01.03.2024
• Subjects: biomaterials; mechanical properties; migration; morphology; tissue engineering; transcriptomics; Mechanical Properties; Transcriptomics; Migration; Morphology; Biomaterials; Tissue Engineering
• ISSN: 2192-2640; 2192-2659
• DOI: 10.1002/adhm.202302968

Peripheral nerve reconstruction through the employment of nerve guidance conduits with Trichonephila dragline silk as a luminal filling has emerged as an outstanding preclinical alternative to avoid nerve autografts. Yet, it remains unknown whether the outcome is similar for silk fibers harvested from other spider species. This study compares the regenerative potential of dragline silk from two orb‐weaving spiders, Trichonephila inaurata and Nuctenea umbratica, as well as the silk of the jumping spider Phidippus regius. Proliferation, migration, and transcriptomic state of Schwann cells seeded on these silks are investigated. In addition, fiber morphology, primary protein structure, and mechanical properties are studied. The results demonstrate that the increased velocity of Schwann cells on Phidippus regius fibers can be primarily attributed to the interplay between the silk's primary protein structure and its mechanical properties. Furthermore, the capacity of silk fibers to trigger cells toward a gene expression profile of a myelinating Schwann cell phenotype is shown. The findings for the first time allow an in‐depth comparison of the specific cellular response to various native spider silks and a correlation with the fibers’ material properties. This knowledge is essential to open up possibilities for targeted manufacturing of synthetic nervous tissue replacement. Nerve guidance conduits prefilled with silk of Trichonephila spiders offer a promising alternative to autografts. However, the potential of fibers from other spider species remains unexplored. This study compares regenerative effects of silk from Trichonephila inaurata, Nuctenea umbratica, and Phidippus regius, revealing the influence of silk mechanics on cellular response. This offers novel possibilities for the fabrication of artificial nerve replacements.