Ecomorphology and ontogeny modulate the mechanical properties of shark skin

Details

• Journal Title:
  Acta Biomaterialia
• Personal Author:
  Hagood, Madeleine E. ; Alexander, Joseph R.S. ; Passerotti, Michelle ; Porter, Marianne E.
• NOAA Program & Office:
  NMFS (National Marine Fisheries Service) ; NEFSC (Northeast Fisheries Science Center)
• Description:
  Shark skin is a biological composite of dermal denticles embedded in a multilayered network of collagen fibers. Variation of skin morphology (dermal denticles and collagen fibers) is observable among species, body regions, and developmental stages, and has been shown to relate to skin mechanics. The orientation of collagen fibers results in mechanical anisotropy; shark skin is more extensible when stressed longitudinally (anteroposterior) and stiffer when stressed perpendicularly (dorsoventral). To evaluate the impact of ecological and ontogenetic factors on mechanical behavior, we tested shark skin in uniaxial tension to failure and calculated the tensile strain and mechanical properties (strength, stiffness, and toughness) from 20 species, and quantified the effects of ecomorphotype and ontogeny, as well as stress axis and body region. The bonnethead shark Sphyrna tiburo was used as a case study to quantify mechanics in a single species across an ontogenetic series. We analyzed skin morphology and correlated this with mechanical behavior to understand the mechanisms that regulate skin function. Across ecomorphotypes, shark skin from deeper-water, non-migratory species (Ecomorphotype E) was stronger and tougher than skin from small-bodied, non-migratory species (Ecomorphotype B), and medium-bodied, migratory species (Ecomorphotype C) had stiffer skin than large-bodied, migratory species (Ecomorphotype D). We found skin from mature sharks was stronger, stiffer, tougher, and more extensible than skin from pups. These results indicate that ontogeny and ecomorphotype impact skin mechanics among sharks. Despite morphological diversity, aspects of skin morphology appear to play less of a role in regulating mechanical function.
• Source:
  Acta Biomaterialia, 204, 470-486
• DOI:
  https://doi.org/10.1016/j.actbio.2025.08.002
• ISSN:
  1742-7061
• Format:
  pdf
• Publisher:
  Elsevier BV
• Document Type:
  Journal Article
• Rights Information:
  Accepted Manuscript
• Compliance:
  Submitted
• Main Document Checksum:
  urn:sha-512:562dfb5bc26101e46b92155a0c3e7ba382942ffeb41392ddaa64aab1c7bfec430f3d05c2c11524a52cef768c352d9cf4300ef6196d58bdc31b33670cec555ce8
• Download URL:
  https://repository.library.noaa.gov/view/noaa/71886/noaa_71886_DS1.pdf
• File Type:
  [PDF - 1.74 MB ]