Data from: Computational biomechanical analyses demonstrate similar shell-crushing abilities in modern and ancient arthropods
The biology of the extant American horseshoe crab, Limulus polyphemus, is well documented—including its dietary habits, particularly the ability to crush shell with its gnathobasic walking appendages—but virtually nothing is known about the feeding biomechanics of this iconic arthropod. This species...
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Zusammenfassung: | The biology of the extant American horseshoe crab, Limulus polyphemus, is
well documented—including its dietary habits, particularly the ability to
crush shell with its gnathobasic walking appendages—but virtually nothing
is known about the feeding biomechanics of this iconic arthropod. This
species is also considered the archetypal functional analogue for a range
of extinct groups that have gnathobasic appendages, including eurypterids,
trilobites, and some of the earliest arthropods, especially Sidneyia
inexpectans from the middle Cambrian (508 million-year-old) Burgess Shale
of Canada. Exceptionally-preserved specimens of S. inexpectans show
intriguing evidence suggestive of durophagous (shell-crushing)
tendencies—including thick gnathobasic spine cuticle and shelly gut
contents—but this feeding mode has never been substantiated using advanced
computational techniques, such as Finite Element Analysis (FEA). Here we
present a unique application of 3D FEA by modelling the feeding mechanics
of L. polyphemus and S. inexpectans, representing the first such analysis
of a modern horseshoe crab, or indeed any fossil arthropod. Results show
that mechanical performance of the feeding appendages in both arthropods
is remarkably similar, confirming that S. inexpectans was a durophagous
predator. This biomechanical solution to processing shelled prey therefore
has a history extending over 500 million years, almost dating back to the
first appearance of shell-bearing animals themselves. The arrival of
durophagous predators such as S. inexpectans during the early phase of
animal evolution undoubtedly fuelled the Cambrian ‘arms race’ that
encompasses the rapid increase in diversity and abundance of
biomineralised prey species. |
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DOI: | 10.5061/dryad.d7s1183 |