MECHANICAL PROPERTIES AND LOCOMOTOR FUNCTIONS OF EEL SKIN

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Biol Bull 158: 58-68. (February 1980)
© 1980 Marine Biological Laboratory

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MECHANICAL PROPERTIES AND LOCOMOTOR FUNCTIONS OF EEL SKIN

MARY REIDY HEBRANK ¹

¹ Department of Zoology, Duke University, Durham, North Carolina 27706

1. The skin of the American eel Anguilla rostrata is composedlargely of a crossed-helical array of fibers, believed to becollagen, that are oriented at an angle of 45° with thelong axis of the fish. Uniaxial and biaxial tension testingof eel skin was used to assess the role of the collagen fibersin the locomotor functions of the skin.

2. The elastic modulusof skin stressed in the circumferential direction of the fishis 14.6 MN/m² while that of skin stressed in the longitudinaldirection is 3.5 MN/m², thus eel skin is an order of magnitudestiffer in the circumferential than in the longitudinal direction.The skin is stiffest in the direction of the fibers, havingan elastic modulus of 0.16 GN/m² in this direction. Within therange of in vivo extensions the behavior of skin stressed inthe longitudinal direction is similar to that of a model consistingof continuous crossed-fibers, while that of skin stressed inthe circumferential direction is not.

3. The mechanical behaviorof the skin indicates that the skin may act as an external tendon,transmitting forces arising in the axial musculature down thelength of the fish to the tail.

4. The collagen fibers withinthe skin may play an important role in torsion resistance whenthe eel executes its peculiar "corkscrew" motion.

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