Structure and function of the median finfold in larval teleosts

Structure and function of the median finfold in larval teleosts

This paper offers a structural and mechanical analysis of the median finfold in larval teleosts. The median finfold is strengthened by bundles of collagen fibres, known as actinotrichia. We demonstrate that these structures contribute to increase the mass of backward accelerated water during swimmin...

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Bibliographic Details
Published in:Journal of experimental biology Vol. 215; no. Pt 14; pp. 2359 - 2368
Main Authors: van den Boogaart, Jos G M, Muller, Mees, Osse, Jan W M
Format: Journal Article
Language:English
Published: England 15-07-2012
Subjects:
Actinotrichia
allometric growth
Animal Fins - anatomy & histology
Animal Fins - cytology
Animal Fins - physiology
Animal Fins - ultrastructure
Animals
behavior
body-size
Carps - growth & development
Carps - physiology
Cyprinus carpio
Danio rerio
dermal skeleton
engraulis-mordax
Fibrillar Collagens - metabolism
fin
fish larvae
hydrodynamics
Larva - anatomy & histology
Larva - cytology
Larva - physiology
Larva - ultrastructure
Models, Biological
Swimming - physiology
Teleostei
zebrafish
Zebrafish - anatomy & histology
Zebrafish - growth & development
Zebrafish - physiology
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Summary:This paper offers a structural and mechanical analysis of the median finfold in larval teleosts. The median finfold is strengthened by bundles of collagen fibres, known as actinotrichia. We demonstrate that these structures contribute to increase the mass of backward accelerated water during swimming. The amount, dimensions, orientation and growth of actinotrichia were measured at various locations along the finfold in several developmental stages of common carp (Cyprinus carpio) and zebrafish (Danio rerio). Actinotrichia morphology, using light microscopy (e.g. diameter, orientation) and electron microscopy (which revealed their anchoring at proximal and distal ends), correlated with expected lateral forces exerted on the water during swimming. An analytical model is proposed that predicts the extent of camber from the oblique arrangement of the actinotrichia and curvature of the body. Camber of the finfold during swimming was measured from high-speed video recordings and used to evaluate the model predictions. Based on structural requirements for swimming and strain limits for collagen, the model also predicts optimal orientations of actinotrichia. Experimental data confirm the predictions of the model.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0022-0949
1477-9145
DOI:10.1242/jeb.065615