Abstract
A thorough hydrodynamic approach to the study of swimming in amphipods demands a multipronged attack. A possible first step would be to gather swimming behavior data and determine the biomechanics and kinematics of pleopod beat. This requires careful observation of the swimming modes, swimming speeds, body positions and other aspects of behavior and limb motion that are crucial to swimming. Secondly, it is important to describe the morphology of the body and swimming appendages. Detailed drawings of body shape and design, skeletomusculature, condylic structure, and setal density and distribution on the pleopods and pereopods, are the tools required to ascribe hydrodynamic function to specific limb and body morphology. Finally, the information gathered from behavioral observations bolstered by functional morphology studies is applied to fluid dynamic calculations of drag, lift, and thrust. The theoretical calculations are then compared with empirical determinations of drag, wake generation, vortex shedding frequency, and flow patterns around an amphipod. The fluid dynamic facet of this research is the most challenging and requires an excellent grasp of the fundamental concepts of fluid flow and access to some highly technical equipment. The proposed tripartite approach for the study of amphipod swimming is by no means an exhaustive review of all the techniques that can be employed to quantify amphipod swimming. It will nevertheless permit a rigorous and systematic study of amphipod swimming.
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References
Adams, J. & P. J. Greenwood, 1987. Loading constraints, sexual selection, and assortative mating in peracarid Crustacea. J. Zool. Lond. 211: 35–46.
Barnard, J. L., 1969. The families and genera of marine Gammaridean Amphipoda. Bull. U.S. Nat. Mus. 271: 535 pp.
Batchelor, G. K., 1967. An introduction to fluid dynamics. Cambridge University Press, London.
Blake, R. W., 1979. The mechanics of labriform locomotion I. Labriform locomotion in the angelfish (Pterophyllum eimekei): an analysis of the power stroke. J. exp. Biol. 82: 255–271.
Blake, R. W., 1980. The mechanics of labriform locomotion II. An analysis of the recovery stroke and the overall fin-beat cycle propulsive efficiency in the angelfish. J. exp. Biol. 85: 337–342.
Blake, R. W., 1981. Influence of pectoral shape on thrust and drag in labriform locomotion. J. Zool., Lond. 194: 53–66.
Blake, R. W., 1983. Mechanics of drag-based mechanisms of propulsion in aquatic vertebrates. IN M. H. Day (ed.), Vertebrate Locomotion. Academic Press, London, Symp. Soc., Lond. 48: 29–52.
Blake, R. W., 1986. Hydrodynamics of swimming in the water boatman, Cenocorixa bifida. Can. J. Zool. 64: 1606–1613.
Blevins, R. D., 1984. Applied fluid dynamics handbook. Van Nostrand Reinhold Company, New York.
Boudrias, M. A., 1987. Effects of current velocity on the swimming behavior of a gravel beach amphipod Paramaera mohri. Am. Zool. 27: 81A (Abstract 416).
Boudrias, M. A., 1988. Locomotion in deep-sea amphipods: body design and functional morphology of swimming appendages. Am. Zool. 28: 3A (Abstract 7)
Boudrias, M. A., 1989. Swimming limb mechanisms in Amphithoe humeralis (Crustacea: Amphipoda). Am. Zool. 29: 130A (Abstract 580).
Bousfield, E. L., 1973. Shallow-water Gammaridean Amphipoda of New England. Cornell University Press. London, 312 pp.
Cheer, A. Y. L. & M. A. R. Koehl, 1987a. Fluid flow through filtering appendages of insects. IMA J. Math. Applied Med. & Biol. 4: 185–199.
Cheer, A. Y. L. & M. A. R. Koehl, 1987b. Paddles and rakes: fluid flow through bristled appendages of small organisms. J. Theor. Biol. 129: 17–39.
Cowles, D. L., J. J. Childress & D. L. Gluck, 1986. New method reveals unexpected relationships between velocity and drag in the bathypelagic mysid Gnathophausia ingens. Deep-Sea Res. 33: 865–880.
Daniel, T. L., 1984. Unsteady aspects of aquatic locomotion. Am. Zool. 24: 121–134.
Fincham, A. A., 1972. Rhythmic swimming and rheotropism in the amphipod Marinogammarus marinus (Leach) J. exp. mar. Biol. Ecol. 8: 19–26.
George, R. Y., 1979a. Behavioral and metabolic adaptations of polar and deep-sea crustaceans: a hypothesis concerning physiological basis for evolution of cold adapted crustaceans. In A. B. Williams (Ed.), Symposium on the composition and evolution of crustaceans in the cold and temperate waters of the world ocean, Bull. Biol. Soc. Wash. 3: 283–296.
George, R. Y., 1979b. What adaptive strategies promote immigration and speciation in deep-sea environment. Sarsia 64: 61–65.
Gharib, M. & C. Willert, 1988. Particle tracing: Revisited. AIAA-88–3776-CP. 1st National Fluid Dynamics Congress, Cincinnati, Ohio: 1935–1943.
Hertel, H., 1966. Structure, form, and movement. Reinhold Publishers, New York.
Hessler, R. R., 1982. The structural morphology of walking mechanisms in Eumalacostracan crustaceans. Phil. trans. r. Soc. London. 296B: 245–298.
Hessler, R. R., 1985. Swimming in Crustacea. Trans. r. Soc. Edinburgh 76: 115–122.
Hoerner, S. F., 1965. Fluid-dynamic drag. S. F. Hoerner, Midland Park, New Jersey.
Ingram, C. L. & R. R. Hessler, 1983. Distribution and behavior of scavenging amphipods from the central North Pacific. Deep-Sea Res. 30: 683–706.
Laver, M. B., M. S. Olson, J. L. Edelman & K. L. Smith Jr., 1985. Swimming rates of scavenging deep-sea amphipods recorded with a free-vehicle video camera. Deep-Sea Res. 32: 1135–1142.
Leonard, A. B., J. R. Strickler & N. D. Holland, 1988. Effects of current speed on filtration during suspension feeding in Oligometra serripinna (Echinodermata: Crinoidea). Mar. Biol. 97: 111–125.
Morgan, E. & S. V. Hayes, 1977. The swimming of Nymphon gracile (Pycnogonida): the vertical lift forces generated while swimming at constant depth. J. exp. Biol. 71: 187–203.
Nachtigall, W., 1977. Swimming mechanics and energetics of locomotion of variously sized water beetles: Dysticidae, body length 2 to 35 mm. IN T. J. Pedley (ed.), Scale effects in animal locomotion. Academic Press, London: 269–283.
Naylor, C. & J. Adams, 1987. Sexual dimorphism, drag constraints, and male performance in Gammarus duebeni (Amphipoda). Oikos 48: 23–27.
Sainte-Marie, B., 1986. Feeding and swimming of lysianassid amphipods in a shallow cold-water bay. Mar. Biol. 91: 219–229.
Sainte-Marie, B. & P. Brunel, 1985. Suprabenthic gradients of swimming activity by cold-water gammaridean amphipod Crustacea over a muddy shelf in the Gulf of Saint-Lawrence. Mar. Ecol. Prog. Ser. 23: 57–69.
Sandeman, D. C., 1989. Physical properties, sensory receptors, and tactile reflexes of the antenna of the australian freshwater crayfish Cherax destructor. J. exp. Biol. 141: 197–217.
Smith, K. L., Jr. & R. J. Baldwin, 1982. Scavenging deep-sea amphipods: effects of food odor on oxygen consumption and a proposed metabolic strategy. Mar. Biol. 68: 287–298.
Smith, K. L., Jr. & R. J. Baldwin, 1984. Vertical distribution of the necrophagous amphipod Eurythenes gryllus in the North Pacific: spatial and temporal variation. Deep-Sea Res. 31: 1179–1196.
Staude, C. P., Jr., 1986. Systematics and behavioral ecology of the amphipod genus Paramaera Miers (Gammaridea: Eusiroidea: Pontogeniidae) in the eastern North Pacific. Ph. D. Thesis. University of Washington, 324 pages.
Strickler, J. R., 1975. Swimming of planktonic Cyclops species (Copepoda, Crustacea): pattern, movements and their control. In T. Y.-T. Wu, C. J. Brokaw & C. Brennen (eds), Swimming and flying in nature. Vol. 2, Plenum Press, New York: 599–613.
Vogel, F., 1985. Das Schwimmen der Talitridae (Crustacea: Amphipoda): Funktionsmorphologie, Phanomenologie und Energetik. Helgolander Meeresunters. 39: 303–339.
Vogel, S., 1981. Life in moving fluids. Princeton University Press, Princeton, New Jersey, 352 pp.
Waterman, T. H. (ed.), 1961. The Physiology of Crustacea. Volumes 1 & 2. Academic Press, New York.
Webb, P. W., 1975a. Hydrodynamics and energetics of fish propulsion. Bull. fish. Res. Bd Can. 190: 1–159.
Webb, P. W., 1984. Form and function in fish swimming. Sci. Am. 251: 72–82.
Webb, P. W., 1988. Simple physical principles and vertebrate aquatic locomotion. Am. Zool. 28: 709–725.
Webb, P. W. & D. Weihs, 1983. Fish biomechanics. Praeger Publishers. New York. 398 pp.
Weis-Fogh, T., 1975. Flapping flight and power in birds and insects, conventional and novel mechanisms. IN T. Y.-T. Wu, C. J. Brokaw & C. Brennen (eds.), Swimming and flying in nature. Vol. 2, Plenum Press, New York: 729–762.
Williams, T. A., 1988. A physical model of aquatic locomotion mimics changes during Artemia's larval development. Am. Zool. 29: 142A (Abstract 755).
Yayanos, A. A., 1978. Recovery and maintenance of live amphipods at a pressure of 580 bars from an ocean depth of 5700 meters. Science 200: 1056–1059.
Yayanos, A. A., 1981. Reversible inactivation of deep-sea amphipods (Paralicella capresca) by a decompression from 601 bars to atmospheric pressure. Compar. Biochem. Physiol. 69A: 563–565.
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Boudrias, M.A. Methods for the study of amphipod swimming: behavior, morphology, and fluid dynamics. Hydrobiologia 223, 11–25 (1991). https://doi.org/10.1007/BF00047624
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DOI: https://doi.org/10.1007/BF00047624