Advertisement
Journal Articles
The diving physiology of bottlenose dolphins (Tursiops truncatus). II. Biomechanics and changes in buoyancy at depth
R.C. Skrovan, T.M. Williams, P.S. Berry, P.W. Moore, R.W. Davis
Journal of Experimental Biology 1999 202: 2749-2761;

Summary

During diving, marine mammals must balance the conservation of limited oxygen reserves with the metabolic costs of swimming exercise. As a result, energetically efficient modes of locomotion provide an advantage during periods of submergence and will presumably increase in importance as the animals perform progressively longer dives. To determine the effect of a limited oxygen supply on locomotor performance, we compared the kinematics and behavior of swimming and diving bottlenose dolphins. Adult bottlenose dolphins (Tursiops truncatus) were trained to swim horizontally near the water surface or submerged at 5 m and to dive to depths ranging from 12 to 112 m. Swimming kinematics (preferred swimming mode, stroke frequency and duration of glides) were monitored using submersible video cameras (Sony Hi-8) held by SCUBA divers or attached to a pack on the dorsal fin of the animal. Drag and buoyant forces were calculated from patterns of deceleration for horizontally swimming and vertically diving animals. The results showed that dolphins used a variety of swimming gaits that correlated with acceleration. The percentage of time spent gliding during the descent phase of dives increased with depth. Glide distances ranged from 7.1+/−1.9 m for 16 m dives to 43.6+/−7.0 m (means +/− s.e.m.) for 100 m dives. These gliding patterns were attributed to changes in buoyancy associated with lung compression at depth. By incorporating prolonged glide periods, the bottlenose dolphin realized a theoretical 10–21 % energetic savings in the cost of a 100 m dive in comparison with dives based on neutral buoyancy models. Thus, modifying locomotor patterns to account for physical changes with depth appears to be one mechanism that enables diving mammals with limited oxygen stores to extend the duration of a dive.

REFERENCES

    1. Alexander, R. McN
    (1990). Size, speed and buoyancy in aquatic animals. Am. Zool 30, 189–.
    1. Breder, C. M. Jr..
    (1965). Vortices and fish schools. Zoologica 50, 97–.
    OpenUrl
    1. Castellini, M. A.,
    2. Murphy, B. J.,
    3. Fedak, M. A.,
    4. Ronald, K.,
    5. Gofton, N. and
    6. Hochachka, P. W.
    (1985). Potentially conflicting metabolic demands of diving and exercise in seals. J. Appl. Physiol 58, 392–.
    OpenUrlAbstract/FREE Full Text
    1. Daniel, T. L.
    (1984). Unsteady aspects of aquatic locomotion. Am. Zool 24, 121–.
    OpenUrl
    1. Davis, R. W.,
    2. Collier, S. O.,
    3. Hagey, W.,
    4. Williams, T. M. and
    5. LeBoeuf, B. J.
    (1999). A video system and three dimensional dive recorder for marine mammals: Using video and virtual reality to study diving behavior. Proceedings of the Fifth European Conference on Biotelemetry, Strasbourg, France.
    1. Dunstone, N. and
    2. O'Connor, R. J.
    (1979). Optimal foraging in an amphibious mammal. I. The aqualung effect. Anim. Behav 27, 11821194.
    OpenUrlAbstract
    1. Fish, F. E.
    (1993). Power output and propulsive efficiency of swimming bottlenose dolphins (Tursiops truncatus). J. Exp. Biol 185, 179–.
    OpenUrlCrossRef
    1. Fish, F. E.,
    2. Fegely, J. F. and
    3. Xanthopoulos, C. J.
    (1991). Burst-and-coast swimming in schooling fish (Notemigonus crysoleucas) with implications for energy economy. Comp. Biochem. Physiol 100, 633–.
    OpenUrlAbstract/FREE Full Text
    1. Fish, F. E.,
    2. Innes, S. and
    3. Ronald, K.
    (1988). Kinematics and estimated thrust production of swimming harp and ringed seals. J. Exp. Biol 137, 157–.
    OpenUrlAbstract/FREE Full Text
    1. Heglund, N. C.,
    2. Taylor, C. R. and
    3. McMahon, T. A.
    (1974). Scaling stride frequency and gait to animal size: mice to horses. Science 186, 1112–.
    OpenUrlCrossRef
    1. Hoyt, D. F. and
    2. Taylor, C. R.
    (1981). Gait and the energetics of locomotion in horses. Nature 292, 239–.
    OpenUrlCrossRef
    1. Hui, C. A.
    (1987). Power and speed of swimming dolphins. J. Mammal 68, 126–.
    OpenUrlAbstract/FREE Full Text
    1. Lang, T. G. and
    2. Norris, K. S.
    (1966). Swimming speed of a Pacific bottlenose dolphin. Science 151, 588–.
    OpenUrlAbstract/FREE Full Text
    1. Lighthill, M. J.
    (1971). Large-amplitude elongated-body theory of fish locomotion. Proc. R. Soc. Lond. B 179, 125–.
    OpenUrlAbstract/FREE Full Text
    1. Lovvorn, J. R.,
    2. Jones, D. R. and
    3. Blake, R. W.
    (1991). Mechanics of underwater locomotion in diving ducks: drag, buoyancy and acceleration in a size gradient of species. J. Exp. Biol 159, 89–.
    OpenUrl
    1. Magana, S. A.,
    2. Hoyt, D. F.,
    3. Wickler, S. J.,
    4. Lewis, C. C.,
    5. Garcia, S. B. and
    6. Padilla, O. R.
    (1997). The effect of load carrying on preferred trotting speed in horses. Am. Zool 37, 176–.
    OpenUrlAbstract/FREE Full Text
    1. Ridgway, S. H. and
    2. Howard, R.
    (1979). Dolphin lung collapse and intramuscular circulation during free diving: Evidence from nitrogen washout. Science 206, 1182–.
    OpenUrlAbstract/FREE Full Text
    1. Ridgway, S. H.,
    2. Scronce, B. L. and
    3. Kanwisher, J.
    (1969). R. C. SKROVANANDOTHERS2761 Biomechanics of diving dolphins Respiration and deep diving in the bottlenose porpoise. Science 166, 1651–.
    OpenUrlAbstract/FREE Full Text
    1. Rohr, J.,
    2. Latz, M. I.,
    3. Fallon, S.,
    4. Nauen, J. C. and
    5. Hendricks, E.
    (1998). Experimental approaches towards interpreting dolphin-simulated bioluminescence. J. Exp. Biol 201, 1447–.
    OpenUrlFREE Full Text
    1. Stahl, W. R.
    (1967). Scaling respiratory variables in mammals. J. Appl. Physiol 22, 453–.
    OpenUrl
    1. Taylor, C. R.
    (1978). Why change gaits? Recruitment of muscles and muscle fibers as a function of speed and gait. Am. Zool 18, 153–.
    OpenUrlAbstract/FREE Full Text
    1. Videler, J. J. and
    2. Kamermans, P.
    (1985). Differences between upstroke and downstroke in swimming dolphins. J. Exp. Biol 119, 265–.
    OpenUrlAbstract/FREE Full Text
    1. Videler, J. J. and
    2. Weihs, D.
    (1982). Energetic advantages of burst-and-coast swimming of fish at high speeds. J. Exp. Biol 97, 169–.
    OpenUrlAbstract/FREE Full Text
    1. Webb, P. M.,
    2. Crocker, D. E.,
    3. Blackwell, S. B.,
    4. Costa, D. P. and
    5. LeBoeuf, B. J.
    (1998). Effects of buoyancy on the diving behavior of northern elephant seals. J. Exp. Biol 201, 2349–.
    OpenUrl
    1. Webb, P. W.
    (1984). Body form, locomotion and foraging in aquatic vertebrates. Am. Zool 24, 107–.
    OpenUrlCrossRef
    1. Weihs, D.
    (1973). Hydromechanics of fish schooling. Nature 241, 290–.
    OpenUrlCrossRefPubMedWeb of Science
    1. Weihs, D.
    (1974). Energetic advantages of burst swimming of fish. J. Theor. Biol 48, 215–.
    OpenUrlAbstract/FREE Full Text
    1. Williams, T. M.
    (1983). Locomotion in the North American mink, a semi-aquatic mammal. II. The effect of an elongate body on running energetics and gait pattern. J. Exp. Biol 105, 283–.
    OpenUrlCrossRef
    1. Williams, T. M.
    (1999). The evolution of cost efficient swimming in marine mammals: limits to energetic optimization. Phil. Trans. R. Soc. Lond. B 354, 193–.
    OpenUrlCrossRefPubMed
    1. Williams, T. M.,
    2. Friedl, W. A.,
    3. Fong, M. L.,
    4. Yamada, R. M.,
    5. Sedivy, P. and
    6. Haun, J. E.
    (1992). Travel at low energetic cost by swimming and wave-riding bottlenose dolphins. Nature 355, 821–.
    OpenUrlAbstract
    1. Williams, T. M.,
    2. Haun, J. E. and
    3. Friedl, W. A.
    (1999). The diving physiology of bottlenose dolphins (Tursiops truncatus). I. Balancing the demands of exercise for energy conservation at depth. J. Exp. Biol 202, 2763–.
    OpenUrl
    1. Wilson, R. P.,
    2. Grant, W. S. and
    3. Duffy, D. S.
    (1986). Recording devices on free-ranging marine animals: does measurement affect foraging performance?. Ecology 67, 1091–.
Back to top

 Download PDF

Email
Journal Articles
The diving physiology of bottlenose dolphins (Tursiops truncatus). II. Biomechanics and changes in buoyancy at depth
R.C. Skrovan, T.M. Williams, P.S. Berry, P.W. Moore, R.W. Davis
Journal of Experimental Biology 1999 202: 2749-2761;
del.icio.us logo Digg logo Reddit logo Twitter logo CiteULike logo Facebook logo Google logo Mendeley logo
Citation Tools
Alerts

Article navigation

Other journals from The Company of Biologists

Advertisement

Predicting the Future: Species Survival in a Changing World

Read our new special issue exploring the significant role of experimental biology in assessing and predicting the susceptibility or resilience of species to future, human-induced environmental change.

Big Biology Podcast - Hollie Putnam and coral bleaching

Catch the next JEB-sponsored episode of the Big Biology Podcast where Art and Marty talk to Hollie Putnam about the causes of coral bleaching and the basic biology of corals in the hope of selectively breeding corals that can better tolerate future ocean conditions.

Read Hollie's Review on the subject, which is featured in our current special issue. 

Stark trade-offs and elegant solutions in arthropod visual systems

Many elegant eye specializations that evolved in response to visual challenges continue to be discovered. A new Review by Meece et al. summarises exciting solutions evolved by insects and other arthropods in response to specific visual challenges.

Head bobbing gives pigeons a sense of perspective

Pigeons might look goofy with their head-bobbing walk, but it turns out that the ungainly head manoeuvre allows the birds to judge distance.