Sage Journals: Discover world-class research

Abstract

Limbs of vertebrate animals have synovial joints. Many arthropod joints and the hinges of bivalve molluscs owe their mobility to components that bend, rather than to surfaces that slide over each other. No lubrication systems have been described for the few sliding surfaces in invertebrate joints. Peak forces on animal joints tend to be roughly proportional to (body mass)^2/3. The fin spines of some fishes have modified joints at their bases, which enable the fish to lock the spine in the erect position.

The ventral surfaces of crawling animals, including earthworms, snakes, and snails, slide over the ground. The conditions required for forward progress are discussed. Particularly, interesting tribological questions arise in the case of snails, which crawl on a mucus trail. For running animals, fast turns and other manoeuvres involving acceleration may be limited by friction with the ground.

The feet of insects and geckos adhere to solid surfaces, enabling these animals to climb vertical walls and even to walk on ceilings. Van der Waals adhesion seems to be responsible in the case of geckos and capillary adhesion in many insects. The trap of pitcher plants captures insects by making the adhesive mechanism ineffective.

Keywords

animal joints animal locomotion crawling worms snakes snails insects geckoes

Get full access to this article

View all access options for this article.

References

Currey

J. D.

Skeletal factors in locomotion In Aspects of animal movement (Eds Elder

H. Y.

Trueman

E. R.

), 1980, pp. 27–44 (Cambridge University Press, Cambridge).

Alexander

R. McN.

Animal mechanics, 2nd edition, 1983 (Blackwell, Oxford).

Alexander

R. McN.

Rubber-like properties of the inner hinge-ligament of Pectinidae

J. Exp. Biol., 1966, 44, 119–130.

Alexander

R. McN.

Forces in animal joints

Eng. Med., 1980, 9, 93–97.

Godfrey

Sutherland

Boy

Gomberg

Scaling of joint surface-areas in anthropoid primates and other mammals

J. Zool., Lond., 1991, 223, 603–625.

Alexander

R. McN.

Jayes

A. S.

Maloiy

G. M. O.

Wathuta

E. M.

Allometry of the limb bones of mammals from shrews to elephants

J. Zool., Lond., 1979, 189, 305–314.

Alexander

R. McN.

Structure and function in the catfish

J. Zool., Lond., 1966, 148, 88–152.

Alexander

R. McN.

Principles of animal locomotion, 2003 (Princeton University Press, Princeton, NJ).

Alexander

R. McN.

Locomotion of animals, 1982 (Blackie, Glasgow).

10.

Elder

H. Y.

Direct peristaltic progression and the functional significance of the dermal connective tissue during burrowing in the polychaete Polyphysia crassa (Oersted)

J. Exp. Biol., 1973, 58, 637–655.

11.

Accoto

Castrataro

Dario

Biomechanical analysis of Oligochaeta crawling

J. Theor. Biol., 2004, 230, 49–55.

12.

Denny

M. W.

The role of gastropod pedal mucus in locomotion

Nature, 1980, 285, 160–161.

13.

Gans

Gasc

J.-P.

Tests on the locomotion of the elongate and limbless reptile Ophisaurus apodus (Sauria, Anguidae)

J. Zool., Lond., 1990, 220, 517–536.

14.

Walton

Jayne

B. C.

Bennett

A. F.

The energetic cost of limbless locomotion

Science, 1990, 249, 524–527.

15.

Greene

P. R.

Running on flat turns: Experiments, theory, and applications

J. Biomech. Eng., 1985, 107, 96–103.

16.

Alexander

R. McN.

Stability and manoeuvrability of terrestrial vertebrates

Integr. Comp. Biol., 2002, 42, 158–164.

17.

Cartmill

The volar skin of primates: Its frictional characteristics and their functional significance

Am. J. Phys. Anthropol., 1979, 50, 497–510.

18.

Denny

M. W.

Air and water, 1993 (Princeton University Press, Princeton, NJ).

19.

Federle

Baumgartner

Hölldobler

Biomechanics of ant adhesive pads: Frictional forces are rate- and temperature-dependent

J. Exp. Biol., 2004, 207, 67–74.

20.

Bohn

H. F.

Federle

Insect aquaplaning: Nepenthes pitcher plants capture prey with the peristome, a fully wettable water-lubricated anisotropic surface

Proc. USA Natl Acad. Sci., 2004, 101, 14138–14143.

21.

Irschick

D. J.

Austin

C. C.

Petren

Fisher

R. N.

Losos

J. B.

Ellers

A comparative analysis of clinging ability among pad-bearing lizards

Biol. J. Linn. Soc., 1996, 59, 21–35.

22.

Autumn

Liang

Y. A.

Hsieh

S. T.

Zesch

Chan

W. P.

Kenny

T. W.

Fearing

Full

R. J.

Adhesive force of a single gecko foot-hair

Nature, 2000, 405, 681–685.

23.

Gao

H. J.

Wang

Yao

H. M.

Gorb

Arzt

Mechanics of hierarchical adhesion structures of geckoes

Mech. Mater., 2005, 37, 275–285.

24.

Spolenak

Gorb

Gao

H. J.

Arzt

Effects of contact shape on the scaling of biological attachments

Proc. Roy. Soc. Lond. A, 2005, 461, 305–319.

25.

Stork

N. E.

Experimental analysis of adhesion of Chrysolina polita (Chrysomelidae: Coleoptera) on a variety of surfaces

J. Exp. Biol., 1980, 88, 91–107.

26.

Scherge

Gorb

S. N.

Biological micro- and nanotechnology: nature's solutions, 2001 (Springer, Berlin).

Introduction to biotribology: Animal locomotion

Abstract

Abstract

Keywords

Get full access to this article

References