Access the full text.
Sign up today, get DeepDyve free for 14 days.
J. Cubit (1969)
Behavior and Physical Factors Causing Migration and Aggregation of the Sand Crab Emerita Analoga (Stimpson)Ecology, 50
A. Kramer, F. Krasne (1984)
Crayfish escape behavior: production of tailflips without giant fiber activity.Journal of neurophysiology, 52 2
D. Skinner, B. Hill (1987)
Feeding and reproductive behaviour and their effect on catchability of the spanner crab Ranina raninaMarine Biology, 94
(2004)
Burrow morphology of the ghost
Z. Faulkes, D. Paul (1997)
Coordination between the legs and tail during digging and swimming in sand crabsJournal of Comparative Physiology A, 180
Clive Jones (1993)
Population structure of Thenus orientalis and T. indicus (Decapoda: Scyllaridae) in northeastern AustraliaMarine Ecology Progress Series, 97
E. Trueman (1970)
The Mechanism of Burrowing of the Mole Crab, EmeritaThe Journal of Experimental Biology, 53
J. Stewart, S. Kennelly (2000)
Growth of the scyllarid lobsters Ibacus peronii and I. chaceiMarine Biology, 136
P. Jacklyn, D. Ritz (1986)
Hydrodynamics of swimming in scyllarid lobstersJournal of Experimental Marine Biology and Ecology, 101
(1980)
Locomotion in a forward walking
N. Tschuluun, W. Hall, B. Mulloney (2001)
Limb Movements during Locomotion: Tests of a Model of an Intersegmental Coordinating CircuitThe Journal of Neuroscience, 21
Z. Faulkes, Dorothy Paul (1997)
Digging in sand crabs (Decapoda, Anomura, Hippoidea): interleg coordinationThe Journal of experimental biology, 200 Pt 4
W. Davis (1969)
The neural control of swimmeret beating in the lobster.The Journal of experimental biology, 50 1
L. Ogren (1977)
Concealment behavior of the spanish lobster, Scyllarides modifer (Stimpson), with observations on its diel activity
H. Jaeger, S. Nagel, R. Behringer (1996)
The Physics of Granular MaterialsPhysics Today, 49
P. Stein (1971)
Intersegmental coordination of swimmeret motoneuron activity in crayfish.Journal of neurophysiology, 34 2
Clive Jones (1988)
The biology and behaviour of bay lobsters, Thenus spp. (Decapoda : Scyllaridae), in Northern Queensland, Australia
D. Paul (2004)
Swimming behavior of the sand crab, Emerita analoga (Crustacea, Anomura)Zeitschrift für vergleichende Physiologie, 75
D. Johnston, D. Yellowlees (1998)
RELATIONSHIP BETWEEN DIETARY PREFERENCES AND DIGESTIVE ENZYME COMPLEMENT OF THE SLIPPER LOBSTER THENUS ORIENTALIS (DECAPODA: SCYLLARIDAE)Journal of Crustacean Biology, 18
Diana Barshaw, K. Lavalli, E. Spanier (2003)
Offense versus defense: responses of three morphological types of lobsters to predationMarine Ecology Progress Series, 256
I. Cooke, D. Macmillan (1985)
Further Studies of Crayfish Escape Behaviour: I. The Role of the Appendages and the Stereotyped Nature of Non-Giant Escape SwimmingThe Journal of Experimental Biology, 118
Z. Faulkes (2004)
Loss of escape responses and giant neurons in the tailflipping circuits of slipper lobsters, Ibacus spp. (Decapoda, Palinura, Scyllaridae).Arthropod structure & development, 33 2
J. Stewart, S. Kennelly (1998)
Contrasting movements of two exploited Scyllarid lobsters of the genus Ibacus off the east coast of AustraliaFisheries Research, 36
(1986)
Intersegmental coordination of swimmeret
A. Correia, O. Ferreira (1995)
Burrowing Behavior of the Introduced Red Swamp Crayfish Procambarus Clarkii (Decapoda: Cambaridae) in PortugalJournal of Crustacean Biology, 15
J. Mewis (1979)
Thixotropy - a general reviewJournal of Non-newtonian Fluid Mechanics, 6
(2001)
Limb movements
(1987)
Feeding and reproductive
B. Mulloney (2003)
During Fictive Locomotion, Graded Synaptic Currents Drive Bursts of Impulses in Swimmeret Motor NeuronsThe Journal of Neuroscience, 23
E. Spanier, G. Almog-Shtayer (1992)
Shelter preferences in the Mediterranean slipper lobster: effects of physical propertiesJournal of Experimental Marine Biology and Ecology, 164
Dugan, Hubbard, Lastra (2000)
Burrowing abilities and swash behavior of three crabs, Emerita analoga Stimpson, Blepharipoda occidentalis Randall, and Lepidopa californica Efford (Anomura, Hippoidea), of exposed sandy beaches.Journal of experimental marine biology and ecology, 255 2
(1971)
Intersegmental coordination of swimmeret motoneuron
Z. Faulkes, D. Paul (1998)
Digging in sand crabs: coordination of joints in individual legs.The Journal of experimental biology, 201 Pt 14
D. Wilson (1966)
Insect walking.Annual review of entomology, 11
J. Stewart (2003)
Long-term recaptures of tagged Scyllarid lobsters (Ibacus peronii) from the east coast of AustraliaFisheries Research, 63
K. Shimoda, A. Tamaki (2004)
Burrow morphology of the ghost shrimp Nihonotrypaea petalura (Decapoda: Thalassinidea: Callianassidae) from western Kyushu, JapanMarine Biology, 144
(1994)
Anti-predator behaviors of the Mediterranean slipper lobster, Scyllarides latus
F. Clarac (2002)
Neurobiology of crustacean walking From past to future
D. Paul, B. Mulloney (1986)
Intersegmental coordination of swimmeret rhythms in isolated nerve cords of crayfishJournal of Comparative Physiology A, 158
Clarac F.
Neurobiology of crustacean walking: from past to future. pp. 119-137.
Martínez, Full, Koehl (1998)
Underwater punting by an intertidal crab: a novel gait revealed by the kinematics of pedestrian locomotion in air versus waterThe Journal of experimental biology, 201 (Pt 18)
J. Ayers (2004)
Underwater walking.Arthropod structure & development, 33 3
K. Kinoshita (2002)
BURROW STRUCTURE OF THE MUD SHRIMP UPOGEBIA MAJOR (DECAPODA: THALASSINIDEA: UPOGEBIIDAE), 22
Sally Sleinis, G. Silvey (1980)
Locomotion in a forward walking crabJournal of comparative physiology, 136
F. Bird, G. Poore (1999)
Functional burrow morphology of Biffarius arenosus (Decapoda: Callianassidae) from southern AustraliaMarine Biology, 134
(1998)
Crayfish fossils and burrows from the Upper Jurassic Morrison Formation of western Colorado
Digging is a distinct form of locomotion that poses different mechanical problems than other locomotor modes that are commonly used by crustaceans, e.g., walking, swimming. I examined the mechanisms of digging by shovel nosed lobsters ( Ibacus peronii ), which spend most of the day underneath sand. Ibacus peronii were videotaped while digging. Ibacus peronii use a “wedge” strategy to submerge into sand. An individual penetrates the sand with the walking legs, then extends the abdomen to push sand backwards, then flexes the abdomen while pushing backward with the legs, which slowly drives the body into the sand. This basic sequence repeats for several minutes. Digging often ends with a short series of tailflips. Digging by “wedging” is substantially different from previously described mechanisms in more specialized digging species. When presented with a choice of substrates, I. peronii preferred to dig in sand over shell grit, but individuals showed no preference for different types of sand.
Journal of Crustacean Biology – Brill
Published: Feb 1, 2006
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.