References

Our publications

1. Cofer, D., G. Cymbalyuk, J. Reid, Y. Zhu, W. Heitler, and D.H. Edwards, AnimatLab: A 3-D graphics environment for neuromechanical simulations. J Neuroscience Methods., 2010. 187(2): p. 280-288.
2. Cofer, D.W. (2009). Neuromechanical Analysis of the Locust Jump (Ph.D. dissertation). Available from digital archive database. (Article No. 1056)
3. Cofer, D.W., G. Cymbalyuk, W.J. Heitler, and D.H. Edwards, Neuromechanical simulation of the locust jump. J Exp Biol, 2010. 213: p. 1060-1068.
4. Cofer, D., G. Cymbalyuk, W.J. Heitler, and D.H. Edwards, Control of tumbling during the locust jump. J Exp Biol, 2010. 213(Pt 19): p. 3378-87.

References

1. Beer RD (1990) Intelligence as Adaptive Behavior: An Experiment in Computational Neuroethology. San Diego: Acadmic Press, Inc.
2. Carlson NA (1992) Foundations of Physiological Psychology. Needham Heights, Massachusetts: Simon & Schuster.
3. Edwards DH, Heitler WJ, Krasne FB (1999) 50 years of a command neuron: The neurobiology of escape behavior in the crayfish . Trends Neurosci 22: 153-161.
4. Edwards DH, Heitler WJ, Leise EM, Fricke RA (1991) Postsynaptic modulation of rectifying electrical synaptic inputs to the LG escape command neuron in crayfish. J Neurosci 11: 2117-2129.
5. Edwards DH, Mulloney B (1987) Synaptic integration in excitatory and inhibitory crayfish motoneurons. J Neurophysiol 57: 1425-1445.
6. Hawkins D, Bey M (1994) A comprehensive approach for studying muscle-tendon mechanics. J Biomech Eng 116: 51-55.
7. Herberholz J, Sen MM, Edwards DH (2004) Escape behavior and escape circuit activation in juvenile crayfish during prey-predator interactions. J Exp Biol 207: 1855-1863.
8. Hines ML, Carnevale NT (2001) NEURON: a tool for neuroscientists. Neuroscientist 7: 123-135.
9. Krasne FB, Edwards DH (2002) Crayfish escape behavior: lessons learned. In: Crustacean Experimental Systems in Neurobiology (Wiese K, ed), pp 3-22. Berlin: Springer.
10. Krasne FB, Wine JJ (1984) The production of crayfish tailflip escape responses. In: Neural Mechanisms of Startle Behavior (Eaton RC, ed), pp 179-211. New York: Plenum Press.
11. McMahon TA (1984) Muscles, reflexes, and locomotion. Princeton: Princeton University Press.
12. Miller MW, Krasne FB (1985) Long-lasting stimulation-induced enhancement of synaptic transmission in the crayfish lateral giant escape circuit. Soc Neurosci Abstr 11 Part 2: 232.3.
13. Reichert H, Wine JJ (1983) Coordination of lateral giant and non-giant systems in crayfish escape behavior. J comp Physiol 153: 3-15.
14. Shapiro, A., Faloutsos, P., and Ng-Thow-HIng, V. Dynamic Animation and Control Environment. 2005. Victoria, British Columbia, Canada. Proceedings of Graphics Interface Conference. Ref Type: Conference Proceeding
15. Teran J, Sifakis E, Blemker SS, Ng-Thow-HIng V, Lau C, Fedkiw R (2005) Creating and simulating skeletal muscle from the visible human data set. IEEE Trans Vis Comput Graph 11: 317-328.
16. Webb PW (1979) Mechanics of escape responses in crayfish (Orconectes virilis). J Exp Biol 79: 245-263.
17. Wine JJ (1977) Crayfish escape behavior. III. monosynaptic and polysynaptic sensory pathways involved in phasic extension. J comp Physiol 121: 187-203.
18. Wine JJ (1984) The structural basis of an innate behavioural pattern. J Exp Biol 112: 283-319.

AnimatLab development was supported by National Science Foundation grant #0641326 to Donald H. Edwards.