The kinematics of multifunctionality: comparisons of biting and swallowing inAplysia californica-Reference-Cited by-同舟云学术

The kinematics of multifunctionality: comparisons of biting and swallowing inAplysia californica

Published:2007-01-15 Issue:2 Volume:210 Page:238-260
ISSN:1477-9145
Container-title:Journal of Experimental Biology
language:en
Short-container-title:

Author:

Neustadter David M.¹,Herman Robert L.²,Drushel Richard F.³,Chestek David W.¹,Chiel Hillel J.³⁴¹

Affiliation:

1. Department of Biomedical Engineering, Case Western Reserve University,Cleveland, OH 44106, USA

2. Department of Electrical Engineering and Computer Science, Case Western Reserve University, Cleveland, OH 44106, USA

3. Department of Biology, Case Western Reserve University, Cleveland, OH 44106, USA

4. Department of Neurosciences, Case Western Reserve University, Cleveland,OH 44106, USA

Abstract

SUMMARYWhat are the mechanisms of multifunctionality, i.e. the use of the same peripheral structures for multiple behaviors? We studied this question using the multifunctional feeding apparatus of the marine mollusk Aplysia californica, in which the same muscles mediate biting (an attempt to grasp food) and swallowing (ingestion of food). Biting and swallowing responses were compared using magnetic resonance imaging of intact, behaving animals and a three-dimensional kinematic model. Biting is associated with larger amplitude protractions of the grasper (radula/odontophore) than swallowing, and smaller retractions. Larger biting protractions than in swallowing appear to be due to a more anterior position of the grasper as the behavior begins, a larger amplitude contraction of protractor muscle I2, and contraction of the posterior portion of the I1/I3/jaw complex. The posterior I1/I3/jaw complex may be context-dependent, i.e. its mechanical context changes the direction of the force it exerts. Thus, the posterior of I1/I3 may aid protraction near the peak of biting, whereas the entire I1/I3/jaw complex acts as a retractor during swallowing. In addition, larger amplitude closure of the grasper during swallowing allows an animal to exert more force as it ingests food. These results demonstrate that differential deployment of the periphery can mediate multifunctionality.

Publisher

The Company of Biologists

Subject

Insect Science,Molecular Biology,Animal Science and Zoology,Aquatic Science,Physiology,Ecology, Evolution, Behavior and Systematics

Link

http://journals.biologists.com/jeb/article-pdf/210/2/238/1260163/238.pdf

Reference69 articles.

1. Ashley-Ross, M. A. and Lauder, G. V. (1997). Motor patterns and kinematics during backward walking in the Pacific Giant Salamander: evidence for novel motor output. J. Neurophysiol.78,3047-3060.

2. Begnoche, V. L., Moore, S. K., Blum, N., Van Gils, C. and Mayeri, E. (1996). Sign stimulus activates a peptidergic neural system controlling reproductive behavior in Aplysia.J. Neurophysiol.75,2161-2166.

3. Berkowitz, A. (2001). Broadly tuned spinal neurons for each form of fictive scratching in spinal turtles. J. Neurophysiol.86,1017-1025.

4. Berkowitz, A. (2002). Both shared and specialized spinal circuitry for scratching and swimming in turtles. J. Comp. Physiol. A188,225-234.

5. Berkowitz, A. (2005). Physiology and morphology indicate that individual spinal interneurons contribute to diverse limb movements. J. Neurophysiol.94,4455-4470.

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