Camazine, S., Deneubourg, J. L., Franks, N. R., Sneyd, J., Theraula, G., & Bonabeau, E. (2003). Self-Organization in Biological Systems. Princeton: Princeton University Press.
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Couzin, I. D., & Krause, J. (2003). Self-Organization and Collective Behavior in Vertebrates. In Charles T. Snowdon and Timothy J. Roper J. S. R. Peter J. B. Slater (Ed.), Advances in the Study of Behavior (Vol. 32, pp. 1–75). Academic Press.
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Aberle, K. S. (2003). Untersuchung der Verwandtschaftsverhältnisse, Inzucht und genetischen Distanzen bei den deutschen Kaltblutpferderassen. Ph.D. thesis, , Hannover.
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van Duijn, M. A. J. (2003). Software for Social Network Analysis. University of Groningen: Heymans Institute/DPMG.
Abstract: This chapter gives a state-of-the art overview of available (free and commercial)
software for social network analysis as of fall 2003. It reviews and compares
six programs, illustrating their functionality with example data. Data manipulation
options and available support are also discussed. Furthermore, seventeen
other, of which nine special-purpose, software packages and ve software routine
packages for general statistical software are reviewed brie
y. The chapter
concludes with some recommendations.
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Lefebvre, L., & Bouchard, J. (2003). Social learning about food in birds. In D. M. Fragaszy, & S. Perry (Eds.), The Biology of Traditions (pp. 94–126). Cambridge: Cambridge University Press.
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Galef, G. G. J. (2003). Social learning: promotor or inhibitor of innovation? In S. M. Reader, & K. N. Laland (Eds.), Animal Intelligence. Oxford: Oxford University Press.
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Tang, A. C. (2003). A hippocampal theory of cerebral lateralization. In Hugdahl K. and Davidson R.J. (Ed.), The asymmetrical brain (pp. 37–68). Massechusetts: MIT Press.
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Tang, A. C., Reeb, B. C., Romeo, R. D., & McEwen, B. S. (2003). Modification of Social Memory, Hypothalamic-Pituitary-Adrenal Axis, and Brain Asymmetry by Neonatal Novelty Exposure. The Journal of Neuroscience, 23(23), 8254–8260.
Abstract: Although corticosterone (a stress hormone) is known to influence social behavior and memory processes, little has been explored concerning its modulatory role in social recognition. In rats, social recognition memory for conspecifics typically lasts <2 hr when evaluated using a habituation paradigm. Using neonatal novelty exposure, a brief and transient early life stimulation method known to produce long-lasting changes in the hypothalamic-pituitary-adrenal axis, we found that social recognition memory was prolonged to at least 24 hr during adulthood. This prolonged social memory was paralleled by a reduction in the basal blood concentration of corticosterone. The same neonatal stimulation also resulted in a functional asymmetry expressed as a greater right-turn preference in a novel environment. Rats that preferred to turn right showed better social recognition memory. These inter-related changes in basal blood corticosterone concentration, turning asymmetry, and social recognition memory suggest that stress hormones and brain asymmetry are likely candidates for modulating social memory. Furthermore, given that neonatal stimulation has been shown to improve learning and memory performance primarily under aversive learning situations, the neonatal novelty exposure-induced enhancement in social recognition broadens the impact of early life stimulation to include the social domain.
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Reader, S. M., & Laland, K. N. (2003). Animal Innovation. Oxford: Oxford University Press.
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Sol, D. (2003). Behavioural flexibility: a neglected issue in the ecological and evolutionary literature. In S. M. Reader and K. N. Laland (Ed.), Animal innovation. (pp. 63–82). Oxford: Oxford University Press.
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