ナガヤ ナオヒサ   NAGAYA NAOHISA
  永谷 直久
   所属   京都産業大学  情報理工学部 情報理工学科
   職種   准教授
言語種別 英語
発行・発表の年月 2017/06
形態種別 研究論文
査読 査読あり
標題 Anomalous diffusion on the servosphere: A potential tool for detecting inherent organismal movement patterns
執筆形態 その他
掲載誌名 PLoS ONE
巻・号・頁 12(6)
著者・共著者 Naohisa Nagaya,Nobuaki Mizumoto,Masato S. Abe,Shigeto Dobata,Ryota Sato,Ryusuke Fujisawa
概要 © 2017 Nagaya et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Tracking animal movements such as walking is an essential task for understanding how and why animals move in an environment and respond to external stimuli. Different methods that implemented image analysis and a data logger such as GPS have been used in laboratory experiments and in field studies, respectively. Recently, animal movement patterns without stimuli have attracted an increasing attention in search for common innate characteristics underlying all of their movements. However, it is difficult to track the movements in a vast and homogeneous environment without stimuli because of space constraints in laboratories or environmental heterogeneity in the field, hindering our understanding of inherent movement patterns. Here, we applied an omnidirectional treadmill mechanism, or a servosphere, as a tool for tracking two-dimensional movements of small animals that can provide both a homogenous environment and a virtual infinite space for walking. To validate the use of our tracking system for assessment of the free-walking behavior, we compared walking patterns of individual pillbugs (Armadillidium vulgare) on the servosphere with that in two types of experimental flat arenas. Our results revealed that the walking patterns on the servosphere showed similar diffusive characteristics to those observed in the large arena simulating an open space, and we demonstrated that our mechanism provides more robust measurements of diffusive properties compared to a small arena with enclosure. Moreover, we showed that anomalous diffusion properties, including Levy walk, can be detected from the free-walking behavior on our tracking system. Thus, our novel tracking system is useful to measure inherent movement patterns, which will contribute to the studies of movement ecology, ethology, and behavioral sciences.
DOI 10.1371/journal.pone.0177480
ISSN /1932-6203
PMID 28570562