Shape mode analysis exposes movement patterns in biology: Flagella and flatworms as case studies

Steffen Werner; Jochen C. Rink; Ingmar H. Riedel-Kruse; Benjamin M. Friedrich

doi:10.1371/journal.pone.0113083

Shape mode analysis exposes movement patterns in biology: Flagella and flatworms as case studies

Steffen Werner, Jochen C. Rink, Ingmar H. Riedel-Kruse, Benjamin M. Friedrich

Research output: Contribution to journal › Article › peer-review

33 Scopus citations

Abstract

We illustrate shape mode analysis as a simple, yet powerful technique to concisely describe complex biological shapes and their dynamics. We characterize undulatory bending waves of beating flagella and reconstruct a limit cycle of flagellar oscillations, paying particular attention to the periodicity of angular data. As a second example, we analyze non-convex boundary outlines of gliding flatworms, which allows us to expose stereotypic body postures that can be related to two different locomotion mechanisms. Further, shape mode analysis based on principal component analysis allows to discriminate different flatworm species, despite large motion-associated shape variability. Thus, complex shape dynamics is characterized by a small number of shape scores that change in time. We present this method using descriptive examples, explaining abstract mathematics in a graphic way.

Original language	English (US)
Article number	0113083
Journal	PloS one
Volume	9
Issue number	11
DOIs	https://doi.org/10.1371/journal.pone.0113083
State	Published - Nov 26 2014
Externally published	Yes

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title = "Shape mode analysis exposes movement patterns in biology: Flagella and flatworms as case studies",

abstract = "We illustrate shape mode analysis as a simple, yet powerful technique to concisely describe complex biological shapes and their dynamics. We characterize undulatory bending waves of beating flagella and reconstruct a limit cycle of flagellar oscillations, paying particular attention to the periodicity of angular data. As a second example, we analyze non-convex boundary outlines of gliding flatworms, which allows us to expose stereotypic body postures that can be related to two different locomotion mechanisms. Further, shape mode analysis based on principal component analysis allows to discriminate different flatworm species, despite large motion-associated shape variability. Thus, complex shape dynamics is characterized by a small number of shape scores that change in time. We present this method using descriptive examples, explaining abstract mathematics in a graphic way.",

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AU - Friedrich, Benjamin M.

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AB - We illustrate shape mode analysis as a simple, yet powerful technique to concisely describe complex biological shapes and their dynamics. We characterize undulatory bending waves of beating flagella and reconstruct a limit cycle of flagellar oscillations, paying particular attention to the periodicity of angular data. As a second example, we analyze non-convex boundary outlines of gliding flatworms, which allows us to expose stereotypic body postures that can be related to two different locomotion mechanisms. Further, shape mode analysis based on principal component analysis allows to discriminate different flatworm species, despite large motion-associated shape variability. Thus, complex shape dynamics is characterized by a small number of shape scores that change in time. We present this method using descriptive examples, explaining abstract mathematics in a graphic way.

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Shape mode analysis exposes movement patterns in biology: Flagella and flatworms as case studies

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