2020
DOI: 10.1242/jeb.217562
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Asymmetrical gait kinematics of free-ranging callitrichines in response to changes in substrate diameter and orientation

Abstract: Arboreal environments present considerable biomechanical challenges for animals moving and foraging among substrates varying in diameter, orientation and compliance. Most studies of quadrupedal gait kinematics in primates and other arboreal mammals have focused on symmetrical walking gaits and the significance of diagonal sequence gaits. Considerably less research has examined asymmetrical gaits, despite their prevalence in small-bodied arboreal taxa. Here, we examined whether and how free-ranging callitrichin… Show more

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Cited by 16 publications
(23 citation statements)
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References 89 publications
(153 reference statements)
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“…Arguably on large diameter substrates, where balance no longer becomes a biomechanical concern, switching to asymmetrical half‐bounds confer a reduction in inter‐cycle variability (Diedrich & Warren, 1995; Granatosky, Bryce, et al, 2018), and energetic expenditure (Hoyt & Taylor, 1981; Reilly et al, 2007). While the use of asymmetrical gaits often comprises a substantial portion of the locomotor repertoire of many small‐bodied arboreal mammals (Dunham et al, 2020; Karantanis et al, 2017a, 2017b; Lammers & Biknevicius, 2004; Lammers & Zurcher, 2011; Nyakatura & Heymann, 2010; Nyakatura et al, 2008; Shapiro & Young, 2010; Young, 2009), an understanding of the biomechanical advantages/disadvantages of these gait types remains elusive.…”
Section: Discussionmentioning
confidence: 99%
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“…Arguably on large diameter substrates, where balance no longer becomes a biomechanical concern, switching to asymmetrical half‐bounds confer a reduction in inter‐cycle variability (Diedrich & Warren, 1995; Granatosky, Bryce, et al, 2018), and energetic expenditure (Hoyt & Taylor, 1981; Reilly et al, 2007). While the use of asymmetrical gaits often comprises a substantial portion of the locomotor repertoire of many small‐bodied arboreal mammals (Dunham et al, 2020; Karantanis et al, 2017a, 2017b; Lammers & Biknevicius, 2004; Lammers & Zurcher, 2011; Nyakatura & Heymann, 2010; Nyakatura et al, 2008; Shapiro & Young, 2010; Young, 2009), an understanding of the biomechanical advantages/disadvantages of these gait types remains elusive.…”
Section: Discussionmentioning
confidence: 99%
“…Asymmetrical gaits, including gallops, half‐bounds, and bounds, are commonly used by mammals at high speeds and frequently include a whole‐body aerial phase (Dunham et al, 2020; Granatosky, 2018b; Herbin et al, 2004; Hildebrand, 1977). Asymmetrical gaits are especially prevalent in small‐bodied arboreal mammals, and often represent a substantial portion of their locomotor repertoire (Dunham et al, 2020; Karantanis et al, 2017a, 2017b; Lammers & Biknevicius, 2004; Nyakatura & Heymann, 2010; Nyakatura et al, 2008; Shapiro & Young, 2010; Young, 2009).…”
Section: Introductionmentioning
confidence: 99%
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“…Animals tend to reduce speed on narrower substrates (e.g., Dunham et al, 2020; Granatosky et al, 2021; Herrel et al, 2013; Hsieh, 2016; Lammers & Biknevicius, 2004; Losos & Irschick, 1996; Stevens, 2008; Young et al, 2016), and squirrel monkeys repeat this pattern on compliant supports, although not on stable supports. Though there are relatively few studies to compare the effect of compliance on stride speed, we predicted that squirrel monkeys would similarly reduce speed on more compliant substrates because of the animal's reduced capacity to control CoM trajectory (MacLellan & Patla, 2006).…”
Section: Discussionmentioning
confidence: 99%