Inter-stride variability triggers gait transitions in mammals and birds

Granatosky, Michael C.; Bryce, Caleb M.; Hanna, Jandy B.; Fitzsimons, Aidan; Laird, Myra F.; Stilson, Kelsey; Wall, Christine E; Ross, Callum F.

doi:10.1098/rspb.2018.1766

Cited by 42 publications

(42 citation statements)

References 56 publications

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“…During locomotion on level substrates, muscle forces produced by limb muscles must support body weight and propel the animal forward. To optimize energy expenditure, animals should only apply the amount of force necessary to achieve support, balance and propulsion (O'Connor et al, 2012;Taylor et al, 1980Taylor et al, , 1982 as increased variability in muscle force magnitude wastes considerable amounts of energy (Agiovlasitis et al, 2015;Granatosky et al, 2018a;O'Connor et al, 2012;Verdaasdonk et al, 2006). Hence, minimizing variability in muscle force generation contributes to energetic efficiency during steady-state locomotion.…”

Section: Discussionmentioning

confidence: 99%

“…Differences in rhythmicity between tachymetabolic and bradymetabolic tetrapods have been identified in limb step cycle duration (Granatosky et al, 2018a;Ross et al, 2013), but these data do not directly refer to variability in the locomotor forces. One important question is whether substrate reaction forces are also less variable in taxa with low variation in step cycle duration.…”

Section: Introductionmentioning

confidence: 99%

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Variation in limb loading magnitude and timing in tetrapods

Granatosky

McElroy

Lemelin

et al. 2019

Journal of Experimental Biology

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Comparative analyses of locomotion in tetrapods reveal two patterns of stride cycle variability. Tachymetabolic tetrapods (birds and mammals) have lower inter-cycle variation in stride duration than bradymetabolic tetrapods (amphibians, lizards, turtles and crocodilians). This pattern has been linked to the fact that birds and mammals share enlarged cerebella, relatively enlarged and heavily myelinated Ia afferents, and γ-motoneurons to their muscle spindles. Both tachymetabolic tetrapod lineages also possess an encapsulated Golgi tendon morphology, thought to provide more spatially precise information on muscle tension. The functional consequence of this derived Golgi tendon morphology has never been tested. We hypothesized that one advantage of precise information on muscle tension would be lower and more predictable limb bone stresses, achieved in tachymetabolic tetrapods by having less variable substrate reaction forces than bradymetabolic tetrapods. To test this hypothesis, we analyzed hindlimb substrate reaction forces during locomotion of 55 tetrapod species in a phylogenetic comparative framework. Variation in species means of limb loading magnitude and timing confirm that, for most of the variables analyzed, variance in hindlimb loading and timing is significantly lower in species with encapsulated versus unencapsulated Golgi tendon organs. These findings suggest that maintaining predictable limb loading provides a selective advantage for birds and mammals by allowing energy savings during locomotion, lower limb bone safety factors and quicker recovery from perturbations. The importance of variation in other biomechanical variables in explaining these patterns, such as posture, effective mechanical advantage and center-of-mass mechanics, remains to be clarified.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Variation in limb loading magnitude and timing in tetrapods

Granatosky

McElroy

Lemelin

et al. 2019

Journal of Experimental Biology

Self Cite

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“…By comparison, the functions of the locomotor system are to move the organism from place to place to acquire food and mates while avoiding predation and minimizing competition. Locomoting animals confront substrates that vary in regularity, mechanical properties and complexity, requiring limbed tetrapods to modulate overall speed and limb-joint excursion in order to maintain dynamic stability (Daley et al, 2006;Granatosky et al, 2018). Moreover, unlike chewing sequences, the goal of which is to reduce food item size, progression through a locomotor bout is not inevitably associated with progressive reduction in substrate size and complexity: the goal of locomotion is not to make the substrate flatter and/or more homogeneous.…”

Section: Cyclic Behaviors: Chewing Versus Walking and Runningmentioning

confidence: 99%

Joint angular excursions during cyclical behaviors differ between tetrapod feeding and locomotor systems

Granatosky

McElroy

Laird

et al. 2019

Journal of Experimental Biology

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Tetrapod musculoskeletal diversity is usually studied separately in feeding and locomotor systems. However, comparisons between these systems promise important insight into how natural selection deploys the same basic musculoskeletal toolkitconnective tissues, bones, nerves and skeletal muscleto meet the differing performance criteria of feeding and locomotion. In this study, we compare average joint angular excursions during cyclic behaviorschewing, walking and runningin a phylogenetic context to explore differences in the optimality criteria of these two systems. Across 111 tetrapod species, average limb-joint angular excursions during cyclic locomotion are greater and more evolutionarily labile than those of the jaw joint during cyclic chewing. We argue that these findings reflect fundamental functional dichotomies between tetrapod locomotor and feeding systems. Tetrapod chewing systems are optimized for precise application of force over a narrower, more controlled and predictable range of displacements, the principal aim being to fracture the substrate, the size and mechanical properties of which are controlled at ingestion and further reduced and homogenized, respectively, by the chewing process. In contrast, tetrapod limbed locomotor systems are optimized for fast and energetically efficient application of force over a wider and less predictable range of displacements, the principal aim being to move the organism at varying speeds relative to a substrate whose geometry and mechanical properties need not become more homogeneous as locomotion proceeds. Hence, the evolution of tetrapod locomotor systems has been accompanied by an increasing diversity of limbjoint excursions, as tetrapods have expanded across a range of locomotor substrates and environments.

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“…Not least, we only consider power and COT metrics as bi-dimensional when they will be affected by multiple properties of the environment that modulate power use, such as slope and surface penetrability [24]. This will be further complicated by gait changes [30][31][32][33][34]. This work nevertheless demonstrates the profound effect that turns have on cost of transport for terrestrial animals using humans as a model, although we expect the principle to be the same for flying and aquatic animals.…”

Section: Discussionmentioning

confidence: 99%

Path tortuosity changes the transport cost paradigm in terrestrial animals

Wilson

Rose

Metcalfe

et al. 2020

Preprint

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Animal movement paths are variously tortuous, with high turn rates predicted to be energetically costly, especially at high speeds. Animals travel most efficiently at the speed that gives the lowest cost of transport (COT), a well-defined point for movement in fluid media. However, theoretically, land animals should travel at their maximum speed to minimize COT, which they do not, instead travelling at walking pace. We measured oxygen consumption in humans to demonstrate that the energetic costs of turning increase disproportionately with both speed and angular velocity. This resulted in the minimum COT speed occurring at very low speeds, which reduced with increased path tortuosity. Data on turn rates from six free-ranging terrestrial species underpinned this because all individuals turned faster at the slowest speeds across the full speed range. The optimum movement speed for minimum COT in land animals thus depends on the environment and behavior since both affect track tortuosity.

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Inter-stride variability triggers gait transitions in mammals and birds

Cited by 42 publications

References 56 publications

Variation in limb loading magnitude and timing in tetrapods

Variation in limb loading magnitude and timing in tetrapods

Joint angular excursions during cyclical behaviors differ between tetrapod feeding and locomotor systems

Path tortuosity changes the transport cost paradigm in terrestrial animals

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