Statistical parametric mapping of the regional distribution and ontogenetic scaling of foot pressures during walking in Asian elephants (<i>Elephas maximus</i>)

Panagiotopoulou, Olga; Pataky, Todd C.; Hill, Zoe; Hutchinson, John R.

doi:10.1242/jeb.065862

Cited by 49 publications

(126 citation statements)

References 20 publications

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“…The experimental approach was similar to that previously used by Panagiotopoulou et al . [4] and did not cause any discomfort to the animals.…”

Section: Methodsmentioning

confidence: 99%

“…The template image (isocontour of threshold 5 kPa), with which all other images were aligned, was the first image to meet the inclusion criteria (see Panagiotopoulou et al . [4]: Material and Methods). Source (non-template) images were manually translated and rotated using the keyboard to align them with the template of each foot (fore left (FL), fore right (FR), hind left (HL), hind right (HR)).…”

Section: Methodsmentioning

confidence: 99%

“…the maximum pressure over time at a particular location) were focused towards the tips of the outermost (lateral) toes (digits III, IV and V) where pathologies are most prevalent in elephants in general, and that the lowest pressures were in the middle and towards the rear of the feet, directly under the fat pad. Pressure reduction underneath the fat pad can be attributed to the compliance of the tissue but also to the observation that elephants minimize heel-only contact while walking, using mainly the front part of their feet to produce vertical forces as they roll over the fat pad during ground contact [4]. …”

Section: Introductionmentioning

confidence: 99%

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Foot pressure distributions during walking in African elephants (Loxodonta africana)

et al. 2016

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Elephants, the largest living land mammals, have evolved a specialized foot morphology to help reduce locomotor pressures while supporting their large body mass. Peak pressures that could cause tissue damage are mitigated passively by the anatomy of elephants' feet, yet this mechanism does not seem to work well for some captive animals. This study tests how foot pressures vary among African and Asian elephants from habitats where natural substrates predominate but where foot care protocols differ. Variations in pressure patterns might be related to differences in husbandry, including but not limited to trimming and the substrates that elephants typically stand and move on. Both species' samples exhibited the highest concentration of peak pressures on the lateral digits of their feet (which tend to develop more disease in elephants) and lower pressures around the heel. The trajectories of the foot's centre of pressure were also similar, confirming that when walking at similar speeds, both species load their feet laterally at impact and then shift their weight medially throughout the step until toe-off. Overall, we found evidence of variations in foot pressure patterns that might be attributable to husbandry and other causes, deserving further examination using broader, more comparable samples.

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“…The experimental approach was similar to that previously used by Panagiotopoulou et al . [4] and did not cause any discomfort to the animals.…”

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Foot pressure distributions during walking in African elephants (Loxodonta africana)

et al. 2016

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“…Elephants are unusual in that they have a subunguligrade skeletal foot posture, but their digital cushion renders them functionally plantigrade, because the digital cushion (containing an enlarged strut-like "predigit") directly supports body weight Hutchinson et al, 2011).Their substantial digital cushions extend proximally from the sole to the metacarpals, providing almost 40 % of the foot's total volume (Warner, 2014). Elephant digital cushions are formed of chambers of differing geometry filled with adipose tissue, with collagen, reticulin and elastic fibers also present (Weissengruber et al, 2006 PrePrints horse digital cushions, meaning that they are better adapted to distributing and thus minimising high pressures (Panagiotopoulou et al, 2012) and dampening impact forces (Aerts et al, 1996;Warner et al, 2013)? And do supposedly disproportionate external foot pressures present a challenge to large animals with regards to foot health?…”

Section: Introductionmentioning

confidence: 99%

“…Does the material composition of elephant digital cushions lead to greater compliance and viscosity compared to horse digital cushions, meaning that they are better adapted to distributing and thus minimising high pressures (Panagiotopoulou et al, 2012) and dampening impact forces (Aerts et al, 1996;Warner et al, 2013)? And do supposedly disproportionate external foot pressures present a challenge to large animals with regards to foot health?…”

Section: Introductionmentioning

confidence: 99%

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Supplemental Information 2: Elephants: Individual Variation in Mean Internal Pressure by Region.

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Horses and elephants have extreme foot designs; horses have an unguligrade foot posture with small, single-toed, rigid hooves housing a small fibrous digital cushion, whereas elephants have large, multi-toed, functionally plantigrade, compliant feet with large adipose filled digital cushions. The morphology of the digital cushion is divergent in these species, in terms of its size, shape, volume, composition and organisation. In the context of foot-ground contact this is interesting, because feet nonetheless have to perform similar mechanical functions in all terrestrial species. How well the digital cushion functions under load may contribute to the aetiopathogenesis of foot disease; a sub-optimal digital cushion is less likely to distribute (and thus reduce) high pressures, moderate impact shock and vibration, or prevent unwarranted bone displacement.In this study, we seek to understand how the digital cushion morphologies evident in horse and elephant feet influence internal and external foot pressures. Our novel use of invasive blood pressure monitoring equipment, combined with a pressure pad and force plate, enabled measurements of (ex vivo) digital cushion pressure under increasing axial loads in seven horse and six elephant forefeet. Linear mixed effects models (LMER) revealed that internal digital cushion pressures increase under load and differ depending on region; elephant feet experienced higher magnitudes of medial digital cushion pressure, whereas horse feet experienced higher magnitudes of centralised digital cushion pressure. Direct comparison of digital cushion pressure magnitudes in both species, at equivalent loads relative to body weight, revealed that medial and lateral pressures increased more rapidly with load in elephant limbs. Within the same approximate region, internal pressures exceeded external, palmar pressures (on the sole of the foot), supporting previous Finite Element (FE) predictions. High pressures and large variations in pressure may relate to the development of foot pathology, which is a major concern in horses and elephants in a We suggest that heterogeneity within the digital cushion allows it to perform conflicting mechanical functions during locomotion; different digital cushion regions may be responsible for specific functions and therefore feature appropriate properties to do so. Determining how internal structures such as the digital cushion respond to locomotor loading is essential to understanding foot health and pathology, as well as the functional consequences of evolutionary changes in foot morphology. PeerJ PrePrints PrePrints IntroductionDigital cushions are specialised fatty/fibrous pads (Wearing and Smeathers 2011) that protect bony prominences within the fore (manus) and hind feet (pes). As well as absorbing shock at foot impact, it has been proposed that these structures may distribute and thus reduce high, localised pressures (and loads) which can cause damage if their magnitudes exceed tissue safety thresholds. Mammalian digital cushion morphology shows ...

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“Keep your feet on the ground”: Simulated range of motion and hind foot posture of the Middle Jurassic sauropod Rhoetosaurus brownei and its implications for sauropod biology

Jannel

Nair

Panagiotopoulou

et al. 2019

Journal of Morphology

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The biomechanics of the sauropod dinosaur pes is poorly understood, particularly among the earliest members of the group. To date, reasonably complete and articulated pedes in Early Middle Jurassic sauropods are rare, limited to a handful of taxa. Of these, Rhoetosaurus brownei, from eastern Australia, is currently the only one from the Gondwanan Middle Jurassic that preserves an articulated pes. UsingRhoetosaurus brownei as a case exemplar, we assessed its paleobiomechanical capabilities and pedal posture. Physical and virtual manipulations of the pedal elements were undertaken to evaluate the range of motion between the pedal joints, under both bone-to-bone and cartilaginous scenarios. Using the results as constraints, virtual reconstructions of all possible pedal postures were generated. We show that Rhoetosaurus brownei was capable of significant digital mobility at the osteological metatarsophalangeal and distal interphalangeal joints. We assume these movements would have been restricted by soft tissue in life but that their presence would have helped in the support of the animal. Further insights based on anatomy and theoretical mechanical constraints restricted the skeletal postures to a range encompassing digitigrade to subunguligrade stances. The approach was extended to additional sauropodomorph pedes, and some validation was provided via the bone data of an African elephant pes. Based on the resulting pedal configurations, the in-life plantar surface of the sauropod pes is inferred to extend caudally from the digits, with a soft tissue pad supporting the elevated metatarsus. The plantar pad is inferred to play a role in the reduction of biomechanical stresses, and to aid in support and locomotion. A pedal pad may have been a key biomechanical innovation in early sauropods, ultimately resulting in a functionally plantigrade pes, which may have arisen during the Early to Middle Jurassic. Further mechanical studies are ultimately required to permit validation of this long-standing hypothesis.

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Statistical parametric mapping of the regional distribution and ontogenetic scaling of foot pressures during walking in Asian elephants (Elephas maximus)

Cited by 49 publications

References 20 publications

Foot pressure distributions during walking in African elephants (Loxodonta africana)

Foot pressure distributions during walking in African elephants (Loxodonta africana)

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“Keep your feet on the ground”: Simulated range of motion and hind foot posture of the Middle Jurassic sauropod Rhoetosaurus brownei and its implications for sauropod biology

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