Biomechanical determinants of transverse and rotary gallop in cursorial mammals

Biancardi, Carlo M.; Minetti, Alberto E.

doi:10.1242/jeb.073031

Cited by 62 publications

(66 citation statements)

References 77 publications

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“…This simply requires a visual check and comparison with expected gait transition values (Heglund et al, 1974). Our results fit with previous observations (Biancardi and Minetti, 2012) that dogs perform transverse and rotary gallops at low and high speeds, respectively ( Fig. 2A,D and B,E and Fig.…”

Section: Resultssupporting

confidence: 90%

An exploratory clustering approach for extracting stride parameters from tracking collars on free ranging wild animals

Dewhirst

Roskilly

Hubel

et al. 2016

Journal of Experimental Biology

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Changes in stride frequency and length with speed are key parameters in animal locomotion research. They are commonly measured in a laboratory on a treadmill or by filming trained captive animals. Here, we show that a clustering approach can be used to extract these variables from data collected by a tracking collar containing a GPS module and tri-axis accelerometers and gyroscopes. The method enables stride parameters to be measured during free-ranging locomotion in natural habitats. As it does not require labelled data, it is particularly suitable for use with difficult to observe animals. The method was tested on large data sets collected from collars on free-ranging lions and African wild dogs and validated using a domestic dog.

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Section: Resultssupporting

confidence: 90%

An exploratory clustering approach for extracting stride parameters from tracking collars on free ranging wild animals

Dewhirst

Roskilly

Hubel

et al. 2016

Journal of Experimental Biology

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“…Dogs were also free to choose the preferred gait between recorded strides of interest. In most cases, and as is expected at high rates of speed, the dogs in this study exhibited a rotary gallop when performing the A-frame and jumping tasks [66]. It is unlikely that this would have a large impact on the findings from this study since these factors would affect both the right and left sides, and our measures were only from the left side.…”

Section: Discussionmentioning

confidence: 67%

The magnitude of muscular activation of four canine forelimb muscles in dogs performing two agility-specific tasks

et al. 2016

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BackgroundThe purpose of this study was to measure the muscular activation in four forelimb muscles while dogs performed agility tasks (i.e., jumping and A-frame) and to provide insight into potential relationships between level of muscular activation and risk of injury. Muscle activation in eight healthy, client-owned agility dogs was measured using ultrasound-guided fine-wire electromyography of four specific forelimb muscles: Biceps Brachii, Supraspinatus, Infraspinatus, and Triceps Brachii – Long Head, while dogs performed a two jump sequence and while dogs ascended and descended an A-frame obstacle at two different competition heights.ResultsThe peak muscle activations during these agility tasks were between 1.7 and 10.6 fold greater than walking. Jumping required higher levels of muscle activation compared to ascending and descending an A-frame, for all muscles of interest. There was no significant difference in muscle activation between the two A-frame heights.ConclusionsCompared to walking, all of the muscles were activated at high levels during the agility tasks and our findings indicate that jumping is an especially demanding activity for dogs in agility. This information is broadly relevant to understanding the pathophysiology of forelimb injuries related to canine athletic activity.

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“…Rotary gallops (opposite side leads), conversely, are usually characterized by prominent spinal flexion/extension, and an “extended” suspension phase (limbs extended), or by a combination of both gathered and extended suspension phases (Hildebrand, , ). Rotary gallops are typically associated with increased maneuverability and with greater acceleration, and tend to be preferred by smaller, faster, and more agile mammals (Biancardi and Minetti, ).…”

Section: Discussionmentioning

confidence: 99%

Effects of Substrate Size and Orientation on Quadrupedal Gait Kinematics in Mouse Lemurs (Microcebus murinus)

2016

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As the smallest living primate, the mouse lemur is a suitable model for reconstructing the locomotor mechanisms by which primate ancestors might have responded to the challenges of an arboreal environment. In this study, we tested the effects of substrate diameter and orientation on quadrupedal gait kinematics in mouse lemurs (Microcebus murinus). Mouse lemurs highly preferred asymmetrical to symmetrical gaits as they moved across a flat board and poles of three diameters (2.5, 1.0, and 0.5 cm), set at horizontal, 30°inclined, and 30°declined orientations. During symmetrical gaits, mouse lemurs used diagonal sequence walking and ambling gaits on the same substrates and at the same duty factors for which some similarly sized nonprimate mammals use lateral sequence gaits, suggesting that reliance on diagonal sequence walking in primates may not be explicitly a response to body size relative to substrate diameter. When using asymmetrical gaits, kinematic adjustments to small diameter and/or nonhorizontal substrates included a preference for transverse gallops over other gaits, the avoidance of whole-body suspensions, increases in limb contact duration, and increases in the time interval between the landing of trailing and leading limbs. All of these adjustments are consistent with increasing locomotor stability by dampening center of mass movements and reducing the forces imparted to the substrate. Like mouse lemurs, small-bodied ancestral primates likely used symmetrical gaits occasionally, but more frequently used asymmetrical gaits that were adjusted in response to challenging substrates. Therefore, asymmetrical gait dynamics should be incorporated into hypotheses addressing early primate locomotor evolution.

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Biomechanical determinants of transverse and rotary gallop in cursorial mammals

Cited by 62 publications

References 77 publications

An exploratory clustering approach for extracting stride parameters from tracking collars on free ranging wild animals

An exploratory clustering approach for extracting stride parameters from tracking collars on free ranging wild animals

The magnitude of muscular activation of four canine forelimb muscles in dogs performing two agility-specific tasks

Effects of Substrate Size and Orientation on Quadrupedal Gait Kinematics in Mouse Lemurs (Microcebus murinus)

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