Validation of vertical ground reaction forces on individual limbs calculated from kinematics of horse locomotion

Bobbert, Maarten F.; Álvarez, C. B. Gómez; Weeren, P. R. van; Roepstorff, L.; Weishaupt, Michael A

doi:10.1242/jeb.02774

Cited by 47 publications

(43 citation statements)

References 42 publications

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“…If markers are easy to place on legs because the bones are visible, other locations on the body such as the hip or the tuber coxae are more difficult to detect because they are covered with muscle and fat. Because markers can be displaced by skin movements (Bobbert et al, 2007), it is important to verify that they do not move away from their original site during measurements. In addition, marker tracking analysis needs the distance from the camera to the animal to be well calibrated to reduce the risk of bias (Ceballos et al, 2004).…”

Section: Discussionmentioning

confidence: 99%

Assessment of lameness in sows using gait, footprints, postural behaviour and foot lesion analysis

Gregoire

Bergeron

D’Allaire

et al. 2013

Animal

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Lameness in sows has an economic impact on pig production and is a major welfare concern. The aim of the present project was to develop methods to evaluate and quantify lameness in breeding sows. Five methods to study lameness were compared between themselves and with visual gait scoring used as a reference: footprint analysis, kinematics, accelerometers, lying-tostanding transition and foot lesion observation. Fifty sows of various parities and stages of gestation were selected using visual gait scoring and distributed into three groups: lame (L), mildly lame (ML) and non-lame (NL). They were then tested using each method. Kinematics showed that L sows had a lower walking speed than NL sows (L: 0.83 6 0.04, NL: 0.96 6 0.03 m/s; P , 0.05), a shorter stride length than ML sows (L: 93.0 6 2.6, ML: 101.2 6 1.5 cm; P , 0.05) and a longer stance time than ML and NL sows (L: 0.83 6 0.03, ML: 0.70 6 0.03, NL: 0.69 6 0.02 s; P , 0.01). Accelerometer measurements revealed that L sows spent less time standing over a 24-h period (L: 6.3 6 1.3, ML: 13.7 6 2.4, NL: 14.5 6 2.4%; P , 0.01), lay down earlier after feeding (L: 33.4 6 4.6, ML: 41.7 6 3.1, NL: 48.6 6 2.9 min; P , 0.05) and tended to step more often during the hour following feeding (L: 10.1 6 2.0, ML: 6.1 6 0.5, NL: 5.4 6 0.4 step/min standing; P 5 0.06) than NL sows, with the ML sows having intermediate values. Visual observation of back posture showed that 64% of L sows had an arched back, compared with only 14% in NL sows (P 5 0.02). Finally, footprint analysis and observation of lying-to-standing transition and foot lesions were not successful in detecting significant differences between L, ML and NL sows. In conclusion, several quantitative variables obtained from kinematics and accelerometers proved to be successful in identifying reliable indicators of lameness in sows. Further work is needed to relate these indicators with causes of lameness and to develop methods that can be implemented on the farm.

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Section: Discussionmentioning

confidence: 99%

Assessment of lameness in sows using gait, footprints, postural behaviour and foot lesion analysis

Gregoire

Bergeron

D’Allaire

et al. 2013

Animal

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“…This is the same as seen in almost all bipeds and quadrupeds, where out-of-phase speeds are walks and in-phase speeds are runs. However, in most bipeds and quadrupeds the step frequency and the mass-specific muscular work done per unit distance (W ext ) present a discontinuity at the speed the animal switches from one gait to the other: a walk-trot or walk-run transition is observed in horses Bobbert et al, 2007), in humans (Nilsson and Thorstensson, 1989;Willems et al, 1995) and in other animals (Ahn et al, 2004;Biewener, 2006;Cavagna et al, 1977;Heglund et al, 1982a;Rubenson et al, 2004).…”

Section: Transition Speed Between Walk and Runmentioning

confidence: 99%

“…The switch in gait also noticeably influences other variables such as the footfall pattern, the limb phase (the time interval between two successive limb touchdowns) and the duty factor (the fraction of a stride during which a limb is in contact with the ground) (Hildebrand, 1977;Hildebrand, 1980;Schmitt et al, 2006). Furthermore, in most cases the presence of a whole-body aerial phase appears when the animal starts to bounce (Biewener, 2006;Biknevicius and Reilly, 2006), and this results in a marked increase in vertical peak force (Biewener, 2006;Bobbert et al, 2007). Apart from a few exceptions -such as the Elegant-crested Tinamou (Hancock et al, 2007), the giant Galapagos tortoise (Zani et al, 2005) and the alligator (Willey et al, 2004) -the kinematics (e.g.…”

Section: Introductionmentioning

confidence: 99%

Biomechanics of locomotion in Asian elephants

Genin

Willems

Cavagna

et al. 2010

Journal of Experimental Biology

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SUMMARYElephants are the biggest living terrestrial animal, weighing up to five tons and measuring up to three metres at the withers. These exceptional dimensions provide certain advantages (e.g. the mass-specific energetic cost of locomotion is decreased) but also disadvantages (e.g. forces are proportional to body volume while supportive tissue strength depends on their cross-sectional area, which makes elephants relatively more fragile than smaller animals). In order to understand better how body size affects gait mechanics the movement of the centre of mass (COM) of 34 Asian elephants (Elephas maximus) was studied over their entire speed range of 0.4-5.0ms -1 with force platforms. The mass-specific mechanical work required to maintain the movements of the COM per unit distance is ~0.2Jkg . At high speeds, elephants use a bouncing mechanism with little exchange between kinetic and potential energies of the COM, although without an aerial phase. Elephants increase speed while reducing the vertical oscillation of the COM from about 3cm to 1cm.

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“…Hyperextension of the metacarpophalangeal (MCP) joint, even in slower gaits such as walking, causes the long digital flexor tendons to stretch, resulting in the storage and release of elastic strain energy (Biewener, 1998). This mechanism is primarily responsible for the distal forelimb acting like a passive spring, allowing the animal to effectively bounce from stride to stride (Bobbert et al, 2007;McGuigan and Wilson, 2003;Witte et al, 2004). Although storage and utilization of strain energy reduces the need for more expensive muscular work (Butcher et al, 2009), it also may increase the likelihood of injury, as relatively high forces are needed to stretch the tendons and ligaments during stance.…”

Section: Introductionmentioning

confidence: 99%

Relationship between muscle forces, joint loading and utilization of elastic strain energy in equine locomotion

Harrison

Whitton

Kawcak

et al. 2010

Journal of Experimental Biology

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SUMMARYStorage and utilization of strain energy in the elastic tissues of the distal forelimb of the horse is thought to contribute to the excellent locomotory efficiency of the animal. However, the structures that facilitate elastic energy storage may also be exposed to dangerously high forces, especially at the fastest galloping speeds. In the present study, experimental gait data were combined with a musculoskeletal model of the distal forelimb of the horse to determine muscle and joint contact loading and muscle-tendon work during the stance phase of walking, trotting and galloping. The flexor tendons spanning the metacarpophalangeal (MCP) joint -specifically, the superficial digital flexor (SDF), interosseus muscle (IM) and deep digital flexor (DDF) -experienced the highest forces. Peak forces normalized to body mass for the SDF were 7.3±2.1, 14.0±2.5 and 16.7±1.1Nkg -1 in walking, trotting and galloping, respectively. The contact forces transmitted by the MCP joint were higher than those acting at any other joint in the distal forelimb, reaching 20.6±2.8, 40.6±5.6 and 45.9±0.9Nkg -1 in walking, trotting and galloping, respectively. The tendons of the distal forelimb (primarily SDF and IM) contributed between 69 and 90% of the total work done by the muscles and tendons, depending on the type of gait. The tendons and joints that facilitate storage of elastic strain energy in the distal forelimb also experienced the highest loads, which may explain the high frequency of injuries observed at these sites.

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Validation of vertical ground reaction forces on individual limbs calculated from kinematics of horse locomotion

Cited by 47 publications

References 42 publications

Assessment of lameness in sows using gait, footprints, postural behaviour and foot lesion analysis

Assessment of lameness in sows using gait, footprints, postural behaviour and foot lesion analysis

Biomechanics of locomotion in Asian elephants

Relationship between muscle forces, joint loading and utilization of elastic strain energy in equine locomotion

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