Moments and power generated by the horse (Equus caballus) hind limb during jumping.
Abstract: The ability to jump over an obstacle depends upon the generation of work across the joints of the propelling limb(s). The total work generated by one hind limb of a horse and the contribution to the total work by four joints of the hind limb were determined for a jump. It was hypothesized that the hip and ankle joints would have extensor moments performing positive work, while the knee would have a flexor moment and perform negative work during the jump. Ground reaction forces and sagittal plane kinematics were simultaneously recorded during each jumping trial. Joint moment, power and work were determined for the metatarsophalangeal (MP), tarsal (ankle), tibiofemoral (knee) and coxofemoral (hip) joints. The hip, knee and ankle all flexed and then extended and the MP extended and then flexed during ground contact. Consistent with our hypothesis, large extensor moments were observed at the hip and ankle joints and large flexor moments at the knee and MP joints throughout ground contact of the hind limb. Peak moments tended to occur earlier in stance in the proximal joints but peak power generation of the hind limb joints occurred at similar times except for the MP joint, with the hip and ankle peaking first followed by the MP joint. During the first portion of ground contact (approximately 40%), the net result of the joint powers was the absorption of power. During the remainder of the contact period, the hind limb generated power. This pattern of power absorption followed by power generation paralleled the power profiles of the hip, ankle and MP joints. The total work performed by one hind limb was 0.71 J kg(-1). Surprisingly, the knee produced 85% of the work (0.60 J kg(-1)) done by the hind limb, and the positive work performed by the knee occurred during the first 40% of the take-off. There is little net work generated by the other three joints over the entire take-off. Velocity of the tuber coxae (a landmark on the pelvis of the animal) was negative (downward) during the first 40% of stance, which perhaps reflects the negative work performed to decrease the potential energy during the first 40% of contact. During the final 60% of contact, the hip, ankle and MP joints generate positive work, which is reflected in the increase of the animal's potential energy.
Publication Date: 2004-01-14 PubMed ID: 14718509DOI: 10.1242/jeb.00808Google Scholar: Lookup
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- Comparative Study
- Journal Article
- Research Support
- U.S. Gov't
- P.H.S.
Summary
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The research article investigates how different joints in a horse’s hind limb contribute to its ability to jump. The study found that the knee joint performs much of the positive work required for the jump during the first 40% of the take-off phase.
Research Methodology
- Ground reaction forces and sagittal plane kinematics were recorded simultaneously during jumping trials to understand the motion and load applied on the hind limb of a horse.
- Joint moment, power, and work were determined for the metatarsophalangeal (MP), tarsal (ankle), tibiofemoral (knee) and coxofemoral (hip) joints of the horse.
Findings
- The study revealed that the hip, knee, and ankle all flex, then extend, and the MP extends, then flexes during the horse’s contact with the ground.
- Large extensor moments were observed at the hip and ankle joints and large flexor moments at the knee and MP joints throughout ground contact of the hind limb, supporting the hypothesis.
- Peak moments occurred earlier in the proximal (closer to the center of the body) joints, with power generation happening almost simultaneously across the hind limb joints, except for the MP joint – the hip and ankle peaked first, followed by the MP joint.
- For about 40% of the ground contact phase, power was absorbed, and power was generated for the remaining period. This trend matched the power profiles of the hip, ankle, and MP joints.
Key Insights and Conclusions
- The total work executed by one hind limb was measured as 0.71 J kg(-1).
- The knee surprisingly contributed to 85% of the work (0.60 J kg(-1)) done by the hind limb, and this positive work ensued during the first 40% of the take-off.
- The other three joints (hip, ankle, and MP) generated little net work during the entire take-off phase.
- The velocity of the tuber coxae (a landmark on the animal’s pelvis) was downward during the initial 40% of stance, indicating the negative work done to reduce potential energy in the first part of contact.
- During the last 60% of the ground contact phase, the hip, ankle, and MP joints produced positive work that increased the animal’s potential energy, enabling a successful jump.
Cite This Article
APA
Dutto DJ, Hoyt DF, Clayton HM, Cogger EA, Wickler SJ.
(2004).
Moments and power generated by the horse (Equus caballus) hind limb during jumping.
J Exp Biol, 207(Pt 4), 667-674.
https://doi.org/10.1242/jeb.00808 Publication
Researcher Affiliations
- Department of Kinesiology and Health Promotion, California State Polytechnic University, Pomona, CA 91768, USA. ddutto@csupomona.edu
MeSH Terms
- Animals
- Biomechanical Phenomena
- Hindlimb / physiology
- Horses / physiology
- Locomotion / physiology
Grant Funding
- S06 GM53933 / NIGMS NIH HHS
Citations
This article has been cited 11 times.- Hobbs SJ, Clayton HM. The Olympic motto through the lens of equestrian sports. Anim Front 2022 Jun;12(3):45-53.
- St George L, Clayton HM, Sinclair J, Richards J, Roy SH, Hobbs SJ. Muscle Function and Kinematics during Submaximal Equine Jumping: What Can Objective Outcomes Tell Us about Athletic Performance Indicators?. Animals (Basel) 2021 Feb 5;11(2).
- Li G, Zhang R, Han D, Pang H, Yu G, Cao Q, Wang C, Kong L, Chengjin W, Dong W, Li T, Li J. Forelimb joints contribute to locomotor performance in reindeer (Rangifer tarandus) by maintaining stability and storing energy. PeerJ 2020;8:e10278.
- Hanot P, Herrel A, Guintard C, Cornette R. Unravelling the hybrid vigor in domestic equids: the effect of hybridization on bone shape variation and covariation. BMC Evol Biol 2019 Oct 15;19(1):188.
- Hanot P, Herrel A, Guintard C, Cornette R. The impact of artificial selection on morphological integration in the appendicular skeleton of domestic horses. J Anat 2018 Apr;232(4):657-673.
- Hanot P, Herrel A, Guintard C, Cornette R. Morphological integration in the appendicular skeleton of two domestic taxa: the horse and donkey. Proc Biol Sci 2017 Oct 11;284(1864).
- Nauwelaerts S, Allen WA, Lane JM, Clayton HM. Inertial properties of equine limb segments. J Anat 2011 May;218(5):500-9.
- Crook TC, Cruickshank SE, McGowan CM, Stubbs N, Wilson AM, Hodson-Tole E, Payne RC. A comparison of the moment arms of pelvic limb muscles in horses bred for acceleration (Quarter Horse) and endurance (Arab). J Anat 2010 Jul;217(1):26-37.
- Williams SB, Usherwood JR, Jespers K, Channon AJ, Wilson AM. Exploring the mechanical basis for acceleration: pelvic limb locomotor function during accelerations in racing greyhounds (Canis familiaris). J Exp Biol 2009 Feb;212(Pt 4):550-65.
- Crook TC, Cruickshank SE, McGowan CM, Stubbs N, Wakeling JM, Wilson AM, Payne RC. Comparative anatomy and muscle architecture of selected hind limb muscles in the Quarter Horse and Arab. J Anat 2008 Feb;212(2):144-52.
- Williams SB, Payne RC, Wilson AM. Functional specialisation of the pelvic limb of the hare (Lepus europeus). J Anat 2007 Apr;210(4):472-90.
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