The effect of three different head–neck positions on the average <scp>EMG</scp> activity of three important neck muscles in the horse

Kienapfel, Kathrin

doi:10.1111/jpn.12210

Cited by 17 publications

(18 citation statements)

References 23 publications

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“…Its bending moments will assume their greatest values, if the neck is stretched or if acceleration forces are transmitted through the forelimbs, especially in the canter. Both require increased muscle activities, which indeed have been observed by Kienapfel ().…”

Section: Discussionsupporting

confidence: 73%

“…In a heavy beam, which is supported like body stem of horse on anterior and posterior limbs, we can expect tensile forces—that is muscle activity—along the ventral side of the belly as well as along the dorsal side of the anterior thorax and proximal neck. The latter has indeed been found in an earlier study (Kienapfel, ). If the same beam is supported near its rear (caudal) end by a forwardly inclined leg, with ground contact underneath its belly, tensile forces will occur at the posterior back and rear margin of the beam.…”

Section: Introductionsupporting

confidence: 87%

“…Between the supports, the trunk tends to sag ventrally downwards, so that compressing forces occur along the upper margin and tension at the lower. This distribution of internal forces is in agreement with the arrangement of the compression‐resistant skeleton (vertebral column and sternum, pelvis, (Preuschoft & Fritz, )) and the tension‐producing musculature (neck, cranial thoracic dorsal musculature and several shoulder muscles, as detailed in Kienapfel ()). Aside from the muscles, there exist very strong strands of connective tissue, which can take over at least part of the tensile forces, and are claimed by several researchers (Gellman & Bertram, ; Nickel, Schummer, Seiferle, & Frewein, ; Slijper, ; Zschokke, ) to do so.…”

Section: Introductionsupporting

confidence: 85%

“…Former investigations have shown that in the phase of forelimb support, the dorsal neck muscles (m. splenius, anterior part of m. trapezius) are active (Kienapfel, ).…”

Section: Discussionmentioning

confidence: 99%

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The biomechanical construction of the horse's body and activity patterns of three important muscles of the trunk in the walk, trot and canter

Kienapfel

Preuschoft

Wulf

et al. 2017

Animal Physiology Nutrition

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The activity patterns of trunk muscles are commonly neglected, in spite of their importance for maintaining body shape. Analysis of the biomechanics of the trunk under static conditions has led to predictions of the activity patterns. These hypotheses are tested experimentally by surface electromyography (EMG). Five horses, with and without a rider, were examined in the walk, trot and canter. Footfall was synchronised with EMG by an accelerometer. Averages of ten consecutive cycles were calculated and compared by statistical methods. The start and stop times of the muscle activities of 5-10 undisturbed EMG plots were determined and the averages and standard deviations calculated. In walking, muscle activities are minor. Electromyography (EMG) activity was increased in the m. rectus during the three-limb support. When the bending moments assume their greatest values, for example while the horses' mass is accelerated upward (two times earth acceleration) in the diagonal support phases in trot and canter the m. rectus, connecting the sternum with the pubic bone is most active. The m. obl. externus is most active when the torsional and bending moments are greatest during the same support phases, but not bilaterally, because the forces exerted on one side by the (recorded) m. obl. externus are transmitted on the other side by the (not recorded) m. obl. internus. While the hindlegs touch the ground in the trot and canter, ground reaction forces tend to flex the hip joint and the lumbar spine. Therefore, the vertebral column needs to be stabilised by the ipsilateral m. longissimus dorsi, which in fact can be observed. As a whole, our EMG data confirm exactly what has been predicted by theoretical analysis.

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Section: Discussionsupporting

confidence: 73%

Section: Introductionsupporting

confidence: 87%

Section: Introductionsupporting

confidence: 85%

“…Former investigations have shown that in the phase of forelimb support, the dorsal neck muscles (m. splenius, anterior part of m. trapezius) are active (Kienapfel, ).…”

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

The biomechanical construction of the horse's body and activity patterns of three important muscles of the trunk in the walk, trot and canter

Kienapfel

Preuschoft

Wulf

et al. 2017

Animal Physiology Nutrition

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“…Further, at walk the horse moves with substantially less muscle activity in the lower back and abdomen (Wakeling et al, 2007;Zsoldos et al, 2010), and with larger lateral movement of the body center of mass, compared to trot (Buchner et al, 2000). Maintaining a defined, non-natural, HNP alters neck muscle activity compared to the free position (Kienapfel, 2014), which may affect the coordination between the neck and trunk movements and necessitate increased core muscle tension. Both effects influence the normal gait mechanics of the walk, as evidenced by the finding in this and earlier studies that a restrained HNP decreases stride length at this gait (Gómez et al, 2006;Rhodin et al, 2005;Weishaupt et al, 2006).…”

Section: Discussionmentioning

confidence: 99%

Effect of different head and neck positions on kinematics of elite dressage horses ridden at walk on treadmill

Rhodin

Byström

Roepstorff

et al. 2018

CEP

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The debate on proper head and neck positions (HNP) in horse training is lively, but little is known about the biomechanical effects of various HNPs in horses ridden at walk. The aim was to quantify the influence of different HNPs on the kinematics of horses ridden at walk. The standard competition position (HNP2) was compared to a free, unrestrained position (HNP1), more flexed positions (HNP3, HNP4), a raised extended position (HNP5) and a forward-downward extended position (HNP6). An experimental study in seven high-level dressage horses ridden at walk on a treadmill was designed. Kinetic and kinematic measurements were obtained with different HNPs. HNP2 was used as a speed-matched reference. Kinematics were measured from skin-fixed markers recorded by high-speed video cameras. The kinetics of the limbs were measured by the force-measuring instrumentation of the treadmill. In HNP1, compared to HNP2, the lumbar back and the pelvis were more horizontally positioned (more extended), and fore- and hindlimb pro- and retraction increased, with increased caudal rotation of the femur during the second half of hindlimb stance. HNP6 induced similar changes as HNP1, but caused larger increases in forelimb pro- and retraction. In HNP3, HNP4 and HNP5 the pelvis was more angled (less extended) compared to HNP2 at hindlimb midstance, and in HNP3 and HNP4 also in early hindlimb stance. All three HNPs caused increased maximum flexion of the tarsus, stifle and metatarsophalangeal joint during the swing phase. HNP3 and HNP5, but not HNP4, had a decreasing influence on fore- and hindlimb pro- and retraction, and decreased caudal rotation of the femur during the second half of hindlimb stance.The main limitation was that horses were not ridden overground and the number of horses was small. Our conclusion was that changes in head and neck position can markedly affect the horse’s movement pattern at walk.

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Surface EMG Recordings in Freely Moving Rats: A Promising Method for Motor Evaluation and for Minimizing Animal Use in Research

Rivolta,

Cano,

Tagashira

et al. 2024

IFMBE Proceedings

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The effect of three different head–neck positions on the average EMG activity of three important neck muscles in the horse

Cited by 17 publications

References 23 publications

The biomechanical construction of the horse's body and activity patterns of three important muscles of the trunk in the walk, trot and canter

The biomechanical construction of the horse's body and activity patterns of three important muscles of the trunk in the walk, trot and canter

Effect of different head and neck positions on kinematics of elite dressage horses ridden at walk on treadmill

Surface EMG Recordings in Freely Moving Rats: A Promising Method for Motor Evaluation and for Minimizing Animal Use in Research

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