Back motion in unridden horses in walk, trot and canter on a circle

Egenvall, Agneta; Engström, Hanna; Byström, Anna

doi:10.1007/s11259-023-10132-y

Cited by 4 publications

(5 citation statements)

References 33 publications

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“…During galloping, our results showed a mean range of flexion of 9.5° (±1.3°) and a mean range of extension of 9.8° (±1.4°) in a large circle in the left rein. These results are consistent with the results of Egenvall et al (2022) [ 15 ], who found a mean range of flexion/extension of 9.2° in the same conditions [ 15 ]. These converging results with MOCAP allow us to compare our IMU results to the MOCAP results, which could be considered a reliable reference.…”

Section: Discussionsupporting

confidence: 93%

“…Other studies measured the flexion and extension ranges of motion in vivo using a motion capture system (MOCAP) [ 1 , 5 , 13 , 14 , 15 ]. These studies showed flexion/extension ranges of motion of approximately 4° between T6, T13, and T18 while trotting in a straight line on a hard surface [ 1 ]; 4.91° and 4.97° between the withers, T15 and the pelvis, while trotting in a straight line on hard and soft surfaces, respectively [ 5 ]; 3.07° at T17 (rotation around the mediolateral axis of the T17 markers) during trotting in a straight line on a hard surface [ 13 ]; and 2.9° between T13, T18, and the pelvis during trotting in a straight line on a hard or soft surface [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

“…These studies showed flexion/extension ranges of motion of approximately 4 • between T6, T13, and T18 while trotting in a straight line on a hard surface [1]; 4.91 • and 4.97 • between the withers, T15 and the pelvis, while trotting in a straight line on hard and soft surfaces, respectively [5]; 3.07 • at T17 (rotation around the mediolateral axis of the T17 markers) during trotting in a straight line on a hard surface [13]; and 2.9 • between T13, T18, and the pelvis during trotting in a straight line on a hard or soft surface [14]. Recently, a study showed flexion/extension ranges of motion of 3.86 • and 4.05 • during walking, 5.96 • and 5.66 • during trotting, and 9.15 • and 9.17 during galloping between the withers, T15, and the pelvis in a circle, respectively, at the left and right rein on a soft surface [15]. MOCAP allows the monitoring of these spatiotemporal events [16], including thoracolumbar angle evolution [5].…”

Section: Introductionmentioning

confidence: 99%

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A Method for Quantifying Back Flexion/Extension from Three Inertial Measurement Units Mounted on a Horse’s Withers, Thoracolumbar Region, and Pelvis

Hatrisse,

Macaire,

Hebert

et al. 2023

Sensors

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Back mobility is a criterion of well-being in a horse. Veterinarians visually assess the mobility of a horse’s back during a locomotor examination. Quantifying it with on-board technology could be a major breakthrough to help them. The aim of this study was to evaluate the accuracy of a method of quantifying the back mobility of horses from inertial measurement units (IMUs) compared to motion capture (MOCAP) as a gold standard. Reflective markers and IMUs were positioned on the withers, eighteenth thoracic vertebra, and pelvis of four sound horses. The horses performed a walk and trot in straight lines and performed a gallop in circles on a soft surface. The developed method, based on the three IMUs, consists of calculating the flexion/extension angle of the thoracolumbar region. The IMU method showed a mean bias of 0.8° (±1.5°) (mean (±SD)) and 0.8° (±1.4°), respectively, for the flexion and extension movements, all gaits combined, compared to the MOCAP method. The results of this study suggest that the developed method has a similar accuracy to that of MOCAP, opening up possibilities for easy measurements under field conditions. Future studies will need to examine the correlations between these biomechanical measures and clinicians’ visual assessment of back mobility defects.

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Section: Discussionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Method for Quantifying Back Flexion/Extension from Three Inertial Measurement Units Mounted on a Horse’s Withers, Thoracolumbar Region, and Pelvis

Hatrisse,

Macaire,

Hebert

et al. 2023

Sensors

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“…Scripts were written in Matlab (version R2020a; Mathworks, Natick, MA, USA) for analysis of kinematic data, producing time-series variables (see below). Data were processed as previously described in Egenvall, Engström & Byström (2023) . In short, circle radius was determined for each measurement (trial) through fitting a circle to the x and y (horizontal plane) coordinate data from the lumbosacral joint marker using the least squares method.…”

Section: Methodsmentioning

confidence: 99%

“…Hind limb maximum protraction was then identified. The kinematic variables were time-normalised to 0–100% (201 values per stride) before extraction of data for statistical analysis ( Egenvall, Engström & Byström, 2023 ).…”

Section: Methodsmentioning

confidence: 99%

Pilot study of locomotor asymmetry in horses walking in circles with and without a rider

Egenvall,

Clayton,

Byström

2023

PeerJ

Self Cite

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Background Horses commonly show asymmetries that manifest as left (L)-right (R) differences in vertical excursion of axial body segments. Moving on a circle confounds inherent individual asymmetries. Our goals were to evaluate individual and group asymmetry patterns and compare objective data with subjective impressions of side preference/laterality in horses walking on L and R circles. Methods Fifteen horses walked on L and R circles unridden and ridden on long and short reins. Optical motion capture (150 Hz) tracked skin-fixed markers. Variables were trunk horizontal angle; neck-to-trunk angle; vertical range of motion (ROM) for the head, withers and sacrum; ROM for pelvic roll, pitch, and yaw; mean pelvic pitch; and ROM for hip, stifle and tarsal joints. Differences between inside and outside hind steps were determined for vertical minima and maxima of the head (HMinDiff/HMaxDiff), withers (WMinDiff/WMaxDiff) and sacrum (PMinDiff/PMaxDiff). Subjective laterality was provided by owners. Data analysis used mixed models, first without and then with subjective laterality. Iterative k-means cluster analysis was used to associate biomechanical variables with subjective laterality. Results PMaxDiff, PMinDiff and WMaxDiff indicated R limb asymmetry in both directions. WMinDiff indicated L (inside) fore asymmetry for L direction but was close to zero for R direction. Hip ROM was significantly smaller for the inside limb in both directions (L inside/outside: 16.7° vs. 20.6°; R: 17.8° vs. 19.4°). Stifle ROM was significantly larger for the inside limb in both directions (L: 43.1° vs. 39.0°; R: 41.9° vs. 40.4°). Taking the general direction effect into account the R hip and L stifle had larger ROM. Adding laterality to the models (seven horses L- vs. six horses R-hollow), PMaxDiff R hind asymmetry was more obvious for L-hollow horses than for R-hollow horses. L-hollow horses had greater pelvic roll ROM moving in L vs. R direction. L-hollow horses had smaller inside and greater outside hip joint ROM in L vs. R direction. R-hollow horses had a significant difference in HMinDiff between L (0 mm) and R (−14 mm) directions, indicating less head lowering at outside forelimb midstance in R direction, and larger outside tarsal ROM in R (38.6°) vs. L (37.4°) direction (p ≤ 0.05). The variables that agreed most frequently with subjective laterality in cluster analysis were pelvic roll ROM, followed by HMinDiff and PMaxDiff. Conclusion Differences between horses walking in L and R directions were found both at group and individual levels, as well as evidence of associations with subjective laterality. Horses maintained more symmetric hip and stifle ROM and withers vertical motion when walking on the R circle. Findings suggest that left and right lateralised horses may not be perfect mirror images. Pelvic roll ROM emerged as a promising variable to determine laterality in walk as perceived by the rider, especially when considered together with other variables.

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Kinematic changes in dairy cows with induced hindlimb lameness: transferring methodology from the field of equine biomechanics

Leclercq,

Ask,

Mellbin

et al. 2024

animal

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Back motion in unridden horses in walk, trot and canter on a circle

Cited by 4 publications

References 33 publications

A Method for Quantifying Back Flexion/Extension from Three Inertial Measurement Units Mounted on a Horse’s Withers, Thoracolumbar Region, and Pelvis

A Method for Quantifying Back Flexion/Extension from Three Inertial Measurement Units Mounted on a Horse’s Withers, Thoracolumbar Region, and Pelvis

Pilot study of locomotor asymmetry in horses walking in circles with and without a rider

Kinematic changes in dairy cows with induced hindlimb lameness: transferring methodology from the field of equine biomechanics

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