The impact of body position on measurement of equine lumbar and hindquarter volume using 3-dimensional scans

IF 0.6 Q3 VETERINARY SCIENCES Comparative Exercise Physiology Pub Date : 2022-11-15 DOI:10.3920/cep220021
A. Borer-Matsui, C. Donnelly, S. Valberg
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Abstract

Well-developed musculature is important for performance yet difficult to quantify. Recently, we validated infrared 3-dimensional (3-D) photonic scanning as an accurate measure of body volume and proxy for regional muscle mass in horses. Our current objective was to determine the impact of body position on measures of lumbar (LV) and hindquarter (HQV) volume. Anatomic markers were placed on 8 horses, positioned at: (1) four hooves square, (2) neck turned ~25°, (3) head raised mean 17 cm, (4) one hind hoof (HH) forward 14±5 cm, (5) a front and contralateral HH ~15 cm all offset, (6) one HH resting. A handheld Occipital Structure Sensor photonic scanner, iPad, Skanect and Materialise 3-Matic programs captured LV and HQV. Measured LV and HQV for whole, same and opposite-side with altered head positions and whole LV and HQV with altered HH positions were compared to volume standing square using repeated measures ANOVA. The volumes of the opposite-side or same-side with altered HH positions were compared to the corresponding side when square using a paired t test with multiple test correction (P<0.017). Head elevated negatively impacted measured left LV (-10% difference, P=0.1) compared to square, however, differences were not significant. Head turned did not impact measured LV. Resting HH significantly increased measured whole (18%, P=0.04) and same-side LV (49%, P=0.001) versus square but not the opposite-side LV. One HH forward (whole 16%, P=0.02; same-side 19%, P=0.01) or all offset (whole 14%, P=0.002; same-side 27%, P=0.0001) significantly increased measured whole or same-side LV versus square. Measured HQV was not impacted by head elevated or limb position but was 2% higher on the opposite-side of the turned head (P=0.01). We conclude that alterations in body position have minimal impact on measured HQV, whereas accurate assessment of LV requires horses stand squarely.
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体位对使用三维扫描测量马腰椎和后腿体积的影响
发达的肌肉组织对表现很重要,但很难量化。最近,我们验证了红外三维光子扫描作为马身体体积的准确测量和区域肌肉质量的代理。我们目前的目的是确定体位对腰椎(LV)和后躯(HQV)体积测量的影响。在8匹马上放置解剖标记,位置为:(1)4蹄方形,(2)颈部转动~25°,(3)头抬高平均17 cm,(4)一只后蹄向前14±5 cm,(5)一只前肢和对侧肢向前偏移~15 cm,(6)一只后蹄休息。手持式枕结构传感器光子扫描仪,iPad, Skanect和Materialise 3-Matic程序捕获LV和HQV。采用重复测量方差分析(repeated measures ANOVA)将改变头位的全侧、同侧和对侧的LV和HQV以及改变HH位的全侧LV和HQV与容积站立方进行比较。不同HH位置的对侧或同侧的体积与对应侧的体积进行对比,采用多重检验修正的配对t检验(P<0.017)。与正方相比,头部升高对左左左室测量值产生负影响(-10%差异,P=0.1),但差异不显著。头部转动不影响测量的LV。静息HH显著增加了测量的整体(18%,P=0.04)和同侧LV (49%, P=0.001),而非对侧LV。1例HH forward(整体16%,P=0.02;同侧19%,P=0.01)或全部偏移(整体14%,P=0.002;同侧27%,P=0.0001)显著增加了测量的整体或同侧LV。测得的HQV不受头部抬高或肢体位置的影响,但在转动头部的另一侧高2% (P=0.01)。我们得出结论,身体位置的改变对测量的HQV影响最小,而准确的LV评估需要马直立。
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来源期刊
Comparative Exercise Physiology
Comparative Exercise Physiology VETERINARY SCIENCES-
CiteScore
1.50
自引率
11.10%
发文量
37
期刊介绍: ''Comparative Exercise Physiology'' is the only international peer-reviewed scientific journal specifically dealing with the latest research in exercise physiology across all animal species, including humans. The major objective of the journal is to use this comparative approach to better understand the physiological, nutritional, and biochemical parameters that determine levels of performance and athletic achievement. Core subjects include exercise physiology, biomechanics, gait (including the effect of riders in equestrian sport), nutrition and biochemistry, injury and rehabilitation, psychology and behaviour, and breeding and genetics. This comparative and integrative approach to exercise science ultimately highlights the similarities as well as the differences between humans, horses, dogs, and other athletic or non-athletic species during exercise. The result is a unique forum for new information that serves as a resource for all who want to understand the physiological challenges with exercise.
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