Influence of Curve Sharpness on Torsional Loading of the Tibia in Running

Kawamoto, Ryuji; Ishige, Yu; Watarai, Koji; Fukashiro, Senshi

doi:10.1123/jab.18.3.218

Cited by 10 publications

(5 citation statements)

References 8 publications

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“…The sharpness of a turn is also found to impact horses and human runners. A sharply curved track (5-m radius) leads to greater torsion on the inside tibia of humans, compared to running on a gently curved track (15-m) or straight line [ 9 ]. When running around a curve, the inside and outside limbs of human subjects are not biomechanically symmetrical.…”

Section: Introductionmentioning

confidence: 99%

The Impact of Circular Exercise Diameter on Bone and Joint Health of Juvenile Animals

Logan

Nielsen

Hiney

et al. 2022

Animals

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Circular exercise is used in many equestrian disciplines and this study aimed to determine if circle diameter impacts juvenile animal forelimb bone and joint health. On day 0, 24 calves at 9 weeks of age were assigned the following exercise treatments: small circle (12 m clockwise), large circle (18-m clockwise), treadmill, or non-exercised control. Exercise was initiated at 1.1–1.5 m/s for 5 min/d and increased 5 min weekly until reaching 30 min/d. On day 49, synovial fluid was collected from multiple joints, cartilage was collected from the proximal surface of fused third and fourth metacarpi (MC III and IV), and forelimbs underwent computed tomography scans. A statistical analysis (PROC mixed) was performed in SAS 9.4. The inside leg of the small circle treatment had a larger MC III and IV dorsopalmar external diameter than the outside (p = 0.05). The medial proximal phalanx had a greater mediolateral diameter than the lateral proximal phalanx of the small circle treatment (p = 0.01). Fetlock nitric oxide was greater in the large circle and treadmill treatments (p < 0.0001). Cartilage glycosaminoglycan concentration was greater in the outside leg of the small circle exercise treatment than the inside leg (p = 0.03). Even at slow speeds, circular exercise diameter can impact joint and bone health, but faster speeds may have greater alterations.

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Section: Introductionmentioning

confidence: 99%

The Impact of Circular Exercise Diameter on Bone and Joint Health of Juvenile Animals

Logan

Nielsen

Hiney

et al. 2022

Animals

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“…Performance depends on morphology, behavior and motor control (Aerts et al, 2003;Alexander, 2002;Carrier et al, 2001;Dial et al, 2008;Eilam, 1994;Jindrich et al, 2006;Jindrich and Full, 1999;Jindrich et al, 2007;Van Damme and van Dooren, 1999). For humans, turns alone comprise up to 50% of walking steps during daily living (Glaister et al, 2007), and can cause injuries directly by increasing the forces and moments experienced by the legs, and indirectly by decreasing stability and causing falls (Besier et al, 2001;Colby et al, 2000;Cross et al, 1989;Kawamoto et al, 2002;McLean et al, 2004;Stacoff et al, 1996). Maneuvering performance reflects dynamic interactions among mechanics, musculoskeletal physiology and motor control (Biewener and Daley, 2007;Dickinson et al, 2000;Full et al, 2002;Jindrich and Qiao, 2009).…”

Section: Introductionmentioning

confidence: 99%

Compensations for increased rotational inertia during human cutting turns

Qiao

Brown

Jindrich

2013

Journal of Experimental Biology

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Locomotion in a complex environment is often not steady state, but unsteady locomotion (stability and maneuverability) is not well understood. We investigated the strategies used by humans to perform sidestep cutting turns when running. Previous studies have argued that because humans have small yaw rotational moments of inertia relative to body mass, deceleratory forces in the initial velocity direction that occur during the turning step, or 'braking' forces, could function to prevent body over-rotation during turns. We tested this hypothesis by increasing body rotational inertia and testing whether braking forces during stance decreased. We recorded ground reaction force and body kinematics from seven participants performing 45 deg sidestep cutting turns and straight running at five levels of body rotational inertia, with increases up to fourfold. Contrary to our prediction, braking forces remained consistent at different rotational inertias, facilitated by anticipatory changes to body rotational speed. Increasing inertia revealed that the opposing effects of several turning parameters, including rotation due to symmetrical anterior-posterior forces, result in a system that can compensate for fourfold changes in rotational inertia with less than 50% changes to rotational velocity. These results suggest that in submaximal effort turning, legged systems may be robust to changes in morphological parameters, and that compensations can involve relatively minor adjustments between steps to change initial stance conditions.

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“…Similarly, running on a sharply curved track has been shown to elevate tibial loads over running on a track with a more gentle curvature (Kawamoto et al 2002).…”

Section: Historymentioning

confidence: 99%