Joint moments and muscle excitations increase with body-mass normalized backpacks across walking slopes

IF 2.2 3区医学 Q3 NEUROSCIENCES

Gait & posture Pub Date : 2025-04-17 DOI:10.1016/j.gaitpost.2025.04.007

Jordan T. Sturdy , Hedaya N. Rizeq , Tyler T. Whittier , Carlie J. Daquino , Amy Silder , Anna C. Corman , Pinata H. Sessoms , Anne K. Silverman

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引用次数: 0

Abstract

Background

Human locomotion is characterized by joint moments and muscle excitations of the leg, which have quantified the demands of backpack loads and sloped walking. However, the combined impact of backpack loads and sloped walking remains poorly characterized, particularly during downhill walking. This study characterized 3D hip and sagittal knee and ankle moments and integrated muscle excitations when walking downhill, level, and uphill while carrying a body-mass normalized backpack load.

Methods

Fourteen healthy, active-duty military service members were enrolled in this study. Participants walked on a treadmill under six walking conditions – uphill, level, and downhill (1) with a baseline load, and (2) with a heavy backpack load. Surface EMG, full body motion capture, and ground reaction forces were captured, and lower body moments and muscle excitations were examined. Fixed effects of slope, pack, and the slope-by-pack interaction were evaluated using linear mixed effects models

Results

The addition of backpack loads generally resulted in greater joint moments and muscle excitations on all slopes; however, several interaction effects highlight the compounding influence of walking slopes and backpacks. The effect of added backpack mass was greatest during uphill for hip extension and ankle plantarflexion moments. In addition, backpack loads had a greater knee extension moment throughout stance when walking downhill, but level and uphill walking had a knee flexion moment in terminal stance that was not affected by the backpack.

Significance

Our overall findings define the biomechanical task demands for sloped walking with a backpack load. These results provide a mechanical context that may be useful for understanding musculoskeletal overuse injury attributed to load carriage.

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关节力矩和肌肉兴奋度随着身体质量标准化背包穿过步行斜坡而增加

人体运动的特点是关节力矩和腿部肌肉兴奋，这已经量化了背包负载和倾斜行走的需求。然而，背包负荷和倾斜行走的综合影响仍然不清楚，特别是在下坡行走时。本研究描述了负重下坡、平坡和上坡行走时的三维髋关节、矢状面膝关节和踝关节瞬间以及综合肌肉兴奋。方法选取14名健康现役军人为研究对象。参与者在跑步机上行走六种步行条件——上坡、水平和下坡(1)在基线负荷下，(2)在沉重的背包负荷下。体表肌电图、全身运动捕捉和地面反作用力被捕捉，下体力矩和肌肉兴奋被检测。使用线性混合效应模型评估斜坡、背包和坡与背包相互作用的固定效应。结果：在所有斜坡上，背包载荷的增加通常会导致更大的关节力矩和肌肉兴奋；然而，一些交互效应突出了步行斜坡和背包的复合影响。在上坡时增加背包质量对髋部伸展和踝关节跖屈力矩的影响最大。此外，在下坡行走时，背包载荷在整个站位都有较大的膝关节伸展力矩，而水平行走和上坡行走在终末站位都有膝关节弯曲力矩，但不受背包的影响。意义：我们的总体研究结果定义了背包负重倾斜行走的生物力学任务需求。这些结果提供了一个机械背景，可能有助于理解肌肉骨骼过度使用损伤归因于负载运输。

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来源期刊

Gait & posture 医学-神经科学

CiteScore

4.70

自引率

12.50%

发文量

616

审稿时长

6 months

期刊介绍： Gait & Posture is a vehicle for the publication of up-to-date basic and clinical research on all aspects of locomotion and balance. The topics covered include: Techniques for the measurement of gait and posture, and the standardization of results presentation; Studies of normal and pathological gait; Treatment of gait and postural abnormalities; Biomechanical and theoretical approaches to gait and posture; Mathematical models of joint and muscle mechanics; Neurological and musculoskeletal function in gait and posture; The evolution of upright posture and bipedal locomotion; Adaptations of carrying loads, walking on uneven surfaces, climbing stairs etc; spinal biomechanics only if they are directly related to gait and/or posture and are of general interest to our readers; The effect of aging and development on gait and posture; Psychological and cultural aspects of gait; Patient education.