Reindeer (Rangifer tarandus) hindlimb joint kinetics: propulsive and energy storage mechanisms and mechanical work

IF 1.5 4区 环境科学与生态学 Q3 BIODIVERSITY CONSERVATION Polar Biology Pub Date : 2024-05-27 DOI:10.1007/s00300-024-03265-6
Guoyu Li, Rui Zhang, Hao Pang, Junfeng Wang, Dan Jin, Xumin Sun, Dianlei Han, Zhisong Li, Lige Wen
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Abstract

As seasonal migratory animals, reindeer inhabit the natural habitats in Arctic regions and have evolved their hindlimb joints to adapt to the complex ground conditions there. Inverse dynamics of the joints is an important tool to study foot functions. Herein, with a motion tracking system and plantar pressure data based on kinematics and inverse dynamics of hindlimbs, we investigated the changes in joint angles, net joint moments, net joint powers, and work of reindeer at different speeds. Reindeer may adopt different movement patterns to efficiently utilize energy and adapt to the demands of different gaits and speeds. The joint ranges of motion (ROM) of the ankle joint (αb), metatarsophalangeal (MTP) joint (αc), and interphalangeal joint (αd) of the hindlimbs were about 20.73°–28.87°, 40.37°–47.69°, and 24.47°–26.18°, respectively. The ankle joint produced positive work to provide propulsion. The positive work done at the ankle joint during walking, slow trotting, and fast trotting was 8.61 × 10–2, 9.25 × 10–2, and 15.44 × 10–2 J·kg−1, respectively. The MTP and interphalangeal joints both absorbed energy during walking, slow trotting, and fast trotting. The energy absorption at the respective speeds was 12.53 × 10–2, 13.57 × 10–2, and 19.90 × 10–2 J·kg−1, respectively, by the MTP joint and was 9.49 × 10–2, 7.71 × 10–2, and 10.26 × 10–2 J·kg−1, respectively, by the interphalangeal joint. The MTP joint and interphalangeal joint of the hindlimbs serve as the primary sites for energy storage and release, functioning as an elastic system. This study contributes to a deeper understanding about the biomechanical properties of hindlimb joints and provides a theoretical basis for designing extremity robots in extreme environments through analyzing the functional characteristics of reindeer foot joints.

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驯鹿(Rangifer tarandus)后肢关节动力学:推进和储能机制以及机械功
作为季节性迁徙动物,驯鹿栖息在北极地区的自然栖息地,并进化出后肢关节,以适应那里复杂的地面条件。关节的反动力学是研究足部功能的重要工具。在此,我们利用运动跟踪系统和基于后肢运动学和反动力学的足底压力数据,研究了驯鹿在不同速度下关节角度、净关节力矩、净关节功率和功的变化。驯鹿可能会采用不同的运动模式来有效利用能量,并适应不同步态和速度的需求。后肢踝关节(αb)、跖趾关节(αc)和趾间关节(αd)的关节活动范围(ROM)分别约为20.73°-28.87°、40.37°-47.69°和24.47°-26.18°。踝关节产生正功以提供推进力。在步行、慢跑和快跑时,踝关节所做的正功分别为 8.61 × 10-2、9.25 × 10-2 和 15.44 × 10-2 J-kg-1。在步行、慢跑和快跑时,MTP 和指间关节都吸收了能量。在不同速度下,MTP关节吸收的能量分别为12.53×10-2、13.57×10-2和19.90×10-2 J-kg-1,而指间关节吸收的能量分别为9.49×10-2、7.71×10-2和10.26×10-2 J-kg-1。后肢的 MTP 关节和指间关节是储存和释放能量的主要部位,是一个弹性系统。这项研究有助于加深对后肢关节生物力学特性的理解,并通过分析驯鹿足关节的功能特性,为设计极端环境下的四肢机器人提供理论依据。
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来源期刊
Polar Biology
Polar Biology 生物-生态学
CiteScore
3.60
自引率
11.80%
发文量
116
审稿时长
3-8 weeks
期刊介绍: Polar Biology publishes Original Papers, Reviews, and Short Notes and is the focal point for biologists working in polar regions. It is also of interest to scientists working in biology in general, ecology and physiology, as well as in oceanography and climatology related to polar life. Polar Biology presents results of studies in plants, animals, and micro-organisms of marine, limnic and terrestrial habitats in polar and subpolar regions of both hemispheres. Taxonomy/ Biogeography Life History Spatio-temporal Patterns in Abundance and Diversity Ecological Interactions Trophic Ecology Ecophysiology/ Biochemistry of Adaptation Biogeochemical Pathways and Cycles Ecological Models Human Impact/ Climate Change/ Conservation
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