Modular control during incline and level walking in humans

Janshen, Lars; Santuz, Alessandro; Ekizos, Antonis; Arampatzis, Adamantios

doi:10.1242/jeb.148957

Cited by 21 publications

(30 citation statements)

References 47 publications

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“…Another outcome of this study was the different contribution of the GM muscle for the 315 participants of G1 and G2. In G1, as found in the past [10,33,35,38,52], the GM and GL were crucial contributors to the propulsion synergy, together with the SO and PL. In G2, though, the contribution of the GM shifted to the weight acceptance phase at both maximal and submaximal speeds.…”

Section: Fast Locomotion Requires Different Muscle Contributionsmentioning

confidence: 53%

“…The fourth and last synergy reflected the late swing and the landing preparation, highlighting the relevant influence of knee flexors and foot dorsiflexors. As showed in the past for other locomotion conditions 110 [10,33,35,38,52], not all the participants exhibited all the four fundamental synergies at all speeds; in particular, 27% and 30% of the total synergies were classified as combined in walking and running, respectively. We reported the detailed numbers in Table 1.…”

Section: Muscle Synergiesmentioning

confidence: 66%

“…The initial angle determines the position of the centre 20 of mass, which reaches its highest (in walking) and lowest (in running) point in the middle of the 265 stance phase [59]. This may physically constrain the production of forward forces in walking from the plantarflexors, which are major contributors in this phase [10,35,52,60], since only after half stance there can be propulsion, while in running it can happen earlier [2]. This could explain the physiological constraint to the recruitment timing of those muscles responsible for the weight acceptance (mostly knee extensors) and propulsion (mostly plantarflexors) phase.…”

Section: Longer Less Complex Motor Primitives Ensure Robust Control mentioning

confidence: 99%

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Lower complexity of motor primitives ensures robust control of high-speed human locomotion

Santuz

Ekizos

Kunimasa

et al. 2020

Preprint

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Walking and running are mechanically and energetically different locomotion modes. For selecting one or another, speed is a parameter of paramount importance. Yet, both are likely controlled by similar low-dimensional neuronal networks that reflect in patterned muscle activations called muscle synergies. Here, we investigated how humans synergistically activate 25 muscles during locomotion at different submaximal and maximal speeds. We analysed the duration and complexity (or irregularity) over time of motor primitives, the temporal components of muscle synergies. We found that the challenge imposed by controlling high-speed locomotion forces the central nervous system to produce muscle activation patterns that are wider and less complex relative to the duration of the gait cycle. The motor modules, or time-independent 30 coefficients, were redistributed as locomotion speed changed. These outcomes show that robust locomotion control at challenging speeds is achieved by modulating the relative contribution of muscle activations and producing less complex and wider control signals, whereas slow speeds allow for more irregular control. 35

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Section: Fast Locomotion Requires Different Muscle Contributionsmentioning

confidence: 53%

Section: Muscle Synergiesmentioning

confidence: 66%

Section: Longer Less Complex Motor Primitives Ensure Robust Control mentioning

confidence: 99%

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Lower complexity of motor primitives ensures robust control of high-speed human locomotion

Santuz

Ekizos

Kunimasa

et al. 2020

Preprint

Self Cite

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“…From insects to mammals, leg muscle activity is thought to be controlled via neural circuits in the central nervous system that integrate descending inputs from the brain and afferent inputs from the leg (Hooper and Büschges, 2017;Orlovsky et al, 1999;Pearson, 1995;Prochazka, 1996). One possibility is that descending inputs mediate distinct motor programs for inclines, for example by modifying muscle synergies (Janshen et al, 2017;Smith et al, 1998). Another possibility is that afferent inputs from leg proprioceptors adjust leg muscle activity on a step-by-step basis.…”

Section: Introductionmentioning

confidence: 99%

Motor control of an insect leg during level and incline walking

Dallmann

Dürr

Schmitz

2019

Journal of Experimental Biology

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During walking, the leg motor system must continually adjust to changes in mechanical conditions, such as the inclination of the ground. To understand the underlying control, it is important to know how changes in leg muscle activity relate to leg kinematics (movements) and leg dynamics (forces, torques). Here, we studied these parameters in hindlegs of stick insects (Carausius morosus) during level and uphill/downhill (±45 deg) walking, using a combination of electromyography, 3D motion capture and ground reaction force measurements. We find that some kinematic parameters including leg joint angles and body height vary across walking conditions. However, kinematics vary little compared with dynamics: horizontal leg forces and torques at the thorax-coxa joint (leg protraction/retraction) and femur-tibia joint (leg flexion/ extension) tend to be stronger during uphill walking and are reversed in sign during downhill walking. At the thorax-coxa joint, the different mechanical demands are met by adjustments in the timing and magnitude of antagonistic muscle activity. Adjustments occur primarily in the first half of stance after the touch-down of the leg. When insects transition from level to incline walking, the characteristic adjustments in muscle activity occur with the first step of the leg on the incline, but not in anticipation. Together, these findings indicate that stick insects adjust leg muscle activity on a stepby-step basis so as to maintain a similar kinematic pattern under different mechanical demands. The underlying control might rely primarily on feedback from leg proprioceptors signaling leg position and movement. Journal of Experimental Biologyinclines, (2) how walking on inclines affects the forces and torques produced by the leg, and (3) how changes in kinematics and dynamics relate to changes in leg muscle activity. Our results suggest that stick insects do not use distinct, inclination-specific motor programs but instead adjust leg muscle activity on a step-bystep basis so as to minimize changes in kinematics under different mechanical demands.

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“…In this context, it is notable that pleurodire turtles, including E. subglobosa, have remained a primarily aquatic lineage throughout their evolutionary history, whereas cryptodires have radiated onto land multiple independent times (Joyce and Gauthier, 2004;Bonin et al, 2006). In addition to being affected by differences in muscle attachment, muscle function also can be influenced by the external environment (Gillis and Blob, 2001;Nishikawa et al, 2007;Foster and Higham, 2017;Janshen et al, 2017), and animals often exhibit differences in both the timing (Gillis and Biewener, 2000;Blob et al, 2008) and intensity (Biewener and Gillis, 1999;Gillis and Biewener, 2000) of muscle use during locomotion in water and on land. In addition to structural variations, such as differences in muscle moment arms, such dynamic modulations of muscle activity are likely an important component of motor control that allows animals to use the same structures to move through different environments (Gillis, 1998;Earhart and Stein, 2000;Rivera et al, 2010;Ashley-Ross et al, 2014;Perlman and Ashley-Ross, 2016).…”

Section: Discussionmentioning

confidence: 99%

Hindlimb muscle function in turtles: is novel skeletal design correlated with novel muscle function?

Mayerl

Pruett

Summerlin

et al. 2017

Journal of Experimental Biology

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Variations in musculoskeletal lever systems have formed an important foundation for predictions about the diversity of muscle function and organismal performance. Changes in the structure of lever systems may be coupled with changes in muscle use and give rise to novel muscle functions. The two extant turtle lineages, cryptodires and pleurodires, exhibit differences in hindlimb structure. Cryptodires possess the ancestral musculoskeletal morphology, with most hip muscles originating on the pelvic girdle, which is not fused to the shell. In contrast, pleurodires exhibit a derived morphology, in which fusion of the pelvic girdle to the shell has resulted in shifts in the origin of most hip muscles onto the interior of the shell. To test how variation in muscle arrangement might influence muscle function during different locomotor behaviors, we combined measurements of muscle leverage in five major hindlimb muscles with data on muscle use and hindlimb kinematics during swimming and walking in representative semiaquatic cryptodire () and pleurodire () species. We found substantial differences in muscle leverage between the two species. Additionally, we found that there were extensive differences in muscle use in both species, especially while walking, with some pleurodire muscles exhibiting novel functions associated with their derived musculoskeletal lever system. However, the two species shared similar overall kinematic profiles within each environment. Our results suggest that changes in limb lever systems may relate to changes in limb muscle motor patterns and kinematics, but that other factors must also contribute to differences in muscle activity and limb kinematics between these taxa.

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Modular control during incline and level walking in humans

Cited by 21 publications

References 47 publications

Lower complexity of motor primitives ensures robust control of high-speed human locomotion

Lower complexity of motor primitives ensures robust control of high-speed human locomotion

Motor control of an insect leg during level and incline walking

Hindlimb muscle function in turtles: is novel skeletal design correlated with novel muscle function?

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