Bioinspired preactivation reflex increases robustness of walking on rough terrain

Haeufle, Daniel F. B.; Remy, C. David; Schmitt, Syn

doi:10.1038/s41598-023-39364-3

Cited by 5 publications

(4 citation statements)

References 42 publications

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“…The consistent patterns observed in these behaviours indicate that these strategies are in uenced by prior experiences, as previously observed by Patla 1 and supported by recent literature [17][18][19]21,22 . These ndings provide a valuable database for further investigations involving children and individuals with pathological conditions.…”

Section: Discussionsupporting

confidence: 88%

“…Different research groups have examined adaptation to uneven terrain through electromyography 19 and centre of mass analysis 20 . Furthermore, Bunz and colleagues employed a neuromusculoskeletal model to predict preactivation re exes during walking on rough terrain 21 , and Bucklin and colleagues studied adaptive behaviour during unpredictable lateral pelvis perturbations on a treadmill 22 . Taylor and colleagues described perturbation effects through treadmill manipulation, albeit with limited reporting of spatiotemporal parameters 23 .…”

Section: Introductionmentioning

confidence: 99%

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Gait Compensation Strategies to Expected and Unexpected Yielding Terrain

Petrarca,

Favetta,

Carniel

et al. 2024

Preprint

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Preventing falls is closely tied to the ability to compensate for perturbations during walking. Some of the most significant perturbations arise from irregular terrain, which can lead to expected or unexpected disturbances. In pathological conditions, these compensation abilities are often greatly compromised, while in children, they are still developing. Research is scarce in this area. To address this gap, we developed a custom Stewart platform for studying perturbations during walking. We recruited ten healthy young adults. Participants walked along a path where the upper plate of a Stewart Platform, controlled in force, was positioned. The platform would move vertically downward when participants stepped on it. The perturbations were normalized based on leg length, while random sequence repetition to induce expected or unexpected conditions was defined. We conducted a comprehensive 3D gait analysis of three strides using an optoelectronic system, before, on, and after the platform. Statistical analysis was performed using one-dimensional Statistical Parametric Mapping to compare perturbed conditions (expected or unexpected) to normal walking. The main findings revealed alterations in spatiotemporal parameters, increased clearance, and increased dorsiflexion of the ankle, with minor effects on knee and hip flexion, pelvis, and trunk anteversion. Furthermore, during unexpected perturbations, participants raised their hands. In summary, our observations indicated an overlap between Anticipatory and Predictive strategies, with signs of anticipation looking at foot clearance and signs of prediction looking at hand elevation. This detailed description forms the foundation for investigating available resources in pathological conditions and their maturation across the lifespan.

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Section: Discussionsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Gait Compensation Strategies to Expected and Unexpected Yielding Terrain

Petrarca,

Favetta,

Carniel

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…Additionally, older adults exhibit greater force-generating errors and larger force variability when producing knee extensor eccentric control [10]. Since it is needed to exert large forces to go atop the perturbation [9], the slowdown exacerbates the magnitude of the positive work performance required for older adults.…”

Section: Discussionmentioning

confidence: 99%

“…This strategy involves speeding up before the perturbation and maintaining speed modulation over multiple steps postperturbation. Additionally, the pre-activation reflexes can enhance a bipedal system's ability to respond to unexpected perturbations on rough terrain [10].…”

Section: Introductionmentioning

confidence: 99%

Uneven Walking Momentum Regulation Exhibit Different Strategies based on Age and State of Lookahead

Hosseini-Yazdi

2024

Preprint

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Uneven terrains enforce challenges to continuously regulate the step parameters. Since forward momentum contributes materially to the walking balance, its step-to-step regulation plays an important role to traverse terrain complexities. Here, we exhibited that young and older adults’ modulation were affected by the state of lookahead. With a normal lookahead, they demonstrated anticipatory control. The young adults encountered terrain irregularities similar to step-up mounting and dismounting in which the total mechanical work was minimum. On the other hand, the older adults might have put more emphasis on foot placement instead, as they slowed down before the encounters. Additionally, their control was extended beyond of young adults. On the other hand, with the restricted lookahead, the control was based on feedback. Since young and older adults’ momentum regulations were very similar, it also supported suggestions that older adults might inherently rely on feedback to control their gait.

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Investigating cerebellar control in slow gait adaptations: Insights from predictive simulations of split-belt walking

Fleischmann,

Shanbhag,

Miehling

et al. 2024

Preprint

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During split-belt treadmill walking, neurotypical humans exhibit slow adaptations, characterized by a gradual decrease in step length asymmetry, whereas individuals with cerebellar damage do not show these motor adaptations. We used a neuromusculoskeletal model to better understand individual aspects of the underlying neural control. Specifically, we extended a spinal reflex model by adding a supraspinal layer, representing the cerebellum and its main function of error-driven motor adaptation. The cerebellum, based on the mismatch between an internal prediction and the actual motor outcome, can modulate spinal motor commands within the simulation. Using this model, we investigated the effect of an isolated adaptation of gait timing parameters, in our case the beginning of the liftoff phase. We created 80 s predictive simulations of the model walking on a split-belt treadmill with a 2:1 belt-speed ratio, and evaluated the results by comparing spatiotemporal parameters and kinematics with literature. The simulations exhibited adaptation patterns similar to those observed in human experiments. Specifically, the step length symmetry decreased from an initial asymmetric level toward the baseline, driven primarily by adaptations in the fast step length, while the individual joint kinematics remained similar. The adaptations affected the spatial and temporal domains, represented by a change in the center of oscillation difference and limb phasing. Our findings suggest that reflex gains do not necessarily need to be adapted to achieve changes in step length asymmetry and that, unlike what had been inferred from experiments, the same neural mechanism might account for adaptations in the spatial and temporal domains at different rates. Our simulations demonstrated distinct adaptation patterns corresponding to slow and fast learning behaviors, as reported in the literature, through modifications of a single cerebellar parameter, the adaptation rate. The framework can be extended to test different hypotheses about motor control and adaptations during continuous perturbation tasks.

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Bioinspired preactivation reflex increases robustness of walking on rough terrain

Cited by 5 publications

References 42 publications

Gait Compensation Strategies to Expected and Unexpected Yielding Terrain

Gait Compensation Strategies to Expected and Unexpected Yielding Terrain

Uneven Walking Momentum Regulation Exhibit Different Strategies based on Age and State of Lookahead

Investigating cerebellar control in slow gait adaptations: Insights from predictive simulations of split-belt walking

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