High-level motor planning allows flexible walking at different gait patterns in a neuromechanical model

Ramadan, Rachid; Meischein, Fabian; Reimann, Hendrik

doi:10.3389/fbioe.2022.959357

Cited by 2 publications

References 50 publications

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New neural-inspired controller generalises modularity over lower limb tasks through internal models

Muñoz,

Holland,

Severini

2024

Preprint

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Predictive neuromuscular models based on neural controllers are a powerful tool for testing assumptions on the underlying architecture of sensorimotor control and its associated neural activity. However, most current controllers suffer from lack of physiological plausibility and are generally task specific. We propose a new neural controller, called Internal Model-based Modular Controller (IMMC), where a hierarchical architecture organises generalizable modules in activation networks dedicated to different motion tasks. The architecture comprises a simple model of the mesencephalic locomotor region (MLR), which sends controlling signals that manage the activity of internal models (IMs). The IMs organise synergies, coordinated and stereotyped activity of multiple muscles, in task-specific networks. The resultant organisations allow the generalisation of this architecture to different lower limb motions. The IMMC was tested in Stand-To-Walk simulations (STW), where the MLR switches between two IMs that recombine five synergies to replicate the standing and walking tasks. The simulation kinematics, muscle activation patterns and ground reaction forces were generally consistent with experimental data. In addition, the controller can transition to slower and faster speeds by tuning a single controlling signal. The proposed architecture is a first step to develop neuromuscular models which integrate multiple motor behaviours in a unified controller.

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New neural-inspired controller generalises modularity over lower limb tasks through internal models

Muñoz,

Holland,

Severini

2024

Preprint

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Methods for integrating postural control into biomechanical human simulations: a systematic review

Shanbhag,

Wolf,

Wechsler

et al. 2023

J NeuroEngineering Rehabil

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Understanding of the human body’s internal processes to maintain balance is fundamental to simulate postural control behaviour. The body uses multiple sensory systems’ information to obtain a reliable estimate about the current body state. This information is used to control the reactive behaviour to maintain balance. To predict a certain motion behaviour with knowledge of the muscle forces, forward dynamic simulations of biomechanical human models can be utilized. We aim to use predictive postural control simulations to give therapy recommendations to patients suffering from postural disorders in the future. It is important to know which types of modelling approaches already exist to apply such predictive forward dynamic simulations. Current literature provides different models that aim to simulate human postural control. We conducted a systematic literature research to identify the different approaches of postural control models. The different approaches are discussed regarding their applied biomechanical models, sensory representation, sensory integration, and control methods in standing and gait simulations. We searched on Scopus, Web of Science and PubMed using a search string, scanned 1253 records, and found 102 studies to be eligible for inclusion. The included studies use different ways for sensory representation and integration, although underlying neural processes still remain unclear. We found that for postural control optimal control methods like linear quadratic regulators and model predictive control methods are used less, when models’ level of details is increasing, and nonlinearities become more important. Considering musculoskeletal models, reflex-based and PD controllers are mainly applied and show promising results, as they aim to create human-like motion behaviour considering physiological processes.

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High-level motor planning allows flexible walking at different gait patterns in a neuromechanical model

Cited by 2 publications

References 50 publications

New neural-inspired controller generalises modularity over lower limb tasks through internal models

New neural-inspired controller generalises modularity over lower limb tasks through internal models

Methods for integrating postural control into biomechanical human simulations: a systematic review

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