A neuromuscular model of human locomotion combines spinal reflex circuits with voluntary movements

Ramadan, Rachid; Geyer, Hartmut; Jeka, John J.; Schöner, Gregor; Reimann, Hendrik

doi:10.1038/s41598-022-11102-1

Cited by 13 publications

(28 citation statements)

References 132 publications

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“…where K l is the gain and h is the resting level of the spinal stretch reflex (see Section 2.3.2). For details on these inversions and the associated simplifying approximations, please see Ramadan et al (2022).…”

Section: Simentioning

confidence: 99%

“…We present a neuromechanical model of human locomotion that is based on the work of Ramadan et al (2022) and spans high-level movement planning and coordination, spinal reflex arcs, muscle physiology, and skeletal biomechanics. Figure 1 provides an overview of the major model components.…”

Section: Modelmentioning

confidence: 99%

“…Motorneural activation is fed into Hill-type muscle models that actuate a three-dimensional biomechanical model. The following section provides a detailed description of the innovations made to the work presented in Ramadan et al (2022) . For details on the adapted parts of the model, please refer to Ramadan et al (2022) .…”

Section: Modelmentioning

confidence: 99%

“…The following section provides a detailed description of the innovations made to the work presented in Ramadan et al (2022) . For details on the adapted parts of the model, please refer to Ramadan et al (2022) .…”

Section: Modelmentioning

confidence: 99%

“…Experimental studies of human walking suggest a duality of steps as both 1) part of the rhythmic movement patterns of the whole body and 2) reaching movements with the foot ( Clark, 2015 ). We previously presented a model that attempts to bridge this gap by integrating high-level, voluntary movement planning for the swing leg with low-level, habitual control ( Ramadan et al, 2022 ). The model could avoid obstacles, vary movement speed and walking direction, and perform goal-directed movements with the swing leg by executing a motor plan to reach a kinematic goal, without re-optimizing model parameters.…”

Section: Introductionmentioning

confidence: 99%

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

Ramadan

Meischein

Reimann

2022

Front. Bioeng. Biotechnol.

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Humans can freely adopt gait parameters like walking speed, step length, or cadence on the fly when walking. Planned movement that can be updated online to account for changes in the environment rather than having to rely on habitual, reflexive control that is adapted over long timescales. Here we present a neuromechanical model that accounts for this flexibility by combining movement goals and motor plans on a kinematic task level with low-level spinal feedback loops. We show that the model can walk at a wide range of different gait patterns by choosing a small number of high-level control parameters representing a movement goal. A larger number of parameters governing the low-level reflex loops in the spinal cord, on the other hand, remain fixed. We also show that the model can generalize the learned behavior by recombining the high-level control parameters and walk with gait patterns that it had not encountered before. Furthermore, the model can transition between different gaits without the loss of balance by switching to a new set of control parameters in real time.

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Section: Simentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

Ramadan

Meischein

Reimann

2022

Front. Bioeng. Biotechnol.

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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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AI-CPG: Adaptive Imitated Central Pattern Generators for Bipedal Locomotion Learned Through Reinforced Reflex Neural Networks

Li,

Ijspeert,

Hayashibe

2024

IEEE Robot. Autom. Lett.

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Humans have many redundancies in their bodies and can make effective use of them to adapt to changes in the environment while walking. They can also vary their walking speed in a wide range. Human-like walking in simulation or by robots can be achieved through imitation learning. However, the walking speed is typically limited to a scale similar to the examples used for imitation. Achieving efficient and adaptable locomotion controllers for a wide range from walking to running is quite challenging. We propose a novel approach named adaptive imitated central pattern generators (AI-CPG) that combines central pattern generators (CPGs) and deep reinforcement learning (DRL) to enhance humanoid locomotion. Our method involves training a CPG-like controller through imitation learning, generating rhythmic feedforward activity patterns. DRL is not used for CPG parameter tuning; instead, it is applied in forming a reflex neural network, which can adjust feedforward patterns based on sensory feedback, enabling the stable body balancing to adapt to environmental or target velocity changes. Experiments with a 28-degree-of-freedom humanoid in a simulated environment demonstrated that our approach outperformed existing methods in terms of adaptability, balancing ability, and energy efficiency even for uneven surfaces. This study contributes to develop versatile humanoid locomotions in diverse environments.

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A neuromuscular model of human locomotion combines spinal reflex circuits with voluntary movements

Cited by 13 publications

References 132 publications

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

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

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

AI-CPG: Adaptive Imitated Central Pattern Generators for Bipedal Locomotion Learned Through Reinforced Reflex Neural Networks

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