Your search keyword '"Modular motor control"' showing total 8 results

1. Modular Control of Kinematics in Prosthetic Gait: Low-Dimensional Description Based on the Planar Covariation Law

Author

Ranaldi, Simone, De Marchis, Cristiano, Serrao, Mariano, Ranavolo, Alberto, Draicchio, Francesco, Lacquaniti, Francesco, Conforto, Silvia, Magjarevic, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Jarm, Tomaz, editor, Cvetkoska, Aleksandra, editor, Mahnič-Kalamiza, Samo, editor, and Miklavcic, Damijan, editor

Published

2021

2. Modular motor control of the sound limb in gait of people with trans-femoral amputation

Author

Cristiano De Marchis, Simone Ranaldi, Mariano Serrao, Alberto Ranavolo, Francesco Draicchio, Francesco Lacquaniti, and Silvia Conforto

Subjects

Trans-femoral amputation, Lower limb prosthesis, Muscle synergies, Gait, sEMG, Modular motor control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background The above-knee amputation of a lower limb is a severe impairment that affects significantly the ability to walk; considering this, a complex adaptation strategy at the neuromuscular level is needed in order to be able to move safely with a prosthetic knee. In literature, it has been demonstrated that muscle activity during walking can be described via the activation of a small set of muscle synergies. The analysis of the composition and the time activation profiles of such synergies have been found to be a valid tool for the description of the motor control schemes in pathological subjects. Methods In this study, we used muscle synergy analysis techniques to characterize the differences in the modular motor control schemes between a population of 14 people with trans-femoral amputation and 12 healthy subjects walking at two different (slow and normal self-selected) speeds. Muscle synergies were extracted from a 12 lower-limb muscles sEMG recording via non-negative matrix factorization. Equivalence of the synergy vectors was quantified by a cross-validation procedure, while differences in terms of time activation coefficients were evaluated through the analysis of the activity in the different gait sub-phases. Results Four synergies were able to reconstruct the muscle activity in all subjects. The spatial component of the synergy vectors did not change in all the analysed populations, while differences were present in the activity during the sound limb’s stance phase. Main features of people with trans-femoral amputation’s muscle synergy recruitment are a prolonged activation of the module composed of calf muscles and an additional activity of the hamstrings’ module before and after the prosthetic heel strike. Conclusions Synergy-based results highlight how, although the complexity and the spatial organization of motor control schemes are the same found in healthy subjects, substantial differences are present in the synergies’ recruitment of people with trans femoral amputation. In particular, the most critical task during the gait cycle is the weight transfer from the sound limb to the prosthetic one. Future studies will integrate these results with the dynamics of movement, aiming to a complete neuro-mechanical characterization of people with trans-femoral amputation’s walking strategies that can be used to improve the rehabilitation therapies.

Published

2019

3. Estimating Spatial Gait Parameters from the Planar Covariation of Lower Limb Elevation Angles: a Pilot Study

Author

Simone Ranaldi, Silvia Conforto, Cristiano De Marchis, IEEE, Ranaldi, S., Conforto, S., and De Marchis, C.

Subjects

kinematic, planar covariation law, gait parameter, modular motor control, gait

Abstract

When characterizing human gait control strategies, theories based on the modularity of the neuromuscular system have been proven to be powerful in providing a compact description of the gait patterns. The planar covariation law of lower limb elevation angles has been proposed as a compact, modular description of gait kinematics. In this paper, we exploit this model for characterizing healthy subjects' spatial gait parameters during walking at different speeds, one self-selected and one slightly slower than the subject's comfortable pace. Different geometrical features have been calculated over the gait loop, that is the planar loop defined by the covariation of the thigh, shank and foot elevation angles. A correlation analysis has been carried out between these features and classical gait spatial parameters (step length, step width, stride length and foot clearance) by training a linear regressor on the dataset comprising both speeds. The results from this analysis have highlighted a correlation with some spatial gait parameters across the two speed conditions, indicating that this compact description of kinematics unravels a significant biomechanical meaning. These results can be exploited to guide the control mechanisms of external assistive devices, such as prostheses or exoskeletons, based purely on the measurement of few relevant kinematic quantities of the lower limb segments.

Published

2022

4. Do muscle synergies reduce the dimensionality of behaviour?

Author

Naveen eKuppuswamy and Christopher M. Harris

Subjects

dimensionality reduction, muscle synergies, Modular Motor Control, Hankel Singular Values, Optimal motor control, system balancing, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The muscle synergy hypothesis is an archetype of the notion of Dimensionality Reduction (DR) occurring in the central nervous system due to modular organisation. Towards validating this hypothesis, it is however important to understand if muscle synergies can reduce the state-space dimensionality while suitably achieving task control. In this paper we present a scheme for investigating this reduction, utilising the temporal muscle synergy formulation. Our approach is based on the observation that constraining the control input to a weighted combination of temporal muscle synergies instead constrains the dynamic behaviour of a system in trajectory-specific manner. We compute this constrained reformulation of system dynamics and then use the method of system balancing for quantifying the DR; we term this approach as Trajectory Specific Dimensionality Analysis (TSDA). We then use this method to investigate the consequence of minimisation of this dimensionality for a given task. These methods are tested in simulation on a linear (tethered mass) and a nonlinear (compliant kinematic chain) system; dimensionality of various reaching trajectories is compared when using idealised temporal synergies. We show that as a consequence of this Minimum Dimensional Control (MDC) model, smooth straight-line Cartesian trajectories with bell-shaped velocity profiles are obtained as the solution to reaching tasks in both of the test systems. We also investigate the effect on dimensionality due to adding via-points to a trajectory. The results indicate that a synergy basis and trajectory-specific DR of motor behaviours results from usage of muscle synergy control. The implications of these results for the synergy hypothesis, optimal motor control, developmental skill acquisition and robotics are then discussed.

Published

2014

5. Modular Control of Kinematics in Prosthetic Gait: Low-Dimensional Description Based on the Planar Covariation Law

Author

Mariano Serrao, Francesco Draicchio, Cristiano De Marchis, Simone Ranaldi, Silvia Conforto, Francesco Lacquaniti, Alberto Ranavolo, Jarm T.,Cvetkoska A.,Mahnic-Kalamiza S.,Miklavcic D., Ranaldi, S., De Marchis, C., Serrao, M., Ranavolo, A., Draicchio, F., Lacquaniti, F., and Conforto, S.

Subjects

Gait (human), Lower limb amputation, Plane (geometry), Gait analysi, Law, Gait analysis, Work (physics), Elevation, Modular motor control, Kinematics, Covariance, Projection (set theory), Mathematics

Abstract

Amputation of a lower limb implies a re-organization in the strategies used to reach a stable walking pattern. The planar covariation law of elevation angles is a well-defined low-dimensional description of the kinematics of movement; according to this law, thigh, shank and foot elevation angle co-vary on a plane, defining a typical gait loop. However, a robust biomechanical interpretation of the outcomes of its related analysis is still missing. In this work, we tested the planar covariation law on a group of 14 trans-femoral amputees, comparing the results with the ones related to 12 healthy people. Moreover, by adopting a common covariance plane for all the subjects, we checked whether the projection of the original elevation angles on this plane is able to yield biomechanically meaningful information on the control of prosthetic gait. A common plane was able to describe the coordination of lower limb elevation angles in all subjects; on this plane, most of the differences among populations were identified on the time course of one principal component.

Published

2021

6. Do muscle synergies reduce the dimensionality of behavior?

Author

Kuppuswamy, Naveen and Harris, Christopher M.

Subjects

DIMENSION reduction (Statistics), CENTRAL nervous system, MUSCLES, SIMULATION methods & models, KINEMATIC chains, CARTESIAN coordinates

Abstract

The muscle synergy hypothesis is an archetype of the notion of Dimensionality Reduction (DR) occurring in the central nervous system due to modular organization. Toward validating this hypothesis, it is important to understand if muscle synergies can reduce the state-space dimensionality while maintaining task control. In this paper we present a scheme for investigating this reduction utilizing the temporal muscle synergy formulation. Our approach is based on the observation that constraining the control input to a weighted combination of temporal muscle synergies also constrains the dynamic behavior of a system in a trajectory-specific manner. We compute this constrained reformulation of system dynamics and then use the method of system balancing for quantifying the DR; we term this approach as Trajectory Specific Dimensionality Analysis (TSDA). We then investigate the consequence of minimization of the dimensionality for a given task. These methods are tested in simulations on a linear (tethered mass) and a non-linear (compliant kinematic chain) system. Dimensionality of various reaching trajectories is compared when using idealized temporal synergies. We show that as a consequence of this Minimum Dimensional Control (MDC) model, smooth straight-line Cartesian trajectories with bell-shaped velocity profiles emerged as the optima for the reaching task. We also investigated the effect on dimensionality due to adding via-points to a trajectory. The results indicate that a trajectory and synergy basis specific DR of behavior results from muscle synergy control. The implications of these results for the synergy hypothesis, optimal motor control, motor development, and robotics are discussed. [ABSTRACT FROM AUTHOR]

Published

2014

7. Modular motor control of the sound limb in gait of people with trans-femoral amputation

Author

De Marchis, Cristiano, Ranaldi, Simone, Serrao, Mariano, Ranavolo, Alberto, Draicchio, Francesco, Lacquaniti, Francesco, and Conforto, Silvia

Published

2019

8. Modular motor control of the sound limb in gait of people with trans-femoral amputation

Author

Alberto Ranavolo, Francesco Draicchio, Francesco Lacquaniti, Silvia Conforto, Simone Ranaldi, Mariano Serrao, Cristiano De Marchis, De Marchis, C., Ranaldi, S., Serrao, M., Ranavolo, A., Draicchio, F., Lacquaniti, F., and Conforto, S.

Subjects

Male, 030506 rehabilitation, Neurology, medicine.medical_treatment, Walking, Gait, Lower limb prosthesis, Modular motor control, Muscle synergies, Trans-femoral amputation, sEMG, 0302 clinical medicine, Gait (human), education.field_of_study, Rehabilitation, Middle Aged, Biomechanical Phenomena, gait, lower limb prosthesis, modular motor control, muscle synergies, semg, trans-femoral amputation, adult, aged, artificial limbs, biomechanical phenomena, electromyography, female, heel, humans, leg, male, middle aged, muscle, skeletal, recruitment, neurophysiological, reproducibility of results, walking, amputation, amputees, Weight transfer, Female, 0305 other medical science, Lower limb prosthesi, Adult, Recruitment, Neurophysiological, medicine.medical_specialty, Population, Health Informatics, Artificial Limbs, Settore BIO/09, Amputation, Surgical, lcsh:RC321-571, 03 medical and health sciences, Physical medicine and rehabilitation, Amputees, medicine, Humans, education, Muscle, Skeletal, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Aged, Leg, Muscle synergie, business.industry, Electromyography, Research, Motor control, Reproducibility of Results, Modular design, Amputation, Heel, business, 030217 neurology & neurosurgery

Abstract

Background The above-knee amputation of a lower limb is a severe impairment that affects significantly the ability to walk; considering this, a complex adaptation strategy at the neuromuscular level is needed in order to be able to move safely with a prosthetic knee. In literature, it has been demonstrated that muscle activity during walking can be described via the activation of a small set of muscle synergies. The analysis of the composition and the time activation profiles of such synergies have been found to be a valid tool for the description of the motor control schemes in pathological subjects. Methods In this study, we used muscle synergy analysis techniques to characterize the differences in the modular motor control schemes between a population of 14 people with trans-femoral amputation and 12 healthy subjects walking at two different (slow and normal self-selected) speeds. Muscle synergies were extracted from a 12 lower-limb muscles sEMG recording via non-negative matrix factorization. Equivalence of the synergy vectors was quantified by a cross-validation procedure, while differences in terms of time activation coefficients were evaluated through the analysis of the activity in the different gait sub-phases. Results Four synergies were able to reconstruct the muscle activity in all subjects. The spatial component of the synergy vectors did not change in all the analysed populations, while differences were present in the activity during the sound limb’s stance phase. Main features of people with trans-femoral amputation’s muscle synergy recruitment are a prolonged activation of the module composed of calf muscles and an additional activity of the hamstrings’ module before and after the prosthetic heel strike. Conclusions Synergy-based results highlight how, although the complexity and the spatial organization of motor control schemes are the same found in healthy subjects, substantial differences are present in the synergies’ recruitment of people with trans femoral amputation. In particular, the most critical task during the gait cycle is the weight transfer from the sound limb to the prosthetic one. Future studies will integrate these results with the dynamics of movement, aiming to a complete neuro-mechanical characterization of people with trans-femoral amputation’s walking strategies that can be used to improve the rehabilitation therapies.

Published

2019