Your search keyword '"muscle synergy"' showing total 1,182 results

301. NEURAL CONTROL OF GAIT IN PEOPLE WITH HAEMOPHILIC ARTHROPATHY

Author

Cruz Montecinos, Carlos Vicente, Maas, Huub, Perez Alenda, Sofia, Cerda Villablanca, Mauricio, Neuromechanics, AMS - Tissue Function & Regeneration, AMS - Musculoskeletal Health, Pérez Alenda, Sofía, and Departament de Fisioteràpia

Subjects

joint damage, muscle synergy, haemophilia, surface electromyography, gait, neural control, knee joint, EMG, SDG 3 - Good Health and Well-being, neuromuscular control, gait analysis, motor control, lower limb, UNESCO::CIENCIAS MÉDICAS ::Patología::Hematología, ankle joint, lower limb kinematics, UNESCO::CIENCIAS MÉDICAS ::Medicina del trabajo::Rehabilitación (médica)

Abstract

La hemofilia es un trastorno hemorrágico causado por una deficiencia de los factores VIII o IX de la coagulación. Las personas con hemofilia grave pueden tener hemorragias espontáneas o hemorragias en respuesta a traumatismos menores; la mayoría de los eventos ocurren en las articulaciones y los músculos. La manifestación clínica más frecuente es la artropatía hemofílica, que resulta del sangrado intraarticular repetitivo y de la membrana sinovial inflamada, lo que puede resultar en dolor crónico y deterioro articular. El objetivo general de mi tesis fue investigar el control neural de la marcha en personas con artropatía hemofílica (PCAH). La hipótesis de mi tesis fue que control neural de la marcha se ve afectado en PCAH, y los cambios en el control neural de la marcha están asociados con el daño articular y la cronicidad de la restricción articular. Se seleccionó la marcha, ya que las rodillas y los tobillos son las articulaciones que más se afectan en adultos PCAH. El núcleo de mi tesis fue investigar el control neural mediante el estudio de patrones de actividad de electromiografía (EMG) de músculos individuales y/o sinergias musculares, así como su interacción con la cinemática articular y evaluaciones clínicas. En el capítulo 1, ofrezco una perspectiva general sobre el impacto de la hemofilia en el sistema musculoesquelético, las lagunas actuales en el conocimiento sobre el control neural de la marcha en la artropatía hemofílica y cómo evaluar el control neural de la marcha. En los Capítulos 2 y 4, a través de las evaluaciones de los patrones de activación muscular de músculos individuales, la coordinación entre pares de músculos antagonistas y el análisis de sinergia muscular, confirmamos la hipótesis de que el control neural de la marcha se ve afectado en PCAH. En los capítulos 3 y 5, confirmamos que el control neural alterado de la marcha en PCAH está asociado con la gravedad del daño articular y la cronicidad de la restricción articular. En el capítulo 6, discutimos los resultados de los capítulos centrados en las perspectivas clínicas y fisiológicas del control neural alterado de la marcha en PCAH. Además, discutimos cómo la evaluación del control neuronal a través del índice dynamic motor control index during walking (Walk-DMC) puede ser una alternativa para monitorear el deterioro motor en PCAH. Con base en nuestros resultados, también discutimos cómo mejorar los resultados de la fisioterapia y las intervenciones quirúrgicas que tienen como objetivo mejorar la locomoción en PCAH. Mi tesis contribuye a comprender las consecuencias de la artropatía hemofílica, en especial en la neuromecánica de la marcha. Los hallazgos de mi tesis indican que el control neural de la marcha se ve afectado en PCAH, y los cambios en el control neural de la marcha están asociados con el daño articular, el dolor y cronicidad de la restricción articular. Desde una perspectiva científica, los cambios en el control neural de la marcha en PCAH implican patrones de actividad alterados de los músculos del tren inferior y una reorganización modular de la marcha. Desde una perspectiva clínica, mi tesis brinda una nueva mirada sobre cómo monitorear la progresión de la enfermedad en PCAH utilizando el índice Walk-DMC, brindando nuevas perspectivas para mejorar las intervenciones terapéuticas que apuntan a recuperar la marcha en PCAH. Haemophilia is a bleeding disorder caused by a deficiency of coagulation factors VIII or factor IX. People with severe haemophilia may have spontaneous bleeding events or bleeding in response to minor trauma; most of the events occur in the joints and muscles. The most frequent clinical manifestation is haemophilic arthropathy, which results from repetitive intraarticular bleeding and inflamed synovial membrane, which may result in chronic pain and joint impairment. The overall aim of my thesis was to investigate the neural control of gait in people with haemophilic arthropathy (PWHA). I hypothesized that neural gait control is affected in PWHA, and the changes in neural control of gait are associated with joint damage and chronicity of the joint constraint. Gait was selected because the knees and ankles are the most prevalent affected joints in adults PWHA. The core of my thesis is investigating neural control by studying electromyography (EMG) activity patterns of single muscles and/or muscle synergies, as well as their interaction with joint kinematics and clinical outcomes. In chapter 1, I provide a general perspective about the impact of haemophilia on the musculoskeletal system, the current gaps in knowledge in the neural control of gait in haemophilic arthropathy, and how to assess the neural control of gait. In Chapters 2 and 4, through the assessments of muscle activation patterns of single muscles, coordination between antagonistic muscle pairs, and muscle synergy analysis, we confirmed the hypothesis that the neural control of gait is affected in PWHA. In chapters 3 and 5, we confirm that the altered neural control of gait in PWHA is associated with the severity of joint damage and chronicity of joint constraint. In chapter 6, we discussed the results of chapters focused on clinical and physiological perspectives of the altered neural control of gait in PWHA. In addition, we discuss how the evaluation of neural control through the Walk-DMC index can be an alternative to monitoring the motor impairment in PWHA. Based on our results, we also discussed on how to improve the outcomes of physical therapy and surgical interventions that aimed to improve the locomotion in PWHA. My thesis contributes to understanding the consequences of haemophilic arthropathy for the neuromechanics of gait. The findings of my thesis indicate that neural control of gait is affected in PWHA, and the changes in the neural control of gait are associated with joint damage, pain and chronicity of the joint constraint. From a scientific perspective, the changes in the neural control of gait in PWHA implicate altered activity patterns of single leg muscles and a modular reorganization of gait. From a clinical perspective, my thesis gives a new perspective on how to monitor disease progression in PWHA using the Walk-DMC index—providing new perspectives to improve the therapeutic interventions that aim to recover gait in PWHA.

Published

2022

302. Static hand posture classification based on the biceps brachii muscle synergy features.

Author

He, Liang and Mathieu, Pierre A.

Subjects

*BICEPS brachii, *MUSCLE injuries, *ELECTROMYOGRAPHY, *POSTURE, *FACTORIZATION, *HAND physiology, *SKELETAL muscle physiology, *ALGORITHMS, *ARTIFICIAL limbs, *BODY movement

Abstract

With modern upper limb myoelectric prostheses, many movements can be produced when many control signals are available. Some of them could originate from the multifunctional biceps brachii which appears to be composed of up to six individually innervated compartments. Given its compartmental nature, this muscle behaves as if composed of many individual muscles acting in synergy to achieve a given motor task. Through an appropriate synergy model, its EMG signals could thus be used to produce some of the many control signals required with modern upper limb myoelectric prostheses. Exploring that possibility, muscular synergy which is usually applied to a group of different muscles, was tested on the biceps brachii only. A non-negative matrix factorization method was applied on pre-recorded data consisting of 8 surface electromyographic signals collected across the biceps of 10 normal subjects who, in Seat or Stand posture, held their hand in 3 different postures. We found that muscular synergies can be extracted from the biceps brachii. With a learning process and a classifier, it was also possible, between a pair of static hand postures, to identify which one was used when a given record was made. The mean score of correctly detected hand posture was >80% for our subjects. [ABSTRACT FROM AUTHOR]

Published

2018

303. The Force Generation in a Two-Joint Arm Model: Analysis of the Joint Torques in the Working Space.

Author

Kostyukov, Alexander I. and Tomiak, Tomasz

Abstract

The two-segment model of the human arm is considered; the shoulder and elbow joint torques (JTs) are simulated, providing a slow, steady rotation of the force vector at any end-point of the horizontal working space. The sinusoidal waves describe the JTs, their periods coincide with that of the rotation, and phases are defined by the slopes of the correspondent lines from the joint axes to the end-point. Analysis of the JTs includes an application of the same discrete changes in one joint angle under fixation of the other one and vice versa; the JT pairs are compared for the "shoulder" and "elbow" end-point traces that pass under fixation of the elbow and shoulder angles, respectively. Both shifts between the sinusoids and their amplitudes are unchanged along the "shoulder" traces, whereas these parameters change along the "elbow" ones. Therefore, if we consider a combined action of both JTs acting at the proximal and distal joints, we can assume that for the end-point transitions along the "shoulder," and "elbow" traces this action possesses isotropic and anisotropic properties, respectively. The model also determines the patterns of the torques of coinciding and opposing directions (TCD, TOD), which would evoke a simultaneous loading of the elbow and shoulder muscles with the coinciding or opposing function (flexors, extensors). For a complete force vector turn, the relationship between the TCD and TOD remains fixed in transitions at the "shoulder" end-point traces, whereas it is changing at the "elbow" ones. [ABSTRACT FROM AUTHOR]

Published

2018

304. Three-Dimensional Representation of Equilibrium Joint Torques in Two-Joint Movements of the Upper Limb.

Author

Vereshchaka, I. V., Pilewska, W., Zasada, M., and Kostyukov, A. I.

Subjects

*ARM, *ANATOMICAL planes, *SHOULDER, *ELBOW, *TORQUE

Abstract

In this theoretical study, two-joint equilibrium muscle contractions were simulated to determine the end-point forces created by the hand of the human right upper limb within the horizontal plane. For invariable frontally directed end-point forces, 3D surfaces simulating joint torques (JTs) at the shoulder and elbow joints are reconstructed by defining the characteristic angles (CAs) between the frontal axis and lines from the joint axes to the end-point. The 3D shoulder JTs are presented by planes oriented perpendicularly to the sagittal plane with a downward sagittal skewness; the elbow JT surfaces are essentially nonlinear, showing higher gradients within the left half of the working space. Oppositely directed end-point forces demonstrate the invariance of the JT surfaces that turn about the zero-torque plane while keeping their shapes. Differences between the JTs in the same curvilinear trajectories of the movements (concentric circles) are also analyzed; generation of unvaried (frontally directed) and changed (tangential) end-point forces are compared. Despite the fact that a symmetric pattern in the shoulder JTs is maintained, a transition from the frontal to tangential forces essentially influences the asymmetric pattern of the elbow JTs. The obtained results are discussed with regard to the control of multijoint movements of the limbs in humans. [ABSTRACT FROM AUTHOR]

Published

2018

305. The motor repertoire of older adult fallers may constrain their response to balance perturbations.

Author

Allen, Jessica L. and Franz, Jason R.

Subjects

*RISK factors of falling down, *GERIATRIC psychology, *MOTOR neurons, *LOCOMOTION, *PERTURBATION theory

Abstract

Older adults are at a high risk of falls, and most falls occur during locomotor activities like walking. This study aimed to improve our understanding of changes in neuromuscular control associated with increased risk of falls in older adults in the presence of dynamic balance challenges during walking. Motor module (also known as muscle synergy) analyses identified changes in the neuromuscular recruitment of leg muscles during walking with and without perturbations designed to elicit the visual perception of lateral instability. During normal walking we found that a history of falls (but not age) was associated with reduced motor module complexity and that age (but not a history of falls) was associated with increased step-tostep variability of module recruitment timing. Furthermore, motor module complexity was unaltered in the presence of optical flow perturbations. The specific effects of a history of falls on leg muscle recruitment included an absence and/or inability to independently recruit motor modules normally recruited to perform biomechanical functions important for walking balance control. These results suggest that fallers do not recruit the appropriate motor modules necessary for well-coordinated walking balance control even in the presence of perturbations. The identified changes in the modular control of walking balance in older fallers may either represent a neural deficit that leads to poor balance control or a prior history of falls that results in a compensatory motor adaptation. In either case, our study provides initial evidence that a reduced motor repertoire in older adult fallers may be a constraint on their ability to appropriately respond to balance challenges during walking. [ABSTRACT FROM AUTHOR]

Published

2018

306. Inter-Limb Muscle Synergies and Kinematic Analysis of Hands-and-Knees Crawling in Typically Developing Infants and Infants With Developmental Delay.

Author

Xiong, Qi L., Wu, Xiao Y., Yao, Jun, Sukal-Moulton, Theresa, Xiao, Nong, Chen, Lin, Zheng, Xiao L., Liu, Yuan, and Hou, Wen S.

Abstract

Hands-and-knees-crawling is an important motor developmental milestone and a unique window into the development of central nervous system (CNS). Mobility during crawling is regularly used in clinical assessments to identify delays in motor development. However, possible contribution from CNS impairments to motor development delay is still unknown. The aim of this study was to quantify and compare inter-limb muscle synergy and kinematics during crawling among infants at a similar developmental age, however, clinically determined to be typically developing (TD, N = 20) infants, infants at risk of developmental delay (ARDD, N = 33), or infants with confirmed developmental delay (CDD, N = 13). We hypothesized that even though all of the groups are at a similar developmental age, there would be differences in kinematic measures during crawling, and such differences would be associated with CNS impairment as measured by electromyography (EMG) features. Surface EMG of eight arm and leg muscles and the corresponding joint kinematic data were collected while participants crawled on hands and knees at their self-selected velocity. Temporal-spatial parameters and normalized Jerk-Cost (JC) function (i.e., smoothness of movement) were computed from the measured kinematics. The inter-limb muscle synergy and the number of co-activating muscles per synergy were measured using EMGs. We found that the infants with CDD demonstrated higher normalized JC values (less movement smoothness), fewer muscle synergies, and more co-activating muscles per synergy, compared to infants with TD (p < 0.05) and ARDD (p < 0.05). Furthermore, the normalized JC values were correlated (p < 0.05) with the number of co-activation muscles per synergy. Our results suggest a constrained neuromuscular control strategy due to neurological injury in infants with CDD, and such constrain may contribute to the reduced movement smoothness in infant crawling. [ABSTRACT FROM AUTHOR]

Published

2018

307. Neuromuscular determinants of slip-induced falls and recoveries in older adults.

Author

Sawers, Andrew and Bhatt, Tanvi

Subjects

*NEUROMUSCULAR system, *HUMAN experimentation, *KINEMATICS, *MOTOR ability, *MUSCULOSKELETAL system

Abstract

Is there a neuromuscular basis for falls? If so, it may provide new insight into falls and their assessment and treatment. We hypothesized that falls and recoveries from a laboratory-induced slip would be characterized by differences in multimuscle coordination patterns. Using muscle synergy analysis, we identified different multimuscle coordination patterns between older adults who fell and those who recovered from a laboratory-induced "feet-forward" slip. Participants who fell recruited fewer muscle synergies than participants who recovered. This suggests that a fall may result from recruitment of an inadequate number of muscle synergies to produce the necessary mechanical functions required to maintain balance. Participants who fell also recruited different muscle synergies, including one with high levels of coactivity consistent with a startle-like response. These differences in multimuscle coordination between slip outcomes were not accompanied by differences in slip difficulty or gait kinematics before or during the slip response. The differences in neuromuscular control may therefore reflect differences in sensorimotor control rather than kinematic constraints imposed by the slip, or the musculoskeletal system. Further research is required to test the robustness of these results and their interpretation with respect to additional mechanical variables (e.g., joint torques, ground reaction forces), responses to other fall types (e.g., trips), and within rather than between individuals. NEW & NOTEWORTHY Do falls and recoveries possess distinct neuromuscular features? We identified differences in neuromuscular control between older adults who fell and those who recovered from a "feet-forward" slip. Differences in neuromuscular control were not accompanied by differences in gait or slip kinematics before or during the slip response, suggesting differences in sensorimotor control rather than kinematics dictated the observed differences in neuromuscular control. An analysis of additional mechanical variables is required to confirm this interpretation. [ABSTRACT FROM AUTHOR]

Published

2018

308. Degraded Synergistic Recruitment of sEMG Oscillations for Cerebral Palsy Infants Crawling.

Author

Gao, Zhixian, Chen, Lin, Xiong, Qiliang, Xiao, Nong, Jiang, Wei, Liu, Yuan, Wu, Xiaoying, and Hou, Wensheng

Subjects

MOTOR ability in infants, ELECTROMYOGRAPHY, INFANT development

Abstract

Background: Synergistic recruitment of muscular activities is a generally accepted mechanism for motor function control, and motor dysfunction, such as cerebral palsy (CP), destroyed the synergistic electromyography activities of muscle group for limb movement. However, very little is known how motor dysfunction of CP affects the organization of the myoelectric frequency components due to the abnormal motor unit recruiting patterns. Objectives: Exploring whether the myoelectric activity can be represented with synergistic recruitment of surface electromyography (sEMG) frequency components; evaluating the effect of CP motor dysfunction on the synergistic recruitment of sEMG oscillations. Methods: Twelve CP infants and 17 typically developed (TD) infants are recruited for self-paced crawling on hands and knees. sEMG signals have been recorded from bilateral biceps brachii (BB) and triceps brachii (TB) muscles. Multi-scale oscillations are extracted via multivariate empirical mode decomposition (MEMD), and non-negative matrix factorization (NMF) method is employed to obtain synergistic pattern of these sEMG oscillations. The coefficient curve of sEMG oscillation synergies are adopted to quantify the time-varying recruitment of BB and TB myoelectric activity during infants crawling. Results: Three patterns of sEMG oscillation synergies with specific frequency ranges are extracted in BB and TB of CP or TD infants. The contribution of low-frequency oscillation synergy of BB in CP group is significantly less than that in TD group (p < 0.05) during forward swing phase for slow contraction; however, this low-frequency oscillation synergy keep higher level during the backward swing phase crawling. For the myoelectric activities of TB, there is not enough high-frequency oscillation recruitment of sEMG for the fast contraction in propulsive phase of CP infants crawling. Conclusion: Our results reveal that, the myoelectric activities of a muscle can be manifested as sEMG oscillation synergies, and motor dysfunction of CP degrade the synergistic recruitment of sEMG oscillations due to the impaired CNS regulation and destroyed MU/muscle fiber. Our preliminary work suggests that time-varying coefficient curve of sEMG oscillation synergies is a potential index to evaluate the abnormal recruitment of electromyography activities affected by CP disorders. [ABSTRACT FROM AUTHOR]

Published

2018

309. Alterations of Muscle Synergies During Voluntary Arm Reaching Movement in Subacute Stroke Survivors at Different Levels of Impairment.

Author

Pan, Bingyu, Sun, Yingfei, Xie, Bin, Huang, Zhipei, Wu, Jiankang, Hou, Jiateng, Liu, Yijun, Huang, Zhen, and Zhang, Zhiqiang

Subjects

SPINAL cord injuries, STROKE, ELECTROMYOGRAPHY, MUSCLE physiology, BODY movement

Abstract

Motor system uses muscle synergies as a modular organization to simplify the control of movements. Motor cortical impairments, such as stroke and spinal cord injuries, disrupt the orchestration of the muscle synergies and result in abnormal movements. In this paper, the alterations of muscle synergies in subacute stroke survivors were examined during the voluntary reaching movement. We collected electromyographic (EMG) data from 35 stroke survivors, ranging from Brunnstrom Stage III to VI, and 25 age-matched control subjects. Muscle synergies were extracted from the activity of 7 upper-limb muscles via nonnegative matrix factorization under the criterion of 95% variance accounted for. By comparing the structure of muscle synergies and the similarity of activation coefficients across groups, we can validate the increasing activation of pectoralis major muscle and the decreasing activation of elbow extensor of triceps in stroke groups. Furthermore, the similarity of muscle synergies was significantly correlated with the Brunnstrom Stage (R = 0.52, p < 0.01). The synergies of stroke survivors at Brunnstrom Stage IV–III gradually diverged from those of control group, but the activation coefficients remained the same after stroke, irrespective of the recovery level. [ABSTRACT FROM AUTHOR]

Published

2018

310. Estimation of Time-Varying Coherence Amongst Synergistic Muscles During Wrist Movements.

Author

Hu, Guiting, Yang, Wenjuan, Chen, Xiaoling, Qi, Wenjing, Li, Xinxin, Du, Yihao, and Xie, Ping

Subjects

TIME-varying systems, SKELETAL muscle, WRIST

Abstract

The central nervous system (CNS) controls the limb movement by modulating multiple skeletal muscles with synergistic modules and neural oscillations with different frequencies between the activated muscles. Several researchers have found intermuscular coherence existing within the synergistic muscle pairs, and pointed out that the intermuscular synchronization existed when functional forces were generated. However, few studies involved the time-varying characteristics of the intermuscular coherence in each synergy module though all activated muscles keep in a dynamic and varying process. Therefore, this study aims to explore the time-varying coherence amongst synergistic muscles during movements based on the combination of the non-negative matrix factorization (NMF) method and the time-frequency coherence (TFC) method. We applied these methods into the electromyogram (EMG) signals recorded from eight muscles involved in the sequence of the wrist movements [wrist flexion (WF), wrist flexion transmission to wrist extension (MC) and wrist extension (WE)] in 12 healthy people. The results showed three synergistic flexor pairs (FCR-PL, FCR-FDS, and PL-FDS) in the WF stage and three extensor pairs (ECU-ECR, ECU-B, and ECR-B) in both MC and WE stages. Further analysis showed intermuscular coherence between each pairwise synergistic muscles. The intermuscular coherence between the flexor muscle pairs was mainly observed in the beta band (15–35 Hz) during the WF stage, and that amongst the extensor muscle pairs was also observed in the beta band during the WE stage. However, the intermuscular coherence between the extensor muscle pairs mainly on gamma band during the MC stage. Additionally, compared to the flexor muscle pairs, the intermuscular coherence of the extensor muscle pairs were lower in the WF stage, and higher in both MC and WE stages. These results demonstrated the time-varying mechanisms of the synergistic modulation and synchronous oscillation in motor-control system. This study contributes to expanded researches for motor control. [ABSTRACT FROM AUTHOR]

Published

2018

311. A recurrent neural network model for generation of humanlike reaching movements.

Author

Tsuzuki, Yuta and Ogihara, Naomichi

Subjects

*ARTIFICIAL neural networks, *HUMANOID robots, *PNEUMATIC control, *ARTIFICIAL muscles, *HUMAN mechanics, *CENTRAL nervous system

Abstract

We constructed a recurrent neural network model that can generate human reaching motion. Given a target position, the neural network model is capable of producing muscular activation signals that move the hand to the target endpoint, while solving the problem of musculoskeletal redundancy by dynamic relaxation of the energy functions embedded in the network. The proposed neural network model was integrated with a two-dimensional three-link eight muscle musculoskeletal model of the human arm to simulate arm reaching movements in the horizontal and sagittal planes. Our results demonstrate that the model is capable of generating natural arm movements that have spatiotemporal features, such as a slightly curved hand path and the characteristic bell-shaped velocity profile, that are similar to those of actual human movements. Some aspects of the proposed computational framework might be utilized in the central nervous system for generation of reaching movements. [ABSTRACT FROM AUTHOR]

Published

2018

312. Neuromuscular synergies in motor control in normal and poststroke individuals.

Author

Israely, Sharon, Leisman, Gerry, and Carmeli, Eli

Subjects

MOTOR ability, NEUROLOGICAL disorders, CENTRAL nervous system, MOTOR neurons, STROKE

Abstract

Muscle synergies are proposed to function as motor primitives that are modulated by frontal brain areas to construct a large repertoire of movement. This paper reviews the history of the development of our current theoretical understanding of nervous system-based motor control mechanisms and more specifically the concept of muscle synergies. Computational models of muscle synergies, especially the nonnegative matrix factorization algorithm, are discussed with specific reference to the changes in synergy control post-central nervous system (CNS) lesions. An alternative approach for motor control is suggested, exploiting a combination of synergies control or flexible muscle control used for gross motor skills and for individualized finger movements. Rehabilitation approaches, either supporting or inhibiting the use of basic movement patterns, are discussed in the context of muscle synergies. Applications are discussed for the use of advanced technologies that can promote the recovery and functioning of the human CNS after stroke. [ABSTRACT FROM AUTHOR]

Published

2018

313. Evaluation of matrix factorisation approaches for muscle synergy extraction.

Author

Ebied, Ahmed, Kinney-Lang, Eli, Spyrou, Loukianos, and Escudero, Javier

Subjects

*FACTORIZATION, *BIOMECHANICS, *PROSTHETICS, *PRINCIPAL components analysis, *INDEPENDENT component analysis

Abstract

The muscle synergy concept provides a widely-accepted paradigm to break down the complexity of motor control. In order to identify the synergies, different matrix factorisation techniques have been used in a repertoire of fields such as prosthesis control and biomechanical and clinical studies. However, the relevance of these matrix factorisation techniques is still open for discussion since there is no ground truth for the underlying synergies. Here, we evaluate factorisation techniques and investigate the factors that affect the quality of estimated synergies. We compared commonly used matrix factorisation methods: Principal component analysis (PCA), Independent component analysis (ICA), Non-negative matrix factorization (NMF) and second-order blind identification (SOBI). Publicly available real data were used to assess the synergies extracted by each factorisation method in the classification of wrist movements. Synthetic datasets were utilised to explore the effect of muscle synergy sparsity, level of noise and number of channels on the extracted synergies. Results suggest that the sparse synergy model and a higher number of channels would result in better estimated synergies. Without dimensionality reduction, SOBI showed better results than other factorisation methods. This suggests that SOBI would be an alternative when a limited number of electrodes is available but its performance was still poor in that case. Otherwise, NMF had the best performance when the number of channels was higher than the number of synergies. Therefore, NMF would be the best method for muscle synergy extraction. [ABSTRACT FROM AUTHOR]

Published

2018

314. Temporal exploration in sequential movements shapes efficient neuromuscular control.

Author

Shinichi Furuya and Sayuri Yokota

Subjects

*NEUROMUSCULAR system, *ELECTROMYOGRAPHY, *NEUROPLASTICITY, *PERFECTION, *SEQUENTIAL analysis, *FACTORIZATION

Abstract

The interaction of early and deliberate practice with genetic predisposition endows experts with virtuosic motor performance. However, it has not been known whether ways of practicing shape motor virtuosity. Here, we addressed this issue by comparing the effects of rhythmic variation in motor practice on neuromuscular control of the finger movements in pianists. With the use of a novel electromyography system with miniature active electrodes, we recorded the activity of the intrinsic hand muscles of 27 pianists while they played the piano and analyzed it by using a nonnegative matrix factorization algorithm and cluster analysis. The result demonstrated that practicing a target movement sequence with various rhythms reduced muscular activity, whereas neither practicing a sequence with a single rhythm nor taking a rest without practicing changed the activity. In addition, practice with rhythmic variation changed the patterns of simultaneous activations across muscles. This alteration of muscular coordination was associated with decreased activation of muscles not only relevant to, but also irrelevant to the task performance. In contrast, piano practice improved the maximum speed of the performance, the amount of which was independent of whether rhythmic variation was present. These results suggest that temporal variation in movement sequences during practice co-optimizes both movement speed and neuromuscular efficiency, which emphasizes the significance of ways of practice in the acquisition of motor virtuosity. [ABSTRACT FROM AUTHOR]

Published

2018

315. Electromyogram refinement using muscle synergy based regulation of uncertain information.

Author

Min, Kyuengbo, Shin, Duk, Lee, Jongho, and Kakei, Shinji

Subjects

*BLAND-Altman plot, *BIOLOGICAL research, *SKELETAL muscle, *ELECTROMYOGRAPHY, *ELECTRIC signs

Abstract

Electromyogram signal (EMG) measurement frequently experiences uncertainty attributed to issues caused by technical constraints such as cross talk and maximum voluntary contraction. Due to these problems, individual EMGs exhibit uncertainty in representing their corresponding muscle activations. To regulate this uncertainty, we proposed an EMG refinement, which refines EMGs with regulating the contribution redundancy of the signals from EMGs to approximating torques through EMG-driven torque estimation (EDTE) using the muscular skeletal forward dynamic model. To regulate this redundancy, we must consider the synergistic contribution redundancy of muscles, including “unmeasured” muscles, to approximating torques, which primarily causes redundancy of EDTE. To suppress this redundancy, we used the concept of muscle synergy, which is a key concept of analyzing the neurophysiological regulation of contribution redundancy of muscles to exerting torques. Based on this concept, we designed a muscle-synergy-based EDTE as a framework for EMG refinement, which regulates the abovementioned uncertainty of individual EMGs in consideration of unmeasured muscles. In achieving the proposed EMG refinement, the most considerable point is to suppress a large change such as overestimation attributed to enhancement of the contribution of particular muscles to estimating torques. Therefore it is reasonable to refine EMGs by minimizing the change in EMGs. To evaluate this model, we used a Bland-Altman plot, which quantitatively evaluates the proportional bias of refined signals to EMGs. Through this evaluation, we showed that the proposed EDTE minimizes the bias while approximating torques. Therefore this minimization optimally regulates the uncertainty of EMGs and thereby leads to optimal EMG refinement. [ABSTRACT FROM AUTHOR]

Published

2018

316. Specific muscle synergies in national elite female ice hockey players in response to unexpected external perturbation.

Author

Kim, Minhee, Kim, Yushin, Kim, Hyeyoung, and Yoon, BumChul

Subjects

*ANKLE, *CLUSTER analysis (Statistics), *ELECTROMYOGRAPHY, *HOCKEY, *MUSCLES, *POSTURE, *WOMEN athletes, *ELITE athletes, *DORSIFLEXION, *PLANTARFLEXION

Abstract

This study aimed to investigate specific muscle synergies in elite ice hockey players indicating highly developed postural control strategies used to restore balance against unexpected external perturbations. Seven elite athletes (EA) on the women’s national ice hockey team and 7 non-athletes (NA) participated in this study. Based on trajectories of centre of mass (COM), analysis periods were divided into an initial phase (a balance disturbance after perturbation onset) and a reversal phase (a balance recovery response), respectively. Muscle synergies were extracted at each phase by using non-negative matrix factorization.k-means cluster analysis was performed to arrange similar muscle synergies in all participants. EA showed significantly shorter recovery period of COM and smaller body sway than NA. In the initial phase, we identified 2 EA-specific synergies related to ankle plantar flexors or neck extensors. In the case of an NA-specific synergy, co-activation of the ankle plantar flexors and dorsiflexors was found. In the reversal phase, no specific muscle synergies were identified. As the results, EA-specific muscle synergies showed low co-activation strategy of agonists and antagonists in ankle and neck extensors. Our results could provide critical information for rehabilitation strategies in athletes requiring high postural stability. [ABSTRACT FROM PUBLISHER]

Published

2018

317. Past, Present, and Emerging Principles in the Neural Encoding of Movement

Author

Ebner, Timothy J., Hendrix, Claudia M., Pasalar, Siavash, and Sternad, Dagmar, editor

Published

2009

318. EMG-Based Position and Force Estimates in Coupled Human-Robot Systems: Towards EMG-Controlled Exoskeletons

Author

Artemiadis, Panagiotis K., Kyriakopoulos, Kostas J., Siciliano, Bruno, editor, Khatib, Oussama, editor, Groen, Frans, editor, Kumar, Vijay, editor, and Pappas, George J., editor

Published

2009

319. Adopting a Tensor-Type Muscle Synergy to an Upper Arm Gym-Workout Analysis

Author

Janghyeon Kim, Ji-Hyeon Yoo, Han Ul Yoon, and Dae Han Sim

Subjects

Physics, Tensor (intrinsic definition), Mathematical analysis, Type (model theory), Muscle synergy

Published

2021

320. Compromised neuromuscular function of walking in people with diabetes: A narrative review.

Author

Hoveizavi, Roya, Gao, Fan, Ramirez, Vanessa J., Shuman, Benjamin R., Joiner, Joshua C., and Fisher, Simon J.

Subjects

*PEOPLE with diabetes, *NEUROMUSCULAR system physiology, *RANGE of motion of joints, *ACHILLES tendon, *WALKING speed

Abstract

This review summarizes recent studies that have investigated the neuromuscular dysfunction of walking in people with diabetes and its relationship to ulcer formation. A comprehensive electronic search in the database (Scopus, Web of Science, PsycINFO, ProQuest, and PubMed) was performed for articles pertaining to diabetes and gait biomechanics. The Achilles tendon is thicker and stiffer in those with diabetes. People with diabetes demonstrate changes in walking kinematics and kinetics, including slower self-selected gait speed, shorter stride length, longer stance phase duration, and decreased ankle, knee, and metatarsophalangeal (MTP) joint range of motion. EMG is altered during walking and may reflect diabetes-induced changes in muscle synergies. Synergies are notable because they provide a more holistic pattern of muscle activations and can help develop better tools for characterizing disease progression. Diabetes compromises neuromuscular coordination and function. The mechanisms contributing to ulcer formation are incompletely understood. Diabetes-related gait impairments may be a significant independent risk factor for the development of foot ulcers. [ABSTRACT FROM AUTHOR]

Published

2023

321. Using different matrix factorization approaches to identify muscle synergy in stroke survivors.

Author

Ma, Yehao, Ye, Sijia, Zhao, Dazheng, Liu, Xiaoguang, Cao, Ling, Zhou, Huilin, Zuo, Guokun, and Shi, Changcheng

Subjects

*MATRIX decomposition, *STROKE patients, *SINGULAR value decomposition, *INDEPENDENT component analysis, *NONNEGATIVE matrices

Abstract

• A performance comparison of different matrix factorization methods (MCR-ALS, SVD-NMF, S-NMF, NMF, ICA and FA) in muscle synergy identification for stroke patients was presented in this paper. • The influences of initial processes of different matrix factorization methods on muscle synergy identification were studied in this paper. • The characteristics of muscle synergies of stroke survivors using different matrix factorization methods were analyzed in this paper. Over the past several decades, many scholars have investigated muscle synergy as a promising tool for evaluating motor function. However, it is challenging to obtain favorable robustness using the general muscle synergy identification algorithms, namely non-negative matrix factorization (NMF), independent component analysis (ICA), and factor analysis (FA). Some scholars have proposed improved muscle synergy identification algorithms to overcome the shortcomings of these approaches, such as singular value decomposition NMF (SVD-NMF), sparse NMF (S-NMF), and multivariate curve resolution-alternating least squares (MCR-ALS). However, performance comparisons of these algorithms are seldom conducted. In this study, experimental electromyography (EMG) data collected from healthy individuals and stroke survivors were applied to assess the repeatability and intra-subject consistency of NMF, SVD-NMF, S-NMF, ICA, FA, and MCR-ALS. MCR-ALS presented higher repeatability and intra-subject consistencies than the other algorithms. More synergies and lower intra-subject consistencies were observed in stroke survivors than in healthy individuals. Thus, MCR-ALS is considered a favorable muscle synergy identification algorithm for patients with neural system disorders. [ABSTRACT FROM AUTHOR]

Published

2023

322. Altered neural control of gait and its association with pain and joint impairment in adults with haemophilic arthropathy: Clinical and methodological implications

Author

Cruz-Montecinos, Carlos, Maas, Huub, Cerda, Mauricio, Pérez-Alenda, Sofía, Cruz-Montecinos, Carlos, Maas, Huub, Cerda, Mauricio, and Pérez-Alenda, Sofía

Abstract

Introduction: It is unknown whether altered neural control is associated with clinical outcomes in people with haemophilic arthropathy (PWHA). The dynamic motor control index during walking (Walk-DMC) is a summary metric of neural control. Aims: The primary aim of this study was to apply the Walk-DMC to assess if people diagnosed with haemophilic arthropathy have impaired neural control of gait and investigate the association of Walk-DMC with pain and joint impairment. Method: The Walk-DMC was assessed using surface electromyography in 11 leg muscles. Twenty-two PWHA and 15 healthy subjects walked on a 30-m walkway at 1 m/s. In addition, pain (visual analogue scale), knee flexion contracture (degrees) and joint impairment (Haemophilia Joint Health Score, HJHS) were assessed. The clinical outcomes were correlated with the Walk-DMC. Multiple regression analysis was performed to predict the Walk-DMC using the clinical outcomes. Results: In 13 PWHA the Walk-DMC was beyond the normal range (80–120 pts). PWHA with an altered Walk-DMC showed more years with arthropathy, more pain, higher knee flexion contracture and a higher HJHS score (P <.05, effect size >.8). Significant negative moderate associations between Walk-DMC and pain, knee flexion contracture and HJHS were found (P <.05). The model that best predicted the Walk-DMC was the pain with knee flexion contracture (R2=.44; P =.004). Conclusions: PWHA with abnormal neural control of gait also has more years with arthropathy, more pain, and more impaired joints. Our results indicate an association between the Walk-DMC index and joint damage, specifically with pain in combination with knee flexion contracture.

Published

2022

323. EMG-driven musculoskeletal model calibration with estimation of unmeasured muscle excitations via synergy extrapolation.

Author

Ao, Di, Ao, Di, Vega, Marleny M, Shourijeh, Mohammad S, Patten, Carolynn, Fregly, Benjamin J, Ao, Di, Ao, Di, Vega, Marleny M, Shourijeh, Mohammad S, Patten, Carolynn, and Fregly, Benjamin J

Abstract

Subject-specific electromyography (EMG)-driven musculoskeletal models that predict muscle forces have the potential to enhance our knowledge of internal biomechanics and neural control of normal and pathological movements. However, technical gaps in experimental EMG measurement, such as inaccessibility of deep muscles using surface electrodes or an insufficient number of EMG channels, can cause difficulties in collecting EMG data from muscles that contribute substantially to joint moments, thereby hindering the ability of EMG-driven models to predict muscle forces and joint moments reliably. This study presents a novel computational approach to address the problem of a small number of missing EMG signals during EMG-driven model calibration. The approach (henceforth called "synergy extrapolation" or SynX) linearly combines time-varying synergy excitations extracted from measured muscle excitations to estimate 1) unmeasured muscle excitations and 2) residual muscle excitations added to measured muscle excitations. Time-invariant synergy vector weights defining the contribution of each measured synergy excitation to all unmeasured and residual muscle excitations were calibrated simultaneously with EMG-driven model parameters through a multi-objective optimization. The cost function was formulated as a trade-off between minimizing joint moment tracking errors and minimizing unmeasured and residual muscle activation magnitudes. We developed and evaluated the approach by treating a measured fine wire EMG signal (iliopsoas) as though it were "unmeasured" for walking datasets collected from two individuals post-stroke-one high functioning and one low functioning. How well unmeasured muscle excitations and activations could be predicted with SynX was assessed quantitatively for different combinations of SynX methodological choices, including the number of synergies and categories of variability in unmeasured and residual synergy vector weights across trials. The two best met

Published

2022

324. Anatomical Description and Its Limitations

Author

Knudson, Duane and Knudson, Duane

Published

2007

325. Extracting Motion Primitives from Natural Handwriting Data

Author

Williams, Ben H., Toussaint, Marc, Storkey, Amos J., Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Dough, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Kollias, Stefanos, editor, Stafylopatis, Andreas, editor, Duch, Włodzisław, editor, and Oja, Erkki, editor

Published

2006

326. Association between Slip Severity and Muscle Synergies of Slipping

Author

Mohammad Moein Nazifi, Kurt E. Beschorner, and Pilwon Hur

Subjects

motor control, muscle synergy, slip, gait, fall, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Falls impose significant negative impacts to the US population and economy. A significant number of falls may be prevented via appropriate slip-responses since a strong relation exists between slips and falls. More importantly, as severe slips are more prone to result in a fall, identifying severe slippers along with the responsible factors for their adverse motor control and severe slipping should be the highest priority in fall prevention process. Previous studies have suggested that muscle synergies may be building blocks of the central nervous system in controlling motor tasks. Muscle synergies observed during slipping (‘post-slip-initiation synergies’ or ‘just briefly,’ ‘slipping muscle synergies’), may represent the fundamental blocks of the neural control during slipping. Hence, studying the differences in slipping muscle synergies of mild and severe slippers can potentially reveal the differences in their neural control and subsequently, indicate the responsible factors for the adverse post-slip response in severe slippers. Even though the slipping muscle synergies have been investigated before, it still remains unclear on how the slip severity is associated with the slipping muscle synergies. More importantly, muscle synergies can be interpreted not only as neural blocks but also as physical sub-tasks of the main motor task. Hence, studying the differences of slipping synergies of mild and severe slippers would reveal the discrepancies in sub-tasks of their post-slip response. These discrepancies help pinpoint the malfunctioning sub-function associated with inadequate motor response seen in severe slippers. Twenty healthy subjects were recruited and underwent an unexpected slip (to extract their slipping synergies). Subjects were classified into mild and severe slippers based on their Peak Heel Speed. An independent t-test revealed several significant inter-group differences for muscle synergies of mild and severe slippers indicating differences in their neural control of slipping. A forward dynamic simulation was utilized to reveal the functionality of each synergy. Decomposition of slipping into sub-tasks (synergies), and finding the malfunctioning sub-task in severe slippers is important as it results in a novel targeted motor-rehabilitation technique that only aims to re-establish the impaired sub-task responsible for the adverse motor-response in severe slippers.

Published

2017

327. Action Direction of Muscle Synergies in Voluntary Multi-Directional Postural Control

Author

Akari Kubo, Shota Hagio, Benio Kibushi, Toshio Moritani, and Motoki Kouzaki

Subjects

center of pressure, electromyogram-weighted averaging method, motor control, muscle synergy, non-negative matrix factorization, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

A muscle synergy is a coordinative structure of muscles that has been proposed as a strategy to reduce the number of variables that the central nervous system (CNS) has to address in motor tasks. In this article, the mechanical contribution of muscle synergies and coordinative structures of muscles in voluntary multi-directional postural control were investigated. The task for healthy, young subjects was to shift and align their center of pressure (COP) to targets dispersed in 12 different directions in the horizontal plane by leaning their bodies for 10 s. Electromyograms (EMGs) of 18 muscles and COPs were recorded in the experiment. Muscle synergies were extracted using non-negative matrix factorization (NMF), and the structure of coordinative modules to keep the posture leaning toward various directions was disclosed. Then the directional properties, such as the mechanical role (i.e., action directions, we use ADs as abbreviation below), of muscle synergies and muscles were estimated using an electromyogram-weighted averaging (EWA) method, which is based on a cross-correlation between the fluctuations in the activation of muscle synergies and the COP. The results revealed that the ADs of muscle synergies were almost uniformly distributed in the task space in most of the subjects, which indicates that mechanical characteristics reduce the redundancy in postural control. In terms of the composition of muscle synergies and the ADs of individual muscles, we confirmed that muscle synergies in multi-directional postural control comprised a combination of several muscles, including various ADs, that generate torque at different joints.

Published

2017

328. Evaluation of Functional Correlation of Task-Specific Muscle Synergies with Motor Performance in Patients Poststroke

Author

Si Li, Cheng Zhuang, Chuanxin M. Niu, Yong Bao, Qing Xie, and Ning Lan

Subjects

muscle synergy, stroke, physiological index, reaching movement, motor performance, kinematics, Neurology. Diseases of the nervous system, RC346-429

Abstract

The central nervous system produces movements by activating specifically programmed muscle synergies that are also altered with injuries in the brain, such as stroke. In this study, we hypothesize that there exists a positive correlation between task-specific muscle synergy and motor functions at joint and task levels in patients following stroke. The purpose here is to define and evaluate neurophysiological metrics based on task-specific muscle synergy for assessing motor functions in patients. A patient group of 10 subjects suffering from stroke and a control group of nine age-matched healthy subjects were recruited to participate in this study. Electromyography (EMG) signals and movement kinematics were recorded in patients and control subjects while performing arm reaching tasks. Muscle synergies of individual patients were extracted off-line from EMG records of each patient, and a baseline pattern of muscle synergy was obtained from the pooled EMG data of all nine control subjects. Peak velocities and movement durations of each reaching movement were computed from measured kinematics. Similarity indices of matching components to those of the baseline synergy were defined by synergy vectors and time profiles, respectively, as well as by a combined similarity of vector and time profile. Results showed that pathological synergies of patients were altered from the characteristics of baseline synergy with missing components, or varied vector patterns and time profiles. The kinematic performance measured by peak velocities and movement durations was significantly poorer for the patient group than the control group. In patients, all three similarity indices were found to correlate significantly to the kinematics of movements for the reaching tasks. The correlation to the Fugl-Meyer score of arm was the highest with the vector index, the lowest with the time profile index, and in between with the combined index. These findings illustrate that the analysis of task-specific muscle synergy can provide valuable insights into motor deficits for patients following stroke, and the task-specific similarity indices are useful neurophysiological metrics to predict the function of neuromuscular control at the joint and task levels for patients.

Published

2017

329. A Longitudinal Electromyography Study of Complex Movements in Poststroke Therapy. 2: Changes in Coordinated Muscle Activation

Author

Negin Hesam-Shariati, Terry Trinh, Angelica G. Thompson-Butel, Christine T. Shiner, and Penelope A. McNulty

Subjects

muscle synergy, non-negative matrix factorization, upper limb, rehabilitation, chronic stroke, Neurology. Diseases of the nervous system, RC346-429

Abstract

Fine motor control is achieved through the coordinated activation of groups of muscles, or “muscle synergies.” Muscle synergies change after stroke as a consequence of the motor deficit. We investigated the pattern and longitudinal changes in upper limb muscle synergies during therapy in a largely unconstrained movement in patients with a broad spectrum of poststroke residual voluntary motor capacity. Electromyography (EMG) was recorded using wireless telemetry from 6 muscles acting on the more-affected upper body in 24 stroke patients at early and late therapy during formal Wii-based Movement Therapy (WMT) sessions, and in a subset of 13 patients at 6-month follow-up. Patients were classified with low, moderate, or high motor-function. The Wii-baseball swing was analyzed using a non-negative matrix factorization (NMF) algorithm to extract muscle synergies from EMG recordings based on the temporal activation of each synergy and the contribution of each muscle to a synergy. Motor-function was clinically assessed immediately pre- and post-therapy and at 6-month follow-up using the Wolf Motor Function Test, upper limb motor Fugl-Meyer Assessment, and Motor Activity Log Quality of Movement scale. Clinical assessments and game performance demonstrated improved motor-function for all patients at post-therapy (p 0.05). NMF analysis revealed fewer muscle synergies (mean ± SE) for patients with low motor-function (3.38 ± 0.2) than those with high motor-function (4.00 ± 0.3) at early therapy (p = 0.036) with an association trend between the number of synergies and the level of motor-function. By late therapy, there was no significant change between groups, although there was a pattern of increase for those with low motor-function over time. The variability accounted for demonstrated differences with motor-function level (p

Published

2017

330. Analysis of muscle synergy and kinematics in sit-to-stand motion of hemiplegic patients in subacute period

Author

Takanori Fujii, Qi An, Fady Alnajjar, Hiroyuki Hamada, Hironori Otomune, Hiroshi Yamasaki, Hajime Asama, Ichiro Miyai, Ruoxi Wang, Yusuke Tamura, Hiroki Kogami, Noriaki Hattori, Kazunori Yoshida, Koji Takahashi, Atsushi Yamashita, Hiroshi Yamakawa, Ningjia Yang, Shingo Shimoda, and Moeka Yokoyama

Subjects

0209 industrial biotechnology, medicine.medical_specialty, medicine.medical_treatment, 02 engineering and technology, Kinematics, Motion (physics), 020901 industrial engineering & automation, Physical medicine and rehabilitation, 0202 electrical engineering, electronic engineering, information engineering, medicine, Muscle synergy, Stroke, Rehabilitation, Sit to stand, business.industry, fungi, food and beverages, medicine.disease, Computer Science Applications, Human-Computer Interaction, Hardware and Architecture, Control and Systems Engineering, 020201 artificial intelligence & image processing, business, Software, Period (music)

Abstract

Patients with stroke experience declined physical functions and aim to recover by rehabilitation. It is important to improve their functions in the subacute period. Hemiplegic patients who can stan...

Published

2021

331. Approaches to revealing the neural basis of muscle synergies: a review and a critique

Author

Vincent C. K. Cheung and Kazuhiko Seki

Subjects

Central Nervous System, Motor module, Basis (linear algebra), Electromyography, Physiology, Computer science, General Neuroscience, Models, Neurological, Motor Activity, Neurophysiology, Modularity, Identification (information), Generative model, medicine.anatomical_structure, medicine, Animals, Humans, Muscle, Skeletal, Muscle synergy, Neuroscience, Psychomotor Performance, Motor cortex

Abstract

The central nervous system (CNS) may produce coordinated motor outputs via the combination of motor modules representable as muscle synergies. Identification of muscle synergies has hitherto relied on applying factorization algorithms to multimuscle electromyographic data (EMGs) recorded during motor behaviors. Recent studies have attempted to validate the neural basis of the muscle synergies identified by independently retrieving the muscle synergies through CNS manipulations and analytic techniques such as spike-triggered averaging of EMGs. Experimental data have demonstrated the pivotal role of the spinal premotor interneurons in the synergies’ organization and the presence of motor cortical loci whose stimulations offer access to the synergies, but whether the motor cortex is also involved in organizing the synergies has remained unsettled. We argue that one difficulty inherent in current approaches to probing the synergies’ neural basis is that the EMG generative model based on linear combination of synergies and the decomposition algorithms used for synergy identification are not grounded on enough prior knowledge from neurophysiology. Progress may be facilitated by constraining or updating the model and algorithms with knowledge derived directly from CNS manipulations or recordings. An investigative framework based on evaluating the relevance of neurophysiologically constrained models of muscle synergies to natural motor behaviors will allow a more sophisticated understanding of motor modularity, which will help the community move forward from the current debate on the neural versus nonneural origin of muscle synergies.

Published

2021

332. Artificial neural network that modifies muscle activity in sit-to-stand motion using sensory input

Author

Kazunori Yoshida, Hiroshi Yamakawa, Atsushi Yamashita, Yusuke Tamura, Qi An, Hiroyuki Hamada, and Hajime Asama

Subjects

musculoskeletal diseases, 0209 industrial biotechnology, Artificial neural network, Sit to stand, Mechanism (biology), Computer science, 02 engineering and technology, musculoskeletal system, Motion (physics), Computer Science Applications, Human-Computer Interaction, Sensory input, surgical procedures, operative, 020901 industrial engineering & automation, Hardware and Architecture, Control and Systems Engineering, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Muscle activity, Muscle synergy, Neuroscience, Software

Abstract

Sit-to-stand motion is an important daily activity, and it is important to study the mechanism of the motion to improve the ability when it becomes weak. To study the mechanism, we hypothesized tha...

Published

2021

333. Synergistic Myoelectrical Activities of Forearm Muscles Improving Robust Recognition of Multi-Fingered Gestures

Author

Xiuying Luo, Xiaoying Wu, Lin Chen, Yun Zhao, Li Zhang, Guanglin Li, and Wensheng Hou

Subjects

gesture recognition, surface electromyography, sEMG decomposition, muscle synergy, Chemical technology, TP1-1185

Abstract

Currently, surface electromyography (sEMG) features of the forearm multi-tendon muscles are widely used in gesture recognition, however, there are few investigations on the inherent physiological mechanism of muscle synergies. We aimed to study whether the muscle synergies could be used for gesture recognition. Five healthy participants executed five gestures of daily life (pinch, fist, open hand, grip, and extension) and the sEMG activity was acquired from six forearm muscles. A non-negative matrix factorization (NMF) algorithm was employed to decompose the pre-treated six-channel sEMG data to obtain the muscle synergy matrixes, in which the weights of each muscle channel determined the feature set for hand gesture classification. The results showed that the synergistic features of forearm muscles could be successfully clustered in the feature space, which enabled hand gestures to be recognized with high efficiency. By augmenting the number of participants, the mean recognition rate remained at more than 96% and reflected high robustness. We showed that muscle synergies can be well applied to gesture recognition.

Published

2019

334. Governing Coordination. Why do Muscles Matter?

Author

Carson, Richard G., Kelso, J. A. Scott, editor, and Jirsa, Viktor K., editor

Published

2004

335. Anatomical Description and Its Limitations

Author

Knudson, Duane and Knudson, Duane

Published

2003

336. A novel physiologic marker of bulbar motor involvement in amyotrophic lateral sclerosis: Jaw muscle synergy

Author

Panying Rong and Omar Jawdat

Subjects

Adult, Male, Facial Muscles, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, stomatognathic system, Physiology (medical), Quantitative assessment, Humans, Speech, Medicine, 0501 psychology and cognitive sciences, Amyotrophic lateral sclerosis, Muscle synergy, Aged, Electromyography, business.industry, Amyotrophic Lateral Sclerosis, 05 social sciences, Antagonist, Jaw movement, Middle Aged, medicine.disease, Sensory Systems, Biomechanical Phenomena, Jaw muscle, Neurology, Female, Neurology (clinical), Speech deficits, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Objective To identify a novel physiologic marker of bulbar motor involvement in amyotrophic lateral sclerosis (ALS) based on jaw muscle synergies. Methods Muscle synergies were extracted from the surface electromyographic recordings of five jaw muscles during speech in 11 individuals at the prodromal or symptomatic stages of bulbar ALS and 10 neurologically-healthy controls, using non-negative matrix factorization. The disrupted muscle synergies in ALS were identified; their efficacy in differentiating individuals with ALS from healthy controls and relation to the previously-reported kinematic and functional speech deficits were determined. Results An antagonist synergy (i.e., masseter × digastric) was significantly disrupted in ALS, which differentiated individuals with ALS from healthy controls with 82% sensitivity and 90% specificity. Such a disruption occurred prodromally and was associated with slowed jaw movement and reduced speaking rate across the range of severity. Conclusions The disruption of jaw antagonist synergy in ALS likely reflects the impact of impaired neural drive on the coordinative functioning of bulbar muscles, which may be used to assess bulbar motor involvement. Significance Jaw antagonist synergy shows promise as a novel physiologic marker of bulbar motor involvement in ALS, which has the potential to serve as a quantitative measurement tool for bulbar assessment.

Published

2021

337. Design of an Isometric End-Point Force Control Task for Electromyography Normalization and Muscle Synergy Extraction From the Upper Limb Without Maximum Voluntary Contraction

Author

CHO, Woorim, Cho, Woorim, BARRADAS, PATINO, Barradas, Victor, SCHWEIGHOFER, NICOLAS, Schweighofer, Nicolas, and Koike, Yasuharu

Subjects

EMG Normalization, Behavioral Neuroscience, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, Neurology, maximal voluntary contraction, Muscle Synergy, Isometric force control, Electromyography-EMG, Biological Psychiatry

Abstract

Muscle synergy analysis via surface electromyography (EMG) is useful to study muscle coordination in motor learning, clinical diagnosis, and neurorehabilitation. However, current methods to extract muscle synergies in the upper limb suffer from two major issues. First, the necessary normalization of EMG signals is performed via maximum voluntary contraction (MVC), which requires maximal isometric force production in each muscle. However, some individuals with motor impairments have difficulties producing maximal effort in the MVC task. In addition, the MVC is known to be highly unreliable, with widely different forces produced in repeated measures. Second, synergy extraction in the upper limb is typically performed with a multidirection reaching task. However, some participants with motor impairments cannot perform this task because it requires precise motor control. In this study, we proposed a new isometric rotating task that does not require precise motor control or large forces. In this task, participants maintain a cursor controlled by the arm end-point force on a target that rotates at a constant angular velocity at a designated force level. To relax constraints on motor control precision, the target is widened and blurred. To obtain a reference EMG value for normalization without requiring maximal effort, we estimated a linear relationship between joint torques and muscle activations. We assessed the reliability of joint torque normalization and synergy extraction in the rotating task in young neurotypical individuals. Compared with normalization with MVC, joint torque normalization allowed reliable EMG normalization at low force levels. In addition, the extraction of synergies was as reliable and more stable than with the multidirection reaching task. The proposed rotating task can, therefore, be used in future motor learning, clinical diagnosis, and neurorehabilitation studies.

Published

2022

338. Muscle synergies underlying sit-to-stand tasks in elderly people and their relationship with kinetic characteristics.

Author

Hanawa, Hiroki, Kubota, Keisuke, Kokubun, Takanori, Marumo, Tatsuya, Hoshi, Fumihiko, Kobayashi, Akira, and Kanemura, Naohiko

Subjects

*NEUROPHYSIOLOGY, *HUMAN kinematics, *MUSCLE physiology, *TASK performance, *MUSCULOSKELETAL system, *HIERARCHICAL clustering (Cluster analysis), *SKELETAL muscle physiology, *AGING, *CLUSTER analysis (Statistics), *ELECTROMYOGRAPHY, *POSTURAL balance, *KINEMATICS, *POSTURE, *TORQUE, *PHYSIOLOGY

Abstract

Background: Physiological evidence suggests that the nervous system controls motion by using a low-dimensional synergy organization for muscle activation. Because the muscle activation produces joint torques, kinetic changes accompanying aging can be related to changes in muscle synergies.Objectives: We explored the effects of aging on muscle synergies underlying sit-to-stand tasks, and examined their relationships with kinetic characteristics.Methods: Four younger and three older adults performed the sit-to-stand task at two speeds. Subsequently, we extracted the muscle synergies used to perform these tasks. Hierarchical cluster analysis was used to classify these synergies. We also calculated kinetic variables to compare the groups.Results: Three independent muscle synergies generally appeared in each subject. The spatial structure of these synergies was similar across age groups. The change in motion speed affected only the temporal structure of these synergies. However, subject-specific muscle synergies and kinetic variables existed.Conclusions: Our results suggest common muscle synergies underlying the sit-to-stand task in both young and elderly adults. People may actively change only the temporal structure of each muscle synergy. The precise subject-specific structuring of each muscle synergy may incorporate knowledge of the musculoskeletal kinetics. [ABSTRACT FROM AUTHOR]

Published

2017

339. Direction Modulation of Muscle Synergies in a Hand-Reaching Task.

Author

Israely, Sharon, Leisman, Gerry, Machluf, Chay, Shnitzer, Tal, and Carmeli, Eli

Subjects

MOTOR ability, NEUROPLASTICITY

Abstract

Functional tasks of the upper extremity can be executed by a variety of muscular patterns, independent of the direction, speed and load of the task. This large number of degrees of freedom imposes a significant control burden on the CNS. Previous studies suggested that the human cortex synchronizes a discrete number of neural functional units within the brainstem and spinal cord, i.e. muscle synergies, by linearly combining them to execute a great repertoire of movements. Further exploring this control mechanism, we aim to study whether a single set of muscle synergies might be generalized to express movements in different directions. This was implemented by using a modified version of the non-negative matrix factorization algorithm on EMG data sets of the upper extremity of healthy people. Our twelve participants executed hand-reaching movements in multiple directions. Muscle synergies that were extracted from movements to the center of the reaching space could be generalized to synergies for other movement directions. This finding was also supported by the application of a weighted correlation matrix, the similarity index and the results of the K-means cluster analysis. This might reinforce the notion that the CNS flexibly combines a single set of small number of synergies in different amplitudes to modulate movement for different directions. [ABSTRACT FROM PUBLISHER]

Published

2017

340. Muscle synergies are similar when typically developing children walk on a treadmill at different speeds and slopes.

Author

Rozumalski, Adam, Steele, Katherine M., and Schwartz, Michael H.

Subjects

*ANALYTICAL mechanics, *GAIT disorders, *MOVEMENT disorders, *WALKING, *ELECTROMYOGRAPHY

Abstract

Background The aim of this study was to determine whether changes in synergies relate to changes in gait while walking on a treadmill at multiple speeds and slopes. The hypothesis was that significant changes in movement pattern would not be accompanied by significant changes in synergies, suggesting that synergies are not dependent on the mechanical constraints but are instead neurological in origin. Methods Sixteen typically developing children walked on a treadmill for nine combinations (stages) of different speeds and slopes while simultaneously collecting kinematics, kinetics, and surface electromyography (EMG) data. The kinematics for each stride were summarized using a modified version of the Gait Deviation Index that only includes the sagittal plane. The kinetics for each stride were summarized using a modified version of the Gait Deviation Index – Kinetic which includes sagittal plane moments and powers. Within each synergy group, the correlations of the synergies were calculated between the treadmill stages. Results While kinematics and kinetics were significantly altered at the highest slope compared to level ground when walking on a treadmill, synergies were similar across stages. Conclusions The high correlations between synergies across stages indicate that neuromuscular control strategies do not change as children walk at different speeds and slopes on a treadmill. However, the multiple significant differences in kinematics and kinetics between stages indicate real differences in movement pattern. This supports the theory that synergies are neurological in origin and not simply a response to the biomechanical task constraints. [ABSTRACT FROM AUTHOR]

Published

2017

341. Association between Slip Severity and Muscle Synergies of Slipping.

Author

Moein Nazifi, Mohammad, Beschorner, Kurt E., and Hur, Pilwon

Subjects

ACCIDENTAL falls, MUSCLE physiology, CENTRAL nervous system, MOTOR ability, T-test (Statistics)

Abstract

Falls impose significant negative impacts to the US population and economy. A significant number of falls may be prevented via appropriate slip-responses since a strong relation exists between slips and falls. More importantly, as severe slips are more prone to result in a fall, identifying severe slippers along with the responsible factors for their adverse motor control and severe slipping should be the highest priority in fall prevention process. Previous studies have suggested that muscle synergies may be building blocks of the central nervous system in controlling motor tasks. Muscle synergies observed during slipping ('post-slip-initiation synergies' or 'just briefly,' 'slipping muscle synergies'), may represent the fundamental blocks of the neural control during slipping. Hence, studying the differences in slipping muscle synergies of mild and severe slippers can potentially reveal the differences in their neural control and subsequently, indicate the responsible factors for the adverse post-slip response in severe slippers. Even though the slipping muscle synergies have been investigated before, it still remains unclear on how the slip severity is associated with the slipping muscle synergies. More importantly, muscle synergies can be interpreted not only as neural blocks but also as physical sub-tasks of the main motor task. Hence, studying the differences of slipping synergies of mild and severe slippers would reveal the discrepancies in sub-tasks of their post-slip response. These discrepancies help pinpoint the malfunctioning sub-function associated with inadequate motor response seen in severe slippers. Twenty healthy subjects were recruited and underwent an unexpected slip (to extract their slipping synergies). Subjects were classified into mild and severe slippers based on their Peak Heel Speed. An independent t-test revealed several significant inter-group differences for muscle synergies of mild and severe slippers indicating differences in their neural control of slipping. A forward dynamic simulation was utilized to reveal the functionality of each synergy. Decomposition of slipping into sub-tasks (synergies), and finding the malfunctioning sub-task in severe slippers is important as it results in a novel targeted motor-rehabilitation technique that only aims to re-establish the impaired sub-task responsible for the adverse motor-response in severe slippers. [ABSTRACT FROM AUTHOR]

Published

2017

342. Chronic pain alters spatiotemporal activation patterns of forearm muscle synergies during the development of grip force.

Author

Manickaraj, Nagarajan, Bisset, Leanne M., Devanaboyina, Venkata S. P. T., and Kavanagh, Justin J.

Abstract

It is largely unknown how the CNS regulates multiple muscle systems in the presence of pain. This study used muscle synergy analysis to investigate multiple forearm muscles in individuals with chronic elbow pain during the development of grip force. Eleven individuals with chronic elbow pain and 11 healthy age-matched control subjects developed grip force to 15% and 30% of maximum voluntary contraction (MVC). Surface electromyography was obtained from six forearm muscles during force development before nonnegative matrix factorization was performed. The relationship between muscle synergies and standard clinical tests of elbow pain were examined by linear regression. During grip force development to 15% MVC the pain group had a lower number of forearm muscle synergies, increased similarity in spatial activation patterns, increased cocontraction of forearm flexors, and a greater magnitude of muscle weightings across the forearm when performing the task. During the 30% MVC grip the numbers of muscle synergies were the same for both groups; however, the pain group had lower activation and reduced variability in the timing of peak activation. The timing of peak activation was delayed in the pain group regardless of the task, and performing the grip in different wrist postures did not affect muscle synergy characteristics in either group. Although localized pain causes direct dysfunction of an affected muscle, this study provides evidence that the timing and amplitude of agonist and antagonist muscle activity are also affected with chronic pain. NEW & NOTEWORTHY Muscle activation patterns of individuals with chronic elbow pain are simplified compared with healthy individuals. This is apparent as individuals with pain exhibit fewer forearm muscle synergies, and increased similarity of activation patterns between forearm muscles, when performing pain-free isometric gripping. As such, even during pain-free tasks it is possible to observe changes in motor control in people with chronic pain. [ABSTRACT FROM AUTHOR]

Published

2017

343. The use of intermuscular coherence analysis as a novel approach to detect age-related changes on postural muscle synergy.

Author

Degani, Adriana M., Leonard, Charles T., and Danna-dos-Santos, Alessander

Subjects

*POSTURAL muscles, *AGING, *SENSORIMOTOR cortex, *NEUROMUSCULAR system, *ELECTROMYOGRAPHY

Abstract

The overall goal of this study was to investigate potential adaptations brought about by the natural processes of aging on the coordination of postural muscles. Considering the progressive and non-homogeneous deterioration of sensorimotor and neuromuscular systems as the individual grows older, it was hypothesized that aging is associated with a reorganization of synergistic mechanisms controlling postural muscles. Therefore, the presence, distribution, and strength of correlated neural inputs to three posterior postural muscles were measured by intermuscular coherence estimations at a low frequency band (0–55 Hz). Nine healthy young adults and thirteen healthy older adults performed ten trials of a perturbed task: bipedal stance while holding a five kg load for fifteen seconds. Estimates of intermuscular coherence for each pair of electromyographic signals (soleus and biceps femoris, soleus and erector spinae, and biceps femoris and erector spinae) were computed. Results revealed significantly stronger levels of synchronization of posterior muscles within 0–10 Hz in seniors compared to young adults. In addition, seniors presented similar spectra of intermuscular coherence within 0–55 Hz for all three muscle pairs analyzed. These findings provide valuable information regarding compensatory mechanisms adopted by older adults to control balance. The age-related reorganization of neural drive controlling posterior postural muscles revealing a stronger synchronization within 0–10 Hz might be related to the faster body sway and muscle co-activation patterns usually observed in this population. Finally, this study supports the use of Intermuscular Coherence Analysis as a sensitive method to detect age-related changes in multi-muscle control. [ABSTRACT FROM AUTHOR]

Published

2017

344. A Longitudinal Electromyography Study of Complex Movements in Poststroke Therapy. 2: Changes in Coordinated Muscle Activation.

Author

Hesam-Shariati, Negin, Trinh, Terry, Thompson-Butel, Angelica G., Shiner, Christine T., and McNulty, Penelope A.

Subjects

FINE motor ability, MUSCLES, MOVEMENT therapy, STROKE patients, ELECTROMYOGRAPHY

Abstract

Fine motor control is achieved through the coordinated activation of groups of muscles, or "muscle synergies." Muscle synergies change after stroke as a consequence of the motor deficit. We investigated the pattern and longitudinal changes in upper limb muscle synergies during therapy in a largely unconstrained movement in patients with a broad spectrum of poststroke residual voluntary motor capacity. Electromyography (EMG) was recorded using wireless telemetry from 6 muscles acting on the more-affected upper body in 24 stroke patients at early and late therapy during formal Wii-based Movement Therapy (WMT) sessions, and in a subset of 13 patients at 6-month follow-up. Patients were classified with low, moderate, or high motor-function. The Wii-baseball swing was analyzed using a non-negative matrix factorization (NMF) algorithm to extract muscle synergies from EMG recordings based on the temporal activation of each synergy and the contribution of each muscle to a synergy. Motor-function was clinically assessed immediately pre- and post-therapy and at 6-month follow-up using the Wolf Motor Function Test, upper limb motor Fugl-Meyer Assessment, and Motor Activity Log Quality of Movement scale. Clinical assessments and game performance demonstrated improved motor-function for all patients at post-therapy (p < 0.01), and these improvements were sustained at 6-month follow-up (p > 0.05). NMF analysis revealed fewer muscle synergies (mean ± SE) for patients with low motor-function (3.38 ± 0.2) than those with high motor-function (4.00 ± 0.3) at early therapy (p = 0.036) with an association trend between the number of synergies and the level of motor-function. By late therapy, there was no significant change between groups, although there was a pattern of increase for those with low motor-function over time. The variability accounted for demonstrated differences with motor-function level (p < 0.05) but not time. Cluster analysis of the pooled synergies highlighted the therapy-induced change in muscle activation. Muscle synergies could be identified for all patients during therapy activities. These results show less complexity and more co-activation in the muscle activation for patients with low motor-function as a higher number of muscle synergies reflects greater movement complexity and task-related phasic muscle activation. The increased number of synergies and changes within synergies by late-therapy suggests improved motor control and movement quality with more distinct phases of movement. [ABSTRACT FROM AUTHOR]

Published

2017

345. Muscle recruitment and coordination with an ankle exoskeleton.

Author

Steele, Katherine M., Jackson, Rachel W., Shuman, Benjamin R., and Collins, Steven H.

Subjects

*MUSCLE recruitment, *ROBOTIC exoskeletons, *MUSCLE contraction, *ELECTROMYOGRAPHY, *NEUROMUSCULAR system

Abstract

Exoskeletons have the potential to assist and augment human performance. Understanding how users adapt their movement and neuromuscular control in response to external assistance is important to inform the design of these devices. The aim of this research was to evaluate changes in muscle recruitment and coordination for ten unimpaired individuals walking with an ankle exoskeleton. We evaluated changes in the activity of individual muscles, cocontraction levels, and synergistic patterns of muscle coordination with increasing exoskeleton work and torque. Participants were able to selectively reduce activity of the ankle plantarflexors with increasing exoskeleton assistance. Increasing exoskeleton net work resulted in greater reductions in muscle activity than increasing exoskeleton torque. Patterns of muscle coordination were not restricted or constrained to synergistic patterns observed during unassisted walking. While three synergies could describe nearly 95% of the variance in electromyography data during unassisted walking, these same synergies could describe only 85–90% of the variance in muscle activity while walking with the exoskeleton. Synergies calculated with the exoskeleton demonstrated greater changes in synergy weights with increasing exoskeleton work versus greater changes in synergy activations with increasing exoskeleton torque. These results support the theory that unimpaired individuals do not exclusively use central pattern generators or other low-level building blocks to coordinate muscle activity, especially when learning a new task or adapting to external assistance, and demonstrate the potential for using exoskeletons to modulate muscle recruitment and coordination patterns for rehabilitation or performance. [ABSTRACT FROM AUTHOR]

Published

2017

346. Increased neuromuscular consistency in gait and balance after partnered, dance-based rehabilitation in Parkinson's disease.

Author

Allen, Jessica L., Lucas McKay, J., Sawers, Andrew, Hackney, Madeleine E., and Ting, Lena H.

Abstract

Here we examined changes in muscle coordination associated with improved motor performance after partnered, dance-based rehabilitation in individuals with mild to moderate idiopathic Parkinson's disease. Using motor module (a.k.a. muscle synergy) analysis, we identified changes in the modular control of overground walking and standing reactive balance that accompanied clinically meaningful improvements in behavioral measures of balance, gait, and disease symptoms after 3 wk of daily Adapted Tango classes. In contrast to previous studies that revealed a positive association between motor module number and motor performance, none of the six participants in this pilot study increased motor module number despite improvements in behavioral measures of balance and gait performance. Instead, motor modules were more consistently recruited and distinctly organized immediately after rehabilitation, suggesting more reliable motor output. Furthermore, the pool of motor modules shared between walking and reactive balance increased after rehabilitation, suggesting greater generalizability of motor module function across tasks. Our work is the first to show that motor module distinctness, consistency, and generalizability are more sensitive to improvements in gait and balance function after short-term rehabilitation than motor module number. Moreover, as similar differences in motor module distinctness, consistency, and generalizability have been demonstrated previously in healthy young adults with and without long-term motor training, our work suggests commonalities in the structure of muscle coordination associated with differences in motor performance across the spectrum from motor impairment to expertise. NEW & NOTEWORTHY We demonstrate changes in neuromuscular control of gait and balance in individuals with Parkinson's disease after short-term, dance-based rehabilitation. Our work is the first to show that motor module distinctness, consistency, and generalizability across gait and balance are more sensitive than motor module number to improvements in motor performance following short-term rehabilitation. Our results indicate commonalities in muscle coordination improvements associated with motor skill reacquisition due to rehabilitation and motor skill acquisition in healthy individuals. [ABSTRACT FROM AUTHOR]

Published

2017

347. Can muscle coordination explain the advantage of using the standing position during intense cycling?

Author

Turpin, Nicolas A., Costes, Antony, Moretto, Pierre, and Watier, Bruno

Abstract

Objectives: When compared to seated, the standing position allows the production of higher power outputs during intense cycling. We hypothesized that muscle coordination could explain this advantage. To test this hypothesis, we assessed muscle activity over a wide range of power outputs for both seated and standing cycling positions.Design: Nine lower limb muscle activities from seventeen untrained volunteers were recorded during cycling sequences performed in the seated and the standing positions at power outputs ranging from ∼100 to 700W at 90±5 revolutions-per-minute (RPM).Methods: Integrated electromyography activity (iEMG), temporal patterns of the EMGs, and muscle synergies were analyzed.Results: Muscle activity was underlain by four muscle synergies in both positions. Muscle synergies were similar in the two positions (Pearson's r=0.929±0.125). The activation patterns of knee and ankle extensor muscles and their associated synergies had different timings in the two positions (differences of ∼2-10% of cycle). No major timing changes were observed with power output (<2% of cycle). Differences in iEMG between the two positions depended strongly on power output in all but the calf muscle (medial gastrocnemius).Conclusions: The number and structure of the muscle synergies play a minor role in the advantage of using the standing position when cycling at high power-outputs. However, the standing position is favorable in terms of iEMG at power outputs ≳500-600W due to position-dependent modulations of muscle activation levels. These data are important for understanding the determinants of the seat-stand transition in cycling. [ABSTRACT FROM AUTHOR]

Published

2017

348. Investigation of the Intra- and Inter-Limb Muscle Coordination of Hands-and-Knees Crawling in Human Adults by Means of Muscle Synergy Analysis.

Author

Xiang Chen, Xiaocong Niu, De Wu, Yi Yu, and Xu Zhang

Subjects

*MOTOR ability, *CRAWLING & creeping, *HUMAN locomotion, *HUMAN mechanics, *ELECTROMYOGRAPHY

Abstract

To investigate the intra- and inter-limb muscle coordination mechanism of human hands-and-knees crawling by means of muscle synergy analysis, surface electromyographic (sEMG) signals of 20 human adults were collected bilaterally from 32 limb related muscles during crawling with hands and knees at different speeds. The nonnegative matrix factorization (NMF) algorithm was exerted on each limb to extract muscle synergies. The results showed that intra-limb coordination was relatively stable during human hands-and-knees crawling. Two synergies, one relating to the stance phase and the other relating to the swing phase, could be extracted from each limb during a crawling cycle. Synergy structures during different speeds kept good consistency, but the recruitment levels, durations, and phases of muscle synergies were adjusted to adapt the change of crawling speed. Furthermore, the ipsilateral phase lag (IPL) value which was used to depict the inter-limb coordination changed with crawling speed for most subjects, and subjects using the no-limb-pairing mode at low speed tended to adopt the trot-like mode or pace-like mode at high speed. The research results could be well explained by the two-level central pattern generator (CPG) model consisting of a half-center rhythm generator (RG) and a pattern formation (PF) circuit. This study sheds light on the underlying control mechanism of human crawling. [ABSTRACT FROM AUTHOR]

Published

2017

349. Neural mechanisms of single corrective steps evoked in the standing rabbit.

Author

Hsu, L.-J., Zelenin, P.V., Lyalka, V.F., Vemula, M.G., Orlovsky, G.N., and Deliagina, T.G.

Subjects

*HINDLIMB abnormalities, *EXTREMITIES (Anatomy), *BACK muscles, *SPINAL cord, RABBIT diseases

Abstract

Single steps in different directions are often used for postural corrections. However, our knowledge about the neural mechanisms underlying their generation is scarce. This study was aimed to characterize the corrective steps generated in response to disturbances of the basic body configuration caused by forward, backward or outward displacement of the hindlimb, as well as to reveal location in the CNS of the corrective step generating mechanisms. Video recording of the motor response to translation of the supporting surface under the hindlimb along with contact forces and activity of back and limb muscles was performed in freely standing intact and in fixed postmammillary rabbits. In intact rabbits, displacement of the hindlimb in any direction caused a lateral trunk movement toward the contralateral hindlimb, and then a corrective step in the direction opposite to the initial displacement. The time difference between onsets of these two events varied considerably. The EMG pattern in the supporting hindlimb was similar for all directions of corrective steps. It caused the increase in the limb stiffness. EMG pattern in the stepping limb differed in steps with different directions. In postmammillary rabbits the corrective stepping movements, as well as EMG patterns in both stepping and standing hindlimbs were similar to those observed in intact rabbits. This study demonstrates that the corrective trunk and limb movements are generated by separate mechanisms activated by sensory signals from the deviated limb. The neuronal networks generating postural corrective steps reside in the brainstem, cerebellum, and spinal cord. [ABSTRACT FROM AUTHOR]

Published

2017

350. Speed dependency in α-motoneuron activity and locomotor modules in human locomotion: indirect evidence for phylogenetically conserved spinal circuits.

Author

Hikaru Yokoyama, Tetsuya Ogawa, Masahiro Shinya, Noritaka Kawashima, and Kimitaka Nakazawa

Subjects

*MOTOR neurons, *MUSCULOSKELETAL system, *PHYLOGENY, *MUSCLES, *ELECTROMYOGRAPHY

Abstract

Coordinated locomotor muscle activity is generated by the spinal central pattern generators (CPGs). Vertebrate studies have demonstrated the following two characteristics of the speed control mechanisms of the spinal CPGs: (i) rostral segment activation is indispensable for achieving high-speed locomotion; and (ii) specific combinations between spinal interneuronal modules and motoneuron (MN) pools are sequentially activated with increasing speed. Here, to investigate whether similar control mechanisms exist in humans, we examined spinal neural activity during varied-speed locomotion by mapping the distribution of MN activity in the spinal cord and extracting locomotor modules, which generate basic MN activation patterns. The MN activation patterns and the locomotor modules were analysed from multi-muscle electromyographic recordings. The reconstructed MN activity patterns were divided into the following three patterns depending on the speed of locomotion: slow walking, fast walking and running. During these three activation patterns, the proportion of the activity in rostral segments to that in caudal segments increased as locomotion speed increased. Additionally, the different MN activation patterns were generated by distinct combinations of locomotor modules. These results are consistent with the speed control mechanisms observed in vertebrates, suggesting phylogenetically conserved spinal mechanisms of neural control of locomotion. [ABSTRACT FROM AUTHOR]

Published

2017