Your search keyword '"muscle synergy"' showing total 158 results

1. Comparison of Lower-Limb Muscle Synergies Between Young and Old People During Cycling Based on Electromyography Sensors—A Preliminary Cross-Sectional Study.

Author

Kong, Li, Yang, Kun, Li, Haojie, Wu, Xie, and Zhang, Qiang

Subjects

*OLDER people, *MATRIX decomposition, *NONNEGATIVE matrices, *CYCLING, *MUSCLE aging

Abstract

The purpose of this study was to analyze the lower-limb muscle synergies of young and older adults during stationary cycling across various mechanical conditions to reveal adaptive strategies employed by the elderly to address various common pedaling tasks and function degradation. By comparing lower-limb muscle synergies during stationary cycling between young and old people, this study examined changes in muscle synergy patterns during exercise in older individuals. This is crucial for understanding neuromuscular degeneration and changes in movement patterns in older individuals. Sixteen young and sixteen older experienced cyclists were recruited to perform stationary cycling tasks at two levels of power (60 and 100 W) and three cadences (40, 60, and 90 rpm) in random order. The lower-limb muscle synergies and their inter- and intra-individual variability were analyzed. Three synergies were extracted in this study under all riding conditions in both groups while satisfying overall variance accounted for (VAF) > 85% and muscle VAF > 75%. The older adults exhibited lower variability in synergy vector two and a higher trend in the variability of activation coefficient three, as determined by calculating the variance ratio. Further analyses of muscle synergy structures revealed increased weighting in major contribution muscles, the forward-shifting peak activation in synergy one, and lower peak magnitude in synergy three among older adults. To produce the same cycling power and cadence as younger individuals, older adults make adaptive adjustments in muscle control—increased weighting in major contribution muscles, greater consistency in the use of primary force-producing synergies, and earlier peak activation of subsequent synergy. [ABSTRACT FROM AUTHOR]

Published

2024

2. Robust fatigue markers obtained from muscle synergy analysis.

Author

Zhang, Chen, Zhou, Zi-jian, Wang, Lu-yi, Ran, Ling-hua, Hu, Hui-min, Zhang, Xin, Xu, Hong-qi, and Shi, Ji-peng

Subjects

*HEART beat, *MUSCLE fatigue, *FATIGUE (Physiology), *LEG exercises, *NONNEGATIVE matrices

Abstract

This study aimed to utilize the nonnegative matrix factorization (NNMF) algorithm for muscle synergy analysis, extracting synergy structures and muscle weightings and mining biomarkers reflecting changes in muscle fatigue from these synergy structures. A leg press exercise to induce fatigue was performed by 11 participants. Surface electromyography (sEMG) data from seven muscles, electrocardiography (ECG) data, Borg CR-10 scale scores, and the z-axis acceleration of the weight block were simultaneously collected. Three indices were derived from the synergy structures: activation phase difference, coactivation area, and coactivation time. The indicators were further validated for single-leg landing. Differences in heart rate (HR) and heart rate variability (HRV) were observed across different fatigue levels, with varying degrees of disparity. The median frequency (MDF) exhibited a consistent decline in the primary working muscle groups. Significant differences were noted in activation phase difference, coactivation area, and coactivation time before and after fatigue onset. Moreover, a significant correlation was found between the activation phase difference and the coactivation area with fatigue intensity. The further application of single-leg landing demonstrated the effectiveness of the coactivation area. These indices can serve as biomarkers reflecting simultaneous alterations in the central nervous system and muscle activity post-exertion. [ABSTRACT FROM AUTHOR]

Published

2024

3. Neuromuscular Control Strategies in Basketball Shooting: Distance-Dependent Analysis of Muscle Synergies.

Author

Penglei Fan, Zhitao Yang, Ting Wang, Jiaying Li, Youngsuk Kim, and Sukwon Kim

Subjects

*SKELETAL muscle physiology, *BIOMECHANICS, *MOTOR ability, *LONG-distance running, *TASK performance, *NEUROPHYSIOLOGY, *NEUROMUSCULAR system, *PHYSICAL training & conditioning, *DESCRIPTIVE statistics, *ATHLETES, *ELECTROMYOGRAPHY, *ATHLETIC ability, *BASKETBALL, *COMPARATIVE studies

Abstract

Basketball victory relies on an athlete's skill to make precise shots at different distances. While extensive research has explored the kinematics and dynamics of different shooting distances, the specific neuromuscular control strategies involved remain elusive. This study aimed to compare the differences in muscle synergies during basketball shooting at different distances, offering insights into neuromuscular control strategies and guiding athletes' training. Ten skilled shooting right-handed male basketball players participated as subjects in this experiment. Electromyographic (EMG) data for full-phase shooting were acquired at short (3.2 m), middle (5.0 m), and long (6.8 m) distances. Non-negative matrix decomposition extracted muscle synergies (motor modules and motor primitives) during shooting. The results of this study show that all three distance shooting can be broken down into three synergies and that there were differences in the synergies between short and long distances, with differences in motor primitive 1 and motor primitive 2 at the phase of 45% - 59% (p < 0.001, t* = 4.418), and 78% - 88% (p < 0.01, t* = 4.579), respectively, and differences in the motor module 3 found in the differences in muscle weights for rectus femoris (RF) (p = 0.001, d = -2.094), and gastrocnemius lateral (GL) (p = 0.001, d = -2.083). Shooting distance doesn't affect the number of muscle synergies in basketball shooting but alters synergy patterns. During long distance shooting training, basketball players should place more emphasis on the timing and synergistic activation of upper and lower limbs, as well as core muscles. [ABSTRACT FROM AUTHOR]

Published

2024

4. Adaptive Adjustments in Lower Limb Muscle Coordination during Single-Leg Landing Tasks in Latin Dancers.

Author

Gao, Xiangli, Jie, Tianle, Xu, Datao, Gál, János, Fekete, Gusztáv, Liang, Minjun, and Gu, Yaodong

Subjects

*LEG muscles, *DANCERS, *VASTUS lateralis, *TIBIALIS anterior, *SKELETAL muscle, *PEARSON correlation (Statistics)

Abstract

Previous research has primarily focused on evaluating the activity of individual muscles in dancers, often neglecting their synergistic interactions. Investigating the differences in lower limb muscle synergy during landing between dancers and healthy controls will contribute to a comprehensive understanding of their neuromuscular control patterns. This study enrolled 22 Latin dancers and 22 healthy participants, who performed a task involving landing from a 30 cm high platform. The data were collected using Vicon systems, force plates, and electromyography (EMG). The processed EMG data were subjected to non-negative matrix factorization (NNMF) for decomposition, followed by classification using K-means clustering algorithm and Pearson correlation coefficients. Three synergies were extracted for both Latin dancers and healthy participants. Synergy 1 showed increased contributions from the tibialis anterior (p < 0.001) and medial gastrocnemius (p = 0.024) in Latin dancers compared to healthy participants. Synergy 3 highlighted significantly greater contributions from the vastus lateralis in healthy participants compared to Latin dancers (p = 0.039). This study demonstrates that Latin dancers exhibit muscle synergies similar to those observed in healthy controls, revealing specific adjustments in the tibialis anterior and medial gastrocnemius muscles among dancers. This research illustrates how dancers optimize control strategies during landing tasks, offering a novel perspective for comprehensively understanding dancers' neuromuscular control patterns. [ABSTRACT FROM AUTHOR]

Published

2024

5. Muscle synergy and kinematic synergy analyses during sit-to-stand motions in hallux valgus patients before and after treatment with Kinesio taping.

Author

Liu, Ruiping, Liu, Yanyan, Zhou, Lihua, Qian, Lei, Chen, Chunyan, Wan, Xinzhu, Wang, Yining, Yu, Wanqi, Liu, Gang, and Ouyang, Jun

Subjects

*TAPING & strapping, *HALLUX valgus, *ANKLE, *GROUND reaction forces (Biomechanics), *KNEE, *MATRIX decomposition, *MOTION capture (Human mechanics)

Abstract

Objectives: To explore the impact of hallux valgus (HV) on lower limb neuromuscular control strategies during the sit-to-stand (STS) movement, and to evaluate the effects of Kinesio taping (KT) intervention on these control strategies in HV patients. Methods: We included 14 young healthy controls (HY), 13 patients in the HV group (HV), and 11 patients in the HV group (HVI) who underwent a Kinesio taping (KT) intervention during sit-to-stand (STS) motions. We extracted muscle and kinematic synergies from EMG and motion capture data using non-negative matrix factorization (NNMF). In addition, we calculated the center of pressure (COP) and ground reaction forces (GRF) to assess balance performance. Results: There were no significant differences in the numbers of muscle and kinematic synergies between groups. In the HV group, knee flexors and ankle plantar flexors were abnormally activated, and muscle synergy D was differentiated. Muscle synergy D was not differentiated in the HVI group. Conclusion: Abnormal activation of knee flexors and plantar flexors led to the differentiation of module D in HV patients, which can be used as an indicator of the progress of HV rehabilitation. KT intervention improved motor control mechanisms in HV patients. [ABSTRACT FROM AUTHOR]

Published

2024

6. Muscle synergy-informed neuromusculoskeletal modelling to estimate knee contact forces in children with cerebral palsy.

Author

Rabbi, Mohammad Fazle, Davico, Giorgio, Lloyd, David G., Carty, Christopher P., Diamond, Laura E., and Pizzolato, Claudio

Subjects

*CHILDREN with cerebral palsy, *KNEE, *KNEE joint, *TORQUE, *CEREBRAL palsy, *HUMAN locomotion

Abstract

Cerebral palsy (CP) includes a group of neurological conditions caused by damage to the developing brain, resulting in maladaptive alterations of muscle coordination and movement. Estimates of joint moments and contact forces during locomotion are important to establish the trajectory of disease progression and plan appropriate surgical interventions in children with CP. Joint moments and contact forces can be estimated using electromyogram (EMG)-informed neuromusculoskeletal models, but a reduced number of EMG sensors would facilitate translation of these computational methods to clinics. This study developed and evaluated a muscle synergy-informed neuromusculoskeletal modelling approach using EMG recordings from three to four muscles to estimate joint moments and knee contact forces of children with CP and typically developing (TD) children during walking. Using only three to four experimental EMG sensors attached to a single leg and leveraging an EMG database of walking data of TD children, the synergy-informed approach estimated total knee contact forces comparable to those estimated by EMG-assisted approaches that used 13 EMG sensors (children with CP, n = 3, R2 = 0.95 ± 0.01, RMSE = 0.40 ± 0.14 BW; TD controls, n = 3, R2 = 0.93 ± 0.07, RMSE = 0.19 ± 0.05 BW). The proposed synergy-informed neuromusculoskeletal modelling approach could enable rapid evaluation of joint biomechanics in children with unimpaired and impaired motor control within a clinical environment. [ABSTRACT FROM AUTHOR]

Published

2024

7. Characterization of muscle synergy during sitting and standing in older adults with hallux valgus.

Author

LIU Yanyan, QIAN Lei, LIU Ruiping, OUYANG Jun, and LIU Gang

Subjects

*OLDER people, *HALLUX valgus, *KNEE joint, *GROUND reaction forces (Biomechanics), *MATRIX decomposition

Abstract

Objective To analyze changes in neuromuscular control during sit-to-stand (STS) in older adults with hallux valgus ( HV) through muscle synergy, and thus to explore the effect of falls in older adults with HV. Methods Four groups of subjects were included in this study, 13 young controls (YC); 12 young HV group ( HVY) ; 14 healthy elderly controls (EC ); and 15 elderly HV group ( HVE ). All subjects completed the STS maneuver in an armless chair, and EMG data were integrated using non-negative matrix factorization to compare muscle synergies in the YC, HVY, EC, and HVE groups; plantar pressures (COP), ground reaction forces (GRF), and fall scores (FES-I) were collected. Results Compared with YC group, HVY, EC, and HVE groups had lower relative activation amplitude of abductor hallucis and lateral gastrocnemius in STS preparation phase ; meanwhile, EC and HVE groups needed more muscle activation to maintain stability of trunk and foot-ankle joints in STS stabilization phase; and HVE group needed more co-contractions of thigh muscles to maintain stability of the knee joint. The COP, FES-I of HVE group was higher than that of the other groups (P < 0.05 ). Conclusion In STS, healthy older adults and older adults with HV required more muscle activation to maintain trunk and ankle stability ; older adults with HV required more co-contraction of the thigh muscles to maintain knee stability; in addition to this, older adults with HV were more prone to falls. [ABSTRACT FROM AUTHOR]

Published

2024

8. Muscle Synergy during Wrist Movements Based on Non-Negative Tucker Decomposition.

Author

Chen, Xiaoling, Feng, Yange, Chang, Qingya, Yu, Jinxu, Chen, Jie, and Xie, Ping

Subjects

*WRIST, *EFFERENT pathways, *EXTENSOR muscles, *FLEXOR muscles, *BICEPS brachii, *CENTRAL nervous system

Abstract

Modular control of the muscle, which is called muscle synergy, simplifies control of the movement by the central nervous system. The purpose of this study was to explore the synergy in both the frequency and movement domains based on the non-negative Tucker decomposition (NTD) method. Surface electromyography (sEMG) data of 8 upper limb muscles in 10 healthy subjects under wrist flexion (WF) and wrist extension (WE) were recorded. NTD was selected for exploring the multi-domain muscle synergy from the sEMG data. The results showed two synergistic flexor pairs, Palmaris longus–Flexor Digitorum Superficialis (PL-FDS) and Extensor Carpi Radialis–Flexor Carpi Radialis (ECR-FCR), in the WF stage. Their spectral components are mainly in the respective bands 0–20 Hz and 25–50 Hz. And the spectral components of two extensor pairs, Extensor Digitorum–Extensor Carpi Ulnar (ED-ECU) and Extensor Carpi Radialis–Brachioradialis (ECR-B), are mainly in the respective bands 0–20 Hz and 7–45 Hz in the WE stage. Additionally, further analysis showed that the Biceps Brachii (BB) muscle was a shared muscle synergy module of the WE and WF stage, while the flexor muscles FCR, PL and FDS were the specific synergy modules of the WF stage, and the extensor muscles ED, ECU, ECR and B were the specific synergy modules of the WE stage. This study showed that NTD is a meaningful method to explore the multi-domain synergistic characteristics of multi-channel sEMG signals. The results can help us to better understand the frequency features of muscle synergy and shared and specific synergies, and expand the study perspective related to motor control in the nervous system. [ABSTRACT FROM AUTHOR]

Published

2024

9. Rectified Latent Variable Model-Based EMG Factorization of Inhibitory Muscle Synergy Components Related to Aging, Expertise and Force–Tempo Variations.

Author

Huang, Subing, Guo, Xiaoyu, Xie, Jodie J., Lau, Kelvin Y. S., Liu, Richard, Mak, Arthur D. P., Cheung, Vincent C. K., and Chan, Rosa H. M.

Subjects

*LATENT variables, *EXPERTISE, *FACTORIZATION, *NERVOUS system, *PIANO playing, *MUSCLES, *HUMAN fingerprints

Abstract

Muscle synergy has been widely acknowledged as a possible strategy of neuromotor control, but current research has ignored the potential inhibitory components in muscle synergies. Our study aims to identify and characterize the inhibitory components within motor modules derived from electromyography (EMG), investigate the impact of aging and motor expertise on these components, and better understand the nervous system's adaptions to varying task demands. We utilized a rectified latent variable model (RLVM) to factorize motor modules with inhibitory components from EMG signals recorded from ten expert pianists when they played scales and pieces at different tempo–force combinations. We found that older participants showed a higher proportion of inhibitory components compared with the younger group. Senior experts had a higher proportion of inhibitory components on the left hand, and most inhibitory components became less negative with increased tempo or decreased force. Our results demonstrated that the inhibitory components in muscle synergies could be shaped by aging and expertise, and also took part in motor control for adapting to different conditions in complex tasks. [ABSTRACT FROM AUTHOR]

Published

2024

10. Structural and Organizational Strategies of Locomotor Modules during Landing in Patients with Chronic Ankle Instability.

Author

Jie, Tianle, Xu, Datao, Zhang, Zanni, Teo, Ee-Chon, Baker, Julien S., Zhou, Huiyu, and Gu, Yaodong

Subjects

*CHRONIC ankle instability, *ANKLE, *ORGANIZATIONAL aims & objectives, *VASTUS lateralis, *GLUTEAL muscles, *TIBIALIS anterior, *MATRIX decomposition

Abstract

Background: Human locomotion involves the coordinated activation of a finite set of modules, known as muscle synergy, which represent the motor control strategy of the central nervous system. However, most prior studies have focused on isolated muscle activation, overlooking the modular organization of motor behavior. Therefore, to enhance comprehension of muscle coordination dynamics during multi-joint movements in chronic ankle instability (CAI), exploring muscle synergies during landing in CAI patients is imperative. Methods: A total of 22 patients with unilateral CAI and 22 healthy participants were recruited for this research. We employed a recursive model for second-order differential equations to process electromyographic (EMG) data after filtering preprocessing, generating the muscle activation matrix, which was subsequently inputted into the non-negative matrix factorization model for extraction of the muscle synergy. Muscle synergies were classified utilizing the K-means clustering algorithm and Pearson correlation coefficients. Statistical parameter mapping (SPM) was employed for temporal modular parameter analyses. Results: Four muscle synergies were identified in both the CAI and healthy groups. In Synergy 1, only the gluteus maximus showed significantly higher relative weight in CAI compared to healthy controls (p = 0.0035). Synergy 2 showed significantly higher relative weights for the vastus lateralis in the healthy group compared to CAI (p = 0.018), while in Synergy 4, CAI demonstrated significantly higher relative weights of the vastus lateralis compared to healthy controls (p = 0.030). Furthermore, in Synergy 2, the CAI group exhibited higher weights of the tibialis anterior compared to the healthy group (p = 0.042). Conclusions: The study suggested that patients with CAI exhibit a comparable modular organizational framework to the healthy group. Investigation of amplitude adjustments within the synergy spatial module shed light on the adaptive strategies employed by the tibialis anterior and gluteus maximus muscles to optimize control strategies during landing in patients with CAI. Variances in the muscle-specific weights of the vastus lateralis across movement modules reveal novel biomechanical adaptations in CAI, offering valuable insights for refining rehabilitation protocols. [ABSTRACT FROM AUTHOR]

Published

2024

11. Selecting Pedal Load for Lower-Limb Rehabilitation Based on the Combination of Muscle Synergy and Fourier Series.

Author

Kuroda, Shigeki, She, Jinhua, Nakamuro, Sota, Wang, Rennong, Chugo, Daisuke, Ishiguro, Keio, Sakai, Hiromi, and Hashimoto, Hiroshi

Subjects

*FOURIER series, *MATRIX decomposition, *SINGULAR value decomposition, *COSINE function, *NONNEGATIVE matrices, *FITNESS walking, *REHABILITATION

Abstract

This paper introduces a new lower-limb rehabilitation machine that meets the rehabilitation needs of hemiplegic patients. First, a left–right independent rotary pedal mechanism was selected to facilitate rehabilitation and adapt to the user's physical condition. Then, a half model of the lower-limb rehabilitation machine is designed and manufactured with ergonomics in mind. As analytical tools, we combine non-negative matrix factorization and non-negative double singular value decomposition to calculate muscle synergy of the walking muscle surface electromyography (sEMG) signal, and use cosine similarity to evaluate the similarity between walking and pedaling activities. By comparing the results of the walking and pedaling experiments, the effectiveness of pedaling in gait rehabilitation is revealed. To further improve the similarity between walking and pedaling, double integration of the sEMG signal is introduced, and the relationship between load input and rotation angle is described for the first time using Fourier series. The results of the experiment confirmed that more than half of the 10 subjects performed pedaling exercises similar to walking using Fourier series loading compared to pedaling exercises with normal constant loading. This loading parameter may have the potential to improve rehabilitation efficiency for many subjects compared to the usual exercise. [ABSTRACT FROM AUTHOR]

Published

2024

12. Corticospinal excitability during motor preparation of upper extremity reaches reflects flexor muscle synergies: A novel principal component-based motor evoked potential analyses.

Author

Augenstein, Thomas E., Oh, Seonga, Norris, Trevor A., Mekler, Joshua, Sethi, Amit, and Krishnan, Chandramouli

Subjects

*TRANSCRANIAL magnetic stimulation, *EVOKED potentials (Electrophysiology), *BRAIN stimulation, *MOTOR cortex, *CENTRAL nervous system

Abstract

Background: Previous research has shown that noninvasive brain stimulation can be used to study how the central nervous system (CNS) prepares the execution of a motor task. However, these previous studies have been limited to a single muscle or single degree of freedom movements (e.g., wrist flexion). It is currently unclear if the findings of these studies generalize to multi-joint movements involving multiple muscles, which may be influenced by kinematic redundancy and muscle synergies. Objective: The objective of this study was to characterize corticospinal excitability during motor preparation in the cortex prior to functional upper extremity reaches. Methods: 20 participants without neurological impairments volunteered for this study. During the experiment, the participants reached for a cup in response to a visual "Go Cue". Prior to movement onset, we used transcranial magnetic stimulation (TMS) to stimulate the motor cortex and measured the changes in motor evoked potentials (MEPs) in several upper extremity muscles. We varied each participant's initial arm posture and used a novel synergy-based MEP analysis to examine the effect of muscle coordination on MEPs. Additionally, we varied the timing of the stimulation between the Go Cue and movement onset to examine the time course of motor preparation. Results: We found that synergies with strong proximal muscle (shoulder and elbow) components emerged as the stimulation was delivered closer to movement onset, regardless of arm posture, but MEPs in the distal (wrist and finger) muscles were not facilitated. We also found that synergies varied with arm posture in a manner that reflected the muscle coordination of the reach. Conclusions: We believe that these findings provide useful insight into the way the CNS plans motor skills. [ABSTRACT FROM AUTHOR]

Published

2024

13. The Impact of Different Self-Selected Walking Speeds on Muscle Synergies in Transfemoral Amputees during Transient-State Gait.

Author

Mehryar, Pouyan, Shourijeh, Mohammad, Rezaeian, Tahmineh, Khandan, Aminreza, Messenger, Neil, O'Connor, Rory, Farahmand, Farzam, and Dehghani-Sanij, Abbas

Subjects

*WALKING speed, *ELECTROMYOGRAPHY, *GAIT in humans, *AMPUTATION, *COEFFICIENTS (Statistics)

Abstract

Facing above-knee amputation poses a significant hurdle due to its profound impact on walking ability. To overcome this challenge, a complex adaptation strategy is necessary at the neuromuscular level to facilitate safe movement with a prosthesis. Prior research conducted on lower-limb amputees has shown a comparable amount of intricacy exhibited by the neurological system, regardless of the level of amputation and state of walking. This research investigated the differences in muscle synergies among individuals with unilateral transfemoral amputations during walking at three different speeds of transient-state gait. Surface electromyography was recorded from eleven male transfemoral amputees' intact limbs (TFA), and the concatenated non-negative matrix factorization technique was used to identify muscle synergy components, synergy vectors (S), and activation coefficient profiles (C). Results showed varying levels of correlation across paired-speed comparisons in TFA, categorized as poor (S1), moderate (S3 and S4), and strong (S2). Statistically significant differences were observed in all activation coefficients except C3, particularly during the stance phase. This study can assist therapists in understanding muscle coordination in TFA during unsteady gait, contributing to rehabilitation programs for balance and mobility improvement, and designing myoelectric prosthetic systems to enhance their responsiveness to trips or falls. [ABSTRACT FROM AUTHOR]

Published

2024

14. Motor patterns of patients with spinal muscular atrophy suggestive of sensory and corticospinal contributions to the development of locomotor muscle synergies.

Author

Cheung, Vincent C. K., Ha, Sophia C. W., Zhang-Lea, Janet H., Chan, Zoe Y. S., Yanling Teng, Geshi Yeung, Lingqian Wu, Desheng Liang, and Cheung, Roy T. H.

Subjects

*SPINAL muscular atrophy, *MUSCLE growth, *SENSORIMOTOR cortex, *PYRAMIDAL tract, *GENE expression, *AGE of onset

Abstract

Complex locomotor patterns are generated by combination of muscle synergies. How genetic processes, early sensorimotor experiences, and the developmental dynamics of neuronal circuits contribute to the expression of muscle synergies remains elusive. We shed light on the factors that influence development of muscle synergies by studying subjects with spinal muscular atrophy (SMA, types II/IIIa), a disorder associated with degeneration and deafferentation of motoneurons and possibly motor cortical and cerebellar abnormalities, from which the afflicted would have atypical sensorimotor histories around typical walking onset. Muscle synergies of children with SMA were identified from electromyographic signals recorded during active-assisted leg motions or walking, and compared with those of age-matched controls. We found that the earlier the SMA onset age, the more different the SMA synergies were from the normative. These alterations could not just be explained by the different degrees of uneven motoneuronal losses across muscles. The SMA-specific synergies had activations in muscles from multiple limb compartments, a finding reminiscent of the neonatal synergies of typically developing infants. Overall, while the synergies shared between SMA and control subjects may reflect components of a core modular infrastructure determined early in life, the SMA-specific synergies may be developmentally immature synergies that arise from inadequate activity-dependent interneuronal sculpting due to abnormal sensorimotor experience and other factors. Other mechanisms including SMA-induced intraspinal changes and altered cortical-spinal interactions may also contribute to synergy changes. Our interpretation highlights the roles of the sensory and descending systems to the typical and abnormal development of locomotor modules. [ABSTRACT FROM AUTHOR]

Published

2024

15. Age‐related differences in the capacity and neuromuscular control of the foot core system during quiet standing.

Author

Lai, Jiaqi, Ye, Yinyan, Huang, Dongfeng, and Zhang, Xianyi

Subjects

*FOOT anatomy, *NEUROPHYSIOLOGY, *RANGE of motion of joints, *SKELETAL muscle, *MUSCLE contraction, *POSTURAL balance, *AGE distribution, *TOES, *NEUROMUSCULAR system, *ANKLE, *LEG, *COMPARATIVE studies, *MUSCLE strength, *POSTURE, *FLEXOR hallucis longus, *RESEARCH funding, *BIOMECHANICS

Abstract

The foot core system is essential for upright stability. However, aging‐induced changes in the foot core function remain poorly understood. The present study aimed to examine age‐related differences in postural stability from the perspective of foot core capacity and neuromuscular control during quiet standing. Thirty‐six older and 25 young adults completed foot core capacity tests including toe flexion strength, muscle ultrasonography, and plantar cutaneous sensitivity. The center of pressure (COP) and electromyography (EMG) of abductor hallucis (ABH), peroneus longus (PL), tibialis anterior (TA) and medial gastrocnemius (GM) were simultaneously recorded during double‐leg and single‐leg standing (SLS). EMG data were used to calculate muscle synergy and intermuscular coherence across three frequency bands. Compared to young adults, older adults exhibited thinner hallucis flexors, weaker toe strength, and lower plantar cutaneous sensitivity. The ABH thickness and plantar cutaneous sensitivity were negatively associated with the COP mean peak velocity in older adults, but not in young adults. Besides, older adults had higher cocontraction of muscles spanning the arch (ABH‐PL) and ankle (TA‐GM), and had lower beta‐ and gamma‐band coherence of the ABH‐PL and TA‐PL during SLS. Foot core capacities became compromised with advancing age, and the balance control of older adults was susceptible to foot core than young adults in balance tasks. To compensate for the weakened foot core, older adults may adopt arch and ankle stiffening strategies via increasing muscle cocontraction. Furthermore, coherence analysis indicated that aging may increase the demand for cortical brain resources during SLS. [ABSTRACT FROM AUTHOR]

Published

2024

16. Characteristics of muscle synergy extracted using an autoencoder in patients with stroke during the curved walking in comparison with healthy controls.

Author

Lee, JaeHyuk

Subjects

*MUSCLES, *STROKE patients, *CONTROL groups, *MOTOR ability, *WALKING

Abstract

This study investigated the spatial and temporal features of muscle synergy during two types of curved walking (CW), according to whether the analyzed legs were located on the outside (OCW) or inside (ICW) on the basis of the curve direction during CW, in patients with stroke. Thirteen patients with stroke and seven age-matched healthy controls participated in this study. Using the autoencoder technique, four muscle synergies were extracted from eight muscles of the paretic legs in patients with stroke and the dominant legs in healthy controls. Walking speed, variance accounted for (VAF) of the four synergies, and each synergy with the same number were compared. Pearson's correlation and activation peak timing calculation were used to identify spatial and temporal features, respectively. Regarding walking speed in patients with stroke, ICW was significantly faster than OCW (P = 0.027). Regarding spatial features, muscle weighting values of patients with stroke in synergy 3 that were mainly involved in the early swing phase had the lowest similarity [r = 0.30] during OCW, and synergy 4 that was mainly involved in the late swing phase had the lowest similarity [r = 0.39] during ICW compared to the healthy group. Meanwhile, in terms of temporal features, activation peak timings of patients with stroke in synergy 1, which was mainly involved in the early stance phase, and synergy 2, which was mainly involved in the mid-late stance phase, were significantly delayed during OCW (P <.001, P = 0.003), while peak timings of synergy 1 and synergy 3 were delayed during ICW (P =.004, P =.002). Based on distinctive features of spatial synergy during the swing phase of CW and temporal synergy during the swing-stance transition phase of CW in patients with stroke in gait rehabilitation, specific approaches need to be considered depending on the curve direction and each gait phase. • Curved walking requires high levels of motor control ability. • Pathological changes in muscle synergy were found in stroke patients during walking. • Changes in muscle synergy were also diverse according to the walking direction. • Future gait rehabilitation should consider patients' individual walking conditions. [ABSTRACT FROM AUTHOR]

Published

2024

17. Characteristics of muscle synergy and anticipatory synergy adjustments strategy when cutting in different angles.

Author

Pan, Zhengye, Liu, Lushuai, Li, Xingman, and Ma, Yunchao

Subjects

*MUSCLE strength, *NEUROMUSCULAR diseases, *ATHLETES, *LEG, *MACHINE learning

Abstract

Cutting is a quick change of direction that challenges body balance and stability. As the cut-angle increases, the elite athlete can achieve higher performance by pre-adjusting the posture of the lower limb joints. However, it is unclear how the cut-angle affects the neuromuscular control of cutting and the step before cutting, which is essential for daily training and preventing injury in large-angle cutting. The purpose of this study was to determine how neuromuscular control strategies change under different angles for cutting and the step before cutting Non-negative matrix factorisation and K-means clustering were used to extract muscle synergy in the trunk and lower limbs of 12 athletes when cutting at different angles. Uncontrolled manifold analysis was used to clarify whether the muscle synergy fluctuations in the step before cutting were beneficial in stabilising the COP during the cutting. This study found that the angle did not affect the number of muscle synergies either in the cutting or the step before the cutting. As the angle increases, the activation timing of synergy module 2 during cutting moves forward and is tightly integrated with module 1. The combined synergy at 90° accounted for the largest proportion of either cutting or the step before cutting and had a lower synergy index. Muscle synergy can respond to large-angle cutting through flexible combinations. The muscle synergy for 90° cutting is less regular and has a lower degree of anticipatory synergy adjustments, which may result in poorer postural stability and an increased risk of lower limb joint injury during cutting. • The cut-angle does not affect the number of synergy modules during cutting. • Different degrees of anticipatory synergy adjustments with different cut-angles. • The weakest degree of muscle synergy and its anticipatory adjustments occurs in 90°. [ABSTRACT FROM AUTHOR]

Published

2024

18. Influence of Anodal tDCS on the Brain.

Author

Sijia Chen, Zhizeng Luo, and Jianjun Lai

Subjects

*FOREARM, *TRANSCRANIAL direct current stimulation, *CEREBRAL cortex, *MOTOR cortex

Abstract

Background: Transcranial direct current stimulation (tDCS) is a non-invasive technique that has demonstrated potential in modulating cortical neuron excitability. The objective of this paper is to investigate the effects of tDCS on characteristic parameters of brain functional networks and muscle synergy, as well as to explore its potential for enhancing motor performance. Methods: By applying different durations of tDCS on the motor cortex of the brain, the 32-lead electroencephalogram (EEG) of the cerebral cortex and 4-lead electromyography (EMG) signals of the right forearm were collected for 4 typical hand movements which are commonly used in rehabilitation training, including right-hand finger flexion, finger extension, wrist flexion, and wrist extension. Results: The study showed that tDCS can enhance the brain’s electrical activity in the beta band of the C3 node of the cerebral cortex during hand movements. Furthermore, the structure of muscle synergy remains unaltered; however, the associated muscle activity is amplified (p < 0.05). Conclusions: Based on the study results, it can be inferred that tDCS enhances the control strength between the motor area of the cerebral cortex and the muscles during hand movements. [ABSTRACT FROM AUTHOR]

Published

2024

19. 肌电控制虚拟现实游戏的腕部训练系统研究.

Author

段银鑫, 曾洪, and 宋爱国

Abstract

Aiming at the problems of boring contents of traditional wrist rehabilitation training methods and low training efficiency due to users' lack of motivation to participate, a wrist training system of myoelectric control virtual reality game was designed. The surface electromyography (SEMG) signals of wrist movement were collected and the wrist joint movement intention was decoded through the principle of muscle synergy for the control of the virtual re- ality game; random disturbance force was introduced into the virtual reality game, and the interaction with the virtual reality environment was realized through the way of impedance control, which enabled users to explore different movement control methods. The feasibility of the system was verified through model calibration experiments, and training experiments were conducted to assess the training effect by evaluating the task completion time as well as the path efficiency. The experimental results show that introducing random interference force reduces the task com- pletion time by 24% and improves the path efficiency by 26%, and the designed training system enables users to perform motion control in a more efficient way and improves the training efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

20. 单侧膝关节屈曲受限下肢肌肉的协同特征.

Author

安义帅, 张峻霞, 李 慧, 张雨虓, 徐国良, 高 昆, 于淑晗, and 刘泽龙

Subjects

*KNEE, *NONNEGATIVE matrices, *RECTUS femoris muscles, *SKELETAL muscle, *VASTUS medialis, *VASTUS lateralis

Abstract

BACKGROUND: Limitation of knee motion is a relatively common post-injury feature, but it remains to be understood how muscle synergy under knee motion limitation is affected. OBJECTIVE: To study the similarities and differences between unilateral knee flexion limitation and normal exercise lower extremity muscle synergy. METHODS: Twenty healthy adults (12 males and 8 females) were recruited as subjects, and the surface electromyogram signals of the lower limbs in natural walking with or without flexion limitation were collected. Muscle synergy was extracted from the surface electromyogram signals of 10 muscles on the restricted side (right leg) by a non-negative matrix factorization algorithm, and one-way analysis of variance was used to study the significant differences in gait parameters of walking in different conditions. RESULTS AND CONCLUSION: (1) Under flexion limitation, the number of muscle synergies decreased during the walking task after restraint, showing different muscle coordination mode control and recruiting new muscle synergy units. With the decrease of the synergistic module, the activation time of the medial gastrocnemius, lateral gastrocnemius and soleus muscle shifted more obviously from the support phase to the swing phase. After the restriction, it mainly relied on the rectus femoris, vastus medialis, vastus lateralis and tensor fascia lata for compensation, making it abnormally active at the activation level, and at the same time, the restricted side showed movements such as circles and crotches, so after the restriction, the hip joint on the restricted side was mainly used as compensation. (2) Under flexion limitation, there were significant differences in gait parameters (frequency, pace, gait cycle, and support ratio) between the restricted side and the non-restricted side compared with those before restriction (P < 0.05). The single-leg support time was significantly increased (P < 0.01) compared to before the restriction. The proportion of support and the time of single-leg support on the restricted side were significantly smaller than those on the non-restricted side (P < 0.01). (3) Therefore, the weakening of knee flexion movement can be considered as a key factor leading to the impaired coordination of lower extremities. The results of the study have implications for the quantitative analysis of motor function and the guidance of human lower extremity rehabilitation, and provide important insights for understanding the neuromuscular control behind motor function impairment mechanism. [ABSTRACT FROM AUTHOR]

Published

2023

21. Restoring natural upper limb movement through a wrist prosthetic module for partial hand amputees.

Author

Choi, Seoyoung, Cho, Wonwoo, and Kim, Keehoon

Subjects

*WRIST, *ARTIFICIAL hands, *MOTION analysis, *AMPUTEES, *MUSCULOSKELETAL system, *USER-centered system design

Abstract

Background: Most partial hand amputees experience limited wrist movement. The limited rotational wrist movement deteriorates natural upper limb system related to hand use and the usability of the prosthetic hand, which may cause secondary damage to the musculoskeletal system due to overuse of the upper limb affected by repetitive compensatory movement patterns. Nevertheless, partial hand prosthetics, in common, have only been proposed without rotational wrist movement because patients have various hand shapes, and a prosthetic hand should be attached to a narrow space. Methods: We hypothesized that partial hand amputees, when using a prosthetic hand with a wrist rotation module, would achieve natural upper limb movement muscle synergy and motion analysis comparable to a control group. To validate the proposed prototype design with the wrist rotation module and verify our hypothesis, we compared a control group with partial hand amputees wearing hand prostheses, both with and without the wrist rotation module prototype. The study contained muscle synergy analysis through non-negative matrix factorization (NMF) using surface electromyography (sEMG) and motion analyses employing a motion capture system during the reach-to-grasp task. Additionally, we assessed the usability of the prototype design for partial hand amputees using the Jebsen-Taylor hand function test (JHFT). Results: The results showed that the number of muscle synergies identified through NMF remained consistent at 3 for both the control group and amputees using a hand prosthesis with a wrist rotation module. In the motion analysis, a statistically significant difference was observed between the control group and the prosthetic hand without the wrist rotation module, indicating the presence of compensatory movements when utilizing a prosthetic hand lacking this module. Furthermore, among the amputees, the JHFT demonstrated a greater improvement in total score when using the prosthetic hand equipped with a wrist rotation module compared to the prosthetic hand without this module. Conclusion: In conclusion, integrating a wrist rotation module in prosthetic hand designs for partial hand amputees restores natural upper limb movement patterns, reduces compensatory movements, and prevent the secondary musculoskeletal. This highlights the importance of this module in enhancing overall functionality and quality of life. [ABSTRACT FROM AUTHOR]

Published

2023

22. Does Spasticity Correlate With Motor Impairment in the Upper and Lower Limbs in Ambulatory Chronic Stroke Survivors?

Author

Sheng Li, Ghuman, Jaskiran, Gonzalez-Buonomo, Javier, Xinran Huang, Malik, Aila, Yozbatiran, Nuray, Francisco, Gerard E., Hulin Wu, and Frontera, Walter R.

Subjects

*GRIP strength, *RESEARCH, *WALKING speed, *STATISTICS, *STROKE, *CHRONIC diseases, *GAIT in humans, *MULTIPLE regression analysis, *MOVEMENT disorders, *SPASTICITY, *LEG, *COMPARATIVE studies, *STROKE patients, *DIAGNOSIS, *DESCRIPTIVE statistics, *STATISTICAL correlation, *DATA analysis software, *DATA analysis

Abstract

Objective: This study aimed to explore correlations between spasticity and motor impairments in the upper and lower limbs in ambulatory chronic stroke survivors. Design: We performed clinical assessments in 28 ambulatory chronic stroke survivors with spastic hemiplegia (female: 12; male: 16; mean ages = 57.8 ±11.8 yrs; 76 ± 45 mos after stroke). Results: In the upper limb, spasticity index and Fugl-Meyer Motor Assessment showed a significant correlation. spasticity index for the upper limb showed a significant negative correlation with handgrip strength of the affected side (r = -0.4, P = 0.035) while Fugl-Meyer Motor Assessment for the upper limb had a significant positive correlation (r = 0.77, P < 0.001). In the LL, no correlation was found between SI&lowbar;LL and FMA&lowbar;LL. There was a significant and high correlation between timed up and go test and gait speed (r = 0.93, P < 0.001). Gait speed was positively correlated with Spasticity index for the lower limb (r = 0.48, P = 0.01), and negatively correlated with Fugl-Meyer Motor Assessment for the lower limb (r = -0.57, P = 0.002). Age and time since stroke showed no association in analyses for both upper limb and lower limb. Conclusions: Spasticity has a negative correlation on motor impairment in the upper limb but not in the lower limb. Motor impairment was significantly correlated with grip strength in the upper limb and gait performance in the lower limb of ambulatory stroke survivors. [ABSTRACT FROM AUTHOR]

Published

2023

23. Synchronous Muscle Synergy Evaluation of Jaw Muscle Activities during Chewing at Different Speeds, a Preliminary Study.

Author

Allami Sanjani, Marzieh, Tahami, Ehsan, and Veisi, Gelareh

Subjects

*MASTICATORY muscles, *TEMPORALIS muscle, *MASSETER muscle, *MASTICATION, *HUMAN mechanics, *BIOFEEDBACK training

Abstract

Human mastication is a complex and rhythmic biomechanical process regulated by the central nervous system (CNS). Muscle synergies are a group of motor primitives that the CNS may combine to simplify motor control in human movement. This study aimed to apply the non-negative matrix factorization approach to examine the coordination of the masticatory muscles on both sides during chewing. Ten healthy individuals were asked to chew gum at different speeds while their muscle activity was measured using surface electromyography of the right and left masseter and temporalis muscles. Regardless of the chewing speed, two main muscle synergies explained most of the muscle activity variation, accounting for over 98% of the changes in muscle patterns (variance accounted for >98%). The first synergy contained the chewing side masseter muscle information, and the second synergy provided information on bilateral temporalis muscles during the jaw closing. Furthermore, there was robust consistency and high degrees of similarity among the sets of muscle synergy information across different rate conditions and participants. These novel findings in healthy participants supported the hypothesis that all participants in various chewing speed conditions apply the same motor control strategies for chewing. Furthermore, these outcomes can be utilized to design rehabilitation approaches such as biofeedback therapy for mastication disorders. [ABSTRACT FROM AUTHOR]

Published

2023

24. Developing new intermuscular coordination patterns through an electromyographic signal-guided training in the upper extremity.

Author

Seo, Gang, Park, Jeong-Ho, Park, Hyung-Soon, and Roh, Jinsook

Subjects

*FORELIMB, *FLEXOR muscles, *MATRIX decomposition, *TASK performance, *NONNEGATIVE matrices, *LEARNING

Abstract

Background: Muscle synergies, computationally identified intermuscular coordination patterns, have been utilized to characterize neuromuscular control and learning in humans. However, it is unclear whether it is possible to alter the existing muscle synergies or develop new ones in an intended way through a relatively short-term motor exercise in adulthood. This study aimed to test the feasibility of expanding the repertoire of intermuscular coordination patterns through an isometric, electromyographic (EMG) signal-guided exercise in the upper extremity (UE) of neurologically intact individuals. Methods: 10 participants were trained for six weeks to induce independent control of activating a pair of elbow flexor muscles that tended to be naturally co-activated in force generation. An untrained isometric force generation task was performed to assess the effect of the training on the intermuscular coordination of the trained UE. We applied a non-negative matrix factorization on the EMG signals recorded from 12 major UE muscles during the assessment to identify the muscle synergies. In addition, the performance of training tasks and the characteristics of individual muscles' activity in both time and frequency domains were quantified as the training outcomes. Results: Typically, in two weeks of the training, participants could use newly developed muscle synergies when requested to perform new, untrained motor tasks by activating their UE muscles in the trained way. Meanwhile, their habitually expressed muscle synergies, the synergistic muscle activation groups that were used before the training, were conserved throughout the entire training period. The number of muscle synergies activated for the task performance remained the same. As the new muscle synergies were developed, the neuromotor control of the trained muscles reflected in the metrics, such as the ratio between the targeted muscles, number of matched targets, and task completion time, was improved. Conclusion: These findings suggest that our protocol can increase the repertoire of readily available muscle synergies and improve motor control by developing the activation of new muscle coordination patterns in healthy adults within a relatively short period. Furthermore, the study shows the potential of the isometric EMG-guided protocol as a neurorehabilitation tool for aiming motor deficits induced by abnormal intermuscular coordination after neurological disorders. Trial registration: This study was registered at the Clinical Research Information Service (CRiS) of the Korea National Institute of Health (KCT0005803) on 1/22/2021. [ABSTRACT FROM AUTHOR]

Published

2023

25. Survey of the Stability of Uniqueness of Muscle Synergy Patterns in Handwritten Signature over Time.

Author

Asemi, Arsalan, Maghooli, Keivan, Rahatabad, Fereidoun Nowshiravan, and Azadeh, Hamid

Subjects

*MATRIX decomposition, *NONNEGATIVE matrices, *HAND signals, *HUMAN fingerprints, *HUMAN body, *FORGERY

Abstract

Biometric characteristics of the human body can play a decisive role in the accuracy of automatic signature verification systems due to their stability over time and resistance to variability in different conditions. In this study, the accuracy of an automatic handwritten signature verification system is checked for nine months. In this system, the electromyography (EMG) signals from the hand muscles of people during signing are recorded at different times up to nine months, and after the pre-processing of the signals, muscle synergy patterns are extracted by the non-negative matrix factorization (NMF) method. Finally, the patterns extracted by the SVM classifier are classified into two classes: genuine and forgery signatures. [ABSTRACT FROM AUTHOR]

Published

2023

26. The effects of facioscapulohumeral dystrophy and dynamic arm support on upper extremity muscle coordination in functional tasks.

Author

Essers, J.M.N., Meijer, K., Peters, A.A., and Murgia, A.

Subjects

*DYSTROPHY, *FORELIMB, *ARM muscles, *MUSCLE weakness, *ASSISTIVE technology, *ACTIVITIES of daily living

Abstract

• First study on muscle coordination in people with FSHD during ADL arm tasks. • People with FSHD have very diverse muscle coordination patterns compared to controls. • Assistive device does not reduce muscle coordination diversity in people with FSHD. This study's objective is to understand the effect of muscular weakness in persons with facioscapulohumeral dystrophy as well as the effect of a dynamic arm support on muscle coordination and activity performance, during activities of daily living. People with facioscapulohumeral dystrophy (n=12, 56.0±14.5 years) and healthy controls (n=12, 55.5±13.4 years) performed five simulated daily activity tasks, while unsupported and supported by the Gowing dynamic arm support. Surface electromyography, kinematics, and maximum force output were recorded. Outcomes were calculated for muscle coordination (muscle synergies), maximum muscle activity, movement performance indicators, and upper limb muscular weakness (maximum force output). Muscle coordination was altered and less consistent in persons with facioscapulohumeral dystrophy compared with healthy controls. The dynamic arm support alleviated muscle efforts and affected muscle coordination in both populations. While populations became more similar, the internal consistency of persons with facioscapulohumeral dystrophy remained unaffected and lower than that of healthy controls. Furthermore, the support affected movements' performance in both groups. The maximum force outputs were lower in persons with facioscapulohumeral dystrophy than controls. Muscle coordination differences were presumably the result of individual-specific in muscle weakness and compensatory strategies for dealing with gravity compensation and movement constraints. [ABSTRACT FROM AUTHOR]

Published

2023

27. Continuous estimation of multi-DOF movement from sEMG based on non-negative matrix factorization and L2 regulation.

Author

Meng, Ming, Zhou, Guangqian, Ma, Yuliang, and Xi, Xugang

Subjects

*MATRIX decomposition, *NONNEGATIVE matrices, *MULTI-degree of freedom, *WRIST

Abstract

Accurate continuous estimation of multi-DOF movement is crucial for simultaneous control of advanced myoelectric prosthetic. The decoupling of multi-DOF is a challenge for continuous estimation. In this paper, we propose a model combined non-negative matrix factorization (NMF) with Hadamard product and L2 regulation to suppress the non-active DOF and achieve the multi-DOF movement continuous estimation. The L2 regulation of non-active DOF activation coefficient was added to the object function of NMF with the benefit of Hadamard product. The angles were estimated by a linear combination of the activation coefficients. We performed a set of continuous estimation experiments for single-DOF and multi-DOF movements of wrist flexion/extend and hand open/close. The results illustrated that the novel model could suppress non-active DOF in single-DOF movement better than other methods based on muscle synergy theory. Moreover, we investigated the robustness of suppression effect and the similarity of synergy matrices at different speeds for NMF-based methods, and the results showed that the proposed method had a superior performance. [ABSTRACT FROM AUTHOR]

Published

2023

28. The Influence of Experience on Neuromuscular Control of the Body When Cutting at Different Angles.

Author

Pan, Zhengye, Liu, Lushuai, Li, Xingman, and Ma, Yunchao

Subjects

*POSTURAL muscles, *NONNEGATIVE matrices, *ANGLES, *FACTORIZATION

Abstract

Cutting is an offensive technique commonly used in football and basketball to pass the opponent's defence by changing direction quickly in running. This paper aims to investigate the effect of experience and angle on the neuromuscular control strategies of the trunk and lower limbs during cutting. Non-negative matrix factorisation and K-means were used to extract muscle synergies (muscles that are activated in parallel) of 12 subjects with cut experience and 9 subjects without experience based on the sEMG signal collected from cutting at three cut angles (45°, 90°, and 135°), which was also mapped into the spinal motor output. Uncontrolled manifold analysis was used to establish the relationship between muscle synergies and COP. This study found that experienced subjects tended to use the lower limb muscles rather than the postural muscles as stabiliser muscles compared to novices. Experienced subjects can recruit an additional set of muscle synergy to cope with large-angle cuts. In addition, experienced subjects can activate the second muscle synergy, involving the hip and ankle stabilisation muscles, in advance to improve postural stability when cutting in large-angle. Synergy index of experienced subjects dropped rapidly before the quick stop and was relatively high during the change of direction. These results suggest that experience can modify the postural stabilisation mechanisms during cutting, and prompt the lower limb muscle synergy to produce anticipatory adjustment to improve postural stability in the anterior-posterior and internal-external directions. [ABSTRACT FROM AUTHOR]

Published

2023

29. Differences in muscle synergies between skilled and unskilled athletes in power clean exercise at various loads.

Author

Hakariya, Nadaka, Kibushi, Benio, and Okada, Junichi

Subjects

*EXERCISE physiology, *EXERCISE, *ATHLETES, *RESISTANCE training, *CONFIDENCE intervals, *WEIGHT lifting, *BODY movement

Abstract

The purpose of this study was to determine the differences in muscle synergy between skilled and unskilled participants using various loading conditions for power clean. Nineteen participants (ten skilled and nine unskilled) performed power clean at 60–90% one repetition maximum (1RM), while measured 12 muscles across the entire body. The vertical impulse was calculated for the unweighting associated with the double-knee bend (DKB) manoeuvre in power clean. Muscle synergies were extracted using non-negative matrix factorization. The weighting of muscle synergies was subsequently compared between the two groups for all loads, and confidence intervals were calculated. The number of muscle synergies in both groups was three, and the functions of all muscle synergies were similar. Muscle synergy 1 involved the first pull, muscle synergy 2 involved the transition and the second pull, and muscle synergy 3 involved DKB. No significant difference in either muscle synergy was observed at 60–80% 1RM weight, while the 90% 1RM showed significantly active in the ankle plantar flexor and knee extensor muscles for muscle synergy 3, which involved DKB only in the skilled group. This indicates that increased joint stiffness during DKB may minimize unweighting. Unskilled individuals may acquire such muscle synergies to lift greater weights. [ABSTRACT FROM AUTHOR]

Published

2023

30. Inter-muscular coordination during running on grass, concrete and treadmill.

Author

Yaserifar, Morteza and Oliveira, Anderson Souza

Subjects

*TREADMILLS, *MATRIX decomposition, *NONNEGATIVE matrices, *IMPACT loads, *RUNNING

Abstract

Running is an exercise that can be performed in different environments that imposes distinct foot–floor interactions. For instance, running on grass may help reducing instantaneous vertical impact loading, while compromising natural speed. Inter-muscular coordination during running is an important factor to understand motor performance, but little is known regarding the impact of running surface hardness on inter-muscular coordination. Therefore, we investigated whether inter-muscular coordination during running is influenced by running surface. Surface electromyography (EMG) from 12 lower limb muscles were recorded from young male individuals (n = 9) while running on grass, concrete, and on a treadmill. Motor modules consisting of weighting coefficients and activation signals were extracted from the multi-muscle EMG datasets representing 50 consecutive running cycles using non-negative matrix factorization. We found that four motor modules were sufficient to represent the EMG from all running surfaces. The inter-subject similarity across muscle weightings was the lowest for running on grass (r = 0.76 ± 0.11) compared to concrete (r = 0.81 ± 0.07) and treadmill (r = 0.78 ± 0.05), but no differences in weighting coefficients were found when analyzing the number of significantly active muscles and residual muscle weightings (p > 0.05). Statistical parametric mapping showed no temporal differences between activation signals across running surfaces (p > 0.05). However, the activation duration (% time above 15% peak activation) was significantly shorter for treadmill running compared to grass and concrete (p < 0.05). These results suggest predominantly similar neuromuscular strategies to control multiple muscles across different running surfaces. However, individual adjustments in inter-muscular coordination are required when coping with softer surfaces or the treadmill's moving belt. [ABSTRACT FROM AUTHOR]

Published

2023

31. Detection of intermuscular coordination based on the causality of empirical mode decomposition.

Author

Cruz-Montecinos, Carlos, García-Massó, Xavier, Maas, Huub, Cerda, Mauricio, Ruiz-del-Solar, Javier, and Tapia, Claudio

Subjects

*ELECTROMYOGRAPHY, *ANKLE, *SKELETAL muscle, *SOLEUS muscle

Abstract

Considering the stochastic nature of electromyographic (EMG) signals, nonlinear methods may be a more accurate approach to study intermuscular coordination than the linear approach. The aims of this study were to assess the coordination between two ankle plantar flexors using EMG by applying the causal decomposition approach and assessing whether the intermuscular coordination is affected by the slope of the treadmill. The medial gastrocnemius (MG) and soleus muscles (SOL) were analyzed during the treadmill walking at inclinations of 0°, 5°, and 10°. The coordination was evaluated using ensemble empirical mode decomposition, and the causal interaction was encoded by the instantaneous phase dependence of time series bi-directional causality. To estimate the mutual predictability between MG and SOL, the cross-approximate entropy (XApEn) was assessed. The maximal causal interaction was observed between 40 and 75 Hz independent of inclination. XApEn showed a significant decrease between 0° and 5° (p = 0.028), between 5° and 10° (p = 0.038), and between 0° and 10° (p = 0.014), indicating an increase in coordination. Thus, causal decomposition is an appropriate methodology to study intermuscular coordination. These results indicate that the variation of loading through the change in treadmill inclination increases the interaction of the shared input between MG and SOL, suggesting increased intermuscular coordination. [ABSTRACT FROM AUTHOR]

Published

2023

32. Muscle coordination during archery shooting: A comparison of archers with different skill levels.

Author

Baifa, Zhang, Xinglong, Zhou, and Dongmei, Luo

Subjects

*SKELETAL muscle physiology, *MUSCLE contraction, *SHOOTING (Sports), *AMATEUR athletes, *ARCHERY, *DESCRIPTIVE statistics, *ELECTROMYOGRAPHY, *BIOMECHANICS, *TIME management, *MOTOR ability

Abstract

This study aimed to compare the muscle coordination of different skill level archers by using the concept of muscle synergies. A total of 28 archers (8 elite, 12 mid-level, and 8 novices) were recruited to participate in this study. Electromyography (EMG) signals were recorded using a 13-channel (Trigno EMG sensor, Delsys Inc., USA) wireless surface EMG system. Fundamental synergies containing time-dependent activation coefficients (motor primitives) and time-invariant muscle weightings (motor modules) were extracted using non-negative matrix factorisation. We observed three fundamental synergies in all groups during archery shooting. The results showed that the centre of activity of the motor primitive of synergy-3 occurred earlier in novice archers than in elite and mid-level archers, which was followed by an increase in the averaged frequency of overlaps. The results also showed a slight difference in the relative muscle contribution of the motor module of synergy-2 and -3 within different groups. These findings revealed that the number of muscle synergies did not depend on the proficiency level; however, more expert archers improved timing management better than less experienced ones. Therefore, we suggest that coaches and athletes focus on optimising the temporal coordination of the follow-through phase. [ABSTRACT FROM AUTHOR]

Published

2023

33. The effects of age and physical activity status on muscle synergies when walking down slopes.

Author

Nash, Laura, Cheung, Vincent C. K., Gupta, Amitabh, Cheung, Roy T. H., He, Borong, Liston, Matthew, and Thomson, Daniel

Abstract

Purpose: The aim of the current study was to determine whether gait control (muscle synergies) or gait stability (margin of stability (MoS)) were different between younger and older adults when walking on level or downhill slopes. Further, it sought to determine associations between either age or physical activity with muscle synergy widths.Ten healthy younger (28.1 ± 8.0 years) and ten healthy older (69.5 ± 6.3 years) adults walked at their preferred walking speed on a treadmill at different slopes (0˚, − 4˚ and − 8˚). Muscle synergies were extracted using non-negative matrix factorisation and compared between groups and walking slopes. Correlations between the full width at half maximum (FWHM) of the synergies’ activations and weekly recreational physical activity minutes and age were also determined.Younger and older adults both walked with similar muscle synergies across all tested slopes, with 4 synergies accounting for > 85% variance of overall muscle activity in both groups across all tested slopes, with high scalar products (≥ 0.86) for each synergy and slope. It was also demonstrated that physical activity and age had different associations with pooled muscle synergies across slopes, as weekly minutes spent in recreational physical activity were associated with the FWHM of a synergy activated at weight acceptance, whereas age was associated with the FWHM of synergies occurring at push off and foot clearance, respectively.Our results suggest that healthy older and younger adults walk with similar muscle synergies on downhill slopes, and that physical activity and age influence different muscle synergies during walking.Methods: The aim of the current study was to determine whether gait control (muscle synergies) or gait stability (margin of stability (MoS)) were different between younger and older adults when walking on level or downhill slopes. Further, it sought to determine associations between either age or physical activity with muscle synergy widths.Ten healthy younger (28.1 ± 8.0 years) and ten healthy older (69.5 ± 6.3 years) adults walked at their preferred walking speed on a treadmill at different slopes (0˚, − 4˚ and − 8˚). Muscle synergies were extracted using non-negative matrix factorisation and compared between groups and walking slopes. Correlations between the full width at half maximum (FWHM) of the synergies’ activations and weekly recreational physical activity minutes and age were also determined.Younger and older adults both walked with similar muscle synergies across all tested slopes, with 4 synergies accounting for > 85% variance of overall muscle activity in both groups across all tested slopes, with high scalar products (≥ 0.86) for each synergy and slope. It was also demonstrated that physical activity and age had different associations with pooled muscle synergies across slopes, as weekly minutes spent in recreational physical activity were associated with the FWHM of a synergy activated at weight acceptance, whereas age was associated with the FWHM of synergies occurring at push off and foot clearance, respectively.Our results suggest that healthy older and younger adults walk with similar muscle synergies on downhill slopes, and that physical activity and age influence different muscle synergies during walking.Results: The aim of the current study was to determine whether gait control (muscle synergies) or gait stability (margin of stability (MoS)) were different between younger and older adults when walking on level or downhill slopes. Further, it sought to determine associations between either age or physical activity with muscle synergy widths.Ten healthy younger (28.1 ± 8.0 years) and ten healthy older (69.5 ± 6.3 years) adults walked at their preferred walking speed on a treadmill at different slopes (0˚, − 4˚ and − 8˚). Muscle synergies were extracted using non-negative matrix factorisation and compared between groups and walking slopes. Correlations between the full width at half maximum (FWHM) of the synergies’ activations and weekly recreational physical activity minutes and age were also determined.Younger and older adults both walked with similar muscle synergies across all tested slopes, with 4 synergies accounting for > 85% variance of overall muscle activity in both groups across all tested slopes, with high scalar products (≥ 0.86) for each synergy and slope. It was also demonstrated that physical activity and age had different associations with pooled muscle synergies across slopes, as weekly minutes spent in recreational physical activity were associated with the FWHM of a synergy activated at weight acceptance, whereas age was associated with the FWHM of synergies occurring at push off and foot clearance, respectively.Our results suggest that healthy older and younger adults walk with similar muscle synergies on downhill slopes, and that physical activity and age influence different muscle synergies during walking.Conclusion: The aim of the current study was to determine whether gait control (muscle synergies) or gait stability (margin of stability (MoS)) were different between younger and older adults when walking on level or downhill slopes. Further, it sought to determine associations between either age or physical activity with muscle synergy widths.Ten healthy younger (28.1 ± 8.0 years) and ten healthy older (69.5 ± 6.3 years) adults walked at their preferred walking speed on a treadmill at different slopes (0˚, − 4˚ and − 8˚). Muscle synergies were extracted using non-negative matrix factorisation and compared between groups and walking slopes. Correlations between the full width at half maximum (FWHM) of the synergies’ activations and weekly recreational physical activity minutes and age were also determined.Younger and older adults both walked with similar muscle synergies across all tested slopes, with 4 synergies accounting for > 85% variance of overall muscle activity in both groups across all tested slopes, with high scalar products (≥ 0.86) for each synergy and slope. It was also demonstrated that physical activity and age had different associations with pooled muscle synergies across slopes, as weekly minutes spent in recreational physical activity were associated with the FWHM of a synergy activated at weight acceptance, whereas age was associated with the FWHM of synergies occurring at push off and foot clearance, respectively.Our results suggest that healthy older and younger adults walk with similar muscle synergies on downhill slopes, and that physical activity and age influence different muscle synergies during walking. [ABSTRACT FROM AUTHOR]

Published

2024

34. Evaluation of Muscle Synergy During Exoskeleton-Assisted Walking in Persons With Multiple Sclerosis.

Author

Afzal, Taimoor, Zhu, Fangshi, Tseng, Shih-Chiao, Lincoln, John A., Francisco, Gerard E., Su, Hao, and Chang, Shuo-Hsiu

Subjects

*ROBOTIC exoskeletons, *RECTUS femoris muscles, *MULTIPLE sclerosis, *LEG muscles, *SKELETAL muscle, *KNEE

Abstract

Objective: Gait deficit after multiple sclerosis (MS) can be characterized by altered muscle activation patterns. There is preliminary evidence of improved walking with a lower limb exoskeleton in persons with MS. However, the effects of exoskeleton-assisted walking on neuromuscular modifications are relatively unclear. The objective of this study was to investigate the muscle synergies, their activation patterns and the differences in neural strategies during walking with (EXO) and without (No-EXO) an exoskeleton. Methods: Ten subjects with MS performed walking during EXO and No-EXO conditions. Electromyography signals from seven leg muscles were recorded. Muscle synergies and the activation profiles were extracted using non-negative matrix factorization. Results: The stance phase duration was significantly shorter during EXO compared to the No-EXO condition (p<0.05). Moreover, typically 3-5 modules were extracted in each condition. The module-1 (comprising Vastus Medialis and Rectus Femoris muscles), module-2 (comprising Soleus and Medial Gastrocnemius muscles), module-3 (Tibialis Anterior muscle) and module-4 (comprising Biceps Femoris and Semitendinosus muscles) were comparable between conditions. During EXO condition, Semitendinosus and Vastus Medialis emerged in module-5 in 7/10 subjects. Compared to No-EXO, average activation amplitude was significantly reduced corresponding to module-2 during the stance phase and module-3 during the swing phase during EXO. Conclusion: Exoskeleton-assistance does not alter the existing synergy modules, but could induce a new module to emerge, and alters the control of these modules, i.e., modifies the neural commands indicated by the reduced amplitude of the activation profiles. Significance: The work provides insights on the potential underlying mechanism of improving gait functions after exoskeleton-assisted locomotor training. [ABSTRACT FROM AUTHOR]

Published

2022

35. Similarity of hand muscle synergies elicited by transcranial magnetic stimulation and those found during voluntary movement.

Author

Yarossi, Mathew, Brooks, Dana H., Erdoğmus, Deniz, and Tunik, Eugene

Subjects

*TRANSCRANIAL magnetic stimulation, *FOREARM, *MOTOR cortex, *AMERICAN Sign Language, *MATRIX decomposition, *MODULAR construction, *THUMB

Abstract

Converging evidence in human and animal models suggests that exogenous stimulation of the motor cortex (M1) elicits responses in the hand with similar modular structure to that found during voluntary grasping movements. The aim of this study was to establish the extent to which modularity in muscle responses to transcranial magnetic stimulation (TMS) to M1 resembles modularity in muscle activation during voluntary hand movements involving finger fractionation. Electromyography (EMG) was recorded from eight hand-forearm muscles in eight healthy individuals. Modularity was defined using non-negative matrix factorization to identify low-rank approximations (spatial muscle synergies) of the complex activation patterns of EMG data recorded during high-density TMS mapping of M1 and voluntary formation of gestures in the American Sign Language alphabet. Analysis of synergies revealed greater than chance similarity between those derived from TMS and those derived from voluntary movement. Both data sets included synergies dominated by single intrinsic hand muscles presumably to meet the demand for highly fractionated finger movement. These results suggest that corticospinal connectivity to individual intrinsic hand muscles may be combined with modular multimuscle activation via synergies in the formation of hand postures. [ABSTRACT FROM AUTHOR]

Published

2022

36. Age-related differences in gait symmetry obtained from kinematic synergies and muscle synergies of lower limbs during childhood.

Author

Xiong, Qiliang, Wan, Jinliang, Jiang, Shaofeng, and Liu, Yuan

Subjects

*NEUROMUSCULAR diseases, *ANKLE, *GAIT in humans, *LEG, *SYMMETRY, *PRINCIPAL components analysis, *WALKING speed, *SKELETAL muscle physiology, *LEG physiology, *ELECTROMYOGRAPHY, *KINEMATICS

Abstract

The age-related changes of gait symmetry in healthy children concerning individual joint and muscle activation data have previously been widely studied. Extending beyond individual joints or muscles, identifying age-related changes in the coordination of multiple joints or muscles (i.e., muscle synergies and kinematic synergies) could capture more closely the underlying mechanisms responsible for gait symmetry development. To evaluate the effect of age on the symmetry of the coordination of multiple joints or muscles during childhood, we measured gait symmetry by kinematic and EMG data in 39 healthy children from 2 years old to 14 years old, divided into three equal age groups: preschool children (G1; 2.0-5.9 years), children (G2; 6.0-9.9 years), pubertal children (G3; 10.0-13.9 years). Participants walked barefoot at a self-selected walking speed during three-dimensional gait analysis (3DGA). Kinematic synergies and muscle synergies were extracted with principal component analysis (PCA) and non-negative matrix factorization (NNMF), respectively. The synergies extracted from the left and right sides were compared with each other to obtain a symmetry value. Statistical analysis was performed to examine intergroup differences. The results showed that the effect of age was significant on the symmetry values extracted by kinematic synergies, while older children exhibited higher kinematic synergy symmetry values compared to the younger group. However, no significant age-related changes in symmetry values of muscle synergy were observed. It is suggested that kinematic synergy of lower joints can be asymmetric at the onset of independent walking and showed improving symmetry with increasing age, whereas the age-related effect on the symmetry of muscle synergies was not demonstrated. These data provide an age-related framework and normative dataset to distinguish age-related differences from pathology in children with neuromotor disorders. [ABSTRACT FROM AUTHOR]

Published

2022

37. Soleus H-reflex modulation in cerebral palsy and its relationship with neural control complexity: a pilot study.

Author

Conner, Benjamin C., Spomer, Alyssa M., Bishe, Safoura Sadegh Pour Aji, Steele, Katherine M., and Lerner, Zachary F.

Subjects

*H-reflex, *CEREBRAL palsy, *ROBOTIC exoskeletons, *PILOT projects, *REFLEXES

Abstract

Individuals with cerebral palsy (CP) display motor control patterns that suggest decreased supraspinal input, but it remains unknown if they are able to modulate lower-limb reflexes in response to more complex tasks, or whether global motor control patterns relate to reflex modulation capacity in this population. Eight ambulatory individuals with CP (12–18 years old) were recruited to complete a task complexity protocol, where soleus H-reflex excitability was compared between bilateral (baseline) and unilateral (complex) standing. We also investigated the relationship between each participant's ability to modulate soleus H-reflex excitability and the complexity of their walking neural control pattern determined from muscle synergy analysis. Finally, six of the eight participants completed an exoskeleton walking protocol, where soleus H-reflexes were collected during the stance phase of walking with and without stance-phase plantar flexor resistance. Participants displayed a significant reduction in soleus H-reflex excitability (− 26 ± 25%, p = 0.04) with unilateral standing, and a strong positive relationship was observed between more refined neural control during walking and an increased ability to modulate reflex excitability (R = 0.79, p = 0.04). There was no difference in neuromuscular outcome measures with and without the ankle exoskeleton (p values all > 0.05), with variable reflex responses to walking with ankle exoskeleton resistance. These findings provide evidence that ambulatory individuals with CP retain some capacity to modulate lower-limb reflexes in response to increased task complexity, and that less refined neural control during walking appears to be related to deficits in reflex modulation. [ABSTRACT FROM AUTHOR]

Published

2022

38. 运动协调理论模型与量化方法的演进.

Author

王佳伟 and 刘 晔

Abstract

BACKGROUND: Motor coordination is an important part of human motor ability, and it is of great significance to explore its rules to understand the coordination and control of “nerves-muscles-joints” in human locomotor system. OBJECTIVE: To review the evolution of theoretical models and quantitative methods of motor coordination through systematic analysis of domestic and foreign research literature on motor coordination. METHODS: We retrieved PubMed, Web of Science, EBSCO and CNKI Full-text databases using the keywords of “motor coordination, segment coordination, muscle synergy, equilibrium point, uncontrolled manifold” in English and “motor coordination, joint coupling, joint coordination, muscle synergy, vector coding, motor control” in Chinese. There was no limitation to the time of literature retrieval. Finally, 111 eligible literatures were included and reviewed. RESULTS AND CONCLUSION: In the current theoretical model of motor coordination, the dynamic system theory, uncontrolled manifold hypothesis, and the muscle synergy hypothesis have been most useful and widely applied. The corresponding quantitative methods are also evolving. Continuity analysis has great potential to explore the coordination characteristics of the joint under periodic and aperiodic relative motion. Muscle synergy analysis can be used to identify the muscle synergy strategies in different groups. It is suggested that research on motor coordination in China should combine the analysis of joint coordination mode and neuromuscular cooperative control strategy based on improving the exploration of basic theories and the use of various quantitative methods, so as to better understand the coordination law of nerves-muscles-joints. [ABSTRACT FROM AUTHOR]

Published

2022

39. Myoelectric interface training enables targeted reduction in abnormal muscle co-activation.

Author

Seo, Gang, Kishta, Ameen, Mugler, Emily, Slutzky, Marc W., and Roh, Jinsook

Subjects

*COMPUTER interfaces, *MATRIX decomposition, *NONNEGATIVE matrices, *MOTOR learning, *STROKE patients, *ARM muscles

Abstract

Background: Abnormal patterns of muscle co-activation contribute to impaired movement after stroke. Previously, we developed a myoelectric computer interface (MyoCI) training paradigm to improve stroke-induced arm motor impairment by reducing the abnormal co-activation of arm muscle pairs. However, it is unclear to what extent the paradigm induced changes in the overall intermuscular coordination in the arm, as opposed to changing just the muscles trained with the MyoCI. This study examined the intermuscular coordination patterns of thirty-two stroke survivors who participated in 6 weeks of MyoCI training.Methods: We used non-negative matrix factorization to identify the arm muscle synergies (coordinated patterns of muscle activity) during a reaching task before and after the training. We examined the extent to which synergies changed as the training reduced motor impairment. In addition, we introduced a new synergy analysis metric, disparity index (DI), to capture the changes in the individual muscle weights within a synergy.Results: There was no consistent pattern of change in the number of synergies across the subjects after the training. The composition of muscle synergies, calculated using a traditional synergy similarity metric, also did not change after the training. However, the disparity of muscle weights within synergies increased after the training in the participants who responded to MyoCI training-that is, the specific muscles that the MyoCI was targeting became less correlated within a synergy. This trend was not observed in participants who did not respond to the training.Conclusions: These findings suggest that MyoCI training reduced arm impairment by decoupling only the muscles trained while leaving other muscles relatively unaffected. This suggests that, even after injury, the nervous system is capable of motor learning on a highly fractionated level. It also suggests that MyoCI training can do what it was designed to do-enable stroke survivors to reduce abnormal co-activation in targeted muscles. Trial registration This study was registered at ClinicalTrials.gov (NCT03579992, Registered 09 July 2018-Retrospectively registered, https://clinicaltrials.gov/ct2/show/NCT03579992?term=NCT03579992&draw=2&rank=1 ). [ABSTRACT FROM AUTHOR]

Published

2022

40. Synergy Analysis of Back Muscle Activities in Patients With Adolescent Idiopathic Scoliosis Based on High-Density Electromyogram.

Author

Wang, Wei, Jiang, Naifu, Teng, Lijun, Sui, Minghong, Li, ChunZhen, Wang, Lin, and Li, Guanglin

Subjects

*ADOLESCENT idiopathic scoliosis, *BACK muscles, *VECTOR data, *MOTOR ability, *NONNEGATIVE matrices, *ZYGAPOPHYSEAL joint, *MUSCLES

Abstract

Objective: Adolescent idiopathic scoliosis (AIS) is a common structural spinal deformity and is typically associated with altered muscle properties. However, it is still unclear how muscle activities and the underlying neuromuscular control are changed in the entire scoliotic zone, restricting the corresponding pathology investigation and treatment enhancements. Methods: High-density electromyogram (HD-EMG) was utilized to explore the neuromuscular synergy of back muscle activities. For each of ten AIS patients and ten healthy subjects for comparison, an HD-EMG array was placed on their back from T8 to L4 to record EMG signals when performing five spinal motions (flexion/extension, lateral bending, axial rotation, siting, and standing). From the HD-EMG recordings, muscle synergies were extracted using the non-negative matrix factorization method and the topographical maps of EMG root-mean-square were constructed. Results: For both the AIS and healthy subjects, the experimental results indicated that two muscle synergy groups could explain over 90% of recorded muscle activities for all five motions. During flexion/extension, the patients presented statistically significant higher activations on the convex side in the entire root-mean-square maps and synergy vector maps (p < 0.05). During lateral bending and axial rotation, the patients exhibited less activated muscles on the dominant actuating side relative to the contralateral side and their synergy vector maps showed a less homogenous and more diffuse distribution of muscle contraction with statistically different centers of gravity. Conclusion: The findings suggest a scoliotic spine might adopt an altered modular muscular coordination strategy to actuate different dominant muscles as adapted compensations for the deformation. [ABSTRACT FROM AUTHOR]

Published

2022

41. 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, and Pérez‐Alenda, Sofía

Subjects

*JOINT diseases, *KNEE pain, *GAIT in humans, *JOINTS (Anatomy), *MULTIPLE regression analysis, *VISUAL analog scale, *CHARCOT joints

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. [ABSTRACT FROM AUTHOR]

Published

2022

42. Estimation of Time-Frequency Muscle Synergy in Wrist Movements.

Author

Xie, Ping, Chang, Qingya, Zhang, Yuanyuan, Dong, Xiaojiao, Yu, Jinxu, and Chen, Xiaoling

Subjects

*WRIST, *EFFERENT pathways, *MATRIX decomposition, *NONNEGATIVE matrices, *EXTENSOR muscles, *FLEXOR muscles

Abstract

Muscle synergy analysis is a kind of modularized decomposition of muscles during exercise controlled by the central nervous system (CNS). It can not only extract the synergistic muscles in exercise, but also obtain the activation states of muscles to reflect the coordination and control relationship between muscles. However, previous studies have mainly focused on the time-domain synergy without considering the frequency-specific characteristics within synergy structures. Therefore, this study proposes a novel method, named time-frequency non-negative matrix factorization (TF-NMF), to explore the time-varying regularity of muscle synergy characteristics of multi-channel surface electromyogram (sEMG) signals at different frequency bands. In this method, the wavelet packet transform (WPT) is used to transform the time-scale signals into time-frequency dimension. Then, the NMF method is calculated in each time-frequency window to extract the synergy modules. Finally, this method is used to analyze the sEMG signals recorded from 8 muscles during the conversion between wrist flexion (WF stage) and wrist extension (WE stage) movements in 12 healthy people. The experimental results show that the number of synergy modules in wrist flexion transmission to wrist extension (Motion Conversion, MC stage) is more than that in the WF stage and WE stage. Furthermore, the number of flexor and extensor muscle synergies in the frequency band of 0–125 Hz during the MC stage is more than that in the frequency band of 125–250 Hz. Further analysis shows that the flexion muscle synergies mostly exist in the frequency band of 140.625–156.25 Hz during the WF stage, and the extension muscle synergies appear in the frequency band of 125–156.25 Hz during the WE stage. These results can help to better understand the time-frequency features of muscle synergy, and expand study perspective related to motor control in nervous system. [ABSTRACT FROM AUTHOR]

Published

2022

43. Methodological and Computational Aspects of Extracting Extensive Muscle Synergies in Moderate-Intensity Locomotions.

Author

Moiseev, S. A., Pukhov, A. M., Mikhailova, E. A., and Gorodnichev, R. M.

Subjects

*PRINCIPAL components analysis, *SIGNAL reconstruction, *MATRIX decomposition, *FACTOR analysis, *BANDPASS filters

Abstract

In motor synergy studies, modern approaches typically include the consideration of synergistic effects at one or, less often, two levels of the nervous system organization, as well as their interaction in the context of solving various motor tasks, including locomotion. However, even when considering movements that are similar in their biomechanical structure, there arise discrepancies in some aspects of studying muscle synergies, which is thought to be due to the use of different methodological and computational approaches that disregard the specificity of motor acts under consideration. The aim of the study was to find optimal parameters of electromyographic (EMG) signal preprocessing and to evaluate their influence on the results of extensive muscle synergy extraction during moderate-intensity locomotions. The study was carried out on 10 male sprinters during moderate-intensity treadmill running. Electromyograms of 16 superficial skeletal muscles of the trunk, upper and lower extremities were recorded. Muscle synergies were extracted by matrix factorization methods using various procedures of original signal preprocessing. It was found that extended muscle synergies extraction gives the best results through the application of a bandpass filter in the range of 20–450 Hz with additional 20-Hz filtering after electromyogram rectification. The number of extracted synergies from different phases of the running step cycle was greater when using principal component analysis (PCA) and smaller when using factor analysis (FA), while in terms of accounted variance, both methods return better results than when analyzing the whole running step cycle. The number of extracted synergies decreased proportionally to an original data amount decrease, while the quality of synergy extraction decreased as the number of analyzed muscles decreased. The results of original EMG signal reconstruction using data factorization methods were more effective when considering individual phases as opposed to the whole running step cycle. The indices of muscle synergy extraction were sensitive to the original set of EMG signals included in the analysis. [ABSTRACT FROM AUTHOR]

Published

2022

44. Investigation of Power Specific Motor Primitives in an Upper Limb Rotational Motion.

Author

Abd, A. T., Singh, R. E., Iqbal, K., and White, G.

Subjects

*ROTATIONAL motion, *MATRIX decomposition, *NONNEGATIVE matrices, *HUMAN mechanics, *ARM

Abstract

The purpose of this study was to investigate muscle synergies (MS) during upper limb cycling motion across power levels (20, 40, 60, 80, 100, and 120 watts). The MS hypothesis is important to the understanding of modular control for human movements. In this study, we explore its importance in execution of phasic movements at various power levels. Electromyographic (EMG) signals were recorded from 7 upper limb muscles during cycling for 30s on a hand-cycle ergometer. A Non-Negative Matrix factorization (NNMF) algorithm was used to extract MS. Cosine similarity was used to compare the MS and cross-correlation was used to compare activation coefficients. We found that the number and structure of synergies were consistent across power levels while admitting modulation in their activation coefficients. A total of three shared MS explaining ≥95% of the variance accounted for (VAF) represented push and pull mechanism during cyclic motion. [ABSTRACT FROM AUTHOR]

Published

2022

45. Effects of body weight support and guidance force settings on muscle synergy during Lokomat walking.

Author

Cherni, Yosra, Hajizadeh, Maryam, Dal Maso, Fabien, and Turpin, Nicolas A.

Subjects

*TIBIALIS anterior, *BODY weight, *VASTUS medialis, *RECTUS femoris muscles, *BODY-weight-supported treadmill training, *MOTOR learning, *TREADMILLS

Abstract

Background: The Lokomat is a robotic device that has been suggested to make gait therapy easier, more comfortable, and more efficient. In this study, we asked whether the Lokomat promotes physiological muscle activation patterns, a fundamental question when considering motor learning and adaptation. Methods: We investigated lower limb muscles coordination in terms of muscle activity level, muscle activity pattern similarity, and muscle synergy in 15 healthy participants walking at 3 km/h on either a treadmill or in a Lokomat at various guidance forces (GF: 30, 50 or 70%) and body weight supports (BWS: 30, 50 or 70% of participant's body weight). Results: Walking in the Lokomat was associated with a greater activation level of the rectus femoris and vastus medialis (×2–3) compared to treadmill walking. The level of activity tended to be diminished in gastrocnemius and semi-tendinosus, which particularly affected the similarity with treadmill walking (normalized scalar product NSP = 0.7–0.8). GF and BWS independently altered the muscle activation pattern in terms of amplitude and shape. Increasing BWS decreased the level of activity in all but one muscle (the soleus). Increasing GF slightly improved the similarity with treadmill walking for the tibialis anterior and vastus medialis muscles. The muscle synergies (N = 4) were similar (NSP = 0.93–0.97), but a cross-validation procedure revealed an alteration by the Lokomat. The activation of these synergies differed (NSP = 0.74–0.82). Conclusion: The effects of GF and BWS are modest compared to the effect of the Lokomat itself, suggesting that Lokomat design should be improved to promote more typical muscle activity patterns. [ABSTRACT FROM AUTHOR]

Published

2021

46. Correlation Evaluation of Functional Corticomuscular Coupling With Abnormal Muscle Synergy After Stroke.

Author

Liu, Jinbiao, Wang, Jixian, Tan, Gansheng, Sheng, Yixuan, Chang, Hui, Xie, Qing, and Liu, Honghai

Subjects

*STROKE patients, *SPATIAL filters, *STROKE rehabilitation, *NEUROPLASTICITY, *NEUROMUSCULAR diseases

Abstract

Objective: While neuroplasticity and functional reorganization during motor recovery can be indirectly reflected and evaluated by functional corticomuscular coupling (fCMC), little work has been published regarding the cortical origin of abnormal muscle synergy and compensatory mechanism in the separation movement of stroke patients. Methods: In this study, we proposed to use extended partial directed coherence (ePDC) combined with an optimal spatial filtering approach to estimate fCMC in stroke patients and healthy controls, and further established muscle synergy model (MSM) to jointly explore the modulation mechanism between cortex and muscles. Results: Compared to healthy controls, stroke patients had significantly reduced coupling strength in both descending and ascending pathway. Moreover, the MSM were abnormal with high variability and low similarity in the separation stage of stroke patients. Further exploration of the positive relationship between fCMC characteristics and MSM parameters proved the possibility of using fCMC-MSM-based correlation indicator to evaluate abnormality of the cortical related synergy movement as well as the rehabilitation level of stroke patients. Conclusion: We developed a computational procedure to evaluate the correlation between fCMC and MSM in stroke patients. Significance: This article provides a quantitative evaluation metrics based on fCMC to reveal the deficits during poststroke motor restoration and a promising approach to help patients correct abnormal movement habits, paving the way for neurophysiological assessment of neuromuscular control in conjunction with clinical scores. [ABSTRACT FROM AUTHOR]

Published

2021

47. Primitive muscle synergies reflect different modes of coordination in upper limb motions.

Author

Pan, Bingyu, Huang, Zhipei, Wu, Jiankang, and Shen, Yanfei

Subjects

*MOTOR ability, *ARM muscles, *MUSCLE analysis, *ELECTROMYOGRAPHY, *HUMAN locomotion, *CENTRAL nervous system, *FACTORIZATION

Abstract

The motor system relies on the recruitment of motor modules to perform various movements. Muscle synergies are the modules used by the central nervous system to simplify the control of complex motor tasks. In this paper, we aim to explore the primitive synergies to reflect different modes of coordination in upper limb motions. Muscle synergies and corresponding activation coefficients were extracted via non-negative matrix factorization from the electromyography signals of three basic and four complex upper limb motions in sagittal plane and coronal plane. Similarities of muscle synergies and activation coefficients between different tasks and different subjects were compared. Moreover, we used network theory to assess the coordination between multiple muscles and to elucidate the neural implementation of muscle synergies. The results showed that the combination of different sets of primitive muscle synergies can achieve complex motions in different planes. The muscle synergy network topology differed significantly between different tasks. We also demonstrated the potential of this study for the understanding of human motor control mechanism and implications for neurorehabilitation. [ABSTRACT FROM AUTHOR]

Published

2021

48. Young adults recruit similar motor modules across walking, turning, and chair transfers.

Author

Carey, Hannah D., Liss, Daniel J., and Allen, Jessica L.

Subjects

*YOUNG adults, *CENTRAL nervous system

Abstract

Moving about in the world during daily life requires executing and successfully shifting between a variety of functional tasks, such as rising from a chair or bed, walking, turning, and navigating stairs. Moreover, moving about during daily life requires not only navigating between different functional tasks, but also performing these tasks in the presence of mental distractions. However, little is known about underlying neuromuscular control for executing and shifting between these different tasks. In this study, we investigated muscle coordination across walking, turning, and chair transfers by applying motor module (a.k.a. muscle synergy) analysis to the Timed‐Up‐and‐Go (TUG) test with and without a secondary cognitive dual task. We found that healthy young adults recruit a small set of common motor modules across the subtasks of the TUG test and that their composition is robust to cognitive distraction. Instead, cognitive distraction impacted motor module activation timings such that they became more consistent. This work is the first to demonstrate motor module generalization across multiple tasks that are both functionally different and crucial for healthy mobility. Overall, our results suggest that the central nervous system may draw from a "library" of modular control strategies to navigate the variety of movements and cognitive demands required of daily life. [ABSTRACT FROM AUTHOR]

Published

2021

49. Modular reorganization of gait in chronic but not in artificial knee joint constraint.

Author

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

Abstract

It is currently unknown if modular reorganization does occur if not the central nervous system, but the musculoskeletal system is affected. The aims of this study were to investigate 1) the effects of an artificial knee joint constraint on the modular organization of gait in healthy subjects; and 2) the differences in modular organization between healthy subjects with an artificial knee joint constraint and people with a similar but chronic knee joint constraint. Eleven healthy subjects and eight people with a chronic knee joint constraint walked overground at 1 m/s. The healthy subjects also walked with a constraint limiting knee joint movement to 20°. The total variance accounted (tVAF) for one to four synergies and modular organization were assessed using surface electromyography from 11 leg muscles. The distribution of number of synergies were not significantly different between groups. The tVAF and the motor modules were not significantly affected by the artificial knee constraint. A higher tVAF for one and two synergies, as well as merging of motor modules were observed in the chronic knee constraint group. We conclude that in the short-term a knee constraint does not affect the modular organization of gait, but in the long-term a knee constraint results in modular reorganization. These results indicate that merging of motor modules may also occur when changes in the mechanics of the musculoskeletal system is the primary cause of the motor impairment. NEW & NOTEWORTHY It is currently unknown if modular reorganization does occur if not the central nervous system, but the musculoskeletal system is affected. This study showed that in the short-term a knee constraint does not affect the modular organization of gait, but in the long-term a knee constraint results in modular reorganization. These results indicate that modular reorganization may also occur when changes in the mechanics of the musculoskeletal system is the primary cause of the motor impairment. [ABSTRACT FROM AUTHOR]

Published

2021

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

Author

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

Subjects

*ARTIFICIAL neural networks, *ANKLE, *KNEE, *REACTION forces

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 that muscle synergy generates muscle activity as a feedforward signal, which is modified by sensory input. This study focuses on determining the sensory input primarily used for modifying sit-to-stand motion. To obtain this, we built artificial neural network models that generate muscle activities based on sensory input and feedforward signals and analyzed the effect of each input on the output. The models were built for each motion phase. The input was information from vestibular and somatosensory input and averaged muscle synergy as feedforward signals, and the output was muscle synergy. As a result, it was revealed that humans may primarily use hip angle to bend forward, ankle and vertical foot reaction force to hip rise, ankle, knee, and lumber angles and vertical foot reaction force to extend body, and lumber angle to stabilize. This indicates the type of sensory input used to control each muscle synergy in each motion phase. The information should be used to modify the sit-to-stand motion in environmental conditions where the motion is performed. [ABSTRACT FROM AUTHOR]

Published

2021