Are Modular Activations Altered in Lower Limb Muscles of Persons with Multiple Sclerosis during Walking? Evidence from Muscle Synergies and Biomechanical Analysis

Lencioni, Tiziana; Jonsdottir, Johanna; Cattaneo, Davide; Crippa, Alessandro; Gervasoni, Elisa; Rovaris, Marco; Bizzi, Emilio; Ferrarin, Maurizio

doi:10.3389/fnhum.2016.00620

Cited by 44 publications

(56 citation statements)

References 72 publications

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“…Second, some synergies were not altered in weights but instead, ceased to be used strongly in patterns. Both of these types of changes are likely significant in motor drive infrastructure, pattern generation, and the pathologies and injury effects where synergies may have impact (27,(33)(34)(35)(36)(37)(38)(39)(40)(44)(45)(46)(47)(48)(49). Synergies normally weakly activated in intact CNS that become active in disease would interfere with normal function and be pathological.…”

Section: Discussionmentioning

confidence: 99%

Motor primitives are determined in early development and are then robustly conserved into adulthood

Yang

Logan

Giszter

2019

Proc. Natl. Acad. Sci. U.S.A.

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Motor patterns in legged vertebrates show modularity in both young and adult animals, comprising motor synergies or primitives. Are such spinal modules observed in young mammals conserved into adulthood or altered? Conceivably, early circuit modules alter radically through experience and descending pathways' activity. We analyze lumbar motor patterns of intact adult rats and the same rats after spinal transection and compare these with adult rats spinal transected 5 days postnatally, before most motor experience, using only rats that never developed hind limb weight bearing. We use independent component analysis (ICA) to extract synergies from electromyography (EMG). ICA information-based methods identify both weakly active and strongly active synergies. We compare all spatial synergies and their activation/drive strengths as proxies of spinal modules and their underlying circuits. Remarkably, we find that spatial primitives/synergies of adult injured and neonatal injured rats differed insignificantly, despite different developmental histories. However, intact rats possess some synergies that differ significantly, although modestly, in spatial structure. Rats injured as adults were more similar in modularity to rats that had neonatal spinal transection than to themselves before injury. We surmise that spinal circuit modules for spatial synergy patterns may be determined early, before postnatal day 5 (P5), and remain largely unaltered by subsequent development or weight-bearing experience. An alternative explanation but equally important is that, after complete spinal transection, both neonatal and mature adult spinal cords rapidly converge to common synergy sets. This fundamental or convergent synergy circuitry, fully determined by P5, is revealed after spinal cord transection.motor primitives | muscle synergies | pattern generation | spinal cord injury | development M otor patterns can show significant modularity in legged vertebrates. Modularity can take several forms (1). Here, we examine modular motor drives in spinal systems. This approach combines both structural and functional neural components. The fundamental idea is that basic movement is largely composed of small numbers of synergies or motor primitives, which act as building blocks (1-5). Synergies for this study are defined as spatial synergies (1), which each represent a premotor drive to motor pools, causing covarying muscle activity in a specific balance. Such drives could arise from a well-defined neural substrate of sets of neurons with specific premotor connectivity. Indeed, some data in frogs and monkeys support this idea (6, 7). Such modularity could arise as follows: first, directly through evolutionarily determined processes in development; second, through plastic online optimizations during development; third, de novo during motor skill learning; or fourth, via some combinations of these (1,2,4,8). The collection of synergies resulting from any of these processes can form a library of compositional elements useful both for new movement con...

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Section: Discussionmentioning

confidence: 99%

Motor primitives are determined in early development and are then robustly conserved into adulthood

Yang

Logan

Giszter

2019

Proc. Natl. Acad. Sci. U.S.A.

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“…37 However, the participant pool represents a large range of walking functions and disability levels (EDSS score = 2.5-6.5), and measures of walking endurance and speed in the present study are similar to those previously reported for men and women with MS. 26,27 The medial gastrocnemius muscle was evaluated in the present study because of the critical role of this muscle in ambulation and its association with gait parameters. 38,39 Yet, note that many other lower extremity and trunk muscles contribute to ambulation, 39 and relationships between muscle function and walking ability may vary if assessed in different lower extremity muscles. In addition, muscle strength was evaluated during voluntary contractions, which can be influenced by both central and peripheral factors, so the observations related to strength cannot be solely attributed to peripheral mechanisms associated with skeletal muscle dysfunction.…”

Section: Discussionmentioning

confidence: 99%

Muscle Dysfunction and Walking Impairment in Women with Multiple Sclerosis

Willingham¹,

Backus²,

McCully³

2019

International Journal of MS Care

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Background: Recent evidence suggests that skeletal muscle dysfunction is involved in disability progression in people with multiple sclerosis (MS). However, the relationship between muscle dysfunction and walking impairments in MS remains unclear. Thus, the cross-sectional relationships between muscle-specific oxidative capacity and walking endurance in women with MS were evaluated. Methods: Twenty women with MS (11 African American, 9 white) were tested. Muscle oxidative capacity of the medial gastrocnemius was measured using near-infrared spectroscopy after electrical stimulation. Muscle endurance was evaluated using accelerometer-based mechanomyography during electrical stimulation. Muscle strength was measured during maximal voluntary plantarflexion using handheld dynamometry. Walking function was measured using the Timed 25-Foot Walk test and the 6-Minute Walk Test (6MWT). Results: Reduced muscle oxidative capacity (R2 = 0.68–0.71, P < .01) and muscle endurance (R2 = 0.59–0.78, P < .01) were associated with lower Timed 25-Foot Walk time and 6MWT distance. Muscle strength was weakly correlated to 6MWT distance (R2 = 0.21, P = .02). No differences in muscle function or clinical outcome measures were found between African American and white subgroups. Women with moderate-to-severe disability (Expanded Disability Status Scale [EDSS] score, 5.0–6.5) had significantly reduced muscle oxidative capacity, muscle endurance, and walking ability compared with women with mild disability (EDSS score, 2.5–4.5). Conclusions: Reductions in muscle function in people with MS are related to declines in walking function across all levels of disability. Muscle dysfunction is not differentially related to walking impairment in African American and white women with MS.

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“…Muscle synergies during walking are generally extracted from a few gait cycles ranging from 1 ( Steele et al, 2015 ; Lencioni et al, 2016 ) to 20 gait cycles ( Kim et al, 2016 ). In most cases, synergies are computed by averaging or concatenating around 10 gait cycles ( Ivanenko et al, 2003 , 2004 ; Monaco et al, 2010 ; Chvatal and Ting, 2012 ; Coscia et al, 2015 ; Haghpanah et al, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Intra-Subject Consistency during Locomotion: Similarity in Shared and Subject-Specific Muscle Synergies

Rimini

Agostini

Knaflitz

2017

Front. Hum. Neurosci.

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Human locomotion is a complex motor task. Previous research hypothesized that muscle synergies reflect the modular control of muscle groups operated by the Central Nervous System (CNS). Despite the high stride-to-stride variability characterizing human gait, most studies analyze only a few strides. This may be limiting, because the intra-subject variability of motor output is neglected. This gap could be filled by recording and analyzing many gait cycles during a single walking task. In this way, it can be investigated if CNS recruits the same muscle synergies consistently or if different strategies are adopted during the locomotion task. The aim of this work is to investigate the intra-subject consistency of muscle synergies during overground walking. Twelve young healthy volunteers were instructed to walk for 5 min at their natural pace. On the average, 181 ± 10 gait cycles were analyzed for each subject. Surface electromyography was recorded from 12 muscles of the dominant lower limb and the trunk. Gait cycles were grouped into subgroups containing 10 gait cycles each. The consistency of the muscle synergies extracted during the gait trial was assessed by measuring cosine similarity (CS) of muscle weights vectors, and zero-lag cross-correlation (CC) of activation signals. The average intra-subject CS and CC were 0.94 ± 0.10 and 0.96 ± 0.06, respectively. We found five synergies shared by all the subjects: high consistency values were found for these synergies (CS = 0.96 ± 0.05, CC = 0.97 ± 0.03). In addition, we found 10 subject-specific synergies. These synergies were less consistent (CS = 0.80 ± 0.20, CC = 0.89 ± 0.14). In conclusion, our results demonstrated that shared muscle synergies were highly consistent during walking. Subject-specific muscle synergies were also consistent, although to a lesser extent.

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Are Modular Activations Altered in Lower Limb Muscles of Persons with Multiple Sclerosis during Walking? Evidence from Muscle Synergies and Biomechanical Analysis

Cited by 44 publications

References 72 publications

Motor primitives are determined in early development and are then robustly conserved into adulthood

Motor primitives are determined in early development and are then robustly conserved into adulthood

Muscle Dysfunction and Walking Impairment in Women with Multiple Sclerosis

Intra-Subject Consistency during Locomotion: Similarity in Shared and Subject-Specific Muscle Synergies

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