Locomotor patterns in cerebellar ataxia

Several studies have demonstrated how cerebellar ataxia (CA) affects gait, resulting in deficits in multijoint coordination and stability. Nevertheless, how lesions of cerebellum influence the locomotor muscle pattern generation is still unclear. To better understand the effects of CA on locomotor output, here we investigated the idiosyncratic features of the spatiotemporal structure of leg muscle activity and impairments in the biomechanics of CA gait. To this end, we recorded the electromyographic (EMG) activity of 12 unilateral lower limb muscles and analyzed kinematic and kinetic parameters of 19 ataxic patients and 20 age-matched healthy subjects during overground walking. Neuromuscular control of gait in CA was characterized by a considerable widening of EMG bursts and significant temporal shifts in the center of activity due to overall enhanced muscle activation between late swing and mid-stance. Patients also demonstrated significant changes in the intersegmental coordination, an abnormal transient in the vertical ground reaction force and instability of limb loading at heel strike. The observed abnormalities in EMG patterns and foot loading correlated with the severity of pathology [International Cooperative Ataxia Rating Scale (ICARS), a clinical ataxia scale] and the changes in the biomechanical output. The findings provide new insights into the physiological role of cerebellum in optimizing the duration of muscle activity bursts and the control of appropriate foot loading during locomotion.

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Changes in Muscle Activity in Response to Different Impact Forces Affect Soft Tissue Compartment Mechanical Properties

Journal of Biomechanical Engineering ◽

10.1115/1.2746384 ◽

2006 ◽

Vol 129 (4) ◽

pp. 594-602 ◽

Cited By ~ 27

Author(s):

Katherine A. Boyer ◽

Benno M. Nigg

Keyword(s):

Mechanical Properties ◽

Soft Tissue ◽

Muscle Activity ◽

Muscle Activation ◽

Joint Stiffness ◽

Heel Strike ◽

Emg Activity ◽

Tissue Compartment ◽

Tissue Compartments ◽

The Impact

Electromyographic (EMG) activity is associated with several tasks prior to landing in walking and running including positioning the leg, developing joint stiffness and possibly control of soft tissue compartment vibrations. The concept of muscle tuning suggests one reason for changes in muscle activity pattern in response to small changes in impact conditions, if the frequency content of the impact is close to the natural frequency of the soft tissue compartments, is to minimize the magnitude of soft tissue compartment vibrations. The mechanical properties of the soft tissue compartments depend in part on muscle activations and thus it was hypothesized that changes in the muscle activation pattern associated with different impact conditions would result in a change in the acceleration transmissibility to the soft tissue compartments. A pendulum apparatus was used to systematically administer impacts to the heel of shod male participants. Wall reaction forces, EMG of selected leg muscles, soft tissue compartment and shoe heel cup accelerations were quantified for two different impact conditions. The transmissibility of the impact acceleration to the soft tissue compartments was determined for each subject/soft tissue compartment/shoe combination. For this controlled impact situation it was shown that changes in the damping properties of the soft tissue compartments were related to changes in the EMG intensity and/or mean frequency of related muscles in response to a change in the impact interface conditions. These results provide support for the muscle tuning idea—that one reason for the changes in muscle activity in response to small changes in the impact conditions may be to minimize vibrations of the soft tissue compartments that are initiated at heel-strike.

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Backward walking highlights gait asymmetries in children with cerebral palsy

Journal of Neurophysiology ◽

10.1152/jn.00679.2017 ◽

2018 ◽

Vol 119 (3) ◽

pp. 1153-1165 ◽

Cited By ~ 12

Author(s):

Germana Cappellini ◽

Francesca Sylos-Labini ◽

Michael J. MacLellan ◽

Annalisa Sacco ◽

Daniela Morelli ◽

...

Keyword(s):

Cerebral Palsy ◽

Muscle Activation ◽

Pattern Generation ◽

Comprehensive Assessment ◽

Emg Activity ◽

Backward Walking ◽

Spinal Circuitry ◽

Children With Cerebral Palsy ◽

Control Circuits ◽

The Brain

To investigate how early injuries to developing motor regions of the brain affect different forms of gait, we compared the spatiotemporal locomotor patterns during forward (FW) and backward (BW) walking in children with cerebral palsy (CP). Bilateral gait kinematics and EMG activity of 11 pairs of leg muscles were recorded in 14 children with CP (9 diplegic, 5 hemiplegic; 3.0–11.1 yr) and 14 typically developing (TD) children (3.3–11.8 yr). During BW, children with CP showed a significant increase of gait asymmetry in foot trajectory characteristics and limb intersegmental coordination. Furthermore, gait asymmetries, which were not evident during FW in diplegic children, became evident during BW. Factorization of the EMG signals revealed a comparable structure of the motor output during FW and BW in all groups of children, but we found differences in the basic temporal activation patterns. Overall, the results are consistent with the idea that both forms of gait share pattern generation control circuits providing similar (though reversed) kinematic patterns. However, BW requires different muscle activation timings associated with muscle modules, highlighting subtle gait asymmetries in diplegic children, and thus provides a more comprehensive assessment of gait pathology in children with CP. The findings suggest that spatiotemporal asymmetry assessments during BW might reflect an impaired state and/or descending control of the spinal locomotor circuitry and can be used for diagnostic purposes and as complementary markers of gait recovery.NEW & NOTEWORTHY Early injuries to developing motor regions of the brain affect both forward progression and other forms of gait. In particular, backward walking highlights prominent gait asymmetries in children with hemiplegia and diplegia from cerebral palsy and can give a more comprehensive assessment of gait pathology. The observed spatiotemporal asymmetry assessments may reflect both impaired supraspinal control and impaired state of the spinal circuitry.

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Muscle Activity as a Releasing Factor for Pain in the Shoulder and Neck

Cephalalgia ◽

10.1177/0333102499019s2501 ◽

1999 ◽

Vol 19 (25_suppl) ◽

pp. 1-8 ◽

Cited By ~ 27

Author(s):

RH Westgaard

Keyword(s):

Muscle Activity ◽

Muscle Activation ◽

Experimental Situation ◽

Activity Patterns ◽

Trapezius Muscle ◽

Emg Activity ◽

Occupational Setting ◽

Autonomic Activation ◽

Pain Symptoms ◽

Vocational Studies

In this review, the evidence for trapezius muscle activity as a releasing factor for shoulder and neck pain is considered, mainly on the basis of studies in our laboratory. Two lines of evidence are produced, (i) vocational studies in an occupational setting, where muscle activity pattern is recorded by surface EMG and a clinical examination of the shoulder region of the subjects performed; and (ii) laboratory studies where muscle activity patterns and pain development are recorded in an experimental situation with mental stress and minimal physical activity. The vocational studies demonstrate pain development in the shoulder and neck despite very low muscle activity recorded, making it very difficult to assume muscular involvement for all cases with such complaints. However, the hypothesis of pain development through overexertion of a subpopulation of low-threshold motor units also makes it difficult to draw a firm negative conclusion. The laboratory experiments, on the other hand, show that trapezius activity patterns in response to stress have many features that would be expected if muscle activation induces pain symptoms. It is further noted that the trapezius is the only muscle with activity patterns that show these features. Possibly, we observe the effects of parallel physiological phenomena, e.g., a systemic autonomic activation that induces pain symptoms and also facilitates the motor response of some muscles. Evidence of autonomic activation of trapezius is presented by the observation of low-level, rhythmic EMG activity during sleep. However, this is not firm evidence for the above hypothesis, which at present best serves as a basis for further experimentation.

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Individuals with medial knee osteoarthritis show neuromuscular adaptation when perturbed during walking despite functional and structural impairments

Journal of Applied Physiology ◽

10.1152/japplphysiol.00244.2013 ◽

2014 ◽

Vol 116 (1) ◽

pp. 13-23 ◽

Cited By ~ 14

Author(s):

Deepak Kumar ◽

Charles (Buz) Swanik ◽

Darcy S. Reisman ◽

Katherine S. Rudolph

Keyword(s):

Knee Osteoarthritis ◽

Muscle Activation ◽

Weight Bearing ◽

Joint Space Width ◽

Neuromuscular Control ◽

Emg Activity ◽

Initial Contact ◽

Knee Motion ◽

Quadriceps Weakness ◽

Knee Oa

Neuromuscular control relies on sensory feedback that influences responses to changing external demands, and the normal response is for movement and muscle activation patterns to adapt to repeated perturbations. People with knee osteoarthritis (OA) are known to have pain, quadriceps weakness, and neuromotor deficits that could affect adaption to external perturbations. The aim of this study was to analyze neuromotor adaptation during walking in people with knee OA ( n = 38) and controls ( n = 23). Disability, quadriceps strength, joint space width, malalignment, and proprioception were assessed. Kinematic and EMG data were collected during undisturbed walking and during perturbations that caused lateral translation of the foot at initial contact. Knee excursions and EMG magnitudes were analyzed. Subjects with OA walked with less knee motion and higher muscle activation and had greater pain, limitations in function, quadriceps weakness, and malalignment, but no difference was observed in proprioception. Both groups showed increased EMG and decreased knee motion in response to the first perturbation, followed by progressively decreased EMG activity and increased knee motion during midstance over the first five perturbations, but no group differences were observed. Over 30 trials, EMG levels returned to those of normal walking. The results illustrate that people with knee OA respond similarly to healthy individuals when exposed to challenging perturbations during functional weight-bearing activities despite structural, functional, and neuromotor impairments. Mechanisms underlying the adaptive response in people with knee OA need further study.

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Changes in Locomotor Muscle Activity After Treadmill Training in Subjects With Incomplete Spinal Cord Injury

Journal of Neurophysiology ◽

10.1152/jn.91131.2008 ◽

2009 ◽

Vol 101 (2) ◽

pp. 969-979 ◽

Cited By ~ 57

Author(s):

Monica A. Gorassini ◽

Jonathan A. Norton ◽

Jennifer Nevett-Duchcherer ◽

Francois D. Roy ◽

Jaynie F. Yang

Keyword(s):

Spinal Cord ◽

Spinal Cord Injury ◽

Muscle Activity ◽

Muscle Activation ◽

Treadmill Training ◽

Emg Activity ◽

Incomplete Spinal Cord Injury ◽

Activation Patterns ◽

Muscle Activation Patterns ◽

Cord Injury

Intensive treadmill training after incomplete spinal cord injury can improve functional walking abilities. To determine the changes in muscle activation patterns that are associated with improvements in walking, we measured the electromyography (EMG) of leg muscles in 17 individuals with incomplete spinal cord injury during similar walking conditions both before and after training. Specific differences were observed between subjects that eventually gained functional improvements in overground walking (responders), compared with subjects where treadmill training was ineffective (nonresponders). Although both groups developed a more regular and less clonic EMG pattern on the treadmill, it was only the tibialis anterior and hamstring muscles in the responders that displayed increases in EMG activation. Likewise, only the responders demonstrated decreases in burst duration and cocontraction of proximal (hamstrings and quadriceps) muscle activity. Surprisingly, the proximal muscle activity in the responders, unlike nonresponders, was three- to fourfold greater than that in uninjured control subjects walking at similar speeds and level of body weight support, suggesting that the ability to modify muscle activation patterns after injury may predict the ability of subjects to further compensate in response to motor training. In summary, increases in the amount and decreases in the duration of EMG activity of specific muscles are associated with functional recovery of walking skills after treadmill training in subjects that are able to modify muscle activity patterns following incomplete spinal cord injury.

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Patterns of muscle activity for digital coarticulation

Journal of Neurophysiology ◽

10.1152/jn.00973.2012 ◽

2013 ◽

Vol 110 (1) ◽

pp. 230-242 ◽

Cited By ~ 16

Author(s):

Sara A. Winges ◽

Shinichi Furuya ◽

Nathaniel J. Faber ◽

Martha Flanders

Keyword(s):

Time Course ◽

Muscle Activation ◽

Motor Pattern ◽

Hand Movement ◽

Time Frame ◽

Pattern Generation ◽

Emg Activity ◽

Key Press ◽

Basic Features ◽

Piano Playing

Although piano playing is a highly skilled task, basic features of motor pattern generation may be shared across tasks involving fine movements, such as handling coins, fingering food, or using a touch screen. The scripted and sequential nature of piano playing offered the opportunity to quantify the neuromuscular basis of coarticulation, i.e., the manner in which the muscle activation for one sequential element is altered to facilitate production of the preceding and subsequent elements. Ten pianists were asked to play selected pieces with the right hand at a uniform tempo. Key-press times were recorded along with the electromyographic (EMG) activity from seven channels: thumb flexor and abductor muscles, a flexor for each finger, and the four-finger extensor muscle. For the thumb and index finger, principal components of EMG waveforms revealed highly consistent variations in the shape of the flexor bursts, depending on the type of sequence in which a particular central key press was embedded. For all digits, the duration of the central EMG burst scaled, along with slight variations across subjects in the duration of the interkeystroke intervals. Even within a narrow time frame (about 100 ms) centered on the central EMG burst, the exact balance of EMG amplitudes across multiple muscles depended on the nature of the preceding and subsequent key presses. This fails to support the idea of fixed burst patterns executed in sequential phases and instead provides evidence for neuromuscular coarticulation throughout the time course of a hand movement sequence.

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Posture effects on timing of abdominal muscle activity during stimulated ventilation

Journal of Applied Physiology ◽

10.1152/jappl.1999.86.6.1994 ◽

1999 ◽

Vol 86 (6) ◽

pp. 1994-2000 ◽

Cited By ~ 8

Author(s):

Tadashi Abe ◽

Takumi Yamada ◽

Tomoyuki Tomita ◽

Paul A. Easton

Keyword(s):

Muscle Activity ◽

Muscle Activation ◽

Moving Average ◽

Abdominal Muscle ◽

Transversus Abdominis ◽

Emg Activity ◽

Abdominal Muscles ◽

External Oblique ◽

End Tidal ◽

Internal Oblique

In humans during stimulated ventilation, substantial abdominal muscle activity extends into the following inspiration as postexpiratory expiratory activity (PEEA) and commences again during late inspiration as preexpiratory expiratory activity (PREA). We hypothesized that the timing of PEEA and PREA would be changed systematically by posture. Fine-wire electrodes were inserted into the rectus abdominis, external oblique, internal oblique, and transversus abdominis in nine awake subjects. Airflow, end-tidal CO2, and moving average electromyogram (EMG) signals were recorded during resting and CO2-stimulated ventilation in both supine and standing postures. Phasic expiratory EMG activity (tidal EMG) of the four abdominal muscles at any level of CO2 stimulation was greater while standing. Abdominal muscle activities during inspiration, PEEA, and PREA, were observed with CO2stimulation, both supine and standing. Change in posture had a significant effect on intrabreath timing of expiratory muscle activation at any level of CO2stimulation. The transversus abdominis showed a significant increase in PEEA and a significant decrease in PREA while subjects were standing; similar changes were seen in the internal oblique. We conclude that changes in posture are associated with significant changes in phasic expiratory activity of the four abdominal muscles, with systematic changes in the timing of abdominal muscle activity during early and late inspiration.

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Consequences of biomechanically constrained tasks in the design and interpretation of synergy analyses

Journal of Neurophysiology ◽

10.1152/jn.00769.2013 ◽

2015 ◽

Vol 113 (7) ◽

pp. 2102-2113 ◽

Cited By ~ 45

Author(s):

Katherine M. Steele ◽

Matthew C. Tresch ◽

Eric J. Perreault

Keyword(s):

Matrix Factorization ◽

Muscle Activity ◽

Neural Control ◽

Muscle Activation ◽

Neuromuscular Control ◽

Task Constraints ◽

Factorization Algorithms ◽

Low Dimensional ◽

Or Task ◽

And Task

Matrix factorization algorithms are commonly used to analyze muscle activity and provide insight into neuromuscular control. These algorithms identify low-dimensional subspaces, commonly referred to as synergies, which can describe variation in muscle activity during a task. Synergies are often interpreted as reflecting underlying neural control; however, it is unclear how these analyses are influenced by biomechanical and task constraints, which can also lead to low-dimensional patterns of muscle activation. The aim of this study was to evaluate whether commonly used algorithms and experimental methods can accurately identify synergy-based control strategies. This was accomplished by evaluating synergies from five common matrix factorization algorithms using muscle activations calculated from 1) a biomechanically constrained task using a musculoskeletal model and 2) without task constraints using random synergy activations. Algorithm performance was assessed by calculating the similarity between estimated synergies and those imposed during the simulations; similarities ranged from 0 (random chance) to 1 (perfect similarity). Although some of the algorithms could accurately estimate specified synergies without biomechanical or task constraints (similarity >0.7), with these constraints the similarity of estimated synergies decreased significantly (0.3–0.4). The ability of these algorithms to accurately identify synergies was negatively impacted by correlation of synergy activations, which are increased when substantial biomechanical or task constraints are present. Increased variability in synergy activations, which can be captured using robust experimental paradigms that include natural variability in motor activation patterns, improved identification accuracy but did not completely overcome effects of biomechanical and task constraints. These results demonstrate that a biomechanically constrained task can reduce the accuracy of estimated synergies and highlight the importance of using experimental protocols with physiological variability to improve synergy analyses.

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Vision fine-tunes preparation for landing in the cane toad, Rhinella marina

Biology Letters ◽

10.1098/rsbl.2018.0397 ◽

2018 ◽

Vol 14 (9) ◽

pp. 20180397 ◽

Cited By ~ 1

Author(s):

Laura J. Ekstrom ◽

Chris Panzini ◽

Gary B. Gillis

Keyword(s):

Muscle Activity ◽

Muscle Activation ◽

Activity Patterns ◽

Fine Tuning ◽

Emg Activity ◽

Activation Patterns ◽

Muscle Activation Patterns ◽

Impact Forces ◽

Before And After ◽

The Impact

In toad hopping, the hindlimbs generate the propulsive force for take-off while the forelimbs resist the impact forces associated with landing. Preparing to perform a safe landing, in which impact forces are managed appropriately, likely involves the integration of multiple types of sensory feedback. In toads, vestibular and/or proprioceptive feedback is critical for coordinated landing; however, the role of vision remains unclear. To clarify this, we compare pre-landing forelimb muscle activation patterns before and after removing vision. Specifically, we recorded EMG activity from two antagonistic forelimb muscles, the anconeus and coracoradialis, which demonstrate distance-dependent onset timing and recruitment intensity, respectively. Toads were first recorded hopping normally and then again after their optic nerves were severed to remove visual feedback. When blind, toads exhibited hop kinematics and pre-landing muscle activity similar to when sighted. However, distance-dependent relationships for muscle activity patterns were more variable, if present at all. This study demonstrates that blind toads are still able to perform coordinated landings, reinforcing the importance of proprioceptive and/or vestibular feedback during hopping. But the increased variability in distance-dependent activity patterns indicates that vision is more responsible for fine-tuning the motor control strategy for landing.

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Neuromuscular control of anguilliform locomotion: patterns of red and white muscle activity during swimming in the american eel anguilla rostrata

Journal of Experimental Biology ◽

10.1242/jeb.201.23.3245 ◽

1998 ◽

Vol 201 (23) ◽

pp. 3245-3256 ◽

Cited By ~ 18

Author(s):

G. B. Gillis

Keyword(s):

Swimming Speed ◽

Muscle Activity ◽

White Muscle ◽

Neuromuscular Control ◽

Emg Activity ◽

Anguilla Rostrata ◽

Significant Shift ◽

Muscle Strain ◽

Body Form ◽

Red Muscle

Two areas that have received substantial attention in investigations of muscle activity during fish swimming are (1) patterns of fiber type recruitment with swimming speed and (2) the timing of muscle activation in relation to muscle strain. Currently, very little is known about either of these areas in eels, which represent an extreme body form among fishes and utilize a mode of locomotion found at one end of the undulatory spectrum(anguilliform locomotion). To assess how this swimming mode and body form influence the neuromuscular control of swimming, I recorded electromyographic data from red and white muscle at four positions, 0.3L,0.45L, 0.6L and 0.75L, where L is body length, in eels (Anguilla rostrata)simultaneously video-taped (250 fields s-1) swimming at three speeds, 0.5,0.75 and 1.0 L s-1. As in other fish, exclusively red muscle is used at slow swimming speeds and white muscle is additionally recruited at higher swimming speeds. However, this study also revealed a novel posterior-to-anterior pattern of muscle recruitment with increasing swimming speed. At slow speeds, anteriorly located muscles are never active, muscle strain is negligible and forward thrust must be generated by posterior muscles. As speed increases, more anterior muscles are additionally recruited. Electromyogram (EMG) burst durations typically occupy between 0.2 and 0.3 undulatory cycles, irrespective of speed or position. EMG burst intensity increases significantly with swimming speed. The onset of EMG activity typically occurred near the end of muscle lengthening, whereas the offset of EMG activity occurred during shortening(typically before the muscle's return to resting length). There was a significant shift in red muscle onset times such that anterior muscles were typically active later in their strain cycle than posterior muscles. When red muscle activity patterns across various fish taxa are compared,differences in propulsive wavelength among species are related to differences in muscle activity, providing insight into the underlying neuromuscular bases of differences among undulatory swimming modes.

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