Your search keyword '"Biceps femoris"' showing total 135 results

1. Intramuscular and intermuscular coherence analysis while obstacle crossing during treadmill gait.

Author

Wen, Lin, Watanabe, Tatsunori, Iwamoto, Yoshitaka, Ishii, Yosuke, Miyoshi, Fumiya, Shiraishi, Kanako, Date, Shota, Siu, Ka-Chun, Kirimoto, Hikari, and Takahashi, Makoto

Subjects

*BICEPS femoris, *FLEXOR muscles, *TIBIALIS anterior, *MOTOR unit, KNEE muscles

Abstract

Purpose: This study aimed to identify the contribution of the common synaptic drives to motor units during obstacle avoidance, using coherence analysis between a-pair electromyography (EMG) signals (EMG-EMG coherence). Materials and Methods: Fourteen healthy volunteers walked on a treadmill with and without obstacle avoidance. During obstacle gait, subjects were instructed to step over an obstacle with their right leg while walking that would randomly and unpredictably appear. Surface EMG signals were recorded from the following muscles of the right leg: the proximal and distal ends of tibialis anterior (TAp and TAd), biceps femoris (BF), semitendinosus (ST), lateral gastrocnemius (LG), and medial gastrocnemius (MG). Beta-band (13–30 Hz) EMG-EMG coherence was analysed. Results: Beta-band EMG-EMG coherence of TAp-TAd during swing phase and BF-ST during pre and initial swing phase when stepping over an obstacle were significantly higher compared to normal gait (both p < 0.05). Beta-band EMG-EMG coherence of TAp-TAd, BF-ST, and LG-MG during stance phase were not significantly different between the two gait conditions (all p > 0.05). Conclusions: The present findings suggest increased common synaptic drives to motor units in ankle dorsiflexor and knee flexor muscles during obstacle avoidance. It also may reflect an increased cortical contribution to modify the gait patterns to avoid an obstacle. [ABSTRACT FROM AUTHOR]

Published

2024

2. Changes in Motor Strategy and Neuromuscular Control During Balance Tasks in People with a Bimalleolar Ankle Fracture: A Preliminary and Exploratory Study.

Author

Salas-Gómez, Diana, Barbado, David, Sánchez-Juan, Pascual, Pérez-Núñez, María Isabel, Laguna-Bercero, Esther, Lantarón-Juarez, Saray, and Fernandez-Gorgojo, Mario

Subjects

*DYNAMIC balance (Mechanics), *ANKLE fractures, *BICEPS femoris, *TIBIALIS anterior, *BALANCE disorders, *ANKLE

Abstract

Ankle fractures can lead to issues such as limited dorsiflexion, strength deficits, swelling, stiffness, balance disorders, and functional limitations, which complicate daily activities. This study aimed to describe neuromuscular adaptations at 6 and 12 months post-surgery during static and dynamic balance tasks, specifically using the Y-Balance Test (YBT). Additionally, the relationship between neuromuscular patterns, balance, and musculoskeletal deficits was evaluated. In 21 participants (14 at 6 months and 21 at 12 months) with bimalleolar fractures, hip strength, ankle dorsiflexion, ankle functionality, and static and dynamic balance were assessed using electromyography of five lower limb muscles (tibialis anterior, peroneus longus, lateral gastrocnemius, biceps femoris, and gluteus medius). A significant interaction effect (limb × proximal [hip]—distal [ankle] muscle) (F = 30.806, p < 0.001) was observed in the anterior direction of the Y-Balance Test (YBTA) at 6 months post-surgery. During the YBTA and YBT posteromedial (YBTPM), it was found that a lower dorsiflexion range of movement was associated specifically at 6 months with greater activation of the lateral gastrocnemius. However, these differences tended to diminish by 12 months. These findings suggest that neuromuscular patterns differ between operated and non-operated limbs during the YBTA at 6 months post-surgery. The Y-Balance Test, particularly its anterior direction, effectively highlighted these neuromuscular changes. This is a preliminary study; further research is needed to explore these findings in depth. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of foot type on electromyography characteristics and synergy of lower limb muscles during running.

Author

Hajilou, Behrouz, Esmaeili, Hamed, and Anbarian, Mehrdad

Subjects

*RUNNING speed, *BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior, *CENTRAL nervous system, *MUSCLES

Abstract

The foot structure is associated with different running mechanics. The central nervous system is responsible for using the muscles through synergies during locomotion. The purpose of the present study was to examine the effect of foot structure on the electromyography factors and the synergy of the selected muscles of the lower extremity. Tibialis anterior, extensor digitorum longus, peroneus longus, soleus, biceps femoris, vastus lateralis, gastrocnemius lateralis and medialis muscles activity of 60 barefoot recreational runners with different foot structures was recorded while running at a speed of 3.3 m/s. Muscle activity was measured in the running cycle. Besides, muscle synergies were extracted using non-negative matrix factorization algorithm. The results showed that there were differences between groups with different foot type in muscle activity under different phases of running in some muscles. Furthermore, the findings indicated that the number of synergies was similar in different groups and the relative weight of muscles was not different across groups. In conclusion, despite the difference in muscle activity under different phases of the running cycle, muscle synergies are similar among the groups. This can indicate similar control by the central nervous system in runners with different arch structures while running and the observed changes in muscle activity can be attributed to the type of forces exerted on the body, the length-tension relationship, and changes in the direction of the lower limbs in people with different arch structures. [ABSTRACT FROM AUTHOR]

Published

2024

4. Ballet practice improves neuromuscular and biomechanical responses to an unexpected standing-slip in older adults.

Author

Simpkins, Caroline and Yang, Feng

Subjects

*BALLET dancers, *LEG muscles, *TIBIALIS anterior, *BICEPS femoris, *RECTUS femoris muscles

Abstract

Falls and fall-induced injuries are common and consequential in older adults. Ballet emphasizes full-body coordination, leg strength, and postural control. However, it remains unknown whether ballet can indeed reduce falls in older adults. This study examined biomechanical and neuromuscular responses of older recreational ballet dancers to an unexpected standing-slip. Twenty older ballet dancers (17 females, 3 males) and 23 age- and sex-matched nondancers (19 females, 4 males) were exposed to an unexpected slip during treadmill standing. The slip-faller rate was the primary outcome. The secondary outcomes were kinematic measurements, including dynamic gait stability, slip distance, and recovery stepping performance (step latency, duration, length, and speed). The tertiary outcome was the electromyography latency of leg muscles (bilateral tibialis anterior, medial gastrocnemius, rectus femoris, and biceps femoris). Fewer dancers fell than nondancers after the standing-slip (45% vs. 83%, P = 0.005, d = 0.970). Dancers displayed better stability at recovery foot liftoff (P = 0.006) and touchdown (P = 0.012), a shorter step latency (P = 0.020), shorter step duration (P = 0.011), faster step speed (P = 0.032), and shorter slip distance (P = 0.015) than nondancers. They also exhibited shorter latencies than nondancers for the standing leg rectus femoris (P = 0.028) and tibialis anterior (P = 0.002), and the stepping leg biceps femoris (P = 0.031), tibialis anterior (P = 0.017), and medial gastrocnemius (P = 0.030). The results suggest that older ballet dancers experience a lower fall risk and are more stable than nondancers following an unexpected standing-slip. The greater stability among dancers could be attributed to more biomechanically effective recovery stepping, possibly associated with the ballet-induced neuromuscular benefit—an earlier leg muscle activation. NEW & NOTEWORTHY: This is the first study to examine how older ballet dancers respond to an unexpected external slip perturbation while standing. The results suggest that older ballet dancers experience a reduced fall risk after the slip than their nondancer counterparts. The lower fall risk can be accounted for by dancers' quicker neuromuscular reactions to the slip that result in a more effective recovery step and thus higher stability against backward falls due to the slip. [ABSTRACT FROM AUTHOR]

Published

2024

5. Automatic gait evoking in healthy adults through Vojta's peripheric somatosensory stimulation: a double-blind randomized controlled trial.

Author

Perales-López, Luis, Sanz-Esteban, Ismael, Jiménez-Antona, Camen, Serrano, J. Ignacio, San-Martín-Gómez, Ana, Vives-Gelabert, Xisca, and Cano-de-la-Cuerda, Roberto

Subjects

*BICEPS femoris, *RECTUS femoris muscles, *ROOT-mean-squares, *TIBIALIS anterior, *RANDOMIZED controlled trials, *ANKLE

Abstract

Background: To study the effects of different interventions on automatic gait processing in contrast with voluntary gait processing in healthy subjects. Methods: A double-blind randomised controlled trial was designed (120 able-body persons between 18 and 65 years old entered and completed the study), with pre-intervention and post-intervention assessments using the 6-Minute Walk Test (6MWT). The participants were randomly distributed into four groups. Prior to intervention, all participants performed voluntary gait on the ground (VoG) in a calibrated circuit following the 6MWT. The presence of automatic gait (AG) was explored post-intervention without a voluntary demand in the same circuit following the 6MWT. Each group received a different intervention for 30 min: Vojta stimulation, MOTOMED® at no less than 60 revolutions/minute, treadmill walking at 3 km/h, and resting in a chair (control). The main assessment, conducted by a blinded rater, was the difference in distance covered (in meters) during the 6MWT between pre- and post-intervention. Surface electromyography (sEMG) average root mean square (RMS) signals in the right tibialis anterior, right soleus, right rectus femoris, and right biceps femoris were also considered outcome measures. Results: The Vojta group was the only one that initiated AG after the intervention (476.4 m ± 57.1 in VoG versus 9.0 m ± 8.9 in AG, p < 0.001) with comparable kinematics and EMG parameters during voluntary gait, except for ankle dorsal flexion. Within the Vojta group, high variability in kinematics, sEMG activity, and distance covered was observed. Conclusions: AG isolation is approachable through Vojta at only one session measurable with the 6MWT without any voluntary gait demand. No automatic gait effects were observed post-intervention in the other groups. Trial registration: NCT04689841 (ClinicalTrials.gov). [ABSTRACT FROM AUTHOR]

Published

2024

6. Light weights are as effective as heavy weights for muscle activation in the Hammerobics exercise.

Author

Murofushi, Koji, Oshikawa, Tomoki, Kaneoka, Koji, Akuzawa, Hiroshi, Mitomo, Sho, Hatano, Genki, Furuya, Hidetaka, Hirohata, Kenji, and Yagishita, Kazuyoshi

Subjects

*BICEPS femoris, *TIBIALIS anterior, *ELECTROMYOGRAPHY, *REHABILITATION, *RECTUS femoris muscles, *PLASTICS

Abstract

Purpose: We previously reported that a Hammerobics exercise using weights can enhance trunk and lower extremity muscles, some studies suggested that training effects could also be expected without heavy weights. If the muscle activity induced by Hammerobics swinging with a 'light plastic ball' equals or surpasses that of the isometric static squat and synchronized squat with a heavy ball, this training approach could alleviate joint strain, fostering an exercise regimen universally accessible across generations, benefit for workouts sports and rehabilitation. Methods: Fifteen healthy men participated in this study. By using surface electromyography, muscle activities for the abductor hallucis, tibialis anterior, tibialis posterior, peroneus longus, rectus femoris, biceps femoris long head, semitendinosus, gluteus maximus, multifidus, and internal oblique muscles were measured during a light Hammerobics synchronized squat (HSS-light), Hammerobics synchronized squat, and conventional isometric squat, and statistically compared. Results: The front-to-back tibialis anterior activity of HSS-light was significantly higher than that of conventional isometric squat. The activities of all other muscles, except for the multifidus, were not significantly different between these exercises in the front-to-back and back-to-front phases. Compared to the Hammerobics synchronized squat, the light Hammerobics synchronized squat showed no differences in front-to-back tibialis anterior, rectus femoris, biceps femoris long head, and internal oblique activities and back-to-front abductor hallucis, tibialis anterior, rectus femoris, and internal oblique activities. Conclusion: The HSS-light could stimulate muscles to the same level as the conventional isometric squat without weight bearing. While the HSS-light was less effective than the Hammerobics synchronized squat, there was no significant difference in internal oblique, rectus femoris, and tibialis anterior activities between these exercises. Hence, the HSS-light is an exercise method that can be viable approach to promoting accessible workouts sports and rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2024

7. Drumming performance and underlying muscle activities in a professional rock drummer with lower-limb dystonia: a case study.

Author

Kazuaki Honda, Shizuka Sata, Mizuki Komine, Satoshi Yamaguchi, SungHyek Kim, Makio Kashino, and Shinya Fujii

Subjects

FINE motor ability, FOCAL dystonia, DRUM set, BICEPS femoris, TIBIALIS anterior

Abstract

Task-specific focal dystonia (TSFD), characterized by the loss of fine motor control and coordination, affects drummers' lower-limb movements. This study explores lower-limb dystonia's impact on drumming performance and underlying muscle activity in a professional rock drummer. The drummer executed an eight-beat pattern on a drum kit. The participant reported the occurrence of symptoms when he felt the abnormality such as the loss of control related to involuntary aspects of movement. We measured the peak amplitude of the bass drumhead vibration, synchronization errors as the time elapsed between the metronome onset and the bass drum onset, and amplitude of electromyographic (EMG) recordings centered on metronome beat. Dystonia symptoms primarily manifested in the initial beat, with fewer symptoms on syncopation of the third beat. Analysis revealed decreased bass-drum peak amplitude and earlier synchronization error during the initial beat. EMG measurements of 10 muscles in the affected right lower limb showed significant changes in the Biceps Femoris (BF), Tibialis Anterior (TA), Extensor Digitorum Longus (EDL), and Extensor Digitorum Brevis (EDB) muscles during symptom onset. We observed (1) earlier overactivation of the TA and EDL muscles during the leg lift-up motion or preparatory phase of pedaling, (2) reduced activation of the EDB muscle, and (3) increased activation of the BF muscle during the final pedaling movement when symptoms occurred. These findings suggest that lower-limb dystonia symptoms are characterized by a reduction in amplitude of the bass drumhead vibration and an increase in synchronization error, potentially due to premature overactivation of the ankle dorsiflexor muscles. [ABSTRACT FROM AUTHOR]

Published

2024

8. Muscle activation in the lower limb muscles in individuals with dynamic knee valgus during single-leg and overhead squats: a meta-analysis study.

Author

Khou, Shima Bakhtiari, Saki, Farzaneh, and Tahayori, Behdad

Subjects

*KEYWORD searching, *BICEPS femoris, *VASTUS medialis, *VASTUS lateralis, *TIBIALIS anterior

Abstract

Background: Dynamic knee valgus (DKV) is a risk factor for non-contact anterior cruciate ligament (ACL) injuries. Understanding the changes in the electromyographic activity of the lower extremity muscles in individuals with DKV helps trainers design ACL injury prevention exercises. Therefore, the present meta-analysis aimed to investigate the muscle activation of the lower limb muscles in individuals with DKV during single-leg and overhead squats. Methods: Articles with titles, abstracts, and full texts were searched and screened independently by two reviewers in the Web of Science, Scopus, PubMed, and Google Scholar databases, without restrictions on publication date and in English using specified keywords from their inception to January 5, 2024. The quality of articles was evaluated using a modified version of the Downs and Black quality checklist. This meta-analysis used mean difference (MD) to compare the muscle activity patterns between individual with DKV and healthy individuals. Heterogeneity was detected using I-square (I2) test. Results: In total, four papers with 130 participants were included in the study. Evidence showed a significant difference between the DKV group and the healthy group regarding the activities of the adductor magnus (MD: 6.25, P < 0.001), vastus medialis (MD: 13.23, P = 0.002), vastus lateralis (MD: 11.71, P = 0.004), biceps femoris (MD: 3.06, P = 0.003), and tibialis anterior muscles (MD: 8.21, P = 0.02). Additionally, muscle activity in the DKV group was higher than that in the healthy group. Conclusions: This meta-analysis reveals distinct muscle activation patterns in individuals with dynamic knee valgus (DKV), with increased activity in key muscles suggesting compensatory responses. These findings underscore the need for targeted rehabilitation to address muscle imbalances and improve knee stability. [ABSTRACT FROM AUTHOR]

Published

2024

9. Comparative Electromyographic Analysis in Leg Press of Traditional Fitness Equipment, Traditional Outdoor Fitness Equipment, and a New Model of Outdoor Fitness Equipment in Trained Young Men.

Author

Abelleira-Lamela, Tomás, Marcos-Pardo, Pablo Jorge, Abraldes, José Arturo, González-Gálvez, Noelia, Espeso-García, Alejandro, Esparza-Ros, Francisco, and Vaquero-Cristóbal, Raquel

Subjects

BICEPS femoris, VASTUS lateralis, STACKING machines, RESISTANCE training, TIBIALIS anterior, RECTUS femoris muscles, MUSCLES

Abstract

Featured Application: The main practical application of this research is the presentation of a new type of outdoor fitness equipment (OFE) available to both trainers and users, with scientific support regarding its ability to recruit the desired muscles in a similar way to conventional gym machinery. In addition, it was possible to improve the effectiveness of the OFE by including an intensity regulation system, thus allowing the principle of intensity progression to be considered, as well as increasing the control of training intensity in this type of machinery. This study compares the electromyographic activity (EMG) of different muscle groups (rectus femoris, vastus lateralis, biceps femoris, tibialis anterior, and gastrocnemius) of the lower limbs when performing a traditional seated leg press (SLP) with a classic piece of outdoor fitness equipment (OFE-SLP), and with a new OFE leg press that allows the user to adjust the intensity of the exercise by means of a selectorized system (BIOFIT-LP). It was found that the EMG of the OFE-SLP was significantly lower than that of the SLP, but similar activations to those of the SLP were achieved with the BIOFIT-LP. In conclusion, the inclusion of a system to be able to change intensity of the exercise in OFE achieves an EMG activity similar to traditional machinery in trained young men. [ABSTRACT FROM AUTHOR]

Published

2024

10. Comparison of muscle activity of the lower limbs while running on different treadmill models.

Author

Kaltenbach, Christina, Gollhofer, Albert, Nigg, Benno M., and Asmussen, Michael J.

Subjects

TREADMILLS, RUNNING speed, MUSCLES, HUMAN locomotion, BICEPS femoris, RECTUS femoris muscles, TIBIALIS anterior, TREADMILL exercise

Abstract

Treadmill running is a common method of exercise and to study human locomotion. Research has examined the kinematics and kinetics of overground and treadmill running, but there has been less focus on the levels of muscle activity during treadmill running. We investigated if muscle activity is different while running overground compared to running on a variety of treadmills. A total of 11 healthy individuals ran at 3 speeds (2.6, 3.6, 4.5 m/s) under 4 different running conditions (3 treadmills, overground). The three treadmills included a typical home exercise treadmill, a midsize commercial research treadmill, and a large, instrumented research treadmill. Surface EMG of the tibialis anterior (TA), gastrocnemius medialis (GM), rectus femoris (RF) and biceps femoris (BF) muscles were measured for each running condition. The integrated EMG was computed for each running condition for the stance and swing phase, as well as 100ms before and after the heel-strike. Friedman analysis revealed significant effects during the stance phase for GM and RF at all speeds, such that muscle activation was lower on the treadmills relative to overground. During the stance phase at faster speeds, themuscle activity was higher for the TA and lower for the BF while running on the different treadmills compared to overground running. Before heel-strike, the TA was significantly less active during treadmill compared to overground running at 2.6 m/s and the RF showed significantly higher activity at 3.6 m/s and 4.5 m/s while running on the different treadmills. Summarizing, differences were mainly observed between the different treadmill conditions relative to overground running. Muscle activation differences between the different treadmill conditions were observed at faster running speeds for RF during the pre-heel-strike phase only. Different types of treadmills with different mechanical properties affects the muscle activity during stance phase as well as in preparation to heel-strike. Additionally, the muscle activity is greater during overground compared to treadmill running during the stance phase for the GM, BF, and RF. [ABSTRACT FROM AUTHOR]

Published

2024

11. Effect of cross-slope angle on running economy and gait characteristics at moderate running velocity.

Author

Elmer, David J. and Asbill, Henry W.

Subjects

*RUNNING speed, *BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior, *RUNNING

Abstract

Purpose: Outdoor running surfaces are designed with a cross-slope, which can alter kinetic and kinematic gait parameters. The purpose of this study was to evaluate running economy, gait characteristics, and muscle activation while running on a surface with cross-slopes similar to those encountered on roads and trails. Methods: Eleven recreational runners (females n = 6) completed 5-min running trials on a treadmill at 10 km h−1 with cross-slopes of 0, 1.15, 2.29, and 6 deg in a randomized order. Results: There were no significant differences in VO2, HR, RER, or VE across cross-slope conditions. Compared to 0 deg of cross-slope, ground contact time and duty factor increased at 2.29 and 6 deg, with significant decreases in absolute and relative flight times. Rear foot angles increased in the upslope leg at 2.29 and 6 deg cross-slopes and decreased in the downslope leg at 6 deg compared to 0 deg of cross-slope, with differences between legs for the 2.29 and 6 deg conditions. Knee flexion at foot strike increased in the upslope leg at a 6 deg cross-slope. Vastus lateralis, biceps femoris, gastrocnemius, and tibialis anterior activation were not affected by the cross-slope conditions. While cross-slopes up to 6 deg result in changes to some gait kinematics, these effects do not impact running economy at moderate running velocity. [ABSTRACT FROM AUTHOR]

Published

2024

12. Persisting effects of jaw clenching on dynamic steady-state balance.

Author

Fadillioglu, Cagla, Kanus, Lisa, Möhler, Felix, Ringhof, Steffen, Schmitter, Marc, Hellmann, Daniel, and Stein, Thorsten

Subjects

*DYNAMIC balance (Mechanics), *TIBIALIS anterior, *BICEPS femoris, *JAWS, *RECTUS femoris muscles, *MASSETER muscle, *RESEARCH questions, *TASK performance

Abstract

The effects of jaw clenching on balance has been shown under static steady-state conditions but the effects on dynamic steady-state balance have not yet been investigated. On this basis, the research questions were: 1) if jaw clenching improves dynamic steady-state balance; 2) if the effects persist when the jaw clenching task loses its novelty and the increased attention associated with it; 3) if the improved dynamic steady-state balance performance is associated with decreased muscle activity. A total of 48 physically active healthy adults were assigned to three groups differing in intervention (Jaw clenching and balance training (JBT), only balance training (OBT) or the no-training control group (CON)) and attending two measurement points separated by two weeks. A stabilometer was used to assess the dynamic steady-state balance performance in a jaw clenching and non-clenching condition. Dynamic steady-state balance performance was measured by the time at equilibrium (TAE). The activities of tibialis anterior (TA), gastrocnemius medialis (GM), rectus femoris (RF), biceps femoris (BF) and masseter (MA) muscles were recorded by a wireless EMG system. Integrated EMG (iEMG) was calculated to quantify the muscle activities. All groups had better dynamic steady-state balance performance in the jaw clenching condition than non-clenching at T1, and the positive effects persisted at T2 even though the jaw clenching task lost its novelty and attention associated with it after balance training with simultaneous jaw clenching. Independent of the intervention, all groups had better dynamic steady-state balance performances at T2. Moreover, reductions in muscle activities were observed at T2 parallel to the dynamic steady-state balance performance improvement. Previous studies showed that jaw clenching alters balance during upright standing, predictable perturbations when standing on the ground and unpredictable perturbations when standing on an oscillating platform. This study complemented the previous findings by showing positive effects of jaw clenching on dynamic steady-state balance performance. [ABSTRACT FROM AUTHOR]

Published

2024

13. Effects of workload and saddle height on muscle activation of the lower limb during cycling.

Author

Bing, Fangbo, Zhang, Guoxin, Wang, Yan, and Zhang, Ming

Subjects

*CYCLING training, *CYCLING, *BICEPS femoris, *RECTUS femoris muscles, *TIBIALIS anterior, *SADDLERY

Abstract

Background: Cycling workload is an essential factor in practical cycling training. Saddle height is the most studied topic in bike fitting, but the results are controversial. This study aims to investigate the effects of workload and saddle height on the activation level and coordination of the lower limb muscles during cycling. Methods: Eighteen healthy male participants with recreational cycling experience performed 15 × 2-min constant cadence cycling at five saddle heights of 95%, 97%, 100%, 103%, and 105% of greater trochanter height (GTH) and three cycling workloads of 25%, 50%, and 75% of functional threshold power (FTP). The EMG signals of the rectus femoris (RF), tibialis anterior (TA), biceps femoris (BF), and medial gastrocnemius (MG) of the right lower limb were collected throughout the experiment. Results: Greater muscle activation was observed for the RF and BF at a higher cycling workload, whereas no differences were observed for the TA and MG. The MG showed intensified muscle activation as the saddle height increased. The mean and maximum amplitudes of the EMG signals of the MG increased by 56.24% and 57.24% at the 25% FTP workload, 102.71% and 126.95% at the 50% FTP workload, and 84.27% and 53.81% at the 75% FTP workload, respectively, when the saddle height increased from 95 to 100% of the GTH. The muscle activation level of the RF was minimal at 100% GTH saddle height. The onset and offset timing revealed few significant differences across cycling conditions. Conclusions: Muscle activation of the RF and BF was affected by cycling workload, while that of the MG was affected by saddle height. The 100% GTH is probably the appropriate saddle height for most cyclists. There was little statistical difference in muscle activation duration, which might be related to the small workload. [ABSTRACT FROM AUTHOR]

Published

2024

14. Comparing the Lower-Limb Muscle Activation Patterns of Simulated Walking Using an End-Effector-Type Robot with Real Level and Stair Walking in Children with Spastic Bilateral Cerebral Palsy.

Author

Ahn, Yongjin, Hong, Juntaek, Shim, Dain, Choi, Joong-on, and Rha, Dong-wook

Subjects

*CEREBRAL palsy, *RECTUS femoris muscles, *CHILDREN with cerebral palsy, *MUSCLES, *BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior

Abstract

Cerebral palsy is a neurologic disorder caused by lesions on an immature brain, often resulting in spasticity and gait abnormality. This study aimed to compare the muscle activation patterns of real level and stair walking with those of simulated walking using an end-effector-type robot in children with spastic cerebral palsy. The electromyographic activities of the vastus lateralis, biceps femoris, tibialis anterior and medial gastrocnemius of nine children with spastic bilateral cerebral palsy were measured during gait using a wireless surface EMG device. Morning walk was used for the simulated gait. Differences in the muscle activation patterns between the real and simulated gait conditions were analyzed. In the loading response, all four muscles showed reduced activity during two simulated conditions. In mid-stance, mGCM showed reduced activity during simulated conditions, whereas BFem showed greater activity during simulated level walking. In the swing phase, BFem and TAnt activity was reduced during the simulated conditions. The onset–offset of the VLat, BFem and TAnt activity was significantly delayed during simulated versus real level walking. No differences in activity onset–offset were observed between the simulated level and stair conditions. In conclusion, the robot-simulated gait showed differences in its muscle activation patterns compared with the real gait conditions, which must be considered for gait training using an end-effector-type robot. [ABSTRACT FROM AUTHOR]

Published

2023

15. Effects of simulated hypo-gravity on lower limb kinematic and electromyographic variables during anti-gravitational treadmill walking.

Author

Malaya, Christopher A., Parikh, Pranav J., Smith, Dean L., Riaz, Arshia, Chandrasekaran, Subhalakshmi, and Layne, Charles S.

Subjects

RECTUS femoris muscles, BICEPS femoris, TREADMILLS, LOADING & unloading, TIBIALIS anterior

Abstract

Introduction: This study investigated kinematic and EMG changes in gait across simulated gravitational unloading levels between 100% and 20% of normal body weight. This study sought to identify if each level of unloading elicited consistent changes—particular to that percentage of normal body weight—or if the changes seen with unloading could be influenced by the previous level(s) of unloading. Methods: 15 healthy adult participants (26.3 ± 2.5 years; 53% female) walked in an Alter-G anti-gravity treadmill unloading system (mean speed: 1.49 ± 0.37 mph) for 1 min each at 100%, 80%, 60%, 40% and 20% of normal body weight, before loading back to 100% in reverse order. Lower-body kinematic data were captured by inertial measurement units, and EMG data were collected from the rectus femoris, biceps femoris, medial gastrocnemius, and anterior tibialis. Data were compared across like levels of load using repeated measures ANOVA and statistical parametric mapping. Difference waveforms for adjacent levels were created to examine the rate of change between different unloading levels. Results: This study found hip, knee, and ankle kinematics as well as activity in the rectus femoris, and medial gastrocnemius were significantly different at the same level of unloading, having arrived from a higher, or lower level of unloading. There were no significant changes in the kinematic difference waveforms, however the waveform representing the change in EMG between 100% and 80% load was significantly different from all other levels. Discussion: This study found that body weight unloading from 100% to 20% elicited distinct responses in the medial gastrocnemius, as well as partly in the rectus femoris. Hip, knee, and ankle kinematics were also affected differentially by loading and unloading, especially at 40% of normal body weight. These findings suggest the previous level of gravitational load is an important factor to consider in determining kinematic and EMG responses to the current level during loading and unloading below standard g. Similarly, the rate of change in kinematics from 100% to 20% appears to be linear, while the rate of change in EMG was non-linear. This is of particular interest, as it suggests that kinematic and EMG measures decouple with unloading and may react to unloading uniquely. [ABSTRACT FROM AUTHOR]

Published

2023

16. Effects of a 4-week plyometric training on activity patterns during different phases of one-leg drop jump with focus on jump height.

Author

Ahmadabadi, Somayeh, Rjabi, Hamid, Gharakhanlou, Reza, Talebian, Saeed, and Basereh, Aref

Subjects

*LEG muscles, *JOINTS (Anatomy), *BICEPS femoris, *RECTUS femoris muscles, *TIBIALIS anterior, *ANTERIOR cruciate ligament injuries

Abstract

Athletic women have shown a higher risk of ACL injury during jump landing compared to men. Plyometric training can be an alternative way to minimize the risk of knee injuries via the changed muscle activity patterns. Hence, the aim of this study was to determine the effects of a 4-week plyometric training program on the muscle activity pattern in different phases of one-leg drop jump in active girls. Active girls were randomly allocated into 2 groups (Plyometric training = 10, Control group = 10) where the plyometric training group (PTG) performed 60 min exercises, 2 sessions/1 week for 4 weeks while the control group (CG) had their daily activity. In the pre to post test, the sEMG was recorded from the Rectus Femoris (RF), Biceps Femoris (BF), Medial Gastrocnemius (GaM), and Tibialis Anterior (TA) muscles of the dominant leg during the Preparatory phase (PP), Contact Phase (CP), Flight Phase (FP) of one-leg drop jump. Electromyography variables (Signal amplitude, Maximum activity, Time to peak (TTP), Onset and activity time and Order muscle activity) and Ergo jump variables (Time of preparatory phase (TPP), Time of contact phase (TCP), Time of flight (jump height) phase (TFP), and Explosive power were analyzed. The Univariate ANCOVA test showed a significant difference between the two groups in Activity Time, whilst adjusting for pre-test as a Covariate, only in TA muscle (F(1,17) = 5.09, p = 0.038, η2 = 0.230). In PTG. TA (− 15%), GaM (− 19%), and BF muscles (− 9%) started their activity earlier while there was no significant difference between the two groups at the Onset time. TTP of RF was significantly different between the 2 groups only in the PR phase (0.216 ± 0.07 vs 0.153 ± 0.09 s) (p = 0.049, 95% CI = 0.001, 0.127). Results of the present study suggest that a 4-week plyometric training can improve the stability of leg joints via earlier recruitment of muscles and change activity patterns in lower limb muscles. It also recommends that the preparatory phase before landing be considered an important stage in preventing sports injuries in a training program. [ABSTRACT FROM AUTHOR]

Published

2023

17. The Effect of Additional Leg Supports in Control of Posture in Sitting.

Author

Ademiluyi, Adeolu, Liang, Huaqing, and Aruin, Alexander S.

Subjects

*ERECTOR spinae muscles, *LEG muscles, *BICEPS femoris, *TIBIALIS anterior, *RECTUS femoris muscles, *POSTURE

Abstract

The objective of the study was to investigate the effect of leg supports on the anticipatory and compensatory postural adjustments of sitting subjects exposed to external perturbations in the anterior-posterior direction. Ten young participants received perturbations applied to the upper body while sitting on a stool with an anterior or posterior leg support and when using a footrest. Electromyographic activities of the trunk and leg muscles and center of pressure displacements were recorded and analyzed during the anticipatory and compensatory phases of postural control. Anticipatory activities were observed in the tibialis anterior, biceps femoris, and erector spinae muscles in the anterior leg support condition. Early onset of muscle activity was observed in the tibialis anterior, biceps femoris, rectus femoris, and erector spinae muscles in the posterior leg support condition compared to the feet support condition. Moreover, to maintain balance participants utilized co-contraction of muscles as the main mechanism of balance control in sitting regardless of the availability of the anterior or posterior leg support. There was no effect of a leg support on center of pressure displacements. The outcome of the study provides a background for future investigations of the effect of leg supports on control of balance in sitting when perturbed. [ABSTRACT FROM AUTHOR]

Published

2023

18. Neuromuscular Changes in Drop Jumps on Different Common Material Surfaces with Incremental Drop Heights.

Author

Peng, Hsien-Te, Chang, Hsiu-Kuang, Chen, Hung-Wen, Huang, Tsung-I, and Chen, Hui

Subjects

SURFACES (Technology), BICEPS femoris, RECTUS femoris muscles, TIBIALIS anterior, STIMULUS & response (Psychology), STRETCH reflex

Abstract

The purpose of this study was to compare changes in muscle pre-activation and short-latency responses in the lower limbs during drop jumps performed on different common soft and hard surfaces and at various platform heights. The study aimed to collect electromyography data from the rectus femoris, biceps femoris, tibialis anterior, gastrocnemius, and soleus of the dominant leg during drop jumps on sand, turf, polyurethane, and wood surfaces from platform heights of 30, 40, 50, and 60 cm. Muscle pre-activation refers to muscle activity 100 ms before ground contact during a drop jump, while short-latency responses refer to muscle activation occurring 30–60 ms after ground contact. These definitions were used to measure and analyze neuromuscular responses in the lower limb muscles during drop jumps using various surfaces and platform heights. Sand as a ground material and platform heights of 50 and 60 cm significantly enhanced pre-activation and activation in short-latency responses of the lower limb muscles (all p < 0.01). The difficulty of the drop jump task can enhance pre-activation and activation in the latency responses of lower limb muscles. It is recommended that athletes perform drop jumps on sandy surfaces or from platforms higher than 50 cm to induce muscle pre-activation of the lower limbs and to improve muscle activation levels in the latency responses after landing. [ABSTRACT FROM AUTHOR]

Published

2023

19. Are changes in nociceptive withdrawal reflex magnitude a viable central sensitization proxy? Implications of a replication attempt.

Author

Guekos, A., Grata, A.C., Hubli, M., Schubert, M., and Schweinhardt, P.

Subjects

*BICEPS femoris, *TIBIALIS anterior, *RECTUS femoris muscles, *REFLEXES, *ELECTRIC stimulation

Abstract

• A previously observed increase in nociceptive withdrawal reflex (NWR) magnitude during application of painful heat was not replicated. • Strong parameter sensitivity in central sensitization and NWR studies warrants precise reporting of study methods to guarantee replicability. • Stimulating the medial plantar nerve and recording from the tibialis anterior muscle yielded response rates of up to 79% for repetitive suprathreshold stimulations. The nociceptive withdrawal reflex (NWR) has been proposed to read-out central sensitization (CS). Replicating a published study, it was assessed if the NWR magnitude reflects sensitization by painful heat. Additionally, NWR response rates were compared for two stimulation, the sural nerve at the lateral malleolus (SU) and the medial plantar nerve on the foot sole (MP), and three recording sites, biceps femoris (BF), rectus femoris (RF), and tibialis anterior (TA) muscles. 16 subjects underwent one experiment with six blocks of eight transcutaneous electrical stimulations to elicit the NWR while surface electromyography was collected. Tonic heat was concurrently applied in the same dermatome. Temperatures rose from 32 °C in the first to 46 °C in the last block following the previously published protocol. Tonic heat did not influence NWR magnitude. The highest NWR response rate was obtained for MP–TA combination (79%). Regarding elicitation in all three muscles, SU stimulation outperformed MP (59% vs 57%). The replication failed. NWR magnitude as a CS proxy in healthy subjects needs continued investigation. With respect to response rates, MP–TA proved efficient, whereas SU stimulation seemed preferable for multiple muscle recordings. Unclear methodological descriptions in the original study affected CS and NWR replication. The NWR magnitude changes induced by CS may closely depend on the different stimulation methods used. [ABSTRACT FROM AUTHOR]

Published

2023

20. Anticipatory postural adjustments in older versus young adults: a systematic review and meta-analysis.

Author

Duarte, Manuela Brito, da Silva Almeida, Gizele Cristina, Costa, Kelly Helorany Alves, Garcez, Daniela Rosa, de Athayde Costa e Silva, Anselmo, da Silva Souza, Givago, de Melo-Neto, João Simão, and Callegari, Bianca

Subjects

*YOUNG adults, *ERECTOR spinae muscles, *OLDER people, *BICEPS femoris, *TIBIALIS anterior

Abstract

Background: Anticipatory postural adjustments (APAs) are a feedforward mechanism triggered in advance to a predictable perturbation, to help the individual counteract mechanical effects that the disturbance may cause. Whether or not this strategy is compromised in the elderly is not a consensus in the literature. Methods: In this systematic review with meta-analysis, we investigated aging effects on postural control, based on anticipatory postural adjustments (APAs). We selected 11 eligible articles of the following databases: Lilacs, SciELO, PubMed, Cochrane Central, Embase, and CINAHL, involving 324 research participants, assessing their methodological quality and extracting electromyographic, posturographic, and kinematic measurements. We included studies that investigated the occurrence of APAs in healthy younger and older adults, published before 10th August 2022, in English. Studies involving participant with conditions that may affect balance or that did not report measures of onset or amplitude of electromyography (EMG), COP, or kinematics were excluded. To analyze the aggregated results from these studies, we performed the analysis based on the outcome measures (EMG, COP, or kinematic measures) used in individual studies. We calculated differences between younger and older adult groups as the mean differences between the groups and the estimated effect. Egger's test was conducted to evaluate whether this meta-analysis had publication bias. Results: Through this review, older adults showed no significant difference in the velocity to perform a movement compared to the younger adults (MD 0.95, 95% CI −0.86, 2.76, I2 = 82%), but both muscle onset and center of pressure (COP) onset were significantly more delayed in older than in younger adults: erector spinae (MD −31.44, 95% CI −61.79, −1.09, I2 = 95%); rectus abdominis (RA) (MD −31.51, 95% CI −70.58, −3.57, I2 = 85%); tibialis anterior (TA) (MD −44.70, 95% CI −94.30, 4.91, I2 = 63%); soleus (SOL) (MD −37.74, 95% CI −65.43, −10.05, I2 = 91%); gastrocnemius (GAS) (MD −120.59, 95% CI −206.70, −34.49, I2 = 94%); quadriceps (Q) (MD −17.42, 95% CI −34.73, −0.12, I2 = 0%); biceps femoris (BF) (MD −117.47, 95% CI −192.55, −42.70, I2 = 97%); COP onset (MD −45.28, 95% CI −89.57, −0.98, I2 = 93%), and COP apa (COPapa) (MD 2.35, 95% CI −0.09, 4.79, I2 = 64%). These changes did not seem to be linked to the speed of movement but possibly to age-related physiological changes that indicated decreased motor control during APAs in older adults. Conclusions: Older adults use different postural strategies that aim to increase the safety margin and stabilize the body to perform the movement, according to the requirements imposed, and this should be considered in rehabilitation protocols. Systematic review registration: PROSPERO CRD420119143198 [ABSTRACT FROM AUTHOR]

Published

2022

21. Biomechanical Effects of Adding an Ankle Soft Actuation in a Unilateral Exoskeleton.

Author

Otálora, Sophia, Ballen-Moreno, Felipe, Arciniegas-Mayag, Luis, Cifuentes, Carlos A., and Múnera, Marcela

Subjects

ANKLE, ANKLE joint, ROBOTIC exoskeletons, BICEPS femoris, TIBIALIS anterior, MUSCLE strength

Abstract

Stroke disease leads to a partial or complete disability affecting muscle strength and functional mobility. Early rehabilitation sessions might induce neuroplasticity and restore the affected function or structure of the patients. Robotic rehabilitation minimizes the burden on therapists by providing repetitive and regularly monitored therapies. Commercial exoskeletons have been found to assist hip and knee motion. For instance, unilateral exoskeletons have the potential to become an effective training system for patients with hemiparesis. However, these robotic devices leave the ankle joint unassisted, essential in gait for body propulsion and weight-bearing. This article evaluates the effects of the robotic ankle orthosis T-FLEX during cooperative assistance with the AGoRA unilateral lower-limb exoskeleton (hip and knee actuation). This study involves nine subjects, measuring muscle activity and gait parameters such as stance and swing times. The results showed a reduction in muscle activity in the Biceps Femoris of 50%, Lateral Gastrocnemius of 59% and Tibialis Anterior of 35% when adding T-FLEX to the AGoRA unilateral lower-limb exoskeleton. No differences were found in gait parameters. Nevertheless, stability is preserved when comparing the two legs. Future works should focus on evaluating the devices in ground tests in healthy subjects and pathological patients. [ABSTRACT FROM AUTHOR]

Published

2022

22. Differences in trunk and lower extremity muscle activity during squatting exercise with and without hammer swing.

Author

Murofushi, Koji, Oshikawa, Tomoki, Kaneoka, Koji, Akuzawa, Hiroshi, Yamaguchi, Daisuke, Mitomo, Sho, Furuya, Hidetaka, Hirohata, Kenji, and Yagishita, Kazuyoshi

Subjects

*MUSCLE strength, *TIBIALIS anterior, *SQUAT (Weight lifting), *RECTUS femoris muscles, *BICEPS femoris, *ELECTROMYOGRAPHY, *HAMMERS

Abstract

Perturbation exercises enhance lower limb and trunk muscles, and adding swing perturbation while loading during exercise might improve muscle activation or strength. This study aimed to check variations in trunk and lower limb muscle activity during conventional isometric squats, and whether it will change with or without swing using the Hammerobics-synchronized squat method. Twelve healthy men participated in this study. Activities for the abductor hallucis, tibialis anterior, tibialis posterior, peroneus longus, rectus femoris, biceps femoris long head, semitendinosus, gluteus maximus, multifidus, and internal oblique muscles were measured using surface electromyography during a Hammerobics-synchronized squat and conventional isometric squat. Muscle activities were statistically compared between squat methods. Hammerobics-synchronized squats significantly activated the abductor hallucis, tibialis anterior, tibialis posterior, peroneus longus, semitendinosus, and multifidus muscles, in both phases, compared with the conventional isometric squats. The Hammerobics-synchronized squat exercise can be considered for trunk and foot stability exercise. [ABSTRACT FROM AUTHOR]

Published

2022

23. Motor Unit Recruitment is Altered When Acute Experimental Pain is Induced at a Site Distant to the Contracting Muscle.

Author

Cleary, Jennifer, Coombes, Brooke K., Hodges, Paul, and Tucker, Kylie

Subjects

*MOTOR unit, *BICEPS femoris, *HYPERTONIC saline solutions, *SALINE injections, *TIBIALIS anterior, *PAIN management

Abstract

• Motor unit discharge is altered when pain is induced in distant tissues. • Demonstrated with pain at a distant (same limb) and in an antagonist muscle. • Altered discharge has limited/no potential to modify load in the painful tissue. • Findings may support hypothesis of redistribution to larger motor units with pain. Acute pain alters motor unit discharge properties in muscles that are painful or influence loading of painful structures. Less is known about the changes in discharge when pain is induced in distant tissues that are unable or have limited capacity to modify the load of the contracting muscle. We aimed to determine whether acute experimental pain alters quadriceps motor unit discharge when pain is induced in; (i) a muscle that is unlikely to be mechanically influenced by modified quadriceps activity (tibialis anterior: TA), or (ii) the antagonist muscle (biceps femoris: BF). Using a within-subject design, 16 adults performed force-matched isometric knee extension during pain-free control conditions, and trials after painful hypertonic saline injections into TA or BF. Surface and intramuscular electromyography recordings were made. Despite maintained force, discharge rate of quadriceps motor units was lower during Pain than Control conditions for TA and BF trials (both P < 0.001). Redistribution of motor unit activity was observed; some units were recruited in control or pain but not both. As modified quadriceps motor unit discharge has limited/no potential to modify load in the painful tissue to protect the painful part, the findings might support an alternative hypothesis that activity is redistributed to larger motor units. [ABSTRACT FROM AUTHOR]

Published

2022

24. University of Cantabria Researcher Publishes New Data on Sensor Research (Changes in Motor Strategy and Neuromuscular Control During Balance Tasks in People with a Bimalleolar Ankle Fracture: A Preliminary and Exploratory Study).

Subjects

ANKLE fractures, BICEPS femoris, TIBIALIS anterior, REPORTERS & reporting, SURGICAL technology

Abstract

Researchers from the University of Cantabria conducted a preliminary study on individuals with bimalleolar ankle fractures to explore changes in motor strategy and neuromuscular control during balance tasks post-surgery. The study assessed hip strength, ankle functionality, and static and dynamic balance using electromyography of lower limb muscles. Findings indicated differences in neuromuscular patterns between operated and non-operated limbs at 6 months post-surgery, emphasizing the importance of the Y-Balance Test in highlighting these changes. Further research is needed to delve deeper into these initial findings. [Extracted from the article]

Published

2024

25. Profiles of muscle-specific oxygenation responses and thresholds during graded cycling incremental test.

Author

Sendra-Pérez, Carlos, Encarnacion-Martinez, Alberto, Salvador-Palmer, Rosario, Murias, Juan M., and Priego-Quesada, Jose I.

Subjects

*OXYGEN saturation, *BICEPS femoris, *TIBIALIS anterior, *VASTUS lateralis, *BLOOD lactate

Abstract

Compared to the determination of exercise thresholds based on systemic changes in blood lactate concentrations or gas exchange data, the determination of breakpoints based on muscle oxygen saturation offers a valid alternative to provide specific information on muscle-derived thresholds. Our study explored the profiles and timing of the second muscle oxygenation threshold (MOT2) in different muscles. Twenty-six cyclists and triathletes (15 male: age = 23 ± 7 years, height = 178 ± 5 cm, body mass = 70.2 ± 5.3 kg; 11 female: age = 22 ± 4 years, height = 164 ± 4 cm, body mass = 58.3 ± 8.1 kg) performed a graded exercise test (GXT), on a cycle ergometer. Power output, blood lactate concentration, heart rate, rating of perceived exertion, skinfolds and muscle oxygen saturation were registered in five muscles (vastus lateralis, biceps femoris, gastrocnemius medialis, tibialis anterior and triceps brachii) and percentage at which MOT2 occurred for each muscle was determinated using the Exponential Dmax. The results of Statistical Parametric Mapping and ANOVA showed that, although muscle oxygenation displayed different profiles in each muscle during a GXT, MOT2 occurred at a similar percentage of the GXT in each muscle (77% biceps femoris, 75% tibalis anterior, 76% gastrocnemius medialis and 72% vastus lateralis) and it was similar that systemic threshold (73% of the GXT). In conclusion, this study showed different profiles of muscle oxygen saturation in different muscles, but without notable differences in the timing for MOT2 and concordance with systemic threshold. Finally, we suggest the analysis of the whole signal and not to simplify it to a breakpoint. [ABSTRACT FROM AUTHOR]

Published

2024

26. The Effects of Verbal Instructions on Lower Limb Muscles' Excitation in Back-Squat.

Author

Coratella, Giuseppe, Tornatore, Gianpaolo, Longo, Stefano, Borrelli, Marta, Doria, Christian, Esposito, Fabio, and Cè, Emiliano

Subjects

*BACK muscles, *BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior, *RESISTANCE training, *ECCENTRICS & eccentricities

Abstract

The present study investigated whether or not verbal instruction affects the electromyographic (EMG) amplitude of back-squat prime movers. Fifteen resistance-trained men performed back-squat at 50%1-RM and 80%1-RM and received external (EF) or internal focus (IF) on lower-limb posterior muscles. EMG amplitude of gluteus maximus, biceps femoris, gastrocnemius medialis, vastus lateralis, and tibialis anterior was recorded during both concentric and eccentric phases. During the concentric phase, the gluteus maximus and biceps femoris EMG amplitude was greater in IF vs EF at 50% [effect size (ES): 0.63 (95%CI 0.09/1.17) and 0.49 (0.10/0.78), respectively] and 80% [ES: 1.30 (0.29/2.21) and 0.59 (0.08/1.10)]. The gastrocnemius medialis EMG amplitude was greater in IF vs EF during the eccentric phase at 50% [ES: 0.73 (0.13/1.33)] and at 80% [ES: 0.72 (0.10/1.34)]. Concomitantly, vastus lateralis EMG amplitude was lower at 50% [ES: −0.71 (−1.38/-0.04)] and 80% [ES: −0.68 (−1.33/-0.03)]. During the eccentric phase, the tibialis anterior EMG amplitude was greater in IF vs EF at 50% [ES: 0.90 (0.12 to 1.68)] and 80% [ES: 0.74 (0.13/1.45)]. Irrespective of the load, in the thigh muscles the internal focus promoted a different motor pattern, increasing the hip extensors and reducing the knee extensor excitation during the concentric phase. Concomitantly, both ankle muscles were more excited during the eccentric phase, possibly to increase the anterior–posterior balance control. The internal focus in back-squat seems to have phase-dependent effects, and it is visible at both moderate and high loads. [ABSTRACT FROM AUTHOR]

Published

2022

27. Comparison of the mass and amount of intramuscular non-contractile tissue of the trunk and lower extremity muscles between patients with Parkinson's disease and community-dwelling older adults.

Author

Masaki, Mitsuhiro, Kasahara, Maki, Takeuchi, Moeka, Minakawa, Kota, Inagaki, Yukika, Ogawa, Yukine, Sato, Yoshino, Yokota, Minori, Maruyama, Seina, Usuki, Ryoko, Azuma, Satomi, and Obinata, Shunsuke

Subjects

*PARKINSON'S disease, *OLDER people, *BICEPS femoris, *TIBIALIS anterior, *WALKING speed, *GLUTEAL muscles

Abstract

Objective: This study compared the masses and amounts of intramuscular non-contractile tissue of the trunk and lower extremity muscles, sagittal spinal alignment, and mobility and balance ability between patients with Parkinson's disease (PD) and older adults. Methods: This study included 26 older adults (control [CTR] group) and eight patients with PD (PD group). Muscle thicknesses and echo intensities of the trunk and lower extremity muscles were measured using an ultrasound imaging device. Sagittal spinal alignments in the standing and prone positions were assessed using a Spinal Mouse. Mobility capacity was assessed based on the measurements of usual and maximal walking speeds, timed up-and-go (TUG) time, and five-chair-stand time, while balance ability was assessed based on the measurement of one-legged stance (OLS) time. Results: Our results showed significantly lower gluteus maximus and tibialis anterior muscle thicknesses, higher thickness of the short head of the biceps femoris muscle, and higher echo intensity of the gluteus maximus muscle in the PD group than in the CTR group. Lumbar lordosis angle in the standing position, usual and maximal walking speeds, and OLS time were significantly lower, while the TUG and five-chair-stand times were significantly higher in the PD group than in the CTR group. The other factors did not differ significantly between groups. Conclusions: Our results revealed lower masses of the gluteus maximus and tibialis anterior muscles, higher mass of the short head of the biceps femoris muscle, and higher amounts of intramuscular non-contractile tissue of the gluteus maximus muscle in patients with PD. [ABSTRACT FROM AUTHOR]

Published

2022

28. Spinal Nociception is Facilitated during Cognitive Distraction.

Author

Henrich, Mauricio Carlos, Frahm, Ken Steffen, Coghill, Robert C., and Andersen, Ole Kæseler

Subjects

*DISTRACTION, *BICEPS femoris, *SPINAL cord, *TIBIALIS anterior, *LEG muscles, *STIMULUS & response (Psychology), *INTERNEURONS

Abstract

• Distraction facilitates the nociceptive withdrawal reflex in healthy humans. • Attention to the stimuli did not modulate the magnitude of the reflex. • Spatial summation of paired stimuli was observed on the withdrawal reflex. • Distraction seems to have minimal impact on spatial tuning of nociceptive processes. • Spinal filtering mechanisms likely instantiate spatial aspects of the perception. The nociceptive withdrawal reflex (NWR) is a behavioral response to protect the body from noxious stimuli. The spatial characteristics of the stimulus modulate the reflex response to prevent damage to the affected tissue. Interneurons in the deep dorsal horn in the spinal cord encode the relationship between stimulus characteristics and the magnitude of the NWR and are also likely integrating spatial information of the nociceptive stimulus. The aim of this study was to use the NWR to investigate whether the spinal spatial integration of a simultaneous stimulus is modulated by shifting the attention of the participant towards (attention) or away from (distraction) the stimulus. We hypothesized that the descending activity shapes the receptive fields of the spinal neurons encoding spatial integration of nociception. Twenty healthy volunteers participated in the study. Single and simultaneous stimuli were delivered through two stimulating electrodes located in the arch and on the lateral side in the sole of the foot. The NWR was quantified by electromyography from the Tibialis Anterior and Biceps Femoris muscles during baseline and active tasks (attention and distraction). During the baseline task, spatial summation of the NWR was evoked during simultaneous stimulation. During the distraction task, the NWR was significantly larger compared to baseline, regardless of the sites being stimulated (single and simultaneous stimuli). In contrast, the NWR recorded during the attention task did not differ from baseline. These results further support that the spinal NWR pathway is under descending control which can be modulated by cognitive processes. The NWRs recorded over both proximal and distal muscles were similarly affected by the tasks, suggesting that the descending control affects the lower leg spinal system, with no discrimination between spinal segments. [ABSTRACT FROM AUTHOR]

Published

2022

29. Age-related changes in the activation timing of postural muscles to the prime mover muscle for bilateral arm flexion during standing.

Author

Kiyota, Takeo and Fujiwara, Katsuo

Subjects

POSTURAL muscles, TIBIALIS anterior, ARM muscles, ERECTOR spinae muscles, BICEPS femoris, RECTUS femoris muscles

Abstract

Background: We aimed to obtain the standard values of age-related changes in the activation timing of postural muscles to the prime mover muscle (anterior deltoid [AD]) for bilateral arm flexion during standing. Methods: The study participants were 276 children (aged 3–14 years) and 32 adults (aged 20–26 years). In response to a visual stimulus, participants raised both arms from a fully extended position as quickly as possible, stopped their arms voluntarily at a horizontal level at the shoulder, and maintained that position for 2 s. Ten test trials were performed. By using surface electromyography, the duration from the burst onset of the postural muscles to that of AD was measured as the starting time of the postural muscles (rectus abdominis [RA], erector spinae [ES], rectus femoris [RF], biceps femoris [BF], tibialis anterior [TA], gastrocnemius medialis [GcM], and soleus [SOL]). The starting time was presented as a negative value when the burst onset of the postural muscles preceded that of AD, which was defined as the preceding activation. A positive value for the starting time was defined as delayed activation. Results: In adults, the burst onsets of ES and BF significantly preceded that of AD. In ES, the starting time preceded the onset of AD in those aged ≥ 5–6 years; no difference with adults was found at age 13–14 years. On the other hand, in BF, significant delayed activation was found at ages 3–4 to 11–12 years. While the starting time decreased with age, no significant preceding activation similar to adults was found, even at age 13–14 years. In TA, no significant difference with the onset of AD was found at age 3–6 years, and significant delayed activation was found at age ≥ 7–8 years. Significant delayed activation in GcM, SOL, RA, and RF was observed in all age groups, and no age-related changes were observed in children. Conclusion: These findings could provide standard values from childhood to adolescence for age-related changes in anticipatory postural muscle activity during voluntary movement while standing and contribute to applications in the fields of sports and rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2022

30. 儿童下肢生物力学特征在视觉剥夺及双重任务时的变化.

Author

欧阳一毅, 彭 杰, 王 坤, 张庭然, and 罗 炯

Subjects

*VESTIBULAR apparatus, *BICEPS femoris, *ROOT-mean-squares, *TIBIALIS anterior, *RECTUS femoris muscles, *ANKLE, *LEG muscles

Abstract

BACKGROUND: Human balance and control depend on the coordination of the inner ear vestibular system, proprioceptors and visual system, and the central nervous system. However, when a person is visually deprived or dual cognitive tasks, it will cause changes in neural control and sensory integration, and then change lower limb balance control ability and movement control strategy. OBJECTIVE: To explore the biomechanical changes of the legs in stair descendent of different visual inputs and cognitive tasks so as to reveal action mechanism, thus preventing and avoiding accidents of children falling off stairs in descending stairs. METHODS: Twenty students from grades 3-6 of the Primary School Attached to Southwest University were volunteered to participate in the research (n=5 for each grade). The biomechanical parameters of participants in stair descendent of different visual inputs and cognitive tasks were collected with such test tools as JVC9800 high-speed video camera of kinematics, BIOFORCEN dynamic balance training assessment system of dynamics, and JE-TB0810 eight-channel electromyogram tester of surface electromyography. RESULTS AND CONCLUSION: (1) The angle of the knee joint and the ankle joint with eyes closed and double tasks was obviously larger than that with eyes open and single task (P < 0.05), while the center of gravity was in the lowest level, the angle of the ankle joint with eyes closed and double tasks was obviously larger than that with eyes open and single task (P < 0.05). (2) The lengthways displacement root mean square of center of pressure, transverse displacement root mean square of center of pressure, length of swing trajectory of center of pressure and the enveloping surface of center of pressure with eyes open and double tasks were all smaller than those with eyes closed (P < 0.05). (3) The average electromyogram amplitude standardization parameter and activation length of the biceps femoris, rectus femoris, tibialis anterior and medial head of gastrocnemius with eyes closed and double tasks were significantly smaller than those with eyes open and single task during the first 200 ms prior to touching the steps (P < 0.05); while the average electromyogram amplitude standardization parameter of the tibialis anterior and medial head of gastrocnemius during the buffer period with eyes closed and double tasks were significantly smaller than those with eyes open and single task (P < 0.01). (4) It is concluded that the visual deprivation and double tasks in stair descendent will both block the information transmission of the central nervous system, influence the adjustment of body position and the activation of leg muscles, and further affect children’s balance control and gait steadily and increase their risk of falling off the stairs. However, the influence of visual deprivation to children’s balance control is significantly higher than that of the double tasks. The changes on balance control are caused by visual deprivation. The block of information transmission in the central nervous system will influence children’s cognitive choice, making them pay more attention on walking behaviors instead of cognitive operations. [ABSTRACT FROM AUTHOR]

Published

2022

31. Effects of Fatigue on Postural Sway and Electromyography Modulation in Young Expert Acrobatic Gymnasts and Healthy Non-trained Controls During Unipedal Stance.

Author

da Silva, Marcos Camargo, Silva, Cristiano Rocha da, de Lima, Felipe Fava, Lara, Jéssica Rodriguez, Gustavson, Jackson Paiva, and Magalhães, Fernando Henrique

Subjects

ELECTROMYOGRAPHY, TIBIALIS anterior, BICEPS femoris, GYMNASTS, PRACTICE (Sports), ATHLETES, SWIMMERS

Abstract

This study investigated whether expert acrobatic gymnasts respond differentially than their non-trained counterparts during a single-legged stance task performed before and after a protocol designed to induce fatigue in the ankle plantarflexor muscles in terms of (a) postural steadiness and (b) electromyography (EMG) activation. We hypothesized that neuromuscular adaptation due to training would lead to different behavior of center of pressure (COP) and EMG quantifiers after fatigue. Twenty eight female volunteers (aged 11 to 24 years) formed two groups: expert acrobatic gymnastics athletes (GYN, n = 14) and age-matched non-gymnasts [control (CTRL), n = 14]. Fatigue of the ankle plantarflexors (dominant leg) was induced by a sustained posture (standing on the toes) until exhaustion. Traditional COP parameters (area, RMS, mean velocity, and power spectrum at low and high frequency ranges) were obtained with a force plate, and time and frequency-domain EMG parameters were obtained by surface electrodes positioned on the tibialis anterior , soleus , lateral gastrocnemius , medial gastrocnemius , vastus lateralis , biceps femoris , spinal erector and rectus abdominis muscles. The main results showed that fatigue induced a significant increase in postural oscillations in the ML axis (including RMS, velocity and frequency components of the power spectrum), with no significant effects in the AP axis. In terms of postural sway parameters (i.e., COP quantifiers), no superior balance stability was found for the GYN group as compared to CTRL, irrespective of the fatigue condition. On the other hand, the modulation of EMG parameters (in both time and frequency domains) indicated that expert acrobatic gymnastics athletes (as compared to healthy untrained matched controls) used different neuromuscular control strategies to keep their postures on single-legged quiet standing after the fatiguing protocol. The present results improve our knowledge of the mechanisms behind the interplay between fatigue and postural performance associated with the neuromuscular adaptations induced by sport practice. The design of gymnastics training might consider strategies aimed at improving the performance of specific muscles (i.e., tibialis anterior , soleus , biceps femoris , spinal erector) for which particular activation patterns were used by the acrobatic gymnastics to control single-legged quiet standing. [ABSTRACT FROM AUTHOR]

Published

2022

32. Effects of Running on Sand vs. Stable Ground on Kinetics and Muscle Activities in Individuals With Over-Pronated Feet.

Author

Jafarnezhadgero, AmirAli, Amirzadeh, Nasrin, Fatollahi, Amir, Siahkouhian, Marefat, Oliveira, Anderson S., and Granacher, Urs

Subjects

GROUND reaction forces (Biomechanics), BICEPS femoris, RUNNING speed, RECTUS femoris muscles, VASTUS medialis, SAND, TIBIALIS anterior

Abstract

Background: In terms of physiological and biomechanical characteristics, over-pronation of the feet has been associated with distinct muscle recruitment patterns and ground reaction forces during running. Objective: The aim of this study was to evaluate the effects of running on sand vs. stable ground on ground-reaction-forces (GRFs) and electromyographic (EMG) activity of lower limb muscles in individuals with over-pronated feet (OPF) compared with healthy controls. Methods: Thirty-three OPF individuals and 33 controls ran at preferred speed and in randomized-order over level-ground and sand. A force-plate was embedded in an 18-m runway to collect GRFs. Muscle activities were recorded using an EMG-system. Data were adjusted for surface-related differences in running speed. Results: Running on sand resulted in lower speed compared with stable ground running (p < 0.001; d = 0.83). Results demonstrated that running on sand produced higher tibialis anterior activity (p = 0.024; d = 0.28). Also, findings indicated larger loading rates (p = 0.004; d = 0.72) and greater vastus medialis (p < 0.001; d = 0.89) and rectus femoris (p = 0.001; d = 0.61) activities in OPF individuals. Controls but not OPF showed significantly lower gluteus-medius activity (p = 0.022; d = 0.63) when running on sand. Conclusion: Running on sand resulted in lower running speed and higher tibialis anterior activity during the loading phase. This may indicate alterations in neuromuscular demands in the distal part of the lower limbs when running on sand. In OPF individuals, higher loading rates together with greater quadriceps activity may constitute a proximal compensatory mechanism for distal surface instability. [ABSTRACT FROM AUTHOR]

Published

2022

33. Perspectives for improvement of karate stance performance on the basis of electromyogram analysis.

Author

VOVKANYCH, LYUBOMYR, KINDZER, BOGDAN, and FEDKIV, MARIA

Subjects

KARATE, BICEPS femoris, LEG muscles, TIBIALIS anterior, RECTUS femoris muscles, EXERCISE

Abstract

Copyright of Ido Movement for Culture. Journal of Martial Arts Anthropology is the property of Idokan Poland Association and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

34. 异构步道中下肢肌群不同时相的表面肌电特性.

Author

张 鹏 and 张峻霞

Subjects

*VASTUS lateralis, *BICEPS femoris, *VASTUS medialis, *TIBIALIS anterior, *MUSCLE strength, *HIP joint, *ANKLE

Abstract

BACKGROUND: Human walking is closely related to the changes of the surface electromyography signal of the lower limbs, but the difference of electromyography signal under the heterogeneous gait environment has not been studied in depth. OBJECTIVE: To quantitatively analyze the differences of surface electromyography signals of lower limb muscles in heterogeneous gait environments, and study muscle characteristics of lower limb muscles in different phases in heterogeneous footpaths. METHODS: Twenty healthy male subjects were recruited. The surface electromyography signals of lower limb muscles were collected in the environment of straight road, curve road, ramp, and stairs. A complete gait cycle was divided into four phases: the first dual support phase (0%-12%), the single support phase (13%-48%), and the second dual support phase (49%-60%) and swing phase (61%-100%). The muscle activation timing and difference of surface electromyography signal in different gait environments were studied through one-way analysis of variance. This study was approved by the Research Ethics Committee of Tianjin University of Science & Technology. RESULTS AND CONCLUSION: (1) The study showed that compared with the straight path environment, in the process of making turn, the internal and external rotation muscles (Biceps Femoris, Gastrocnemius Medialis, Tibialis Anterior) of hip joint and ankle joint were used to complete the turn. When going upstairs and uphill, in the stage of single support phase, Vastus Lateralis and Vastus Medialis had the most significant difference (P < 0.05), and muscle strength increased significantly. In the second double support phase, the amplitude of Gastrocnemius Medialis increased significantly. When going downstairs and downhill, in the first dual support phase, Vastus Lateralis and Vastus Medialis were required to exert additional assistance. In the single support phase, the amplitudes of Gastrocnemius Medialis and Semitendinosus were significantly increased. In the second double support phase, the amplitude of Gastrocnemius Medialis decreased significantly. (2) The research results can provide reference value for the research and development of the control system of lower limb rehabilitation walking aid. [ABSTRACT FROM AUTHOR]

Published

2021

35. Researchers from Keio University Describe Research in Neurology (Drumming performance and underlying muscle activities in a professional rock drummer with lower-limb dystonia: a case study).

Subjects

FINE motor ability, FOCAL dystonia, DRUM set, BICEPS femoris, TIBIALIS anterior

Abstract

A recent study conducted by researchers from Keio University in Japan examined the impact of lower-limb dystonia on drumming performance in a professional rock drummer. The study found that dystonia symptoms primarily manifested during the initial beat, with fewer symptoms during syncopation. Analysis revealed decreased bass-drum peak amplitude and earlier synchronization errors during the initial beat. The study also observed changes in muscle activity in the affected right lower limb, suggesting that lower-limb dystonia symptoms are characterized by a reduction in bass drumhead vibration and an increase in synchronization error. [Extracted from the article]

Published

2024

36. Passive stretching decreases muscle efficiency in balance tasks.

Author

Coratella, Giuseppe, Longo, Stefano, Rampichini, Susanna, Doria, Christian, Borrelli, Marta, Limonta, Eloisa, Michielon, Giovanni, Cè, Emiliano, and Esposito, Fabio

Subjects

*MUSCLE contraction, *BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior, *ROOT-mean-squares, *KNEE, *MUSCLES

Abstract

The current study aimed to verify whether or not passive static stretching affects balance control capacity. Thirty-eight participants (19 women and 19 men) underwent a passive static stretching session, involving the knee extensor/flexor and dorsi/plantarflexor muscles, and a control session (no stretching, CTRL). Before (PRE), immediately after (POST), after 15 (POST15) and 30 min (POST30) from stretching (or rest in CTRL), balance control was evaluated under static and dynamic conditions, with open/closed eyes, and with/without somatosensory perturbation (foam under the feet). During tests, centre of pressure (CoP) sway area and perimeter and antero-posterior and medio-lateral sway mean speed were computed. Surface electromyography root mean square (sEMG RMS) was calculated from the vastus lateralis, biceps femoris, gastrocnemius medialis, and tibialis anterior muscles during MVC and during the balance tests. Hip flexion/extension and dorsi/plantarflexion range of motion (ROM), maximum voluntary contraction (MVC) and sEMG RMS during MVC were measured at the same time points. After stretching, ROM increased (≈6.5%; P<0.05), while MVC and sEMG RMS decreased (≈9% and ≈7.5%, respectively; P<0.05). Regardless of the testing condition, CoP sway area and the perimeter remained similar, while antero-posterior and medio-lateral sway mean speed decreased by ≈8% and ≈12%, respectively (P<0.05). sEMG RMS during the balance tests increased in all muscles in POST (≈7%, P<0.05). All variables recovered in POST30. No changes occurred in CTRL. Passive static stretching did not affect the overall balance control ability. However, greater muscle activation was required to maintain similar CoP sway, thus suggesting a decrease in muscle efficiency. [ABSTRACT FROM AUTHOR]

Published

2021

37. Tempo-spatial integration of nociceptive stimuli assessed via the nociceptive withdrawal reflex in healthy humans.

Author

Henrich, Mauricio Carlos, Frahm, Ken Steffen, and Andersen, Ole Kæseler

Subjects

*REFLEXES, *BICEPS femoris, *INTERSTIMULUS interval, *SPINAL cord, *TIBIALIS anterior

Abstract

Spatial information of nociceptive stimuli applied in the skin of healthy humans is integrated in the spinal cord to determine the appropriate withdrawal reflex response. Double-simultaneous stimulus applied in different skin sites are integrated, eliciting a larger reflex response. The temporal characteristics of the stimuli also modulate the reflex, e.g., by temporal summation. The primary aim of this study was to investigate how the combined tempo-spatial aspects of two stimuli are integrated in the nociceptive system. This was investigated by delivering single- and double-simultaneous stimulation and sequential stimulation with different interstimulus intervals (ISIs ranging 30-500 ms) to the sole of the foot of 15 healthy subjects. The primary outcome measure was the size of the nociceptive withdrawal reflex (NWR) recorded from the tibialis anterior (TA) and biceps femoris (BF) muscles. Pain intensity was measured using a numerical rating scale (NRS) scale. Results showed spatial summation in both TA and BF when delivering simultaneous stimulation. Simultaneous stimulation provoked larger reflexes than sequential stimulation in TA, but not in BF. Larger ISIs elicited significantly larger reflexes in TA, whereas the opposite pattern occurred in BF. This differential modulation between proximal and distal muscles suggests the presence of spinal circuits eliciting a functional reflex response based on the specific tempo-spatial characteristics of a noxious stimulus. No modulation was observed in pain intensity ratings across ISIs. Absence of modulation in the pain intensity ratings argues for an integrative mechanism located within the spinal cord governed by a need for efficient withdrawal from a potentially harmful stimulus. [ABSTRACT FROM AUTHOR]

Published

2021

38. Shoe sole impedes leg muscle activation and impairs dynamic balance responding to a standing-slip.

Author

Ahn, Jiyun, Simpkins, Caroline, Shin, Sangwon, and Yang, Feng

Subjects

*SHOE soles, *DYNAMIC balance (Mechanics), *LEG muscles, *BICEPS femoris, *ELECTROMYOGRAPHY, *TIBIALIS anterior

Abstract

The shoe sole is identified as a fall risk factor since it may impede the afferent information about the outside world collected by the plantar sensory units. However, no study has directly quantified how the shoe sole compromises body balance and increases fall risk. This study aimed to inspect how the sole affects human balance after an unexpected standing-slip. It was hypothesized that individuals wearing the sole, relative to their barefoot counterparts, would exhibit 1) more impaired stability and 2) disrupted lower limb muscle activation following a standing-slip. Twenty young adults were evenly randomized into two groups: soled and barefoot. The soled group wore a pair of customized 10-mm thick soles, while the other group was bare-footed. Full-body kinematics and leg muscle electromyography (EMG) were collected during a standardized and unexpected standing-slip. The EMG electrodes were placed on the tibialis anterior, gastrocnemius, rectus femoris, and biceps femoris bilaterally. Dynamic stability, spatiotemporal gait parameters, and the EMG latency of the leg muscles were compared between groups. The sole impeded the initiation of the recovery step possibly because it interfered with the accurate detection of the external perturbation and subsequently activated the leg muscles later in the soled group than in the barefoot group. As a result, individuals in the soled group experienced a longer slip distance and were more unstable than the barefoot group at the recovery foot liftoff. The findings of this study could augment our understanding of how the shoe sole impairs body balance and increases the fall risk. [ABSTRACT FROM AUTHOR]

Published

2024

39. Patterns of whole-body muscle activations following vertical perturbations during standing and walking.

Author

Cano Porras, Desiderio, Jacobs, Jesse V., Inzelberg, Rivka, Bahat, Yotam, Zeilig, Gabriel, and Plotnik, Meir

Subjects

*RECTUS femoris muscles, *POSTURAL muscles, *DELTOID muscles, *RECTUS abdominis muscles, *TIBIALIS anterior, *BICEPS femoris

Abstract

Background: Falls commonly occur due to losses of balance associated with vertical body movements (e.g. reacting to uneven ground, street curbs). Research, however, has focused on horizontal perturbations, such as forward and backward translations of the standing surface. This study describes and compares muscle activation patterns following vertical and horizontal perturbations during standing and walking, and investigates the role of vision during standing postural responses.Methods: Fourteen healthy participants (ten males; 27±4 years-old) responded to downward, upward, forward, and backward perturbations while standing and walking in a virtual reality (VR) facility containing a moveable platform with an embedded treadmill; participants were also exposed to visual perturbations in which only the virtual scenery moved. We collected bilateral surface electromyography (EMG) signals from 8 muscles (tibialis anterior, rectus femoris, rectus abdominis, external oblique, gastrocnemius, biceps femoris, paraspinals, deltoids). Parameters included onset latency, duration of activation, and activation magnitude. Standing perturbations comprised dynamic-camera (congruent), static-camera (incongruent) and eyes-closed sensory conditions. ANOVAs were used to compare the effects of perturbation direction and sensory condition across muscles.Results: Vertical perturbations induced longer onset latencies and shorter durations of activation with lower activation magnitudes in comparison to horizontal perturbations (p<0.0001). Downward perturbations while standing generated earlier activation of anterior muscles to facilitate flexion (for example, p=0.0005 and p=0.0021 when comparing the early activators, rectus femoris and tibialis anterior, to a late activator, the paraspinals), whereas upward perturbations generated earlier activation of posterior muscles to facilitate extension (for example, p<0.0001 and p=0.0004, when comparing the early activators, biceps femoris and gastrocnemius, to a late activator, the rectus abdominis). Static-camera conditions induced longer onset latencies (p=0.0085 and p<0.0001 compared to eyes-closed and dynamic-camera conditions, respectively), whereas eyes-closed conditions induced longer durations of activation (p=0.0001 and p=0.0008 compared to static-camera and dynamic-camera, respectively) and larger activation magnitudes. During walking, downward perturbations promptly activated contralateral trunk and deltoid muscles (e.g., p=0.0036 for contralateral deltoid versus a late activator, the ipsilateral tibialis anterior), and upward perturbations triggered early activation of trunk flexors (e.g., p=0.0308 for contralateral rectus abdominis versus a late activator, the ipsilateral gastrocnemius). Visual perturbations elicited muscle activation in 67.7% of trials.Conclusion: Our results demonstrate that vertical (vs. horizontal) perturbations generate unique balance-correcting muscle activations, which were consistent with counteracting vertical body extension induced by downward perturbations and vertical body flexion induced by upward perturbations. Availability of visual input appears to affect response efficiency, and incongruent visual input can adversely affect response triggering. Our findings have clinical implications for the design of robotic exoskeletons (to ensure user safety in dynamic balance environments) and for perturbation-based balance and gait rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2021

40. Effects of Speed Bounding on Different Sloped Surface on Muscle Activation in Youth Male Sprinters.

Author

Sanpasitt, Chanawat, Intiraporn, Chaninchai, and Yimlamai, Tossaporn

Subjects

TIBIALIS anterior, EXTENSOR muscles, RECTUS femoris muscles, VASTUS lateralis, BICEPS femoris, PERSONAL coaching, GLUTEAL muscles

Abstract

The purpose of this study was to determine whether there was a dose-response relationship between muscle activity during a propulsive phase of speed bounding on sloped surfaces in youth male sprinters. In a randomized, crossover counterbalanced design, 12 male sprinters (age: 15.75 ± 0.45 yrs, height: 1.72 ± 0.06 m), performed 4 sessions of speed bounding on 4 different sloped surfaces (0°, 3° 6°, and 9°). Each session comprised 5 trials of 10-m speed bounding, interspersed with a 5-min rest period between trials, which was separated by 7-day apart. Surface electromyography (EMG) was used to measure muscle activation of gluteus maximus (GM), rectus femoris (RF), vastus lateralis (VL), gastrocnemius medialis (GD), soleus (SL), tibialis anterior (TA), biceps femoris (BF), semitendinosus (SM), and pectoralis major (PM). Overall, muscle activation during speed bounding was significantly increased with increasing slopes surface in all muscles examined, except for BF and SM. The average EMG amplitude was highest in SL and VL, and was lowest in TA and PM in all slopes. In addition, the average time to peak EMG and rate of EMG rise increased across slopes in all muscles, with the higher values observed at 9° compared to 0°, 3°, and 6°. Our results indicate that there was a dose-dependent increase in muscle activation during a propulsive phase of speed bounding on a sloped surface, with a greater magnitude observed in the extensor muscles group compared to other muscles. This finding could have implications for coaches and personal trainers who wish to develop an appropriate training program to improve acceleration ability in youth sprinter. [ABSTRACT FROM AUTHOR]

Published

2021

41. Amplitude and stride-to-stride variability of muscle activity during Lokomat guided walking and treadmill walking in children with cerebral palsy.

Author

van Kammen, Klaske, Reinders-Messelink, Heleen A., Elsinghorst, Anne L., Wesselink, Carlijn F., Meeuwisse-de Vries, Berna, van der Woude, Lucas H.V., Boonstra, Anne M., and den Otter, Rob

Subjects

CHILDREN with cerebral palsy, BICEPS femoris, TREADMILLS, TIBIALIS anterior, VASTUS lateralis, MUSCLES, LEG muscles

Abstract

The Lokomat is a commercially available exoskeleton for gait training in persons with cerebral palsy (CP). Because active contributions and variability over movement repetitions are determinants of training effectiveness, we studied muscle activity in children with CP, and determined (i) differences between treadmill and Lokomat walking, and (ii) the effects of Lokomat training parameters, on the amplitude and the stride-to-stride variability. Ten children with CP (age 13.2 ± 2.9, GMFCS level II(n = 6)/III(n = 4)) walked on a treadmill (±1 km/h; 0% bodyweight support(BWS)), and in the Lokomat (50% and 100% guidance; ±1 km/h and ±2 km/h; 0% and 50% BWS). Activity was recorded from Gluteus Medius (GM), Vastus Lateralis (VL), Biceps Femoris (BF), Medial Gastrocnemius (MG) and Tibialis Anterior (TA) of the most affected side. The averaged amplitude per gait phase, and the second order coefficient of variation was used to determine the active contribution and stride-to-stride variability, respectively. Generally, the amplitude of activity was lower in the Lokomat than on the treadmill. During Lokomat walking, providing guidance and BWS resulted in slightly lower amplitudes whereas increased speed was associated with higher amplitudes. No significant differences in stride-to-stride variability were observed between Lokomat and treadmill walking, and in the Lokomat only speed (MG) and guidance (BF) affected variability. Lokomat walking reduces muscle activity in children with CP, whereas altering guidance or BWS generally does not affect amplitude. This urges additional measures to encourage active patient contributions, e.g. by increasing speed or through instruction. • Muscle activity in children with CP is reduced in the Lokomat. • In the Lokomat, guidance and BWS result in slightly lower muscular amplitudes. • Increasing speed results in higher amplitudes during Lokomat walking. • Stride-to-stride muscle variability was similar during treadmill and Lokomat walking. • Within the Lokomat only speed and guidance slightly affected muscular variability. [ABSTRACT FROM AUTHOR]

Published

2020

42. Influence of running shoes on muscle activity.

Author

Hoitz, Fabian, Vienneau, Jordyn, and Nigg, Benno M.

Subjects

*RUNNING shoes, *TIBIALIS anterior, *BICEPS femoris, *VASTUS lateralis, *MUSCLES, *ANKLE, *KNEE

Abstract

Studies on the paradigm of the preferred movement path are scarce, and as a result, many aspects of the paradigm remain elusive. It remains unknown, for instance, how muscle activity adapts when differences in joint kinematics, due to altered running conditions, are of low / high magnitudes. Therefore, the purpose of this work was to investigate changes in muscle activity of the lower extremities in runners with minimal (≤ 3°) or substantial (> 3°) mean absolute differences in the ankle and knee joint angle trajectories when subjected to different running footwear. Mean absolute differences in the integral of the muscle activity were quantified for the tibialis anterior (TA), peroneus longus (PL), gastrocnemius medialis (GM), soleus (SO), vastus lateralis (VL), and biceps femoris (BF) muscles during over ground running. In runners with minimal changes in 3D joint angle trajectories (≤ 3°), muscle activity was found to change drastically when comparing barefoot to shod running (TA: 35%; PL: 11%; GM: 17%; SO: 10%; VL: 27%; BF: 16%), and minimally when comparing shod to shod running (TA: 10%; PL: 9%; GM: 13%; SO: 8%; VL: 8%; BF: 12%). For runners who showed substantial changes in joint angle trajectories (> 3°), muscle activity changed drastically in barefoot to shod comparisons (TA: 39%; PL: 14%; GM: 16%; SO: 16%; VL: 25%; BF: 24%). It was concluded that a movement path can be maintained with small adaptations in muscle activation when running conditions are similar, while large adaptations in muscle activation are needed when running conditions are substantially different. [ABSTRACT FROM AUTHOR]

Published

2020

43. Spring-like leg dynamics and neuromuscular strategies for hopping on a mini-trampoline in adults and children.

Author

Beerse, Matthew and Wu, Jianhua

Subjects

*BICEPS femoris, *VASTUS lateralis, *TIBIALIS anterior, *LEG, *HORIZONTAL wells

Abstract

Improved balance control is an often-cited potential benefit for trampoline interventions. However, it is unknown whether the soft, elastic surface of a trampoline elicits different motion and neuromuscular strategies between adults and children. Therefore, the purpose of the study was to evaluate the center-of-mass (COM) dynamics and neuromuscular strategies for hopping on a mini-trampoline in adults and children. Fourteen children aged 7–12 years and 15 adults aged 18–35 years hopped on a stiff surface and a mini-trampoline. We evaluated the vertical displacement of COM and leg length, as well as the horizontal displacements between hops. We also assessed muscle activation from tibialis anterior, lateral gastrocnemius, biceps femoris, and vastus lateralis during time periods surround landing and estimated fatigue across the hopping cycles. Our results indicated both groups used spring-like leg dynamics to regulate the COM movement while hopping on a mini-trampoline. Children increased horizontal displacements between hops on the mini-trampoline, requiring greater muscle activation during time-periods associated with proprioceptive input. Moreover, children might not have developed the adult-like ability to appropriately adjust muscle pre-activation for feedforward control. Hopping on a mini-trampoline might increase proprioceptive information and postural demand compared to a stiff surface while reducing neuromuscular fatigue. [ABSTRACT FROM AUTHOR]

Published

2020

44. Análisis comparativo de la actividad electromiográfica en miembro inferior entre técnicas de antepié y retropié, en corredores amateur.

Author

Valencia, Oscar, Cristi, Iver, Ahumada, Darío, Meza, Keiny, Salas, Rodrigo, Weinstein, Alejandro, and Guzmán-Venegas, Rodrigo

Subjects

ELECTROMYOGRAPHY, RECTUS femoris muscles, RUNNING techniques, BICEPS femoris, TIBIALIS anterior, SOCIAL contact

Abstract

Copyright of Retos: Nuevas Perspectivas de Educación Física, Deporte y Recreación is the property of Federacion Espanola de Asociaciones de Docentes de Educacion Fisica and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

45. 戶外騎乘不同市售輪組及地形對下肢肌肉活性 之影響.

Author

王翔星, 林子鈞, and 陳家祥

Subjects

*BICEPS femoris, *RECTUS femoris muscles, *VASTUS lateralis, *TIBIALIS anterior, *SKELETAL muscle

Abstract

Purpose: The aim of this study was to investigate lower limb muscle activation differences by riding different commercially available bike wheels on three terrains (ascent, descent, and flat). Methods: This study recruited 12 male college students (mean age: 19.5±1.7 years old, mean height: 174.7±4.7 cm, mean body mass: 69.7±7.14 kg). All of the participants performed regular weekly exercise routines. To obtain access to the lower limb muscle activation data, six electromyography sensors were positioned on the vastus medialis, vastus lateralis, rectus femoris, biceps femoris, tibialis anterior and gastrocnemius. The sampling rate was set as 1000 Hz, and two-way repeated measures ANOVA was applied to analyze the relationship between different bike wheels and lower limb muscle activation. All statistical measurements were performed using SPSS 22.0, and a significance level of α = .05 was adopted. Results: Referring to the test results, lower limb muscle activation showed no significant difference between the G wheel and the P wheel. However, when riding on different terrains, the vastus lateralis, biceps femoris and tibialis anterior muscle activation rates were found to be significantly lower during descents than during ascents. In terms of the gastrocnemius, the muscle activation rate was lower during descents than on horizontal terrain. Comparing ascents to horizontal terrain, the former induced higher muscle activation in the gastrocnemius during the trial. Conclusion: In summary, it is recommended that cyclists choose bike wheels that are able to meet their personal needs, such as functional demands, price, weight, and rim height. Weight itself is not the only consideration for selecting bike wheels, etc. Furthermore, in regard to cycling on different kinds of terrains, it was indicated that the gastrocnemius plays an important role during rides. If the rider can increase the muscle activation rate in the gastrocnemius, it is possible that performance can be enhanced. [ABSTRACT FROM AUTHOR]

Published

2020

46. Changes in Muscle Activity Patterns and Joint Kinematics During Gait in Hemophilic Arthropathy.

Author

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

Subjects

KINEMATICS, TIBIALIS anterior, RECTUS femoris muscles, BICEPS femoris, JOINT diseases, GLUTEAL muscles, ANKLE

Abstract

Hemophilic arthropathy is the result of repetitive intra-articular bleeding and synovial inflammation. In people with hemophilic arthropathy (PWHA), very little is known about the neural control of individual muscles during movement. The aim of the present study was to assess if the neural control of individual muscles and coordination between antagonistic muscle pairs and joint kinematics during gait are affected in PWHA. Thirteen control subjects (CG) walked overground at their preferred and slow velocity (1 m/s), and 14 PWHA walked overground at the preferred velocity (1 m/s). Joint kinematics and temporal gait parameters were assessed using four inertial sensors. Surface electromyography (EMG) was collected from gluteus maximus (GMAX), gluteus medius (GMED), vastus medialis (VM), vastus lateralis (VL), rectus femoris (RF), medial gastrocnemius (MG), lateral gastrocnemius (LG), soleus (SOL), tibialis anterior (TA), semitendinosus (ST), and biceps femoris (BF). Waveforms were compared using the time-series analysis through statistical parametric mapping. In PWHA compared to CG, EMG amplitude during the stance phase was higher for LG (for both velocities of the CG), BF (slow velocity only), and ST (preferred velocity only) (p < 0.05). Co-contraction during the stance phase was higher for MG-TA, LG-TA, VL-BF, VM-ST, LG-VL, and MG-VM (both velocities) (p < 0.05). MG and LG were excited earlier (preferred velocity only) (p < 0.05). A later offset during the stance phase was found for VL, BF, and ST (both velocities), and BF and GMAX (preferred velocity only) (p < 0.05). In addition, the range of motion in knee and ankle joints was lower in PWHA (both velocities) and hip joint (preferred velocity only) (p < 0.05). In conclusion, the neural control of individual muscles and coordination between antagonistic muscles during gait in PWHA differs substantially from control subjects. [ABSTRACT FROM AUTHOR]

Published

2020

47. Electromyography and dynamometry in the prediction of risk of falls in the elderly using machine learning tools.

Author

da Silva, Daniele Alves, Castelo Branco, Nayra Ferreira Lima, de Andrade Mesquita, Laiana Sepúlveda, Castelo Branco, Hermes Manoel Galvão, and de Alencar Barreto, Guilherme

Subjects

MACHINE learning, OLDER people, ELECTROMYOGRAPHY, BICEPS femoris, TIBIALIS anterior, VASTUS lateralis, LEG muscles

Abstract

• Assessing the risk of falls in the elderly is important for effective care. • ML tools can be used to predict the risk of falls with both EMG and force signals. • ML tools are more effective in predicting BBS score using EMG signal. The aging process affects mechanisms for maintaining physical integrity. The assessment of the risk of falls is routine in the services of assistance to the elderly, but subjective and time-consuming, so that the automation of the process is desirable as a supporting tool. In this regard, the aim of this study is to carry out a comprehensive evaluation study on the use of machine learning techniques as an instrument to predict the Berg Balance Scale (BBS) score, using different sets of electromyographic and dynamometric data collected during a voluntary isometric contraction. Thirty participants were evaluated with the BBS and with electromyography and dynamometry of the vastus lateralis, biceps femoris, lateral gastrocnemius and tibialis anterior muscles during maximal isometric voluntary contractions. After pre-processing the dataset, the features were selected through principal components analysis (PCA), correlation-based function select (CFS) and relief-F to then be applied to the multilayer perceptron (MLP), random forest (RF), random tree (RT), k-nearest neighbors (KNN), Multiple Linear Regression (MLR), and least-squares support vector regression (LS-SVR). From the fitted regression models, our ultimate goal is to infer which selected features correlate most with the risk of falling for elderly people and how those features connect themselves to certain groups of muscles. In this regard, the features extracted from myoelectric signals proved to be more effective for use in predicting the risk of falls in the elderly in relation to the force-related signal. The proposed models obtained good results for predicting the BBS score and classifying the risk of falls. [ABSTRACT FROM AUTHOR]

Published

2024

48. Human Cutaneous Reflexes Evoked with Simultaneous Multiple Nerve Stimulation during Rhythmic Locomotor-Like Arm and Leg Cycling in Stroke Subjects

Author

Andersen, Ole Kæseler, Klimstra, Marc, Thomas, Evan, Loadman, Pamela M., Hundza, Sandra R., Zehr, E. Paul, Guglielmelli, Eugenio, Series editor, Jensen, Winnie, editor, Andersen, Ole Kæseler, editor, and Akay, Metin, editor

Published

2014

49. Electromyographic activity and kinematics of sit-to-stand in individuals with muscle disease.

Author

Sütçü, Gülşah, Yalçın, Ali İmran, Ayvat, Ender, Kılınç, Özge Onursal, Ayvat, Fatma, Doğan, Mert, Harput, Gülcan, Yıldırım, Sibel Aksu, and Kılınç, Muhammed

Subjects

*MUSCLE diseases, *BICEPS femoris, *RECTUS femoris muscles, *MUSCLE fatigue, *TIBIALIS anterior, *SOLEUS muscle, *PLICA syndrome, *FACIOSCAPULOHUMERAL muscular dystrophy, *MUSCULAR dystrophy, *SKELETAL muscle, *SELF-evaluation, *LEG, *ELECTROMYOGRAPHY, *MOTOR ability, *KINEMATICS, *HEALTH self-care, *PHYSIOLOGY

Abstract

Objective: The aim of this study was to compare activation levels of rectus femoris, biceps femoris, tibialis anterior, and soleus muscles and biomechanical properties of individuals with muscle disease and healthy individuals during sit-to-stand.Methods: Fifteen patients (11 muscular dystrophy, 4 myopathy) and 15 healthy individuals were included in the study. A Noraxon superficial electromyography device and high-speed cameras were used to evaluate muscle activations and biomechanical properties.Results: There was a difference between the activation levels of bilateral rectus femoris, tibialis anterior, soleus, and right biceps femoris of patients and healthy subjects (p < 0.05). When groups were compared in terms of biomechanical properties, there was no difference in the range of motion during sit-to-stand (p > 0.05), but there was a difference in phase 1: flexion momentum phase, phase 3: extension phase, phase 4: stabilization phase, and total time of sit-to-stand (p < 0.05).Conclusion: We observed that individuals with muscle disease are able to stand up in a similar sit-to-stand pattern to healthy individuals with longer duration and higher muscle activation levels. Prolonged high muscle activation during functional activities may cause fatigue and muscle destruction in patients. For this reason, planning of exercise programs for appropriate muscles and phases will enable the patients to perform the activity of sit-to-stand more easily. Thus, patients will become more functional and independent in their daily lives with less effort. [ABSTRACT FROM AUTHOR]

Published

2019

50. Effects of Increasing Balance Task Difficulty on Postural Sway and Muscle Activity in Healthy Adolescents.

Author

Gebel, Arnd, Lüder, Benjamin, and Granacher, Urs

Subjects

POSTURAL muscles, LEVEL of difficulty, BICEPS femoris, MULTIPLE regression analysis, TEENAGERS, TIBIALIS anterior

Abstract

Evidence-based prescriptions for balance training in youth have recently been established. However, there is currently no standardized means available to assess and quantify balance task difficulty (BTD). Therefore, the objectives of this study were to examine the effects of graded BTD on postural sway, lower limb muscle activity and coactivation in adolescents. Thirteen healthy high-school students aged 16 to 17 volunteered to participate in this cross-sectional study. Testing involved participants to stand on a commercially available balance board with an adjustable pivot that allowed six levels of increasing task difficulty. Postural sway [i.e., total center of pressure (CoP) displacements] and lower limb muscle activity were recorded simultaneously during each trial. Surface electromyography (EMG) was applied in muscles encompassing the ankle (m. tibialis anterior, medial gastrocnemius, peroneus longus) and knee joint (m. vastus medialis, biceps femoris). The coactivation index (CAI) was calculated for ankle and thigh muscles. Repeated measures analyses of variance revealed a significant main effect of BTD with increasing task difficulty for postural sway (p < 0.001; d = 6.36), muscle activity (p < 0.001; 2.19 < d < 4.88), and CAI (p < 0.001; 1.32 < d < 1.41). Multiple regression analyses showed that m. tibialis anterior activity best explained overall CoP displacements with 32.5% explained variance (p < 0.001). The observed increases in postural sway, lower limb muscle activity, and coactivation indicate increasing postural demands while standing on the balance board. Thus, the examined board can be implemented in balance training to progressively increase BTD in healthy adolescents. [ABSTRACT FROM AUTHOR]

Published

2019