Muscle in Variable Gravity: “I Do Not Know Where I Am, But I Know What to Do”

Monti, Elena; Waldvogel, Janice; Ritzmann, Ramona; Freyler, Kathrin; Albracht, Kirsten; Helm, Michael; Cesare, Niccolò de; Pavan, Piero G.; Reggiani, Carlo; Gollhofer, Albert; Narici, Marco V.

doi:10.3389/fphys.2021.714655

Cited by 3 publications

(4 citation statements)

References 44 publications

(110 reference statements)

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“…Consequently, due to insufficient muscle contraction, cross-bridges possibly are detached beyond their SRES ( Ishikawa et al, 2005 ) resulting in lower force generating capacity evidenced by the theoretical sarcomere contextualization. Similarly, during hyper-gravity-induced overload it was shown that the estimated sarcomere operating range shifts towards the ascending limb ( Monti et al, 2021 ). However, it has been shown that forces similar to those at 1 g can be generated after the deceleration phase ( Monti et al, 2021 ), suggesting that mechanically detached cross-bridges may reattach more rapidly during the take-off phase ( Ishikawa et al, 2005 ).…”

Section: Discussionmentioning

confidence: 98%

“…Similarly, during hyper-gravity-induced overload it was shown that the estimated sarcomere operating range shifts towards the ascending limb ( Monti et al, 2021 ). However, it has been shown that forces similar to those at 1 g can be generated after the deceleration phase ( Monti et al, 2021 ), suggesting that mechanically detached cross-bridges may reattach more rapidly during the take-off phase ( Ishikawa et al, 2005 ). Therefore, the data implies that lower pre-activity combined with reduced reflex associated muscle activity ( Helm et al, 2020 ) potentially impairs additional muscle generated contractile force (SRES and RFE effect) due to titin folding ( Eckels et al, 2018 ).…”

Section: Discussionmentioning

confidence: 98%

“…For the figures the averaged fascicle trajectories per subject and condition were normalized to the time interval from GC ranging until COM min . The sarcomere length was theoretically contextualized by the procedures reported by Monti et al (2021) . In detail sarcomere number was calculated by dividing the individual fascicle length while standing in an upright position by the reported sarcomere resting length of 3.09 μm measured in vivo in the same position ( Sanchez et al, 2015 ).…”

Section: Methodsmentioning

confidence: 99%

“…We acknowledge that this study has some limitations. First, the sarcomere length was contextualized based on fascicle data recorded by ultrasound ( Monti et al, 2021 ). As existing technology to directly measure sarcomere length in vivo is invasive ( Llewellyn et al, 2008 ; Sanchez et al, 2015 ; Lichtwark et al, 2018 ) and is not yet applicable to dynamic movements, the theoretically derived contextualisation was the only way to get an detailed insight into the force-length relationship on the sarcomere level, however the results only represents average sarcomere behaviour, therefore allowing only limited conclusion.…”

Section: Limitationsmentioning

confidence: 99%

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Energy transfer in reactive movements as a function of individual stretch load

Waldvogel,

Freyler,

Ritzmann

et al. 2023

Front. Physiol.

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Background: By directly recording electromyographic activity profiles and muscle-tendon interaction, this study aimed to elucidate the mechanisms why well-trained track and field athletes (experts) are able to outperform untrained individuals without former systematic experience in reactive jump training (novices). In particular, reactive power output and the elastic recoil properties of the muscle-tendon unit (MTU) were of special interest. For this purpose, stiffness regulation on muscle and joint level, energy management in terms of storing or dissipating elastic energy were compared between experts and novices during various stretch loads.Methods: Experts were compared with novices during reactive drop jumps (DJs) from drop heights ranging between 25 and 61 cm. Delta kinetic energy (Ekin) was calculated as the difference between the Ekin at take-off and ground contact (GC) to determine energy management. By recording electromyography of the lower limb muscles, in vivo fascicle dynamics (gastrocnemius medialis) and by combining kinematics and kinetics in a 3D inverse dynamics approach to compute ankle and knee joint kinetics, this study aimed to compare reactive jump performance, the neuromuscular activity and muscle-tendon interaction between experts and novices among the tested stretch loads.Results: Experts demonstrated significantly higher power output during DJs. Among all drop heights experts realized higher delta Ekin compared to novices. Consequently, higher reactive jump performance shown for experts was characterized by shorter GC time (GCT), higher jump heights and higher neuromuscular activity before and during the GC phase compared to novices. Concomitantly, experts were able to realize highest leg stiffness and delta Ekin in the lowest stretch load; however, both groups compensated the highest stretch load by prolonged GCT and greater joint flexion. On muscle level, experts work quasi-isometrically in the highest stretch load, while in novices GM fascicles were forcefully stretched.Conclusion: Group-specific stiffness regulation and elastic recoil properties are primarily influenced by the neuromuscular system. Due to their higher neuromuscular activity prior and during the GC phase, experts demonstrate higher force generating capacity. A functionally stiffer myotendinous system through enhanced neuromuscular input enables the experts loading their elastic recoil system more efficiently, thus realizing higher reactive power output and allowing a higher amount of energy storage and return. This mechanism is regulated in a stretch load dependent manner.

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Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 98%

Section: Methodsmentioning

confidence: 99%

Section: Limitationsmentioning

confidence: 99%

See 2 more Smart Citations

Energy transfer in reactive movements as a function of individual stretch load

Waldvogel,

Freyler,

Ritzmann

et al. 2023

Front. Physiol.

Self Cite

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Changes in gravity affect neuromuscular control, biomechanics, and muscle-tendon mechanics in energy storage and dissipation tasks

Waldvogel

Freyler

Helm

et al. 2023

Journal of Applied Physiology

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This study evaluates neuromechanical control and muscle-tendon interaction during energy storage and dissipation tasks in hypergravity. During parabolic flights, while 17 subjects performed drop jumps (DJs) and drop landings (DLs), electromyography (EMG) of the lower limb muscles was combined with in vivo fascicle dynamics of the gastrocnemius medialis, 2D kinematics, and kinetics to measure and analyze changes in energy management. Comparisons were made between movement modalities executed in hypergravity (1.8G) and gravity on ground (1G). In 1.8G, ankle dorsiflexion, knee joint flexion, and vertical center of mass (COM) displacement are lower in DJs than in DLs; within each movement modality, joint flexion amplitudes and COM displacement demonstrate higher values in 1.8G than in 1G. Concomitantly, negative peak ankle joint power, vertical ground reaction forces, and leg stiffness are similar between both movement modalities (1.8G). In DJs, EMG activity in 1.8G is lower during the COM deceleration phase than in 1G, thus impairing quasi-isometric fascicle behavior. In DLs, EMG activity before and during the COM deceleration phase is higher and fascicles are stretched less in 1.8G than in 1G. Compared to the situation in 1G, highly task-specific neuromuscular activity is diminished in 1.8G, resulting in fascicle lengthening in both movement modalities. Specifically, in DJs, a high magnitude of neuromuscular activity is impaired, resulting in altered energy storage. In contrast, in DLs, linear stiffening of the system due to higher neuromuscular activity combined with lower fascicle stretch enhances the buffering function of the tendon, and thus the capacity to safely dissipate energy.

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Realizing the gravity of the simulation: adaptation to simulated hypogravity leads to altered predictive control

Rock,

Kwak,

Luo

et al. 2024

Front. Physiol.

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Accurate predictive abilities are important for a wide variety of animal behaviors. Inherent to many of these predictions is an understanding of the physics that underlie the behavior. Humans are specifically attuned to the physics on Earth but can learn to move in other environments (e.g., the surface of the Moon). However, the adjustments made to their physics-based predictions in the face of altered gravity are not fully understood. The current study aimed to characterize the locomotor adaptation to a novel paradigm for simulated reduced gravity. We hypothesized that exposure to simulated hypogravity would result in updated predictions of gravity-based movement. Twenty participants took part in a protocol that had them perform vertically targeted countermovement jumps before (PRE), during, and after (POST) a physical simulation of hypogravity. Jumping in simulated hypogravity had different neuromechanics from the PRE condition, with reduced ground impulses (p ≤ .009) and muscle activity prior to the time of landing (i.e., preactivation; p ≤ .016). In the 1 g POST condition, muscle preactivation remained reduced (p ≤ .033) and was delayed (p ≤ .008) by up to 33% for most muscles of the triceps surae, reflecting an expectation of hypogravity. The aftereffects in muscle preactivation, along with little-to-no change in muscle dynamics during ground contact, point to a neuromechanical adaptation that affects predictive, feed-forward systems over feedback systems. As such, we conclude that the neural representation, or internal model, of gravity is updated after exposure to simulated hypogravity.

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Muscle in Variable Gravity: “I Do Not Know Where I Am, But I Know What to Do”

Cited by 3 publications

References 44 publications

Energy transfer in reactive movements as a function of individual stretch load

Energy transfer in reactive movements as a function of individual stretch load

Changes in gravity affect neuromuscular control, biomechanics, and muscle-tendon mechanics in energy storage and dissipation tasks

Realizing the gravity of the simulation: adaptation to simulated hypogravity leads to altered predictive control

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