On the ascent: the soleus operating length is conserved to the ascending limb of the force-length curve across gait mechanics in humans

The goal of this study was to gain insight into how ankle exoskeletons affect the behavior of the plantarflexor muscles during walking. Using data from previous experiments, we performed electromyographydriven simulations of musculoskeletal dynamics to explore how changes in exoskeleton assistance affected plantarflexor muscletendon mechanics, particularly for the soleus. We used a model of muscle energy consumption to estimate individual muscle metabolic rate. As average exoskeleton torque was increased, while no net exoskeleton work was provided, a reduction in tendon recoil led to an increase in positive mechanical work performed by the soleus muscle fibers. As net exoskeleton work was increased, both soleus muscle fiber force and positive mechanical work decreased. Trends in the sum of the metabolic rates of the simulated muscles correlated well with trends in experimentally observed whole-body metabolic rate (R 2 =0.9), providing confidence in our model estimates. Our simulation results suggest that different exoskeleton behaviors can alter the functioning of the muscles and tendons acting at the assisted joint. Furthermore, our results support the idea that the series tendon helps reduce positive work done by the muscle fibers by storing and returning energy elastically. We expect the results from this study to promote the use of electromyography-driven simulations to gain insight into the operation of muscle-tendon units and to guide the design and control of assistive devices.

Section: Discussionsupporting

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Muscle-tendon mechanics explain unexpected effects of exoskeleton assistance on metabolic rate during walking

Jackson

Dembia

Delp

et al. 2017

“…Previous studies investigating the behavior of the lateral gastrocnemius in the turkey and the wallaby found similar nearisometric muscle fiber contractions, irrespective of locomotion speed (Taylor, 1994;Roberts et al, 1997;Biewener et al, 1998;Gabaldón et al, 2008). Muscle fiber length change for the human ankle plantar-flexors has also been observed to be small during running in experimental studies involving dynamic ultrasound recordings (Lichtwark et al, 2007;Farris and Sawicki, 2012;Rubenson et al, 2012;Cronin and Finni, 2013) as well as in a recent musculoskeletal modeling study (Arnold et al, 2013). The small muscle fiber length change noted in these studies (and in the present study) implies that the soleus and gastrocnemius muscle fibers operate under favorable contractile conditions on their force-velocity (F-V) relationship, allowing the development of larger muscle forces than would otherwise be possible.…”

Section: −1mentioning

confidence: 88%

Tendon elastic strain energy in the human ankle plantar-flexors and its role with increased running speed

Lai

Schache

Lin

et al. 2014

112

125

The human ankle plantar-flexors, the soleus and gastrocnemius, utilize tendon elastic strain energy to reduce muscle fiber work and optimize contractile conditions during running. However, studies to date have considered only slow to moderate running speeds up to 5 m s −1 . Little is known about how the human ankle plantar-flexors utilize tendon elastic strain energy as running speed is advanced towards maximum sprinting. We used data obtained from gait experiments in conjunction with musculoskeletal modeling and optimization techniques to calculate muscle-tendon unit (MTU) work, tendon elastic strain energy and muscle fiber work for the ankle plantar-flexors as participants ran at five discrete steady-state speeds ranging from jogging (~2 m s −1 ) to sprinting (≥8 m s −1 ). As running speed progressed from jogging to sprinting, the contribution of tendon elastic strain energy to the positive work generated by the MTU increased from 53% to 74% for the soleus and from 62% to 75% for the gastrocnemius. This increase was facilitated by greater muscle activation and the relatively isometric behavior of the soleus and gastrocnemius muscle fibers. Both of these characteristics enhanced tendon stretch and recoil, which contributed to the bulk of the change in MTU length. Our results suggest that as steady-state running speed is advanced towards maximum sprinting, the human ankle plantar-flexors continue to prioritize the storage and recovery of tendon elastic strain energy over muscle fiber work.

“…Passive forces are not developed in muscle typically until after the length at which peak active muscle force is produced. In cases where we have measurements of muscle operating length during locomotion, most force production appears to occur at lengths less than that at which passive force is developed Rubenson et al, 2012). If non-cross-bridge elements are stiffened in the presence of Ca 2+ , the fiber lengths at which they can contribute force may be shorter than suggested by the passive force-length curve.…”

Section: Titin-and Single-fiber-based Passive Forcesmentioning

confidence: 94%

Contribution of elastic tissues to the mechanics and energetics of muscle function during movement

Roberts

2016

159

115

Muscle force production occurs within an environment of tissues that exhibit spring-like behavior, and this elasticity is a critical determinant of muscle performance during locomotion. Muscle force and power output both depend on the speed of contraction, as described by the isotonic force-velocity curve. By influencing the speed of contractile elements, elastic structures can have a profound effect on muscle force, power and work. In very rapid movements, elastic mechanisms can amplify muscle power by storing the work of muscle contraction slowly and releasing it rapidly. When energy must be dissipated rapidly, such as in landing from a jump, energy stored rapidly in elastic elements can be released more slowly to stretch muscle contractile elements, reducing the power input to muscle and possibly protecting it from damage. Elastic mechanisms identified so far rely primarily on in-series tendons, but many structures within muscles exhibit springlike properties. Actomyosin cross-bridges, actin and myosin filaments, titin, and the connective tissue scaffolding of the extracellular matrix all have the potential to store and recover elastic energy during muscle contraction. The potential contribution of these elements can be assessed from their stiffness and estimates of the strain they undergo during muscle function. Such calculations provide boundaries for the possible roles these springs might play in locomotion, and may help to direct future studies of the uses of elastic elements in muscle.