The active force–length relationship is invisible during extensive eccentric contractions in skinned skeletal muscle fibres

Tomalka, André; Rode, Christian; Schumacher, Jens; Siebert, Tobias

doi:10.1098/rspb.2016.2497

Cited by 35 publications

(50 citation statements)

References 74 publications

(124 reference statements)

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“…Assuming homogeneous titin properties across sarcomeres, bound titin is stiffer in initially longer half-sarcomeres [31]. (This result of the titin model is in accordance with recent muscle fibre experiments [59]). Hence, in subsequent stretches, titin forces increase disproportionately in half-sarcomeres, which are initially longer.…”

Section: Discussionsupporting

confidence: 73%

“…Hence, actin—titin interaction might be particularly important for stable operation of muscles working on the descending limb of the force—length relation. Moreover, history- and activation-dependent actin—titin interactions can explain the phenomenon of force enhancement more completely than the sarcomere—length inhomogeneity theory [31] (especially forces exceeding the maximum isometric force by large amounts, e. g. [59, 72]).…”

Section: Discussionmentioning

confidence: 99%

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A continuum-mechanical skeletal muscle model including actin-titin interaction predicts stable contractions on the descending limb of the force-length relation

et al. 2017

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Contractions on the descending limb of the total (active + passive) muscle force—length relationship (i. e. when muscle stiffness is negative) are expected to lead to vast half-sarcomere—length inhomogeneities. This is however not observed in experiments—vast half-sarcomere—length inhomogeneities can be absent in myofibrils contracting in this range, and initial inhomogeneities can even decrease. Here we show that the absence of half-sarcomere—length inhomogeneities can be predicted when considering interactions of the semi-active protein titin with the actin filaments. Including a model of actin—titin interactions within a multi-scale continuum-mechanical model, we demonstrate that stability, accurate forces and nearly homogeneous half-sarcomere lengths can be obtained on the descending limb of the static total force—length relation. This could be a key to durable functioning of the muscle because large local stretches, that might harm, for example, the transverse-tubule system, are avoided.

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Section: Discussionsupporting

confidence: 73%

Section: Discussionmentioning

confidence: 99%

A continuum-mechanical skeletal muscle model including actin-titin interaction predicts stable contractions on the descending limb of the force-length relation

et al. 2017

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“…As demonstrated by previous investigations [2,4,57], the excised rat heart trabeculae featured a monotonically increasing FLR. This is in contrast with the typical slope change between the shallow and steep slope regions at the ascending limb of the FLR in striated skeletal muscles [5,56]. In cardiac muscle, the mean total stress was at 0.75 L 0 about 3% of the maximal isometric stress, P 0 , accompanied with zero passive stress (figure 1a, grey dotted line).…”

Section: (B) Isometric Stress -Length Characteristicsmentioning

confidence: 71%

“…Comparing the mechanical response of skeletal [5] and cardiac muscle exposes differences in the underlying microstructure, in the force-producing mechanisms, and in the functioning of the respective muscles. Hence, the aim of our study was to investigate total force generation in intact cardiac trabeculae during extensive isokinetic eccentric contractions in order to examine a potential contribution of a calcium-dependent, adjustable spring element (i.e.…”

Section: Introductionmentioning

confidence: 99%

Extensive eccentric contractions in intact cardiac trabeculae: revealing compelling differences in contractile behaviour compared to skeletal muscles

et al. 2019

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Force enhancement (FE) is a phenomenon that is present in skeletal muscle. It is characterized by progressive forces upon active stretching—distinguished by a linear rise in force—and enhanced isometric force following stretching (residual FE (RFE)). In skeletal muscle, non-cross-bridge (XB) structures may account for this behaviour. So far, it is unknown whether differences between non-XB structures within the heart and skeletal muscle result in deviating contractile behaviour during and after eccentric contractions. Thus, we investigated the force response of intact cardiac trabeculae during and after isokinetic eccentric muscle contractions (10% of maximum shortening velocity) with extensive magnitudes of stretch (25% of optimum muscle length). The different contributions of XB and non-XB structures to the total muscle force were revealed by using an actomyosin inhibitor. For cardiac trabeculae, we found that the force–length dynamics during long stretch were similar to the total isometric force–length relation. This indicates that no (R)FE is present in cardiac muscle while stretching the muscle from 0.75 to 1.0 optimum muscle length. This finding is in contrast with the results obtained for skeletal muscle, in which (R)FE is present. Our data support the hypothesis that titin stiffness does not increase with activation in cardiac muscle.

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“…Even molecular muscle mechanics help to simplify control (e.g. [42][43][44]). A more exhaustive discussion of such specific muscle properties can be found in [38,45].…”

Section: Muscle Architecture and Muscle Propertiesmentioning

confidence: 99%

Biarticular muscles in light of template models, experiments and robotics: a review

Schumacher

Sharbafi

Seyfarth

et al. 2020

J. R. Soc. Interface.

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Leg morphology is an important outcome of evolution. A remarkable morphological leg feature is the existence of biarticular muscles that span adjacent joints. Diverse studies from different fields of research suggest a less coherent understanding of the muscles' functionality in cyclic, sagittal plane locomotion. We structured this review of biarticular muscle function by reflecting biomechanical template models, human experiments and robotic system designs. Within these approaches, we surveyed the contribution of biarticular muscles to the locomotor subfunctions (stance, balance and swing). While mono-and biarticular muscles do not show physiological differences, the reviewed studies provide evidence for complementary and locomotor subfunction-specific contributions of mono-and biarticular muscles. In stance, biarticular muscles coordinate joint movements, improve economy (e.g. by transferring energy) and secure the zig-zag configuration of the leg against joint overextension. These commonly known functions are extended by an explicit role of biarticular muscles in controlling the angular momentum for balance and swing. Human-like leg arrangement and intrinsic (compliant) properties of biarticular structures improve the controllability and energy efficiency of legged robots and assistive devices. Future interdisciplinary research on biarticular muscles should address their role for sensing and control as well as non-cyclic and/or non-sagittal motions, and non-static moment arms. royalsocietypublishing.org/journal/rsif J. R. Soc. Interface 17: 20180413 royalsocietypublishing.org/journal/rsif J. R. Soc. Interface 17: 20180413

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The active force–length relationship is invisible during extensive eccentric contractions in skinned skeletal muscle fibres

Cited by 35 publications

References 74 publications

A continuum-mechanical skeletal muscle model including actin-titin interaction predicts stable contractions on the descending limb of the force-length relation

A continuum-mechanical skeletal muscle model including actin-titin interaction predicts stable contractions on the descending limb of the force-length relation

Extensive eccentric contractions in intact cardiac trabeculae: revealing compelling differences in contractile behaviour compared to skeletal muscles

Biarticular muscles in light of template models, experiments and robotics: a review

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