Large-scale Models Reveal the Two-component Mechanics of Striated Muscle

Jarosch, R.

doi:10.3390/ijms9122658

Cited by 12 publications

(18 citation statements)

References 222 publications

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“…For example, an in vitro motility assay demonstrated that actin filaments gliding over a myosin-coated coverslip surface can rotate around their long axis 61,62 and form a superhelix 63 . Also, the actin filament can undergo a rolling sliding motion in sarcomeres 64,65 . The torque may cause the generation of torsion in the myofilaments as sarcomeres contract.…”

Section: Scientific Reportsmentioning

confidence: 99%

Nanoscopic changes in the lattice structure of striated muscle sarcomeres involved in the mechanism of spontaneous oscillatory contraction (SPOC)

Kono

Kawai

Shimamoto

et al. 2020

Sci Rep

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Muscles perform a wide range of motile functions in animals. Among various types are skeletal and cardiac muscles, which exhibit a steady auto-oscillation of force and length when they are activated at an intermediate level of contraction. This phenomenon, termed spontaneous oscillatory contraction or SPOC, occurs devoid of cell membranes and at fixed concentrations of chemical substances, and is thus the property of the contractile system per se. We have previously developed a theoretical model of SPOC and proposed that the oscillation emerges from a dynamic force balance along both the longitudinal and lateral axes of sarcomeres, the contractile units of the striated muscle. Here, we experimentally tested this hypothesis by developing an imaging-based analysis that facilitates detection of the structural changes of single sarcomeres at unprecedented spatial resolution. We found that the sarcomere width oscillates anti-phase with the sarcomere length in SPOC. We also found that the oscillatory dynamics can be altered by osmotic compression of the myofilament lattice structure of sarcomeres, but they are unchanged by a proteolytic digestion of titin/connectin—the spring-like protein that provides passive elasticity to sarcomeres. Our data thus reveal the three-dimensional mechanical dynamics of oscillating sarcomeres and suggest a structural requirement of steady auto-oscillation.

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Section: Scientific Reportsmentioning

confidence: 99%

Nanoscopic changes in the lattice structure of striated muscle sarcomeres involved in the mechanism of spontaneous oscillatory contraction (SPOC)

Kono

Kawai

Shimamoto

et al. 2020

Sci Rep

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“…A series of steps should produce more friction since the redeveloped force after each quick release depends on additional internal rotation during rewinding the Z-filaments [2]. …”

Section: The Underlying Mechanicsmentioning

confidence: 99%

The Different Muscle-Energetics during Shortening and Stretch

Jarosch

2011

IJMS

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The helical shape of the thin filaments causes their passive counterclockwise rotation during muscle stretch that increases tensile stress and torque at first by unwinding and then by winding up the four anchoring Z-filaments. This means storage of energy in the series elastic Z-filaments and a considerable decrease of the liberated energy of heat and work to (h—wap), where h is the heat energy and wap the stretch energy induced from outside by an apparatus. The steep thin filament helix with an inclination angle of 70° promotes the passive rotation during stretch, but impedes the smooth sliding of shortening by increased friction and production of frictional heat. The frictional heat may be produced by the contact with the myosin cross-bridges: (1) when they passively snap on drilling thin filaments from cleft to cleft over a distance 2 × 2.7 nm = 5.4 nm between the globular actin monomers in one groove, causing stepwise motion; or (2) when they passively cycle from one helical groove to the next (distance 36 nm). The latter causes more heat and may take place on rotating thin filaments without an effective forward drilling (“idle rotation”), e.g., when they produce “unexplained heat” at the beginning of an isometric tetanus. In an Appendix to this paper the different states of muscle are defined. The function of its most important components is described and rotation model and power-stroke model of muscular contraction is compared.

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“…Heat also increases glycogen resynthesis and muscle recovery [10]. Heat is also cited as increasing flexibility and thus reducing the chance of injury, and reducing energy cost of muscle contraction by reducing internal friction [11,12]. Internal energy costs are reduced by warming muscle, but many of these studies have been done in animals and very few in humans.…”

Section: Introductionmentioning

confidence: 99%

“…The response of stretch receptors in the cat are also increased by heat [15]. The mechanism of the changes in the series’ elastic component is partly due to unwinding of the actin filaments in muscle due to stretch and partly due to collagen relaxation [11,12]. There is also rotation of the actin filaments with heat [11].…”

Section: Introductionmentioning

confidence: 99%

“…The mechanism of the changes in the series’ elastic component is partly due to unwinding of the actin filaments in muscle due to stretch and partly due to collagen relaxation [11,12]. There is also rotation of the actin filaments with heat [11]. While there is some evidence that heat increases muscle flexibility in humans, there has been no study of where the benefit is (parallel or series elastic components, or how long the benefit lasts) [16–19].…”

Section: Introductionmentioning

confidence: 99%

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Effect of heat and cold on tendon flexibility and force to flex the human knee

Lee

2013

Med Sci Monit

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BackgroundIt is commonly believed in medicine that using heat will increase the distensability and flexibility of soft tissue. If true, increased flexibility would be a positive factor to reduce injuries in sports. However, cold should have the opposite effect and is often used to treat sports injuries. This study was accomplished to quantify the effect of heat and cold on the force needed to flex the knee and laxness of the anterior and posterior cruciate ligaments.Material/MethodsThe present study examined 20 male and female subjects to determine if heat would increase extensibility of the anterior and posterior cruciate ligaments of the knee and reduce the force needed to flex the knee. Cold exposure was examined to see if it would have the opposite effect. There were 4 experiments in the series: The first was a room temperature series; the second was a series where cold was applied with an ice pack for 20 minutes; in the third, hydrocollator heat packs were applied for 20 minutes; and in the fourth, ThermaCare heat wraps were applied for 4 hours on the quadriceps and knee. Tendon extensibility was measured with a KT2000. The force for flexing the knee was measured by passive movement being applied (CPM) to the knee through 30° and the force required to move the leg was measured.ResultsThe results show that the anterior and posterior cruciate ligament flexibility increased and the force needed to move the knee decreased with heat by about 25% compared to cold application.ConclusionsHeat is beneficial in increasing muscle and ligament flexibility and may help reduce athletic injuries, but cold treatment may have the opposite effect.

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Large-scale Models Reveal the Two-component Mechanics of Striated Muscle

Cited by 12 publications

References 222 publications

Nanoscopic changes in the lattice structure of striated muscle sarcomeres involved in the mechanism of spontaneous oscillatory contraction (SPOC)

Nanoscopic changes in the lattice structure of striated muscle sarcomeres involved in the mechanism of spontaneous oscillatory contraction (SPOC)

The Different Muscle-Energetics during Shortening and Stretch

Effect of heat and cold on tendon flexibility and force to flex the human knee

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