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The sliding filament theory is a widely accepted explanation of the mechanism that underlies muscle contraction. [ 6 ] This model shows the four main and significant steps of the sliding filament theory as well as with a detailed visual.
During this step ADP and Pi are released. In step 3 a new ATP binds to the myosin head and the cross bridge between the myosin and actin detach. In the last step the myosin head uses the new ATP to return to its erect state and is now ready to repeat the cycle.
Sliding filament theory: A sarcomere in relaxed (above) and contracted (below) positions. The sliding filament theory describes a process used by muscles to contract. It is a cycle of repetitive events that cause a thin filament to slide over a thick filament and generate tension in the muscle. [22]
A diagram of the structure of a myofibril (consisting of many myofilaments in parallel, and sarcomeres in series) Sliding filament model of muscle contraction. The myosin heads form cross bridges with the actin myofilaments; this is where they carry out a 'rowing' action along the actin. When the muscle fibre is relaxed (before contraction ...
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In effect, the thick filament moves or slides along the thin filament, resulting in muscle contraction. This process is known as the sliding filament model. The binding of the myosin heads to the muscle actin is a highly regulated process. The thin filament is made of actin, tropomyosin, and troponin.
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Phosphorylated myosin is able to form crossbridges with actin thin filaments, and the smooth muscle fiber (i.e., cell) contracts via the sliding filament mechanism. (See reference [13] for an illustration of the signaling cascade involving L-type calcium channels in smooth muscle).