How muscles work

How muscles work

In this short lesson, you will learn how muscles work, including how muscles contract, and how they respond to different amounts of load or weight.

Motor units

Skeletal muscle motor unit
Figure 1. Skeletal muscle motor unit.
Your skeletal muscles are controlled by your somatic nervous system. Muscle contractions are activated by nerve cells called motor neurons. A single motor neuron may stimulate between one and several hundred muscle fibers. Some motor neurons activate Type I fibers, while others activate Type IIa or Type IIb fibers. A motor neuron and the fibers that it stimulates are collectively called a motor unit. If a motor neuron fires, it activates all of the muscle fibers in its motor unit (Figure 1).

How motor units are recruited for contraction

The contraction of a single muscle is often coordinated by groups of motor units. The number of motor units involved in the contraction depends on the amount of load, weight, or resistance. If the load is light, a relatively small number of Type I motor units will be recruited. As the load increases, more Type I motor units will be called into action, and then Type IIa and Type IIb motor units, until all of the muscle’s motor units are utilized. This means that the only way to stimulate the entire muscle is to work with weights that are personally very heavy.

How muscles contract

As explained in Muscle structure, muscle fibers are composed of cylindrical strands called myofibrils, which are in turn composed of filaments of the proteins actin and myosin. The filaments, known as myofilaments, repeat in units called sarcomeres. The two ends of each sarcomere are marked by a Z disc.

Sarcomere and muscle fiber contraction
Figure 2. Muscle fiber contraction.

Sarcomeres are the basic functional units of muscle fibers. They form the basic machinery necessary for muscle contraction. If you understand how sarcomeres function, you will understand how muscles work.

Put simply, when an impulse from a motor neuron reaches the muscle fiber, it creates chemical changes that cause the actin filaments to slide along the myosin filaments, which shortens the length of the sarcomere and thus changes the length and shape of the muscle fiber (Figure 2). Once the stimulation stops, the actin and myosin filaments move apart, and the sarcomere (and thus the muscle fiber) returns to its resting length and shape.

More specifically, the thick myosin filaments possess protruding heads that can bind to the thin actin filaments. When an impulse hits the muscle fiber, the protruding heads of the myosin filaments bind to the actin filaments, after which the myosin filaments undergo a change in shape. The change in shape cocks the protruding heads of the myosin filaments, which pulls the actin filaments inwards. Since the actin filaments are anchored to the ends of the sarcomere (the Z discs), the sarcomere shortens in length. All of the sarcomeres in the muscle fiber shorten at the same time, producing the action we call contraction.

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