The primary function of muscle is
contraction. Myokines in turn are believed to mediate the health benefits of
exercise. Myokines are secreted into the bloodstream after muscle contraction.
Interleukin 6 (IL-6) is the most studied myokine, other muscle contraction-induced myokines include
BDNF,
FGF21, and
SPARC. Muscle also functions to produce body heat. Muscle contraction is responsible for producing 85% of the body's heat. This heat produced is as a by-product of muscular activity, and is mostly wasted. As a
homeostatic response to extreme cold, muscles are signaled to trigger contractions of
shivering in order to generate heat.
Contraction Contraction is achieved by the muscle's structural unit, the muscle fiber, and by its functional unit, the
motor unit. In addition to the
actin and
myosin myofilaments in the
myofibrils that make up the contractile
sarcomeres, there are two other important regulatory proteins –
troponin and
tropomyosin, that make muscle contraction possible. These proteins are associated with actin and cooperate to prevent its interaction with myosin. Once a cell is sufficiently stimulated, the cell's
sarcoplasmic reticulum releases ionic calcium (Ca2+), which then interacts with the regulatory protein troponin. Calcium-bound troponin undergoes a conformational change that leads to the movement of tropomyosin, subsequently exposing the myosin-binding sites on actin. This allows for myosin and actin ATP-dependent
cross-bridge cycling and shortening of the muscle.
Excitation-contraction coupling Excitation contraction coupling is the process by which a
muscular action potential in the muscle fiber causes the
myofibrils to contract. This process relies on a direct coupling between the
sarcoplasmic reticulum calcium release channel
RYR1 (ryanodine receptor 1), and
voltage-gated L-type calcium channels (identified as dihydropyridine receptors, DHPRs). DHPRs are located on the sarcolemma (which includes the surface sarcolemma and the
transverse tubules), while the RyRs reside across the SR membrane. The close apposition of a transverse tubule and two SR regions containing RyRs is described as a triad and is predominantly where excitation–contraction coupling takes place. Excitation–contraction coupling occurs when depolarization of skeletal muscle cell results in a muscle action potential, which spreads across the cell surface and into the muscle fiber's network of
T-tubules, thereby depolarizing the inner portion of the muscle fiber. Depolarization of the inner portions activates dihydropyridine receptors in the terminal cisternae, which are close to ryanodine receptors in the adjacent
sarcoplasmic reticulum. The activated dihydropyridine receptors physically interact with ryanodine receptors to activate them via foot processes (involving conformational changes that allosterically activates the ryanodine receptors). As the ryanodine receptors open, is released from the sarcoplasmic reticulum into the local junctional space and diffuses into the bulk cytoplasm to cause a
calcium spark. The sarcoplasmic reticulum has a large
calcium buffering capacity partially due to a
calcium-binding protein called
calsequestrin. The near synchronous activation of thousands of
calcium sparks by the action potential causes a cell-wide increase in calcium giving rise to the upstroke of the
calcium transient. The released into the cytosol binds to
Troponin C by the
actin filaments, to allow crossbridge cycling, producing force and, in some situations, motion. The
sarco/endoplasmic reticulum calcium-ATPase (SERCA) actively pumps back into the sarcoplasmic reticulum. As declines back to resting levels, the force declines and relaxation occurs.
Muscle movement The
efferent leg of the
peripheral nervous system is responsible for conveying commands to the muscles and glands, and is ultimately responsible for voluntary movement.
Nerves move muscles in response to
voluntary and
autonomic (involuntary) signals from the
brain. Deep muscles, superficial muscles,
muscles of the face and internal muscles all correspond with dedicated regions in the
primary motor cortex of the
brain, directly anterior to the central sulcus that divides the frontal and parietal lobes. In addition, muscles that react to
reflexive nerve stimuli do not always send signals all the way to the brain. In this case, the signal from the afferent fiber does not reach the brain, but produces the reflexive movement by direct connections with the efferent nerves in the
spine. However, the majority of muscle activity is volitional, and the result of complex interactions between various areas of the brain like the
basal ganglia,
thalamus,
cerebellum, and other neuron groups in the midbrain and
brain stem. Nerves that control skeletal muscles in
mammals correspond with neuron groups along the primary motor cortex of the brain's
cerebral cortex. Commands are routed through the basal ganglia and are modified by input from the cerebellum before being relayed through the
pyramidal tract to the
spinal cord and from there to the
motor end plate at the muscles. Along the way, feedback, such as that of the
extrapyramidal system contribute signals to influence
muscle tone and response. Deeper muscles such as those involved in
posture often are controlled from nuclei in the brain stem and basal ganglia.
Proprioception In skeletal muscles,
muscle spindles convey information about the degree of muscle length and stretch to the central nervous system to assist in maintaining posture and joint position. The
sense of where our bodies are in space is called
proprioception, the perception of body awareness, the "unconscious" awareness of where the various regions of the body are located at any one time. Several areas in the brain coordinate movement and position with the feedback information gained from proprioception. The cerebellum and
red nucleus in particular continuously sample position against movement and make minor corrections to assure smooth motion.
Energy consumption . If oxygen is not available, pyruvic acid is converted to lactic acid, which may contribute to
muscle fatigue. This occurs during strenuous exercise when high amounts of energy are needed but oxygen cannot be sufficiently delivered to muscle. (c) Aerobic respiration is the breakdown of glucose in the presence of oxygen (O2) to produce carbon dioxide, water, and ATP. Approximately 95 percent of the ATP required for resting or moderately active muscles is provided by aerobic respiration, which takes place in mitochondria. Muscular activity accounts for much of the body's
energy consumption. All muscle cells produce
adenosine triphosphate (ATP) molecules which are used to power the movement of the
myosin heads. Muscles have a short-term store of energy in the form of
creatine phosphate which is generated from ATP and can regenerate ATP when needed with
creatine kinase. Muscles also keep a storage form of glucose in the form of
glycogen. Glycogen can be rapidly converted to
glucose when energy is required for sustained, powerful contractions. Within the voluntary skeletal muscles, the glucose molecule can be metabolized anaerobically in a process called glycolysis which produces two ATP and two
lactic acid molecules in the process (in aerobic conditions, lactate is not formed; instead
pyruvate is formed and transmitted through the
citric acid cycle). Muscle cells also contain globules of fat, which are used for energy during
aerobic exercise. The aerobic energy systems take longer to produce the ATP and reach peak efficiency, and requires many more biochemical steps, but produces significantly more ATP than anaerobic glycolysis. Cardiac muscle on the other hand, can readily consume any of the three macronutrients (protein, glucose and fat) aerobically without a 'warm up' period and always extracts the maximum ATP yield from any molecule involved. The heart, liver and red blood cells will also consume lactic acid produced and excreted by skeletal muscles during exercise. Skeletal muscle uses more calories than other organs. At rest it consumes 54.4 kJ/kg (13.0 kcal/kg) per day. This is larger than
adipose tissue (fat) at 18.8 kJ/kg (4.5 kcal/kg), and bone at 9.6 kJ/kg (2.3 kcal/kg).
Efficiency The
efficiency of human muscle has been measured (in the context of
rowing and
cycling) at 18% to 26%. The efficiency is defined as the ratio of
mechanical work output to the total
metabolic cost, as can be calculated from oxygen consumption. This low efficiency is the result of about 40% efficiency of generating
ATP from
food energy, losses in converting energy from ATP into mechanical work inside the muscle, and mechanical losses inside the body. The latter two losses are dependent on the type of exercise and the type of muscle fibers being used (fast-twitch or slow-twitch). For an overall efficiency of 20 percent, one watt of mechanical power is equivalent to 4.3 kcal per hour. For example, one manufacturer of rowing equipment calibrates its
rowing ergometer to count burned calories as equal to four times the actual mechanical work, plus 300 kcal per hour, this amounts to about 20 percent efficiency at 250 watts of mechanical output. The mechanical energy output of a cyclic contraction can depend upon many factors, including activation timing, muscle strain trajectory, and rates of force rise & decay. These can be synthesized experimentally using
work loop analysis.
Muscle strength Muscle strength is a result of three overlapping factors:
physiological strength (muscle size, cross sectional area, available crossbridging, responses to training),
neurological strength (how strong or weak is the signal that tells the muscle to contract), and
mechanical strength (muscle's force angle on the lever, moment arm length, joint capabilities). Vertebrate muscle typically produces approximately of force per square centimeter of muscle cross-sectional area when isometric and at optimal length. Some
invertebrate muscles, such as in crab claws, have much longer
sarcomeres than vertebrates, resulting in many more sites for actin and myosin to bind and thus much greater force per square centimeter at the cost of much slower speed. The force generated by a contraction can be measured non-invasively using either
mechanomyography or
phonomyography, be measured
in vivo using tendon strain (if a prominent tendon is present), or be measured directly using more invasive methods. The strength of any given muscle, in terms of force exerted on the skeleton, depends upon
length, shortening speed, cross sectional area,
pennation,
sarcomere length,
myosin isoforms, and neural activation of
motor units. Significant reductions in muscle strength can indicate underlying pathology, with the chart at right used as a guide. The
maximum holding time for a contracted muscle depends on its supply of energy and is stated by
Rohmert's law to
exponentially decay from the beginning of exertion.
The "strongest" human muscle Since three factors affect muscular strength simultaneously and muscles never work individually, it is misleading to compare strength in individual muscles, and state that one is the "strongest". But below are several muscles whose strength is noteworthy for different reasons. • In ordinary parlance, muscular "strength" usually refers to the ability to exert a force on an external object—for example, lifting a weight. By this definition, the
masseter or
jaw muscle is the strongest. The 1992
Guinness Book of Records records the achievement of a bite strength of for 2 seconds. What distinguishes the masseter is not anything special about the muscle itself, but its advantage in working against a much shorter lever arm than other muscles. • If "strength" refers to the force exerted by the muscle itself, e.g., on the place where it inserts into a bone, then the strongest muscles are those with the largest cross-sectional area. This is because the tension exerted by an individual skeletal
muscle fiber does not vary much. Each fiber can exert a force on the order of 0.3 micronewton. By this definition, the strongest muscle of the body is usually said to be the
quadriceps femoris or the
gluteus maximus. • Because muscle strength is determined by cross-sectional area, a shorter muscle will be stronger "pound for pound" (i.e., by
weight) than a longer muscle of the same cross-sectional area. The
myometrial layer of the uterus may be the strongest muscle by weight in the female body. At the time when an
infant is delivered, the entire uterus weighs about 1.1 kg (40 oz). During childbirth, the uterus exerts 100 to 400 N (25 to 100 lbf) of downward force with each contraction. • The external muscles of the eye are conspicuously large and strong in relation to the small size and weight of the
eyeball. It is frequently said that they are "the strongest muscles for the job they have to do" and are sometimes claimed to be "100 times stronger than they need to be." However, eye movements (particularly
saccades used on facial scanning and reading) do require high speed movements, and eye muscles are exercised nightly during
rapid eye movement sleep. • The statement that "the
tongue is the strongest muscle in the body" appears frequently in lists of surprising facts, but it is difficult to find any definition of "strength" that would make this statement true. The tongue consists of eight muscles, not one.
Force generation Muscle force is proportional to
physiological cross-sectional area (PCSA), and muscle velocity is proportional to muscle fiber length. The torque around a joint, however, is determined by a number of biomechanical parameters, including the distance between muscle insertions and pivot points, muscle size and
architectural gear ratio. Muscles are normally arranged in opposition so that when one group of muscles contracts, another group relaxes or lengthens. Antagonism in the transmission of nerve impulses to the muscles means that it is impossible to fully stimulate the contraction of two
antagonistic muscles at any one time. During ballistic motions such as throwing, the antagonist muscles act to 'brake' the
agonist muscles throughout the contraction, particularly at the end of the motion. In the example of throwing, the chest and front of the shoulder (anterior deltoid) contract to pull the arm forward, while the muscles in the back and rear of the shoulder (posterior deltoid) also contract and undergo eccentric contraction to slow the motion down to avoid injury. Part of the training process is learning to relax the antagonist muscles to increase the force input of the chest and anterior shoulder. Contracting muscles produce vibration and sound. Slow twitch fibers produce 10 to 30 contractions per second (10 to 30 Hz). Fast twitch fibers produce 30 to 70 contractions per second (30 to 70 Hz). The vibration can be witnessed and felt by highly tensing one's muscles, as when making a firm fist. The sound can be heard by pressing a highly tensed muscle against the ear, again a firm fist is a good example. The sound is usually described as a rumbling sound. Some individuals can voluntarily produce this rumbling sound by contracting the
tensor tympani muscle of the middle ear. The rumbling sound can also be heard when the neck or jaw muscles are highly tensed.
Signal transduction pathways Skeletal muscle fiber-type phenotype in adult animals is regulated by several independent signaling pathways. These include pathways involved with the
Ras/mitogen-activated protein kinase (
MAPK) pathway, calcineurin, calcium/calmodulin-dependent protein kinase IV, and the peroxisome proliferator γ coactivator 1 (PGC-1). The
Ras/MAPK signaling pathway links the motor neurons and signaling systems, coupling excitation and transcription regulation to promote the nerve-dependent induction of the slow program in regenerating muscle.
Calcineurin, a Ca2+/
calmodulin-activated
phosphatase implicated in nerve activity-dependent fiber-type specification in skeletal muscle, directly controls the phosphorylation state of the transcription factor
NFAT, allowing for its translocation to the nucleus and leading to the activation of slow-type muscle proteins in cooperation with myocyte enhancer factor 2 (
MEF2) proteins and other regulatory proteins.
Ca2+/calmodulin-dependent protein kinase activity is also upregulated by slow motor neuron activity, possibly because it amplifies the slow-type calcineurin-generated responses by promoting MEF2
transactivator functions and enhancing oxidative capacity through stimulation of
mitochondrial biogenesis. Contraction-induced changes in intracellular calcium or reactive oxygen species provide signals to diverse pathways that include the MAPKs, calcineurin and calcium/calmodulin-dependent protein kinase IV to activate transcription factors that regulate gene expression and enzyme activity in skeletal muscle. PGC1-α (
PPARGC1A), a transcriptional coactivator of nuclear receptors important to the regulation of a number of mitochondrial genes involved in oxidative metabolism, directly interacts with MEF2 to synergistically activate selective slow twitch (ST) muscle genes and also serves as a target for calcineurin signaling. A peroxisome proliferator-activated receptor δ (
PPARδ)-mediated transcriptional pathway is involved in the regulation of the skeletal muscle fiber phenotype. Mice that harbor an activated form of PPARδ display an "endurance" phenotype, with a coordinated increase in oxidative enzymes and
mitochondrial biogenesis and an increased proportion of ST fibers. Thus—through functional genomics—calcineurin, calmodulin-dependent kinase, PGC-1α, and activated PPARδ form the basis of a signaling network that controls skeletal muscle fiber-type transformation and metabolic profiles that protect against insulin resistance and obesity. The transition from aerobic to anaerobic metabolism during intense work requires that several systems are rapidly activated to ensure a constant supply of ATP for the working muscles. These include a switch from fat-based to carbohydrate-based fuels, a redistribution of blood flow from nonworking to exercising muscles, and the removal of several of the by-products of anaerobic metabolism, such as carbon dioxide and lactic acid. Some of these responses are governed by transcriptional control of the fast twitch (FT) glycolytic phenotype. For example, skeletal muscle reprogramming from an ST glycolytic phenotype to an FT glycolytic phenotype involves the Six1/Eya1 complex, composed of members of the Six protein family. Moreover, the hypoxia-inducible factor 1-α (
HIF1A) has been identified as a master regulator for the expression of genes involved in essential hypoxic responses that maintain ATP levels in cells.
Ablation of HIF-1α in skeletal muscle was associated with an increase in the activity of rate-limiting enzymes of the mitochondria, indicating that the citric acid cycle and increased fatty acid oxidation may be compensating for decreased flow through the glycolytic pathway in these animals. However, hypoxia-mediated HIF-1α responses are also linked to the regulation of mitochondrial dysfunction through the formation of excessive reactive oxygen species in mitochondria. Other pathways also influence adult muscle character. For example, physical force inside a muscle fiber may release the transcription factor
serum response factor from the structural protein titin, leading to altered muscle growth. == Exercise ==