cardiac muscle
| Dictionary: cardiac muscle |
n.
The specialized striated muscle tissue of the heart; the myocardium.
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| World of the Body: cardiac muscle |
Your heart beats about once a second for the whole of your life, and of course has no opportunity to rest. Its output must adjust rapidly to meet the needs of the body, and can increase from about 5 litres of blood/min at rest to more than 25 litres/min in heavy exercise. The special requirements of the heart call for a special type of muscle, cardiac muscle, which is not found anywhere else in the body. Cardiac muscle is in some ways similar to skeletal and smooth muscle. For example, all three contract when a rise in calcium inside the muscle cell allows interaction between actin and myosin filaments. However, cardiac muscle has a unique structure, and differs in the way that contraction is initiated and regulated.
Structure
Under the microscope, cardiac muscle is seen to consist of interlacing bundles of cardiac myocytes (muscle cells). Like skeletal muscle it is striated with narrow dark and light bands, due to the parallel arrangement of actin and myosin filaments that extend from end to end of each myocyte. However, cardiac myocytes are narrower and much shorter than skeletal muscle cells, being about 0.02 mm wide and 0.1 mm long, and are more rectangular than smooth muscle cells, which are normally spindle-shaped. They are often branched, and contain one nucleus but many mitochondria, which provide the energy required for contraction. A prominent and unique feature of cardiac muscle is the presence of irregularly-spaced dark bands between myocytes. These are known as intercalated discs, and are due to areas where the membranes of adjacent myocytes come very close together. The intercalated discs have two important functions: one is to ‘glue’ the myocytes together so that they do not pull apart when the heart contracts; the other is to allow an electrical connection between the cells, which, as we will see, is vital to the function of the heart as a whole. The electrical connection is made via special junctions (gap junctions) between adjoining myocytes, containing pores through which small ions and therefore electrical current can pass. As the myocytes are electrically connected, cardiac muscle is often referred to as a functional syncytium (continuous cellular material).
Mechanism of contraction
Cardiac myocytes contract when the voltage across the membrane, the resting membrane potential, is reduced sufficiently to initiate an action potential. In most parts of the heart this is caused by an action potential in an adjacent myocyte being transmitted through the gap junctions. The action potential starts with a very rapid reduction in voltage toward zero, which is due to sodium ions entering the myocyte. This phase of the action potential is also seen in skeletal muscle and nerves. In cardiac muscle, however, the membrane potential then remains close to zero for about 0.3 sec — the plateau phase, which is largely due to entry of calcium ions. It is this entry of calcium that leads to contraction. At the end of the plateau phase the membrane potential returns to resting levels. The plateau means that cardiac muscle action potentials last much longer than those in skeletal muscle or nerves, where calcium does not enter the cell and there is therefore no plateau phase.
When an action potential is initiated in one myocyte, it causes an electrical current to pass through gap junctions in the intercalated discs to its neighbours. This current initiates action potentials in these cells, which in turn stimulate their neighbours. As a result, a wave of activation, and therefore contraction, passes through the heart. This process allows synchronization of contraction throughout the heart, and is vital for proper function. When it is disrupted, as in some types of heart disease, the myocytes may lose synchronization. In severe cases, such as ventricular fibrillation, the heart cannot pump at all, and is said to look like a ‘bag of (writhing) worms’.
The amount of calcium entering the myocyte during an action potential is not enough to cause contraction. However, its entry causes more calcium to be released from stores in the sarcoplasmic reticulum, a membranous structure within the myocyte. This is known as calcium-induced calcium release. The amount of calcium released depends on the amount that enters during the action potential, so that contractile force can therefore be regulated by controlling calcium entry. This is increased by adrenaline and the autonomic nervous system. At the end of the beat, calcium is rapidly taken back into the sarcoplasmic reticulum, causing relaxation. Excess calcium — the amount that entered during the action potential — is expelled from the myocyte during the interval between beats by pumps in the membrane. If the heart rate increases there is less time to remove this calcium. As a result there is more calcium in the myocyte for the next beat, and so the force developed increases. This staircase effect allows the heart to expel blood more rapidly when the heart rate is increased. Drugs that inhibit removal of calcium from the myocyte can similarly increase cardiac muscle force. An example is digitalis, which was originally derived from the foxglove and has been used for treating heart disease for centuries.
Special types of cardiac muscle
Some areas of the heart contain myocytes that have specialized functions. One is the sino-atrial node or pacemaker region in the right atrium, where modified myocytes generate action potentials automatically, and are responsible for initiating the heartbeat. Although nervous activity is not required for the heart to beat, the autonomic nervous system can modulate the activity of the pacemaker, and hence heart rate. The atria and ventricles are separated by a non-conducting band except at the atrio-ventricular node. This node consists of small myocytes that do conduct, but delay the impulse from the pacemaker, thus allowing the atria to contract before the ventricles. From here the impulse is distributed rapidly around the ventricles via bundles of specialized large myocytes called Purkinje fibres. Defects in any part of this conduction system can lead to a disordered heartbeat.
Diagrammatic section of cardiac muscle
— Jeremy Ward
| Food and Fitness: cardiac muscle |
Special muscle found only within the heart. It can contract rhythmically without any external stimulation from nerves or hormones, as long as it is supplied with sufficient nutrients and oxygen. Unlike other types of muscle, cardiac muscle does not fatigue. However, it will stop contracting if its oxygen supply is interrupted.
| Sports Science and Medicine: cardiac muscle |
Muscle found only in the heart. The cells are striated, contain a single nucleus and branch, so that they fit together tightly at junctions called intercalated discs. Although cardiac muscle is myogenic, it has a contractile mechanism similar to that of striped muscle (see sliding-filament theory). However, cardiac muscle does not fatigue and it cannot tolerate lack of oxygen.
Cardiac muscle
| Wikipedia: Cardiac muscle |
| cardiac muscle | |
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Cardiac muscle is a type of involuntary striated muscle found in the walls of the heart, specifically the myocardium. Cardiac muscle cells are known as cardiac myocytes (or cardiomyocytes). Cardiac muscle is one of three major types of muscle, the others being skeletal and smooth muscle. The cells that comprise cardiac muscle are sometimes seen as intermediate between these two other types in terms of appearance, structure, metabolism, excitation-coupling and mechanism of contraction. Cardiac muscle shares similarities with skeletal muscle with regard to its striated appearance and contraction, with both differing significantly from smooth muscle cells.
Coordinated contraction of cardiac muscle cells in the heart propel blood from the atria and ventricles to the blood vessels of the circulatory system. Cardiac muscle cells, like all tissues in the body, rely on an ample blood supply to deliver oxygen and nutrients and to remove waste products such as carbon dioxide. The coronary arteries fulfill this function.
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Metabolism
Cardiac muscle is adapted to be highly resistant to fatigue: it has a large number of mitochondria, enabling continuous aerobic respiration via oxidative phosphorylation, numerous myoglobins (oxygen-storing pigment) and a good blood supply, which provides nutrients and oxygen. The heart is so tuned to aerobic metabolism that it is unable to pump sufficiently in ischaemic conditions. At basal metabolic rates, about 1% of energy is derived from anaerobic metabolism. This can increase to 10% under moderately hypoxic conditions, but, under more severe hypoxic conditions, not enough energy can be liberated by lactate production to sustain ventricular contractions.[1]
Under basal aerobic conditions, 60% of energy comes from fat (free fatty acids and triglycerides), 35% from carbohydrates, and 5% from amino acids and ketone bodies. However, these proportions vary widely according to nutritional state. For example, during starvation, lactate can be recycled by the heart. This is very energy efficient, because one NAD+ is reduced to NADH and H+ (equal to 2.5 or 3 ATP) when lactate is oxidized to pyruvate, which can then be burned aerobically in the TCA cycle, liberating much more energy (ca 14 ATP per cycle).
In the condition of diabetes, more fat and less carbohydrate is used due to the reduced induction of GLUT4 glucose transporters to the cell surfaces. However, contraction itself plays a part in bringing GLUT4 transporters to the surface.[2] This is true of skeletal muscle as well, but relevant in particular to cardiac muscle due to its continuous contractions.
Appearance
Striation
Cardiac muscle exhibits cross striations formed by alternating segments of thick and thin protein filaments. Like skeletal muscle, the primary structural proteins of cardiac muscle are actin and myosin. The actin filaments are thin causing the lighter appearance of the I bands in striated muscle, while the myosin filament is thicker lending a darker appearance to the alternating A bands as observed with electron microscopy. However, in contrast to skeletal muscle, cardiac muscle cells may be branched instead of linear and longitudinal.
T-Tubules
Another histological difference between cardiac muscle and skeletal muscle is that the T-tubules in cardiac muscle are larger, broader and run along the Z-Discs. There are fewer T-tubules in comparison with skeletal muscle. Additionally, cardiac muscle forms dyads instead of the triads formed between the T-tubules and the sarcoplasmic reticulum in skeletal muscle. T-tubules play critical role in excitation-contraction coupling (ECC). Recently, the action potentials of T-tubules were recorded optically by Guixue Bu et al. [3]
Intercalated discs
Intercalated discs (IDs) are complex adhering structures which connect single cardiac myocytes to an electrochemical syncytium (in contrast to the skeletal muscle, which becomes a multicellular syncytium during mammalian embryonic development) and are mainly responsible for force transmission during muscle contraction. Intercalated discs also support the rapid spread of action potentials and the synchronized contraction of the myocardium. In the old textbook dogma IDs are described to consist of three different types of cell-cell junctions: the actin filament anchoring adherens junctions (fasciae adhaerentes), the intermediate filament anchoring desmosomes (maculae adhaerentes) and gap junctions. Gap junctions are responsible for electrochemical and metabolic coupling. They allow action potentials to spread between cardiac cells by permitting the passage of ions between cells, producing depolarization of the heart muscle. However, novel molecular biological and comprehensive studies unequivocally showed that IDs consist for the most part of mixed type adhering junctions named area composita (pl. areae compositae) representing an amalgamation of typical desmosomal and fascia adhaerens proteins (in contrast to various epithelia)[citation needed]. The authors discuss the high importance of these findings for the understanding of inherited cardiomyopathies (such as Arrhythmogenic Right Ventricular Cardiomyopathy, ARVC).
Under light microscopy, intercalated discs appear as thin, typically dark-staining lines dividing adjacent cardiac muscle cells. The intercalated discs run perpendicular to the direction of muscle fibers. Under electron microscopy, an intercalated disc's path appears more complex. At low magnification, this may appear as a convoluted electron dense structure overlying the location of the obscured Z-line. At high magnification, the intercalated disc's path appears even more convoluted, with both longitudinal and transverse areas appearing in longitudinal section.[4]
Role of calcium in contraction
In contrast to skeletal muscle, cardiac muscle requires extracellular calcium ions for contraction to occur. Like skeletal muscle, the initiation and upshoot of the action potential in ventricular muscle cells is derived from the entry of sodium ions across the sarcolemma in a regenerative process. However, an inward flux of extracellular calcium ions through L-type calcium channels sustains the depolarization of cardiac muscle cells for a longer duration. The reason for the calcium dependence is due to the mechanism of calcium-induced calcium release (CICR) from the sarcoplasmic reticulum that must occur under normal excitation-contraction (EC) coupling to cause contraction. Once the intracellular concentration of calcium increases, calcium ions bind to the protein troponin, which initiates contraction by allowing the contractile proteins, myosin and actin to associate through cross-bridge formation. Cardiac muscle is intermediate between smooth muscle, which has an unorganized sarcoplasmic reticulum and derives its calcium from both the extracellular fluid and intracellular stores, and skeletal muscle, which is only activated by calcium stored in the sarcoplasmic reticulum.
Regeneration of heart muscle cells
Until recently, it was commonly believed that cardiac muscle cells could not be regenerated. However, a study reported in the April 3, 2009 issue of Science contradicts that belief.[5] Olaf Bergmann and his colleagues at the Karolinska Institute in Stockholm tested samples of heart muscle from people born before 1955 when nuclear bomb testing caused elevated levels of radioactive carbon 14 in the earth's atmosphere. They found that samples from people born before 1955 did have elevated carbon 14 in their heart muscle cell DNA, indicating that the cells had divided after the person's birth. By using DNA samples from many hearts, the researchers estimated that a 20-year-old renews about 1% of heart muscle cells per year and about 45 percent of the heart muscle cells of a 50-year-old were generated after he or she was born.
See also
References
- ^ Ganong, Review of Medical Physiology, 22nd Edition.Specialized form of muscle that is peculiar to the vertebrate heart.p81
- ^ S Lund, GD Holman, O Schmitz, and O Pedersen. Contraction Stimulates Translocation of Glucose Transporter GLUT4 in Skeletal Muscle Through a Mechanism Distinct from that of Insulin. PNAS 92: 5817-5821.
- ^ Guixue Bu, et al. Uniform action potential repolarization within the sarcolemma of in situ ventricular cardiomyocytes. Biophysical Journal, Vol.96, No.6, March 2009, pp.2532-2546.
- ^ Histology at BU 22501loa
- ^ Science News, April 25, 2009, page 11.
- Lodish, H., Berk, A., Zipursky, L. S., Matsudaira, P., Baltimore, D., Darnell, J. 2000. Molecular Cell Biology. ISBN 0-7167-3136-3 1
- Franke, W. W., Borrmann, C. M. ,Grund, C., Pieperhoff, S., 2006. The area composita of adhering junctions connecting heart muscle cells of vertebrates. I. Molecular definition in intercalated disks of cardiomyocytes by immunoelectron microscopy of desmosomal proteins. Eur J Cell Biol 85, 69-82.
- Borrmann, C. M., Grund, C., Kuhn, C., Hofmann, I., Pieperhoff, S., Franke, W. W., 2006. The area composita of adhering junctions connecting heart muscle cells of vertebrates. II. Colocalizations of desmosomal and fascia adhaerens molecules in the intercalated disk. Eur J Cell Biol 85, 469-85.
- Pieperhoff, S., Franke, W. W., 2007. The area composita of adhering junctions connecting heart muscle cells of vertebrates - IV: Coalescence and amalgamation of desmosomal and adhaerens junction components - Late processes in mammalian heart development. Eur J Cell Biol 86, 377-91.
- Pieperhoff, S., Franke, W. W., 2008. The area composita of adhering junctions connecting heart muscle cells of vertebrates -VI. Polar and lateral junctions of non-mammalian species. Eur J Cell Biol. 87, 413-30.
- Shimada, T., Kawazato, H., Yasuda, A., Ono, N., Sueda, K., 2004. Cytoarchitecture and intercalated disks of the working myocardium and the conduction system in the mammalian heart. Anat Rec A Discov Mol Cell Evol Biol. 280, 940-51.
- Waschke, J., 2008. The desmosome and pemphigus. Histochem Cell Biol 130, 21-54.
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Mentioned in
- intercalated disc
- rigor mortis
- myocardium
- cardiotonic drug (pharmacology)
- diphtheritic myocarditis (medicine)
- How is cardiac muscle different from skeletal muscle? (anatomy)
- How is the cardiac muscle supplied with blood? (anatomy)
- involuntary muscle
- cardiac impulse
- inotropic
- staircase phenomenon
- Purkinje fibers (histology)
- Sarcosporida (invertebrate zoology)
- cardiac fatigue
