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NAME: NIMIBOFA ESENDU MATRIC NUMBER: 14/MHS05/005 NURSING SCIENCE ANA 203 HISTOLOGY OF MUSCLE AS A TISSUE AND ITS TYPES Muscle tissue is categorized on the basis of a functional property: the ability of its cells to contract. In muscle tissue, the bulk of the cytoplasm volume consists of the contractile protein fibrils actin and myosin. Muscle is responsible for movement of the body and changes in the size and shape of internal organs. Muscle cells are generally referred to as muscles fibers. The term fibers is used for both for muscle cells and for the extracellular elements e.g. collagen produced by connective tissue cells. Muscle fibers are typically arraigned in parallel arrays allowing them to work together effectively. TYPES OF TISSUE Three types of muscle tissue can be identified histologically: skeletal, cardiac and smooth muscles. The fibers in skeletal muscle and cardiac muscle exhibit cross striations at the light microscope level and they are both referred to as STRIATED muscles. SKELETAL MUSCLE This constitutes the muscle that is attached to the skeleton and control motor movements and posture. There are a few instances where this type of muscle is restricted to soft tissue: the tongue, pharynx, diaphragm and upper part esophagus. Skeletal muscle fibers (cells) are actually a multinucleated syncytium formed by the fusion of individual small muscle cells or myoblasts, during development. They are filled with longitudinally arrayed subunits called myofibrils. The myofibrils are made up of the myofilaments myosin (thick filaments) and actin (thin filaments). The striations reflect the arrangement of actin and myosin filaments and support structures. The individual contractile units are called sarcomeres. A myofibril consists of many sarcomeres arranged end to end. The entire muscle exhibits cross-striations because sarcomeres in adjacent myofibrils and muscle fibers are in register. The most obvious feature in longitudinal sections of skeletal muscle is the alternating pattern of dark and light bands, called respectively the A (anisotropic) and I (isotropic) band. The I band is bisected by a dense zone called the Z line, to which the thin filaments of the I band are attached. The nuclei are located peripherally, immediately under the plasma membrane (sarcolemma). The thickness of individual muscle fibers varies (depending for example on location in the body and exercise) but each fiber is of uniform thickness throughout its length. Skeletal muscle fibers do not branch. Connective tissue elements surround muscle fibers. Individual muscle fibers are surrounded by a delicate layer of reticular fibers called the endomysium. Groups of fibers are bundled into fascicles by a thicker CT layer called the perimysium. The collection of fascicles that constitutes one muscle is surrounded by a sheath of dense CT called the epimysium, which continues into the tendon. Blood vessels and nerves are found in the CT associated with muscle. The endomysium contains only capillaries and the finest neuronal branches. Cardiac muscle Cardiac muscle is the type of muscle found in the heart, and at the base of the venae cavae as they enter into the heart. Cardiac muscle is intrinsically contractile but is regulated by autonomic and hormonal stimuli. Cardiac muscle exhibits striations because it also has actin and myosin filaments arranged into sarcomeres. Generally these striations do not appear as well-defined as in skeletal muscle. (At the ultrastructural level, some differences in the arrangement of the sarcoplasmic reticulum and T tubules can be seen. Cardiac muscle also has a much greater number of mitochondria in its cytoplasm. More details on the anatomy and physiology of muscle will be discussed in H&D and Cardiovascular Blocks.) At the light microscope level, a number of features distinguish cardiac from skeletal muscle. Cardiac muscle cells have only one or two nuclei, which are centrally located. The myofibrils separate to pass around the nucleus, leaving a perinuclear clear area (not always evident in standard preparations). This clear area is occupied by organelles, especially mitochondria (which are of course not visible in LM). As in skeletal muscle, individual muscle fibers are surrounded by delicate connective tissue. Numerous capillaries are found in the connective tissue around cardiac muscle fibers. Cardiac muscle cells are joined to one another in a linear array. The boundary between two cells abutting one another is called an intercalated disc. Intercalated discs consist of several types of cells junctions whose purpose is to facilitate the passage of an electrical impulse from cell to cell and to keep the cells bound together during constant contractile activity. Unlike skeletal muscle fibers, cardiac muscle fibers branch and anastomose with one another. Although made up of individual fibers, heart muscle acts as a functional syncytium during contraction for the efficient pumping of blood. Specialized fibers, called Purkinje fibers, arise from the atrioventricular node and travel along the interventricular septum toward the apex of the heart, sending branches into the ventricular tissue. Purkinje fibers are of larger diameter than ordinary cardiac fibers, with fewer myofibrils and an extensive, well-defined clear area around the nucleus. They conduct impulses at a rate about four times faster than that of ordinary cardiac fibers and serve to coordinate the contraction of the atria and ventri Smooth muscle Smooth muscle is the intrinsic muscle of the internal organs and blood vessels. It is also found in the iris and ciliary body of the eye and associated with hair follicles (arrector pili). No striations are present in smooth muscle due to the different arrangement of actin and myosin filaments. Like cardiac muscle, smooth muscle fibers are intrinsically contractile but responsive to autonomic and hormonal stimuli. They are specialized for slow, prolonged contraction. Smooth muscle fibers are generally arranged in bundles or sheets. Each fiber is fusiform in shape with a thicker central portion and tapered at both ends. The single nucleus is located in the central part of the fiber. Fibres do not branch. They range enormously in size, from 20 (in wall of small blood vessels) to 500 (in wall of uterus during pregnancy) micrometers. Smooth muscle fibers lie over one another in a staggered fashion (tapered part of one fiber over thicker part of another). In longitudinal sections, it is often not possible to distinguish the fiber boundaries, and smooth muscle may closely resemble connective tissue (bundles of collagen). Where smooth muscle bundles are interlaced with bundles of connective tissue (e.g. in the uterus), one can distinguish the smooth muscle by the orientation of the nuclei (all oriented in the same direction), and the greater abundance of nuclei per unit area (every smooth muscle cell has a nucleus, fibroblast nuclei are more scattered in bundles of CT). Also, smooth muscle nuclei often have a corkscrew shape in longitudinal section due to contraction of the muscle fiber during fixation. In cross section, smooth muscle appears as profiles of various sizes, depending on whether the cut went through the thick central part or tapered end of any individual fiber. Nuclei are seen only in the thicker profiles. One distinguishing physiological feature of smooth muscle is its ability to secrete connective tissue matrix. In the walls of blood vessels and the uterus in particular, smooth muscle fibers secrete large amounts of collagen and elastin LINES AND BANDS OF MUSCLE TISSUE Light microscopic studies show that, each myofibril consists of a number of two alternating bands which are also called the sections, segments or disks. the two bands are: 1. Light band or 'I' band. 2. Dark band or 'A' band. LIGHT BAND OR 'I' BAND The light band is isotropic in nature. When the polarized light is passed through the muscle fiber at this area the light rays are refracted at the same angle. So, this band is called 'I' (isotropic) band. DARK BAND OR 'A' BAND The dark band is anisotropic in nature. When the polarized light is passed through the muscle fiber at this area, the light rays are refracted at different directions (An=not; iso=it; trops=turning). So, this band is otherwise called 'A' (anisotropic) band. Dark band is also called Q disk(Querscheibe=cross disk). In an intact muscle fiber, 'I' band and 'A' band of the adjacent myofibrils are placed side-by-side. It gives the appearance of characteristics cross striations in the muscle fiber. I band is divided into two portions by means of a narrow and dark line called 'Z' line or 'Z' disk (in German zwischenscheibe=between disks). The 'Z' line is formed by a protein disk which does not permit passage of light. The portion of myofibril in between two 'Z' lines is called sarcomere. Within the A-band is a paler region called the H-zone (from the German "heller", brighter). Named for their lighter appearance under a polarization microscope. H-band is the zone of the thick filaments that is not superimposed by the thin filaments. Inside the H-zone is a thin M-line (from the German "Mittelscheibe", the disc in the middle of the sarcomere) formed of cross-connecting elements of the cytoskeleton.