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13.9: Muscle and Nervous Tissues

  • Page ID
    44708
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    Learning Objectives
    • Describe three types of muscle tissues
    • Describe nervous tissue

    Muscle Tissues

    There are three types of muscle in animal bodies: smooth, skeletal, and cardiac. They differ by the presence or absence of striations or bands, the number and location of nuclei, whether they are voluntarily or involuntarily controlled, and their location within the body. Table 1 summarizes these differences.

    Table 1. Types of Muscles
    Type of Muscle Striations Nuclei Control Location
    smooth no single, in center involuntary visceral organs
    skeletal yes many, at periphery voluntary skeletal muscles
    cardiac yes single, in center involuntary heart

    Smooth Muscle

    Smooth muscle does not have striations in its cells. It has a single, centrally located nucleus, as shown in Figure 1. Constriction of smooth muscle occurs under involuntary, autonomic nervous control and in response to local conditions in the tissues. Smooth muscle tissue is also called non-striated as it lacks the banded appearance of skeletal and cardiac muscle. The walls of blood vessels, the tubes of the digestive system, and the tubes of the reproductive systems are composed of mostly smooth muscle.

    Skeletal Muscle

    Skeletal muscle has striations across its cells caused by the arrangement of the contractile proteins actin and myosin. These muscle cells are relatively long and have multiple nuclei along the edge of the cell. Skeletal muscle is under voluntary, somatic nervous system control and is found in the muscles that move bones. Figure 1 illustrates the histology of skeletal muscle.

    Cardiac Muscle

    Cardiac muscle, shown in Figure 1, is found only in the heart. Like skeletal muscle, it has cross striations in its cells, but cardiac muscle has a single, centrally located nucleus. Cardiac muscle is not under voluntary control but can be influenced by the autonomic nervous system to speed up or slow down. An added feature to cardiac muscle cells is a line than extends along the end of the cell as it abuts the next cardiac cell in the row. This line is called an intercalated disc: it assists in passing electrical impulse efficiently from one cell to the next and maintains the strong connection between neighboring cardiac cells.

    The smooth muscle cells are long and arranged in parallel bands. Each cell has a long, narrow nucleus. Skeletal muscle cells are also long but have striations across them and many small nuclei per cell. Cardiac muscles are shorter than smooth or skeletal muscle cells, and each cell has one nucleus.
    Figure 1. Smooth muscle cells do not have striations, while skeletal muscle cells do. Cardiac muscle cells have striations, but, unlike the multinucleate skeletal cells, they have only one nucleus. Cardiac muscle tissue also has intercalated discs, specialized regions running along the plasma membrane that join adjacent cardiac muscle cells and assist in passing an electrical impulse from cell to cell.

    Nervous Tissues

    Illustration shows a neuron which has an oval cell body. Branchlike dentrites extend from three sides of the body. A long, thin axon extends from the fourth side. At the end of the axon are branchlike terminals. A cell called an oligodendrocyte grows alongside the axon. Projections from the oligodendrocyte wrap around the axon, forming a myelin sheath. Gaps between parts of the sheath are called nodes of Ranvier. Another cell called an astrocyte sits alongside the axon.
    Figure 2. Diagram of a neuron

    Nervous tissues are made of cells specialized to receive and transmit electrical impulses from specific areas of the body and to send them to specific locations in the body. The main cell of the nervous system is the neuron, illustrated in Figure 2.

    The large structure with a central nucleus is the cell body of the neuron. Projections from the cell body are either dendrites specialized in receiving input or a single axon specialized in transmitting impulses. Some glial cells are also shown. Astrocytes regulate the chemical environment of the nerve cell, and oligodendrocytes insulate the axon so the electrical nerve impulse is transferred more efficiently. Other glial cells that are not shown support the nutritional and waste requirements of the neuron. Some of the glial cells are phagocytic and remove debris or damaged cells from the tissue. A nerve consists of neurons and glial cells.

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