A symphysis (fibrocartilaginous joint) is a joint in which the body (physis) of one bone meets the body of another. All but two of the symphyses lie in the vertebral (spinal) column, and all but one contain fibrocartilage as a constituent tissue. The short-lived suture between the two halves of the mandible is called the symphysis menti (from the Latin mentum, meaning “chin”) and is the only symphysis devoid of fibrocartilage. All of the other symphyses are permanent.

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The symphysis pubis joins the bodies of the two pubic bones of the pelvis. The adjacent sides of these bodies are covered by cartilage through which collagen fibres run from one pubis to the other. On their way they traverse a plate of cartilage, which in some instances (especially in the female) may contain a small cavity filled with fluid. Surrounding the joint and attached to the bones is a coat of fibrous tissue, particularly thick below (the subpubic ligament). The joint is flexible enough to act as a hinge that allows each of the two hip bones to swing a little upward and outward, as the ribs do during inspiration of air. This slight movement is increased in a woman during childbirth because of the infiltration of the joint and its fibrous coat by fluid toward the end of pregnancy; the fluid makes the joint even more flexible. In both sexes the joint acts as a buffer against shock transmitted to the pelvic bones from the legs in running and jumping.


synovial joint
Synovial joint.
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The fibrous layer

The fibrous layer is composed of collagen. The part that is visible in an unopened joint cavity is referred to as the investing ligament or joint capsule. At the point where it reaches the articulating bones, it attaches to the periosteum lining the outer surface of the cortex.

Articular cartilage

Articular cartilage (cartilage that covers the articulating part of a bone) is of the type called hyaline (glasslike) because thin sections of it are translucent, even transparent. Unlike bone, it is easily cut by a sharp knife. It is deformable but elastic, and it recovers its shape quickly when the deforming stress is removed. These properties are important for its function.


hyaline cartilage
Histological image of hyaline cartilage.

The surface of articular cartilage is smooth to the finger, like that of a billiard ball. Images obtained by a scanning electron microscope have shown, however, that the surface is actually irregular, more like that of a golf ball. The part of the cartilage nearest to the bone is impregnated with calcium salts. This calcified layer appears to be a barrier to the passage of oxygen and nutrients to the cartilage from the bone, such that the cartilage is largely dependent upon the synovial fluid for its nourishment.

Every articular cartilage has two parts: a central articulating part and a marginal nonarticulating part. The marginal part is much smaller than the central and is covered by a synovial membrane. It will be described later in connection with that membrane.

The central part is either single, if only two bones are included in the joint, or divided into clearly distinct portions by sharp ridges, if more than two bones are included. Thus, the upper articular surface of the arm bone (humerus) is single, for only this bone and the shoulder blade (scapula) are included in the shoulder joint. The lower articular surface of the humerus is subdivided into two parts, one for articulation with the radius and one for articulation with the ulna, both being included in the elbow joint. There is a functional reason for the subdivision, or partition, of articular cartilage when it does occur.

Within a diarthrosis joint, bones articulate in pairs, each pair being distinguished by its own pair of conarticular surfaces. Conarticular surfaces constitute “mating pairs.” Each mating pair consists of a “male” surface and a “female” surface; the reasoning for these terms is explained below. As previously stated, there is only one such pair of bones within the shoulder joint; hence, there is only one pair of conarticular surfaces. There are two such pairs within the elbow joint—the humeroradial and humeroulnar. The radius moves on one of the two subdivisions of the lower humeral articular cartilage; the ulna moves on the other subdivision. There are then two pairs of conarticular surfaces within the elbow joint, even though there are only three bones in it.

Articular surfaces are divisible into two primary classes: ovoid and sellar. An ovoid surface is either convex in all directions or concave in all directions; in this respect it is like one or other of the two sides of a piece of eggshell, hence the name (ovum, egg). A sellar surface is convex in one direction and concave in the direction at right angles to the first; in this respect it is like the whole or part of a horse saddle (sella, saddle). There are no flat articular surfaces, although slightly curved ovoid or sellar surfaces may be classified as flat. Following an engineering convention, an ovoid surface is called “male” if it is convex, “female” if it is concave. In any diarthrosis having ovoid conarticular surfaces, the male surface is always of larger area than the female. For this reason the larger of two sellar conarticular surfaces is called male and the smaller female. The larger the difference in size between conarticular surfaces, the greater the possible amount of motion at the joint.

In all positions of a diarthrosis, except one, the conarticular surfaces fit imperfectly. This incongruence may not be large and may be lessened by mutual deformation of the opposed parts of the surfaces, a consequence of the deformability of articular cartilage. The exceptional position is called the close-packed position; in it the whole of the articulating portion of the female surface is in complete contact with the apposed part of the male surface, and the joint functionally is no longer a diarthrosis but is instead called a synchondrosis. Every joint has its close-packed position brought about by the action of the main ligaments of the joint. A good example is that of the wrist when the hand is fully bent backward (dorsiflexed) on the forearm. In closed-packed positions two bones in series are converted temporarily into a functionally single, but longer, unit that is more likely to be injured by sudden torsional stresses. Thus, a sprained or even fractured wrist usually occurs when that joint, when close packed, is suddenly and violently bent.

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No articular surface is of uniform curvature; neither is it a “surface of revolution” such as a cylinder is. That part of a male conarticular surface that comes into contact with the female in close pack is both wider and of lesser curvature than is the remainder. Inspection of two articulating bones is enough to establish their position of close pack, flexion, extension, or whatever it may be.