The Project Gutenberg eBook ofEncyclopaedia Britannica, 11th Edition, "Joints" to "Justinian I."This ebook is for the use of anyone anywhere in the United States and most other parts of the world at no cost and with almost no restrictions whatsoever. You may copy it, give it away or re-use it under the terms of the Project Gutenberg License included with this ebook or online atwww.gutenberg.org. If you are not located in the United States, you will have to check the laws of the country where you are located before using this eBook.Title: Encyclopaedia Britannica, 11th Edition, "Joints" to "Justinian I."Author: VariousRelease date: October 6, 2012 [eBook #40956]Most recently updated: October 23, 2024Language: EnglishCredits: Produced by Marius Masi, Don Kretz and the OnlineDistributed Proofreading Team at http://www.pgdp.net*** START OF THE PROJECT GUTENBERG EBOOK ENCYCLOPAEDIA BRITANNICA, 11TH EDITION, "JOINTS" TO "JUSTINIAN I." ***
This ebook is for the use of anyone anywhere in the United States and most other parts of the world at no cost and with almost no restrictions whatsoever. You may copy it, give it away or re-use it under the terms of the Project Gutenberg License included with this ebook or online atwww.gutenberg.org. If you are not located in the United States, you will have to check the laws of the country where you are located before using this eBook.
Title: Encyclopaedia Britannica, 11th Edition, "Joints" to "Justinian I."Author: VariousRelease date: October 6, 2012 [eBook #40956]Most recently updated: October 23, 2024Language: EnglishCredits: Produced by Marius Masi, Don Kretz and the OnlineDistributed Proofreading Team at http://www.pgdp.net
Title: Encyclopaedia Britannica, 11th Edition, "Joints" to "Justinian I."
Author: Various
Author: Various
Release date: October 6, 2012 [eBook #40956]Most recently updated: October 23, 2024
Language: English
Credits: Produced by Marius Masi, Don Kretz and the OnlineDistributed Proofreading Team at http://www.pgdp.net
*** START OF THE PROJECT GUTENBERG EBOOK ENCYCLOPAEDIA BRITANNICA, 11TH EDITION, "JOINTS" TO "JUSTINIAN I." ***
Articles in This Slice
JOINTS,in anatomy. The study of joints, or articulations, is known as Arthrology (Gr.ἄρθρον), and naturally begins with the definition of a joint. Anatomically the term is used for any connexion between two or more adjacent parts of the skeleton, whether they be bone or cartilage. Joints may be immovable, like those of the skull, or movable, like the knee.
Immovable joints, orsynarthroses, are usually adaptations to growth rather than mobility, and are always between bones. When growth ceases the bones often unite, and the joint is then obliterated by a process known assynostosis, though whether the union of the bones is the cause or the effect of the stoppage of growth is obscure. Immovable joints never have a cavity between the two bones; there is simply a layer of the substance in which the bone has been laid down, and this remains unaltered. If the bone is being deposited in cartilage a layer of cartilage intervenes, and the joint is calledsynchondrosis(fig. 1), but if in membrane a thin layer of fibrous tissue persists, and the joint is then known as asuture(fig. 2). Good examples of synchondroses are the epiphysial lines which separate the epiphyses from the shafts of developing long bones, or the occipito-sphenoid synchondrosis in the base of the skull. Examples of sutures are plentiful in the vault of the skull, and are given special names, such as sutura dentata, s. serrata, s. squamosa, according to the plan of their outline. There are two kinds of fibrous synarthroses, which differ from sutures in that they do not synostose. One of these is aschindylesis, in which a thin plate of one bone is received into a slot in another, as in the joint between the sphenoid and vomer. The other is a peg and socket joint, orgomphosis, found where the fangs of the teeth fit into the alveoli or tooth sockets in the jaws.Fig. 3.—Vertical section through an amphiarthrodial joint.b,b, the two bones;c,c, the plate of cartilage on the articular surface of each bone;Fc, the intermediate fibro-cartilage;l,l, the external ligaments.Movable joints, ordiarthroses, are divided into those in which there is much and little movement. When there is little movement the term half-joint oramphiarthrosisis used. The simplest kind of amphiarthrosis is that in which two bones are connected by bundles of fibrous tissue which pass at right angles from the one to the other; such a joint only differs from a suture in the fact that the intervening fibrous tissue is more plentiful and is organized into definite bundles, to which the name ofinterosseous ligamentsis given, and also that it does not synostose when growth stops. A joint of this kind is called asyndesmosis, though probably the distinction is a very arbitrary one, and depends upon the amount of movement which is brought about by the muscles on the two bones. As an instance of this the inferior tibio-fibular joint of mammals may be cited. In man this is an excellent example of a syndesmosis, and there is only a slight play between the two bones. In the mouse there is no movement, and the two bones form a synchondrosis between them which speedily becomes a synostosis, while in many Marsupials there is free mobility between the tibia and fibula, and a definite synovial cavity is established. The other variety of amphiarthrosis or half-joint is thesymphysis, which differs from the syndesmosis in having both bony surfaces lined with cartilage and between the two cartilages a layer of fibro-cartilage, the centre of which often softens and forms a small synovial cavity. Examples of this are the symphysis pubis, the mesosternal joint, and the joints between the bodies of the vertebrae (fig. 3).Thetrue diarthrosesare joints in which there is either fairly free or very free movement. The opposing surfaces of the bones are lined with articular cartilage, which is the unossified remnant of the cartilaginous model in which they are formed and is called thecartilage of encrustment(fig. 4,c). Between the two cartilages is thejoint cavity, while surrounding the joint is thecapsule(fig. 4,l), which is formed chiefly by the superficial layers of the original periosteum or perichondrium, but it may be strengthened externally by surrounding fibrous structures, such as the tendons of muscles, which become modified and acquire fresh attachments for the purpose. It may be said generally that the greater the intermittent strain on any part of the capsule the more it responds by increasing in thickness. Lining the interior of the capsule, and all other parts of the joint cavity except where the articular cartilage is present, is thesynovial membrane(fig. 4, dotted line); this is a layer of endothelial cells which secrete the synovial fluid to lubricate the interior of the joint by means of a small percentage of mucin, albumin and fatty matter which it contains.Fig. 4.—Vertical section through a diarthrodial joint.b,b, the two bones;c,c, the plate of cartilage on the articular surface of each bone;l,l, the investing ligament, the dotted line within which represents the synovial membrane. The lettersis placed in the cavity of the joint.Fig. 5.—Vertical section through a diarthrodial joint, in which the cavity is subdivided into two by an interposed fibro-cartilage or meniscus,Fc. The other letters as in fig. 4.Acompound diarthrodial jointis one in which the joint cavity is divided partly or wholly into two by ameniscusorinterarticular fibro-cartilage(fig. 5,Fc).The shape of the joint cavity varies greatly, and the different divisions of movable joints depend upon it. It is often assumed that the structure of a joint determines its movement, but there is something to be said for the view that the movements to which a joint issubject determine its shape. As an example of this it has been found that the mobility of the metacarpo-phalangeal joint of the thumb in a large number of working men is less than it is in a large number of women who use needles and thread, or in a large number of medical students who use pens and scalpels, and that the slightly movable thumb has quite a differently shaped articular surface from the freely movable one (seeJ. Anat. and Phys.xxix. 446). R. Fick, too, has demonstrated that the concavity or convexity of the joint surface depends on the position of the chief muscles which move the joint, and has enunciated the law that when the chief muscle or muscles are attached close to the articular end of the skeletal element that end becomes concave, while, when they are attached far off or are not attached at all, as in the case of the phalanges, the articular end is convex. His mechanical explanation is ingenious and to the present writer convincing (seeHandbuch der Gelenke, by R. Fick, Jena, 1904). Bernays, however, pointed out that the articular ends were moulded before the muscular tissue was differentiated (Morph. Jahrb.iv. 403), but to this Fick replies by pointing out that muscular movements begin before the muscle fibres are formed, and may be seen in the chick as early as the second day of incubation.The freely movable joints (true diarthrosis) are classified as follows:—(1)Gliding joints(Arthrodia), in which the articular surfaces are flat, as in the carpal and tarsal bones.(2)Hinge joints(Ginglymus), such as the elbow and interphalangeal joints.(3)Condyloid joints(Condylarthrosis), allowing flexion and extension as well as lateral movement, but no rotation. The metacarpo-phalangeal and wrist joints are examples of this.(4)Saddle-shaped joints(Articulus sellaris), allowing the same movements as the last with greater strength. The carpo-metacarpal joint of the thumb is an example.(5)Ball and socket joints(Enarthrosis), allowing free movement in any direction, as in the shoulder and hip.(6)Pivot-joint(Trochoides), allowing only rotation round a longitudinal axis, as in the radio-ulnar joints.
Immovable joints, orsynarthroses, are usually adaptations to growth rather than mobility, and are always between bones. When growth ceases the bones often unite, and the joint is then obliterated by a process known assynostosis, though whether the union of the bones is the cause or the effect of the stoppage of growth is obscure. Immovable joints never have a cavity between the two bones; there is simply a layer of the substance in which the bone has been laid down, and this remains unaltered. If the bone is being deposited in cartilage a layer of cartilage intervenes, and the joint is calledsynchondrosis(fig. 1), but if in membrane a thin layer of fibrous tissue persists, and the joint is then known as asuture(fig. 2). Good examples of synchondroses are the epiphysial lines which separate the epiphyses from the shafts of developing long bones, or the occipito-sphenoid synchondrosis in the base of the skull. Examples of sutures are plentiful in the vault of the skull, and are given special names, such as sutura dentata, s. serrata, s. squamosa, according to the plan of their outline. There are two kinds of fibrous synarthroses, which differ from sutures in that they do not synostose. One of these is aschindylesis, in which a thin plate of one bone is received into a slot in another, as in the joint between the sphenoid and vomer. The other is a peg and socket joint, orgomphosis, found where the fangs of the teeth fit into the alveoli or tooth sockets in the jaws.
Movable joints, ordiarthroses, are divided into those in which there is much and little movement. When there is little movement the term half-joint oramphiarthrosisis used. The simplest kind of amphiarthrosis is that in which two bones are connected by bundles of fibrous tissue which pass at right angles from the one to the other; such a joint only differs from a suture in the fact that the intervening fibrous tissue is more plentiful and is organized into definite bundles, to which the name ofinterosseous ligamentsis given, and also that it does not synostose when growth stops. A joint of this kind is called asyndesmosis, though probably the distinction is a very arbitrary one, and depends upon the amount of movement which is brought about by the muscles on the two bones. As an instance of this the inferior tibio-fibular joint of mammals may be cited. In man this is an excellent example of a syndesmosis, and there is only a slight play between the two bones. In the mouse there is no movement, and the two bones form a synchondrosis between them which speedily becomes a synostosis, while in many Marsupials there is free mobility between the tibia and fibula, and a definite synovial cavity is established. The other variety of amphiarthrosis or half-joint is thesymphysis, which differs from the syndesmosis in having both bony surfaces lined with cartilage and between the two cartilages a layer of fibro-cartilage, the centre of which often softens and forms a small synovial cavity. Examples of this are the symphysis pubis, the mesosternal joint, and the joints between the bodies of the vertebrae (fig. 3).
Thetrue diarthrosesare joints in which there is either fairly free or very free movement. The opposing surfaces of the bones are lined with articular cartilage, which is the unossified remnant of the cartilaginous model in which they are formed and is called thecartilage of encrustment(fig. 4,c). Between the two cartilages is thejoint cavity, while surrounding the joint is thecapsule(fig. 4,l), which is formed chiefly by the superficial layers of the original periosteum or perichondrium, but it may be strengthened externally by surrounding fibrous structures, such as the tendons of muscles, which become modified and acquire fresh attachments for the purpose. It may be said generally that the greater the intermittent strain on any part of the capsule the more it responds by increasing in thickness. Lining the interior of the capsule, and all other parts of the joint cavity except where the articular cartilage is present, is thesynovial membrane(fig. 4, dotted line); this is a layer of endothelial cells which secrete the synovial fluid to lubricate the interior of the joint by means of a small percentage of mucin, albumin and fatty matter which it contains.
Acompound diarthrodial jointis one in which the joint cavity is divided partly or wholly into two by ameniscusorinterarticular fibro-cartilage(fig. 5,Fc).
The shape of the joint cavity varies greatly, and the different divisions of movable joints depend upon it. It is often assumed that the structure of a joint determines its movement, but there is something to be said for the view that the movements to which a joint issubject determine its shape. As an example of this it has been found that the mobility of the metacarpo-phalangeal joint of the thumb in a large number of working men is less than it is in a large number of women who use needles and thread, or in a large number of medical students who use pens and scalpels, and that the slightly movable thumb has quite a differently shaped articular surface from the freely movable one (seeJ. Anat. and Phys.xxix. 446). R. Fick, too, has demonstrated that the concavity or convexity of the joint surface depends on the position of the chief muscles which move the joint, and has enunciated the law that when the chief muscle or muscles are attached close to the articular end of the skeletal element that end becomes concave, while, when they are attached far off or are not attached at all, as in the case of the phalanges, the articular end is convex. His mechanical explanation is ingenious and to the present writer convincing (seeHandbuch der Gelenke, by R. Fick, Jena, 1904). Bernays, however, pointed out that the articular ends were moulded before the muscular tissue was differentiated (Morph. Jahrb.iv. 403), but to this Fick replies by pointing out that muscular movements begin before the muscle fibres are formed, and may be seen in the chick as early as the second day of incubation.
The freely movable joints (true diarthrosis) are classified as follows:—
(1)Gliding joints(Arthrodia), in which the articular surfaces are flat, as in the carpal and tarsal bones.
(2)Hinge joints(Ginglymus), such as the elbow and interphalangeal joints.
(3)Condyloid joints(Condylarthrosis), allowing flexion and extension as well as lateral movement, but no rotation. The metacarpo-phalangeal and wrist joints are examples of this.
(4)Saddle-shaped joints(Articulus sellaris), allowing the same movements as the last with greater strength. The carpo-metacarpal joint of the thumb is an example.
(5)Ball and socket joints(Enarthrosis), allowing free movement in any direction, as in the shoulder and hip.
(6)Pivot-joint(Trochoides), allowing only rotation round a longitudinal axis, as in the radio-ulnar joints.
Embryology.
Joints are developed in the mesenchyme, or that part of the mesoderm which is not concerned in the formation of the serous cavities. The synarthroses may be looked upon merely as a delay in development, because, as the embryonic tissue of the mesenchyme passes from a fibrous to a bony state, the fibrous tissue may remain along a certain line and so form a suture, or, when chondrification has preceded ossification, the cartilage may remain at a certain place and so form a synchondrosis. The diarthroses represent an arrest of development at an earlier stage, for a part of the original embryonic tissue remains as a plate of round cells, while the neighbouring two rods chondrify and ossify. This plate may become converted into fibro-cartilage, in which case an amphiarthrodial joint results, or it may become absorbed in the centre to form a joint cavity, or, if this absorption occurs in two places, two joint cavities with an intervening meniscus may result. Although, ontogenetically, there is little doubt that menisci arise in the way just mentioned, the teaching of comparative anatomy suggests that, phylogenetically, they originate as an ingrowth from the capsule pushing the synovial membrane in front of them. The subject will be returned to when the comparative anatomy of the individual joints is reviewed. In the human foetus the joint cavities are all formed by the tenth week of intra-uterine life.
Anatomy
Joints of the Axial Skeleton.
The bodies of the vertebrae except those of the sacrum and coccyx are separated, and at the same time connected, by theintervertebral disks. These are formed of alternating concentric rings of fibrous tissue and fibro-cartilage, with an elastic mass in the centre known as thenucleus pulposus. The bodies are also bound together byanteriorandposterior common ligaments. The odontoid process of the axis fits into a pivot joint formed by the anterior arch of the atlas in front and thetransverse ligamentbehind; it is attached to the basioccipital bone by two stronglateral check ligaments, and, in the mid line, by a feeblermiddle check ligamentwhich is regarded morphologically as containing the remains of the notochord. Thisatlanto-axial jointis the one which allows the head to be shaken from side to side. Nodding the head occurs at theoccipito-atlantal joint, which consists of the two occipital condyles received into the cup-shaped articular facets on the atlas and surrounded by capsular ligaments. The neural arches of the vertebrae articulate one with another by thearticular facets, each of which has a capsular ligament. In addition to these the laminae are connected by the very elasticligamenta subflava. The spinous processes are joined byinterspinous ligaments, and their tips by asupraspinous ligament, which in the neck is continued from the spine of the seventh cervical vertebra to the external occipital crest and protuberance as theligamentum nuchae, a thin, fibrous, median septum between the muscles of the back of the neck.
The combined effect of all these joints and ligaments is to allow the spinal column to be bent in any direction or to be rotated, though only a small amount of movement occurs between any two vertebrae.
The heads of the ribs articulate with the bodies of two contiguous thoracic vertebrae and the disk between. The ligaments which connect them are calledcosto-central, and are two in number. The anterior of these is thestellate ligament, which has three bands radiating from the head of the rib to the two vertebrae and the intervening disk. The other one is theinterarticular ligament, which connects the ridge, dividing the two articular cavities on the head of the rib, to the disk; it is absent in the first and three lowest ribs.
Thecosto-transverse ligamentsbind the ribs to the transverse processes of the thoracic vertebrae. Thesuperior costo-transverse ligamentbinds the neck of the rib to the transverse process of the vertebra above; themiddleorinterosseousconnects the back of the neck to the front of its own transverse process; while theposteriorruns from the tip of the transverse process to the outer part of the tubercle of the rib. The inner and lower part of each tubercle forms a diarthrodial joint with the upper and fore part of its own transverse process, except in the eleventh and twelfth ribs. At the junction of the ribs with their cartilages no diarthrodial joint is formed; the periosteum simply becomes perichondrium and binds the two structures together. Where the cartilages, however, join the sternum, or where they join one another, diarthrodial joints with synovial cavities are established. In the case of the second rib this is double, and in that of the first usually wanting. Themesosternal joint, between the pre- and mesosternum, has already been given as an example of a symphysis.
Comparative Anatomy.—For the convexity or concavity of the vertebral centra in different classes of vertebrates, seeSkeleton:axial. The intervertebral disks first appear in the Crocodilia, the highest existing order of reptilia. In many Mammals the middle fasciculus of the stellate ligament is continued right across the ventral surface of the disk into the ligament of the opposite side, and is probably serially homologous with the ventral arch of the atlas. A similar ligament joins the heads of the ribs dorsal to the disk. To these bands the names of anterior (ventral) and posterior (dorsal)conjugal ligamentshave been given, and they may be demonstrated in a seven months’ human foetus (see B. Sutton,Ligaments, London, 1902). Theligamentum nuchaeis a strong elastic band in the Ungulata which supports the weight of the head. In the Carnivora it only reaches as far forward as the spine of the axis.
Comparative Anatomy.—For the convexity or concavity of the vertebral centra in different classes of vertebrates, seeSkeleton:axial. The intervertebral disks first appear in the Crocodilia, the highest existing order of reptilia. In many Mammals the middle fasciculus of the stellate ligament is continued right across the ventral surface of the disk into the ligament of the opposite side, and is probably serially homologous with the ventral arch of the atlas. A similar ligament joins the heads of the ribs dorsal to the disk. To these bands the names of anterior (ventral) and posterior (dorsal)conjugal ligamentshave been given, and they may be demonstrated in a seven months’ human foetus (see B. Sutton,Ligaments, London, 1902). Theligamentum nuchaeis a strong elastic band in the Ungulata which supports the weight of the head. In the Carnivora it only reaches as far forward as the spine of the axis.
TheJaw Joint, ortemporo-mandibular articulation, occurs between the sigmoid cavity of the temporal bone and the condyle of the jaw. Between the two there is an interarticular fibro-cartilage or meniscus, and the joint is surrounded by a capsule of which the outer part is the thickest. On first opening the mouth, the joint acts as a hinge, but very soon the condyle begins to glide forward on to the eminentia articularis (seeSkull) and takes the meniscus with it. This gliding movement between the meniscus and temporal bone may be separately brought about by protruding the lower teeth in front of the upper, or, on one side only, by moving the jaw across to the opposite side.
Comparative Anatomy.—The joint between the temporal and mandibular bones is only found in Mammals; in the lower vertebrates the jaw opens between the quadrate and articular bones. In the Carnivora it is a perfect hinge; in many Rodents only the antero-posterior gliding movement is present; while in the Ruminants the lateralizing movement is the chief one. Sometimes, as in the Ornithorhynchus, the meniscus is absent.
Comparative Anatomy.—The joint between the temporal and mandibular bones is only found in Mammals; in the lower vertebrates the jaw opens between the quadrate and articular bones. In the Carnivora it is a perfect hinge; in many Rodents only the antero-posterior gliding movement is present; while in the Ruminants the lateralizing movement is the chief one. Sometimes, as in the Ornithorhynchus, the meniscus is absent.
Joints of the Upper Extremity.
Thesterno-clavicular articulation, between the presternum and clavicle, is a gliding joint, and allows slight upward and downward and forward and backward movements. The two bony surfaces are separated by a meniscus, the vertical movements taking place outside and the antero-posterior inside this. There is a well-marked capsule, of which the anterior part is strongest. The two clavicles are joined across the top of the presternum by aninterclavicular ligament.
Theacromio-clavicular articulationis also a gliding joint, but allows a swinging or pendulum movement of the scapula on the clavicle. The upper part of the capsule is strongest, and from it hangs down a partial meniscus into the cavity.