Connective Tissues: Matrix Composition and Its Relevance to Physical Therapy.Key Words: Connective tissues, Fibers, Function, Proteoglycans proteoglycans (prō´tēōglī´kans), n.pl the mucopolysaccharides bound to protein chains occurring in the extracellular matrix of connective tissue. . [Culav EM, Clark CH, Merrilees MJ. Connective tissues: matrix composition and its relevance to physical therapy. Phys Ther. 1999;79:308-319.] The purposes of this update are to provide an overview of the composition, structure, and function of the connective tissue (CT) matrix and to illustrate how recent research has contributed to an improved understanding of the ways in which CT responds to mechanical forces. The overview is not exhaustive, but rather seeks to illustrate the complexity of these tissues, tissues once regarded as relatively simple structures within a mechanical system. Specific tissues and their special features, such as those of cartilage and bone, are not discussed in depth; instead, the overview emphasizes general principles that apply across the CT spectrum. Components of Connective Tissues Connective tissues and their matrix components make up a large proportion of the total body mass, are highly specialized, and have a diversity of roles. They provide for mechanical support, movement, tissue fluid transport, cell migration, wound healing wound healing Physiology The repair of a wound Steps Inflammation, repair and closure, remodeling, final healing; repair of incisions may be either simple–'clean' wounds with little loss of tissue heal by 'primary intention', or 'dirty' wounds heal by , and--as is becoming increasingly evident--control of metabolic processes in other tissues.[1, 2] Unlike the properties of epithelial, muscle, or nerve tissues, which depend primarily on their cellular elements, the properties of CT are determined primarily by the amount, type, and arrangement of an abundant extracellular matrix extracellular matrix (eksˈ·tr  ·selˑ·y (ECM (1) (Enterprise Change Management) See version control and configuration management.(2) (Error Correcting Mode) A Group 3 fax capability that can test for errors within a row of pixels and request retransmission. ). The ECM consists of g major types of macromolecules--fibers, proteoglycans (PGs), and glycoproteins--each of which is synthesized and maintained by cells specific to the tissue type (Fig. 1). [Figure 1 ILLUSTRATION OMITTED] The 2 most important fibrous components of the ECM are collagen and elastin elastin /elas·tin/ (e-las´tin) a yellow scleroprotein, the essential constituent of elastic connective tissue; it is brittle when dry, but when moist is flexible and elastic. e·las·tin n. , both insoluble macromolecular mac·ro·mol·e·cule n. A very large molecule, such as a polymer or protein, consisting of many smaller structural units linked together. Also called supermolecule. proteins. Collagen has a variety of forms but is perhaps best exemplified by the prominent aligned fibers of tendons and ligaments. Other collagen fibers, which are far less prominent, include the small reticular fibers of soft organs such as the liver and the submicroscopic submicroscopic /sub·mi·cro·scop·ic/ (-mi?kro-skop´ik) too small to be visible with the light microscope. sub·mi·cro·scop·ic adj. fibrils found in basement membranes. The striking feature of the most prominent collagens is their ability to resist tensile loads. Generally, they show minimal elongation (less than 10%) under tension; a proportion of this elongation is not the result of true elongation of individual fibers, but of the straightening of fibers that are packed in various 3-dimensional arrays.[3,4] In contrast, elastic fibers may increase their length by 150%, yet still return to their previous configuration.[3] The second major component of the ECM is the PGs, a diverse group of soluble macromolecules Macromolecules A large molecule composed of thousands of atoms. Mentioned in: Gene Therapy macromolecules that have both structural and metabolic roles.[5,6] They occupy, along with collagen, the interstitial spaces Interstitial spaces Spaces within body tissues that are outside the blood vessels. Interstitial spaces are also known as interstitial compartments. Mentioned in: Edema, Electrolyte Supplements between the cells, form part of basement membranes, and attach to cell surfaces where they function as receptors.[5,6] Important mechanical functions of PGs include hydration hydration /hy·dra·tion/ (hi-dra´shun) the absorption of or combination with water. hy·dra·tion n. 1. The addition of water to a chemical molecule without hydrolysis. 2. of the matrix, stabilization of collagen networks, and the ability to resist compressive com·pres·sive adj. Serving to or able to compress. com·pres  sive·ly adv. forces, an
ability best exhibited by the PGs of articular cartilage articular cartilagen. The cartilage covering the articular surfaces of the bones forming a synovial joint. Also called arthrodial cartilage, diarthrodial cartilage, investing cartilage. .[5] Hyaluronan (HA), which is technically not a PG because it lacks a protein core, is particularly important because it readily entrains large amounts of water and is abundant in hydrated hy·drat·ed adj. Chemically combined with water, especially existing in the form of a hydrate. Adj. 1. hydrated - containing combined water (especially water of crystallization as in a hydrate) hydrous soft loose tissues where repeated movement is required (eg, tendon sheaths tendon sheaths (tenˑ·d  n shēthzˑ),n. and bursae Bursae A closed sac lined with a synovial membrane and filled with fluid, usually found in areas subject to friction, such as where a tendon passes over a bone. ).[7,8] The third group of matrix molecules, the glycoproteins, are ubiquitous in all CTs and, as with the PGs, have both structural and metabolic roles. Their mechanical roles include providing linkage between matrix components and between cells and matrix components. An important concept is that the mechanical properties of CT, such as the ability to resist tension, compression, extensibility, and torsion torsion, stress on a body when external forces tend to twist it about an axis. See strength of materials. , are determined by the proportions of the matrix components. In turn, the maintenance of these matrix components and their organization depend on the nature and extent of loading these tissues experience. Generally, tissues with a high collagen-fiber content and low amounts of PG resist tensile forces, and those tissues with a high PG content, combined with a network of collagen fibers, withstand compression (Tab. 1). Trauma or pathology may affect normal movements and lead to changed mechanical stresses placed on the CT. Table 1. Major Extracellular Matrix Components and Mechanical Properties of the Common Connective Tissues1(1,7,a)
Principal Cell Dominant
Tissue Type Fiber
Tendon Tenocytes Collagen
Articular Chondrocytes Collagen
cartilage
Bone Osteoblasts Collagen
Osteocytes
Dermis Fibroblasts Collagen
Elastin
Dominant PG/GAG and Total GAG
Tissue Content
Tendon Dermatan sulphate PG ~0.2% of dry
weight
Articular Chondroitin sulphate PG ~8%-10% of
cartilage dry weight
Bone Chondroitin sulphate PG
Very small percentage of dry weight
Dermis Dermatan and chondroitin sulphate PG
~1% of dry weight
Tissue Mechanical Properties
Tendon Resists tensional forces
Articular Resists compressive forces
cartilage
Bone Resists tension, compression, and
torsion (due to hydroxyapatite)
Dermis Resists tension and moderate
compression and accomodates
stretching
PG = proteoglycan proteoglycan /pro·teo·gly·can/ (pro?te-o-gli´kan) any of a group of polysaccharide-protein conjugates present in connective tissue and cartilage, consisting of a polypeptide backbone to which many glycosaminoglycan chains are covalently , GAG = glycosaininoglycan. This, in turn, produces changes in the ECM and at the level of gene expression, as will be discussed below. Collagens: Framework of the Extracellular Matrix Nineteen distinct types of collagens are recognized, all with individual characteristics that serve specific functions in a variety of tissues.[9] The common structural feature that identifies all collagens, however, is a triple helix region within the molecule. This section of the molecule provides the characteristic mechanical properties of tendons and ligaments (ie, the ability to withstand tensile loads). The triple helix is made up of 3 polypeptide polypeptide: see peptide. chains folded to form a ropelike coil. Each chain, known as an [Alpha]-chain, is characterized by repeating sequences of 3 amino acids, glycine-X-Y (Fig. 2). Because glycine glycine (glī`sēn), organic compound, one of the 20 amino acids commonly found in animal proteins. Glycine is the only one of these amino acids that is not optically active, i.e. is the smallest amino acid and occupies the central core of the triple helix, the repetition of glycine as every third amino acid is essential for the correct folding of the 3 [Alpha]-chains into the helical conformation con·for·ma·tion n. One of the spatial arrangements of atoms in a molecule that can come about through free rotation of the atoms about a single chemical bond. ,[10,11] Specific collagen types are formed by a variety of [Alpha]-chains and by variations in the combination of different [Alpha]-chains: in some collagens, all 3 [Alpha]-chains are identical; in other collagens, 2 a-chains may be identical; and in some collagens, all 3 a-chains are different. Alteration of the glycine-X-Y sequence of amino acids usually results in dysfunction of the collagen molecule and loss of its mechanical properties (eg, osteogenesis imperfecta osteogenesis imperfecta Group of connective-tissue diseases in which the bones are very fragile. Several forms probably reflect different degrees of expression of the same disorder. ).[12] The helical complex, which inherently resists tension, is further strengthened by intermolecular Adj. 1. intermolecular - existing or acting between molecules; "intermolecular forces"; "intermolecular condensation" bonds between the a-chains of adjacent molecules.[13] [Figure 2 ILLUSTRATION OMITTED] The extremities or terminals of the collagen molecule are nonhelical but are important for the formation of collagen fibrils and for other nontensile functions, including interactions with other extracellular components. The [Alpha]-chains of me principal collagens are synthesized with relatively long extremities, and, after formation of the triple helix, this newly formed collagen molecule (called procollagen) is emitted from the cell into the extracellular space where most of the nonhelical ends are enzymatically removed. Removal allows the shortened molecules, now called tropocollagen tropocollagen /tro·po·col·la·gen/ (tro?po-kol´ah-jen) the basic structural unit of all forms of collagen; it is a helical structure of three polypeptides wound around each other. tro·po·col·la·gen n. , to associate with each other and form fibrils, which are visible under the electron microscope electron microscope: see microscope. and characterized by distinct cross-bands. These fibrils then aggregate to form fibers, which are visible under the light microscope, and bundles of fibers, which are visible to the eye[14] (Fig. 3). [Figure 3 ILLUSTRATION OMITTED] Modifications, variations, and additions to the basic triple-helix conformation give rise to 6 classes of collagens (Tab. 2).[9,10] Of most relevance to physical therapists are the fibril-forming collagens that are found in tissues (ie, tendons, ligaments) where their primary function is to resist tensile forces and in tissues where there is a requirement for resisting tensile loads (ie, dermis dermis: see skin. , articular cartilage, intervertebral intervertebral /in·ter·ver·te·bral/ (-ver´te-bral) situated between two contiguous vertebrae; see under disk. in·ter·ver·te·bral adj. Located between vertebrae. disks [IVDs], bone). The other 5 classes of collagen, which are much less abundant but nevertheless essential to CT functions throughout the body, have a variety of roles.[9,10] These classes of collagen and their roles are summarized in Table 2.
Table 2.
Collagen Types, Location, and Functions[9,10]
Classes of Collagen Collagen Types
Fibril-forming collagens I, II, III, V, XI
Fibril-associated collagens with IX, XII, XIV, XVI
interrupted triple helices (FACIT)
Network-forming collagens IV
Filamentous collagens
Short-chain collagens VIII, X, XIII
Long-chain collagens VII
Classes of Collagen Examples of Location
Fibril-forming collagens Tendon, ligament,
intervertebral disk, bone,
cartilage, blood vessels,
dermis
Fibril-associated collagens with Coassemble with fibril-
interrupted triple helices (FACIT) forming collagens (eg,
type IX and type II) in
cartilage
Network-forming collagens Basement membranes
Filamentous collagens Ubiquitous in connective
tissue
Short-chain collagens VIII: cornea and vascular
tissue
X: hyaline cartilage
XIII: blood vessel wall,
glomeruli of kidney
Long-chain collagens Basement membrane
Classes of Collagen Functions
Fibril-forming collagens I, II, III: resist tension
V, XI: control fibril
diameter
Fibril-associated collagens with Interact with other matrix
interrupted triple helices (FACIT) components
Network-forming collagens Separates tissue
compartments
Surrounds many cell types
(eg, smooth muscle cells and
nerve cells)
Plays a role in regulation
of cell growth, migration,
and differentiation
Filamentous collagens Bridges and anchors cells to
other components of
extracellular matrix
Important in development and
maintenance of tissues
Short-chain collagens Unknown
Long-chain collagens Secures basement membrane to
adjacent connective tissue
matrix
Fibril-forming collagens (types I, II, III, V, and XI). Fibril-forming collagens account for over 70% of the total collagen found in the body.[10] Type I collagen predominates in tissues such as bones, tendons, ligaments, joint capsules, and the annulus fibrosus of the IVD (Interactive VideoDisc) See interactive video. . Type II collagen is located principally in articular cartilage and the nucleus pulposus Nucleus pulposus (NP) The center portion of the intervertebral disk that is made up of a gelatinous substance. Mentioned in: Chemonucleolysis, Herniated Disk of the IVD. Type III collagen appears to play a role in the extensibility of tissue and is found especially in embryonic tissues and in many adult tissues, such as arteries, skin, and soft organs, where they form reticular fibers.[11,15] The prevalence of type III collagen is also an indicator of tissue maturity and is also prominent in the initial stages of healing and scar-tissue formation, where it provides early mechanical strength to the newly synthesized matrix.[14] As fetal development proceeds and as healing tissue gains in strength, type III fibers are replaced by the stronger type I fibers.[16-18] Generally, type I fibrils have a large diameter, a feature that correlates with the ability to carry a greater mechanical load. In young, growing tendons, exercise increases fibril fibril /fi·bril/ (fi´bril) a minute fiber or filament.fibril´larfib´rillary collagen fibrils diameter and ultimate tensile strength, but, in the adult, the effect of exercise is minimal. Nevertheless, continued tension is necessary to maintain tendon structure because immobilization Immobilization Definition Immobilization refers to the process of holding a joint or bone in place with a splint, cast, or brace. This is done to prevent an injured area from moving while it heals. leads to a loss of tensile strength.[19] Fibrils may also be formed of more than one type of collagen. Types V and XI combine with type I and II collagen, respectively, to form heterotypic heterotypic /het·ero·typ·ic/ (-tip´ik) pertaining to, characteristic of, or belonging to a different type. het·er·o·typ·ic or het·er·o·typ·i·cal adj. fibrils, an arrangement that is thought to play a role in determining fibril diameter and thereby influence mechanical properties. In general, the greater the fibril diameter, the smaller the percentage of type V and type XI collagen.[11] The tension-resisting property of the fibril-forming collagens is the principal means of limiting the range of motion of joints, transmitting forces generated by muscle, imparting tensile strength to the bony skeleton, and resisting extension by the surface layers of articular cartilage. The arrangement and alignment of the collagen fibers reflect the mechanical stresses acting on the tissues. In tendons, the majority of fibers are aligned in parallel, enabling them to resist unidirectional forces and to efficiently transmit forces generated by muscles to bones.[4] In comparison, type I fibers in ligaments are often positioned in slightly less parallel arrays, reflecting the need to resist multidirectional mul·ti·di·rec·tion·al adj. 1. Reaching out in several directions: a multidirectional campaign. 2. forces. For example, in ligaments associated with joints, there is a need to both limit motion and provide for joint stability. Collagen also plays an important role in attaching tendons and ligaments to bone. At these junctions, tendons and ligaments usually widen and give way to fibrocartilage fibrocartilage /fi·bro·car·ti·lage/ (-kahr´ti-laj) cartilage of parallel, thick, compact collagenous bundles, separated by narrow clefts containing the typical cartilage cells (chondrocytes). , a transformation where the aligned fibers originating from the tendon or ligament are separated by other collagen fibers arranged in a 3-dimensional network surrounding rounded cells.[20] This arrangement helps to transmit tensile forces onto a broad area and reduces the chance of failure under excessive loading. The type I collagen fibers of bone have a more complex arrangement. Generally, the fibrils are arranged in orthogonal arrays, similar to the way the wood fibers in plywood are arranged in alternating sheets. This arrangement, especially when configured as small cylinders, such as in osteons, imparts a great deal of multidirectional tensile strength. A combination of type I and type II collagen is found in the IVD and in tendons with fibrocartilaginous pressure pads.[21] In the annulus fibrosus of the IVD, alternating layers of type I fibers link adjacent vertebral ver·te·bral adj. 1. Of, relating to, or of the nature of a vertebra. 2. Having or consisting of vertebrae. 3. Having a spinal column. bodies and surround the central nucleus pulposus. The fibrous bands are generally aligned at angles of about 45 degrees from the vertebral axis, an arrangement that provides a mechanism for spinal flexibility and for increasing resistance to excessive motion near the limits of movement. In the nucleus pulposus, type II collagen predominates and there are high levels of HA and sulphated PG that function in association with the type II fibers to provide a hydrated and pressure-resistant core.[22] In articular cartilage, the principal collagen fibers are type II, which are arranged to form a network of bands between the cells. Superficially, these fibrous bands are mostly tangential to the articular articular /ar·tic·u·lar/ (ahr-tik´u-ler) pertaining to a joint. ar·tic·u·lar adj. Of or relating to a joint or joints. articular pertaining to a joint. surface, but, with increasing depth, they become more radial and pass between columns of cells. Immediately around the cells, other type II collagen fibers combine with types VI, IX, and XI in a dense capsule arrangement. These fibrous bands provide both the tensile properties of cartilage and, in conjunction with large sulphated PG, a mechanism for resisting compression. The capsular cap·su·lar adj. Of, relating to, or resembling a capsule. Adj. 1. capsular - resembling a capsule; "the capsular ligament is a sac surrounding the articular cavity of a freely movable joint and attached to the bones" collagen is thought to protect the chondrocytes from these external Forces.[23,24] Elastic fibers: extensible elements of the extracellular matrix. Elastic fibers in the ECM allow tissues such as skin, the lungs, and blood vessels Blood vessels Tubular channels for blood transport, of which there are three principal types: arteries, capillaries, and veins. Only the larger arteries and veins in the body bear distinct names. to withstand repeated stretching and considerable deformation and to return to a relaxed state. The arrangement of elastin varies and depends largely on the strength and direction of forces on the tissue. The fibers may be organized into concentric fenestrated fenestrated /fen·es·trat·ed/ (fen´es-trat?ed) pierced with one or more openings. fen·es·trat·ed or fen·es·trate adj. Having fenestrae or windowlike openings. sheets (eg, aorta), as small individual fibers (eg, skin, lung), or as a 3-dimensional honeycomb-like network of fine fibers (eg, elastic cartilage elastic cartilage n. A yellowish flexible cartilage in which the matrix is infiltrated by a network of elastic fibers; it occurs primarily in the external ear, eustachian tube, and some cartilages of the larynx and epiglottis. ).[25] Elastic fibers are composed of an elastin core and microfibrils located mostly around the periphery (Fig. 4). The microfibrils, which are chiefly made up of fibrillin, initially act as a scaffold on which elastin is deposited, but once the core elastin is generated, the majority of microfibrils are displaced to the outer aspect of the fiber. Elastin contains 2 amino acids (ie, desmosine and isodesmosine) that form cross-linkages between adjacent tropoelastin chains and are important in imparting the elastic properties to elastin.[26] The exact mechanism of extensibility is not clearly understood, but the quantity of elastin found within the tissue usually reflects the amount of mechanical strain imposed on it and the requirement for reversible deformation (for a review of elastin see Chadwick and Goode[27]). [Figure 4 ILLUSTRATION OMITTED] Elastic fibers are widely distributed and found in most organs to varying degrees. They are found throughout the tracheobronchial tracheobronchial /tra·cheo·bron·chi·al/ (-brong´ke-al) pertaining to the trachea and bronchi. tra·che·o·bron·chi·al adj. Of or relating to the trachea and the bronchi. tree of the lung and are largely responsible for accommodating pressure changes.[28] The potential energy stored in the elastic fiber at the end of inspiration is released during expiration with the consequent assisted recoil of the lung tissue.[28] Similarly, the elastin that is found in the walls of arteries withstands the deformation produced by systole systole /sys·to·le/ (sis´to-le) the contraction, or period of contraction, of the heart, especially of the ventricles.systol´ic aborted systole , recoils during diastole diastole /di·as·to·le/ (di-as´tah-le) the dilatation, or the period of dilatation, of the heart, especially of the ventricles.diastol´ic di·as·to·le n. , and accommodates the hemodynamic he·mo·dy·nam·ics n. (used with a sing. verb) The study of the forces involved in the circulation of blood. he stresses that the flow of blood imposes on the artery wall.[25,29] In the dermis, the elastic fibers provide the characteristic resilience of skin. There is a preferential orientation with coiled fibers aligning predominantly at right angles so as to form a right angle or right angles, as when one line crosses another perpendicularly. See also: Right to lines of skin tension and in a direction that allows for greater stretching of the skin.[18] Both a changed conformation and general loss of elastic fibers with increasing age reduce the ability of the skin to recoil.[30] Elastic fibers are relatively sparse in ligaments, with 2 notable exceptions: the ligamenta nuchae in the cervical region of the vertebral column vertebral column: see spinal column. vertebral column or spinal column or spine or backbone Flexible column extending the length of the torso. and the ligamenta flava connecting the laminae of adjacent vertebrae Vertebrae Bones in the cervical, thoracic, and lumbar regions of the body that make up the vertebral column. Vertebrae have a central foramen (hole), and their superposition makes up the vertebral canal that encloses the spinal cord. ?.[31] The elastic recoil elastic recoil Physiology The inherent resistance of a tissue to changes in shape, and the tendency of the tissue to revert to its original shape once deformed; a sensitive indicator of ER is the coefficient of retraction; ER is the effective pressure driving in these ligaments assists in extending the head, neck, and trunk against gravity, thereby reducing the load imposed on the erector spinae muscles of the back. The lack of regeneration of functional elastic fibers in adults is a major problem, and, once this ability to regenerate is lost, the restoration of normal function is not possible.[30] Elastin, however, is synthesized by adult tissues in response to cyclic stretching, injury, and ultraviolet radiation[32] and by tissues in a number of disease states, including emphysema emphysema (ĕmfĭsē`mə), pathological or physiological enlargement or overdistention of the air sacs of the lungs. A major cause of pulmonary insufficiency in chronic cigarette smokers, emphysema is a progressive disease that commonly .[33] Adults, however, apparently cannot rebuild the elastic fiber assembly mechanisms, and function is not restored.[27] In general, there is a lack of knowledge about the mechanisms of control of elastic fiber formation.[27] Proteoglycans: Hydrators, Stabilizers, and Space Fillers of the Extracellular Matrix The PCs are characterized by a core protein covalently attached to one or more sulphated glycosaminoglycan glycosaminoglycan /gly·cos·ami·no·gly·can/ (gli?kos-ah-me?no-gli´kan) any of a group of high molecular weight linear polysaccharides with various disaccharide repeating units and usually occurring in proteoglycans, including the (GAG) side chains. The core proteins are generally specific to each of the PG types and show considerable variability in size. Similarly, there are various GAG chains. The GAG chains are composed of repeating disaccharide disaccharide /di·sac·cha·ride/ (di-sak´ah-rid) any of a class of sugars yielding two monosaccharides on hydrolysis. di·sac·cha·ride n. units, with the type and number of units largely determining the properties of the PG.[5] Combinations of sugars make up the disaccharide units, resulting in 6 major GAGs: chondroitin chondroitin (k  n·droiˑ·tin),n sulphates 4 (CS A) and 6 (CS C), keratan sulphate (KS), dermatan sulphate (DS, also known as CS B), heparan sulphate, and HA. Hyaluronan is atypical because it is not attached to a protein core, nor is it sulphated. It is usually included under a discussion of PC, however, because it is the most abundant and ubiquitous of the GAGs, and it plays an important role in bonding to other PCs to form supramolecular su·pra·mo·lec·u·lar adj. 1. Consisting of more than one molecule. 2. Of greater complexity than a molecule. complexes. All GAGs are negatively charged and have a propensity to attract ions, creating an osmotic osmotic, adj pertaining to osmosis. osmotic pressure, n See pressure, osmotic. osmotic emanating from or pertaining to the pressure of osmosis. imbalance that results in the PC-GAG absorbing water from surrounding areas. This absorption helps maintain the hydration of the matrix; the degree of hydration depends on the number of GAG chains and on the restriction placed on PG swelling by the surrounding collagen fibers.[6] The percentage of GAG within CT varies directly with mechanical load. Tissues subjected to high compressive forces (eg, articular cartilage) have a large PG content (approximately 8%-10% of the dry weight of the tissue). Conversely, in tension-resisting tissues such as tendons and ligaments, PGs are found in relatively small concentrations (approximately 0.2% of dry weight).[7] Furthermore, the proportions of PG species differ with the mechanical load in such a way that the CS:DS ratio is higher in tissues subjected to compression and lower in tissues that resist tension.[7] Proteoglycan can be divided into aggregating and nonaggregating PGs. The key features that distinguish between these 2 groups are their ability or inability to aggregate with HA and the number of GAG side chains that bond to the protein core.[7] Aggregating proteoglycans. Aggregating PGs bond to HA. A large complex results when many PG monomers link to a single strand of HA. The PG-HA linkage is stabilized by a glycoprotein glycoprotein (glī'kōprō`tēn), organic compound composed of both a protein and a carbohydrate joined together in covalent chemical linkage. known as link protein that helps secure the PG monomers to the HA.[34] Because the GAG chains attached to the PG core are negatively charged and extend from the core protein like the bristles of a bottle brush, a high charge density is created. This charge density induces an osmotic swelling pressure, resulting in the movement of water into the matrix. Therefore, the PG will tend to swell, but the tension-resistant collagen fibers and the bonding of the negatively charged GAG chains to regions of positive charge on collagen fibrils limits the expansion of PGs to approximately 20% of their swelling capacity.[35,36] This limited expansion provides the rigidity of the matrix and, where PG content is high, endows the tissue with the ability to resist compressive forces. Two examples of aggregating PGs are aggrecan and versican. Aggrecan is the best-known and best-understood aggregating PG. It is the predominant PG in articular cartilage and plays a major role in normal joint function and in skeletal growth.[6,37] A large compliment of CS chains (approximately 100) and a smaller compliment of KS chains (approximately 30) are attached to the protein core of the monomer (Fig. 5). Versican has fewer CS chains (approximately 30) attached to its core protein, but it also aggregates with HA and contributes to resistance of compressive forces.[5] Versican is found in many tissues, including blood vessel blood vessel n. An elastic tubular channel, such as an artery, a vein, a sinus, or a capillary, through which the blood circulates. blood vessel(s), n the network of muscular tubes that carry blood. walls,[36] the IVD,[22] and some tendon sites that are subjected to compressive loading.[21] Versican, along with HA, also functions as an antiadhesive molecule and facilitates cell migration.[38,39] [Figure 5 ILLUSTRATION OMITTED] Nonaggregating proteoglycans. The nonaggregating PGs do not bond to HA and frequently possess only a small number of GAG side chains composed of CS and DS. They appear to play a limited role in withstanding compression, but they interact with other matrix components and contribute to mechanical stability through interaction with collagen. Decorin, which has one GAG chain, is one of the smallest PGs and functions, in part, to link adjacent collagen fibrils. The core proteins bind at specific sites on the surface of fibrils, and the GAG chain extends to form an antiparallel antiparallel /an·ti·par·al·lel/ (-par´ah-lel) denoting molecules arranged side by side but in opposite directions. array with a neighboring decorin GAG chain extending from an adjacent fibril.[40] Biglycan (2 GAG chains) is also small and is found in the matrix between bundles of collagen fibrils. The mechanical and other functions of biglycan are not understood, but both biglycan and decorin play a role in regulating cell activity, most notably through the binding of growth factors through specific high- and low-affinity sites on the core proteins[41] (Fig. 6). [Figure 6 ILLUSTRATION OMITTED] The heparan sulphate PG, syndecan, is attached to the cell membrane Cell membrane The membrane that surrounds the cytoplasm of a cell; it is also called the plasma membrane or, in a more general sense, a unit membrane. This is a very thin, semifluid, sheetlike structure made of four continuous monolayers of molecules. and plays a role in cell growth through binding growth factors, such as basic fibroblast growth factor Basic fibroblast growth factor, also known as bFGF or FGF2, is a member of the fibroblast growth factor family. In normal tissue, basic fibroblast growth factor is present in basement membranes and in the subendothelial extracellular matrix of blood , and acting as a co-receptor.[42,43] Perlecan is found close to cell surfaces and contributes to the structure of basement membranes. In addition to providing support, it assists in cellular differentiation.[44] Hyaluronan is an important component of the aggrecan complex, but it also exists as a free molecule. Hyaluronan avidly entrains water and is prominent where the matrix is highly hydrated, such as in loose CT.[7,8] A relatively rich solution of HA is found in the vitreous humor vitreous humor n. 1. The clear gelatinous substance that fills the eyeball between the retina and the lens. 2. The vitreous body. of the eye, the umbilical cord umbilical cord (ŭmbĭl`ĭkəl), cordlike structure about 22 in. (56 cm) long in the pregnant human female, extending from the abdominal wall of the fetus to the placenta. , and the synovial fluid of joints where its theological properties are suited for lubrication lubrication, introduction of a substance between the contact surfaces of moving parts to reduce friction and to dissipate heat. A lubricant may be oil, grease, graphite, or any substance—gas, liquid, semisolid, or solid—that permits free action of .[45,46] Role of mechanical forces in determining proteoglycan content and type. There is good evidence to show that the maintanence of normal tissue architecture requires normal physiological mechanical loading and that CTs respond to changes in applied stresses by altering their PG content and type. Joint motion is important for the normal maintenance and turnover of PG in healthy articular cartilage. Conversely, joint immobilization or disuse results in atrophy of the articular cartilage because of a loss of PG from the matrix.[37] Importantly, this PG loss following joint immobilization is reversible with a remobilization program.[37,47] Movement alone, without weight bearing, is sufficient to maintain PG content in sheep articular cartilage.[48] The absence of both weight bearing and movement, however, resulted in a large loss (40%) of PG over a period of 1 month. Arthritic diseases induced by trauma or degenerative processes also lead to a disturbance in aggrecan synthesis and degradation and in the inability of the aggrecan monomer to bond to HA and form large aggregates.[49] As a result, cartilage may fail to resist compression effectively. The load-bearing IVD also has a high PG content, with the PG being concentrated mostly in the nucleus pulposus and decreasing peripherally toward the annulus fibrosus, where the tissue is under increasing tension. Even the outer region of the annulus fibrosus, however, has a higher PG content than major tension-resisting structures such as tendons and ligaments, reflecting the need to resist both tension and pressure. Failure of the IVD may result, in part, from the inability of the aggrecan and HA to form a stable complex because of the fragmentation of the link protein.[50] In flexor flexor /flex·or/ (flek´ser) 1. causing flexion. 2. a muscle that flexes a joint. flexor retina´culum see entries under retinaculum. tendons that are angulated around a bony prominence, the outer portion of the tendon subjected to tension has a low PG content, with a high proportion of dermatan sulphate PG.[7] In contrast, the deeper part of the tendon that is compressed against the bony surface has a high PG content, with a high proportion of chondroitin sulphate PG.[7,51] Cell morphology also changes.[51] In the region under tension, the cells are greatly elongated e·lon·gate tr. & intr.v. e·lon·gat·ed, e·lon·gat·ing, e·lon·gates To make or grow longer. adj. or elongated 1. Made longer; extended. 2. Having more length than width; slender. . In the pressure region, they are rounded and similar to fibrocartilage cells. Importantly, the removal of the compressive forces by translocation translocation /trans·lo·ca·tion/ (trans?lo-ka´shun) the attachment of a fragment of one chromosome to a nonhomologous chromosome. Abbreviated t. of the tendon results in rapid (within 2 weeks) remodeling remodeling /re·mod·el·ing/ (re-mod´el-ing) reorganization or renovation of an old structure. bone remodeling and loss of chondroitin sulphate PG from the pressure-bearing region. With the application of tension, total PG content decreases, but with a rise in the proportion of dermatan sulphate PG. The return of the tendon to its original position results in a slow (months) increase in PG content.[7] More recently, it has been shown that lateral compression of fetal tendons leads to marked changes in specific PGs and at the level of the gene.[52] Aggrecan and biglycan messenger ribonucleic acids (mRNAs) were increased without a change in decorin or type I collagen mRNAs. Furthermore, these changes appeared to be driven by increased synthesis of a specific growth factor (ie, transforming growth factor beta transforming growth factor beta (TGF-β), n a substance that is produced by bone cells and platelets to promote bone regeneration and wound healing. ) that is known to be a potent stimulator for aggrecan and biglycan synthesis but not decorin.[52] Glycoproteins: Stabilizers and Linkers of the Extracellular Matrix Glycoproteins constitute a small, but important, proportion of the total matrix components. They are soluble, multidomain, multifunctional macromolecules. Although they do not have prominent mechanical functions, they are integral to stabilizing the surrounding matrix and linking the matrix to the cell.[53] They are credited with the regulation of many functions, including producing changes in cell shape, enhancing cell motility, and stimulating cell proliferation and differentiation.[53] Among the best-characterized glycoproteins are fibronectin, tenascin, laminin laminin (lam´  n , link protein, thrombospondin,
osteopontin, and fibromodulin. Fibronectin is widespread in the ECM of
most CTs and plays a role in cell attachment to matrix components
through, for example, integrin integrin /in·te·grin/ (in´te-grin) any of a family of heterodimeric cell adhesion receptors, each consisting of an a and a ß polypetide chain, that mediate cell-to-cell and cell-to–extracellular matrix interactions. receptors; tenascin, also involved in
modulating cell attachment, is widespread in embryonic tissues and in
certain adult tissues including the myotendinous junction; and laminin
contributes to basement membrane structure.[53-57] Link protein, as
discussed above, is required to stabilize the PG aggregates in the
cartilage matrix, fibromodulin interacts with various matrix components
and controls collagen fibril formation, osteopontin sequesters calcium
and promotes tissue calcification calcification /cal·ci·fi·ca·tion/ (kal?si-fi-ka´shun) the deposit of calcium salts in a tissue.dystrophic calcification , and thrombospondin plays a role in cell attachment.[34,53] Changes to the Matrix in Connective Tissue Diseases and Injury Under normal physiological conditions, the maintenance of fibers, PG, and glycoproteins is tightly regulated and controlled through a balance between synthesis and degradation. This balance is maintained largely by stimulatory cytokines Cytokines Chemicals made by the cells that act on other cells to stimulate or inhibit their function. Cytokines that stimulate growth are called "growth factors. and growth factors in addition to the degradative matrix metalloproteinases (MMPs) and the tissue inhibitors of metalloproteinases (TIMPs).[58] The synthesis and secretion of MMPs and TIMPs is similarly modulated by an intricate network of signaling factors, cytokines, growth factors, and hormones.[58] The alteration of the balance between synthesis and degradation influences normal tissue architecture, impairs organ function, and changes the mechanical properties of the tissues. As a general observation, net degradation of matrix components occurs in osteoarthritis osteoarthritis or osteoarthrosis or degenerative joint disease Most common joint disorder, afflicting over 80% of those who reach age 70. It does not involve excessive inflammation and may have no symptoms, especially at first. , rheumatoid arthritis, pulmonary emphysema pulmonary emphysema n. See emphysema. , and osteoporosis. Net increases in synthesis over degradation leads to accumulation of ECM in fibrotic conditions, such as interstitial pulmonary fibrosis, liver fibrosis, and the sclerodermas. Trauma to CT also alters function. A partial or complete rupture of CT through excessive tensile loading commonly occurs in ligaments and tendons and at musculo-tendinous junctions. As a general principle, the loss of tensile loading, or compressive loading in the case of articular cartilage in a joint,[48] leads to rapid tissue deterioration.[59] The repair and remodeling of these structures is usually slow, taking many months, but follows a generally predicable pred·i·ca·ble adj. That can be stated or predicated: a predicable conclusion. n. 1. Something, such as a general quality or attribute, that can be predicated. 2. pattern.[26,59] During the initial stages of healing, rupture sites are bridged by newly synthesized type III collagen, but, as remodeling proceeds, increasing amounts of type I collagen predominate and provide greater strength.[20] Physical exercise also appears to have a beneficial effect on the strength of normal tendons and ligaments, although the results are somewhat equivocal. This may be because normal tendons and ligaments are in an optimal state.[60] Tension exerted on wounds is also thought to stimulate collagen synthesis and enhance the repair process by causing the collagen fibrils to align parallel to the direction of force sooner than for wounds that are not subjected to tension.[18] The degree of tension exerted on healing skin wounds, however, is more problematic, as prolonged tension leads to hypertrophic Hypertrophic Enlarged. Mentioned in: Heart Failure hypertrophic characterized by a state of hypertrophy. hypertrophic pulmonary osteoarthropathy see hypertrophic osteopathy. scarring where excess sulphated PGs produce a thickened thick·en tr. & intr.v. thick·ened, thick·en·ing, thick·ens 1. To make or become thick or thicker: Thicken the sauce with cornstarch. The crowd thickened near the doorway. 2. dermis.[61,62] Summary In the last 2 decades, the understanding of CT structure and function has increased enormously. It is now clear that the cells of the various GTs synthesize a variety of ECM components that act not only to underpin the specific biomechanical and functional properties of tissues, but also to regulate a variety of cellular functions. Importantly for the physical therapist, and as discussed above, CTs are responsive to changes in the mechanical environment, both naturally occurring and applied. The relative proportions of collagens and PGs largely determine the mechanical properties of CTs. The relationship between the fibril-forming collagens and PG concentration is reciprocal. Connective tissues designed to resist high tensile forces are high in collagen and low in total PG content (mostly dermatan sulphate PGs), whereas CTs subjected to compressive forces have a greater PG content (mostly chondroitin sulphate PGs). Hyaluronan has multiple roles and not only provides tissue hydration and facilitatation of gliding and sliding movements but also forms an integral component of large PG aggregates in pressure-resisting tissues. The smaller glycoproteins help to stabilize and link collagens and PGs to the cell surface. The result is a complex interacting network of matrix molecules[5,10,53] (Fig. 7), which determines both the mechanical properties and the metabolic responses of tissues. [Figure 7 ILLUSTRATION OMITTED] Patients with CT problems affecting movement are frequently examined and treated by physical therapists. A knowledge of the CT matrix composition and its relationship to the biomechanical properties of these tissues, particularly the predictable responses to changing mechanical forces, offers an opportunity to provide a rational basis for treatments. The complexity of the interplay among the components, however, requires that further research be undertaken to determine more precisely the effects of treatments on the structure and function of CTs. Acknowledgment We thank Mr Arthur Ellis, Department of Anatomy With Radiology, School of Medicine, The University of Auckland Not to be confused with Auckland University of Technology. The University of Auckland (Māori: Te Whare Wānanga o Tāmaki Makaurau) is New Zealand's largest university. , for assistance with preparation of the figures. References [1] Comper WD, ed. Extracellular Matrix, Volume 1: Tissue Function. Amsterdam, the Netherlands: Harwood Academic Publishers; 1996. [2] Comper WD, ed. Extracellular Matrix, Volume 2: Molecular Components and Interactions. Amsterdam, the Netherlands: Harwood Academic Publishers; 1996. [3] Harkness RD. Mechanical properties of connective tissues in relation to function. In: Parry DAD, Creamer LK, eds. Fibrous Proteins: Scientific, Industrial, and Medical Aspects. London, England: Academic Press; 1980:207-230. [4] Jozsa L, Kannus P, Balint JB, Reffy A. Three-dimensional ultrastructure ultrastructure /ul·tra·struc·ture/ (-struk?chur) the structure beyond the resolution power of the light microscope, i.e., visible only under the ultramicroscope and electron microscope. of human tendons. Acta Anat (Basel). 1991;142:306-312. [5] Heinegard D, Oldberg A. Glycosylated matrix proteins. In: Royce PM, Steinmann B, eds. Connective Tissue and Its Heritable her·i·ta·ble adj. 1. Capable of being passed from one generation to the next; hereditary. 2. Capable of inheriting or taking by inheritance. Disorders: Molecular, Genetic, and Medical Aspects. New York, NY: Wiley-Liss; 1993: 189-209. [6] Hardingham TE, Fosang AJ. Proteoglycans: many forms and many functions. FASEB FASEB Federation of American Societies for Experimental Biology J. 1992;6:861-870. [7] Flint MH, Gillard GC, Merrilees MJ. Effects of local environmental factors on connective tissue organisation and glycoaminoglycan synthesis. In: Parry DAD, Creamer LK, eds. Fibrous Proteins: Scientific, Industrial, and Medical Aspects. London, England: Academic Press; 1980:107-119. [8] Fraser JRE See Java Runtime Environment. JRE - Java Run-Time Environment , Laurent TC. Hyaluronan. In: Comper WD, ed. Extracellular Matrix, Volume 1: Tissue Function. Amsterdam, the Netherlands: Harwood Academic Publishers; 1996. [9] Bateman JF, Lamande SR, Ramshaw JAM. Collagen superfamily superfamily /su·per·fam·i·ly/ (soo´per-fam?i-le) 1. a taxonomic category between an order and a family. 2. . In: Comper WD, ed. Extracellular Matrix, Volume 2: Molecular Components and Interactions. 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The other principal urban centers are Newcastle, Wagga Wagga, Lismore, Wollongong, and Broken Hill. , Australia: Butterworths; 1971:730-740. [18] Flint MH. Connective tissue biology. In: McFarlane RM, McCrouther DA, Flint MH, eds. Dupuytren's Disease. Edinburgh, Scotland: Churchill Livingstone; 1990:13-24. [19] Vogel KG, Koob TJ. Structural specialization in tendons under compression. Int Rev Cytol. 1989;115:267-293. [20] Liu SH, Yang R-S R-S Reed-Solomon R-S Reset-Set R-S Relative Severity , al-Shaikh R, Lane JM. Collagen in tendon, ligament, and bone healing: a current review. Clin Orthop. 1995;318: 265-278. [21] Robbins JR, Vogel KG. Regional expression of mRNA for proteoglycans and collagen in tendon. Eur J Cell Biol. 1994;64:264-270. [22] Urban JPG See JPEG. jpg - JPEG , Roberts S. Intervertebral disc. In: Comper WD, ed. Extracellular Matrix, Volume 1: Tissue Function. Amsterdam, the Netherlands: Harwood Academic Publishers; 1996:203-233. [23] Meachim G, Stockwell RA. The matrix. 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[48] Houlbrooke K, Vause K, Merrilees MJ. Effects of movement and weightbearing on glycosaminoglycan content of sheep articular cartilage. Australian Journal of Physiotherapy. 1990;36:88-91. [49] Burton-Wurster N, Todhunter RJ, Lust G. Animal models of osteoarthritis. In: Woessner JF, Howell DS, eds. Joint Cartilage Degeneration: Basic and Clinical Aspects. New York, NY: Marcel Dekker Inc; 1993: 347-360. [50] Johnstone B, Bayliss MT. The large proteoglycans of the human intervertebral disc: changes in their biosynthesis and structure with age, topography, and pathology. Spine. 1995;20:674-684. [51] Merrilees MJ, Flint MH. Ultrastructural study of tension and pressure zones in a rabbit flexor tendon. Am J Anat. 1980;157:87-106. [52] Robbins JR, Evanko SP, Vogel KG. Mechanical loading and TGF-beta regulate proteoglycan synthesis in tendon. Arch Biochem Biophys. 1997;342:203-211. [53] von der Mark K, Goodman S. Adhesive glycoproteins. In: Royce PM, Steinmann B, eds. 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Extracellular matrix degradation. In: Hay ED, ed. Cell Biology of Extracellular Matrix. 2nd ed. New York, NY: Plenum Press; 1991:255-302. [59] Viidik A. Structure and function of normal and healing tendons and ligaments. In: Mow VC, Ratcliffe A, Woo SLY, eds. Biomechanics of Diathrodial Joints, Volume 1. New York, NY: Springer-Verlag New York Inc; 1990:3-38. [60] Viidik A. Adaptability of connective tissues. In: Saltin B, ed. Biochemistry of Exercise: Metabolic Regulation and Its Practical Significance. Champaign, Ill: Human Kinetics Publishers Inc; 1986:545-546. [61] Gillard GC, Reilly HC, Bell-Booth PG, Flint MH. A comparison of the glycosaminoglycans of weight-bearing and non-weight-bearing human dermis. J Invest Dermatol. 1977;69:257-261. [62] Kischer CW, Shetlar MR. Collagen and mucopolysaccharides in the hypertrophic scar. Connect Tissue Res. 1974;2:205-213. EM Culav, MHSc(Hons), BPT BPT Bridgeport (Connecticut) BPT Best Practicable Control Technology BPT Best Practicable Control Technology Currently Available BPT BP Prudhoe Bay Royalty Trust (stock symbol) BPT Boston Playwrights' Theatre , is Senior Lecturer, School of Physiotherapy School of Physiotherapy is located in Lahore, Punjab, Pakistan. It is located in Mayo Hospital and is affiliated with King Edward Medical College. , Faculty of Health Studies, Auckland Institute of Technology, Private Bag 92006, Auckland 1020, New Zealand (elizabeth.culav@ait.ac.nz). Address all correspondence to Ms Culav. CH Clark, MHSc(Hons), BSc, Dip Phys, is Senior Lecturer, School of Physiotherapy, Faculty of Health Studies, Auckland Institute of Technology. MJ Merrilees, PhD, is Associate Professor, Department of Anatomy With Radiology, School of Medicine, The University of Auckland, Auckland, New Zealand. |
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