Synovial joint
Template:Short description Template:Infobox anatomy A synovial joint, also known as diarthrosis, joins bones or cartilage with a fibrous joint capsule that is continuous with the periosteum of the joined bones, constitutes the outer boundary of a synovial cavity, and surrounds the bones' articulating surfaces. This joint unites long bones and permits free bone movement and greater mobility.<ref>The Musculoskeletal System. In: Dutton M. eds. Dutton's Orthopaedic Examination, Evaluation, and Intervention, 5e. McGraw-Hill; Accessed January 25, 2021. https://accessphysiotherapy-mhmedical-com.libaccess.lib.mcmaster.ca/content.aspx?bookid=2707§ionid=224662311</ref> The synovial cavity/joint is filled with synovial fluid. The joint capsule is made up of an outer layer of fibrous membrane, which keeps the bones together structurally, and an inner layer, the synovial membrane, which seals in the synovial fluid.
They are the most common and most movable type of joint in the body. As with most other joints, synovial joints achieve movement at the point of contact of the articulating bones. They originated 400 million years ago in the first jawed vertebrates.
StructureEdit
Synovial joints contain the following structures:
- Synovial cavity: all diarthroses have the characteristic space between the bones that is filled with synovial fluid.
- Joint capsule: the fibrous capsule, continuous with the periosteum of articulating bones, surrounds the diarthrosis and unites the articulating bones; the joint capsule consists of two layers - (1) the outer fibrous membrane that may contain ligaments and (2) the inner synovial membrane that secretes the lubricating, shock absorbing, and joint-nourishing synovial fluid; the joint capsule is highly innervated, but without blood and lymph vessels, and receives nutrition from the surrounding blood supply via either diffusion (slow), or via convection (fast, more efficient), induced through exercise.
- Articular cartilage: the bones of a synovial joint are covered by a layer of hyaline cartilage that lines the epiphyses of the joint end of the bone with a smooth, slippery surface that prevents adhesion; articular cartilage functions to absorb shock and reduce friction during movement.
Many, but not all, synovial joints also contain additional structures:<ref name="Graysp20"/>
- Articular discs or menisci - the fibrocartilage pads between opposing surfaces in a joint
- Articular fat pads - adipose tissue pads that protect the articular cartilage, as seen in the infrapatellar fat pad in the knee
- Tendons<ref name="Graysp20"/> - cords of dense regular connective tissue composed of parallel bundles of collagen fibers
- Accessory ligaments (extracapsular and intracapsular) - the fibers of some fibrous membranes are arranged in parallel bundles of dense regular connective tissue that are highly adapted for resisting strains to prevent extreme movements that may damage the articulationTemplate:Citation needed
- Bursae - sac-like structures that are situated strategically to alleviate friction in some joints (shoulder and knee) that are filled with fluid similar to synovial fluid<ref name="Tortora12thEd"/>Template:Page needed
The bone surrounding the joint on the proximal side is sometimes called the plafond (French word for ceiling), especially in the talocrural joint. Damage to this structure is referred to as a Gosselin fracture.
Blood supplyEdit
The blood supply of a synovial joint is derived from the arteries sharing in the anastomosis around the joint.
TypesEdit
There are seven types of synovial joints.<ref name="umich2010couse"/> Some are relatively immobile, therefore more stable. Others have multiple degrees of freedom, but at the expense of greater risk of injury.<ref name="umich2010couse"/> In ascending order of mobility, they are:
| Name | Example | Description |
|---|---|---|
| Plane joints (or gliding joint) |
carpals of the wrist, acromioclavicular joint | These joints allow only gliding or sliding movements, are multi-axial such as the articulation between vertebrae. |
| Hinge joints | elbow (between the humerus and the ulna) | These joints act as a door hinge does, allowing flexion and extension in just one plane, i.e. uniaxial. |
| Pivot joints | atlanto-axial joint, proximal radioulnar joint, and distal radioulnar joint | One bone rotates about another |
| Condyloid joints (or ellipsoidal joints) |
wrist joint (radiocarpal joint) | A condyloid joint is a modified ball and socket joint that allows primary movement within two perpendicular axes, passive or secondary movement may occur on a third axes. Some classifications make a distinction between condyloid and ellipsoid joints;<ref name="Rogers2010p157"/><ref name="Sharkey2008p33"/> these joints allow flexion, extension, abduction, and adduction movements (circumduction). |
| Saddle joints | Carpometacarpal or trapeziometacarpal joint of thumb (between the metacarpal and carpal - trapezium), sternoclavicular joint | Saddle joints, where the two surfaces are reciprocally concave/convex in shape, which resemble a saddle, permit the same movements as the condyloid joints but allows greater movement. |
| Template:Nowrap "universal Joint" |
shoulder (glenohumeral) and hip joints | These allow for all movements except gliding |
| Compound joints<ref name="Moini2011p231"/><ref name="Abernethy2005p331"/> / bicondyloid joints<ref name="Graysp20"/> |
knee joint | condylar joint (condyles of femur join with condyles of tibia) and saddle joint (lower end of femur joins with patella) |
Multiaxial jointsEdit
A multiaxial joint (polyaxial joint or triaxial joint) is a synovial joint that allows for several directions of movement.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> In the human body, the shoulder and hip joints are multiaxial joints.<ref>Template:Cite book</ref> They allow the upper or lower limb to move in an anterior-posterior direction and a medial-lateral direction. In addition, the limb can also be rotated around its long axis. This third movement results in rotation of the limb so that its anterior surface is moved either toward or away from the midline of the body.<ref name="ana&physio">Template:Cite book</ref>
FunctionEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} The movements possible with synovial joints are:
- abduction: movement away from the mid-line of the body
- adduction: movement toward the mid-line of the body
- extension: straightening limbs at a joint
- flexion: bending the limbs at a joint
- rotation: a circular movement around a fixed point
Clinical significanceEdit
Template:AnchorThe joint space equals the distance between the involved bones of the joint. A joint space narrowing is a sign of either (or both) osteoarthritis and inflammatory degeneration.<ref name="JacobsonGirish2008">Template:Cite journal</ref> The normal joint space is at least 2 mm in the hip (at the superior acetabulum),<ref name="Lequesne2004">Template:Cite journal</ref> at least 3 mm in the knee,<ref>Template:Cite book</ref> and 4–5 mm in the shoulder joint.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}, in turn citing: Template:Cite journal</ref> For the temporomandibular joint, a joint space of between 1.5 and 4 mm is regarded as normal.<ref name="Massilla ManiSivasubramanian2016">Template:Cite journal</ref> Joint space narrowing is therefore a component of several radiographic classifications of osteoarthritis.
In rheumatoid arthritis, the clinical manifestations are primarily synovial inflammation and joint damage. The fibroblast-like synoviocytes, highly specialized mesenchymal cells found in the synovial membrane, have an active and prominent role in the pathogenic processes in the rheumatic joints.<ref name=nygaard>Template:Cite journal</ref> Therapies that target these cells are emerging as promising therapeutic tools, raising hope for future applications in rheumatoid arthritis.<ref name=nygaard />
Evolutionary originsEdit
Synovial joints has been found in earliest jawed vertebrates (gnathostomes) 400 million years ago during the Silurian and Devonian. This finding overturns an earlier view that these joints first evolved in early tetrapods for terrestrial locomotion. Comparative studies find that synovial joints in all major groups of jawed vertebrates, including cartilaginous fishes (sharks, skates, and rays), bony fishes, and tetrapods. They are however absent in jawless vertebrates such as lampreys and hagfish. Cartilaginous fishes have true synovial joints with clear synovial cavities, articular cartilage lined by flattened chondrocytes, and express key developmental signaling molecules including growth differentiation factor-5 (Gdf5) and β-catenin, and require muscle contraction for proper joint cavitation. In contrast, cyclostomes have joints filled with tissue rather than fluid-filled cavities, with proteoglycans uniformly distributed across cartilages. Fossil evidence finds jawless osteostracans had pectoral fin connections filled with canals incompatible with fluid-filled joint cavities, while early jawed placoderms have reciprocally articulating surfaces separated by joint cavities. Synovial joints, it have been suggested, arose due to the high mechanical loads associated with predation and feeding and as a result allowed for the evolution of the complex skeletons of modern jawed vertebrates.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>
ReferencesEdit
<references> <ref name="Graysp20">Template:Cite book</ref> <ref name="Tortora12thEd">Tortora & Derrickson () Principles of Anatomy & Physiology (12th ed.). Wiley & Sons</ref> <ref name="umich2010couse">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> <ref name="Rogers2010p157">Rogers, Kara (2010) Bone and Muscle: Structure, Force, and Motion p.157</ref> <ref name="Sharkey2008p33">Sharkey, John (2008) The Concise Book of Neuromuscular Therapy p.33</ref> <ref name="Moini2011p231">Moini (2011) Introduction to Pathology for the Physical Therapist Assistant pp.231-2</ref> <ref name="Abernethy2005p331">Bruce Abernethy (2005) The Biophysical Foundations Of Human Movement pp.23, 331</ref> </references>