Arthrokinematics: Difference between revisions
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A '''slide '''is a translatory movement, sliding of one joint surface over another.<br> | A '''slide '''is a translatory movement, sliding of one joint surface over another.<br> | ||
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The '''convex-concave rule''' is the basis for determining the direction of the mobilizing force when joint mobilization gliding techniques are used to increase a certain joint motion. | The '''convex-concave rule''' is the basis for determining the direction of the mobilizing force when joint mobilization gliding techniques are used to increase a certain joint motion. | ||
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The direction in which sliding occurs depends on whether the moving surface is concave or convex. | The direction in which sliding occurs depends on whether the moving surface is concave or convex. | ||
Revision as of 19:47, 18 June 2019
Original Editor - Justine Haroon
Top Contributors - Abdul Wajid, Justine Haroon, Admin, Lucinda hampton, Laura Ritchie, Shaimaa Eldib, Claire Knott, Tony Lowe, Kai A. Sigel, WikiSysop, Kim Jackson and Ahmed M Diab
'Arthrokinematics' refers to the movement of joint surfaces.
The angular movement of bones in the human body occurs as a result of a combination of rolls, spins, and slides.
A roll is a rotary movement, one bone rolling on another.
A spin is a rotary movement, one body spinning on another.
A slide is a translatory movement, sliding of one joint surface over another.
The convex-concave rule is the basis for determining the direction of the mobilizing force when joint mobilization gliding techniques are used to increase a certain joint motion.
The direction in which sliding occurs depends on whether the moving surface is concave or convex.
Concave = hollowed or rounded inward
Convex = curved or rounded outward
If the moving joint surface is CONVEX, sliding is in the OPPOSITE direction of the angular movement of the bone.
If the moving joint surface is CONCAVE, sliding is in the SAME direction as the angular movement of the bone.
Examples:
- Glenohumeral articulation: concave glenoid fossa articulates with the convex humeral head
Glenohumeral posterior glide increases flexion and internal rotation
Glenohumeral anterior glide increases extension and external rotation
- Humeroradial articulation: convex capitulum articulates with the concave radial head
Dorsal or posterior glide of the head of radius increases elbow extension
Volar or anterior glide of the head of the radius increases elbow flexion
- Hip joint: concave acetabulum articulates with the convex femoral head
Hip posterior glide increases flexion and internal rotation
Hip anterior glide increases extension and external rotation
- Tibiofemoral articulation: concave tibial plateaus articulate on the convex femoral condyles
Tibiofemoral posterior glide increases flexion
Tibiofemoral anterior glide increases extension
- Talocrural joint: convex talus articulates with the concave mortise (tibia and fibula)
Talocrural dorsal or posterior glide increases dorsiflexion
Talocrural ventral or anterior glide increases plantarflexion
Resources[edit | edit source]
Kisner, C. & Colby, L.A. (2002). Therapeutic Exercise: Foundations and Techniques, 5th ed. F.A. Davis: Philadelphia.
References[edit | edit source]
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