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BIOMECHANICS OF ELBOW COMPLEX

BIOMECHANICS OF ELBOW COMPLEX. Prepared by: Dr. Ishaq Ahmed MSPT(KMU), BSPT(UHS), t-DPT(KMU). LECTURE-3. Elbow biomechanics. ROM flexion and extension - 0 to 140 30 to 130 required for most ADL flexion-extension axis - a loose hinge .

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BIOMECHANICS OF ELBOW COMPLEX

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  1. BIOMECHANICS OF ELBOW COMPLEX Prepared by: Dr. Ishaq Ahmed MSPT(KMU), BSPT(UHS), t-DPT(KMU) LECTURE-3

  2. Elbow biomechanics • ROM flexion and extension - 0 to 140 • 30 to 130 required for most ADL • flexion-extension axis - a loose hinge. • The active ROM for elbow flexion with the forearm supinated is typically considered to be from about 135 to 145 degrees. • the range for passive flexion is between 150and 160. • the forearm is either in pronation or midway between supination and pronation, the ROM is less than it is when the forearm is supinated.

  3. Passive tension in the triceps may limit elbow flexion when the shoulder is simultaneously moved into full flexion • Passive tension created in the long head of the biceps brachii by passive shoulder hyperextension may limit full elbow extension

  4. Axis of forearm motion.

  5. Axis of motion: • Variation of the flexion axis throughout ROM described in terms of the screw displacement axis (SDA), which shows the instantaneous rotation and position of the axis throughout flexion. • The average SDA - shown to be in line with the anteroinferior aspect of the medial epicondyle, the center of the trochlea, and the center projection of the capitellum onto a parasagittal plane.

  6. Variations • activity of the various muscles may influence the pattern of motion during active flexion, • differences in contours of the joint surfaces may explain differences during passive motion. • Intra individual and inter individual variations in the axes appear to be greater in the frontal plane than in the horizontal plane.

  7. valgus-varus laxity was greatest between 0and 40of flexion and decreased considerably when flexion exceeded 100. • all instantaneous rotation axes nearly intersected on the medial facet of the trochlea.

  8. Carrying angle: • The average angle in full elbow extension is about 15 • This normal valgus angulation is called the carrying angle or cubitus valgus. • A varus angulation at the elbow is referred to as cubitus varus • the carrying angle disappears when the forearm is pronated and the elbow is in full extension • and when the supinated forearm is flexed against the humerus in full elbow flexion.

  9. The configuration of the trochlear groove determines the pathway of the forearm during flexion and extension. • In the most common configuration of the groove, the ulna is guided progressively medially from extension to flexion, so that in full flexion, the forearm comes to rest in the same plane as the humerus. • In extension, the forearm moves laterally until it reaches a position slightly lateral to the axis of the humerus in full extension.

  10. Pronation-supination • The radiocapitellar and proximal radioulnar joints • The normal range of forearm rotation is 180 with • pronation of 80 to 90 and • supination of ~ 90 • Most ADL can be accomplished with 100 of forearm rotation • (50 of pronation and 50 of supination)

  11. The normal axis of forearm rotation - • the center of the radial head to the center of the distal ulna • axis of rotation shifts slightly ulnar and volar during supination • shifts radial and dorsal during pronation • The radius moves • proximally with pronation • distally with supination

  12. The elbow has inherent articular stability at the extremes of extension and flexion. • In full extension, the humeroulnar joint is in a close-packed position. • Bony contact of the olecranon process in the olecranon fossa limits the end of the extension range, • configuration of the joint structures helps provide valgus and varus stability. • Resistance to valgus stress in extension: • The bony components, MCL, and anterior joint capsule. • Resistance to varus stress in full extension, • lateral collateral complex and joint capsule.( half) • The bony component (half).

  13. Resistance to joint distraction in the extended position is provided entirely by soft tissue structures. • Anterior portion of the joint capsule provides the majority of the resistance to anterior displacement of the distal humerus out of the olecranon fossa, whereas the MCL and LCL contribute only slightly. • Elbow flexion of about 80is considered to be the elbow position at which the least amount of tension is present in the joint capsule

  14. Stability of elbow with rotation • Forearm rotation - important role in stabilizing the elbow, especially when the elbow is moved passively. • With passive flexion, the MCL deficient elbow is more stable in supination. • LCL-deficient elbow is more stable in pronation. • Elbow more stable in supination in coronoid fractures that involve more than 50% of the coronoid with or without an intact MCL.

  15. Most simple elbow dislocations - relatively stable once reduced • MCL is completely ruptured in nearly all cases. • LCL is disrupted in most cases

  16. Coronoid • Fractures involving > 50% of the coronoid shows significantly increased varus-valgus laxity, even in the setting of repaired collateral ligaments • The coronoid plays a significant role in posterolateral stability in combination with the radial head.

  17. Soft tissues that attach to the base of the coronoid include • Anteriorly- Insertion of the anterior capsule and brachialis • Medial- insertion of the MCL. • Reduction and fixation of coronoid fractures help to restore the actions of these stabilizers

  18. Olecranon • One study - no significant differences in elbow extensor power between olecranonectomywith triceps reattachment and open reduction internal fixation of olecranon fractures • There are significant increases in joint pressure with excision of 50% of the olecranon, which over time may contribute to elbow pain and arthritis

  19. Proximal radius • The radial head is an important secondary valgus stabilizer of the elbow (30%) • more important for valgus stability in the presence of MCL deficiency • Radial head excision also increases varus-valgus laxity and posterolateral rotatory instability, regardless of whether the collateral ligaments are intact.

  20. Soft tissue stabilization • Medial collateral ligament complex • AMCL is the primary constraint for valgus and posteromedial stability • Complete division causes valgus and internal rotatory instability throughout the complete arch of flexion with • maximal valgus instability at 70 • maximal rotational instability at 60

  21. LCL complex • The LCL is the primary constraint of external rotation and varus stress at the elbow. • complete sectioning causes varus and posterior radial head subluxation • The flexion axis of the elbow passes through the origin of the LCL so that there is uniform tension in the ligament throughout the arc of flexion.

  22. damage to the LCL complex is the initial injury seen along the continuum of injuries resulting from elbow dislocation • In Lateral surgical approaches to the elbow for radial head fixation or replacement. • As long as the annular ligament is intact, the radial collateral ligament or the lateral ulnar collateral ligament can be cut and repaired without causing instability

  23. When the radial head is excised in the presence of a deficient LCL, there is increased varus and external rotatory instability. • Radial head replacement in this setting improves posterolateral instability.

  24. Joint forces • significant compressive and shear forces at the elbow • Loads across the elbow - distributed • 43% across the ulnohumeral joint and • 57% across the radiocapitellar joint • Joint reaction forces vary with elbow position. • Force transmission at the radiocapitellar joint is greatest between 0 and 30 of flexion and is greater in pronation than in supination.

  25. Muscles • Muscles that cross the elbow joint act as • dynamic stabilizers as they compress the joint. • Compression of the elbow joint by the muscles protects the soft tissue constraints. • throwing an object can cause a valgus stress that is greater than the failure strength of the MCL. • The flexor-pronator muscle group contracts during the throwing motion and provides dynamic stabilization to the medial aspect of the elbow, which protects the MCL from injury

  26. Muscles • Elbow flexors • Biceps brachii • Brachialis • Brachioradialis • Weak assistance from Pronatorteres • Elbow extensor • Triceps brachii • Anconeus provides assistance

  27. Muscles • Radioulnar pronators • Pronatorteres • Pronatorquadratus • Brachioradialis • Radioulnar supinators • Biceps brachii • Supinator muscle • Brachioradialis

  28. Muscles • “Tennis elbow" - common problem usually involving extensor digitorum muscle near its origin on lateral epicondyle • known lateral epicondylitis • associated with gripping & lifting activities • Medial epicondylitis • somewhat less common • known as golfer's elbow • associated with medial wrist flexor & pronator group near their origin on medial epicondyle • Both conditions involve muscles which cross elbow but act primarily on wrist & hand

  29. Muscles • Anterior • Primarily flexion & pronation • Biceps brachii • Brachialis • Brachioradialis • Pronator teres • Pronator quadratus

  30. Muscles • Posterior • Primarily extension & supination • Triceps brachii • Anconeus • Supinator

  31. Nerves • All elbow & radioulnar joints muscles are innervated from median, musculotaneous, & radial nerves of brachial plexus

  32. Nerves • Median nerve - derived from C6 & C7 • Pronator teres • Pronator quadratus (anterior interosseus nerve) • Sensation to palmar aspect of hand & first three phalanges, palmar aspect of radial side of fourth finger, dorsal aspect of index & long fingers

  33. Nerves • Musculotaneous nerve - branches from C5 & C6 • Biceps brachii • Brachialis

  34. Biceps Brachii Muscle Flexion of elbow Supination of forearm Weak flexion of shoulder joint Weak abduction of shoulder joint when externally rotated

  35. Brachialis Muscle True flexion of elbow

  36. Brachioradialis Muscle Flexion of elbow Pronation from supinated position to neutral Supination from pronated position to neutral

  37. Triceps BrachiiMuscle All heads: extension of elbow Long head: extension of shoulder joint; adduction of shoulder joint;horizontal abduction

  38. Anconeus Muscle Extension of elbow

  39. Pronator Teres Muscle Pronation of forearm Weak flexion of elbow

  40. Pronator Quadratus Muscle Pronation of forearm

  41. Supinator Muscle Supination of forearm

  42. Elbow Flexion • Ex. Biceps curl • Agonists • Biceps brachii • Brachialis • Brachioradialis

  43. Elbow Extension • EX. Push-up • Agonists • Triceps brachii • Anconeus

  44. Radioulnar Pronation • Agonists • Pronator teres • Pronator quadratus • Brachioradialis

  45. Radioulnar Supination • Ex. Tightening a screw • Agonists • Biceps brachii • Supinator muscle • Brachioradialis

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