Elbow Anatomy, Biomechanics, and Pathology PDF

Summary

This document provides a detailed description of the elbow joint, including its anatomy, biomechanics, and pathologies. It covers the structure and function of the crucial parts of the elbow joint, such as the humero-ulnar and humero-radial joints. The document also discusses the implications of various factors impacting the elbow's range of motion and stability.

Full Transcript

The Elbow
Anatomy, Biomechanics, and Pathology

 The elbow joint is a complex joint due to the number of articulations that work
together to perform its motions:
• Humero-ulnar joint.
• Humero-radial joint.
• Proximal radio-ulnar joint.
• Distal radio-ulnar joint.
 While the interactions are complex, the humero-ulnar and humero-radial joints
can be viewed together as a uni- axial joint providing the main flexion/extension
of the elbow joint with the following range of motion:
 flexion: - approximately 145° (actively) approximately 160° (passively)
 extension: - approximately 0-15°
 Elbow flexion is limited or checked by a muscular end-field from either the
triceps muscle or from the biceps if there is a large muscle belly. Elbow extension
is limited by a bony end-field. The olecranon abuts against the olecranon fossa to
prevent hyperextension. It is common for flexible females to exhibit
hyperextension of the elbow up to 20°.
 The resting position for the elbow is 90° flexion with the forearm in neutral
supination and pronation.
 The position of reference is the upper arm and forearm in the frontal plane with
the elbow straight and the forearm supinated.
 The close-packed position is full extension.

The Humero-ulnar Joint
 The humero-ulnar joint is the medial joint system between the humerus,(the
trochlea) and the ulna (the olecranon). Its classification is a diarthrodial, synovial,
hinge (uniaxial) joint. The elbow is a compound joint that is considered to have
one degree of freedom for flexion and extension. The trochlea is situated
between the two epicondyles of the distal end of the humerus.
 The trochlea’s transverse surface is concave and its antero- posterior surface is
convex, which melds a convex surface with a concave one to make one complex
curved surface shaped like a saddle. Therefore, the humero-ulnar joint is a saddle
joint.
 The transverse axis of the humerus does not lie at a right angles to its
longitudinal axis. The transverse axis lies in a slightly oblique and medially
directed line
 The ulna tends to have a deviation laterally from the longitudinal axis of the
humerus that forms an acute angle of between 7°and 12°. This is known as the
carrying angle and occurs with elbow extension.

Humero-Ulnar Joint
 The carrying angle of the elbow will usually be caused by a few common factors.
 The transverse axis through the trochlea tilts medially and obliquely causing the
medial surface to lie distal to the lateral surface.

 The articular groove between the medial and lateral surfaces of the trochlea
circumscribes a spiral. From an anterior view, the groove is directed laterally. As
this groove circumscribes the spiral on the trochlea, it faces medially on its
posterior surface. The olecranon glides medially on this spiral groove during
extension to create the carrying angle and direct the forearm laterally. During
flexion the olecranon follows the trochlear groove laterally thereby directing the
forearm medially.
 This actually creates a medial gapping with lateral gliding and a lateral gapping
with medial glide during flexion and extension

 Flexion-extension of the elbow is accompanied by a screw- home mechanism
with conjunct rotation of the ulna. With the elbow fully flexed, the olecranon is
directed laterally. As the elbow is extended, the olecranon circumscribes the
trochlear groove to direct itself medially. By following the trochlear groove, the
ulna externally rotates (or supinates) during elbow flexion and internally rotates
(or pronates) during elbow extension. Whether or not the carrying angle changes
in flexion and extension is controversial. It has been described as both decreasing
in angle with flexion and not changing at all. If change does indeed occur, it is
related to the angulation of the trochlea

 The conjunct rotation during flexion and extension at the elbow can be observed
of the every time you bring food to your mouth. In order to feed yourself, your
forearm must lie medial to the axis of the upper arm. This is achieved by a
combination of internal rotation of the glenohumeral-humeral joint and flexion
of the elbow with slight supination or external rotation of the forearm.

ELBOW JOINT
 The forearm is also influenced by the carrying angle. As you completely extend
your elbow, the medial structures move apart while the lateral structures
become compressed, creating the elbow deformity known as cubitus valgus
commonly seen in tennis players, pitchers, and javelin throwers. The radius
becomes close-packed against the capitellum during full extension, which causes
a tendency for it to glide distally.
 Excessive valgus overload during the acceleration phase of pitching. This valgus
overload wedges the olecranon into the olecranon fossa. The follow-through
phase of a throw can cause impingement farther posteriorly and increase
symptoms by adding stress to this area. This valgus stress occurs before full
extension of the elbow.
 Osteochondritis can also be a secondary pathology with repetitive microtrauma
in the throwing athlete . The repetitive compression forces associated with
elbow extension in the throwing maneuver may result in cartilage damage and
formation of loose bodies. Osteochondrosis and osteochondritis dissecans may
be more prevalent in the immature skeleton and are often associated with the
“Little League elbow syndrome

HUMERAL-RADIAL JOINT
 The humero-radial joint forms the lateral relationship between the humerus
(capitulum) and the head of the radius. It is a diarthrodial, synovial, hinge joint by
classification. The hemispherical capitulum articulates with a concave, oval facet
on the proximal head of the radius .
 The medial rim of the head of the radius fits into a groove between the trochlea
and capitulum . During both flexion-extension and pronation-supination, this
capitulo-trochlear groove guides movement and increases the stability of the
head of the radius.
 The humero-radial joint is a modified saddle joint. The capitulum has no
cartilage on its extreme posterior surface. And the articular cartilage of the
radius has no contact with the posterior part of the capitulum at full
extension.
 The radial cartilage is commonly irritated by bony contact with the
posterior aspect of capitulum during traumatic hyperextension injuries. An
initial stage of cartilage degeneration accompanied by pain and
dysfunction can occur as a result of this trauma. This injury is frequently
misinterpreted as a lateral epicondylitis.

HUMERAL-RADIAL JOINT
 As the capitulum assumes a close-packed position against the radius during
extreme extension, it creates a lateral compression at the humero-radial joint. If
the hyperextension is preceded by a “running start” such as occurs during a
tennis player’s backhand swing, the capitulum makes even greater bony contact
against the radial cartilage which further increases the chances for injury
including micro-trauma to the cartilage, bleeding, swelling, and resultant muscle
guarding.
 During flexion, the coronoid process of the ulna glides into the coronoid fossa,
which is devoid of articular cartilage. If one has small biceps, irritation of the
interarticular tissues can occur with pain and dysfunction
 The articular cartilage of the head of the radius extends distally around the head
to articulate with the annular ligament. The motion that occurs within this joint is
a uniaxial spin. Rotation between these structures produces pronation and
supination of the forearm.
 The radial head is a tapered disk, more oval than round. This oval head of
the radius is also tapered like a section of a cone.

LIGAMENTS of the Elbow

Ligaments of the Elbow
 The medial collateral ligament reinforces the humero-ulnar articulation. This
triangular shaped ligament extends from the medial epicondyle of the humerus
and attaches to the coronoid and olecranon process of the ulna. The medial
collateral ligament is a thickening of the joint capsule.
 Two distinct ligamentous bundles correspond to the anterior and posterior
portions of the ulnar collateral ligament. The posterior bundle consists of
collagen bundles within the layers of the capsule; the anterior bundle consists of
a similar thickening within the capsular layers, but has an additional ligament
complex superficial to the capsular layers
 The medial collateral ligament (MCL) resists any valgus load to the joint. The
ligament has three bands: the anterior oblique, posterior oblique, and transverse
portions. The anterior oblique band originates from the inferior surface of the
medial epicondyle. It lies just posterior to the flexion/extension axis, which
causes its anterior portion to be taut in extension and the posterior position to
be taut in flexion. The anterior band is the primary ligamentous support for the
medial elbow.

LIGAMENTS
 The transverse band originates from the medial olecranon and inserts on the
coronoid process of the ulna. This is primarily a thickening of the joint capsule
that has only minor contribution to elbow stability.
 The posterior oblique band originates from the medial epicondyle and inserts
into the posteromedial olecranon. The band is taut in flexion, primarily after 60°.
 The fan-shaped radial collateral ligament, also called the lateral collateral
ligament, reinforces the humero-radial joint. It runs from the lateral epicondyle
of the humerus and attaches to the annular ligament and olecranon process.
 The annular ligament is a strong fibrous-osseous ring lined with articular
cartilage that surrounds the circumference of the head of the radius. The
ligament covers four- fifths of the circumference of the radial head and is funnel
shaped tapering distally. Its external surface blends with the joint capsule and
radial collateral ligament. The annular ligament is attached to the anterior and
posterior edges of the radial notch.

Humeral-Radial Joint and Ligaments

 When the elbow is semi-flexed, the radio-humeral joint lacks bony stabilization
and is vulnerable to injury. The strong biceps tendon inserts into the radial
tuberosity and provides a cranial force and can stress on the annular ligament.
This lack of bony stabilization frequently results in an elbow dislocation where
the radius loses its relationship with the capitulum, the radial notch of the ulna,
and the capitulo-trochlear groove.
 Since the radius lacks bony stability in flexion, it can only rely on the annular
ligament to hold it in place. If one pronates the forearm, not only is a fulcrum
created between the radius and ulna, but also the biceps tendon is lengthened to
create a greater pull. By lifting the heavy suitcase in this position, an annular
ligament rupture can occur due to the cranial pull of the biceps tendon

Interosseous Membranes

MUSCLES of the FOREARM

 Pronator teres
O: Humeralhead—Immediately above the medial epicondyle of the
humerus, common flexor tendon
Ulnar head—Medial side coronoid process of ulna I: Middle of lateral
surface of radius
A: Pronate forearm and assist in flexion elbow
N: Median nerve,C6-C7
 Pronator quadratus
O: Medial side, anterior surface of distal quarter of ulna I: Lateral side,
anterior surface distal quarter radius
A: Pronates forearm\

N: Median nerve,C8-T1
 Supinator
O: Lateral epicondyle of humerus, radial collateral ligament, annular
ligament, and supinator crest of ulna
I: Lateral surface, upper third of anterior and posterior body of radius
A: Supinates forearm N: Radial nerve,C5-C6

 Biceps brachii

 O: Short head—Apex of coracoid process
Long head—Supraglenoid tubercle of scapula
 I: Tuberosity of radius
A: Flexes and supinates elbow and flexes shoulder with
 some abduction if humerus is externally rotated
 N: Musculocutaneousnerve,C5-C6
 Triceps brachii
 O: Long head—Infraglenoid tubercle of scapula
Lateral head—lateral and posterior surfaces, proximal half
 body of humerus, above radial groove Medial head—distal two thirds medial and
posterior
 surfaces of humerus, below radial groove
I: Posterior surface of olecranon process of ulna
A: Extends elbow, and ADD and extends shoulder (long head)
N: Radialnerve,C6-C8
 Anconeus
 O: Posterior surface lateral epicondyle of humerus I: Lateral side olecranon process and
upper quarter
 posterior surface of ulna
 A: Extends elbow
 N: Radialnerve,C7-C8

ARTERIAL SUPPLY to the ARM

NERVES of the FOREARM

Median Nerve

Nerves of the Elbow and Forearm
 Median Nerve
 Segmental levels C5-T1 Cords: medial and lateral
 Travels down medial aspect of arm with brachial artery and ulnar nerve.

 Forearm: About 5 to 8 centimeters below the lateral epicondyle it gives off the
anterior interosseous branch innervating muscles anterior to the membrane. The
median nerve proper passes between the superficial and deep flexors
innervating the flexor digitorum superficialis and palmaris longus.
 Approximately 5.5 centimeters above the radial styloid, the palmar cutaneous
branch innervates the skin of the proximal palm over the first, second, and third
metacarpals. The median nerve passes through the carpal tunnel and gives off a
motor branch to the thenar muscles, and a terminal motor branch to the two
radial lumbricals and palmar digital nerves to the volar surface of I, II, III, and
radial half of IV, and the dorsal surface of their middle and distal phalanges.

Median Nerve Pathology
 Pathology:
 1. Common sites of injury:
a. Fracture of humerus and distal radius
b. Dislocations of the elbow and anterior dislocation of the lunate.
c. Lacerations of the anterior wrist. d. Compression sites:
 Ligament of Struthers
Pronator teres (pronator syndrome) Anterior interosseous syndrome Carpal tunnel
 2. SYMPTOMS:
A. Distal injury: Deficits involve precision movements of the thumb and index, loss of
thumb tip to fingertip prehension, loss of pulp to pulp prehension, and loss of protective
and discriminatory sensibility in I, II, III, and the radial half of IV.
Presentation will be an “ape hand” appearance.
 B. Proximal to elbow: there is an additional loss of wrist flexion secondary to flexor carpi
radialis.
 C. Injury of the anterior interossei nerve results in loss of flexion of the distal thumb and
index finger.

Median Nerve and Muscles
of the forearm

Normal carpal tunnel and Guyon’s canal. Axial proton density MR image at level of
proximal carpal tunnel shows flexor retinaculum (straight black arrow) extending
between pisiform (P) and scaphoid (S) and enclosing median nerve (round-tailed
arrow)and low-signal-intensity flexor digitorum and flexor pollicis longus tendons.
Guyon canal is visualized at this level with ulnar nerve (straight white arrow)
between pisiform and ulnar artery (dashed arrow) and its paired veins. Flexor carpi
ulnaris tendon (curved black arrow) and flexor carpi radialis tendon (curved white
arrow) are visualized.

Axial proton density MR image at level of distal carpal tunnel shows
flexor retinaculum (straight black arrow) extending between hook of
hamate (H) and trapezium (Tm). Median nerve is mildly flattened
(round-tailed arrow). Ulnar nerve (straight white arrow) lies adjacent
to tip of hook of hamate, with adjacent ulnar artery (dashed arrow)
and veins. Flexor carpi radialis tendon (curved arrow) is visualized.

Ulnar Nerve Pathology
Segmental level: C7 to T1 Cords: Medial
Pathways:
 Arm: Travels medial to median nerve and brachial artery approximately halfway down and
descending posteriorly.
 Elbow: Crosses the elbow posteriorly between the medial epicondyle and olecranon.
 Forearm: In upper forearm it passes through and innervates the two heads of the flexor
carpi ulnaris and flexor digitorum profundus of the fourth and fifth fingers. It continues on
a straight course down the forearm.
 Wrist: The nerve becomes superficial and travels with the ulnar artery. Proximal to the
pisiform it gives off a palmar cutaneous branch, which innervates the ulnar proximal palm.
It also gives off a dorsal cutaneous branch, which innervates the ulnar half of the dorsum
of the hand and half of the fourth and all of the fifth digits.
 The ulnar nerve proper passes through Guyon’s Tunnel giving off superficial terminal
cutaneous branches to V and half of IV digit, and a deep motor branch to hypothenar
muscles, interossei muscles, and lumbricals IV and V, adductor pollicis and the deep head
of the flexor pollicis brevis.

29-year-old man with Guyon canal syndrome. Axial proton density
image shows multilobulated ganglion cyst (white arrows) within
Guyon canal compressing ulnar nerve (black arrow) against pisiform.

Ulnar Nerve

ULNAR NERVE PATHOLGY
Common sites of injury:
A. Fractures to the medial epicondyle and olecranon, or osteophyte formations.
B. Cubital tunnel entrapment is the second most common form of entrapment
neuropathy of the upper limb. The nerve passes through a fibrous tunnel where it may
become entrapped. During elbow flexion the nerve will elongate proximally but not
distally to the tunnel. The length of the cubital tunnel retinaculum will also increase by
an average of 45 percent from full elbow extension to full flexion. Other etiologies of
cubital tunnel syndrome include osteoarthritis of the elbow joint, isolated cubitus valgus
deformity, isolated cubitus varus deformity, rheumatoid arthritis and trauma to the
cubital tunnel.
 The nerve itself will also enlarge in this region adding to the compression through this
tunnel. Enlargement can start 15-19 millimeters proximal to the distal humerus extending
distally for 10-12 millimeters. Other compression sites at the elbow include a “snapping”
separate medial head of triceps, a prominent medial head of triceps covering the ulnar
nerve, anconeus epitrochlear, and the ligament of Struthers have been implicated.
 Ulnar neuropathies may occur in conjunction with medial epicondylitis. Other than
positive tests for tendonitis of the common flexor tendon, the most provocative test for
the nerve in this case is resisted pronation of the forearm with resisted flexion of the wrist
being slightly less sensitive.
 C. Compression sites: Cubital Tunnel of Guyon.

ULNAR NERVE
 Mechanism for ulnar nerve entrapment at the elbow.
 Elbow flexion decreases available space for ulnar nerve in cubital tunnel. Causes
compression by aponeurosis that bridges the two heads of flexor carpi ulnaris
muscle.
 Posterior interosseous nerve (one of main branches of the musculospiral)
Passes through substance of supinator brevis.
 Liable to become pinched by unusual action of the muscular fibers.
 Passes through the two heads of the supinator, in the arcade of Froshe, a fibrous
arch occurring in 30 percent of the population.

ULNAR/MEDIAN NERVE
SENSORY DISTRIBUTION

ULNAR NERVE PATHOLGY
*Symptoms include pain and paresthesia in the ulnar distribution of the hand. Atrophy of the
hypothenar may be present.
*Distal lesion results in an inability to perform thumb lateral pinch against resistance
secondary to loss of adductor pollicis.
*Lack of interossei function and lumbrical function of IV and V results in decreased grip
strength, inability to fully extend the fingers (IV and V) for picking up objects resulting in a
‘claw hand’, inability to fully flex the fingers into cylindrical or spherical grip limiting grip
function to a hook-like grasp, and loss of protective and discriminatory sensibility in ulnar half
of hand.
* The “claw hand” deformity is caused by weakness of the
 Lumbricals, interossei, and flexor digitorum profundus muscles with unopposed action of
the finger extensors (radial nerve) and flexor digitorum superficialis (median nerve) all
leading to hyperextension of the 4th and 5th digits at the MCP joints with flexion of the
interphalangeal joints.
 Proximal lesion: additional loss of grip secondary to loss of profundus to IV and V and
decreased flexor power secondary to flexor carpi ulnaris.

Ulnar Nerve Entrapment
 Ulnar nerve compression at the elbow is the second most common nerve
entrapment of the upper extremity, after carpal tunnel syndrome
 Flexion of the elbow causes increased tensile load on the ulnar nerve as well as
increasing the pressure within the cubital tunnel up to 20 times the pressure at
rest

 People with recurrent anterior dislocation of the ulnar nerve. This abnormal
nerve translation has been reported in 16% to 20% of asymptomatic people.
 Risk factors for ulnar nerve dis- location include cubitus varus deformity, an
absent or lax ligament of Osborne, a hyper- trophic medial head of the triceps, or
an accessory head of the triceps
 Compression of the ulnar nerve may occur at four different locations along its
course at the elbow from proximal to distal: 1) the intermuscular septum due to
the arcade of Struthers; 2) at the medial epicondyle at the entrance to the
cubital tunnel; 3) within the cubital tunnel; 4) at the flexor-pronator aponeurosis
between the heads of the flexor carpi ulnaris as the nerve enters the forearm

Fig. 1—Axial proton density MR image through cubital tunnel shows
olecranon process (OP), joint capsule, and posterior bundle of medial
collateral ligament (round-tailed arrow), medial epicondyle (ME), and
ligament of Osborne (straight black arrows). Ulnar nerve (white arrow)
is surrounded by fat.

30-year-old man with cubital tunnel syndrome.
A, Axial proton density MR image shows ulnar nerve
(round-tailed arrow) compressed against medial
epicondyle (ME) by anconeus epitrochlearis (straight
arrow).

Sagittal proton density MR image shows ulnar nerve
(arrow) compressed against medial epicondyle (ME) by
anconeus epitrochlearis (AE)

RADIAL NERVE
 Segmental level: C5-T1
Cord level: Major derivative of posterior cord Pathways:
 Arm: Passes through the axilla and innervates the triceps at the lower border of the axilla.
It continues posterior to the humerus via the spiral groove to the radial border of the
humerus.
 Elbow: Approximately 10-12 centimeters proximal to the lateral epicondyle it pierces the
intermuscular septum to come into the anterior flexor compartment of the humerus. It
lies between the brachialis and the extensor muscles of the lateral epicondyle. It
innervates the muscles of the elbow and divides into a superficial radial sensory branch
and deep posterior interosseous motor branch.
 The posterior interosseous nerve immediately innervates the ECRB and passes through
“Arcade of Frohse” in the supinator muscle. It then extends dorsally down the
interosseous membrane. The nerve must also pass through the “supinator tunnel or canal
which is formed by the two heads of the supinator muscle.
The posterior interosseus nerve travels down the radial aspect of the forearm posteriorly
becoming superficial in the distal half of the forearm and terminating there.

RADIAL and POSTERIOR
INTEROSSEUS NERVE
 Nerve compression of the radial/posterior interossesous nerve is caused by both
intrinsic and extrinsic factors. In addition to the factors listed below,
compression can be caused from tumors, septic arthritis in the elbow, synovitis
secondary to rheumatoid arthritis, lipomas, hemangiomas, ganglion cysts, and
other masses. Also, a tardy palsy may occur secondary to compression by a
callus in a healing fracture at any of the locations.
 The close proximity of the radial/posterior interosseous nerve to bony, muscular,
tendinous, and arterial structures put it at risk for entrapment. There are several
regions where compression of the radial/posterior interosseous nerve occurs – in
the axillary/proximal region, at the elbow, and very rarely at the wrist

 Compression can be caused from tumors, septic arthritis in the elbow, synovitis
secondary to rheumatoid arthritis, lipomas, hemangiomas, ganglion cysts, and
other masses. Also, a tardy palsy may occur secondary to compression by a
callus in a healing fracture at any of the locations.

RADIAL NERVE
High radial nerve (Above elbow) compression sites and syndromes:
 Close proximity of the radial nerve to the radial groove of the humerus puts the
nerve at risk for compression against the bone, being severed secondary to a
fracture, or, compressed by either orthopedic plates to repair a fracture or by a
callus during bone healing
 Close proximity of the radial nerve to the medial and lateral head of the triceps,
or a fibrous origin of the lateral head of the triceps leading to injury during
strenuous activity

 Compression secondary to axillary crutches
 Secondary to “windmill” pitching in competitive softball
 “Saturday Night Palsy” – arm draped over a chair or hard surface as patient is
asleep or intoxicated, “Honeymooners Palsy”- caused by one honeymooner
resting on the other’s arm
 External compression and trauma most common cause of problems in this region
At the elbow

RADIAL NERVE
 Entrapment by fibrous bands around the anterior margin of the radial head
 Entrapment by the “Leash of Henry”- vessels from the radial recurrent artery
 Entrapment by the tendinous edge of Extensor Carpi Radialis Brevis
 Entrapment at the Arcade of Frohse (proximal entrance of the posterior interosseous
nerve into the supinator muscle)-this structure is soft in childhood and can become
fibrous in adulthood with fibrous occurrence ranging from 30-50% in cadaver studies but
present in 80% of patients who undergo radial nerve decompression at the elbow
 Entrapment at the distal entrance of the posterior interosseous nerve from the supinator
muscle

 Compression secondary to elbow synovitis in patients with rheumatoid arthritis
 Compression secondary to Monteggia fracture (fracture of proximal ulna in combination
with posterior dislocation of the radial head)
 Radial nerve compression often coexists with compression syndromes of other nerves or
with other conditions such as lateral epicondylitis

33-year-old woman with radial tunnel syndrome. Sagittal
proton density MR image shows mass (white arrow)
displacing radial nerve (black arrows).

47-year-old man with posterior interosseous nerve syndrome. Axial
fat-suppressed T2-weighted MR image shows denervation edema in
posterior aspect of supinator muscle (S), extensor digitorum
communis muscle (straight arrow), and extensor carpi radialis brevis
muscle (round-tailed arrow).

DERMATOMES of the FOREARM
and HAND

Pathologies/Injuries of the Elbow
 Traumatic Arthritis
 Injury of any severity, may lead to capsular pattern. . Flexion limited, extension markedly
limited, and painful. Rotation - full R.O.M., painless or painful rotation which Indicates
head of radius chipped or cracked.
 Complications: May lead to myositis ossificans.

 Osteoarthritis
 Insidious onset in late middle-age. The cartilage of the lateral compartment of the elbow
(humero-radial) is preferentially affected as compared with that of the medial
compartment

 Follows fracture involving an articular surface.
 Aching after considerable exertion and loss of full extension.

Radial Head fracture

Fracture at the Elbow
 Head of Radius.
One of the most common fractures of upper limb in young adults.
Cause: fall on outstretched hand. Force transmitted axially along the shaft of
radius.
 Clinical-cartilage covering articular surface often badly bruised often at the
capitellum.
 This leads to joint stiffness, elbow does not tolerate manipulation or forced
passive movements. b. Osteoarthritis may be delayed by excision of radial head.

 Fracture of Coronoid process.
Seldom fractured except in association with posterior dislocation of elbow.
Marked displacement presented by strong aponeurotic fibers that invest the
bone.
 Fracture of upper end of ulna with dislocation of head of radius. (Monteggia
Fracture dislocation)

 Fall with forced pronation of forearm or direct blow on back of upper forearm.
Displacement - ulna angled forwards, head radius dislocated forwards.

Capitulum Fracture

Monteggia Fracture-Dislocation

Fractures of the Elbow
 Fracture of Olecranon process.
Cause: fall on point of the elbow, usually in an adult.
Clinical: fracture line nearly always enters joint near middle of trochlear notch.
Complications.
Non-union - extension weakened.
Osteoarthritis - unlikely to become severe unless used for heavy work.
 Fracture of upper end of ulna with dislocation of head of radius.
(Monteggia Fracture dislocation)

 1. Cause: fall with forced pronation of forearm or direct blow on back of upper
forearm.
2. Displacement - ulna angled forwards, head of radius dislocated forwards.
 Often requires surgical repair ORIF with immobilization 4-6 weeks
 4-6 weeks immobilization in non-displaced without surgical stabilization

Monteggia with proximal fracture

Elbow Dislocation

Elbow dislocations
 Elbow dislocations are the most common major joint dislocation second to
the shoulder
 Most common dislocated joint in children and account for 10-25% of injuries
to the elbow

 Posterolateral is the most common type of dislocation (80%)
 Predominantly affects patients between age 10-20 years old
 Mechanism for posterolateral dislocation

 Usually a combination of axial loading, supination/external rotation of the
forearm, andvalgus posterolateral force
 A varus posteromedial mechanism (combined with axial load and forearm
external rotation) has also been reported
 Posterior dislocations may involve more than one injury mechanism

Ellbow Dislocation
 Often associated with full or near full capsuloligamentous disruption/tears
 Progression will often be from lateral to medial with the LCL failing first and may
result in avulsion of the the lateral epicondyle
 Followed by the MCL depending on the forces that are generated
 Elbow dislocation with no associated fracture
 Accounts for 50-60% of elbow dislocations
 Elbow dislocation associated with a LUCL tear, radial head fracture, and coronoid tip
fracture
Radial head fractures occur in up to 10-15% of elbow dislocations
Radial head dislocation often Annular ligament tear
Varus posteromedial rotatory instability
Elbow dislocation injury associated with an LCL tear and a coronoid fracture
(Terrible triad)
 Coronoid fracture characterisitics
medial facet fracture
comminuted

 Assessment
 Status of the skin - evaluate for open injuries
 Presence of compartment syndrome
 Neurovascular (Motor and sensory or vascular compromise)
 Wrist and shoulder cleared
 Concomitant injuries occur in 10-15% of elbow dislocations

 Closed reduction with splinting
 ensure patient has sufficient analgesia to allow for adequate muscle
relaxation

 reduction maneuver requires a combination of:
 Inline traction to improve coronal displacement
 Forearm supination to shift the coronoid under the trochlea
 Elbow flexion while placing direct pressure on tip of olecranon
 a palpable "clunk" can be appreciated after most reductions

Elbow Dislocations
 Assess post reduction stability
 Elbow is often unstable in extension
 Elbow is often unstable to valgus stress
 Test by stressing elbow with forearm in pronation to lock the lateral side
 place post-reduction posterior mold splint in flexion and appropriate forearm
rotation
 splint in at least 90° of elbow flexion
 if LCL is disrupted - elbow will be more stable in pronation
 if MCL is disrupted - elbow will be more stable in supination
 obtain post-reduction radiographs
 If joint is concentric, immobilize (5-10 days) and start early therapy
 Obtain repeat radiographs at 3-5 days and 10-14 days to confirm reduction

Elbow Dislocations

Initial Rehab
Immobilize for 5-10 days
Immobilization for >3 weeks results in poor final ROM outcomes
Early
Supervised (PT) active and active assist range-of-motion exercises within
stable arc
Extension block brace is used for 3-4 weeks
Proceed with light duty use 2 weeks from injury
Late rehabilitation
Extension block is decreased such that by 6-8 weeks after the injury full
stable extension is achieved
Once Full pain free extension is obtained the progression should begin increasing
both open and closed chained exercises varying loads to assist with return to prior
activity
This should lead to tri-joint movements, and combinations of isometric, concentric,
and eccentric loading
Consider ways to load load ligaments in both flexion and extension in combo with
closed and open chain exercises

Elbow Dislocations
 ORIF of coronoid, radial head, repair of LCL +/- MCL
 Approach depends on the pathology
 Kocher approach (ECU/anconeus)

Used to address the LCL complex, common extensor tendon origin,
coronoid, capitellum, and/or radial head fractures
When approaching joint (ie, for radial head fractures) during deep
dissection, make incision slightly anterior to midline of the radial head to
protect the posterior fibers of the LCL complex
take care with retractor placement to avoid injury to the PIN
 medial approach
used to address the MCL, flexor/pronator mass origin, and/or
comminuted coronoid fractures
identify and protect the ulnar nerve

Coronoid and Radial Head Fractures
 Coronoid Fractures
 ORIF
 rarely needed, as most fractures involve only the coronoid tip (proximal to insertion
of brachialis)
 Typically approached laterally, but can also be addressed via a medial approach,
especially if comminuted
 Radial head Fractures

 ORIF when placing fixation on the proximal radius, one must be aware of the "safe
zone" (a 90° arc in the radial head that does not articulate with the proximal ulna)

 The "safe zone" can be identified by its relationship to Lister's tubercle and the
radial styloid
 Radial head Arthroplasty is indicated if radial head can not be reconstructed
 If radial head is replaced the replacement should be anatomic and restore
normal length/size

 this improves the varus and external rotatory stability of the elbow, but
stability isn't restored until LCL is addressed. Excision of the radial head leads
to varus/external rotatory instability when the LCL function is absent

Complications that Can Occur
 Loss of full elbow extension is the most common problem yo occur after simple
closed elbow dislocation
 Early AROM is essential and even at times progressive splinting is used as
inflammatory process diminishes
 Posterior medial instability (Varus)
 Injury to the LCL with fracture to the anteriomedial facet of the coronoid

 Fixation is needed to prevent future arthrosis and outcomes
 Neurovascular Injuries
 brachial artery injuries (rare) typically associated with open dislocations

 ulnar nerve injury typically results from stretch
 median nerve injury (rate) typically associated with brachial artery injury
 Compartment syndrome

 Recurrent Instability
 Heterotrophic bone

Lateral Epicondylitis/Epicondylopathy
 90 percent of cases pain starts at outer side of elbow when lesion lies at common
extensor tendon.

 Epicondyle is tender.
Referred pain along back of forearm often as far as wrist, dorsum of hand.
Occasionally the ring fingers ache.
Rarely - no pain in forearm.
 Referred pain up from elbow to shoulders.
 Pain aggravated by grasping and lifting or any exertion with extension of wrist.
 Can be constant ache worse at night with stiffness of elbow on waking.
 At moment of initial trauma there is no pain. 2. Days later notices ache in
forearm with certain movements. Worsens after 14 days.
 It is not a tear in tendon that causes pain.

 Symptoms result from painful scar that forms later.

Lateral Epicondylitis
 Tenoperiosteal type.
 a. Injury - no exact parallel exists in body. b. Usual lesion - tear between common
extensor tendon and periosteum of lateral humeral epicondyle.
 c. Tear lies at origin of extensor carpi radialis brevis muscle.
d. Early stage: as tear begins to unite, patient using his hand pulls healing
surfaces apart again.
 Painful scar forms at tenoperiosteal junction with self-perpetuating
inflammation.
 Later stages: lymphocytic infiltration, scattered areas, fine calcification.
Onset is a slow process and demonstrates that a minor tear in tendon is not
itself a source of appreciable pain.
Influence of cervical spine on elbow pain, function and progression to pathological
state

Lateral Epicondylitis
 Radial nerve entrapment distally causing a false positive or lateral elbow pain
and resisted pain compressing nerve further. Secondary muscle guarding and
vasoconstriction from the entrapment, however, can lead to primary tissue
change consistent with true epicondylitis.
 Injection of steroid inhibits mechanism of spontaneous cure.
 Gradual widening of gap between the two edges.
Finally lose apposition - tension of the scar ceases.
 Gap fills with fibrous tissue and heals with permanent lengthening.

Stages of repair:
 Recent injury: effusion of blood, tissue fluids.

 Local hyperemia, round cell infiltration.
 Constant pain, diffuse tenderness.

Lateral Epicondylitis
 Early repair.
 Damaged structures being replaced by vascular repair tissue.
Torn periosteum - laying down new bone.
 Pain only with certain movements. c. Permanent repair.
 Granulation tissue becomes avascular fibrous tissue.
Symptoms present only if repair has formed adhesions limiting motion.
 Complications.
Periositiswheretendontornfrom periosteum.
Myofascitis, fibrositis of muscle. Involuntary muscle spasm occurs in extensor
muscles. Prevents complete elbow extension.
Chronic cases
 Synovia of extended capsule of elbow that lie beneath and adjacent to extensor
muscles becomes affected. Synovial sac may encroach upon the epicondyle. The
lateral part of sac is subject to compression by extensor muscles, and this may
cause inflammatory reaction of synovia resulting in pain.

Lateral Epicondylitis
 Clearing and/or treatment of the C6 cervical segment.
 This may include treating for hypo or hypomobilities based on exam findings
 STM, manipulation, exercises (concentric/eccentric/isometrics)

Normalization of joint motion of elbow complex.


Manipulation, if indicated, of adhesion of extensor digitorum to radiohumeral
joint capsule.

 Mobilization of radial head, if indicated, or mobilization of the radial nerve.
 STM to forearm extensors and triceps due to fascial connections to lateral
compartment
 Therapeutic exercises

 Concentrics to biceps/triceps at wrist without gripping
 Concentric wrist flex/ext without gripping
 Progressing to pain free wrist flex/ext concentric to eccentrics as condition
settles and gripping is painfree

Medial epicondylitis/epicondylopathy
 Defined: lesion of common flexor tendon at medial epicondyle, less common
than tennis elbow. Associated with a poor golf swing (Golfer’s Elbow) and with
poor technique in swimming (Swimmer’s Elbow).
 Much less disabling than tennis elbow.

 Pain at inner side of elbow.
 Full range of painless movement - elbow.
 Resisted movements at elbow painless except

 occasionally with pronation.
Resisted wrist flexion - pain at elbow (elbow extended).

Medial epicondylitis/epicondylopathy
 Clearing and/or treatment of the C5 cervical segment.
 This may include treating for hypo or hypomobilities based on exam findings
 STM, manipulation, exercises (concentric/eccentric/isometrics)

Normalization of joint motion of elbow complex.
 Mobilization of radial head, med/lat glides of the ulna if indicated, or
mobilization of the ulnar nerve

 STM to forearm flexors and biceps
 Therapeutic exercises
 Concentrics to biceps/triceps at wrist without gripping
 Concentric wrist flex/ext without gripping
 Progressing to pain free wrist flex/ext concentric to eccentrics as condition
settles and gripping is pain free

 Triplanar movements for more functuional training

Olecranon Bursitis
 Olecranon bursitis is a condition in which there is an inflammation of the bursa
overlying the olecranon process at the proximal aspect of the ulna
 The superficial location of the bursa, namely between the ulna and the skin is
susceptible to inflammation from a variety of mechanisms, primarily either acute
or repetitive trauma
 Two-thirds of the cases are bursitis without an infection or non-septic
bursitis. Nevertheless this type of bursitis is less common.
 Typically affects men between the ages of 30 and 60 years. Two-thirds of cases
are non-septic and usually occur with trauma or repeated small injuries lead to
bleeding into the bursa or release of inflammatory mediators.
 Can be caused by acute injuries (trauma) during sports activities because they
can include any action that involves direct trauma to the posterior elbow.

Olecranon Bursitis
Signs and Symptoms

 Patients usually remark a focal swelling at the posterior elbow. The swelling is
sometimes painless and is clearly marked off by its appearance as a goose egg
over the olecranon process.
 Pressure, like leaning on the elbow or rubbing against a table while writing with
the ipsilateral hand, are factors which can often exacerbate the pain.

 Chronic recurrent swelling is usually not tender and can be visible and palpable
 A typical symptom of olecranon bursitis is the frequent bumping of the swollen
elbow, because it protrudes further than it usually would.
 The Range of motion (ROM) of the affected elbow is usually normal, but in
severe cases and be limited
 Differential diagnosis would include ruling out RA, Gout, pseudogout, olecranon
fracture, and triceps tendon tear

Olecranon Bursitis
 Manage inflammation early

 Promote AROM and concentric vascular exercises
 Remove aggravating stimulus or factors based on work or sports
 Patient education
 Aspiration if needed which may include injection of methyl prednisone and
lidocaine from a lateral approach

Radial Collateral Ligament
 Injury is often associated with trauma and forceful motion into varus. These
injuries are commonly associated with a fracture or subluxation at the elbow
joint.
 Differential Diagnosis
 Heterotopic Ossification: Considerable loss of passive range of motion without loss of
strength
 Malignancy: Severe progressive pain that is not affected by movement
 Inflammatory Arthritis: Abnormal systemic signs
 Fracture: History of trauma, marked limitations in range of motion and ecchymosis,
with pain
 Dislocation: Exaggerated boney prominence, effusion, or appearance of elongation of
forearm and could affect neurovascular status.
 Infection: Sudden swelling without trauma
 Vascular Compromise: numbness, tingling, pulse abnormalities
 Cervicogenic
 Referred From Shpoulder

Ulnar Collateral Ligament
 The most common UCL injury is a UCL tear that is usually gradual but may also
happen in a single traumatic event.
 Pain on the inner side of the elbow is the most common symptom of a UCL
injury. A UCL tear may sometimes feel like a “pop” after throwing followed by
intense pain.

 Occurs with Ulnar dislocations posterior from fall posterior onto extended elbow
and with Monteggia fracture.
 Children, particularly baseball pitchers under age 15, may develop UCL tears
from repeated stress. It is important to remember that pain when throwing is not
normal for young children
 The ulnar collateral ligament may also be injured by fall on an outstretched arm.
The UCL may rupture or get pulled off the humerus, chipping a small piece of
bone, resulting in an avulsion fracture. This type of trauma is sometimes
accompanied by elbow dislocation or elbow fracture.

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