Fractures & Dislocations Of The Upper Limb (2) PDF

Summary

This document provides information on fractures and dislocations of the upper limb, focusing on elbow dislocations. It covers different types and mechanisms of injury, treatment approaches, and rehabilitation strategies. It is intended for medical professionals or students studying orthopedics.

Full Transcript

Fractures & Dislocations Of The Upper Limb
(2)

By
Dina Othman Shokri
 Elbow dislocation
Elbow dislocations constitute 10% to 25% of all injuries to the elbow. Among
injuries to the upper extremity, dislocation of the elbow is second only to
dislocation of the shoulder in adults.
Elbow dislocations can be broken up into simple and complex patterns.
Simple dislocations of the elbow are those in which the injury is only
ligamentous without any associated fractures. It can be classified as anterior or
posterior.
Posterior dislocation is by far the most common and is further subdivided by the
direction of the dislocated ulna (posterior, posteromedial, posterolateral, direct
lateral).

X-ray of right elbow dislocated and clinical
appearance
 Posterior elbow dislocation (PED)
Anterior elbow dislocation ,radius occurs when the radius and ulna are
and ulna are driven anterior to forcefully driven posterior to the
humerus. humerus
Complex elbow dislocations are elbow dislocations that include
associated fractures. The most common associated fractures include
the radial head, coronoid process of the ulna, and the olecranon. The
“terrible triad” elbow dislocation commonly mentioned is an elbow
dislocation with injuries to the coronoid process, radial head, and
posterior lateral dislocation of the elbow joint. It may be associated
with nerveovascular injury as ulnar/median neuropraxia, possible
brachial artery Injury. Sometimes elbow dislocation are accompanied
by ulnar collateral ligament tear.
 Mechanism of injury
In children under 10 years, PEDs are the most common type of joint
dislocation. Most commonly due to fall on outstretched hand or
elbow resulting in force to unlock the olecranon from the trochlea.
Posterior dislocation following axial compression, valgus stress, arm
abduction, and forearm supination. Anterior dislocation ensuing
from direct force to the posterior forearm with elbow flexed, it is
rarely occurred.
 TREATMENT

Simple posterior dislocation: Closed reduction under
sedation, fixation in plaster cast or posterior splint with
the elbow at 90 degrees for 2-3 weeks. Active range of
motion exercise should be start early as much as possible.
Complex or unstable elbow dislocation, severe soft tissue
injuries or bony entrapment need open reduction with or
without internal fixation and usually require ulnar
collateral repair.
 Reduction of Posterior Elbow Dislocation

Palm-palm technique: Grasp pt’s hand with
palm to palm and fingers interlocked. Place
examiner’s elbow in patient’s ante cubital fossa,
Distract dislocation by pushing downward on
patient’s distal humerus with examiner’s elbow
Pull posteriorly dislocated elbow back into
anatomic position.
 Rehabilitation considerations

Most agree that extended casting and prolonged immobilization lead to elbow
post-traumatic stiffness and should be avoided. For simple elbow dislocations,
early active ROM is the key to preventing post-traumatic stiffness and obtaining a
favorable result. The elbow is splinted for 5 to 7 days to allow soft tissue rest. Soft
tissue swelling can be controlled with compressive dressings and application of
ice. Beginning at day 5 to 7, a hinged elbow brace from 30 to 90 degrees is applied
and active ROM is initiated. Active ROM requires muscle activation and assists
with elbow stability and compression across the joint. ROM is increased in the
hinged elbow brace 10 to 15 degrees per week.
Up to 2 week the following should be avoided (Passive ROM should be
avoided because it increases swelling and inflammation, Valgus stress to
the elbow should be avoided because it may disrupt healing of the MCL
and lead to instability or recurrent dislocation, avoid abduction and
external rotation). Forced terminal extension should be avoided.
During this time, no strengthening or resistive exercises should be
prescribed because this may place tension on the healing ligamentous
structures. At 6 to 8 weeks, strengthening can begin
Elbow flexion returns first, with full flexion obtained by 6 to 12 weeks.
Extension returns more slowly and may continue to improve for 3 to 5
months.
 Radial Head Fracture

Radial head fractures usually occur as a result of indirect trauma, with most resulting from a
fall on an abducted arm with minimal or moderate flexion of the elbow joint (0-80 degrees).
This results in valgus pronation stress with the radial head forcibly pushed against the
capitalism of the humerus. In practice, the history is often a fall onto an outstretched arm. A
direct blow to the elbow can cause a radial head fracture but is uncommon. May occur in
elbow dislocation, Swelling at lateral aspect. Limited ROM, maximal tenderness over radial
head. Most common complication: 10º to 15º limit to ROM.

X ray for stable radius head fr
FIGURE 14.12 The Mason classification of radial head fractures. Type I—minimally displaced
fractures (2mm of
displacement. Type III—complete articular fractures with severe comminution. Type IV—radial
head fracture associated with an elbow dislocation. (Reproduced with permission from Morrey
BF. The Elbow and its Disorders. Philadelphia: W.B. Saunders Company; 1993.)
 Treatment

Type I- immobilization in plaster cast for 3 weeks
Type II: ORIF and immobilization in plaster cast for 2 weeks
Type III- ORIF or excision of radial head, immobilization in plaster
cast for 2 weeks
Type IV: radial head resection or replacement.
Physical therapy guide
No passive movement should be given to the elbow or radio ulnar
joint for 14 to 21 days at least to decrease liability for myositis
osificans. active and active-assisted ROM exercises start early.
 Forearm bone shaft fracture

Monteggia fracture and Galeazzi fracture-dislocation
 MoNtegia fracture dislocation

It is a fracture of the upper third of the ulna with anterior displacement of
the upper fragment of the ulna and anterior dislocation of the radius. In
short, Monteggia’s fracture is the proximal ulnar fracture with superior
radio-ulnar joint dislocation
It requires ORIF or it will redisplace
 Galeazzi fracture-dislocation
It is a fracture of the distal 1/3rd of the radius with dislocation or
subluxation of the inferior radioulnar joint. It is due to rotational force
causing swelling of the lower forearm; prominent head of ulna; and ulnar
nerve injury. Like Montegia fracture if treated conservatively it will
redisplaye

This fracture appeared in acceptable Fracture redisplaced in POP. This required
position after reduction and POP ORIF
Galeazzi Fracture
Both bone forearm fracture rehabilitation
Phase I: (weeks 0–2)
Patient is placed into a splint and surgical incisions are protected
Sutures or staples are removed at week two.
Elevation of extremity encouraged
Edema control and ROM of fingers
Phase II: (weeks 2–6)
Active and active-assisted ROM of elbow, forearm, and wrist
No repetitive forearm twisting
Phase III: (weeks 6 and beyond)
Lifting and twisting restrictions lifted once union has been Achieved
Work on regaining preoperative motion if not already achieved.
It is crucial to communicate with the treating surgeon regarding When union has
been achieved and when restrictions may be removed or surgeon preference
regarding weight lifting limits despite lack of full union.
 Distal Radial Fractures

Colle’s fracture
Smith fracture
Barton’s fracture= volar and dorsal
Radial Styloid Fracture (Chauffeur Fracture).
 Colle’s fracture

Extra-Articular: The major fracture line runs transversely across the
distal radius, usually about 2 cm proximal to the radiocarpal joint. This
is one of the most common of all fractures. It affects primarily older
people. Women are afflicted more often than men because of the
prevalence of osteoporosis, especially in older women. It results from a
fall on dorsi flexed (extended) wrist, typical deformity: Dinner Fork
The momentum of the body weight causes the distal fragment to
displace radially and rotate in a supinatory direction with respect to
the proximal bone end. The momentum that results in radial
displacement may also cause a sprain of the ulnar collateral ligament
and an avulsion fracture of the ulnar styloid process. Because this
metaphyseal area of bone is typically osteoporotic, the compression
force often results in comminution and impaction of the distal
fragment.
 Complications

Complications of Colles fracture:
Early complications of Colles fracture are
Radial artery injury
Carpal tunnel syndrome
Extensor pollicis longus injury
Late complications of Colles fracture are
Malunion
Joint stiffness
Volkman ischemic contracture
Osteoarthritis
Sudeck's osteodystrophy (CRPS: Complex regional pain syndrome)
Malunion: A Colles' fracture rarely heals without some residual malalignment. The
radius invariably ends up foreshortened such that the radial styloid process no
longer extends beyond the ulnar styloid process. The distal end of the radius also
tends to be angulated and displaced dorsally. The malalignment described above
will result in a permanent loss of full wrist flexion and ulnar deviation. In addition,
there may be some residual mal alignment of the distal fragment toward supination,
resulting in a loss of pronation. The distal fragment may also heal when displaced
radially, but this would have little effect on motion.
 Reflex sympathetic dystrophy syndrome (Sudecks atrophy)
Complex regional pain syndrome (CRPS) is a form of chronic pain that
usually affects an arm or a leg. Complex regional pain syndrome
(CRPS) typically develops after an injury, a surgery, a stroke or a heart
attack. The pain is out of proportion to the severity of the initial injury.
Type 1 complex regional pain syndrome (CRPS 1), formerly known
as reflex sympathetic dystrophy (RSD), it is a clinical syndrome of
variable course and unknown cause characterized by pain, swelling, and
vasomotor dysfunction of an extremity. CRPS 1 may also develop in the
absence of an identifiable precipitating event. the patho-physiology of
RSDS is not well understood. It has been postulated that both peripheral
and central mechanisms may lead to sympathetic dysfunction.
Its clinical symptoms are intense prolonged pain, pitting edema,
tenderness, change skin color with shiny discoloration, vasomotor
dysfunction of the extremity and restricted movements. Treatment of
the patients depends on early recognition, early intervention of
physical therapy besides the anti-inflammatory agents and nerve
blocks.
The physical therapy for CRPS: concentrate on pain and edema control, TENS
,active exercises of upper limb, auto passive exercises to regain the normal range,
weight bearing exercises, and functional activities of upper limb as well
and aquatic therapy, mirror therapy ,desensitization.
Mirror therapy or mirror visual feedback, mirror therapy is where both hands are
placed into a box with a mirror separating the two compartments and, whilst
moving both hands, the patient watches the reflection of the unaffected hand in the
mirror.

Desensitization consist of giving stimuli of different fabrics, different pressures

(light or deep), vibration, tapping, heat or cold.
 Treatment
An undisplaced fracture may be treated with a cast alone. The cast
is applied with the distal fragment in slight palmar flexion and ulnar
deviation which called colles cast.
A fracture with mild angulation and displacement may require
closed reduction.
Significant angulation and deformity may require an open
reduction and internal fixation or external fixation.
 Physical therapy guide
One of the primary focuses in early rehab is to limit pain and the
amount of edema present in the wrist and hand region.

Emphasize motion at the shoulder, elbow, and fingers during all
phases of rehab. The focus in the beginning of rehabilitation is to
mobilize the wrist, which is indicated approximately 7-8 weeks post
fracture. If the fracture is managed using an internal fixation device,
early mobilization can begin approximately 1 week after surgery.
Regain range of motion (ROM) at the wrist with passive ROM and
progressing to active ROM. Active and active assisted wrist
exercises as much as range as possible specially extension and
radial deviation.
In the next phase of rehabilitation to focus on increasing ROM and
beginning strengthening exercises. For surgically treated wrist, the
majority of ROM should be regained between 6 to 8 weeks post-op.
During this phase, progressive stretching can begin to increase
available ROM. The two most common stretches are bringing the
wrist into extension or flexion. If the patient is unable to tolerate a
slow, prolonged stretch, shorter stretches of 10 seconds are
performed for 10 repetitions.
 Smith Fracture

Smith fracture also called reserved colles fracture or a Goyrand fracture. in which
transverse fracture occurs at the lower end of radius 2.5 cm proximal of the articular
surface with anterior displacement of distal fragment of radius (Palmar
displacement). Almost the opposite of Colles’ fracture, Much less common
compared to colles’.Results from a fall on palmer flexed wrist.
Typical deformity: Garden Spade.
Management is the same as in colles EXCEPT we concentrated on regaining of
wrist flexion ROM
Colle’s versus smith’s fr
 Barton’s Fracture Dislocation

It is Intra-Articular distal radius fracture with volar displacement
which looks like smith fracture. There is dorsal type which looks
like Colles’ fracture. Management is by ORIF.

ORIF Volar Barton’s
 Radial Styloid Fracture

Radial Styloid Fracture (Chauffeur Fracture).
Mechanism of injury is compression of the scaphoid against the
styloid.
Treated by Non-displaced: Cast immobilization
Displaced: Surgical fixation