1. Scapula Fractures �Thomas P. Goss, MD�Robert V. Cantu, MD�University of Massachusetts Medical Center��Scapulothoracic Dissociation� Andrew H. Schmidt, MD��Created March 2004
2. Outline� 1. Incidence and Mechanisms
2. Diagnosis and Nonoperative Treatment
3. Fractures of the Glenoid Process
4. Isolated Fractures of the Coracoid Process
3. Outline Continued 5. Isolated Fractures of the Acromial Process
6. Double Disruptions of the Superior Shoulder Suspensory Complex
7. Scapulothoracic Dissociation
8. Complications
4. Incidence of Scapula Fractures
1% of all fractures
3% of injuries to shoulder girdle
5% of shoulder fractures
5. Location of Scapula Fractures
6. Diagnosis History typically high energy injury (80-95% incidence other injury)
Mechanism often direct but can be indirect
Diagnosis ultimately radiographic
7. Radiographs “Scapula trauma series”: AP and Lat of scapula, true glenohumeral axillary view
CT scanning for complex injuries with 3D reconstructions
Stress AP projection if injury to the clavicular-scapular linkage suspected
8. Nonoperative Treatment >90% scapular fractures minimally displaced
Treatment in sling and swathe with gradual increase of functional use for first 6 weeks
x-rays at 2 week intervals until 6 weeks
9. Nonoperative Tx Continued At 6 weeks osseous union usually present and sling/swathe discontinued
Full recovery may take 6 months to 1 year
10. Operative Indications 1. Significantly displaced (5-10mm) fractures of glenoid cavity (rim and fossa)
2. Significantly displaced (10mm or 40 degrees rotation) fractures of the glenoid neck
3. Double Disruptions of the superior suspensory shoulder complex with displacement of one or more elements
11. Glenoid Process
Glenoid process includes glenoid cavity (rim and fossa) and glenoid neck
12. Fractures of the Glenoid Cavity (Rim and Fossa)
10% of scapula fractures of which no more than 10% are significantly displaced
13. Classification Glenoid Cavity Fractures Ia= anterior rim fracture
Ib=posterior rim fracture
14. Classification Glenoid Cavity Fractures II= fracture line through glenoid fossa exiting at lateral border of scapula
15. Classification Glenoid Cavity Fractures III= fracture line through glenoid fossa exiting at superior border of the scapula
16. Classification Glenoid Cavity Fractures IV= fracture line through glenoid fossa exiting at the medial border of the scapula
17. Classification Glenoid Cavity Fractures Va= combination types II and IV
Vb= combination types III and IV
Vc= combination types II,III, and IV
18. Classification Glenoid Cavity Fractures
VI= comminuted fracture
19. Glenoid Rim Fractures Instability anticipated if fracture displaced 10mm and involves one fourth anterior aspect or one third posterior aspect glenoid cavity
Fractures of anterior rim approached anteriorly and posterior rim posteriorly
20. Fractures of the Glenoid Fossa Surgery if articular step-off 5-10mm or displacement causes subluxation humeral head out of glenoid cavity
All glenoid fossa fractures approached posteriorly
21. Glenoid Neck Fractures 25% of scapula fractures of which 10% or less are significantly displaced
Mechanism can be direct blow, fall on outstretched arm, or fall on superior aspect shoulder
22. Classification Glenoid Neck Fractures Type I: non and minimally displaced (<10mm)
Type II: translational displacement 1cm or more or angulatory displacement 40 degrees or more
23. Glenoid Neck Fractures Continued Surgery for type II fractures
Posterior approach between infraspinatus and teres minor
Fixation with 3.5mm recon plate, and possibly k-wires or interfragmentary screws
24. Isolated Fractures of the Coracoid Process Fracture can be at base of coracoid, between CA and CC ligaments, or at tip (avulsion)
Diagnosis often on plain films but CT scan may be needed to better define fracture
Fractures at tip of coracoid typically treated non-operatively (athletes and manual laborers may be exceptions)
25. Coracoid Fractures Con’t Surgical options include ORIF (cannulated 3.5 or 4.0mm screw) or excision fragment and suture fixation conjoined tendon to remaining coracoid process
Fractures between CA and CC ligaments can often be treated non-operatively unless high physical demand patient
Fractures at base coracoid generally minimally displaced and treated non-operatively. Fibrous union may occur but rarely source discomfort
26. Isolated Fractures of the Acromial Process Scapula series detects most acromial fractures
Os acromionale may complicate evaluation
Most are nondisplaced or minimally displaced and treated symptomatically
27. Fixation of Acromial Fractures If ORIF undertaken tension band construct for fractures at distal portion and 3.5mm recon plate for more proximal fractures
28. Double Disruptions of the Superior Suspensory Shoulder Complex (SSSC) SSSC is a bone-soft tissue ring at the end of a superior and inferior bone strut
Ring includes glenoid process, coracoid process, CC ligaments, distal clavicle, AC joint, acromial process
Superior strut is middle third clavicle
Inferior strut is lateral scapular body and spine
29. Superior Shoulder Suspensory Complex
30. Double Disruption of SSSC Traumatic disruption 2 or more components SSSC usually secondary to high energy injury and frequently require surgical management
Frequently described as “Floating Shoulder”
Potential long term consequences non-operative treatment include: nonunion, malunion, impingement, altered shoulder mechanics, DJD, neurovascular compromise
31. Floating Shoulder Operative management recommended because of potential instability, displacement of glenoid
Recent series of floating shoulders treated nonoperatively shows good results with conservative care.
32. Nonoperative Management of Ipsilateral Fractures of the Scapula and Clavicle Retrospective review of 20 cases
11 of 20 clavicle fx’s displaced > 10 mm
5 of 20 scapular fx’s displaced > 5 mm
Treated with sling or immobilizer
Evaluated by 3 different shoulder scores, strength compared to uninjured shoulder.
33. Results 1 clavicle nonunion (segmental bone loss at injury)
Strength = to opposite arm in all
Constant score 96, Rowe score 95
17-18 patients excellent results depending on evaluation system
34. Summary - Floating Shoulder Nonoperative treatment sufficient for many of these injuries.
Each component of the injury should be separately evaluated for indications for surgery, but the combination itself does not mandate operative intervention
35. Scapulothoracic Dissociation Traumatic disruption of scapula from posterior chest wall
Neurovascular injury common
36. Scapulothoracic Dissociation�=�Closed Forequarter Amputation
37. Scapulothoracic Dissociation Left scapulothoracic dissociation with brachial artery disruption
38. Scapulothoracic Dissociation Rare, life-threatening injury
First described in 1984 (Oreck, JBJS 66A:758).
Hallmark: Severe neurovascular injury to the upper extremity, associated with lateral displacement of the scapula.
Sometimes associated with obvious fracture or dislocation about the shoulder
Sometimes without obvious bone injury
39. Scapulothoracic Dissociation Caused by Blunt Trauma Review of 4 personal cases and 54 described in the literature
Broad spectrum of injuries:
Neurologic injuries in 94%
Vascular injuries in 88%
Poor Outcome
Flail extremity in 52%
Early amputation in 21%
Death in 10%, 8% due to this injury
40. Musculoskeletal Injuries
41. Brachial Plexus Injury Complete brachial plexopathy: 81%
Partial plexopathy: 13%
None: 6%
42. Neurologic Injury in Scapulothoracic Dissociation If deficit present EMG done at 3 weeks to determine extent and assess recovery if any
Cervical myelography can be performed at 6 weeks
Nerve root avulsions and complete deficits have a poor prognosis
Partial plexus injuries have good prognosis and functional use extremity often regained
43. Vascular Injury Subclavian or axillary artery: 88%
None: 12%
44. Diagnosis Massive swelling of shoulder region
Pulseless arm
Complete or partial neurologic deficit
Lateral displacement of scapula on a non-rotated chest radiograph is diagnostic
45. 37 year old male, found lying on ground, intoxicated.
Paramedics noted broken branches above.
Patient later found to have fallen from 2nd story balcony
47. Chest Radiography
48. CT Scan
49. Arteriogram
50. Classification Type I: Musculoskeletal injury alone
Type IIA: Musculoskeletal injury with vascular disruption
Type IIB: Musculoskeletal injury with neurologic impairment
Type III: Musculoskeletal injury with both neurologic and vascular injury
51. Initial Treatment Patients often polytraumatized
ATLS protocols must be followed.
Angiography of limb.
Vascular repair, with exploration of brachial plexus.
52. Case Example To OR immediately
Revascularization of Left Arm with Goretex graft.
Musculocutaneous nerve avulsion ???
53. What can the orthopedist do? Stabilize associated bone or joint injury
Clavicle fractures are most common.
54. Benefits of Skeletal Stabilization Avoid delayed or nonunion
Stabilize shoulder girdle
Protect vascular and/or neurologic repairs
55. ORIF Clavicle
56. Complications of Revascularization Graft thrombosis
Compartment syndrome
Hyperkalemia
Rhabdomyolysis, myoglobinuria
57. Case Example CPK levels: 9579 IU/L just after admission
Hb: 13.7 @admission to 8.1 4 hrs later
Treated with iv fluids and alkalinization of urine, no renal failure seen.
58. Deep Vein Thrombosis Severe swelling of arm 2 weeks later
DVT L cephalic and brachial veins
59. Later Treatment 3 weeks: EMG
6 weeks: cervical myelography
Shoulder arthrodesis and/or above-elbow amputation may be necessary if the limb is flail.
60. Prognosis Nerve avulsion or complete neurologic deficit: poor
Partial neurologic deficit: good
61. Case Example Cervical myelogram: no root avulsion
EMG 4 months: severe, widespread brachial plexopathy, complete denervation.
Repeat EMG 7 months: no change.
To OR for exploration, neurolysis.
2.5 years, arm remains paralyzed.
62. Limb Salvage If initial exploration of the brachial plexus reveals a severe injury, primary above-elbow amputation should be considered .
If cervical myelography reveals 3 or more pseudomeningoceles, the prognosis is similarly poor.
63. Summary - Scapulothoracic Dissociation Scapulothoracic dissociation may be a life or limb-threatening injury
If revascularization is necessary, try to explore the brachial plexus at the same time - if it is “shredded” amputation may be considered
Orthopedic stabilization of any skeletal injury is warranted - although the outcome remains poor in most cases.
64. Intrathoracic Dislocation of the Scapula
Extremely rare
Inferior angle scapula locked in intercostal space
Chest CT may be needed to confirm diagnosis
65. Intrathoracic Dislocation of the Scapula Continued
Treatment is closed reduction and immobilization with sling and swathe and tape for 2 weeks followed by progressive functional use of shoulder and arm
66. Complications of Scapula Fractures Nonunion (rare)
Malunion more common
DJD glenohumeral joint
Shoulder instability
Glenohumeral pain and dysfunction
Infection, neurovascular injury, loss of fixation
