AUTHOR AND EDITOR INFORMATION

Section 1 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

INTRODUCTION

Section 2 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

History of the Procedure

Radial head and neck fractures and dislocations have been treated by closed and open methods. Early attempts at closed treatment with casting resulted in stiffness and loss of function in the elbow. Consequently, treatment has evolved so that only patients with fractures stable enough to allow early motion undergo closed treatment, while essentially all other patients are treated with a form of surgical treatment. Surgical methods have included excision of the fracture fragments, replacement, and internal fixation. Problems with proximal radial migration, especially with excision but also with replacement, and problems with the replacement implants has led to the belief that anatomic reduction and internal fixation is currently the treatment of choice for unstable and displaced radial head and neck fractures and dislocations.

Problem

Radial head fractures and dislocations are traumatic injuries that require adequate treatment to prevent disability from stiffness, deformity, posttraumatic arthritis, nerve damage, or other serious complications. Radial head fractures and dislocations may be isolated just to the radial head (and neck) and the lateral elbow (and proximal forearm), or they may be part of a combined complex fracture injury pattern involving the other structures of the elbow, distal humerus, or forearm and wrist.

Frequency

The radial head is fractured in about 20% of cases of elbow trauma, and about 33% of elbow fractures and dislocations include injury to the radial head and/or neck.

Etiology

Except for the occurrence of congenital radial head dislocations, which are by definition congenital, radial head fractures and dislocations are the result of trauma, usually from a fall on the outstretched arm with the force of impact transmitted up the hand through the wrist and forearm to the radial head, which is forced into the capitellum. Recognizing the congenital radial head dislocation, where the radial head is larger and rounder than expected, is important because operative treatment to reduce a congenital radial head dislocation is not indicated (see Image 1).

Pathophysiology

See Relevant Anatomy, below. The radial head is intra-articular, so anatomic reduction of bone fragments is necessary to minimize the risks of lateral posttraumatic arthritis from mechanical grinding. The intra-articular position also means that soft tissue attachments to the most proximal portion of the bone are limited, so fractured fragments frequently lose their blood supply, resulting in avascular necrosis and potential nonunion. Luckily, the radial head mostly acts as a spacer preventing proximal migration of the radius, and as long as it maintains its structural support, the patient may do well even if the bone dies.

Clinical

History

The patient with radial head fracture-dislocations usually presents with a history of a fall on the outstretched hand. Blunt or penetrating trauma rarely causes radial head injury. The wrist, especially the distal radioulnar joint, may be damaged simultaneously, and the presence of wrist pain, grinding, or swelling should be determined. The presence of bleeding, even with small puncture wounds, should alert the examiner to the possibility of open injury. Neurovascular symptoms of numbness, tingling, or loss of sensation should be identified to rule out nerve or vascular injury. The presence of severe pain should alert the examiner to the possibility of compartment syndrome.

Physical examination

Patients with radial head fractures and dislocations present with localized swelling, tenderness, and decreased motion. The physician needs to carefully examine any wounds to make sure no open fractures are present. Evaluating wounds over the subcutaneous border of the ulna is especially important in fracture-dislocations to avoid missing open fractures. The examiner should also palpate the elbow, especially the radial head, feeling for deformity, and the wrist should be examined, especially feeling for stability of the distal radioulnar joint. All 3 major nerves of the forearm are in danger with elbow fractures and dislocations, so the examiner should also carefully assess neurovascular function for all of the nerves of the forearm and hand. Radial nerve function is especially important to assess with displaced fractures through the neck of the radius. The motor (posterior interosseous) branch provides extension for the fingers and wrist (see Relevant Anatomy, below.).

The examiner must also assess the firmness of all compartments, check for pain with passive stretch, and measure compartment pressures if in doubt to avoid missing compartment syndromes. Elbow stability needs to be assessed even with seemingly nondisplaced radial neck fractures. The elbow is tested with valgus stress at 30° of flexion to determine the competency of the medial collateral ligament.

INDICATIONS

Section 3 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

The goal of treatment of radial head fractures and dislocations, as with all orthopedic injuries, is a successful functional outcome. A successful outcome correlates directly with accuracy of anatomic reduction, restoration of mechanical stability that allows early motion, and attention to the soft tissues. Treatment can be closed, with immediate early motion to prevent stiffness in stable fractures, or it may be open, with surgical reconstruction depending on the fracture type. Specific indications are discussed in Treatment, below.

RELEVANT ANATOMY

Section 4 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

The elbow joint consists of 3 bones and 3 joints. The bones are the distal humerus, proximal ulna, and proximal radius. The ulnotrochlear joint is between the olecranon process of the ulna and the medial condyle of the humerus. This is a constrained joint that allows only flexion/extension. The radiocapitellar joint is between the radial head and the lateral condyle of the humerus. This joint is less constrained and allows both flexion and extension and forearm rotation. Finally, the radioulnar joint is between the radial head and the proximal ulna. This joint is minimally constrained and allows forearm rotation.

The joints are controlled by the ligamentous anatomy of the elbow. The elbow joint (ulnotrochlear joint) is constrained by the medial collateral ligament, which has well-defined anterior, posterior, and transverse bundles. The elbow is also constrained by the lateral collateral ligament, which is poorly defined, and the radial collateral, lateral ulnohumeral, and accessory collateral ligaments provide stability. The radioulnar joint is constrained by the annular ligament.

The neurovascular structures of the elbow are easily damaged in fractures and dislocations of the elbow. The physician needs to be especially aware of the ulnar nerve proximally because it passes behind the medial epicondyle and the posterior interosseous nerve because it wraps around the radial neck and is most likely to be damaged with radial head fractures or dislocations or during surgery to correct these injuries. The median nerve and brachial artery are in danger in the front of the elbow.

CONTRAINDICATIONS

Section 5 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

No contraindications to treatment exist. Contraindications for surgical treatment are listed as indications for nonoperative treatment in Treatment, Medical therapy, below.

WORKUP

Section 6 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

Lab Studies

• No laboratory tests are relevant.
  

Imaging Studies

• Most radial head injuries can be adequately assessed with standard plain radiography of the elbow. Normal radiographic examination findings demonstrate that the radial head is aligned with the capitellum on all views. A dislocation of the radial head can be easily missed if all radiographs are not carefully examined for this relationship. For the normal elbow, a line drawn through the radial head and shaft should always line up with the capitellum, and with a supinated lateral view, lines drawn tangential to the head anteriorly and posteriorly should enclose the capitellum. With a radial head dislocation, these radiographic findings are disrupted. Images 2-3 are examples of an injury that appears to be a simple ulna fracture when only the anteroposterior view is evaluated, but it clearly has a dislocated radial head on the lateral view. As with any fracture assessment, 2 views perpendicular to each other are always required.
• In rare circumstances, CT scanning of the elbow is useful to define fracture patterns.

Diagnostic Procedures

• Most radial head fractures and dislocations are well defined by the findings on clinical examination and imaging studies. If a high index of suspicion exists for an occult fracture, the joint can be aspirated. Fat globules in the fluid imply a fracture. If suspicious wounds are present and an open fracture or dislocation is suspected, the joint can be injected. If fluid comes out the wound, then the wound communicates with the joint.
  

TREATMENT

Section 7 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

Medical therapy

Treatment options for radial head fractures or dislocations include closed reduction with casting or early motion or open reduction with internal fixation, replacement, or resection. Closed reduction and casting often has associated high rates of stiffness, and closed reduction and early motion may still have high rates of nonunion and malunion in comminuted or unstable fractures, resulting in generally poor functional results. Open treatment (including internal fixation, replacement, or excision depending on the fracture) is associated with better long-term function.

The condition of the soft tissues is as important as the condition of the bone in determining the eventual functional outcome (see Image 4). Schatzker's general observation concerning fracture care is especially relevant for elbow injuries, "long term disability following a fracture is almost never the result of damage to the bone. It is the result of damage to the soft tissues and stiffness of neighboring joints" (Schatzker, 1987).

An isolated radial head dislocation is almost always treated with closed reduction and early motion. If closed reduction cannot be achieved, then open reduction is indicated (see Image 5). Congenital radial head dislocations do not require treatment (see Image 1).

For isolated radial head fractures, the Mason classification guides treatment. Nonsurgical treatment of radial head fractures is indicated if minimal displacement, minimal angulation, and minimal head involvement are noted (see Image 6). Early motion with a functional brace is encouraged to minimize elbow stiffness. Adequate follow-up is essential to be sure late displacement is not missed. (If displacement occurs, operative intervention is usually indicated.)

In the Mason classification, the fracture is type I if it is undisplaced, type II if a single fragment is displaced, and type III if it is comminuted. Type I (nondisplaced) is generally treated nonoperatively. Type II may be treated nonoperatively if the displacement is minimal. The rule of threes is used. Nonsurgical treatment can be considered if the fracture involves less than one third of the articular surface, less than 30° of angulation, and if displacement is less than 3 mm. Type III fractures usually require operative intervention but may occasionally be treated closed with early motion if the radial head is not reconstructible. If a mechanical block to motion is present, then nonsurgical treatment cannot be used.

Fracture-dislocations of the radial head can rarely be treated with closed reduction and splinting, but better results are expected in most cases with operative stabilization and early motion.

Patients whose medical condition is too unstable to allow safe surgery when surgery is indicated can also be treated with splinting followed by early motion, but the prognosis is guarded for achieving optimal function.

Surgical therapy

Surgical treatment is indicated for all unstable radial head (and neck) fractures and dislocations. As described above, the rule of threes can be used for determining the need for surgical intervention. Surgery is required if the fracture involves more than 33% of the articular surface, is angulated more than 30°, or is displaced more than 3 mm. A mechanical block to motion always requires open treatment to remove the blocking bone or osteochondral fragment or fragments. Open fractures are also surgical emergencies. They require surgical irrigation and debridement in an operating room with appropriate antibiotics even if the wound is small. At the same time, immediate stabilization of the bone injury is also performed.

Monteggia fracture-dislocations are a special type of radial head injury. Classically, Monteggia fractures are ulna fractures in the proximal one third with associated radial head dislocation. Instead of the radial head dislocation, the radial head or neck may be fractured as an equivalent injury (see Images 2-3 and Images 14-16). Classification is listed in the following table.

Classification of Monteggia fracture-dislocations

The injury pattern is similar to both bone forearm fractures. Monteggia fracture-dislocations are included here because of the importance of not missing either injury. The isolated injuries (radial head dislocation by itself or ulna [nightstick] fracture by itself) are often treated by closed treatment with good results, but the combined injury can almost never be treated by closed methods if good results are expected. Appropriate treatment requires diagnosing both (see Workup, Imaging Studies, above, and Images 2-3).

Floating elbow injures are another special case that can include radial head injury. Floating elbow injuries include associated ipsilateral forearm and humerus fractures. They are severe high-energy injuries. The best outcome almost always requires fixation at both levels. Standard fixation methods for the individual fractures are used (see Image 7). Surgical treatment options include open reduction internal fixation with plates and screws, excision of fragments, or radial head replacement.

Preoperative details

Adequate preoperative planning is essential. If replacement is a possibility based on imaging studies demonstrating excessive comminution with distal radioulnar joint instability, then the surgeon needs to be sure an adequate stock of radial head replacement implants is available. Similarly, a wide range of minifragment plates and screws should be available to accomplish fixation.

Intraoperative details

The radial head is approached posteriorly. The surgeon must be aware of the posterior interosseous nerve, which winds around the neck of the radius and lies directly on the bone. During the approach (and throughout the case), the surgeon should attempt to use indirect reduction techniques preserving soft tissue attachments. Periosteal stripping must be minimized. Narrow retractors are used, and the surgeon must avoid penetration of the interosseous membrane to avoid the complication of synostosis that can cause severe limitation of motion that is difficult or impossible to treat (see Complications, below).

For isolated radial head dislocations, reduction of the head is usually stable and no specific repair is necessary. If unstable, the annular ligament is repaired (if unstable, the surgeon should look for a missed forearm fracture).

Once the fracture is opened, the final decision is made regarding fixation, replacement, or excision. When possible, best results are obtained with anatomic reduction and fixation. As with any surgical fracture treatment, if fixation is chosen, the first step is reduction of the bone fragments. The surgeon reduces and provisionally fixes the intra-articular fragments first and then attaches the construct to the shaft. In some cases, the radial head is removed and assembled on the back table, but if possible, fixing the fracture in place is preferable to preserve the blood supply provided through the remaining soft tissue attachments.

Fixation options include minifragment plates and screws and Herbert screws. Usually 2.7-mm implants are used with interfragmentary lag screw fixation of individual fragments. Bone graft is included if the bone is significantly comminuted or if bone loss is preventing stable fixation. If more than 33% of the cortical circumference is lost, interfragmentary compression becomes impossible. Examples of radial head fracture fixation in an adult are presented in Images 8-9 and in Images 17-19. Images 10-11 show treatment of a radial head fracture in a child. Children require anatomic reduction with the same indications as adults, but additionally, the surgeon must be aware of potential growth plate injury and late deformity.

If repair is not possible, excision of comminuted radial head fragments can be considered. The surgeon must test for valgus instability and, if necessary, repair the medial collateral ligament to restore stability if excision is chosen. If instability persists, replacement with a radial head spacer is the appropriate treatment instead of excision alone (see Images 12-13). The surgeon must also be aware of the Essex-Lopresti lesion (ipsilateral injury to the distal radioulnar joint) and repair or fixate the distal radioulnar joint as necessary.

When radial head excision is chosen, the surgeon must not excise distal to the annular ligament because this results in an unstable proximal radioulnar joint (see Images 14-15). If comminution extends distal to the annular ligament, then replacement with a spacer should be strongly considered. The spacers shown in these figures are silicone. Newer recommended implants use titanium. The silicone implants were easier to place because of their flexibility, but concerns over silicone synovitis, late fragmentation, and loosening led to the development of the metal implants.

For Monteggia fracture-dislocations, best treatment includes open reduction internal fixation of the ulna diaphyseal fracture (see Images 2-3 and Image 7). The ulna fracture is approached and reduced first. The radial head dislocation then usually reduces indirectly and is stable. (More than 90% of radial head dislocations are stable after fixation of the ulna.) If it is stable, then the radial head dislocation is treated closed. An irreducible radial head usually occurs because the diaphyseal ulna fracture has been poorly reduced, and this should be carefully reassessed both radiographically and clinically. If it is unstable or irreducible (and the ulna is anatomic), then open reduction of the joint is required. The annular ligament is repaired during the open reduction.

Failure of the radial head to reduce with the ulna reduction is usually due to interposed annular ligament or, rarely, to interposed radial nerve. Image 16 shows a patient who presented after an unsuccessful attempt at open reduction of both components of the injury. If the radial head or neck is fractured and stable, then the choice of open versus closed treatment can be made as if the radial head injury were isolated, using the indications for open surgery as described above. If the radial head or neck is fractured and unstable, then it is approached and dealt with by open surgery as described above (see Images 14-15 and Images 22-23).

Elbow fracture-dislocations are usually due to more violent trauma and are usually unstable after reduction. They require open reduction and internal fixation. All efforts should be made to salvage the radial head because it is a secondary stabilizer of the elbow. The goal is stable fixation for early motion.

Postoperative details

The wound can usually be closed, or skin grafts may be used for open wounds within 3-5 days.

Follow-up

Rehabilitation with range of motion exercises is begun as soon as the wound is healed, depending on the type of fracture and stability of fixation. The typical time to union is 6-8 weeks. Casting with the elbow in 90° of flexion is rarely needed to maintain the radial head reduction, but if the radial head is unstable, the surgeon needs to search for other causes such as interposed annular ligament or osteochondral fragment or poorly reduced fracture.

COMPLICATIONS

Section 8 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

Early complications of radial head or neck fractures or dislocations include compartment syndrome, neurovascular injury, and infection. Late complications include nonunion, hardware failure, malunion, infection, synostosis, and persistent pain.

Compartment syndrome after isolated radial head fracture is unlikely but could occur with Monteggia fractures, floating elbow injuries, and associated crush injuries to the forearm. Compartment syndromes usually occur in high-energy trauma but can occur with prolonged low-energy injuries and gun shot injuries. Predisposing factors include vascular injury, coagulopathy, and limb compression. Prevent iatrogenic compartment syndrome during surgery by obtaining good hemostasis and not closing the fascia at surgery. Early diagnosis is necessary. The treating physician needs to have a high index of suspicion, remembering the standard signs and symptoms of increased compartment pressure: pain on passive stretch, palpable firmness or tightness of the compartment, altered sensation or paresthesias, pain out of proportion to that expected, pallor, pulselessness, and less than 30 mm Hg difference between compartment pressure and diastolic pressure. All affected compartments should be released.

Neurovascular injury after radial head fracture or dislocation is not common but occurs more often if the fracture is open. Iatrogenic injury is more frequent. The surgeon needs to remember the location of the posterior interosseous nerve as it travels along the neck of the radius. If no recovery occurs, the nerve is usually explored at 3 months.

Infection after radial head fracture can occur either early or late. Treatment requires irrigation and debridement and appropriate antibiotics, usually by IV. If the fracture is healed or the hardware is loose, the hardware should be removed. If the fracture has not healed and the hardware is stable, the hardware is maintained.

Persistent pain after radial head fracture may be due to the hardware, intra-articular cartilage injury and posttraumatic arthritis, adhesions, malalignment, or associated nerve or muscle injuries. Hardware removal may be helpful, but potential complications, including iatrogenic nerve injury when dissecting through scar, may outweigh the benefits. Persistent pain may be due to nonunion. Images 17-19 show a patient who had persistent painful clicking after his radial head fixation, which resolved after hardware removal.

Nonunion and resultant hardware failure after radial head fracture is usually due to poor biomechanics. Poor biology is the result of poor initial fracture characteristics and damage to the soft tissue envelope. An open injury or an extensive surgical reconstruction with periosteal stripping predisposes to slow healing. Poor surgical technique with overaggressive iatrogenic damage to soft tissues contributes. Poor mechanics occurs when the surgeon is unable to obtain a stable construct. (This occurs with too few screws or failure to obtain interfragmentary compression.) Treatment of nonunion requires restoration of normal biomechanics with stable internal fixation or radial head excision or replacement depending on the fracture and wrist and elbow stability.

Stiffness is common after elbow injuries, especially if they have been immobilized. Motion is difficult to recover even with extensive physical therapy, dynamic bracing, manipulation, or open release of adhesions. Avoiding the problem by early motion is preferable to trying to deal with it after contracture has already occurred.

Synostosis after radial head fracture or dislocation can be a disabling complication because it limits motion, especially rotation of the forearm. Risks include closed head injury, surgical delay longer than 2 weeks, and penetration of the interosseous membrane by bone graft or screws, bone fragments, or surgical instruments. Treatment by resection with an interposition spacer restores motion in about 50% of patients. Generally, the surgeon should wait at least a year or until the bone is metabolically inactive on bone scanning. Surgery should generally be completed before 3 years. Image 16 shows an example of a patient who developed synostosis. Image 20 shows the synostosis. The synostosis was resected, and an interposition fat spacer was used with early motion. Significantly increased motion was obtained and maintained (see Image 21).

OUTCOME AND PROGNOSIS

Section 9 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

For a good result in radial head and neck fractures and dislocations, achieve the following:

• Mechanical stability with anatomic reduction and stable internal fixation
• Optimal biology of healing with anatomic reduction, indirect techniques, and maintenance of soft tissue attachments

FUTURE AND CONTROVERSIES

Section 10 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

The treatment of radial head fractures and dislocations is relatively uncontroversial. Less prominent implants are being devised to decrease problems from hardware. Fixed angled locking screw plates are gaining a role, especially when interfragmentary compression cannot be adequately achieved. While internal fixation that fixes the whole head is currently the treatment of choice, partial internal fixation (where the head cannot be fully reconstructed) may have worse results in terms of elbow function than excision or replacement but might have better results in terms of distal radioulnar function. The specific indications for replacement or excision versus internal fixation continue to be studied.

MULTIMEDIA

Section 11 of 12  

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

Media file 1:  Congenital radial head dislocation.
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Media file 2:  The radial head must be aligned with the capitellum on all views. Simple ulna fracture on anteroposterior view; radial head appears in place but see Image 3.
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Media file 3:  The radial head must be aligned with the capitellum on all views. Dislocated radial head is observed on the lateral radiograph.
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Media file 4:  Soft tissue injury. Soft tissues are as important as bone in determining functional outcome.
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Media file 5:  Isolated radial head dislocation is almost always treated closed.
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Media file 6:  Minimally displaced radial head/neck fractures can be treated with early motion.
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Media file 7:  Floating elbow. Combined Monteggia fracture with dislocation and supracondylar humerus fractures. Treatment of a floating elbow requires fixation of both fractures.
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Media file 8:  Displaced radial head fracture.
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Media file 9:  Radial head fracture fixation.
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Media file 10:  Radial head fracture in a child.
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Media file 11:  Radial head fracture in a child.
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Media file 12:  Radial head replacement, Monteggia variant and the radial head could not be salvaged.
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Media file 13:  Radial head replacement, temporary spacer.
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Media file 14:  Radial head excessive excision. Do not excise distal to the annular ligament because the forearm becomes unstable.
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Media file 15:  Radial head replacement, salvage with radial head spacer.
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Media file 16:  Unsuccessful open reduction of Monteggia fracture-dislocation.
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Media file 17:  Displaced radial head fracture.
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Media file 18:  Fixation with hardware pain.
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Media file 19:  Same patient as in Image 18. Pain was resolved after hardware removal.
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Media file 20:  Synostosis after Monteggia fracture-dislocation, see Image 21.
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Media file 21:  Improved motion after synostosis resection, see Image 20.
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Media file 22:  Monteggia variant with radial head fracture.
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Media file 23:  Fixation of both radial head and ulna.
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REFERENCES

Section 12 of 12

• Authors and Editors
• Introduction
• Indications
• RELEVANT ANATOMY
• Contraindications
• Workup
• Treatment
• Complications
• Outcome And Prognosis
• Future And Controversies
• Multimedia
• References

• Boyer MI, Galatz LM, Borrelli J, et al. Intra-articular fractures of the upper extremity: new concepts in surgical treatment. Instr Course Lect. 2003;52:591-605. [Medline].
• Harrington IJ, Sekyi-Otu A, Barrington TW, et al. The functional outcome with metallic radial head implants in the treatment of unstable elbow fractures: a long-term review. J Trauma. Jan 2001;50(1):46-52. [Medline].
• Ikeda M, Yamashina Y, Kamimoto M, Oka Y. Open reduction and internal fixation of comminuted fractures of the radial head using low-profile mini-plates. J Bone Joint Surg Br. Sep 2003;85(7):1040-4. [Medline].
• Judet T. The importance of rotational seating of radial head prostheses in achieving valgus stability of the elbow. J Bone Joint Surg Am. Nov 2002;84-A(11):2102; author reply 2102. [Medline].
• Judet T. Results of acute excision of the radial head in elbow radial head fracture-dislocations. J Orthop Trauma. May 2001;15(4):308-9. [Medline].
• Liow RY, Cregan A, Nanda R, Montgomery RJ. Early mobilisation for minimally displaced radial head fractures is desirable. A prospective randomised study of two protocols. Injury. Nov 2002;33(9):801-6. [Medline].
• Malmvik J, Herbertsson P, Josefsson PO, et al. Fracture of the radial head and neck of Mason types II and III during growth: a 14-25 year follow-up. J Pediatr Orthop B. Jan 2003;12(1):63-8. [Medline].
• Moro JK, Werier J, MacDermid JC, et al. Arthroplasty with a metal radial head for unreconstructible fractures of the radial head. J Bone Joint Surg Am. Aug 2001;83-A(8):1201-11. [Medline].
• O''Driscoll SW, Jupiter JB, Cohen MS, et al. Difficult elbow fractures: pearls and pitfalls. Instr Course Lect. 2003;52:113-34. [Medline].
• Rabin SI, Rabin SL. Indications for radial head replacement following elbow trauma. Medscape Orthopaedics and Sports Medicine eJournal [serial online]. September 1997;1(5). Available at: http://www.medscape.com.
• Ring D, Quintero J, Jupiter JB. Open reduction and internal fixation of fractures of the radial head. J Bone Joint Surg Am. Oct 2002;84-A(10):1811-5. [Medline].
• Ring D, Jupiter JB, Zilberfarb J. Posterior dislocation of the elbow with fractures of the radial head and coronoid. J Bone Joint Surg Am. Apr 2002;84-A(4):547-51. [Medline].
• Sanchez-Sotelo J, Romanillos O, Garay EG. Results of acute excision of the radial head in elbow radial head fracture-dislocations. J Orthop Trauma. Jun-Jul 2000;14(5):354-8. [Medline].
• Schatzker J. The Rationale of Operative Fracture Care. New York, NY:. Springer Verlag;1987.
• Stabile KJ, Pfaeffle HJ, Tomaino MM. The Essex-Lopresti fracture-dislocation factors in early management and salvage alternatives. Hand Clin. Feb 2002;18(1):195-204. [Medline].

Article Last Updated: Oct 14, 2005