John T. Capo and Colin Harris
DEFINITION
The first carpometacarpal (CMC) joint comprises the thumb metacarpal base and the trapezium.
The thumb CMC joint is vital to the function of the hand, and injuries can result in pain, weakness, and loss of grip or pinch strength.
Two fracture-dislocation patterns commonly result from trauma to the thumb CMC joint: Bennett and Rolando fractures.
Bennett fractures are intra-articular fractures in which the metacarpal shaft is radially displaced by the pull of the abductor pollicis longus tendon, leaving an intact ulnar fragment at the base of the thumb metacarpal that is held reduced by the strong volar beak ligament (FIG 1A).
Rolando fractures are complex intra-articular fractures involving the base of the thumb metacarpal that often have a T- or Y-type pattern. These fractures are classically described as being three-part; however, the name also applies to more comminuted fracture variants (FIG 1B).8
ANATOMY
Understanding the deforming forces in these fracture-dislocations is important when deciding on treatment options and determining prognosis.
The thumb metacarpal serves as the site of attachment for several tendons, including the abductor pollicis longus (APL) at the proximal base, the adductor pollicis (AP) distally, and the thenar muscles volarly.15
The articular surfaces of the thumb metacarpal base and trapezium resemble reciprocally interlocking saddles and allow motion in many planes.10,15
Joint stability is maintained by five primary ligaments: the anterior-volar (beak), the posterior oblique, the dorsal radial, and the anterior and posterior intermetacarpal ligaments (FIG 2).18
FIG 1 • A. A typical Bennett fracture is a unicondylar fracture of the base of the first metacarpal with the fracture fragment consisting of the volar-ulnar corner of the proximal metacarpal. B. A Rolando fracture is multifragmentary, with the entire articular base of the metacarpal being involved. By definition, no portion of the metacarpal shaft is in continuity with the carpometacarpal joint.
FIG 2 • A,B. Anterior and posterior views of the thumb basal joint stabilizing ligamentous structures. The crucial anterior, volar-oblique (beak) ligament is often attached to the displaced Bennett fragment.
FIG 3 • The three zones found in fractures of the first metacarpal base. The central zone 2 is critical for joint stability and if involved usually requires open reduction and internal fixation.
Buchler et al2 described three zones at the base of the thumb metacarpal (FIG 3):
Zone 2 represents the central portion of the joint that is normally loaded.
Zone 1 includes the volar aspect of the joint.
Zone 3 involves the dorsal aspect of the joint.
The trapezium has several important adjacent articulations. These include the first metacarpal base, the radial aspect of the second metacarpal base, the scaphoid, and the trapezoid (along with the trapezium, these last two make up the STT joint).
PATHOGENESIS
Bennett fractures occur when the partially flexed thumb metacarpal is axially loaded, resulting in a Bennett articular fragment (the volar-ulnar portion of the metacarpal base) and the remainder of the metacarpal that displaces dorsally, proximally, and radially.
Rolando fractures result from a similar injury mechanism and may have a variable degree of comminution at the base of the thumb metacarpal.
In Bennett-type fractures, the thumb metacarpal shaft is displaced dorsally and proximally by the pull of the APL at the metacarpal base, and angulated ulnarly by the AP and the extensor pollicis longus (EPL) tendons, which insert more distally on the digit.15
Rolando-type fractures are subject to the same deforming forces, except that the APL can sometimes displace both the shaft and the dorsal-radial basilar articular fragment.
Due to the deforming forces that act on the fracture fragments, both injury patterns are usually unstable and difficult to reduce and stabilize by closed means.
NATURAL HISTORY
Injuries to the thumb CMC joint are the most common of all thumb fractures.4,8
Nonoperative treatment is generally reserved for nondisplaced fractures. There is a low likelihood of maintaining reduction using closed means in displaced fractures.
Residual subluxation of the metacarpal shaft leads to basal joint incongruity and the potential for developing posttraumatic arthrosis.5 In addition, residual intra-articular step-off greater than 1 mm may predispose to the development of arthrosis, although this has not been found to be true in all studies.5,6,19
PATIENT HISTORY AND PHYSICAL FINDINGS
Most of these fractures occur with direct trauma to the thumb tip, often from a fall or sports-related injury.
The injury is most common in young males, and two thirds occur in the dominant hand.8,15
The history should reveal whether the patient had pre-existing basal joint arthritis, which is common and will affect treatment options and expected results.
Common physical examination findings include tenderness and ecchymosis surrounding the thumb CMC joint, crepitus with attempted motion, instability, and a “shelf” deformity resulting from displacement of the metacarpal shaft dorsally (FIG 4).16
Metacarpal subluxation or dislocation represents an unstable fracture.
Range of motion is decreased and may be associated with crepitus. Adjacent joints may also have arthrosis and decreased range of motion.
It is important to perform a complete neurovascular examination and to search for associated pathology such as wrist ligamentous injuries.
Neurovascular injuries are uncommon but compartment syndrome should be suspected in higher-energy injuries.
Tendon function should be examined, specifically the EPL, flexor pollicis longus (FPL), and extensor pollicis brevis (EPB).
FIG 4 • A typical shelf deformity is depicted in a Bennett fracture. When viewing the thumb from the lateral perspective, the thumb metacarpal shaft can be seen riding dorsally as it displaces from the unstable carpometacarpal joint.
IMAGING AND OTHER DIAGNOSTIC STUDIES
AP, lateral, and oblique images of the hand should be obtained, although the oblique plane of the thumb in relation to the hand may make these images difficult to interpret.
A true AP view of the thumb CMC joint can be obtained with the forearm maximally pronated with the dorsum of the thumb placed on the cassette (FIG 5A).17
A true lateral view, advocated by Billing and Gedda,1 is obtained with the hand pronated 20 degrees and the thumb positioned flat on the cassette. The x-ray beam is tilted 10 degrees from vertical in a distal-to-proximal direction (FIG 5B).
Radiographs of the contralateral, uninjured basal joint are helpful in certain cases as a template for reconstruction.
Computed tomography may be indicated if a significant amount of articular comminution is present or when plain films inadequately demonstrate the pathology.
A traction view may be helpful in Rolando-type fractures in which nonoperative treatment is being considered and tomography is not available (FIG 5C).
Fluoroscopy alone should be used with caution in ensuring anatomic reduction as this has recently been shown to be less accurate than plain x-rays or direct visualization.3
DIFFERENTIAL DIAGNOSIS
Bennett-type fracture
Rolando-type fracture
Basal joint degenerative joint disease
STT joint arthrosis
Thumb CMC joint ligamentous injury
Trapezial body fracture
De Quervain tenosynovitis
NONOPERATIVE MANAGEMENT
Nondisplaced, minimally comminuted fractures may be treated with closed reduction and thumb spica casting, but precise molding of the cast and close observation for fracture displacement are necessary.
In a Bennett fracture, closed treatment may be indicated if there is minimal displacement between the volar ulnar fragment and the metacarpal shaft. Most importantly, a concentric reduction of the metacarpal base in Bennett fractures must be maintained.6
Several factors make closed treatment of these intra-articular fractures problematic and worsen results:
Difficulty in providing accurate three-point molding of the thumb metacarpal
Treatment of patients 4 or more days after the initial injury
Difficulty assessing the adequacy of reduction with radiographs taken through the cast4,9
Some studies looking at closed treatment have demonstrated decreased motion, grip strength, and radiographic evidence of degenerative joint disease at long-term follow-up.14
Development of degenerative changes may occur if there is any residual subluxation of the thumb metacarpal shaft.5,8
SURGICAL MANAGEMENT
The majority of displaced Bennett fractures and almost all Rolando fractures require percutaneous Kirschner wire fixation or open reduction and internal fixation.
The goals of surgery are to restore the articular congruity of the thumb CMC joint and to align the first metacarpal base articular surface with the trapezium.
In thumb CMC joint fractures associated with trapezial body fractures, the trapezial articular surface should first be reduced anatomically before proceeding to the thumb metacarpal fracture.16
Bennett Fractures
Closed reduction and percutaneous pinning is the preferred treatment for most Bennett fractures with displaced fracture fragments representing less than 25% to 30% of the articular surface.16,18
FIG 5 • A. An ideal AP view of the thumb and carpometacarpal joint is taken with the forearm hyperpronated and the dorsum of the thumb on the cassette. B. A true lateral view of the carpometacarpal joint is obtained with the radial aspect of the thumb on the cassette and the other fingers clear of the x-ray beam. C. A fluoroscopic view of a Rolando fracture with traction applied. Distraction at the carpometacarpal joint helps to delineate the fragments at the base of the metacarpal. (Copyright John Capo, MD.)
The metacarpal base often needs to be pinned to the unfractured second metacarpal, trapezoid, or trapezium to lessen the deforming forces on the fracture.
Residual displacement of the joint surface greater than 2 mm after attempted closed reduction and percutaneous pinning or impaction in the force-bearing aspect of the joint surface (Buchler zone 2) necessitates open reduction.15
Rolando Fractures
Closed reduction with longitudinal traction and percutaneous pinning is indicated if successful reduction can be achieved under fluoroscopic guidance; however, this is usually successful only when large T- or Y-type fragments are present.
If the joint cannot be reduced by closed methods, open reduction and internal fixation with a combination of smooth wires, screws, and 1.5- to 2.7-mm L, T, or blade plates is indicated.
Significant comminution may require either external fixation or a combination of external fixation, limited internal fixation with Kirschner wires and small (1.3 or 1.5 mm) screws, and cancellous bone grafting as advocated by Buchler et al.2
An additional option is tension-band wiring with or without external fixation, as described by Howard.11 The external fixator maintains length and alignment, while the tension-band construct provides stability to the fracture fragments.
Preoperative Planning
A thorough history and physical examination are mandatory to choose the appropriate treatment and rule out associated injuries.
True AP, lateral, and oblique radiographs of the thumb should be obtained in all cases. Traction radiographs help assess the effects of ligamentotaxis on fracture reduction.
Surgery may be performed acutely, but if significant soft tissue swelling is present, elevation in a well-padded thumb spica splint for 2 to 5 days may be necessary before undergoing operative fixation.16
Positioning
The patient is placed supine on the operating room table.
A radiolucent hand table is used to allow for intraoperative fluoroscopy.
The patient is moved toward the operative side to center the hand on the table.
A non-sterile tourniquet is placed on the upper arm.
General, regional (axillary or infraclavicular), or local (wrist block with local infiltration) anesthesia can be used, although muscle relaxation is often necessary to obtain proper reduction.16,18
Approach
The Wagner approach can be used for both Bennett and Rolando fractures in which open reduction is necessary.
TECHNIQUES
CLOSED REDUCTION AND PERCUTANEOUS PINNING OF BENNETT AND ROLANDO FRACTURES
Longitudinal traction, abduction, and pronation of the thumb is performed while applying direct manual pressure over the metacarpal base.16
Traction is maintained and the reduction is held while fluoroscopy is used to verify acceptable fracture reduction and alignment of the articular surface (TECH FIG 1A,B).
TECH FIG 1 • A,B. Lateral and PA views of a Bennett fracture with intra-articular displacement. C. The metacarpal base is first reduced to the trapezium and then a pin (0.045) is placed across the carpometacarpal joint. Two additional pins are provisionally placed and readied to stabilize the Bennett fracture fragment. D. The two smaller pins (0.035) are then advanced across into the Bennett fragment. (Copyright John Capo, MD.)
Smooth 0.045-inch Kirschner wires are inserted from the proximal thumb metacarpal shaft into the uninjured index metacarpal base or trapezium. These wires stabilize the concentrically reduced metacarpal shaft and CMC joint (TECH FIG 1C).
The size of the articular Bennett fracture determines whether fixation to this fragment is needed (TECH FIG 1D).
Large fragments may be manipulated percutaneously with Kirschner wire “joysticks” and then stabilized.
The wires are bent and cut outside of the skin, followed by application of a well-padded thumb spica splint with the thumb in abduction and wrist in extension.
If less than 2 mm of step-off cannot be obtained by closed reduction, the surgeon should consider abandoning this technique for an open reduction and internal fixation.16,18
In rare instances, a similar technique can be used for Rolando fractures, with large T- or Y-type fracture patterns with minimal comminution.
OPEN REDUCTION AND INTERNAL FIXATION OF BENNETT FRACTURES
Incision and Dissection
A Wagner approach is used for open reduction of a Bennett fracture (TECH FIG 2A).
An incision is made on the dorsal-radial aspect of the thumb CMC joint, at the junction of the glabrous and nonglabrous skin, and curved in a volar direction toward the distal wrist crease to the flexor carpi radialis (FCR) tendon sheath (TECH FIG 2B).
The palmar cutaneous branch of the median nerve, the superficial radial nerve, and distal branches of the lateral antebrachial cutaneous nerve are at risk in this approach and should be carefully protected (TECH FIG 2C).
The thenar muscles are elevated extraperiosteally from the CMC joint and a longitudinal capsulotomy is made to expose the joint and the fracture fragments.
An effort should be made to preserve all soft tissue attachments to the fracture fragments (TECH FIG 2D). The fracture line is exposed and cleaned of all hematoma and early callus.
This often requires abduction, supination, and dorsal displacement of the metacarpal shaft to expose the volar-ulnar Bennett fragment.
TECH FIG 2 • A. A preoperative radiograph demonstrating a large (~40%) Bennett fracture with intra-articular displacement. B. The typical incision for open reduction and internal fixation of a Bennett or Rolando fracture. The proximal aspect starts at the flexor carpi radialis tendon sheath. In the case of a Rolando fracture, especially one treated by plate fixation, the distal portion of the incision should extend along the thumb metacarpal. C.Distal nerve branches are seen during the exposure of these fractures. The nerves can usually be retracted dorsally to allow exposure of the carpometacarpal joint. D. The thenar muscles are reflected volarly and the carpometacarpal joint is entered. The volar, oblique fracture is now clearly visualized. Care is taken to maintain soft tissue attachments. (Copyright John Capo, MD.)
Reduction and Fixation
The displaced thumb metacarpal shaft should be reduced to the volar-ulnar fragment under direct visualization and secured with fine reduction clamps or Kirschner wires (TECH FIG 3A).
One or two 0.045-inch smooth Kirschner wires are used to provisionally hold the reduction, or in certain fracture patterns they can serve as the definitive means of fixation.
Alternatively, 1.3- to 2.0-mm screws can be placed in an interfragmentary compression fashion for added stability (TECH FIG 3B).7
One Kirschner wire is removed at a time and replaced with a screw.
Generally, the path of the removed Kirschner wire effectively guides the drill in the appropriate direction. Use of a mini-fluoroscopy unit is helpful.
Care should be exercised to avoid overcompression, which may cause an alteration in the arc of curvature of the articular surface.
If fixation is tenuous, the metacarpal base can be pinned to the second metacarpal or to the carpus for added stability.
Anatomic reduction of the articular surface is verified under direct visualization.
The wound is closed in layers with absorbable suture in the capsule, followed by nylon sutures in the skin. A thumb spica splint is applied.
The screws should be precisely evaluated fluoroscopically to be certain they are not in the CMC joint or adjacent second metacarpal base (TECH FIG 3C,D).
TECH FIG 3 • A. The fracture is cleared of hematoma and then reduced with a pointed reduction forceps. A provisional Kirschner wire is placed percutaneously from the dorsal metacarpal shaft into the fragment. B. Two screws of 1.3 mm diameter are placed in a lag fashion from the metacarpal shaft into the fracture fragment. C,D. Lateral and AP postoperative views showing reduction of the fracture and articular surface with two screws inserted in different planes. (Copyright John Capo, MD.)
OPEN REDUCTION AND INTERNAL FIXATION OF ROLANDO FRACTURES
Incision and Dissection
The previously described Wagner approach is used to expose the thumb CMC joint (TECH FIG 4A,B).
The radial portion of the incision is extended distally to expose the diaphysis of the thumb metacarpal. Branches of the radial sensory nerve must be protected at this stage (TECH FIG 4C).
Reduction and Fixation
The basilar-articular fragments are then reduced under direct visualization and provisional fixation is performed with Kirschner wires or bone reduction clamps (TECH FIG 5A).
A lag screw can be placed in a transverse direction by overdrilling the proximal cortex to compress the basilar fragments together, followed by application of a minifragment neutralization plate or by additional Kirschner wires to stabilize the shaft (TECH FIG 5B,C).6,16
If greater fracture stability is desired, a small (1.5 to 2.7 mm) T, L, or blade plate can be used alone.
The palmar radial incision is extended further distally to expose the thumb metacarpal shaft to accommodate the plate.
Reduction is obtained using the above techniques, with axial traction to maintain appropriate length and bone reduction forceps or smooth Kirschner wires to provisionally hold the articular reduction.
Once the fracture fragments are aligned, the plate is secured to the thumb metacarpal, with the transverse portion of the plate placed over the basilar fracture fragments.16
The most palmar and dorsal proximal holes of the T portion of the plate can be drilled eccentrically to allow for compression at the fracture site between the basilar fragments,7,13 followed by fixation of the plate to the metacarpal shaft with cortical screws (TECH FIG 5D,E).
Additionally, a lag screw can be placed between the shaft and the basilar fragment either within or outside of the plate. An appropriate bit is used for overdrilling of the shaft fragment, followed by core drilling of the distal basilar fragment. This interfragmentary screw increases the stability of the construct and may allow for earlier functional range of motion (TECH FIG 5F–I).
The joint surface reduction is visualized directly with distal traction of the thumb and ensured to be anatomic.
The wound is then irrigated and closed in layers, followed by immobilization in a well-padded thumb spica splint.
TECH FIG 4 • A,B. Preoperative radiographs of a Rolando fracture demonstrating severe intra-articular comminution. C. The thumb thenar muscles have been elevated from the carpometacarpal joint and a capsulotomy has been performed. The fracture fragments are identified and cleared of hematoma. (Copyright John Capo, MD.)
TECH FIG 5 • A. The articular surface is first reduced and provisionally stabilized with multiple small Kirschner wires. B,C. Intraoperative fluoroscopic lateral and AP views demonstrate excellent restoration of the joint surface. Kirschner wires have been placed from the thumb metacarpal into the trapezium and second metacarpal to stabilize the construct. D. The two proximal holes of the T plate are drilled offset for articular fragment reduction. E. The two proximal screws are tightened to compress the proximal fragments. F,G. AP and lateral views of a comminuted, displaced Rolando fracture. H,I. Postoperative radiographs demonstrating excellent articular reduction using a 2-mm T plate. (A–C: copyright John Capo, MD; D,E: adapted from Howard F. Fractures of the basal joint of the thumb. Clin Orthop Relat Res 1987;220: 46–51; F–I: courtesy of Dominik Heim, MD.)
APPLICATION OF AN EXTERNAL FIXATOR FOR COMMINUTED ROLANDO FRACTURES
Before this procedure, a radiograph of the contralateral thumb CMC joint is advised for templating and to judge postreduction length.
A mini-external fixator (2.0- to 2.5-mm pins) is applied to the thumb and index metacarpals using standard technique with a quadrilateral frame configuration.2,12
Exposure and open reduction are then performed as discussed previously.
Distraction is maintained using the external fixator, and the depressed joint fragments are elevated and aligned using the preoperative radiograph of the opposite side as a guide.
A sharp dental pick is an excellent tool to manipulate small fragments.
0.045-inch smooth Kirschner wires or interfragmentary screws can then be used to secure the fracture fragments.
The external fixator is loosened to decrease the flexion deformity of the thumb metacarpal shaft, and to ensure the base of the thumb is maintained in the proper position. It should be co-linear with the base of the second metacarpal base.
At the end of the procedure the thumb should be in 45 degrees of palmar and radial abduction and about 120 degrees of pronation in relation to the plane of the hand (TECH FIG 6).
The incision is irrigated and closed in layers.
TECH FIG 6 • A schematic of an external fixator frame used for stabilization of a comminuted Rolando-type fracture. Care should be taken to place the thumb in a functional position with wide palmar and radial abduction.
POSTOPERATIVE CARE
Bennett Fractures
A thumb spica splint is applied in the operating room. Pin sites are inspected at 1 week and a thumb spica cast is applied for 4 to 6 weeks, until fracture union.
Hand therapy is begun early for thumb IP and MP joint motion and index through small finger range of motion.
Pins are removed at 4 to 6 weeks and therapy is advanced to the CMC joint along with intermittent immobilization using a removable thumb spica splint.16
In patients treated with interfragmentary compression screws and therefore more stable fixation, active range-of-motion exercises can by started at 1 to 2 weeks postoperatively with a removable splint for protection.
Rolando Fractures
Patients treated with closed reduction and percutaneous pinning are placed in a thumb spica splint, which is removed at 1 week for pin inspection. A thumb spica cast is applied for an additional 4 to 5 weeks.
The pins are removed in the outpatient office at 6 weeks after surgery. A removable splint may be continued for 2 to 4 additional weeks while active range-of-motion exercises are advanced.16
In patients treated with stable plate fixation, active range-ofmotion exercises may be instituted at 1 to 2 weeks after surgery. Patients typically wear a removable splint for 2 to 4 weeks.
If a severe injury dictated the use of external fixation, the pins and frame should remain in place for about 6 weeks, or until fracture stability is adequate based on interval radiographs. A removable thumb spica splint can then be worn for an additional 4 to 6 weeks.
OUTCOMES
The majority of patients can expect a successful recovery after operative treatment of Bennett or Rolando fractures (FIG 6).
FIG 6 • Clinical photographs of a patient with a Rolando fracture who had undergone open reduction and internal fixation 8 months previously, demonstrating a functional range of flexion (A) and extension (B). (Copyright John Capo, MD.)
Superior results are seen in operatively treated fractures in which there is no residual subluxation of the thumb metacarpal shaft and less than 2 mm of intra-articular displacement.5,15
It is generally agreed that if pain and articular incongruity persist after 6 months of observation after closed or open treatment, arthrodesis of the thumb metacarpal to the trapezium or basal joint arthroplasty may be indicated.
CMC joint fusion is durable, but patients have difficulty with placing their hand on a flat surface and getting the hand into a pants pocket.
Basal joint arthroplasty for acute fractures should be reserved for older, lower-demand patients.
COMPLICATIONS
Malunion and subsequent arthrosis resulting from inadequate articular reduction
Pin tract infection
Injury to the superficial cutaneous nerves during open dissection and percutaneous fixation
Contracture of the first web space from immobilization or pinning of the thumb in an adducted position
REFERENCES
1. Billing L, Gedda K. Roentgen examination of Bennett's fracture. Acta Radiol 1952;38:471–476.
2. Buchler U, McCollam S, Oppikofer C. Comminuted fractures of the basilar joint of the thumb: combined treatment by external fixation, limited internal fixation, and bone grafting. J Hand Surg Am 1991; 16A:556–560.
3. Capo JT, Kinchelow T, Orillaza NS, Rossy W. Accuracy of fluoroscopy in closed reduction and percutaneous fixation of simulated Bennett's fracture. J Hand Surg (Am), 2009;34(4):637-41.
4. Charnley J. The Closed Treatment of Common Fractures, 3rd ed. Edinburgh: Churchill Livingstone, 1974:150.
5. Cannon S, Dowd G, Williams D, Scott J. A long-term study following Bennett's fracture. J Hand Surg Br 1986;11:426–431.
6. Cullen J, Parentis M, Chinchilli V, et al. Simulated Bennett fracture treated with closed reduction and percutaneous pinning: a biomechanical analysis of residual incongruity of the joint. J Bone Joint Surg Am 1997;79:413–420.
7. Foster R, Hastings H. Treatment of Bennett, Rolando, and vertical intra-articular trapezial fractures. Clin Orthop Relat Res 1987;214: 121–129.
8. Gedda K. Studies on Bennett fractures: anatomy, roentgenology, and therapy. Acta Chir Scand Suppl 1954;193:5.
9. Griffiths J. Fractures of the base of the first metacarpal bone. J Bone Joint Surg Br 1964;46B:712–719.
10. Haines R. The mechanism of rotation at the first carpometacarpal joint. J Anat 1944;78:4.
11. Howard F. Fractures of the basal joint of the thumb. Clin Orthop Relat Res 1987;220:46–51.
12. Jobe M, Calandruccio J. The hand: fractures, dislocations, and ligamentous injuries. In Canale T, ed. Campbell's Operative Orthopedics, 10th ed. Philadelphia: Elsevier, 2003:3489.
13. Jupiter J, Axelrod T, Belsky M. Fractures and dislocations of the hand. In Browner B, Jupiter J, Levine A, Trafton P, eds. Skeletal Trauma: Basic Science, Management, and Reconstruction, 3rd ed. Philadelphia: Elsevier, 2003:1196.
14. Livesley J. The conservative management of Bennett's fracturedislocation: a 26-year follow-up. J Bone Joint Surg Br 1990;15B: 291–294.
15. Pellegrini V. Fractures at the base of the thumb. Hand Clin 1988;4: 87–102.
16. Raskin K, Shin S. Surgical treatment of fractures of the thumb metacarpal base: Bennett's and Rolando's fractures. In Strickland J, Graham T, eds. The Hand (Master's Techniques in Orthopaedic Surgery). Philadelphia: Lippincott Williams & Wilkins, 2005:125–135.
17. Roberts P. Bulletins et memoires de la Societe de Radiologie Medicale de France, 1936;24:687.
18. Stern P. Fractures of the metacarpals and phalanges. In Green D, Hotchkiss R, Pederson W, et al, eds. Green's Operative Hand Surgery, 5th ed. Philadelphia: Elsevier, 2005:332–338.
19. Thurston A, Dempsey S. Bennett's fracture: a medium to long-term review. Aust NZ J Surg 1993;63:120–123.