Percutaneous Fixation of Acute Scaphoid Fractures

 

 

 

DEFINITION

Located in the proximal carpal row, the scaphoid serves as an important link between the proximal and distal carpal rows. It is the most commonly fractured carpal bone, accounting for about 1 in every 100,000 emergency room visits.17

Scaphoid fractures typically result from a fall on an outstretched hand or less commonly following forced palmar flexion of the wrist16 or axial loading of the flexed wrist such as in punching.14,26

There are about 345,000 scaphoid fractures annually in the United States.

 

 

ANATOMY

 

The scaphoid has a complex three-dimensional geometry that has been described as a “twisted peanut.”8 Anatomically, the scaphoid is organized into proximal pole, waist, and distal pole regions.

 

Scaphoid dimensions vary between genders; the male scaphoid is usually longer and wider than the females. In addition, the diameter of most commercially available standard screws are larger than the proximal pole of the

female scaphoid.13

 

The scaphoid articulates with the radius, lunate, capitate, trapezium, and trapezoid; thus, its surface is almost completely covered with hyaline cartilage. This feature has several important implications, including articular disruption during wire or screw insertion, paucity of vascular supply, and the absence of periosteum.

 

 

Lacking periosteum, the scaphoid heals almost completely by primary bone healing, resulting in minimal callus and a biomechanically weak early union.23

 

Blood supply comes from branches of the radial artery that enter the scaphoid via two main routes7:

 

 

A dorsal branch, which enters the scaphoid via the dorsal ridge, provides the primary supply and 70% to 80% of the overall vascularity, including the entire proximal pole (via retrograde endosteal branches).

 

A volar branch, which enters through the tubercle, supplies 20% to 30% of the internal vascularity, all in the distal pole.

 

 

The precarious blood supply contributes to the high incidence of nonunion after a fracture at the scaphoid waist or proximal pole. It also places the proximal pole at risk for the development of avascular necrosis.

 

PATHOGENESIS

 

A scaphoid fracture classically occurs in a young, active adult most commonly following a fall onto an outstretched hand.

 

 

Studies have demonstrated that wrist extension of more than 95 degrees combined with more than 10

degrees of radial deviation is required for a scaphoid fracture to occur. In this position, the scaphoid abuts the distal radius, resulting in fracture.

 

The scaphoid can also be fractured following a forced palmar flexion of the wrist injury such as punching an object.14,26

 

Seventy percent to 80% of scaphoid fractures occur at the waist region, whereas 10% to 20% involve the proximal pole and 5% occur at the distal pole and tuberosity.

 

In children, the most common location for a scaphoid fracture is the distal pole.2

 

 

Although rare, scapholunate ligament injuries can occur in association with a scaphoid fracture.15,22,28,31

 

NATURAL HISTORY

 

The true natural history of an untreated scaphoid fracture is unknown due to limitations in the existing literature, particularly with respect to study design.16 However, several retrospective studies have suggested that if a nonunion occurs, a predictable pattern of wrist arthritis develops, usually within 10 years of the injury.19,21

 

Unrecognized, untreated, or inadequately treated scaphoid fractures have an increased likelihood of nonunion and secondary carpal instability.

 

A fracture through the proximal pole has the highest likelihood of nonunion, followed by a fracture of the scaphoid waist.

 

If the scaphoid fracture is unstable, extension forces exerted on the proximal fragment (via the long radiolunate and the radioscaphocapitate ligaments) and flexion forces at the distal fragment result in a flexion (“humpback”) deformity of the scaphoid.

 

 

This deformity and loss of scaphoid support results in carpal instability, most frequently a dorsal intercalated segment instability (DISI) pattern, which eventually leads to arthritis as previously described.

 

 

The overall incidence of nonunion after fracture at the scaphoid waist region is about 5% to 10%.18

 

PATIENT HISTORY AND PHYSICAL FINDINGS

 

A patient with an acute or subacute scaphoid fracture presents with radial-sided wrist pain, swelling, and loss of motion, particularly with dorsiflexion.

 

Classic physical examination findings include the following:

 

 

Edema over the dorsoradial aspect of the wrist

 

 

 

Tenderness to palpation between the first and third dorsal compartments (the “anatomic snuffbox”) Tenderness with palpation volarly over the distal tubercle

 

 

 

Pain with axial compression of the wrist (scaphoid compression test) Acutely, swelling and ecchymosis over the volar radial wrist

 

P.333

IMAGING AND OTHER DIAGNOSTIC STUDIES

 

The following plain radiographs should routinely be ordered in the patient with a suspected scaphoid fracture: posteroanterior (PA), oblique, lateral, and dedicated scaphoid views.

 

 

The PA view allows visualization of the proximal pole of the scaphoid.

 

 

The semipronated oblique view provides the best visualization of the waist and distal pole regions. The semisupinated oblique view provides the best visualization of the dorsal ridge.

 

The lateral view permits an assessment of fracture angulation, carpal alignment, and carpal instability.

 

The dedicated scaphoid view is a PA view with the wrist in ulnar deviation. This results in scaphoid extension, allowing visualization of the scaphoid in profile.

 

Displaced and unstable fractures are defined by the following criteria:

 

 

At least 1 mm of displacement

 

 

More than 10 degrees of angular displacement Fracture comminution

 

 

 

Radiolunate angle of more than 15 degrees Scapholunate angle of more than 60 degrees Intrascaphoid angle of more than 35 degrees

 

Computed tomography (CT) scan is helpful in identifying and characterizing an acute fracture and evaluating for a nonunion. Thin 1-mm cuts are obtained in the sagittal and coronal planes.

 

Magnetic resonance imaging (MRI) is useful for diagnosing an occult fracture and, when combined with gadolinium administration, can be used to assess the vascularity of the proximal pole and the presence of avascular necrosis. Bone bruising without a fracture detected on MRI may eventually be found to be the result

of an occult fracture in 2% of cases.27

 

Technetium bone scan has been shown to be up to 100% sensitive in identifying occult fractures but lacks specificity. It is optimally used 48 hours after injury.

 

DIFFERENTIAL DIAGNOSIS

Scapholunate injury Wrist sprain

Wrist contusion

Fracture of other carpal bones Distal radius fracture

 

 

NONOPERATIVE MANAGEMENT

 

Nonoperative management, specifically cast immobilization, is indicated for a nondisplaced, acute (<4 weeks from injury) fracture of the distal pole. For a nondisplaced, acute waist fracture, there is debate regarding the preferred treatment approach—cast immobilization or surgical stabilization.

 

With cast immobilization, there is no consensus regarding the preferred position of the wrist, the need to immobilize other joints besides the wrist, and the duration of immobilization.4

 

Clinical studies have demonstrated no benefit with thumb immobilization nor any influence of wrist position on the rate of union.

 

Studies have also demonstrated no difference in union rates with use of a long-arm versus short-arm cast;

however, a small randomized prospective study by Gellman et al9 demonstrated a shorter time to union and fewer nonunions and delayed unions with the initial use of a long-arm cast.

 

In general, cast immobilization is required for 6 weeks after a distal pole fracture and 10 to 12 weeks following a nondisplaced waist fracture.

 

 

Confirmation of fracture union requires serial plain radiographs demonstrating progressive obliteration of the fracture line and clear trabeculation across the fracture site.6

 

If there is any question regarding fracture union, particularly if the patient is returning to a contact sport, a CT scan should be obtained.

 

SURGICAL MANAGEMENT

 

Operative treatment is advocated for fractures that are unstable or displaced (see previously mentioned criteria) and following a significant treatment delay.20

 

Percutaneous fixation is indicated for the following:

 

 

 

 

Nondisplaced fractures of the scaphoid waist Displaced fractures of the scaphoid waist Proximal pole fractures

 

Percutaneous stabilization of scaphoid fractures may be performed using either a volar or dorsal approach under fluoroscopic guidance.3,11,12 If desired, a dorsal arthroscopically assisted reduction and fixation (AARF) technique can be used, which allows direct visualization after fracture reduction and stabilization.23,24,25

 

Regardless of the technique used, the screw must be inserted in the middle third or central axis of the scaphoid, as this provides the greatest stability and stiffness, and decreases time to union.1,29,30

Preoperative Planning

 

All imaging studies should be reviewed to identify the location of the fracture and the size of the scaphoid, both of which influence implant selection.

 

Plain radiographs should be templated to determine the approximate screw length.

 

 

The smaller size of the female scaphoid must be taken into consideration when planning internal fixation, as the diameters of most commercially available headless screws are larger than the proximal pole.13

 

Required equipment

 

 

 

Portable mini-fluoroscopy unit Kirschner wires

 

Cannulated headless compression screw system

 

Wrist arthroscopy equipment and traction tower for AARF

 

Positioning

 

The patient is positioned supine on the operating table, with the shoulder abducted 90 degrees and the arm on a radiolucent hand table.

 

A pneumatic tourniquet is applied to the upper arm.

 

The portable fluoroscopy unit is positioned at the end of the hand table.

 

 

P.334

 

TECHNIQUES

• Dorsal Arthroscopy-Assisted Reduction and Fixation

Nondisplaced Fracture of the Scaphoid Waist or Proximal Pole

Position the wrist to obtain a PA view of the wrist.

Under fluoroscopic guidance, gently pronate the wrist until the scaphoid appears as an oblong cylinder, indicating that the proximal and distal poles are aligned.

Flex the wrist about 45 degrees until the cylinder rotates into the plane of imaging, forming a “ring” sign. The center of the ring indicates the central axis of the scaphoid (TECH FIG 1).

Using a 14-gauge angiocatheter as a guide for wire insertion, place the tip of a 0.045-inch guidewire through the catheter and onto the proximal pole of the scaphoid, at the center of the scaphoid ring. Confirm correct positioning with fluoroscopy.24,25

Insert the guidewire down the central axis of the scaphoid using a wire driver. Keep the wrist flexed to avoid bending the wire.

Insert the guidewire through the trapezium and advance it until the proximal tip of the guidewire clears the radiocarpal joint such that the wrist can be extended for arthroscopic examination.

Confirm correct wire position with fluoroscopy.

Perform a diagnostic arthroscopy to assess for any associated injuries and to evaluate the fracture reduction.24,25

The radial midcarpal portal is used to evaluate the accuracy of fracture reduction.

The 3-4 and 4-5 portals are used assess the integrity of the radiocarpal and intercarpal ligaments.

Create a small longitudinal incision over each portal site, and bluntly dissect down to the capsule with a hemostat. Enter the capsule with a blunt trocar.

Confirm accurate fracture reduction and assess for other intraarticular injuries. Remove the hand from traction for screw insertion.

The radial midcarpal portal is used to evaluate the accuracy of fracture reduction.

The 3-4 and 4-5 portals are used to assess the integrity of the radiocarpal and intercarpal ligaments.

Suspend the hand vertically in finger traps and apply 10 pounds of traction to the upper arm to distract the radiocarpal and midcarpal articulations.

Create a small longitudinal incision over each portal site and bluntly dissect down to the capsule with a hemostat. Enter the capsule with a blunt trocar.

 

 

 

 

TECH FIG 1 • The scaphoid ring sign indicates the central axis of the scaphoid, which is critical for accurate insertion of the cannulated compression screw. A,B. The wrist is positioned in flexion and pronation until the scaphoid appears as a ring (arrow) on fluoroscopic imaging. A 0.045-inch guidewire is inserted through the center of the ring.

 

 

Remove the hand from traction for screw insertion.

 

Position the wrist again to obtain the ring sign, and maintain the wrist in flexion.

 

Drive the guidewire from volar to dorsal, perpendicular to the fracture line, until the distal tip lies just within the distal pole of the scaphoid (TECH FIG 2A-C).

 

Place a second guidewire of equal length against the tip of the proximal pole, parallel and next to the first guidewire. The difference between lengths of the protruding wires represents the length of the scaphoid.

 

Subtract at least 4 mm from the length of the scaphoid to obtain the desired screw length.

 

Make a small longitudinal incision around the guidewire and bluntly dissect down to the joint capsule. Carefully retract the extensor pollicis longus and extensor digitorum communis tendons away from the surgical site.

 

Use the cannulated reamer to ream the near cortex only.

 

Insert an Acutrak 2, mini-Acutrak 2 screw (Acumed, Beaverton, OR), or other cannulated headless compression screw of appropriate length (at least 4 mm shorter than the measured scaphoid length) to within 1 to 2 mm of the distal surface.

 

The tip of the screw should not penetrate the distal surface, and the proximal end of the screw should rest 2 mm deep to the proximal articular cartilage (TECH FIG 2D,E).

 

Confirm satisfactory screw position and fracture reduction with fluoroscopy. The screw should be inserted down the central axis of the scaphoid. If any doubt exists, use the arthroscopic portals to confirm that the screw is buried in the scaphoid.

 

The 3-4 portal and the radial midcarpal portals provide the best view to ensure that the fracture is adequately reduced and that there is no violation of the midcarpal joint.

Displaced Scaphoid Waist Fracture

 

Insert two percutaneous 0.062-inch smooth Kirschner wires dorsally into each fragment perpendicular to

 

the long axis of the scaphoid to be used as joysticks to reduce the fracture (TECH FIG 3A,B). Position the wrist as previously described.

 

The guidewire from the Acutrak 2 system (or the surgeon's chosen system) is inserted from proximal to distal, starting dorsally and aiming for the central axis of the distal fragment.

 

The guidewire is driven through the distal fragment and out through the volar skin of the hand. The protruding tip is then pulled volarly until the wire is only in the distal fragment (TECH FIG 3C).24,25

 

P.335

 

 

 

TECH FIG 2 • A-C. Before screw insertion, the position of the Kirschner wire must be changed from its position used for arthroscopy. The Kirschner wire should be driven from volar to dorsal until the distal end lies just beneath the articular surface of the scaphoid. D,E. Screw fixation of minimally displaced scaphoid fracture via the dorsal percutaneous technique. The screw tip should rest within 1 to 2 mm of the distal cortex. Excellent compression should be obtained with this technique.

 

 

The proximal fragment, which is now freely mobile, is reduced manually using the Kirschner wire joysticks.

 

Once the fracture is reduced, the central guidewire is driven from volar to dorsal into the proximal fragment, securing it in place (TECH FIG 3D).24,25

 

The guidewire is further advanced from volar to dorsal until its distal tip is just within the subchondral bone of the distal articular surface. This allows for measurement of the screw length as previously described.

 

An additional 0.045-inch Kirschner wire is inserted parallel to the guidewire to prevent rotation of the scaphoid fragments during reaming and screw implantation.

 

Maintenance of reduction during and after screw insertion is confirmed with fluoroscopy, and all wires

are subsequently removed.

 

 

 

TECH FIG 3 • A. Reduction of a displaced scaphoid waist fracture using Kirschner wire joysticks. B. The Kirschner wire joystick technique for fracture reduction. (continued)

 

 

P.336

 

 

 

TECH FIG 3 • (continued) C. The guidewire is pulled volarly until it remains only in the distal fragment. The joysticks are then utilized to reduce the fracture. D. The guidewire is driven from volar to dorsal, transfixing the proximal fragment.

• Volar Percutaneous Approach

   

  Position the patient in a supine position with the shoulder abducted and the forearm in supination. The wrist is placed into an extended and ulnarly deviated position over a rolled towel to gain access to the distal pole of the scaphoid.12

   

  Position the portable fluoroscopy unit such that PA and lateral views of the wrist can be obtained. Image intensification is used to locate the distal scaphoid tuberosity.

   

  A small longitudinal stab incision is made at this point, and the soft tissues are bluntly dissected down to the scaphotrapezial articulation.

   

  Introduce the guidewire on the distal scaphoid tuberosity. Under image guidance, the wire is advanced toward the center of the proximal pole, aiming for the Lister's tubercle (TECH FIG 4).

   

  The volar prominence of the trapezium may be partially excised to facilitate the correct starting point and trajectory for the guidewire.

   

   

   

  TECH FIG 4 • A-C. In the percutaneous volar approach, the guidewire is inserted into the scaphoid at the scaphotrapezial joint and into the center of the proximal pole. The wire should be inserted aiming for the Lister's tubercle.

   

   

   

  Alternatively, the guidewire may be placed directly through the trapezium into the scaphoid distal pole.11 Advance the guidewire to the subchondral bone of the proximal pole.

   

  Place a second guidewire of equal length against the surface of the distal scaphoid, adjacent and parallel

  to the first guidewire. The difference between the lengths of the wires represents the length of the scaphoid.

   

   

  Subtract 4 mm from the length of the scaphoid to obtain the desired screw length. Use the cannulated reamer to ream the near cortex.

   

  Insert an Acutrak 2 or mini-Acutrak 2 screw (or a screw from the surgeon's chosen system) of appropriate length, remove the guidewire, and confirm satisfactory screw position and fracture reduction with fluoroscopy.

   

   

   

  P.337

   

  PEARLS AND PITFALLS
  	Dorsal Technique     Injury to dorsal ▪ Blunt dissection through the capsule minimizes the risk of injury. structures     Malpositioning of ▪ Pronate and flex the wrist until the ring sign is noted; the center of the ring is

   

  guidewire the insertion point for the guidewire.

   

  Screw penetration

  • Select a screw that is at least 4 mm shorter than the measured length of the scaphoid.

  • A common mistake is to place a screw that ends up too long once the screw compresses the fragments.

  • Confirm central position of guidewire via fluoroscopy.

 

Reduction of unstable fracture

• Kirschner wires may be used as joysticks for reduction.

• A derotational Kirschner wire should be placed before reaming and screw insertion if the fragments are unstable.

   

  Extremely small proximal pole fractures

  • Use a mini-Acutrak 2 screw to prevent comminution of the proximal fracture fragment.

     

    Volar Technique

     

    Injury to volar structures

    • Blunt dissection to the scaphoid minimizes the risk of injury.

       

      Malpositioning of guidewire

• A central starting point on the distal scaphoid tuberosity can be hindered by the trapezium.

• Part of the volar trapezium can be resected to achieve a correct starting point for trajectory of the guidewire, or the wire may be inserted through the trapezium.

   

  Screw penetration

  • Select a screw that is at least 4 mm shorter than the measured length of the scaphoid.

  • Confirm central position of guidewire via fluoroscopy.

 

POSTOPERATIVE CARE

 

Dressings are applied, and the limb is immobilized in a forearm-based splint, immobilizing only the wrist. The thumb and fingers remain free for range-of-motion exercises.

 

The patient is instructed in the importance of limb elevation and finger range-of-motion exercises.

 

At 2 weeks postoperatively, the sutures are removed, a removable wrist splint is applied, and a wrist range-of-motion exercise program is initiated if fixation is rigid, the fracture is stable, and bone quality is good.

 

 

If the patient is noncompliant, the fracture is deemed unstable, the fixation is less than ideal, or bone quality is poor, then a short-arm cast is applied for at least 6 weeks.

 

Plain radiographs are obtained at 2, 6, 12, and 24 weeks postoperatively.

 

The splint (or cast) is discontinued when union is confirmed on serial plain radiographs. If there is any question regarding fracture union, a CT scan is obtained.

 

Unprotected strenuous activity or contact sports are not permitted until 3 months postoperatively.

 

Contact sports may be permitted sooner in a brace depending on the type of sport, player position, and quality of fixation.

 

 

OUTCOMES

Results of contemporary techniques of percutaneous fixation are excellent; it has been shown to allow for earlier mobilization and return to activity and high satisfaction rates compared to nonoperative measures.3,5,11,12,23,24,32

The surgical approach (dorsal vs. volar percutaneous) does not affect the clinical and functional outcome.11 Use of the transtrapezial approach does not lead to symptomatic scaphotrapezial arthritis at the short- to medium-term follow-up.10

Earlier mobilization avoids complications such as muscle atrophy and joint stiffness. Percutaneous techniques result in decreased soft tissue damage compared to conventional open techniques.32

In a series of 27 consecutive patients, the union rate (confirmed by CT) was 100%. The average time to union was 12 weeks, with a prolonged time to union noted in patients with a proximal pole fracture.24

 

 

COMPLICATIONS

The risks associated with open reduction and internal fixation, such as damage to the ligamentous support of the carpus and disruption of the dorsal blood supply, are minimized.

Possible complications include the following25: Nonunion

Malunion

Injury to the dorsal sensory branch of the radial nerve Extensor tendon injury

Infection

Technical problems: screw protrusion, screw malposition, bending or breakage of guidewire

Erosion of the trapezium and discomfort from the head of the screw has been reported with the use of a percutaneous cannulated screw inserted via the volar approach.32

 

 

REFERENCES

1. Adams BD, Blair WF, Reagan DS, et al. Technical factors related to Herbert screw fixation. J Hand Surg Am 1988;13(6):893-899.

    

    

2. Amadio PC, Moran SL. Fractures of the carpal bones. In: Green D, Hotchkiss R, Pederson WC, eds. Green's Operative Hand Surgery, ed

    

    

   5. Philadelphia: Churchill Livingstone, 2005:711-740.

    

    

3. Bond CD, Shin CA. Percutaneous cannulated screw fixation of acute scaphoid fractures. Tech Hand Up Extrem Surg 2000;4:81-87.

    

    

4. Burge P. Closed cast treatment of scaphoid fractures. Hand Clin 2001;17:541-552.

    

    

5. Chen AC, Chao EK, Hung SS, et al. Percutaneous screw fixation for unstable scaphoid fractures. J Trauma 2005;59:184-187.

    

    

   P.338

    

6. Dias JJ, Taylor M, Thompson J, et al. Radiographic signs of union of scaphoid fractures: an analysis of inter-observer agreement and reproducibility. J Bone Joint Surg Br 1988;70:299-301.

    

    

7. Gelberman RH, Menon J. The vascularity of the scaphoid bone. J Hand Surg Am 1980;5:508-513.

    

    

8. Gelberman RH, Wolock BS, Siegel DB. Fractures and non-unions of the carpal scaphoid. J Bone Joint Surg Am 1989;71A:1560-1565.

    

    

9. Gellman H, Caputo RJ, Carter V, et al. Comparison of short and long thumb-spica casts for non-displaced fractures of the carpal scaphoid. J Bone Joint Surg Am 1989;71(3):354-357.

    

    

10. Geurts G, van Riet R, Meermans G, et al. Incidence of scaphotrapezial arthritis following volar percutaneous fixation of nondisplaced scaphoid waist fractures using a transtrapezial approach. J Hand Surg Am 2011;36(11):1753-1758.

     

     

11. Gürbüz Y, Kayalar M, Bal E, et al. Comparison of dorsal and volar percutaneous screw fixation methods in acute Type B scaphoid fractures. Acta Orthop Trauma Tur 2012;46(5):339-345.

     

     

12. Haddad FS, Goddard NJ. Acute percutaneous scaphoid fixation. A pilot study. J Bone Joint Surg Br 1998;80(1):95-99.

     

     

13. Heinzelmann AD, Archer G, Bindra RR. Anthropometry of the human scaphoid. J Hand Surg 2007;32(7):1005-1008.

     

     

14. Horii E, Nakamura R, Watanabe K, et al. Scaphoid fracture as a “puncher's fracture.” J Ortho Trauma 1994;8:107-110.

     

     

15. Jørgsholm P, Thomsen NO, Björkman A, et al. The incidence of intrinsic and extrinsic ligament injuries in scaphoid waist fractures. J Hand Surg 2010;35(3):368-374.

     

     

16. Kerluke L, McCabe SJ. Nonunion of the scaphoid: a critical analysis of recent natural history studies. J Hand Surg Am 1993;18(1):1-3.

     

     

17. Kozin SH. Incidence, mechanism, and natural history of scaphoid fractures. Hand Clin 2001;17:515-524.

     

     

18. Leslie IJ, Dickson RA. The fractured carpal scaphoid. Natural history and factors influencing outcome. J

    Bone Joint Surg Br 1981;63-B(2): 225-230.

     

     

19. Mack GR, Bosse MJ, Gelberman RH, et al. The natural history of scaphoid nonunion. J Bone Joint Surg Am 1984;66(4):504-509.

     

     

20. Martus JE, Bedi A, Jebson PJ. Cannulated variable pitch compression screw fixation of scaphoid fractures using a limited dorsal approach. Tech Hand Upper Ext Surg 2005;9:202-206.

     

     

21. Ruby LK, Stinson J, Belsky MR. The natural history of scaphoid non-union: a review of fifty-five cases. J Bone Joint Surg Am 1985;67(3):428-432.

     

     

22. Schädel-Höpfner M, Junge A, Böhringer G. Scapholunate ligament injury occurring with scaphoid fracture

    —a rare coincidence? J Hand Surg Br 2005;30:137-142.

     

     

23. Slade JF III, Dodds SD. Minimally invasive management of scaphoid nonunions. Clin Orthop 2006;445:108-119.

     

     

24. Slade JF III, Gutow AP, Geissler WB. Percutaneous internal fixation of scaphoid fractures via an arthroscopically assisted dorsal approach. J Bone Joint Surg Am 2002;84:21-36.

     

     

25. Slade JF III, Jaskwhich D. Percutaneous fixation of scaphoid fractures. Hand Clin 2001;17:553-574.

     

     

26. Sutton PA, Clifford O, Davis TRC. A new mechanism of injury for scaphoid fractures: ‘test your strength’ punch-bag machines. J Hand Surg Eur Vol 2010;35(5):419-420.

     

     

27. Thavarajah D, Syed T, Shah Y, et al. Does scaphoid bone bruising lead to occult fractures? A prospective study of 50 patients. Injury 2011;42:1303-1306.

     

     

28. Thomsen L, Falcone MO. Lesions of the scapholunate ligament associated with minimally displaced or non-displaced fractures of the scaphoid waist. Which incidence? Chir Main 2012;31:234-238.

     

     

29. Trumble TE, Clarke T, Kreder HJ. Non-union of the scaphoid. Treatment with cannulated screws compared with treatment with Herbert screws. J Bone Joint Surg Am 1996;78(12):1829-1837.

     

     

30. Trumble TE, Gilbert M, Murray LW, et al. Displaced scaphoid fractures treated with open reduction and internal fixation with a cannulated screw. J Bone Joint Surg Am 2000;82(5):633-641.

     

     

31. Wong TC, Yip TH, Wu WC. Carpal ligament injuries with acute scaphoid fractures: a combined wrist injury. J Hand Surg Br 2005;30:415-418.

     

     

32. Yip HS, Wu WC, Chang RY, et al. Percutaneous cannulated screw fixation of acute scaphoid waist fracture. J Hand Surg Br 2002;27(1):42-46.