Pediatric Scaphoid Nonunions: A Case Series, Review of the Literature, and Evidence-Based Guidelines

• Abstract
• Materials and Methods
• Case Series
• Material and Methods
• Review of the Literature: Pediatric Scaphoid Nonunions
• Results and Integrated Discussion
• Pediatric Scaphoid Nonunions
• Management of Pediatric Scaphoid Nonunions
• Nonoperative Treatment of Pediatric Scaphoid Nonunions
• Surgical Treatment of Pediatric Scaphoid Nonunions
• Results and Integrated Discussion
• Review of the Literature: Scaphoid Fractures
• Epidemiology of Scaphoid Fractures
• Classification of Scaphoid Fractures
• Management of Pediatric Scaphoid Fractures
• Acute Fractures: Undisplaced
• Acute Fractures: Displaced
• Conclusions and Summary
• References

Abstract

Background Scaphoid fractures represent less than 3% of hand and wrist fractures in the pediatric population. Nonunions are very rare. We present a case series (n = 18) of nonunions in skeletally immature children and adolescents. We further present a review of the literature on pediatric scaphoid nonunions.

Materials and Methods We reviewed the literature by searching the main databases on pediatric scaphoid nonunions, but to identify factors that lead to nonunion, we also searched for databases on scaphoid fractures. Seventy articles were found for the period between 1961 and 2019, all with level 4/5 evidence.

Results The nonunion rate of pediatric scaphoid fractures in the literature is on average 1.5%, occurring mostly as a result of missed or underdiagnosed injuries, similar to our presented case series. Half (n = 9) of the injuries in our case series were missed initial injuries, leading to scaphoid nonunions and half developed nonunions after initial treatment. We found excellent outcomes and with surgical and nonoperative management, with few complications. Not surprisingly, the duration of immobilization is longer with nonoperative management.

Conclusions Based on the literature, we recommend a period of nonoperative management before surgery in undisplaced nonunions. In displaced nonunions, open reduction and internal fixation ± bone grafting is necessary. In pediatric scaphoid fractures, similar to adult cases, we identified that suspicious scaphoid fractures should be considered for initial immobilization, and repeat X-rays and early magnetic resonance imaging (MRI) or computed tomography (CT) scans should be considered at follow-up. Immobilization time and type of plaster should be appropriate in relation to the fracture site, similar to the adult scaphoid fracture.

Level of Evidence This is a Level IV study.

Fractures of the scaphoid are rare events representing between 0.3 and 0.4% of all pediatric fractures.[1] [2] [3] [4] [5] [6] [7] [8] [9] The scaphoid is affected in 2 to 3% of pediatric hand and wrist fractures,[4] [5] [6] [7] [10] [11] albeit it is the most often affected carpal bone in the pediatric population (87%).[7] It most commonly affects adolescents between 11 and 17 years of age[2] [4] [7] [10] [12] [13] [14] and very rarely children younger than 8 years.[2] [4] [7] These injuries may become more common as children take part in more sporting activities,[7] [15] [16] [17] and possibly also with an increase in body mass index (BMI).[7]

Pediatric scaphoid fractures have an excellent prognosis once and if acutely diagnosed. Nonunions are exceedingly rare, and management of such cases varies widely throughout the literature, ranging from plaster immobilization to osteosynthesis, with or without bone graft.

The aim of this study was to present a case series with various treatments, all leading to a successful outcome, review the literature on both pediatric scaphoid fractures and nonunions, and, based on these two, present both experience- and evidence-based guidelines for the management of pediatric nonunions of the scaphoid.

Materials and Methods

Case Series

We included 18 pediatric patients (15 boys and 3 girls) from three units ([Table 1]) who presented with delayed or nonunion of the scaphoid with a mean age of 13 years (range: 9–15 years). The trauma mechanism was falling onto an outstretched hand (FOOSH) in six patients, hyperextension or hyperflexion trauma while playing football/rugby in six patients, crush injury in two patients, falling off a horse in one patient, and unclear in three patients. Of the 18 patients, there was an initial diagnosis of a scaphoid fracture in 9 and of “sprain” in 4; 10 of these 13 patients had some form of initial immobilization due to the initial presentation. Five patients did not have any initial review and subsequently no initial treatment ([Fig. 1]).

Diagnosis and start of treatment of the nonunions was 8 months (range: 2–28 months) after initial trauma. The nonunions were undisplaced waist in 11 children; six were in the proximal pole and one in the distal pole. All children underwent plain X-rays for diagnosis, as well as additional imaging (magnetic resonance imaging [MRI] = 13 and/or computed tomography [CT] = 14). Patients were treated nonoperatively with immobilization alone (n = 6), screw fixation and bone graft (n = 6), screw fixation without bone graft (n = 2) ([Fig. 1]), and K-wires and bone graft (n = 2) ([Table 1]). Bone graft, if used, was taken either from the iliac crest or the distal radius. One patient was immobilized for 6 weeks after initial trauma and remained asymptomatic in spite of partial union/nonunion on X-ray ([Fig. 2]). One patient was initially diagnosed as a child (below the age of 16 years) but was further followed-up within the adults department.

All patients were asymptomatic after treatment, and healing was achieved in 16 cases, as confirmed with CT in 13/16 cases.

Material and Methods

Review of the Literature: Pediatric Scaphoid Nonunions

We reviewed the literature on pediatric scaphoid nonunion and their management. We further added management of pediatric scaphoid fractures for completion and identifiable factors to avoid nonunions ([Table 2]).

Seventy articles were found for the period between 1961 and 2019. None of them was level 1 to 3 evidence, that is, prospective randomized studies, prospective series, or comparison studies. All articles found were either case series (level 4) or cases with reviews (level 5).

Results and Integrated Discussion

Pediatric Scaphoid Nonunions

The nonunion rate of pediatric scaphoid fractures in the literature is on average 1.5% (range: 0–4.3%) ([Table 3]). Scaphoid nonunion is usually a result of a missed or neglected injury or an underdiagnosed fracture,[24] similar to our presented case series. The mean age of children reported with scaphoid nonunions is 13 years following a systematic review of 176 pediatric scaphoid nonunions in the literature ([Table 4]), also similar to that in our case series.

There is no standard duration of time that it takes for a pediatric or adolescent scaphoid fracture to be classified as delayed union or nonunion.[17] Most commonly, nonunion is defined as the absence of bony union at least 3 months after injury.[5] [17] [18] [19] However, others take a more adult view and define it as 6 months after the injury.[1] [6] [18] Furthermore, others believe that the definition of scaphoid nonunion is the presence of cystic changes of the scaphoid or sclerosis of the bone ends around the radiolucent line at the fracture site seen on standard radiographs at least 3 months after injury.[5] [18] [20] In a recent paper,[21] it has been implied that nonunion is a displacement of scaphoid fracture fragments more than 1 mm on CT scans, with signs of cystic resorption and sclerosis on radiographs and CT scans occurring later than 6 weeks after scaphoid fractures.[21]

In regard to this controversy, we have defined delayed healing in our case series as 6 weeks after injury in the skeletally immature patients in whom healing potential is better than that in adults, suggesting that a nonunion type of management should be considered at 6 weeks after injury in the pediatric population.

Two types of pediatric scaphoid nonunions have been suggested.[4] [14] [22] The first group (42%) includes those correctly diagnosed at the time of injury and treated, but where failure of union occurs despite adequate treatment. The second group (58%) involves completely missed injuries, inadequately investigated injuries with a combination of lack of awareness about the possibility of pediatric scaphoid fractures and the difficulty in examining young patients. Some nonunions are simply incidental findings on radiographs for other pathology.[23] [24]

Management of Pediatric Scaphoid Nonunions

Nonoperative Treatment of Pediatric Scaphoid Nonunions

In adults, the preferred management for a scaphoid nonunion is open reduction internal fixation (ORIF).[25] In children, it has been suggested that a trial of cast immobilization be attempted first[1] [7] [26] due to the fact that the pediatric scaphoid fractures have a more favorable healing capacity than adult fractures. The average time for immobilization is 15 weeks ([Table 5]). Almost all nonunions involved the scaphoid waist.[23] Most of the fractures had been neglected without initial immobilization at the time of injury. Further causes of failure to achieve bony union may be noncompliance (with immobilization, no loading instructions, etc.) and inadequate length of immobilization.[17] [27] [28]

Immediate treatment of an early diagnosed pediatric scaphoid fracture using cast results in radiographic healing in more than 90% of cases.[17] In patients with a delay in diagnosis and thereby in treatment (more than 6 weeks), chances of healing are reduced to 23% with nonoperative management.[17]

Complications after plaster treatment in children are infrequent, with rare examples of malunion, “deformity,” and decrease in wrist extension noted clinically.[27] [29] Stiffness is rarely an issue in the pediatric population.[4] [16] There are no reports of failure with nonoperative treatment of pediatric scaphoid nonunions. In children, a trial of immobilization can be recommended, although a long period of time to union should be expected ([Table 5]). Our case series included six children, all of whom healed after immobilization alone without complications.

Surgical Treatment of Pediatric Scaphoid Nonunions

Surgical management of pediatric scaphoid nonunions has been found to be successful for over 40 years[29] [30]; hence, surgical management has become more widely accepted in the pediatric population.

Surgical management of pediatric scaphoid nonunions was found in 153 children in our literature search, with ORIF, autogenous bone graft, and screw fixation being the most common methods ([Table 6]) similar to adults. Other techniques included various combinations such as autogenous bone graft without fixation,[30] [31] [32] [33] bone graft with K-wire fixation,[24] [31] [33] [34] [35] [36] [37] ORIF and lag screw fixation,[29] [31] and closed reduction and percutaneous screw fixation ([Table 6]).[17] [31] [38] [39]

All surgical techniques have proven to be successful ([Table 6]). The principal difference has been the length of postoperative immobilization ([Table 6]). The shortest immobilization periods required for union have been associated with ORIF.[31] In select series of fibrous nonunion, union was seen within only 3 weeks using percutaneous screws without graft[29] ([Table 6]). It has been shown that ORIF halved the postoperative immobilization period when bone graft was used.[31] [33] However, the length of postoperative immobilization with osteosynthesis is comparable to all other operative series. There is a revision rate of approximately 3% in all surgical techniques.[17] Other complications reported include proximal migration of screws, malunion, pin-site infection, and restriction of wrist movements compared with the contralateral wrist ([Table 6]).[17] [29] [31] [32] [33] [37]

An important technical aspect is that there has been some concern about the use of compression screws in children because of the ossification pattern with the cartilage cap of the scaphoid ([Fig. 3]).[23] [32] [39] However, ORIF with screw fixation has the advantages of strong internal fixation with compression, prevention of scaphoid collapse, and reduction of the time of postoperative immobilization.[23] However, these screws have been used successfully in children as young as 9 years,[23] [33] and only one proximal migration has been reported[31]; yet the choice of inserting a screw is a very important part of the preoperative planning in particular whether the surgeon believes that an internal screw stuck in the growing scaphoid is better than K-wires that can easily be removed after union to have a more normal growing scaphoid.

Surgical management of pediatric scaphoid nonunions should be performed based on clinical and radiographic presentation, noting that there is a chance of remodeling of the pediatric united nonunion[4] as opposed to the adult situation where scaphoid nonunion will progressively lead to scaphoid nonunion advanced collapse, with radiological signs correlating to the nonunion duration, displacement, and increased scapholunate angles.[17] The natural history of pediatric nonunions is difficult to document, and it has not been established if the well-described adult long-term complications of nonunions are also true for skeletally immature patients.[29] [33] In fact, it has been reported that dorsal intercalated segment instability (DISI) deformity was spontaneously corrected due to remodeling in a small case series.[4] The presence of scaphoid humpback deformity and/or DISI deformity may be a stronger indication for surgical intervention in pediatric nonunion cases,[17] [32] [40] albeit with weak evidence of such management.

Results and Integrated Discussion

Review of the Literature: Scaphoid Fractures

Epidemiology of Scaphoid Fractures

Pediatric scaphoid fractures are rare injuries,[41] representing between 2 and 3% of pediatric hand and wrist injuries ([Table 2]).[1] [5] [7] [8] [9] [23] It remains the most common carpal bone to be fractured in all pediatric age groups.[36] Studies revealed an incidence of 0.4 per 100,000 females and 2 per 100,000 males.[41] [42] [43] An 8-year observation of discharge data revealed an incidence of 3 per 100,000 females and 39 per 100,000 males.[42] [43] Pediatric scaphoid fractures usually occur at 11 to 15 years of age,[1] [2] [7] [13] [14] [17] [23] but fractures have been reported as early as 4 years, though not identified until years later.[26] Most occur through FOOSH,[2] [6] [7] [12] [14] [44] during sporting activities, punching and fighting, or road traffic related trauma.[1] [7] It has been suggested that the incidence of scaphoid fractures will rise with the increased popularity of sports such as skiing and skateboarding and the use of recreational punching games machines, possibly also due to an increase in BMI in children.[7] [13] [14] [29] [45] The scaphoid fracture can be associated with other injuries in 15% of the cases,[7] such as distal radius fractures (5%), transscaphoid–perilunate dislocations (1%), ulnar styloid fractures (1%), and capitate fractures (1%).[7]

Initial radiographs fail to reveal the fractures in 12 to 37% of the cases[1] [2] [14]; therefore, many authors choose to treat children with clinical suspicion of scaphoid fracture and negative findings on radiographs conservatively for 2 to 3 weeks. With this management, 30% of those clinically suspected fractures were proven to be true fractures.[2] [5] [14] Around 45% of the suspected scaphoid fractures have the diagnosis confirmed on the first follow-up, 2 weeks after the injury, and 84% are evident 5 weeks after injury.[2] [7] It has also been highlighted that MRI had a negative predictive value of 100% and avoided unnecessary radiation and immobilization in 58% of patients.[1] [44]

Classification of Scaphoid Fractures

Most pediatric scaphoid fractures are classified and divided by the anatomical fracture site.[7] The distal third of the scaphoid (avulsion, tuberosity or complete fractures) represent 36 to 87% of cases ([Table 7]).[3] [4] [5] [6] [7] [14] [28] [31] [35] [44] [45] This is in direct contrast to adults, in whom 70 to 80% of fractures occur in the middle third. Proximal pole fractures occur in 0 to 6% of the pediatric scaphoid fractures[4] [5] [14] [46] ([Table 7]). This can be explained by the process of enchondral ossification, which progressively occurs eccentrically from distal to proximal after the appearance of the scaphoid ossifying nucleus at 5 years and then further develops until around 13 years in females and around 15 years in males ([Fig. 3]).[1] [6] [7] [30] [37]

It has been suggested that the cartilage affords protection to the immature carpus, explaining why fewer carpal fractures occur in the pediatric population and occur more frequently in the distal third, which is ossified earlier, particularly in younger children ([Fig. 3]).[4] [5] [10] [17] [23] [28] [30] [37] [44] [45] [46] In older teenagers, with scaphoids near complete ossification, scaphoid fractures more closely resemble the adult pattern ([Fig. 3]). Consequently, newer literature suggests that 71% of the fractures of the scaphoid fractures in children and adolescents occur in the waist of the bone, especially in those who have closed physes (84%).[7]

Another, less used, classification system is based on radiographic features and stage of ossification[1] [7] [47] [48]:

• Type 1(pure chondral fracture): this occurs in children younger than 8 years and requires MRI or CT to diagnose.

• Type 2 (osteochondral fracture): This occurs between 8 and 11 years of age.

• Type 3 (the most common): this occurs when ossification is almost complete, from the age of 12 years onward.

The retrograde distally based vascular supply to the scaphoid is the same in children as in adults.[42] [43] [49] Consequently, many pediatric scaphoid fractures, which involve the well-vascularized distal third pole, unite favorably. A majority of pediatric scaphoid nonunions occur in the middle third of the scaphoid carpus, where healing is more affected by the retrograde vascular supply to the scaphoid.[23] This also applies to the less common proximal third scaphoid fractures in the pediatric population.

In addition, a greater proportion of scaphoid fractures are undisplaced and unicortical in children, again possibly because of the protective cartilaginous periphery ([Fig. 3]).[5] [8] [10] [23] [30] [37] [44] [45] This would explain why the incidence of scaphoid fracture nonunion is lower in children, particularly in children below 11 years of age. Our review of the largest published series reveals a 1.5% rate of pediatric scaphoid nonunions ([Table 3]).

Management of Pediatric Scaphoid Fractures

Acute Fractures: Undisplaced

Management of acute undisplaced or minimally displaced pediatric scaphoid fractures should consist of cast immobilization.[14] [15] In children, tuberosity, avulsion, and unicortical fractures require 3 to 6 weeks of immobilization, whereas waist and distal third fractures require 6 to 10 weeks of immobilization.[7] [8] [9] [13] [36] [45] [49] [51] [52] Proximal pole fractures, albeit rare, may require up to 12 to 15 weeks of cast treatment.[7] [48] [51] [52] However, these are guidelines, and immobilization should be tailored to clinical and radiological signs of healing.

Around 90% of patients with acute undisplaced scaphoid injuries who are treated with cast immobilization alone achieve a successful union.[7] [8] [13] [51] [52] The type of cast may have an influence on the final results of the treatment of acute undisplaced fractures. Patients treated initially with long arm cast for 6 weeks had a faster healing process (9.5 weeks; rate of union: 97%) than those treated with short arm thumb cast (12.7 weeks; rate of union: 100%).[7] [11] The mold of the cast to the palm, not its length, has been stated to be the most important factor for fracture healing.[11] Thus far, it has not been trialed in children if a forearm cast excluding the thumb component, as seen in a randomized controlled trial in adults, will produce the same healing rate as the typical scaphoid cast (including the thumb).[51] [52] Furthermore, advantages of nonoperative management include cost-effectiveness of the treatment and prevention of the negative effects associated with surgery, such as exposition to anesthesia, placement of hardware, possible growth reduction, and risk of infection.[11] Operative treatment should be reserved for patients at or near skeletal maturity.[11] Disadvantages of nonoperative management, however, can be the length of immobilization with return to hospital for reviews and the risk of noncompliance in the pediatric patient, as well as nonunion despite adequate immobilization with further surgical treatment.

Acute Fractures: Displaced

Acute displaced scaphoid fractures in children have not been widely reported. The outcome of nonoperative treatment for displaced fractures may lead to a satisfactory union without complications[40] but should be looked at as an exception to the general guidelines.[53] According to evidence-based guidelines and general advice, surgical treatment is indicated for acute displaced fractures to achieve good union rates with less time and quicker return to normal activities.[11] [15] The more specific indication for surgical treatment in pediatric scaphoid fractures, especially in patients near skeletal maturity, is a presence of more than 1 mm of displacement, fracture comminution, fractures of the proximal pole, delay in diagnosis and initial treatment, poor patient compliance, and a fracture angulation in the sagittal plane with a lateral interscaphoid angle of more than 45 degrees and a height-to-length ratio of more than 0.65.[1]

There is a trend toward early surgical treatment for undisplaced fractures, as one series showed chronic nonunions in one-third of the patients.[14] In fact, there are groups suggesting ORIF with screws and bone graft as the first-line treatment even in undisplaced fractures.[23] We struggle to find any support in the literature for this trend toward surgical management in these benign fractures.

Conclusions and Summary

Scaphoid fractures are rare injuries in skeletally immature wrists, representing less than 3% of hand and wrist injuries. As opposed to the skeletally mature patients, the distal third of the scaphoid is extensively affected, and proximal pole fractures are very rare due to the large cartilage cap of the proximal pole ([Fig. 3]).

Nonoperative management is advised in undisplaced fractures of all kinds and possibly also in displaced fractures due to the remodeling capacity in a growing child. ORIF should be considered in undisplaced fractures with more than 1 mm of displacement, fracture comminution, involvement of the proximal pole, delay in diagnosis and initial treatment, poor patient compliance, and increased fracture angulation.[1]

To avoid delayed diagnosis and hence the risk of pediatric scaphoid nonunion, a high suspicion of scaphoid fracture in the injured child should indicate initial X-rays, consideration for immobilization for 2 to 3 weeks, follow-up with repeat clinical assessment, repeat X-rays, and consideration for other imaging modalities (MRI preferred to CT both to minimize radiation and to find associated injuries) as diagnosis may still be unclear up to 5 weeks after injury ([Table 8]).

Pediatric scaphoid nonunions are very rare (1.5%) and are most commonly caused by not only missed injuries but also missed initial diagnosis and treatment. Management of nonunion involves a variety of surgical and nonoperative techniques. Regardless of treatment, excellent outcomes have been reported with surgical and nonoperative management, with few complications, though the duration of immobilization is longer without internal fixation ([Table 8]). Our case series clearly shows this.

We would recommend, in conjunction with our presented case series, that in an undisplaced scaphoid nonunion, a period of nonoperative management before surgery ought to be considered. The classic rule, that is, “treat the patient, not the X-ray,” is very valid in this age group. If displaced nonunion persists, then surgical fixation and bone grafting have support in the literature ([Table 8]). Although all methods have been reported to be successful, we strongly recommend surgeons to use a technique they are familiar with, as demonstrated with our case series.

Conflict of Interest

None declared.

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• 47 D'Arienzo M. Scaphoid fractures in children. J Hand Surg Br 2002; 27 (05) 424-426
  CrossrefPubMedGoogle Scholar
• 48 Elhassan BT, Shin AY. Scaphoid fracture in children. Hand Clin 2006; 22 (01) 31-41
  CrossrefPubMedGoogle Scholar
• 49 Taleisnik J, Kelly PJ. The extraosseous and intraosseous blood supply of the scaphoid bone. J Bone Joint Surg Am 1966; 48 (06) 1125-1137
  CrossrefPubMedGoogle Scholar
• 50 Wulff RN, Schmidt TL. Carpal fractures in children. J Pediatr Orthop 1998; 18 (04) 462-465
  PubMedGoogle Scholar
• 51 Rupani N, Riley N, McNab I. Spontaneous healing of a pediatric scaphoid proximal pole fracture nonunion. J Wrist Surg 2018; 7 (01) 81-83
  Article in Thieme ConnectPubMedGoogle Scholar
• 52 Buijze GA, Goslings JC, Rhemrev SJ. , et al; CAST Trial Collaboration. Cast immobilization with and without immobilization of the thumb for nondisplaced and minimally displaced scaphoid waist fractures: a multicenter, randomized, controlled trial. J Hand Surg Am 2014; 39 (04) 621-627
  CrossrefPubMedGoogle Scholar
• 53 De Boeck H, Van Wellen P, Haentjens P. Nonunion of a carpal scaphoid fracture in a child. J Orthop Trauma 1991; 5 (03) 370-372
  CrossrefPubMedGoogle Scholar
• 54 Vahvanen V, Westerlund M. Fracture of the carpal scaphoid in children. A clinical and roentgenological study of 108 cases. Acta Orthop Scand 1980; 51 (06) 909-913
  CrossrefPubMedGoogle Scholar
• 55 Carlson EJ, Save AV, Slade III JF, Dodds SD. Low-intensity pulsed ultrasound treatment for scaphoid fracture nonunions in adolescents. J Wrist Surg 2015; 4 (02) 115-120
  Article in Thieme ConnectPubMedGoogle Scholar
• 56 Ben-Amotz O, Ho C, Sammer DM. Reconstruction of scaphoid non-union and total scaphoid avascular necrosis in a pediatric patient: a case report. Hand (N Y) 2015; 10 (03) 477-481
  CrossrefPubMedGoogle Scholar
• 57 Iqbal S, Higgins G, Ratcliffe P. Avascular necrosis of both poles of a paediatric was it of scaphoid fracture. Inj Extra 2007; 38: 247-249
  CrossrefPubMedGoogle Scholar
• 58 Larson B, Light TR, Ogden JA. Fracture and ischemic necrosis of the immature scaphoid. J Hand Surg Am 1987; 12 (01) 122-127
  CrossrefPubMedGoogle Scholar
• 59 Pick RY, Segal D. Carpal scaphoid fracture and non-union in an eight-year-old child. Report of a case. J Bone Joint Surg Am 1983; 65 (08) 1188-1189
  CrossrefPubMedGoogle Scholar
• 60 Godley DR. Nonunited carpal scaphoid fracture in a child: treatment with pulsed electromagnetic field stimulation. Orthopedics 1997; 20 (08) 718-719
  PubMedGoogle Scholar
• 61 Littlefield WG, Friedman RL, Urbaniak JR. Bilateral non-union of the carpal scaphoid in a child. A case report. J Bone Joint Surg Am 1995; 77 (01) 124-126
  CrossrefPubMedGoogle Scholar

Address for correspondence

• References

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  CrossrefPubMedGoogle Scholar
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  PubMedGoogle Scholar
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  Article in Thieme ConnectPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
• 55 Carlson EJ, Save AV, Slade III JF, Dodds SD. Low-intensity pulsed ultrasound treatment for scaphoid fracture nonunions in adolescents. J Wrist Surg 2015; 4 (02) 115-120
  Article in Thieme ConnectPubMedGoogle Scholar
• 56 Ben-Amotz O, Ho C, Sammer DM. Reconstruction of scaphoid non-union and total scaphoid avascular necrosis in a pediatric patient: a case report. Hand (N Y) 2015; 10 (03) 477-481
  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar
• 59 Pick RY, Segal D. Carpal scaphoid fracture and non-union in an eight-year-old child. Report of a case. J Bone Joint Surg Am 1983; 65 (08) 1188-1189
  CrossrefPubMedGoogle Scholar
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  PubMedGoogle Scholar
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  CrossrefPubMedGoogle Scholar