key: cord-0835979-zdeps735
authors: Zeng, Shuaidan; Deng, Hansheng; Zhu, Tianfeng; Han, Shuai; Xiong, Zhu; Tang, Shengping
title: Calcaneal Skeletal Traction versus Elastic Intramedullary Nailing of Displaced Tibial Shaft Fractures in Children
date: 2020-10-07
journal: Injury
DOI: 10.1016/j.injury.2020.10.035
sha: 07d678a3c9cb8aa42c13d8439a82f6450325daa0
doc_id: 835979
cord_uid: zdeps735

BACKGROUND: The objective of this study was to compare the outcomes and complications of patients who underwent either the calcaneal skeletal traction (CST) or the elastic intramedullary nails (EIN) procedure. METHODS: We retrospectively reviewed data of patients who underwent EIN or CST surgery for tibia shaft fracture at our center from 2013 to 2018. The patient demographics, fracture characteristics, radiographic information, length of hospital stay, and medical expenses were recorded. All patients were clinically followed-up until they started to walk or for at least 6 months. The treatment outcomes and postoperative complications of the two procedures were compared. RESULTS: Overall, 186 patients who underwent EIN and CST were included in the study. The EIN patients had more low-energy mechanism of injury. In radiographic evaluation, significant differences were observed in distributions of fracture classification and location. Moreover, associated fibula fractures were higher in the EIN group than in the CST group. The CST procedure had faster surgical time, cast duration and lower expenses, and longer hospitalization time. Although they required more clinical visits, patients in the EIN group began exercising and endured weight-bearing earlier than those in the CST group. The average time for bone healing was 68.5 days in the EIN group, and 69.6 days in the CST group. However, the CST provided slight better results of coronal correction than EIN. Moreover, CST patients had less malalignment (> 5 degree) in complications. None had delay union, nonunion, and shortening over 10 mm at final assessment. CONCLUSIONS: Both EIN and CST patients showed similar treatment outcomes. Hence, not only the characteristics of the patient and fracture, but also the individual's situation and expectation should be considered when choosing the best approach.

Tibial shaft fractures (TSF) are extremely common in children and adolescents.

These fractures result from various causes such as from high-energy trauma in vehicular accidents to low-energy damage from sports injuries or falls on level ground [1] , [2] . There are multiple surgical and non-surgical management interventions for TSF such as casting with closed reduction, elastic intramedullary nailing (EIN), plate osteosynthesis, external fixation, and rigid intramedullary nailing [2] . Surgeons may select any of them based on the following parameters: age and weight, characteristics of the fractures, and requirements from the parents.

EIN is gaining popularity for treatment of displaced TSF (DTSF) in children as a result of its small incision, earlier weight-bearing, an increased range of motion compared with casting, and physeal fracture avoidance. However, implant irritation and a second surgery for implant removal are still potential disadvantages [2] .

Calcaneal skeletal traction (CST) with long-leg casting is a traditional and prevalent treatment for DTSF in children and adolescents at our centre, and in China.

Consequently, it is widely accepted by most families and is more manageable as far as surgeons are concerned. However, studies on CST are comparatively rare and there are no published studies comparing EIN with CST in the management of DTSF. There is no clear policy for the treatment of DSTF in our institution especially for older children, with some surgeons preferring EIN and others, CST.

The main objective of this study was to retrospectively analyse treatment outcomes and complications of DTSF treated with EIN as opposed to CST in children over 5 years old.

We retrospectively reviewed clinical information and radiographs of all patients treated with EIN and CST for DTSF of the tibia, from January 2013 to December 2018. A patient was deemed eligible for the study if (1) age at the time of injury was above 5 years; (2) the fracture was closed and treated by closed reduction; (3) there was clinical follow-up, either for a radiographic union, or 6 months from the surgery, detailed records existed. The exclusion criteria for the study were (1) underlying syndromes and metabolic bone diseases, (2) fracture line extended into the metaphysis, (3) closed growth plates, and (4) incomplete treatment records. The design of the study was granted by the investigational review board (IRB) of our centre.

The mechanism of the injury that caused the fracture was determined from the medical records. Motor-vehicle collisions, and pedestrians versus automobile incidents were classified as high-energy mechanisms, whereas mechanical falls and sporting injuries were regarded as low-energy mechanisms. The emergency department and hospital records were further reviewed for the presence of coincident traumatic injuries, such as head injuries, solid-organ injuries, and other fractures.

Pre-reduction radiographs for each patient were evaluated and classified according to the AO paediatric comprehensive classification of long bone fractures (PCCF) classification system [3] . In addition, injury films were also assessed for the angulation, shortening, displacement, and location of the diaphysis and its associated fibula fracture.

For the CST, we first drew a line to connect the lateral malleolus and heel before the operation, then the line was equally divided into 3 parts by 2 points. The outer point was the optimal location of the percutaneous K-wire. Thereafter, the pin was hammered across the calcaneus, perpendicular to the limb. The primary tractive weight was 1/10 of the patient's body weight up to a maximum 3.5 kg. This was adjusted based on periodic bedside radiographs to ensure the fracture was satisfactorily aligned without shortening or lengthening. Once callus occurred, we removed the traction pin and fixed the patient's limb with a polymer plaster long-leg cast. This could also be done under local anaesthesia for compliable patients to avoid another general anesthesia. For EIN, we used the standard method to perform the procedure as described by Flynn et al [4] .

Hospital charts were reviewed for relevant clinical and demographic information.

The date of injury, duration of surgery, length of hospital stay, and hospitalization expenses were also recorded. Patients were followed up with serial clinical visits, and radiographs were obtained until they were finally healed, or until 6 months after the index procedure. Healing occurred when the fracture lines faded, and the callus bridging across 3 of the 4 cortices, on both anteroposterior and lateral radiographs, appeared [5] . In addition, fracture alignment at the final assessment and changes in alignment were measured. Coronal alignment was also measured from the anteroposterior radiographs, and sagittal alignment was assessed on lateral films. In addition, fracture shortening was measured as the vertical displacement of the non-opposed fracture ends. Additional patient data were gathered from the final follow-up time records, including total number of X-rays, clinical visits, and complications.

Compartment syndrome (CS), venous thromboembolic events (VTE), and respiratory infections (RI) were checked from hospital records. Postoperative complications were defined as follows [3] , [6] : (1) delayed union: union over 6 months;

(2) non-union: union after 9 months or union with an additional procedure; (3) malunion: malalignment of over 10 degrees in the coronal or sagittal planes and (4) shortening of over 10 mm.

Data are presented as average and standard deviation; count and percentages are used appropriately. The ANOVA or Kruskal-Wallis tests were used for the comparison of continuous parametric variables between the 2 groups according to the homogeneity test of variances. The Pearson's chi-squared test or Yates continuity correction were used for dichotomous variables. A P value less than 0.05 was considered statistically significant. Lastly, SPSS v.23 was utilized to perform analysis (SPSS Inc., Chicago, IL).

Out of the 186 patients who were included in the study, 122 were treated with EIN, and 64 were treated with CST. The treatment decision was made by the orthopaedic surgeon based on the following; injury X-ray films, technical experience, personal circumstances of the patients, and their treatment attempts. Furthermore, the average age, weight, and gender of the patients in both the EIN and CST groups were shown in demographic data (Table 1) , which revealed no difference between the groups with respect to age and gender (P > 0.05). However, the weight and injury data showed some differences between the 2 groups (P < 0.001). Patients in the EIN group were heavier and had lower energy mechanisms of injury. This might be because of their older ages and higher alertness.

Fracture characteristics and alignment data of each cohort are summarized in Table 2 . We observed a significant difference in the distribution of the fracture classification (P = 0.003). There was a higher percentage of the simple transverse fracture (32.8% vs. 15.6%), while that of the multifragmentary oblique/spiral fracture was lower (6.2% vs. 25.4%) in the CST group. Patients treated with EIN had significantly more midshaft tibial fractures and associated fibula fractures (67.2% vs.

25% and 95.1% vs. 75%, P < 0.001). No other differences were noted between the groups with respect to the angulation, shortening, and displacement of fractures.

Patients in the EIN group who stayed in hospital for 6.5±3.8 days had a mean surgical time of 72.5±34.6 minutes. All patients were casted on average for 31.7±19.0 days. Some had their cast replaced with an external brace because of its convenience and portability. Furthermore, they had clinical followed-ups 7.4±2.8 times and received postoperative X-rays 6.9±1.9 times until the fractures healed every 1-2 weeks. After 65.0±22.6 days, patients were encouraged to perform some proper exercises and allowed to bear weight 79.8±22.6 days later. All fractures healed with a mean time of 68.5±17.9 days, and the EIN was removed 149.7±26.7 days after surgery (Table 3 ).

In the healing radiographic assessment, patients had achieved mean alignment with 2.9±2.2 degrees in the coronal plane and 2.9±2.0 degrees in the sagittal plane.

Furthermore, the EIN procedure corrected 3.5±5.9 and 3.1±3.7 degrees in the coronal and the sagittal planes respectively. The mean cost of both hospitalization and treatment was 20435.6±5631.9 RMB.

For patients in the CST group, their mean surgical time was 22.8±11.5 minutes, and they stayed in hospital for a mean time of 26.9±8.4 days. All patients in the CST group were casted on average for 43.0±20.9 days and afterwards, the cast was replaced with a removable brace. They had fewer clinical visits than patients in the EIN group (3.0±1.4 times, p < 0.001); however, the total X-rays in both groups were similar (7.3±1.6 times, P = 0.157). After 78.7±20.6 days, patients were encouraged to start exercising and allowed to begin weight-bearing at 98.0±20.6 days. As a result, all fractures healed with a mean time of 69.6±15.9 days. The films of the healed fractures showed that the average angulations were 2.6±1.8 degrees in the coronal plane and 2.8±2.2 degrees in the sagittal plane, with mean shortening of 0.7±1.5 mm. Moreover, the changes in angulation in the coronal and the sagittal planes were 5.2±5.7 and 3.4±3.4 degrees respectively, and shortening was improved by 2.6±2.3mm.

After surgery, 2 patients (1.6%) in the EIN group who developed compartment syndrome, which was reported to be 2% and 4.5% [5, 6] , were cured by conservative treatment and subsequently neither of them had further complications. In addition, 1 patient had a respiratory infection. There were 28 healed patients (23%) with mild malalignment (5-10 degrees). Malunion occurred in 1 patient (0.8%); a 5-year-old girl with a fractured distal tibia and fibula from a vehicular collision. The preoperative angulations were 12.2 degrees valgus and 8.1 degrees procurvatum, with 1.8 mm shortening and 2.1 mm displacement. After surgery, she still had a 13.0 degrees valgus and 6.0 degrees procurvatum deformity until the fracture union. However, with the persistent correction of the EIN, she finally achieved acceptable alignment without an additional operation, and the nails were removed uneventfully 223 days after surgery.

In the CST group, 3 patients (4.6%) had early stage compartment syndrome after surgery. However, without external pressure, they were soon cured by medications. All patients returned to their activities without symptomatic complications at the final clinical visit. Although some cases had muscle weakness, the range of motion of the injured limb was nearly normal.

While comparing the EIN group with the CST group, the surgical time for CST was approximately 50 minutes faster than that for EIN (P < 0.001). However, patients needed approximately 20 days more in hospital for traction (P < 0.001). The EIN group required an approximate 2 weeks immobilization (P < 0.001) and had 4 times more clinical visits (P < 0.001). In addition, although there were no significant differences in union time between the groups, the EIN group began functional exercises and weight-bearing 12 days earlier (P < 0.001). For the alignment outcomes, no significant difference was observed in sagittal angulation and shortening changes between both groups. However, the CST group tended towards more coronal angulation corrections (P = 0.063). Considering the cost, the mean treatment expenses of the EIN was more than twice the CST cost (P < 0.001).

To date, this is the first and largest study that compares the outcomes of EIN with CST for the treatment of displaced tibial shaft fractures in a Chinese population.

There were noticeable significant differences in the mechanism of injury and fracture characteristics between the two groups. In the EIN group, the incidence of low-energy injuries was higher (56.6%) than in the CST group, and the fracture types were mainly simple oblique and spiral fractures (55.7%), followed by multifragmentary spiral and oblique fractures (25.4%). Midshaft fracture accounted for about 67.2% of cases.

However, in the CST group, the proportion of high-energy injuries was higher (68.8%). Simple oblique or spiral fractures (56.3%) were also the most common type of fracture, followed by simple transverse fractures (32.8%). Distal tibia fractures accounted for 75% of cases.

We thought the differences were because the ideal patients for EIN were those with transverse, length-stable, midshaft tibial fractures [2] , while traction was more suitable for patients with high risks of unacceptable shortening, which was more likely in children older than 6 years or in children with high-energy injuries [7] . The surgeon considers these factors when choosing the appropriate treatment modality.

Hence, the EIN group comprised patients with midshaft fractures due to low-energy injuries, and low-energy injuries are more likely to lead to oblique and spiral fractures because of the mechanisms of applied force [8] . The CST group mainly consisted of distal tibial fractures due to high-energy injuries. In addition to simple oblique and spiral fractures, high-energy direct trauma was more likely to lead to transverse fractures [8] . Concerning the weight and age of the patients, previous studies confirmed that poor outcomes of EIN were associated with increasing age and higher body mass index [9] . Finally, regarding parents' concerns and expectations, the risks and benefits of treatment should be discussed with the parents to allay their fears [7] .

However, the surgeon's proficiency and experience with each operation also played an important role. This implies that a certain degree of selection bias existed. Therefore, the differences between the two groups were inevitable.

Predictably this study showed that both approaches provided satisfactory outcomes. However, we noted the different advantages and disadvantages of each procedure. Patients in the EIN group had a shorter stay in hospital, and began functional exercises and weight-bearing earlier than subjects in the CST group. This was probably because the effective internal fixation provided patients a faster recovery of motion than the isolated external fixation. In addition, early weight-bearing was probably beneficial for patients with transverse tibial shaft fractures that were treated by EIN [10] . Some studies report that tibial shaft fractures can be treated successfully without cast immobilization [11] , [12] . However, patients incurred higher expenses, had more clinical visits, and underwent 2 surgeries under general anaesthesia simultaneously. Prior to this study, we thought that CST would be better than EIN in the shortening correction. However, gaps between the fracture showed up in some of the postoperative X-ray films in the EIN group. This could be because the nail pushed the distal fracture site away when the surgeon placed it and reversed the shortening. Hence, surgeons need to pay attention to this and check the EIN location by intraoperative radiography to prevent excessive lengthening.

EIN has always been a straightforward and effective internal fixation method for long bone fractures in children since Ligier, et al. [13] initial report from France. This is now known as "the gift from god to children" in China. Since then, the scope of treatment with EIN is wider than before. Research has shown that EIN can be used for femoral shaft fractures in patients who are 2 years old to school-age, who weigh a maximum of 50 kg [14] , [15] . The EIN technique is also reliable for tibia fractures in patients younger than 16 years who weigh between 21 to 122 kg [9] . However, EIN has potential disadvantages that may be unacceptable to the general Chinese population. The disadvantages of EIN which make it less appealing to parents are as follows; the second surgery under is general anaesthesia, hospitalization of children for nail removal, more time commitment, and higher expenses. Besides, meta-analysis conducted by Stenroos, et al. [16] showed that patients treated with EIN had a higher incidence of complications than those conservatively treated (24% vs. 9%).

Additionally, after spending a lot of time and money, it is difficult for parents to accept complications or extra operations which are inevitable during the process.

Similarly, most pediatric orthopaedists at our centre are not willing to take treatment failure risks because of the heavy workload and strained patient-doctor relationship with Chinese doctors [17] . Consequently, these factors make CST another good option for the treatment of displaced tibial shaft fractures.

CST is a incision-free treatment with a shorter surgical time, a wide range of indications, and is more economical. Additionally, this procedure can be done under spinal anaesthesia in older compliable children. Although the CST procedure is simple, some complications may arise. If the pin goes in too deep, there could be damage to the posterior tibial artery. In addition, if traction tends outwards, recurvatum may occur as exemplified by the patient with malunion in the CST group. Although the CST costs longer hospitalization, it can significantly maintain the alignment persistently to avoid shortening and malunion, without affecting the union time. If a procedure achieves better alignment, then longer immobilization is not a shortcoming of a treatment. This is because correcting a malunion is harder than regaining motility of a limb in children 2 . Additionally, when the patient is transferred to a cast after traction, the fracture would have begun to heal. Consequently the casting time of CST was 2 weeks shorter than that of EIN, which decreased casting related problems and shortened the uncomfortable period.

Objectively, several factors play an important role in determining the treatment of DTSF at our centre. Firstly, the cost of treatment is always a crucial problem compared to developing countries. Most patients without medical insurance are more likely to choose a more economic treatment even if it would cost them more time.

Secondly, the number of emergency patients who need surgery. As the only paediatric specialized hospital in this area, we may receive 7 trauma cases on average in a single day. This may increase up to 20 during summer vacation. Therefore, we must treat them as efficiently as possible if many operations are required, because more emergency patients could come the following day.

An unfortunate but valuable case in the EIN group should be discussed. There are several limitations to this study. First is the nature of the retrospective study for which data were collected and reviewed. Additionally, patients were followed up only for 6 months or until radiographic healing. Thus, the long-term outcome measures are not included. Finally, the initial treatment method was determined by the emergency surgeon who decided to admit the patient, and the senior orthopaedic surgeon in the ward who actually managed each case depending on their experience. It is difficult to account for surgeon bias to determine why each of the treatment approaches were selected. Furthermore, the decision could be influenced by considering the different expectations and economic capabilities of the guardians.

However, those would be perhaps more reflective of actual clinical practice.

This study revealed that both procedures have acceptable clinical and radiographical results at final follow-up. However, each procedure has its own comparative advantages and favourable conditions. Patients with EIN had shorter hospital stays and faster recovery, which complies with the concept of enhanced recovery after surgery (ERAS). The CST procedure, however, provided a faster surgical time and a slightly better correction of coronal angulation with a lower rate of malalignment and economic costs. Furthermore, the shorter casting time reduced casting related problems and patient's discomfort. Therefore, a variety of factors should be considered when determining the optimal initial intervention for each individual patient, even in different regions. 

What's New in Pediatric Orthopaedic Trauma: The Lower Extremity

Tibial Shaft Fractures in Children and Adolescents

AO Pediatric Classification Group. Fracture and dislocation classification compendium for children: the AO pediatric comprehensive classification of long bone fractures (PCCF)

Titanium elastic nails for pediatric femur fractures: a multicenter study of early results with analysis of complications

Operative Versus Conservative Management of Displaced Tibial Shaft Fracture in Adolescents

Elastic Intramedullary Nailing Versus Open Reduction Internal Fixation of Pediatric Tibial Shaft Fractures

Management of pediatric femoral shaft fractures

Pediatric tibia fractures: current concepts

Titanium Elastic Nailing for Pediatric Tibia Fractures: Do Older, Heavier Kids Do Worse?

Treatment of Unstable Pediatric Tibia Shaft Fractures in Finland

Elastic stable intramedullary nailing of tibial shaft fractures in children

Displaced tibia shaft fractures in children treated by elastic stable intramedullary nailing: results and complications in children weighing 50 kg (110 lb) or more

Closed flexible medullary nailing in paediatric traumatology

Titanium elastic nailing of fractures of the femur in children: predictors of complications and poor outcome

Decreased complications of pediatric femur fractures with a change in management

Treatment of Closed Tibia Shaft Fractures in Children: A Systematic Review and Meta-Analysis

Workplace violence, psychological stress, sleep quality and subjective health in Chinese doctors: a large cross-sectional study

We would like to express gratitude to all the patients and their families. We also acknowledge the Radiology Department of our hospital for providing support, and colleague Ting Cai for statistical analysis.