Is Nonoperative Treatment Appropriate for All Patients With Type 1 Tibial Spine Fractures? A Multicenter Study of the Tibial Spine Research Interest Group.

Background: Type 1 tibial spine fractures are nondisplaced or ≤2 mm-displaced fractures of the tibial eminence and anterior cruciate ligament (ACL) insertion that are traditionally managed nonoperatively with immobilization. Hypothesis: Type 1 fractures do not carry a significant risk of associated injuries and therefore do not require advanced imaging or additional interventions aside from immobilization. Study Design: Case series; Level of evidence, 4. Methods: We reviewed 52 patients who were classified by their treating institution with type 1 tibial spine fractures. Patients aged ≤18 years with pretreatment plain radiographs and ≤ 1 year of follow-up were included. Pretreatment imaging was reviewed by 4 authors to assess classification agreement among the treating institutions. Patients were categorized into 2 groups to ensure that outcomes represented classic type 1 fracture patterns. Any patient with universal agreement among the 4 authors that the fracture did not appear consistent with a type 1 classification were assigned to the type 1+ (T1+) group; all other patients were assigned to the true type 1 (TT1) group. We evaluated the rates of pretreatment imaging, concomitant injuries, and need for operative interventions as well as treatment outcomes overall and for each group independently. Results: A total of 48 patients met inclusion criteria; 40 were in the TT1 group, while 8 were in the T1+ group, indicating less than universal agreement in the classification of these fractures. Overall, 12 (25%) underwent surgical treatment, and 12 (25%) had concomitant injuries. Also, 8 patients required additional surgical management including ACL reconstruction (n = 4), lateral meniscal repair (n = 2), lateral meniscectomy (n = 1), freeing an incarcerated medial meniscus (n = 1), and medial meniscectomy (n = 1). Conclusion: The classification of type 1 fractures can be challenging. Contrary to prior thought, a substantial number of patients with these fractures (>20%) were found to have concomitant injuries. Overall, surgical management was performed in 25% of patients in our cohort.

A Multicenter Comparison of Open Versus Arthroscopic Fixation for Pediatric Tibial Spine Fractures.

BACKGROUND: When operative treatment is indicated, tibial spine fractures can be successfully managed with open or arthroscopic reduction and internal fixation (ARIF). The purpose of the study is to evaluate short-term treatment outcomes of tibial spine fractures in patients treated with both open and arthroscopic fracture reduction. METHODS: We performed an Institutional Review Board (IRB)-approved retrospective cohort study of pediatric tibial spine fractures presenting between January 1, 2000 and January 31, 2019 at 10 institutions. Patients were categorized into 2 cohorts based on treatment: ARIF and open reduction and internal fixation (ORIF). Short-term surgical outcomes, the incidence of concomitant injuries, and surgeon demographics were compared between groups. RESULTS: There were 477 patients with tibial spine fractures who met inclusion criteria, 420 of whom (88.1%) were treated with ARIF, while 57 (11.9%) were treated with ORIF. Average follow-up was 1.12 years. Patients treated with ARIF were more likely to have an identified concomitant injury (41.4%) compared with those treated with ORIF (24.6%, P=0.021). Most concomitant injuries (74.5%) were treated with intervention. The most common treatment complications included arthrofibrosis (6.9% in ARIF patients, 7.0% in ORIF patients, P=1.00) and subsequent anterior cruciate ligament injury (2.1% in ARIF patients and 3.5% in ORIF, P=0.86). The rate of short-term complications, return to the operating room, and failure to return to full range of motion were similar between treatment groups. Twenty surgeons with sports subspecialty training completed 85.0% of ARIF cases; the remaining 15.0% were performed by 12 surgeons without additional sports training. The majority (56.1%) of ORIF cases were completed by 14 surgeons without sports subspecialty training. CONCLUSION: This study demonstrated no difference in outcomes or nonunion following ARIF or ORIF, with a significantly higher rate of concomitant injuries identified in patients treated with ARIF. The majority of identified concomitant injuries were treated with surgical intervention. Extensive surgical evaluation or pretreatment magnetic resonance imaging should be considered in the workup of tibial spine fractures to increase concomitant injury identification. LEVEL OF EVIDENCE: Level III.

Tibial Spine Fractures: How Much Are We Missing Without Pretreatment Advanced Imaging? A Multicenter Study.

BACKGROUND: There is a high rate of concomitant injuries reported in pediatric patients with tibial spine fractures, ranging from 40% to 68.8%. Many tibial spine fractures are treated without initial magnetic resonance imaging (MRI). PURPOSE: To understand rates of concomitant injury and if the reported rates of these injuries differed among patients with and without pretreatment MRI. STUDY DESIGN: Cross-sectional study; level of evidence, 3. METHODS: We performed an institutional review board-approved multicenter retrospective cohort study of patients treated for tibial spine fractures between January 1, 2000, and January 31, 2019, at 10 institutions. Patients younger than 25 years of age with tibial spine fractures were included. Data were collected on patient characteristics, injury, orthopaedic history, pretreatment physical examination and imaging, and operative findings. We excluded patients with multiple trauma and individuals with additional lower extremity fractures. Patients were categorized into 2 groups: those with and those without pretreatment MRI. The incidence of reported concomitant injuries was then compared between groups. RESULTS: There were 395 patients with a tibial spine fracture who met inclusion criteria, 139 (35%) of whom were reported to have a clinically significant concomitant injury. Characteristics and fracture patterns were similar between groups. Of patients with pretreatment MRI, 79 of 176 (45%) had an identified concomitant injury, whereas only 60 of 219 patients (27%) without pretreatment MRI had a reported concomitant injury (P < .001). There was a higher rate of lateral meniscal tears (P < .001) in patients with pretreatment MRI than in those without. However, there was a higher rate of soft tissue entrapment at the fracture bed (P = .030) in patients without pretreatment MRI. Overall, 121 patients (87%) with a concomitant injury required at least 1 treatment. CONCLUSION: Patients with pretreatment MRI had a statistically significantly higher rate of concomitant injury identified. Pretreatment MRI should be considered in the evaluation of tibial spine fractures to improve the identification of concomitant injuries, especially in patients who may otherwise be treated nonoperatively or with closed reduction. Further studies are necessary to refine the indications for MRI in patients with tibial spine fractures, determine the characteristics of patients at highest risk of having a concomitant injury, define the sensitivity and specificity of MRI in tibial spine fractures, and investigate patient outcomes based on pretreatment MRI status.

Surgical site infection prevention protocol for pediatric spinal deformity surgery: does it make a difference?

STUDY DESIGN: Retrospective. OBJECTIVE: Can a standardized, hospital-wide care bundle decrease surgical site infection (SSI) rate in pediatric spinal deformity surgery? SSI is a major concern in pediatric spinal deformity surgery. METHODS: We performed a retrospective review of our primary scoliosis surgeries between 1999 and 2017. In 2008, we implemented a standardized infection reduction bundle. Interventions included preoperative nares screening for methicillin-resistant staphylococcus aureus or methicillin-sensitive Staphylococcus aureus 2 weeks preoperatively, and treatment with intranasal mupirocin when positive, a bath or shower the night before surgery, a preoperative chlorohexidine scrub, timing of standardized antibiotic administration, standardized intraoperative re-dosing of antibiotics, limiting operating room traffic, and standardized postoperative wound care. In 2011, we added intrawound vancomycin powder at wound closure. Our inclusion criteria were patients 21 years of age or less with idiopathic, neuromuscular, syndromic, or congenital scoliosis who had a primary spinal fusion or a same day anterior and posterior spine fusion with segmental spinal instrumentation of six levels or more. We compared the incidence of early (within 90 days of surgery) and late (> 91 days) SSI during the first postoperative year. RESULTS: There were 804 patients who met inclusion criteria: 404 in the non-bundle group (NBG) for cases prior to protocol change and 400 in the bundle group (BG) for cases after the protocol change. Postoperatively, there were 29 infections (7.2% of total cases) in the NBG: 9 early (2.2%) and 20 late (5.0%) while in the BG there were only 10 infection (2.5%): 6 early (1.5%) and 4 late (1.0%). The reduction in overall SSIs was statistically significant (p = 0.01). There was a trend toward decreased early infections in the BG, without reaching statistical significance (p = 0.14). CONCLUSION: Standardized care bundles appear effective in reducing the incidence of postoperative pediatric spine SSIs. LEVEL OF EVIDENCE: Level III.