能否预测胫骨骨干骨折合并后踝骨折的大小、Hara-guchi 分型和术前移位?
Can we predict size, Haraguchi type and preoperative displacement of posterior malleolar fractures in association with tibial shaft fractures?
机构信息
NYU Langone Orthopedic Hospital, 301 East 17th Street Suite 1402, New York, NY, 10003, USA.
Jamaica Hospital Medical Center, 8900 Van Wyck Expressway, Richmond Hill, NY, 11418, USA.
出版信息
Eur J Orthop Surg Traumatol. 2023 Jul;33(5):1641-1651. doi: 10.1007/s00590-022-03327-7. Epub 2022 Jul 7.
PURPOSE
To (1) determine if any injury characteristics or radiographic parameters of tibial shaft fractures (TSFs) could predict posterior malleolar fracture (PMF) size, and (2) identify characteristics of PMFs that were fixed versus those that were not in a cohort of ipsilateral TSFs that underwent intramedullary nailing.
METHODS
A cross-sectional radiographic study was performed at a single academic institution. Demographic and radiographic parameters of TSFs were recorded, including fracture obliquity angle (FOA) and distance from distal extent of fracture to plafond (DFP). Using CT, the PMFs were evaluated for Haraguchi classification, size measurements, and preoperative displacement. Multivariate regression analysis was used to identify independent predictors of PMF Harachuchi classification, size parameters, and preoperative displacement. Univariate differences between PMF that were fixed and not fixed were identified.
RESULTS
47 (50%) PMF underwent surgical fixation with 47 treated conservatively. There were no demographic differences between groups. Multivariate linear regression demonstrated increasing DFP and high energy injury mechanism as independent variables correlated with plafond surface area involvement, PMF height and width on sagittal CT cuts. Increasing DFP alone was correlated with PMF width on axial CT cuts and extent > 50% into incisura. Haraguchi type II fractures were associated with high energy injury mechanism (OR = 4.2 [95% CI = 1.3-14.5]; p = 0.02). Odds of Haraguchi type 3 fractures increased 9% per increased year of age (OR = 1.09 [95% CI = 1.04-1.16]; p = 0.006) and decreased 13% per 1% increase in relative DFP (OR = 0.87 [95% CI = 0.75-0.98]; p = 0.04).
CONCLUSIONS
An increasing DFP of TSFs and high energy injury mechanism were independent predictors of PMF size, and high energy injury mechanism was also correlated with Haraguchi type II fracture patterns. Increasing age and decreasing DFP of TSFs predict Haraguchi type III PMF patterns. These radiographic parameters should prompt surgeons to plan for fixation in scenarios in which CT scan is not available.
LEVEL OF EVIDENCE
Diagnostic Level III.
目的
(1)确定胫骨骨干骨折(TSF)的任何损伤特征或影像学参数是否可预测后踝骨折(PMF)的大小,以及(2)确定 PMF 固定与未固定的特征,这些特征来自接受髓内钉治疗的同侧 TSF 队列。
方法
在一家学术机构进行了一项横断面影像学研究。记录了 TSF 的人口统计学和影像学参数,包括骨折倾斜角(FOA)和骨折远端至距骨平台的距离(DFP)。使用 CT 评估 PMF 的 Haraguchi 分类、大小测量值和术前移位。采用多元回归分析确定 PMF Harachuchi 分类、大小参数和术前移位的独立预测因素。确定了 PMF 固定与未固定之间的单变量差异。
结果
47 例(50%)PMF 行手术固定,47 例保守治疗。两组之间无统计学差异。多元线性回归显示,DFP 增加和高能损伤机制是与距骨平台表面积受累、PMF 矢状 CT 切面上的高度和宽度相关的独立变量。DFP 单独增加与 PMF 轴位 CT 切面上的宽度和>50%的切迹内宽度相关。Haraguchi Ⅱ型骨折与高能损伤机制相关(OR=4.2[95%CI=1.3-14.5];p=0.02)。Haraguchi Ⅲ型骨折的几率每增加 1 岁增加 9%(OR=1.09[95%CI=1.04-1.16];p=0.006),相对 DFP 增加 1%减少 13%(OR=0.87[95%CI=0.75-0.98];p=0.04)。
结论
TSF 的 DFP 增加和高能损伤机制是 PMF 大小的独立预测因素,高能损伤机制与 Haraguchi Ⅱ型骨折模式也相关。TSF 的年龄增加和 DFP 减少预测 Haraguchi Ⅲ型 PMF 模式。这些影像学参数应提示外科医生在无法进行 CT 扫描的情况下计划进行固定。
证据水平
诊断 III 级。
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