Zhang Lei, Wang Junqiu, Li Wen, Xia Yu
Department of Orthopedics, the Affiliated Traditional Chinese Medicine Hospital, Southwest Medical University, Luzhou Sichuan, 646000, P. R. China.
Luzhou Key Laboratory of Orthopedic Disorders, Luzhou Sichuan, 646000, P. R. China.
Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2025 Mar 15;39(3):271-277. doi: 10.7507/1002-1892.202501012.
To investigate the correlation between the anterior talofibular ligament (ATFL) injury and the pathological changes of the anterior tibiotalar fat pad (ATFP) based on MRI.
The clinical and imaging data of 217 patients with ankle sprain who met the selection criteria between January 2019 and March 2024 were retrospectively analyzed. There were 113 males and 104 females with an average age of 38.2 years ranging from 18 to 60 years. Patients were divided into mild group ( =106), moderate group ( =63), and severe group ( =48) according to the degree of ATFL injury. There was no significant difference in gender, side, and body mass index among the 3 groups ( >0.05). The age of the mild group was significantly older than that of the moderate and severe groups ( <0.05). The imaging parameters including the longest and shortest sagittal axis, the largest thickness, the longest and shortest transverse axis, the ATFP area, the area of ATFP high-signal region, and the anterior distal tibial angle (ADTA) were measured according to the MRI and X-ray films of patients. According to the morphology of ATFP, the patients were divided into type Ⅰ ( =128), type Ⅱ ( =73), and type Ⅲ ( =16) based on the severity of the lesions. The distribution of ATFP types, ATFP area, area of ATFP high-signal region, and the ratio of area of ATFP high-signal region to ATFP area at the same level were statistically analyzed and compared among different ATFL injury groups. Additionally, radiographic parameters were compared across different ATFP types. Spearman rank correlation analysis was used to assess the relationships between ATFP area, area of ATFP high-signal region, and the ratio of area of ATFP high-signal region to ATFP area at the same level with patient baseline data. Through analysis of the area under curve (AUC) of ROC, optimal variables were selected for quantification to predict ATFL injury.
There were significant differences in ATFP types among different ATFL injury groups ( <0.05). The mild group had a higher proportion of type Ⅰ, the moderate group had a higher proportion of type Ⅱ, and the severe group had higher proportions of both typeⅡ and type Ⅲ. No significant difference was found in ATFP area among the different ATFL injury groups ( >0.05). However, the area of ATFP high-signal region and the ratio of area of ATFP high-signal region to ATFP area at the same level were significantly lower in the mild group compared to the moderate and severe groups ( <0.05). Except for the longest sagittal axis, maximum thickness, and longest transverse axis, which were significantly smaller in ATFP types Ⅱ and Ⅲ compared to type Ⅰ ( <0.05), there was no significant difference in the remaining radiographic parameters among the different ATFP types ( >0.05). Spearman rank correlation analysis revealed that ATFP area was negatively correlated with patient gender ( <0.05), while area of ATFP high-signal region and the ratio of area of ATFP high-signal region to ATFP area at the same level were negatively correlated with patient age ( <0.05). Through analysis of the AUC for the response variable ATFP injury, the combined diagnostic AUC of ROC for the reciprocal of the maximum thickness and the reciprocal of the area of ATFP high-signal region was 0.839 (asymptotic <0.001). The corresponding cutoff value when the Youden index reached its maximum was 0.570 3.
As the severity of ATFL injury increases, the ATFP undergoes gradual morphological and functional changes. Classification based on ATFP types can assist in assessing the level of ATFL injury, thereby aiding in the prevention of post-traumatic osteoarthritis.
基于磁共振成像(MRI)研究距腓前韧带(ATFL)损伤与胫距前脂肪垫(ATFP)病理变化之间的相关性。
回顾性分析2019年1月至2024年3月期间符合入选标准的217例踝关节扭伤患者的临床和影像资料。其中男性113例,女性104例,平均年龄38.2岁,年龄范围为18至60岁。根据ATFL损伤程度将患者分为轻度组(n = 106)、中度组(n = 63)和重度组(n = 48)。三组患者在性别、患侧及体重指数方面差异无统计学意义(P>0.05)。轻度组患者年龄显著高于中度组和重度组(P<0.05)。根据患者的MRI和X线片测量影像参数,包括矢状轴最长和最短值、最大厚度、横轴最长和最短值、ATFP面积、ATFP高信号区面积以及胫距关节前远端角(ADTA)。根据ATFP形态,依据病变严重程度将患者分为Ⅰ型(n = 128)、Ⅱ型(n = 73)和Ⅲ型(n = 16)。对不同ATFL损伤组之间ATFP类型分布、ATFP面积、ATFP高信号区面积以及同一水平ATFP高信号区面积与ATFP面积之比进行统计学分析和比较。此外,比较不同ATFP类型之间的影像学参数。采用Spearman等级相关分析评估ATFP面积、ATFP高信号区面积以及同一水平ATFP高信号区面积与ATFP面积之比与患者基线数据之间的关系。通过分析ROC曲线下面积(AUC),选择最佳变量进行量化以预测ATFL损伤。
不同ATFL损伤组之间ATFP类型存在显著差异(P<0.05)。轻度组Ⅰ型比例较高,中度组Ⅱ型比例较高,重度组Ⅱ型和Ⅲ型比例均较高。不同ATFL损伤组之间ATFP面积差异无统计学意义(P>0.05)。然而,与中度组和重度组相比,轻度组ATFP高信号区面积以及同一水平ATFP高信号区面积与ATFP面积之比显著更低(P<0.05)。除了Ⅱ型和Ⅲ型ATFP的矢状轴最长值、最大厚度和横轴最长值显著小于Ⅰ型(P<0.05)外,不同ATFP类型之间其余影像学参数差异无统计学意义(P>0.05)。Spearman等级相关分析显示,ATFP面积与患者性别呈负相关(P<0.05),而ATFP高信号区面积以及同一水平ATFP高信号区面积与ATFP面积之比与患者年龄呈负相关(P<0.05)。通过对反应变量ATFP损伤的AUC分析,最大厚度倒数和ATFP高信号区面积倒数的联合诊断ROC曲线下面积为0.839(渐近P<0.001)。约登指数达到最大值时的相应截断值为0.570 3。
随着ATFL损伤严重程度增加,ATFP发生逐渐的形态和功能改变。基于ATFP类型的分类有助于评估ATFL损伤程度,从而有助于预防创伤后骨关节炎。
