扁平足的形态变化:利用负重 CT 扫描进行三维分析。

IF 2.9 3区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING BMC Medical Imaging Pub Date : 2024-08-19 DOI:10.1186/s12880-024-01396-0
Yuchun Cai, Zhe Zhao, Jianzhang Huang, Zhendong Yu, Manqi Jiang, Shengjie Kang, Xinghong Yuan, Yingying Liu, Xiaoliu Wu, Jun Ouyang, Wencui Li, Lei Qian
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引用次数: 0

摘要

背景:扁平足是一种由复杂的三维(3D)形态变化引起的疾病。以往的研究大多受限于二维射线照片和非负重条件。扁平足的畸形与骨骼的三维形态有关。这些形态变化会影响后足/中足/前足的力线传导,导致进一步的形态改变。由于二维平面轴线忽略了三维结构信息,因此必须结合站立姿势下的定义测量整个足部的三维模型。本研究旨在利用负重 CT(WBCT)的三维测量结果分析扁平足的形态变化:在这项回顾性对比研究中,我们检索了 2021 年 4 月至 2022 年 3 月期间的 CT 数据库。纳入标准如下患者需表现出提示扁平足的临床症状,包括足底内侧区域肿胀疼痛或步态异常,并经临床检查和 CT 或 MRI 放射学检查结果证实。健康参与者必须没有任何足部疾病或影响下肢运动的疾病。在应用排除标准(平足伴有其他足部疾病)后,CT扫描结果(平均年龄=20.9375,SD=16.1)确认符合进一步分析的条件。两组患者在重建的三维模型上的距离、矢状面/横断面/冠状面角度和体积采用t检验进行比较。使用逻辑回归确定扁平足风险因素,然后使用接收器操作特征曲线和提名图进行分析:研究结果验证了扁平足的三维空间位置改变。这些改变包括前足内收、第一跖骨近端下垂、足弓塌陷、中足距骨关节半脱位、小关节内收和外翻、后足距骨内收和跖侧运动,以及前足第一跖骨内收和外翻。
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Morphological changes in flatfoot: a 3D analysis using weight-bearing CT scans.

Background: Flatfoot is a condition resulting from complex three-dimensional (3D) morphological changes. Most Previous studies have been constrained by using two-dimensional radiographs and non-weight-bearing conditions. The deformity in flatfoot is associated with the 3D morphology of the bone. These morphological changes affect the force line conduction of the hindfoot/midfoot/forefoot, leading to further morphological alterations. Given that a two-dimensional plane axis overlooks the 3D structural information, it is essential to measure the 3D model of the entire foot in conjunction with the definition under the standing position. This study aims to analyze the morphological changes in flatfoot using 3D measurements from weight-bearing CT (WBCT).

Method: In this retrospective comparative our CT database was searched between 4-2021 and 3-2022. Following inclusion criteria were used: Patients were required to exhibit clinical symptoms suggestive of flatfoot, including painful swelling of the medial plantar area or abnormal gait, corroborated by clinical examination and confirmatory radiological findings on CT or MRI. Healthy participants were required to be free of any foot diseases or conditions affecting lower limb movement. After applying the exclusion criteria (Flatfoot with other foot diseases), CT scans (mean age = 20.9375, SD = 16.1) confirmed eligible for further analysis. The distance, angle in sagittal/transverse/coronal planes, and volume of the two groups were compared on reconstructed 3D models using the t-test. Logistic regression was used to identify flatfoot risk factors, which were then analyzed using receiver operating characteristic curves and nomogram.

Result: The flatfoot group exhibited significantly lower values for calcaneofibular distance (p = 0.001), sagittal and transverse calcaneal inclination angle (p < 0.001), medial column height (p < 0.001), sagittal talonavicular coverage angle (p < 0.001), and sagittal (p < 0.001) and transverse (p = 0.015) Hibb angle. In contrast, the sagittal lateral talocalcaneal angle (p = 0.013), sagittal (p < 0.001) and transverse (p = 0.004) talocalcaneal angle, transverse talonavicular coverage angle (p < 0.001), coronal Hibb angle (p < 0.001), and sagittal (p < 0.001) and transverse (p = 0.001) Meary's angle were significantly higher in the flatfoot group. The sagittal Hibb angle (B =  - 0.379, OR = 0.684) and medial column height (B =  - 0.990, OR = 0.372) were identified as significant risk factors for acquiring a flatfoot.

Conclusion: The findings validate the 3D spatial position alterations in flatfoot. These include the abduction of the forefoot and prolapse of the first metatarsal proximal, the arch collapsed, subluxation of the talonavicular joint in the midfoot, adduction and valgus of the calcaneus, adduction and plantar ward movement of the talus in the hindfoot, along with the first metatarsal's abduction and dorsiflexion in the forefoot.

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来源期刊
BMC Medical Imaging
BMC Medical Imaging RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
4.60
自引率
3.70%
发文量
198
审稿时长
27 weeks
期刊介绍: BMC Medical Imaging is an open access journal publishing original peer-reviewed research articles in the development, evaluation, and use of imaging techniques and image processing tools to diagnose and manage disease.
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