Université Catholique de Louvain (UCLouvain)-Institut de Recherche Expérimentale et Clinique (IREC), Neuromusculoskeletal Lab (NMSK), Brussels, Belgium.
Department of Orthopaedic and Trauma Surgery, Cliniques universitaires Saint-Luc, Brussels, Belgium.
J Anat. 2024 Nov;245(5):725-739. doi: 10.1111/joa.14125. Epub 2024 Aug 30.
The fascial system has gained recognition for its integral role in connecting skin, superficial and deep fasciae, and underlying muscles. However, consensus on its microstructure depending on its topography remains elusive as well as its implications in clinical practices, such as reconstructive surgery and physiotherapy techniques. This study focuses on the iliotibial tract (ITT) implicated in the iliotibial band syndrome. The goal is to describe microstructural characteristics using classical 2D histology and cryogenic contrast-enhanced microcomputed tomography (cryo-CECT) such as the total thickness, number of layers, layer thickness, fibre orientation and tortuosity, according to the specific topography. The total thickness of the ITT varied across topographic regions, with the superior part being on average thicker but non-significantly different from the other regions. The inferior part showed heterogeneity, with the anterior region (AI) being the thinnest and the posterior one (PI) the thickest. The ITT exhibited 1-3 layers, with no significant differences among regions. Most commonly, it consisted of two layers, except for the antero-superior (AS) and antero-middle (AM) regions, which sometimes had only one layer. The posterior regions frequently had 2 or 3 layers, with the PI region having the highest mean (2.7 layers). The intermediate layer was the thickest one, varying from the AI region (0.368 mm ± 0.114) to the PI region (0.640 mm ± 0.305). The superficial layer showed regional variability, with the AS region being the thinnest. The deep layer appeared thinner than the superficial one. Fibre orientation analysis indicated that the intermediate layer mainly consisted of oblique longitudinal fibres, orientated downward and forward, while the superficial and deep layers had transversal or oblique transversal fibres. Cryo-CECT 3D observations confirmed these findings, revealing distinct orientations for different layers. Fibre tortuosity exhibited differences based on orientation. Transversal fibres (>65°) were significantly less tortuous than longitudinal fibres (<25°) and oblique intermediate fibres (25°-65°), aligning with 3D plot observations. This quantitative study highlights various microstructural characteristics of the ITT, offering insights into its regional variations. The analysis accuracy is increased due to the novel technology of cryo-CECT which emerges as a valuable tool for precise assessment of 3D fibre orientation and tortuosity. These findings contribute to a deeper understanding of the ITT structure, useful in clinical practices, such as reconstructive surgery and physiotherapy, and future research endeavours.
筋膜系统因其在连接皮肤、浅筋膜和深筋膜以及下面的肌肉方面的整体作用而受到认可。然而,其微观结构取决于其拓扑结构的共识以及其在临床实践中的影响,如重建手术和物理治疗技术,仍然难以捉摸。本研究集中在与髂胫束综合征有关的髂胫束(ITT)。目的是使用经典的 2D 组织学和冷冻对比增强微计算机断层扫描(cryo-CECT)来描述微观结构特征,根据特定的地形,包括总厚度、层数、层厚度、纤维方向和扭曲度。ITT 的总厚度在不同的地形区域有所不同,上部分的平均厚度较厚,但与其他区域无显著差异。下部分表现出异质性,前区(AI)最薄,后区(PI)最厚。ITT 显示 1-3 层,各区域之间无显著差异。最常见的是,它由两层组成,除了前上(AS)和前中(AM)区域,这些区域有时只有一层。后区通常有 2 层或 3 层,PI 区的平均层数最高(2.7 层)。中间层是最厚的一层,从 AI 区(0.368mm±0.114)到 PI 区(0.640mm±0.305)逐渐变厚。浅层表现出区域性变异性,AS 区最薄。深层比浅层更薄。纤维方向分析表明,中间层主要由向下和向前倾斜的斜向纵向纤维组成,而浅层和深层有横向或斜向横向纤维。Cryo-CECT 3D 观察结果证实了这些发现,显示出不同层的不同方向。纤维扭曲度根据方向而有所不同。横向纤维(>65°)明显比纵向纤维(<25°)和斜向中间纤维(25°-65°)扭曲度小,与 3D 图谱观察结果一致。这项定量研究强调了 ITT 的各种微观结构特征,深入了解其区域变化。由于 cryo-CECT 的新技术的出现,分析精度得到了提高,该技术成为评估 3D 纤维方向和扭曲度的精确工具。这些发现有助于加深对 ITT 结构的理解,在临床实践中如重建手术和物理治疗以及未来的研究工作中非常有用。
