Trinity Centre for Bioengineering, Trinity College Dublin, Dublin, Ireland; School of Engineering, Trinity College Dublin, Dublin, Ireland.
Trinity Centre for Bioengineering, Trinity College Dublin, Dublin, Ireland; School of Engineering, Trinity College Dublin, Dublin, Ireland.
J Mech Behav Biomed Mater. 2017 Nov;75:359-368. doi: 10.1016/j.jmbbm.2017.07.036. Epub 2017 Jul 25.
The collagen fibre architecture of arterial tissue is known to play a key role in its resultant mechanical behaviour, while maladaptive remodelling of this architecture may be linked to disease. Many of the techniques currently used to analyse collagen fibre architecture require time consuming tissue preparation procedures and are destructive in nature. The aim of this study is to fully explore Small Angle Light Scattering (SALS) as a means to non-destructively assess collagen fibre architecture in arterial tissue and subsequently gain insights into load induced reorientation. The optimised configuration of the SALS system for arterial tissue was determined using quantitative comparisons to histological analyses of porcine carotid artery as its basis. Once established, layer specific fibre orientation and the influence of tissue loading was determined for thin sections of carotid artery using SALS. This process was subsequently repeated for intact carotid artery layers. A single family of circumferentially orientated collagen fibres were found in the intima (- 0.1 ± 1.4° (5.5°)) and media (- 1.7 ± 1.9° (4.7°)) while two perpendicular families of fibres were identified in the adventitia (- 6.4 ± 0.7° (37.7°)) and (118.3 ± 2.7 (39.9°)). An increase in fibre alignment in response to a 20% circumferential strain was also identified using SALS, characterised by an increase in scattered light eccentricity.
determined using SALS agreed with those found using traditional destructive techniques, however SALS has the important benefits of allowing vessel layers to remain intact, and has a fast processing time. SALS unique ability to identify load induced reorganisation in intact arterial layers offers an efficient means to gain crucial insights into arterial disease and its development over time.
动脉组织的胶原纤维结构已知在其产生的机械行为中起着关键作用,而这种结构的适应性重塑可能与疾病有关。目前许多用于分析胶原纤维结构的技术都需要耗时的组织准备程序,并且具有破坏性。本研究的目的是充分探索小角光散射(SALS)作为一种非破坏性评估动脉组织中胶原纤维结构的方法,并随后深入了解负载诱导的重新取向。使用 SALS 对猪颈动脉进行组织学分析作为基础,对 SALS 系统进行了定量比较,以确定其优化配置。一旦建立,就使用 SALS 确定颈动脉薄片的层特异性纤维取向和组织加载的影响。然后对完整的颈动脉层重复此过程。在血管内膜中发现了一组单一的圆周取向胶原纤维(-0.1±1.4°(5.5°))和中膜(-1.7±1.9°(4.7°)),而在血管外膜中发现了两组相互垂直的纤维(-6.4±0.7°(37.7°))和(118.3±2.7°(39.9°))。使用 SALS 还确定了对 20%周向应变的纤维取向增加,其特征在于散射光偏心率增加。
使用 SALS 确定的结果与使用传统破坏性技术的结果一致,但是 SALS 具有允许血管层保持完整的重要优点,并且具有快速的处理时间。SALS 独特的能力可以识别完整动脉层中的负载诱导重组,为深入了解动脉疾病及其随时间的发展提供了一种有效的方法。
