Department of Biomedical Engineering, Tufts University, Medford, MA 02155, USA.
Proc Natl Acad Sci U S A. 2013 Apr 16;110(16):6370-5. doi: 10.1073/pnas.1300135110. Epub 2013 Apr 1.
Tendons have uniquely high tensile strength, critical to their function to transfer force from muscle to bone. When injured, their innate healing response results in aberrant matrix organization and functional properties. Efforts to regenerate tendon are challenged by limited understanding of its normal development. Consequently, there are few known markers to assess tendon formation and parameters to design tissue engineering scaffolds. We profiled mechanical and biological properties of embryonic tendon and demonstrated functional properties of developing tendon are not wholly reflected by protein expression and tissue morphology. Using force volume-atomic force microscopy, we found that nano- and microscale tendon elastic moduli increase nonlinearly and become increasingly spatially heterogeneous during embryonic development. When we analyzed potential biochemical contributors to modulus, we found statistically significant but weak correlation between elastic modulus and collagen content, and no correlation with DNA or glycosaminoglycan content, indicating there are additional contributors to mechanical properties. To investigate collagen cross-linking as a potential contributor, we inhibited lysyl oxidase-mediated collagen cross-linking, which significantly reduced tendon elastic modulus without affecting collagen morphology or DNA, glycosaminoglycan, and collagen content. This suggests that lysyl oxidase-mediated cross-linking plays a significant role in the development of embryonic tendon functional properties and demonstrates that changes in cross-links alter mechanical properties without affecting matrix content and organization. Taken together, these data demonstrate the importance of functional markers to assess tendon development and provide a profile of tenogenic mechanical properties that may be implemented in tissue engineering scaffold design to mechanoregulate new tendon regeneration.
肌腱具有独特的高强度拉伸能力,这对其将肌肉力量传递到骨骼的功能至关重要。当肌腱受伤时,其内在的愈合反应会导致基质组织异常和功能特性改变。肌腱再生的努力受到对其正常发育有限理解的挑战。因此,几乎没有已知的标志物来评估肌腱形成,也没有参数来设计组织工程支架。我们分析了胚胎肌腱的力学和生物学特性,并证明了发育中肌腱的功能特性不能完全反映在蛋白质表达和组织形态上。使用力体积原子力显微镜,我们发现纳米和微尺度肌腱弹性模量在胚胎发育过程中呈非线性增加,并变得越来越具有空间异质性。当我们分析潜在的生化因素对模量的影响时,我们发现弹性模量与胶原蛋白含量之间存在统计学上显著但较弱的相关性,与 DNA 或糖胺聚糖含量之间没有相关性,表明存在其他因素对机械性能有贡献。为了研究胶原交联作为潜在的贡献因素,我们抑制赖氨酰氧化酶介导的胶原交联,这显著降低了肌腱的弹性模量,而不影响胶原形态或 DNA、糖胺聚糖和胶原蛋白含量。这表明赖氨酰氧化酶介导的交联在胚胎肌腱功能特性的发育中起着重要作用,并表明交联的变化会改变机械性能,而不影响基质的含量和组织。总之,这些数据表明功能标志物对于评估肌腱发育的重要性,并提供了可能在组织工程支架设计中实施的肌腱机械性能特征,以机械调节新的肌腱再生。