BioSpectroscopie Translationnelle, EA 7506, Université de Reims Champagne-Ardenne, UFR de Pharmacie, 51 rue Cognacq-Jay, 51096 Reims cedex, France.
Extracellular Matrix and Cell Dynamics Unit CNRS UMR 7369, Université de Reims Champagne-Ardenne, UFR de Médecine, 51 rue Cognacq-Jay, 51096 Reims cedex, France.
Acta Biomater. 2022 Jan 1;137:64-78. doi: 10.1016/j.actbio.2021.10.020. Epub 2021 Oct 19.
The main propose of this study is to characterize the impact of chronological aging on mechanical, structural, biochemical, and morphological properties of type I collagen. We have developed an original approach combining a stress-strain measurement device with a portable Raman spectrometer to enable simultaneous measurement of Raman spectra during stress vs strain responses of young adult, adult and old rat tail tendon fascicles (RTTFs). Our data showed an increase in all mechanical properties such as Young's modulus, yield strength, and ultimate tensile strength with aging. At the molecular level, Raman data revealed that the most relevant frequency shift was observed at 938 cm in Old RTTFs, which is assigned to the C-C. This suggested a long axis deformation of the peptide chains in Old RTTFs during tensile stress. In addition, the intensity of the band at 872 cm, corresponding to hydroxyproline decreased for young adult RTTFs and increased for the adult ones, while it remained unchanged for Old RTTFs during tensile stress. The amide III band (1242 and 1265 cm) as well as the band ratios I/ I and I / I responses to tensile stress were depending on mechanical phases (toe, elastic and plastic). The quantification of advanced glycation end-products by LC-MS/MS and spectrofluorometry showed an increase in their content with aging. This suggested that the accumulation of such products was correlated to the alterations observed in the mechanical and molecular properties of RTTFs. Analysis of the morphological properties of RTTFs by SHG combined with CT-FIRE software revealed an increase in length and straightness of collagen fibers, whereas their width and wavy fraction decreased. Our integrated study model could be useful to provide additional translational information to monitor progression of diseases related to collagen remodeling in musculoskeletal disorders. STATEMENT OF SIGNIFICANCE: Type I collagen is the major component of the extracellular matrix. Its architectural and structural organization plays an important role in the mechanical properties of many tissues at the physiological and pathological levels. The objective of this work is to develop an integrated approach to bring a new insight on the impact of chronological aging on the structural organization and mechanical properties of type I collagen. We combined a portable Raman spectrometer with a mechanical tensile testing device in order to monitor in real time the changes in the Raman fingerprint of type I collagen fibers during the mechanical stress. Raman spectroscopy allowed the identification of the type I collagen bonds that were affected by mechanical stress in a differential manner with aging.
本研究的主要目的是表征时程老化对 I 型胶原的机械、结构、生化和形态特性的影响。我们开发了一种结合了应变测量装置和便携式拉曼光谱仪的原创方法,以实现在对年轻成年、成年和老年大鼠肌腱束(RTTF)进行力学测试的同时进行拉曼光谱测量。我们的数据显示,随着年龄的增长,所有力学性能如杨氏模量、屈服强度和极限拉伸强度均有所增加。在分子水平上,拉曼数据显示,在老年 RTTF 中,观察到最相关的频率位移在 938cm-1,这归因于 C-C。这表明在拉伸应力下,老年 RTTF 中的肽链长轴发生了变形。此外,在拉伸应力下,对应于羟脯氨酸的 872cm-1 处的带的强度对于年轻成年 RTTF 降低,对于成年 RTTF 增加,而对于老年 RTTF 不变。酰胺 III 带(1242 和 1265cm-1)以及带比 I/I 和 I/I 的响应随拉伸应力而变化取决于力学相(起始、弹性和塑性)。通过 LC-MS/MS 和荧光光谱法对晚期糖基化终产物的定量分析表明,随着年龄的增长,其含量增加。这表明,此类产物的积累与 RTTF 的力学和分子特性的改变有关。通过 SHG 结合 CT-FIRE 软件对 RTTF 的形态特性进行分析表明,胶原纤维的长度和直线度增加,而宽度和波浪部分减少。我们的综合研究模型可用于提供有关监测肌肉骨骼疾病中与胶原重塑相关的疾病进展的额外转化信息。意义声明:I 型胶原是细胞外基质的主要成分。其架构和结构组织在生理和病理水平上对许多组织的力学性能起着重要作用。本工作的目的是开发一种综合方法,以提供对时程老化对 I 型胶原结构组织和力学性能影响的新见解。我们结合了便携式拉曼光谱仪和机械拉伸测试装置,以便实时监测 I 型胶原纤维在机械应力下的拉曼指纹变化。拉曼光谱允许以不同的方式识别受机械应力影响的 I 型胶原键,其方式随年龄而变化。
