Abstract
Tensile testing to failure followed by imaging is a simple way of studying the structure-function relationship of connective tissues such as skin, tendon, and ligament. However, interpretation of these datasets is complex due to the hierarchical structures of the tissues spanning six or more orders of magnitude in length scale. Here we present a dataset obtained through the same scheme at the single collagen fibril level, the fundamental tensile element of load-bearing tissues. Tensile testing was performed on fibrils extracted from two types of bovine tendons, adsorbed on a glass surface and glued at both ends. An atomic force microscope (AFM) was used to pull fibrils to failure in bowstring geometry. The broken fibrils were then imaged by AFM for morphological characterization, by second harmonic generation microscopy to assess changes to molecular packing, and by fluorescence microscopy after incubation with a peptide probe that binds specifically to denatured collagen molecules. This dataset linking stress-strain curves to post-failure molecular changes is useful for researchers modelling or designing functional protein materials.
Highlights
Background & SummaryCollagen fibrils are the load-bearing element of connective tissues and a source of inspiration for researchers trying to emulate their mechanical function for tissue or material engineering purposes
Each fibril is first stretched to failure imaged sequentially by atomic force microscopy (AFM), second harmonic generation microscopy (SHG), and fluorescence microscopy (Fig. 1)
The collagen fibrils used for this dataset were extracted from superficial digital flexor (SDF) and common digital extensor (CDE) tendons dissected from two forelimbs, each from a different 24–36 month-old steer killed for food at a local abattoir (Oulton’s Farm, Nova Scotia, Canada)
Summary
Collagen fibrils are the load-bearing element of connective tissues and a source of inspiration for researchers trying to emulate their mechanical function for tissue or material engineering purposes. Each fibril is first stretched to failure imaged sequentially by AFM, SHG, and fluorescence microscopy (Fig. 1) From these measurements we obtain a stress-strain curve for each fibril, quantify the spatial frequency of plastic damage sites along the fibril using AFM, measure the average SHG intensity and characterize the distribution of the anisotropy parameter along the fibril (a measure of molecular order), and via fluorescence microscopy provide a qualitative yes/no answer to the presence of denatured collagen in the broken fibrils. With this workflow, it is possible to perform fibril-level mechanotyping of collagen-rich tissues as a function of anatomical location, animal source, age, and pathology. The dataset presented here illustrates the utility of this approach: we have been able to demonstrate that tendons exposed to different stress levels in vivo are composed of fibrils with distinct structure-function relationships, having both different stress-strain responses and different susceptibilities to structural disruption on overload[11]
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