Comparative multi‐scale hierarchical structure of the tail, plantaris, and Achilles tendons in the rat

AH Lee, DM Elliott - Journal of anatomy, 2019 - Wiley Online Library
Journal of anatomy, 2019Wiley Online Library
Rodent tendons are widely used to study human pathologies such as tendinopathy and
repair, and to address fundamental physiological questions about development, growth, and
remodeling. However, how the gross morphology and multi‐scale hierarchical structure of
rat tendons, such as the tail, plantaris, and Achilles tendons, compare with that of human
tendons are unknown. In addition, there remains disagreement about terminology and
definitions. Specifically, the definitions of fascicle and fiber are often dependent on diameter …
Abstract
Rodent tendons are widely used to study human pathologies such as tendinopathy and repair, and to address fundamental physiological questions about development, growth, and remodeling. However, how the gross morphology and multi‐scale hierarchical structure of rat tendons, such as the tail, plantaris, and Achilles tendons, compare with that of human tendons are unknown. In addition, there remains disagreement about terminology and definitions. Specifically, the definitions of fascicle and fiber are often dependent on diameter sizes, not their characteristic features, and these definitions impair the ability to compare hierarchical structure across species, where the sizes of the fiber and fascicle may change with animal size and tendon function. Thus, the objective of the study was to select a single species that is commonly used for tendon research (rat) and tendons with varying mechanical functions (tail, plantaris, Achilles) to evaluate the hierarchical structure at multiple length scales using histology, SEM, and confocal imaging. With the exception of the specialized rat tail tendon, we confirmed that in rat tendons there are no fascicles and the fiber is the largest subunit. In addition, we provided a structurally based definition of a fiber as a bundle of collagen fibrils that is surrounded by elongated cells, and this definition was supported by both histologically processed and unprocessed samples. In all rat tendons studied, the fiber diameters were consistently between 10 and 50 μm, and this diameter range appears to be conserved across larger species. Specific recommendations were made highlighting the strengths and limitations of each rat tendon as a research model. Understanding the hierarchical structure of tendon can advance the design and interpretation of experiments and development of tissue‐engineered constructs.
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