In pulmonary arteries (PA), mechanical function is largely driven by the underlying microstructure of the structural proteins collagen and elastin, which reside within the extracellular matrix (ECM) of the arterial tissue. It has long been established that much of the mechanical non-linearity associated with arterial tissue is the result of collagen mechanics. Arterial collagen is arranged within the vascular wall as tortuous fibrils with a bulk fiber orientation of roughly helical configuration. When arterial tissue is deformed, these collagen fibers become straightened in the direction of applied load. At some critical deformation, termed the transition stretch (λTrans), collagen fibers begin to carry load, thus significantly altering material stiffness. This in turn gives rise to the non-linear force-stretch (F-λ) response typical of these tissues, Figure 1. We have recently found that λTrans is significantly reduced in the hypoxia-induced pulmonary hypertensive (PH) rat model. We therefore propose that this model constitutes an ideal system to study the effect of collagen microstructure on the mechanics of arterial tissues in response to PH vascular remodeling. We hypothesize that quantitative characterization of collagen microstructure will predict pulmonary artery (PA) λTrans within this model system. By directly relating collagen microstructural changes to bulk tissue mechanics in response to PH-induced vascular remodeling we can better understand how changes in collagen structure impact pulmonary hemodynamic capacitance, a major component of cardiac load and contributing factor to right heart failure.
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