Anisotropic swelling due to hydration in fibrous biomaterials

Naturally occurring protein fibres often undergo anisotropic swelling when hydrated. Within a tendon, a hydrated collagen fibril's radius expands by 40\% but its length only increases by 5\%. The same effect, with similar magnitude, is observed for keratin microfibrils within hair. Nevertheless, current explanations for swelling anisotropy are based on molecular details that are unique to each material. Here, we describe a coarse-grained liquid-crystalline elastomer model for biomaterial hydration that allows for anisotropic swelling. We show that our model is consistent with previously observed behavior for both hair fibers and collagen fibrils. Despite a non-linear relationship between water saturation and relative humidity, we find that the squared deformation in the axial and radial directions is approximately linear with water saturation. We further find that anisotropic swelling is linear with respect to volume and shape changes. Hair and collagen exhibit remarkably similar behavior under hydration. We suggest that our model may also be useful for other biomaterials that exhibit anisotropic swelling.