Elastic discontinuity due to ectopic calcification in a human fibrous joint.

Disease can alter natural ramp-like elastic gradients to steeper step-like profiles at soft-hard tissue interfaces. Prolonged function can further mediate mechanochemical events that alter biomechanical response within diseased organs. In this study, a human bone-tooth fibrous joint was chosen as a model system, in which the effects of bacterial-induced disease, i.e. periodontitis, on natural elastic gradients were investigated. Specifically, the effects of ectopic biomineral, i.e. calculus, on innate chemical and elastic gradients within the cementum-dentin complex, both of which are fundamental parameters to load-bearing tissues, are investigated through comparisons with a healthy complex. Complementary techniques for mapping changes in physicochemical properties as a result of disease included micro X-ray computed tomography, microprobe micro X-ray fluorescence imaging, transmission electron and atomic force microscopy (AFM) techniques, and AFM-based nanoindentation. Results demonstrated primary effects as derivatives of ectopic mineralization within the diseased fibrous joint. Ectopic mineralization with no cementum resorption, but altered cementum physicochemical properties with increasing X-ray attenuation, exhibited stratified concretion with increasing X-ray fluorescence counts of calcium and phosphorus elements in the extracellular matrix in correlation with decreased hygroscopicity, indenter displacement, and apparent strain-relieving characteristics. Disease progression, identified as concretion through the periodontal ligament (PDL)-cementum enthesis, and sometimes the originally hygroscopic cementum-dentin junction, resulted in a significantly increased indentation elastic modulus (3.16±1.19 GPa) and a shift towards a discontinuous interface compared with healthy conditions (1.54±0.83 GPa) (Student's t-test, P<0.05). The observed primary effects could result in secondary downstream effects, such as compromised mechanobiology at the mechanically active PDL-cementum enthesis that can catalyze progression of disease. Published by Elsevier Ltd.