Beyond dissolution: Xerostomia rinses affect composition and structure of biomimetic dental mineral in vitro.

Xerostomia, known as dry mouth, is caused by decreased salivary flow. Treatment with lubricating oral rinses provides temporary relief of dry mouth discomfort; however, it remains unclear how their composition affects mineralized dental tissues. Therefore, the objective of this study was to analyze the effects of common components in xerostomia oral rinses on biomimetic apatite with varying carbonate contents. Carbonated apatite was synthesized and exposed to one of the following solutions for 72 hours at varying pHs: water-based, phosphorus-containing (PBS), mucin-like containing (MLC), or fluoride-containing (FC) solutions. Post-exposure results indicated that apatite mass decreased irrespective of pH and solution composition, while solution buffering was pH dependent. Raman and X-ray diffraction analysis showed that the addition of phosphorus, mucin-like molecules, and fluoride in solution decreases mineral carbonate levels and changed the lattice spacing and crystallinity of bioapatite, indicative of dissolution/recrystallization processes. The mineral recrystallized into a less-carbonated apatite in the PBS and MLC solutions, and into fluorapatite in FC. Tap water did not affect the apatite lattice structure suggesting formation of a labile carbonate surface layer on apatite. These results reveal that solution composition can have varied and complex effects on dental mineral beyond dissolution, which can have long term consequences on mineral solubility and mechanics. Therefore, clinicians should consider these factors when advising treatments for xerostomia patients.

Iron accumulation during cellular senescence.

Iron accumulates as a function of age and is associated with the pathology of numerous age-related diseases. These changes may be caused by altered iron homeostasis at the cellular level, yet this is poorly understood. Therefore, changes in iron content in primary human fibroblasts were studied in culture models of cellular senescence. Total iron content increased exponentially during cellular senescence, reaching approximately 10-fold higher levels than young cells. Increasing intracellular iron levels through iron-citrate supplementation or decreasing intracellular iron levels using iron-selective chelators had little effect on cellular life span and markers of cellular senescence when used at subtoxic doses. However, accelerating cellular senescence with low-dose H(2)O(2) also accelerated senescence-associated iron accumulation. Delaying cellular senescence with N-tert-butyl-hydroxylamine (NtBHA) attenuated senescence-associated iron accumulation. Furthermore, H(2)O(2) or NtBHA had no effect on iron intracellular levels in immortalized fibroblasts. Thus, iron accumulation is not a cause, but a consequence of normal cellular senescence in vitro. Senescence-associated iron accumulation may contribute to the increased oxidative stress and cellular dysfunction seen in senescent cells.