Managing Dental Erosion: Current Understanding and Future Directions
Fluoride and Dental Erosion

While dental erosion, like caries, is a mineral process, the erosion process follows a somewhat different pathway.^38,50 There is little possibility of reversal, as erosive acids are able to overwhelm the protective pellicle layer and soften outer surfaces of the tooth; these softened surfaces can then be lost to abrasive forces, resulting in permanent and irreversible loss of tooth structure (Figure 12).

It is well accepted that fluoride helps keep teeth strong. However, recent studies have demonstrated that all fluorides are not alike with their ability to help prevent dental erosion. While there would likely be a greater incidence of dental erosion in the absence of fluoride, the data suggest that most fluorides do not provide a high level of benefit against the increasing levels of challenge teeth are facing in today’s environment. In spite of the fact that almost 100% of the world’s toothpastes contain fluoride, the incidence and prevalence of dental erosion both appear to be on the rise. These data suggest many fluoride products may not be sufficiently effective to protect teeth against erosive acid challenges. However, one of the currently used sources of fluoride, stannous fluoride (SnF₂) (Figure 13), has been demonstrated in a broad range of studies to be unique in its ability to help prevent the initiation and progression of dental erosion. These include both laboratory^51-54 and human in situ erosion clinical studies.^55-60 Different from other sources of fluoride used, stannous fluoride deposits a retentive, acid resistant barrier layer onto exposed tooth surfaces that is protective against both the initiation and progression of dental erosion (Figure 14).⁶¹