Clinical minimally invasive treatments require the elimination of dental caries-infected tissues in order to stop the progression of bacteria to the pulpal chamber and maximize the reparative potential of the remaining partially demineralized tissues.

In order to encourage the remineralization of the remaining partially demineralized dental tissues after caries removal, glass-ionomer cements are currently used to favor the diffusion of the specific ions into mineral-depleted dentin. Nevertheless, these cements have no therapeutic ability to bio-remineralize the partially demineralized caries-affected dentine, accurately. It means that glass-ionomer cements, along with most of the restorative materials currently used in minimally invasive dentistry, do not induce nucleation of new hydroxyapatite crystals within the demineralized dentine collagen at intra-fibrillar level.

Salvatore Sauro, Professor of Dental Biomaterials and Minimally Invasive Dentistry at CEU Cardenal Herrera University, has led a research project which focused first on the use of phosphoproteins' biomimetic analogues in combination with experimental bioactive resin-based dental adhesives to remineralize the mineral-depleted dentin at the bonding interface of teeth filled with common restorative dental composites. The biomimetic analogues used in this study permitted the remineralization of collagen fibrils through precipitation of hydroxyapatite at intra-fibrillar level, so that the biomechanical properties of the demineralized dentin, such as the elastic modulus and hardness, were completely recovered. The results of this recent study have been published in Dental Materials.

According to professor Sauro, "The most important problem related to dental fillings in demineralized dental tissues, such as caries-affected dentine, is the lack of therapeutic bio-remineralization which can extend the durability of the resin-dentine bonding interface created with dental adhesives and resin composites."

Biomimetic Remineralization

Professor Sauro and collaborators have also shown that by using analogues of phosphoproteins in combination with bioactive adhesive resin-based materials doped with calcium and phosphates, it is possible to improve the longevity of the adhesion of dental composite restorations to dental tissues due to the biomimetic remineralization of mineral-depleted dentine at the bonding interface.

According to Salvatore Sauro, this study has demonstrated that the use of resin- adhesive doped with bioactive micro-fillers applied onto demineralized dentine pre-treated using biomimetic analogues of the phosphoproteins, such as polyaspartic acid (PLA) or sodium trimetaphosphate (TMP) represents an efficient and innovative therapeutic strategy to trigger biomimetic remineralization processes at the bonding area between dentine and restorative materials. This result is a further step to the prolific research activity of Professor Sauro, who is currently focusing the energy of his entire group of research on the development of innovative bioactive and biomimetic restorative materials for therapeutic and aesthetic restorations of teeth affected by large caries lesions.

Source: Science Daily