Journal of Dental Medicine

The Guided Bone Regeneration (GBR) treatment concept advocates that regeneration of osseous defects is predictably attainable via the application of occlusive membranes, which mechanically exclude non-osteogenic cell populations from the surrounding soft tissues, thereby allowing osteogenic cell populations originating from the parent bone to inhabit the osseous wound. The use of membrane to exclude non-osteogenic cells, is a key principle of guided bone regeneration. A large number of membranes have been evaluated in clinical and experimental studies. The object of this study was to review the literature regarding guided bone regeneration and all types of membranes that were used in this technique. 72 articles between the years 1968 through the 2016 from PubMed, Medline and Google Scholar using the related keywords, were selected. Finally, we concluded that the modification of mechanical and physico-chemical properties of membranes could improve the process of new bone growth. However, determination of the exact role of membrane porosity in this process, still needs to be clarified. Optimization the chemical composition of membrane with the focus and attention to obstructive property and bioactivity, is an important point in this research field. Various factors such as flexibility, mechanical strength and degradation rate determine the type of membrane used for bone tissue regeneration.

This narrative review provides a comprehensive overview of the potential of plant-derived polyphenols in restorative and preventive dentistry. As natural bioactive compounds such as polyphenols reshape the oral microbial ecology by attenuating virulence, inhibiting quorum-sensing communication, disrupting extracellular polymeric substance (EPS) formation, and reducing acidogenicity within dental biofilms. Beyond their antimicrobial effects, polyphenols can protect host tissues, namely, enamel, dentin, and gingiva, by cross-linking collagen fibrils, suppressing matrix metalloproteinase (MMP) activity, and modulating inflammatory pathways. Experimental, in situ, and clinical evidence consistently demonstrated improved bond durability at the dentin–resin interface. The most compelling data support the use of primers containing proanthocyanidins, quercetin, epigallocatechin gallate (EGCG), and resveratrol. In preventive applications, catechin-based varnishes have demonstrated remineralization effects comparable to those of fluoride varnishes. Conversely, pomegranate extract–enriched mouthrinses, in the presence of fluoride, could enhance both anti-demineralization and antibiofilm activity. In the context of implants and dental prostheses, the polyphenol-functionalized coatings, particularly those based on tannic or caffeic acid, would reduce biofilm formation and provide corrosion resistance for metallic surfaces. Nevertheless, several formulation challenges remain, including rapid oxidation, limited solubility, and discoloration, all of which require careful management. Strategies such as dose optimization, solvent selection, covalent stabilization, and microencapsulation are recommended to overcome these limitations. For broader and more effective clinical translation, standardization of multispecies laboratory models and harmonization of clinical endpoints are essential. Furthermore, future longitudinal trials are needed to bridge the gap between laboratory findings and clinical performance. Ultimately, with the design of innovative delivery systems and long-term monitoring of parameters such as restoration survival, secondary caries, periodontal health, and color stability, polyphenols hold promise to define a new generation of antibacterial, biocompatible, and aesthetically stable dental materials.