Maxillary sinus augmentation is a key procedure for rehabilitating the atrophic posterior maxilla and enabling predictable implant-supported restorations. Although autogenous bone remains the biological gold standard due to its osteogenic potential, its clinical use has declined because of donor-site morbidity, limited availability, and increased surgical burden. Deproteinized bovine bone mineral (DBBM) is currently the most widely used substitute, providing excellent biocompatibility and long-term volumetric stability. However, its inert nature, limited bioactivity, and slow resorption have driven the development of next-generation graft materials. Recent biomaterial innovations aim to enhance vascularization, accelerate osteogenesis, modulate immune responses, and achieve controlled resorption while maintaining favorable handling properties. These include ion-releasing bioactive ceramics, growth factor-enhanced allografts, polysaccharide-hydroxyapatite composites, smart hydrogels, and synthetic scaffolds with tunable degradation profiles. Given the complexity of bone regeneration, effective clinical translation requires an integrated framework combining in vitro assays, animal models, and human clinical studies. This review synthesizes evidence published since 2018 on emerging biomaterials for sinus floor elevation, critically evaluating their potential to overcome the limitations of DBBM and highlighting the importance of a coordinated preclinical-to-clinical research continuum.
Keywords: biomaterials; bone regeneration; deproteinized bovine bone mineral; maxillary sinus augmentation; translational research.