Alexander Revathi, Liu Xiaohua
NextGen Precision Health Institute, University of Missouri, Columbia, MO, USA.
NextGen Precision Health Institute, University of Missouri, Columbia, MO, USA; Department of Chemical and Biomedical Engineering, University of Missouri, Columbia, MO, USA.
Biomaterials. 2025 Jun 9;324:123491. doi: 10.1016/j.biomaterials.2025.123491.
While osseointegration has traditionally been the focal point of dental implant design, recent research highlights the equally crucial role of establishing a resilient and biologically integrated soft tissue seal for long-term implant success. This review critically examines recent advances (primarily from the past five years) that elucidate the molecular, cellular, and materials science strategies essential for enhancing peri-implant soft tissue integration. Key factors include precisely engineered surface topographies at micro- and nanoscale levels, surface chemical modifications that enhance wettability and protein adsorption, and biomimetic coatings incorporating extracellular matrix-derived peptides, chemokines, and growth factors. Recent studies underscore the impact of laser micro- and nano-texturing, plasma treatments, and biofunctionalization in modulating fibroblast and epithelial cell behaviors, accelerating tissue attachment, and mitigating early inflammatory responses. Emerging implant-abutment designs, such as platform switching and transmucosal zirconia abutments, demonstrate improved soft tissue stability and reduce crestal bone loss. Additionally, the immunomodulatory potential of next-generation materials offers promising avenues for directing macrophage polarization and enhancing wound resolution. Collectively, this review synthesizes the latest evidence on material-driven and biological strategies for engineering a stable soft tissue interface. It provides a translational roadmap for the development of implant systems optimized for long-term soft tissue health, addressing a critical unmet need in dental implantology.
虽然骨结合传统上一直是牙种植体设计的重点,但最近的研究强调,建立一个有弹性且生物整合的软组织密封对种植体的长期成功同样至关重要。本综述批判性地审视了最近的进展(主要是过去五年的),这些进展阐明了增强种植体周围软组织整合所必需的分子、细胞和材料科学策略。关键因素包括在微米和纳米尺度上精确设计的表面形貌、增强润湿性和蛋白质吸附的表面化学修饰,以及包含细胞外基质衍生肽、趋化因子和生长因子的仿生涂层。最近的研究强调了激光微纳纹理化、等离子体处理和生物功能化在调节成纤维细胞和上皮细胞行为、加速组织附着以及减轻早期炎症反应方面的影响。新兴的种植体-基台设计,如平台转换和穿龈氧化锆基台,显示出改善的软组织稳定性并减少牙槽嵴骨吸收。此外,下一代材料的免疫调节潜力为引导巨噬细胞极化和增强伤口愈合提供了有前景的途径。总体而言,本综述综合了关于材料驱动和生物学策略以构建稳定软组织界面的最新证据。它为开发针对长期软组织健康进行优化的种植体系统提供了一个转化路线图,解决了牙种植学中一个关键的未满足需求。