GelMA-based moldable and rapid-curable osteogenic paste inspired by ceramic craft for alveolar bone defect regeneration.

Alveolar bone defects pose a significant challenge in oral clinical treatments, impacting procedures such as dental implants, orthodontics, and oral restoration. Despite their frequent occurrence due to various causes, the effective restoration and reconstruction of alveolar bone defects remain a significant clinical challenge in dentistry. Existing treatments often rely on intrinsic blood coagulation to stabilize bone grafts, but they present limitations such as gradual clotting and reduced effectiveness in patients with coagulation dysfunction.

Bioinspired polysaccharide-based nanocomposite membranes with robust wet mechanical properties for guided bone regeneration.

Polysaccharide-based membranes with excellent mechanical properties are highly desired. However, severe mechanical deterioration under wet conditions limits their biomedical applications. Here, inspired by the structural heterogeneity of strong yet hydrated biological materials, we propose a strategy based on heterogeneous crosslink-and-hydration (HCH) of a molecule/nano dual-scale network to fabricate polysaccharide-based nanocomposites with robust wet mechanical properties.

Harmonizing Thickness and Permeability in Bone Tissue Engineering: A Novel Silk Fibroin Membrane Inspired by Spider Silk Dynamics.

Guided bone regeneration gathers significant interest in the realm of bone tissue engineering; however, the interplay between membrane thickness and permeability continues to pose a challenge that can be addressed by the water-collecting mechanism of spider silk, where water droplets efficiently move from smooth filaments to rough conical nodules. Inspired by the natural design of spider silk, an innovative silk fibroin membrane is developed featuring directional fluid transportation via harmoniously integrating a smooth, dense layer with a rough, loose layer; conical microchannels are engineered in the smooth and compact layer. Consequently, double-layered membranes with cone-shaped microporous passageways (CSMP-DSF membrane) are designed for in situ bone repair.