This research develops smart, biodegradable bone scaffolds that guide regeneration in severe fractures. By delivering healing molecules directly to damaged tissue, the scaffolds promote stronger bone growth, reduce inflammation, and eliminate the need for repeated surgeries, enabling faster and more natural recovery in children.

Corneal scarring causes widespread vision loss and is poorly treated by transplantation alone. This research develops a bioengineered corneal glue that both seals and heals wounds by promoting cell infiltration and reducing fibrosis. The approach enables scar-free healing, lowers transplant rejection risk, and offers a regenerative alternative to sutures and conventional sealants.

The speaker investigates why surgical sutures often fail and explores bio-inspired alternatives. Studying freshwater mussels—experts at sticking to wet surfaces—they analyze adhesive proteins to design stronger, water-compatible tissue adhesives. This research aims to create safer, more reliable surgical closure methods that reduce complications, infections, and reliance on traditional suturing.

This research transforms natural silk fibers into biodegradable “silk paper” membranes that support bone regeneration for dental implants. Unlike titanium meshes, silk papers dissolve in the body, eliminating the need for a second surgery. They support human cell growth, reduce costs, and promise safer, more accessible dental and medical treatments.