A cube of healthy bone is anything but solid. Inside it, countless tiny channels carry fluid and help cells move, feed, and ...

The challenges of connecting molecular changes to tissue structure and highlights the potential of multifractal frameworks to quantify complex biological patterns ...

Researchers in Sweden have engineered a cell-free cartilage scaffold that can guide the body to rebuild damaged bone. By removing the cells but preserving the structure and natural growth signals, the ...

When a bone break is too severe to heal on its own, surgeons often rely on grafts or rigid metal implants — but both come ...

Bone implants often fail to fully integrate with surrounding tissue, limiting their effectiveness in regeneration. A natural but often overlooked cellular process could hold the key to better outcomes ...

(Nanowerk Spotlight) Surgeons treating large bone defects—whether after tumor removal, traumatic injury, or severe infection—face a material problem with few good options. After clearing the damaged ...

ETH researchers have developed a novel hydrogel consisting mainly of water and a polymer network. Using laser light, the researchers can very quickly solidify the hydrogel into a material with ...

New research shows how curcumin’s molecular power protects bone cells from high-glucose stress, repairs mitochondria, and boosts antioxidant defences, offering hope for tackling diabetes-related bone ...

Researchers recently developed a bone marrow model to study how the body generates cells. Interestingly, this model is the first of its kind to be developed entirely from human cells. Not only can ...