In recent years, there have been tremendous advances in tissue engineering, the field of biomaterials research and development that combines living cells with 3D microstructures and biologically ...

Two million bone transplants are performed worldwide yearly, including half a million in the United States alone. Yet, a QUT-led study has found surgeons are slow to adopt newly developed biomaterials ...

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 ...

Piezoelectricity in native bones has been well recognized as the key factor in bone regeneration. However, the current additive-manufactured scaffolds mainly focus on the reconstruction of bionic ...

Various tissues and organs in the human body, such as nerves, heart, bones, and skin, rely on bioelectrical signals to maintain function and support ...

A handheld device can apply synthetic bone grafts directly at the site of a defect or injury without the need for prior imaging or fabrication. Researchers demonstrated the technology by modifying a ...

A team develops an innovative injectable hydrogel for bone regeneration, addressing the limitations of traditional bone grafts and adhesion methods. A research team led by Professor Hyung Joon Cha ...

The field of bone implants has taken incredible strides thanks to technological innovations that allow for stronger grafts that are easier to install. Yet even with these advances, there are still ...