Investigating the Multiscale and Cellular Frontier: A Scientific Quest to Remediate Bone Fragility

Addressing fragility fractures, prevalent in aging, osteoporosis, and diabetes, poses a persistent challenge in clinical practice. While the fracture mechanisms in engineering materials are well-established, understanding bone remains complex. Currently, bone mass is the primary indicator of fracture risk; however, this metric alone falls short in accurately predicting an individual's risk of fracture. Therefore, the field of bone fragility is now exploring other factors, such as bone quality, which involves investigating material, structural, and cellular changes associated with fragility diseases and how they impair bone fracture toughness. This pursuit requires a mechanical approach combined with biophysics and skeletal biology to expand our knowledge in biological sciences.

During this talk, I will demonstrate how we used multiscale experimental approaches, such as high-resolution and advanced x-ray radiation experiments, and novel in situ imaging techniques to reveal dynamic 3D mechanisms of bone across molecular to millimeter length scales. I will show that deficits in nanoscale collagen deformation are a key contributor to bone fragility in diabetes and aging. Finally, I will discuss the central role of osteocyte cells in maintaining bone composition, organization, and function in response to damage and mechanical stress. By identifying mechanisms that weaken bone, we can pave the way for new diagnostic tools and therapeutic targets for managing bone fracture risk.