Body Fat to Bone: How Scientists Are Healing Spinal Fractures

By turning these cells into bone-forming clusters and pairing them with a bone-rebuilding material, rats regained stronger, healthier spines.

The approach could provide a safe and minimally invasive alternative for treating bone diseases in humans.

Researchers at Osaka Metropolitan University have developed a promising new method for repairing spinal fractures using stem cells extracted from adipose tissue, also known as body fat.

In animal studies, the treatment successfully healed spinal injuries in rats that mimic osteoporosis-related fractures seen in humans. Because these cells are easy to collect, even from older adults, and cause minimal strain on the body, the technique could provide a gentle, non-invasive alternative for treating bone diseases.

Osteoporosis weakens bones, making them fragile and more likely to break. As Japan's population continues to age, the number of people affected is projected to surpass 15 million.

Among the various types of fractures caused by osteoporosis, compression fractures of the spine, known as osteoporotic vertebral fractures, are the most common.

These injuries can result in long-term disability and severely reduce quality of life, highlighting the need for safer and more effective treatments.

Researchers at Osaka Metropolitan University have developed a promising new method for repairing spinal fractures using stem cells extracted from adipose tissue, also known as body fat.

In animal studies, the treatment successfully healed spinal injuries in rats that mimic osteoporosis-related fractures seen in humans.

Because these cells are easy to collect, even from older adults, and cause minimal strain on the body, the technique could provide a gentle, non-invasive alternative for treating bone diseases.

How Fat-Derived Stem Cells Help Rebuild Bone

Stem cells derived from adipose tissue (ADSCs) show strong potential for repairing bone damage. These multipotent cells can develop into various types of tissue, including bone.

When ADSCs are cultivated into three-dimensional spherical groups called spheroids, their ability to promote tissue repair increases.

Pre-differentiating these spheroids toward bone-forming cells further enhances their effectiveness in stimulating bone regeneration.

Led by Graduate School of Medicine student Yuta Sawada and Dr. Shinji Takahashi, the Osaka research team used ADSCs to create bone-differentiated spheroids and combined them with b-tricalcium phosphate, a material commonly used in bone reconstruction. The mixture was applied to rats with spinal fractures, resulting in significant improvements in bone healing and strength.

The researchers also observed that genes responsible for bone formation and regeneration became more active after the treatment, suggesting that the approach stimulates the body's natural healing processes.

Promising Outlook for Future Treatments

"This study has revealed the potential of bone differentiation spheroids using ADSCs for the development of new treatments for spinal fractures," said Sawada. "Since the cells are obtained from fat, there is little burden on the body, ensuring patient safety."

Dr. Takahashi added, "This simple and effective method can treat even difficult fractures and may accelerate healing. This technique is expected to become a new treatment that helps extend the healthy life of patients."

The findings were published in Bone and Joint Research.

- ANI