Mechanisms found to explain atypical femoral fractures

Radiograph imaging of a fragility fracture of the hip
Donnelly Research Lab/Provided
Radiograph imaging showing morphology of a typical fragility fracture of the hip (A), compared with an atypical femoral fracture, or AFF (B). The nature of the AFF indicates a brittle fracture process, possibly due to excess mineralization of the bone.

There is no disputing that the use of bisphosphonates – with brand names such as Fosamax, Boniva and Reclast – is proven to combat bone loss and fragility fractures in millions of osteoporosis patients for whom a fracture could be debilitating, even life-threatening.

But there is a caveat: Prolonged use of these drugs can alter the composition of bone, making it more brittle and more susceptible to a rare but serious form of fracture. And a group led by Eve Donnelly, assistant professor and Dale R. Corson Sesquicentennial Faculty Fellow in the Department of Materials Science and Engineering (MSE), has put forth a couple of possible explanations for this phenomenon.

Her group – in collaboration with researchers from Weill Cornell Medicine and the Hospital for Special Surgery in New York, among others – detail their findings in “Atypical Fracture with Long-Term Bisphosphonate Therapy is Associated with Altered Cortical Composition and Reduced Fracture Resistance,” published July 31 in the Proceedings of the National Academy of Sciences. Ashley Lloyd, doctoral student in MSE, was lead author.

Modern medicine and attention to healthier lifestyles has contributed to people living into their 80s, 90s and beyond. Some estimates say that by 2050, the number of U.S. residents age 65 and older will be near 84 million, nearly double the 2012 total.

But that has also made more people – especially postmenopausal women – vulnerable to conditions such as osteoporosis, a loss of bone tissue due in part to hormonal changes.

“Because of the changing demographics of our country,” Donnelly said, “the Surgeon General’s office estimates that by the year 2020, half of our population over age 50 will either have or be at risk for fractures from osteoporosis.”

It’s been known for some time that prolonged use of bisphosphonates can put people at risk for atypical femoral fracture (AFF), a break in the shaft of the femur that can occur as a result of little or no trauma. The Donnelly group set out to understand the link between the drugs and AFF.

For this study, the team examined biopsies of cortical bone – the outer layer – from the shaft of the femur obtained from postmenopausal women during fracture repair surgery. Analysis of bone samples was conducted at the Cornell Center for Materials Research and with collaborating labs at Lawrence Berkeley National Laboratory and University Medical Center Hamburg-Eppendorf.

The participants were placed in five groups, based on fracture type and bisphosphonate use. Some of the women in the study had used bisphosphonates for more than eight years.

The testing pointed to a couple of contributing factors: Bisphosphonate-treated women with AFF had bone that was harder and more mineralized than bisphosphonate-treated women with typical osteoporotic fractures. Donnelly said this is due to bisphosphonates’ main function: slowing the resorption (shedding) of old bone, which is typically followed by remodeling, the growth of new bone. In healthy adults, cortical bone is constantly being resurfaced, such that the entire adult skeleton is overhauled every 10 years or so.

But that resurfacing process begins with resorption, and if resorption is slowed by bisphosphonates, the remodeling process is also affected. The result: The existing bone ages and gets brittle over time.

“It’s kind of a double-edged sword,” Donnelly said. “It’s extremely good to prevent bone loss, but the drugs will also slow this natural process, which allows turnover.”

The other unforeseen side effect to long-term bisphosphonate use involves crack-deflection – the resurfaced bone’s ability to stop a microscopic crack from propagating, which can lead to a break. New layers of bone can act as a “firewall” of sorts, stopping a crack from spreading, but mineralized, older bone loses that function.

“Bone usually has natural variability in mineralization within the tissue, which may help to deflect cracks,” Donnelly said. “As you increase the mineralization, you may tend to lose that natural variation.”

The Food and Drug Administration is now recommending patients use bisphosphonates for three to five years, followed by reassessment of their risk. Donnelly makes it clear that her study is not proposing doing away with bisphosphonate treatment. Studies have estimated the risk of AFF among bisphosphonate users at between one and 10 in 10,000, and have shown the benefit of bisphosphonates continues to far outweigh the risk of AFFs.

One study, published in 2011 on pubmed.gov, estimated that for each reduction of 100 typical hip fractures associated with bisphosphonate use, there was an increase of one AFF.

“That’s one of the cautions I’d like to impart,” Donnelly said. “What we have observed is really the result of long-term treatment, well beyond what the FDA is recommending for these drugs now. Our work explains some of the underlying mechanisms of AFFs and can inform the refinement of dosing schedules for patients at risk of fragility fractures.”

Among the collaborators were Dr. Joseph M. Lane and Dr. Dean G. Lorich, orthopedic surgeons at Weill Cornell Medicine and at Hospital for Special Surgery in New York.

This work was supported by grants from the National Science Foundation and the American Society for Bone and Mineral Research.

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Daryl Lovell