We appreciate the engagement in the Commentaries (1) for our recent Viewpoint paper (2).
Although our concern related to the use of population normative Z-scores mainly referred to potentially overlooking symptoms of low energy availability (LEA) in high-impact (HI) sport athletes, also overlooking athletes at high risk for fractures is worrying. About 10% of all sports-related injuries, being as high as 30% in running, are stress fractures, depriving athletes from sport participation (3). Tolerance for sport-specific training may take as long as 6 mo postfracture, and more likely up to 12 mo (4). The inappropriate use of bone mineral density (BMD) Z-scores from the general population to evaluate risk in athletes was highlighted by the recent findings of “normal clinical” BMD values in collegiate distance runners who experienced bone stress injuries (5). Heikura et al. (6) reported a 4.5 times higher risk for bone stress injuries in runners and race-walkers with symptoms of LEA, despite “normal” mean BMD Z-scores, which also were similar to the BMD Z-scores of the athletes without fractures (6). Importantly, normal BMD Z-scores, when being based on the general population, do not seem to successfully identify athletes at high risk for bone stress injuries. The difficulties in identifying athletes at risk for complications from LEA, like bone stress injuries, by comparing BMD values to the general population, were also illustrated by Ackerman (7). BMD Z-scores in the femur and the total hip regions were both higher in eumenorrheic runners compared with nonathletes, but also much lower in amenorrheic compared with both eumenorrheic runners and nonathletes (7). This study was the first to report deteriorated microarchitecture in adolescent amenorrheic athletes; an important determinant for fracture risk.
Interestingly, DXA does not distinguish cortical from trabecular bone mass, whereas trabecular bone mass is early to deteriorate with persistent overload or poor recovery, the BMD changes may be masked in cortical-dominated bone areas (8). This was highlighted in a finding of similar tibial-BMD in sport- and age-matched females with or without fracture, but with dissimilar regional bone quality (8). Not all studies including bone quality measurements have identified differences between individuals with or without fracture (9). Still, region-specific measurements and consideration of the timing of measurement are important factors that may explain the different findings related to BMD and microarchitecture.
As such, “normal” BMD Z-scores, still being lower than expected for a HI athlete, may indicate a high risk for bone stress injury, and some of the explanations may be impaired bone quality. This is not measurable by DXA but has typically been reported by BMD Z-scores around “0” or less. As long as values above −1 are considered clinically normal, we may overlook athletes at high risk for fractures, also leaving them at high risk for the many other clinical complications by relative energy deficiency in sport (RED-S), if the reason for impaired bone quality relates to LEA. Hence, in contrast to van Weijer et al. (1), we argue that an athlete-specific BMD range may both reduce complications from undiscovered LEA as well as risk for fractures.
DISCLOSURES
No conflicts of interest, financial or otherwise, are declared by the authors.
AUTHOR CONTRIBUTIONS
T.F.M. drafted manuscript; K.L.J., M.K.T., J.K.S.-B., and T.F.M. edited and revised manuscript; K.L.J., M.K.T., J.K.S.-B., and T.F.M. approved final version of manuscript.
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