Bone Quality in Female Ballet Dancers: A Possible Determinant of Bone Health ()
1. Introduction
The position stand, introduced by the American College of Sports Medicine (ACSM), defined the female athlete triad (FAT) as low energy availability, amenorrhea and osteoporosis [1] [2] . FAT can be clinically manifested by stress fractures. It has been recently addressed by the International Olympic Committee (IOC), and focus was mainly on relative energy deficiency in FAT [3] [4] . In regard to bone health, the position stands have related only to bone mineral density (BMD), but BMD is only one of bone strength indicators: even amongst patients with the same BMD values, fractures develop only in few. Recent studies indicate that not only BMD but also bone quality seems to play an important role in bone strength by its direct relationship with collagen cross-link formation [3] [5] [6] [7] [8] [9] . Collagen cross-links can be divided into physiological enzymatic cross-links and non-physiological oxidative stress-induced crosslinks, the latter including advanced glycation end products (AGEs) such as pentosidine (Pent). In osteoporotic patients, serum levels of homocystein (HC), a marker of increased oxidative stress, and Pent have been widely used as determinants of bone quality [6] [7] [10] - [15] ; however, no studies have been performed on status of bone quality in young female athletes.
The purpose of this study was to evaluate bone quality in elite female ballet dancers by measuring serum HC and Pent levels as well as BMD and bone metabolism markers, and to determine whether these markers show any relationship with amenorrhea and/or fatigue fractures.
2. Methods
2.1. Subjects
Inclusion criteria were the dancers 1): their age was 20 years old or over, 2): their training experience was 10 years or more, and 3): their training frequency was more than five days in a week. Out of 20 top-leveled female ballet dancers of the Ochanomizu University in Tokyo, Japan, who filled the above criteria, 13 dancers (mean and SD; age: 21.8 ± 2.0 years; body mass: 49 ± 6.3 kg; height: 160.7 ± 6.4 cm and BMI 18.8 ± 1.2 kg∙m−2) with an average 15.8 years of training experience agreed to participate in this study. All subjects signed a written informed consent. The ethic committees of Jikei University (No. 23-026) and Ochanomizu University (No. 23-3) approved the study design.
2.2. Body Health Questionnaire (History of Fatigue Fracture and Menstrual Cycle Status)
The dancers were asked to fill a health status questionnaire, which included questions on history of fatigue fractures, menstrual history and cycle characteristics, history of other diseases and drug use, including oral contraceptive agents. A regular cycle was defined as menstrual periods occurring every 21 to 35 days. Primary amenorrhea was defined as absence of menarche by the age of 15 years and secondary amenorrhea as cessation of menses for three or more consecutive cycles after the menarche onset. Oligomenorrhea was defined as menstrual bleeding occurring at intervals longer than 35 days [2] [16] [17] . Fatigue fracture was defined as being diagnosed by an orthopedic surgeon, and the questionnaire included questions on time of fracture and affected bone.
2.3. Bone Mineral Density (BMD)
BMD of the lumbar spine (L1?L4) was examined by dual-energy X-ray absorptiometry (DXA) (GE Lunar Prodigy densitometer, Version 10.51; Madison, Wisconsin) and body composition was also assessed. The daily coefficient of variation of the calibration phantom over a 6-month period was 0.16%. The International Society for Clinical Densitometry (ISCD), World Health Organization (WHO), and ACSM classification systems were used to define low BMD based on Z-scores.
2.4. Blood Sampling
Blood samples were obtained by venipuncture in the afternoon and the following serum parameters were measured: 1) serum bone metabolic markers: bone alkaline phosphatase (BAP) and tartrate-resistant acid phosphatase 5b (TRAP5b); 2) bone quality-related markers: HC and Pent; 3) thyroid-stimulating hormone (TSH), intact parathyroid hormone (iPTH) and adrenocorticotropic hormone (ACTH) to exclude endocrinologic disturbances potentially involved in regulation of calcium metabolism. All blood examinations were carried out at the SRL laboratory (Tokyo, Japan) accordingly with the previously reported methods [18] .
2.5. Statistical Analysis
Database construction and statistical analyses were performed using SPSS for Windows (version 19, IBM Corp). Continuous variables were expressed as mean ± SD. Pearson product moment correlation coefficients were computed to determine a relationship between BMD and Pent. Statistical significance was set at p ≤ 0.05.
3. Results
3.1. History of Fatigue Fractures
Two ballet dancers had a history of fatigue fracture: one developed bilateral pars-interarticularis fracture of the 4th lumbar spine (spondylolysis) (case No. 4) and the other suffered from a tibial fracture (case No. 9). They occurred 8 and 14 years before commencement of the study, respectively, and were conservatively treated (Table 1 and Table 2).
3.2. History of Menstrual Dysfunction
The onset age of menarche was from 11 to 15 years, 12.8 years in average. Three subjects had a history of secondary amenorrhea (cases No. 3, 6, 10); in these cases, the age at menarche cessation was 19, 18 and 17 years, respectively. The duration of amenorrhea was 2 years in all subjects. In case 6, the dancer continuously suffered from amenorrhea until the time of present study. Overall, 4
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Table 1. Subjects’ characteristics (1).
* Standard Deviation ** Body Mass Index.
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Table 2. Subjects’ characteristics (2).
* Standard Deviation **Bone mineral density.
subjects considered their menstrual cycles as irregular in the questionnaire (3 cases with amenorrhea and one case without, case No. 12).
3.3. BMD
BMD ranged from 1.064 to 1.518 g/cm2 and averaged 1.305 ± 0.121 g/cm2. T-score was from −0.6 to 3.1 (1.34 in average), and Z-score was from 0 to 3.1 (1.43 in average), in all dancers the scores were higher than −2.5 and −1.0, for T- and Z-score, respectively.
3.4. Serum Bone Metabolic Markers (BAP, TRAP5b), Bone Quality-Related Markers (HC, Pent), And Other Hormonal Assays Related to Calcium Metabolism (TSH, iPTH, ACTH)
In all subjects, BAP, TRAP5b, TSH, iPTH and ACTH values were within normal limits. Although HC levels in all subjects were normal, in 2 dancers (cases No. 6, 10) the levels of Pent were abnormally increased. Both two subjects also had a history of secondary amenorrhea (Table 3). No relationships between any of the measured parameters and fatigue fractures were found. The level of Pent was significantly negatively correlated with the lumbar spine BMD (r = −0.37, p < 0.05).
(BAP: bone alkaline phosphatase, TRAP5b: tartrate-resistant acid phosphatase 5b, HC: homocystein, Pent: pentosidine, TSH: thyroid-stimulating hormone, iPTH: intact parathyroid hormone, ACTH: adrenocorticotropic hormone).
*abnormally high leve.
4. Discussion
Although epidemiologic data relating BMD to fractures in adolescents and premenopausal women are lacking, athletes doing weight-bearing sports usually have 5% - 15% higher BMDs than non-athletes [2] . There have been several reports regarding BMD in ballet dancers. Lichtenbelt et al. reported that the BMD in ballet dancers (n = 24) was significantly higher than that of a reference population [19] . On the other hand, Lucas reported that the BMD of ballet dancers (n = 15) was not significantly different from the control subjects [20] .
BMD and menstrual cycle relationship was also addressed. Warren et al. [21] and Kaufman et al. [22] demonstrated that BMD values in ballet dancers with regular menstrual cycles were not significantly different from those in control subjects; though in dancers after menopause the BMD levels were significantly lower. Recently, Amorin carried out a systematic review on prevalence of low BMD in female dancers and concluded that the published work cannot answer the fundamental question whether low BMD is actually more prevalent in female dancers [23] . BMD varies accordingly with age: it is different between in premenopausal and postmenopausal women. ISCD and ACSM recommended that BMD in premenopausal populations be expressed as Z-scores to compare individuals to age and sex-matched controls, and that Z-scores below −1.0 be considered as low bone density values.
Furthermore, an association between low BMD and stress fractures has been reported in female athletes including dancers [24] [25] [26] . However, BMD represents only one aspect of bone strength. Recent studies have clearly shown that bone quality also plays an important role and it has been thought that its involvement in establishing bone strength is approximately 30%. Bone quality is maintained by collagen cross-links, whose formation affects tensile strength and post-yield properties of the bone. Recent studies have demonstrated that AGEs cross-link formation affects bone toughness and stiffness, and the elastic modulus was independent of other determinants of bone strength such as the mineral phase and microarchitecture [5] [6] [7] .
Shiraki et al. divided bone fragility into three types based on BMD and bone quality involvement in postmenopausal population: 1) low BMD with normal bone quality; 2) bone quality degradation with normal BMD, and 3) low BMD with bone quality degradation, and investigated the risk of the fractures compared to the women who had normal BMD and bone quality. They concluded that fracture risk ratio was 3.6, 1.5, and 7.2 times higher, respectively [13] .
Although bone quality is a dependent factor and plays an important role in bone strength in postmenopausal population, little attention has been paid to bone quality in young female athletes and there has been only one report available in the literature addressing this issue. Wakamatsu et al. reported that HC and Pent were not significantly different between lacrosse players who had experienced stress fracture and those who had not [27] . Since the menstrual abnormalities are estimated to occur in 20% of exercising females, with prevalence reported as high as 44% in ballet dancers and 51% in endurance runners [28] [29] [30] [31] , the prevalence of high pentosidine levels could not be assumed low.
The present study demonstrated that in 2 out of 13 dancers, the levels of pentosidine were increased notwithstanding normal stress oxidative markers and bone metabolism markers including BMD. These subjects were also the two out of 3 subjects with secondary amenorrhea. It has been reported that Pent increases due to several factors such as aging, estrogen impairment, increased oxidative stress, diabetes and zero gravity [6] . We presumed that high Pent levels in the 2 subjects were caused by estrogen imbalances due to secondary amenorrhea, because other hormonal, metabolic or lifestyle-related diseases were not observed.
The present study has several limitations. It was a cross-sectional study, not case control or prospective study, and the number of subjects was small. The reasons why in 2 subjects pentosidine levels were high without decreased BMD remain unknown. We consider two potential explanations. First, the subjects with abnormally high levels of Pent also had low BMD due to secondary amenorrhea, but Pent levels had not yet recovered even BMD values normalized after re-start of menarche. This could have meant that bone quality recovery time is longer than that of BMD even after re-start of menstrual cycle. Second, high pentosidine levels were caused by secondary amenorrhea without any influence on BMD.
Timing of blood testing during menstrual cycle in the two subjects with higher pentosidine levels was not standardized. This is another limitation of the study, because there is evidence for cycle-related changes in other bone markers along phases of menstrual cycle [32] [33] .
Notwithstanding the limitations, our study indicates that latent deterioration of bone quality can develop in female athletes who have experienced secondary amenorrhea but present with otherwise normal BMD and other calcium metabolic markers. Although we did not find any correlation between pentosidine levels and fatigue fractures, further prospective studies on the relationship between bone quality and stress fractures are necessary.
Acknowledgements
The authors thank the ballet dancers for participating in this study.
Conflict of Interest Statement
The authors declare that there is no conflict of interests regarding the publication of this article.