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Vitamin K status is associated with childhood bone mineral content

Published online by Cambridge University Press:  01 October 2008

Marieke J. H. van Summeren*
Affiliation:
Department of Paediatric Immunology, University Medical Centre Utrecht, PO Box 85090, Utrecht, The Netherlands
Silvia C. C. M. van Coeverden
Affiliation:
Department of Public and Occupational Health, EMGO-Institute, VU University Medical Centre, De Boelelaan 1117, 1081 HVAmsterdam, The Netherlands
Leon J. Schurgers
Affiliation:
VitaK and Cardiovascular Research Institute, University of Maastricht, Maastricht, The Netherlands
Lavienja A. J. L. M. Braam
Affiliation:
VitaK and Cardiovascular Research Institute, University of Maastricht, Maastricht, The Netherlands
Florence Noirt
Affiliation:
Danone Research Centre Daniel Carasso, Palaiseau Cedex, France
Cuno S. P. M. Uiterwaal
Affiliation:
Julius Centre for Health Sciences and Primary Care, University Medical Centre Utrecht, Utrecht, The Netherlands
Wietse Kuis
Affiliation:
Department of Paediatric Immunology, University Medical Centre Utrecht, PO Box 85090, Utrecht, The Netherlands
Cees Vermeer
Affiliation:
VitaK and Cardiovascular Research Institute, University of Maastricht, Maastricht, The Netherlands
*
*Corresponding author: Dr Marieke J. H. van Summeren, fax +31 302505349, email [email protected]
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Abstract

In adult bone, vitamin K contributes to bone health, probably through its role as co-factor in the carboxylation of osteocalcin. In children, the significance of vitamin K in bone-mass acquisition is less well known. The objective of this longitudinal study was to determine whether biochemical indicators of vitamin K status are related to (gains in) bone mineral content (BMC) and markers of bone metabolism in peripubertal children. In 307 healthy children (mean age 11·2 years), BMC of the total body, lumbar spine and femoral neck was determined at baseline and 2 years later. Vitamin K status (ratio of undercarboxylated (ucOC) to carboxylated (cOC) fractions of osteocalcin; UCR) was also measured at both time points. Markers of bone metabolism, sex steroids, vitamin D status and growth hormones were measured at baseline only. Large variations in the levels of the UCR were found at both time-points, indicating a substantial interindividual difference in vitamin K status. Improvement of vitamin K status over 2 years (n 281 children) was associated with a marked increase in total body BMC (r − 49·1, P < 0·001). The UCR was associated with pubertal stage, markers of bone metabolism, sex hormones and vitamin D status. A better vitamin K status was associated with more pronounced increase in bone mass in healthy peripubertal children. In order to determine the significance of these findings for childhood bone health, additional paediatric studies are needed.

Type
Full Papers
Copyright
Copyright © The Authors 2008

Several studies in adults suggest a beneficial role for vitamin K in bone mineral metabolism and bone fracture prevention, although precise mechanisms have not been entirely elucidated(Reference Braam, Knapen, Geusens, Brouns, Hamulyak, Gerichhausen and Vermeer1, Reference Feskanich, Weber, Willett, Rockett, Booth and Colditz2). A well-recognized concept is the vital role of vitamin K as a co-factor in the posttranslational carboxylation of osteocalcin, a protein synthesized by osteoblasts(Reference Shearer3). In this carboxylation process, glutamate (Glu) residues are converted into γ-carboxyglutamate (Gla)(Reference Wallin, Sane and Hutson4). The common property of all Gla-proteins is their high affinity for Ca which is essential for their function. Osteocalcin, the most abundant non-collagenous protein found in human bone, consists of forty-nine amino-acids three of which are Gla(Reference Hauschka, Lian and Gallop5, Reference Price, Poser and Raman6). Here, we will designate the 3-Gla molecule as carboxylated osteocalcin (cOC). In order to adequately carboxylate osteocalcin, the osteoblast requires sufficient vitamin K(Reference Koshihara and Hoshi7). In the case of vitamin K deficiency, undercarboxylated osteocalcin (ucOC) will be produced. In the healthy adult population, osteocalcin is carboxylated to a variable extent, suggesting that the dietary vitamin K intake is insufficient for full osteocalcin carboxylation(Reference Binkley, Krueger, Engelke, Foley and Suttie8). Markedly higher osteocalcin carboxylation is obtained by increased vitamin K intake(Reference Binkley, Krueger, Kawahara, Engelke, Chappell and Suttie9, Reference Sokoll, Booth, O'Brien, Davidson, Tsaioun and Sadowski10). Previous studies in postmenopausal women found a clear association between elevated ucOC levels and increased fracture risk(Reference Szulc, Chapuy, Meunier and Delmas11, Reference Vergnaud, Garnero, Meunier, Breart, Kamihagi and Delmas12). Bioavailable vitamin K is mainly derived from nutritional sources such as green leafy vegetables and cheese(Reference Schurgers and Vermeer13).

Research in the elderly population has revealed that serum ucOC and the ratio of ucOC to cOC (UCR) are reliable and stable markers for vitamin K status of bone, and that a high vitamin K intake may improve bone mineral content (BMC) and strength and diminish fracture risk(Reference Feskanich, Weber, Willett, Rockett, Booth and Colditz2, Reference Sokoll, Booth, O'Brien, Davidson, Tsaioun and Sadowski10, Reference Szulc, Chapuy, Meunier and Delmas11, Reference Cockayne, Adamson, Lanham-New, Shearer, Gilbody and Torgerson14, Reference Luukinen, Kakonen, Pettersson, Koski, Laippala, Lovgren, Kivela and Vaananen15). Also in children, the amount of ucOC relative to the total (or carboxylated) osteocalcin is used to study the relationship between vitamin K status and bone health(Reference O'Connor, Molgaard, Michaelsen, Jakobsen, Lamberg-Allardt and Cashman16Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). Using the UCR, we have recently shown that the majority of healthy children have a suboptimal vitamin K status of bone(Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). Additionally, a marked correlation between the bone metabolism markers and the fractions of osteocalcin was found in these children(Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). Recently, another study in a large cohort of healthy girls aged 11–12 years showed that better vitamin K status was associated with increased BMC(Reference O'Connor, Molgaard, Michaelsen, Jakobsen, Lamberg-Allardt and Cashman16).

The objective of the present study was to assess the vitamin K status in healthy children during puberty and to study its association with bone mass and changes in bone mass. In addition, the associations between vitamin K status and biochemical markers of bone metabolism, sex steroids and growth hormones were analyzed.

Subjects and methods

Subjects and design

Originally, this study was designed to evaluate associations between bone markers, sex steroids and (changes in) bone mass throughout puberty in healthy children. The results of this study and a detailed description of the study design were previously published(Reference Coeverden, Netelenbos, Ridder, Roos, Popp-Snijders and Delemarre-van de Waal19). The present study consists of a cross-sectional study at baseline in which the associations between vitamin K status and biochemical markers of bone metabolism, sex steroids and growth hormones are investigated. It also contains a prospective part which assesses the vitamin K status in healthy children during puberty and its association with bone mass and changes in bone mass over 2 years.

A total of 307 children aged between 8 and 14 years, recruited from a number of primary and secondary schools in the villages around Amsterdam, participated in this study. The children were white, reported to be healthy and did not take any medication. At the first visit, height, weight, pubertal development and bone densitometry were measured and serum samples were collected. Height and weight were measured using a stadiometer and a calibrated scale, respectively, subjects wearing underwear only. Pubertal development was assessed in boys on genital stages (G1–5) and in girls on breast stages (B1–5) according to Tanner. After 2·0 (sd 0·10) years, bone densitometry measurement was repeated in 281 children. At this study visit, height, weight and pubertal development were determined for the second time and collection of serum samples took place. Dietary intakes or vitamin K intake were not recorded since validated FFQ that include vitamin K1 (phylloquinone) and all forms of vitamin K2 (menaquinones-n) are not available at present. The study protocol was approved by the Committee of Ethics on Human Research of the VU University Medical Centre.

Collection and preparation of samples

Blood samples were drawn in the morning after overnight fasting. After blood sampling and serum preparation, samples were frozen and kept at − 70°C until use.

Experimental techniques

Serum carboxylated and undercarboxylated osteocalcin

The ucOC and cOC fractions of osteocalcin were measured by ELISA (Takara, Japan). The UCR was used as an indicator of vitamin K status. Elevated levels of the UCR are indicative of an inferior vitamin K status and are related to suboptimal nutritional vitamin K intake(Reference Binkley, Krueger, Engelke, Foley and Suttie8, Reference Sokoll and Sadowski20). Δ-UCR is defined as the difference of the natural log-transformed UCR at follow-up minus baseline. This means that a negative figure for Δ-UCR indicates a decrease in UCR over time which means an improved vitamin K status. Vice versa, a positive figure for Δ-UCR represents an increase in UCR over time, suggesting a deteriorated vitamin K status.

Bone markers

Bone-specific alkaline phosphatase, marker of bone formation, was measured with an assay by wheat germ agglutinin(Reference Bouman, Scheffer, Ooms, Lips and Netelenbos21). Procollagen type-I amino terminal propeptides, marker of bone formation, and type I carboxy terminal telopeptides, marker of bone resorption, were estimated by radioimmunoassay of Orion Diagnostica (Espoo, Finland).

Vitamin D

The level of 25(OH)-vitamin D3 was measured using a competitive binding assay (Nichols) after alcohol extraction. The level of 1,25(OH)2-vitamin D was measured using the IDS-assay (Tyne and Wear, UK).

Hormones

Oestradiol (in girls only) was determined by radioimmunoassay (Sorin Biomedica, Saluggia, Italy) as well as testosterone (in boys only; Coat-A-Count, DPC, Los Angeles, CA, USA). Insulin-like growth factor (IGF)-1 and IGF-BP3 were determined by immunoradiometric assays (DSL, Webster, TX, USA).

All samples were analyzed using the same assay lot run to reduce interassay variation. Levels of ucOC and cOC were determined at baseline and after 2 years; all other biochemical markers of bone metabolism and vitamin D status, sex steroids, IGF-1 and IGF-BP3 measurements were determined at baseline only.

Bone mineral content

BMC (g) and bone size (anterior–posterior projected bone area (cm2)) of the L1–L4 region of the lumbar spine (LS), the femoral neck (FN) and the total body (TB) were measured at baseline and at follow-up with dual-energy X-ray absorptiometry (DEXA) using the Hologic QDR-2000 (Hologic Inc., Waltham, MA, USA). All scans were carried out in the array mode and analyzed by the same investigator. The reproducibility of the different scans has been described previously(Reference Van Coeverden, De Ridder, Roos, Van't Hof, Netelenbos and Delemarre-Van de Waal22). Δ-BMC is defined as the difference in BMC at follow-up minus BMC at baseline.

Statistical methods

Normality of distributions was checked for all study parameters. The distributions of ucOC and UCR, testosterone and oestradiol were skewed to the right, and their absolute values are given as median and range. The data of ucOC, UCR, testosterone and oestradiol were converted to natural logarithms, prior to use in regression- and correlation analyses. Paired samples t tests were used for comparison of continuous parameters (age, height, weight, BMI, bone-DEXA-parameters) between baseline and follow-up. Comparisons of ucOC and UCR between baseline and follow-up were performed using Wilcoxon signed rank-tests. ANOVA was used to compare the distribution of pubertal stages at baseline and after 2 years. Possible associations of anthropometric data with the UCR were investigated using bivariate correlation tests.

In order to explore the association between vitamin K status (UCR), bone markers and hormones, we used multivariate linear regression analysis. The (log-transformed) UCR at baseline was used as dependent variable and bone markers and hormones at baseline as independent variables. Analyses were adjusted for sex, age, pubertal stage, weight and height, but only when these variables were associated with the UCR outcome at P < 0·05. In these analyses, pubertal stage was dichotomized into a prepubertal/early stage (Tanner stage 1–2) v. late/end of puberty-stages (Tanner stage 3–5). Because data on bone markers and hormones after 2 years were lacking, we could not perform their association with vitamin K status at 2 years.

Multiple linear regression analyses were also used to examine the association of (increase in) bone density and (changes in) vitamin K status. Dependent variables were the TB-BMC, LS-BMC and FN-BMC at baseline and at follow-up. In addition, differences (Δ) in TB-BMC, LS-BMC and FN-BMC, indicating gains in BMC over time, were also used as dependent variables. In these analyses, we adjusted BMC for (site-specific) bone size in order to minimize size-related effects on (longitudinal) estimates of bone mass by DEXA, according to the recommendation for children by Prentice et al. (Reference Prentice, Parsons and Cole23). The independent variables of interest in the regression analyses were the UCR at baseline and follow-up, and the changes in UCR (Δ-UCR) over time. Furthermore, besides adjustment for bone size, other potential confounders (sex, age, pubertal stage (early v. late)) were included into the model, but only when these variables were associated with the BMC outcome at P < 0·05. Weight and height were also considered in the models but because of multicollinearity with bone area, these variables were omitted from the definitive models. In the regression analyses for Δ-BMC, besides sex, other potential confounders included in the model were the differences in bone size, weight, height and pubertal stage.

The statistical tests were executed using a two-sided significance level of 5 %. A value of P < 0·05 was considered to be statistically significant. SPSS Base 12.0.2 for Windows (SPSS Inc., Chicago, IL, USA) was used for all analyses.

Results

Anthropometric, dual-energy X-ray absorptiometry- and vitamin K-parameters at baseline and follow-up

In Table 1, the anthropometric variables and DEXA-parameters at baseline and follow-up are shown. Over 2 years time, significant increases in weight, height and BMI were noted. At baseline, most children were prepubertal or in early puberty. Expectedly, more children were found in later pubertal stages after 2 years. As expected, BMC increased significantly in the course of time in all children.

Table 1 Characteristics of the study subjects at baseline and follow up (2 years)

(Values are means with standard deviation or number and percentage*)

DEXA, dual-energy X-ray absorptiometry; BMC, bone mineral content; LS, lumbar spine; FN, femur neck; TB, total body; ucOC, undercarboxylated osteocalcin; cOC, carboxylated osteocalcin; UCR, ratio of ucOC and cOC.

* ucOC and UCR are presented as median and range.

P values are presented for differences in values at baseline and follow-up; P values are based on paired t tests except for pubertal stage (based on ANOVA) and ucOC and UCR (based on Wilcoxon signed-rank test).

Table 1 also shows the levels of ucOC, cOC and UCR at the start of the study and after 2 years. Large ranges in the level of the UCR were found at both time-points, indicating a substantially interindividual difference in vitamin K status. The median ucOC increased significantly from baseline to follow-up whereas the cOC showed a marginal, borderline-significant, increase. However, the median UCR did not change over time.

The UCR at baseline was significantly associated with pubertal stage (r 0·165, P = 0·004), baseline-weight (r 0·183, P = 0·001) and baseline-BMI (r 0·190, P = 0·001). The UCR at follow-up was associated with gains in height (r 0·342, P < 0·01) and weight (r 0·204, P = 0·001) over 2 years.

Associations of vitamin K status with bone markers and hormones (cross-sectional)

In Table 2, the associations of vitamin K status (UCR) with bone markers (resorption and formation), vitamin D status and hormones (growth, sex steroids) at baseline are shown. The UCR was found to have a positive correlation with markers of bone formation (bone-specific alkaline phosphatase and procollagen type-I amino terminal propeptides) and the marker for bone resorption (type I carboxy terminal telopeptides). The UCR was not related to the level of IGF-1 and IGF-BP3. No significant association was found for 25(OH) vitamin D3 and UCR. However, an evident correlation between 1,25-(OH)2 vitamin D and the UCR was found. In girls, oestradiol was associated with the UCR, whereas in boys, testosterone was correlated with the UCR.

Table 2 Bone markers and hormones at baseline and their associations with the ratio of undercarboxylated osteocalcin to carboxylated osteocalcin (UCR)*

(Values are means and standard deviations (medians and ranges for sex steroids) with regression coefficient (B ) and 95 % CI)

BAP, bone-specific alkaline phosphatase; PINP, procollagen type-I amino terminal propeptides; ICTP, type I carboxyterminal telopeptide; IGF-1, insulin-like growth factor-1; IGF-BP3, IGF-1 binding protein 3.

* For details of subjects and procedures Subjects and methods and Table 1.

P values, B and 95 % CI for B are based on multivariate linear regression analyses with natural log-transformed UCR as dependent variable, adjusted for sex, pubertal stage (early v. late) and weight. Log-transformed values of testosterone and oestradiol were used in regression analyses. Direct interpretation of the coefficients requires back transformation to original units.

Associations of bone mineral content and vitamin K status (longitudinal)

Table 3 shows the associations between bone mass and vitamin K status (UCR) at baseline and follow-up. In addition, this table depicts the associations between the increase in BMC and changes in UCR over time. The association of bone mass and vitamin K status was more evident for TB-BMC than for the other sites (FN and LS). At baseline, the UCR was inversely associated with TB-BMC, but this association merely showed a statistical trend. At follow-up, the UCR was inversely associated with TB-BMC after 2 years, even when adjusted for covariates. Considering changes over time, improvement of the UCR was inversely associated with more pronounced increase in whole-body bone mass (Table 3). The association of FN-BMC with vitamin K status was not consistent at the different time-points. At baseline, the UCR was related to FN-BMC whereas at follow-up, no significant association was found. In addition, improvements in UCR were inversely associated with more pronounced increases in FN-BMC. No statistically significant associations were found between LS-BMC and vitamin K status.

Table 3 Associations between (changes in, Δ) bone mineral content (BMC) and (changes in) the ratio of undercarboxylated osteocalcin to carboxylated osteocalcin (UCR). Values (regression coefficient (B ), 95 % CI and ) are based on linear regression analyses with BMC parameters as dependent variables and the natural log-transformed UCR as the variable of interest. Direct interpretation of the coefficients requires back transformation to original units*

TB, total body; LS, lumbar spine; FN, femoral neck.

* For details of subjects and procedures see Subjects and methods.

Adjusted for bone size, age, sex and pubertal stage (early v. late) at baseline.

Adjusted for bone size, age, sex and pubertal stage (early v. late) at follow-up.

§ Adjusted for difference in bone size (follow-up to baseline), difference in bodyweight, difference in body height, sex and differences in pubertal stage.

Δ-UCR is the difference in natural log-transformed UCR at follow up v. baseline. A negative figure for Δ-UCR indicates a decrease in UCR over time. Vice versa, a positive figure for Δ-UCR represents an increase in UCR over time. Higher UCR values indicate an inferior vitamin K status.

Discussion

In the present study in healthy peripubertal children, we have found that gains in whole-body bone mass over 2 years are associated with changes in vitamin K status of bone, even after adjusting for the potential confounders bone size, sex, body-height and -weight, and pubertal stage. Furthermore, vitamin K status was related to BMC, most evident at follow-up. In addition, vitamin K status was associated with markers of bone formation, vitamin D status and sex steroids at baseline.

The relationship between vitamin K status and bone health has already been studied extensively in the adult population(Reference Cockayne, Adamson, Lanham-New, Shearer, Gilbody and Torgerson14). It is recognized that circulating ucOC levels may be useful in predicting fracture rate and relate to bone mass in the elderly(Reference Szulc, Chapuy, Meunier and Delmas11, Reference Knapen, Nieuwenhuijzen Kruseman, Wouters and Vermeer24). Also in healthy children, evidence for the usefulness of the carboxylation of osteocalcin as biochemical marker for vitamin K status is available(Reference O'Connor, Molgaard, Michaelsen, Jakobsen, Lamberg-Allardt and Cashman16Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). In these studies, vitamin K status is expressed as the amount of ucOC relative to the amount of total or cOC. In the present study, better vitamin K status was associated with higher bone mass at baseline and after 2 years of follow-up, although this relation was more evident at follow-up. The associations found were more pronounced for bone mass of the whole body than for site-specific bone mass at FN or LS. It has been suggested that in growing children, the TB-BMC is a preferable outcome measure to monitor changes in overall bone mass over time because it takes bone size and shape of all skeletal regions into account(Reference Nelson and Koo25). The association of current vitamin K status and bone mass in healthy children has also been described in other observational studies(Reference O'Connor, Molgaard, Michaelsen, Jakobsen, Lamberg-Allardt and Cashman16, Reference Kalkwarf, Khoury, Bean and Elliot17). O'Connor and co-workers also found that better vitamin K status, expressed as % cOC, was positively related to current BMC of TB and LS(Reference O'Connor, Molgaard, Michaelsen, Jakobsen, Lamberg-Allardt and Cashman16). Kalkwarf and colleagues found that % ucOC was related to markers of bone turnover in a group of healthy girls(Reference Kalkwarf, Khoury, Bean and Elliot17). In addition, indicators of vitamin K status were not consistently associated with 4-year changes in BMC(Reference Kalkwarf, Khoury, Bean and Elliot17). In our study, we have found similar associations of the UCR and markers of bone turnover. However, in contrast to the findings from the study by Kalkwarf, we have found that improvement of the vitamin K status over time, indicated by a decrease in UCR, is related to an additional increase in BMC. A possible explanation for this divergent finding is that the broad age range of the healthy girls (3–16 years) in the study cohort of Kalkwarf have obscured the relation between vitamin K status and bone mass variables, despite the large number of participants (n 245).

A previous study conducted by our group has shown that the majority of healthy children have a suboptimal vitamin K status, based on the extent of osteocalcin carboxylation. In the latter study, we found high circulating levels of ucOC and high UCR levels in children in comparison with the adult population(Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). Also in the present study, we have found high levels of UCR in children, suggesting a relative vitamin K shortage in bone. Furthermore, the UCR was correlated to pubertal stages, indicating that in advanced pubertal stages, coinciding with highest growth velocities, higher UCR levels are found. Comparable associations of UCR and pubertal development were also observed in our previous study(Reference van Summeren, Braam, Noirt, Kuis and Vermeer18). It may be reasoned that the high levels of UCR result from an imbalance between dietary vitamin K intake and the metabolic requirement for vitamin K during growth. A gradual decline in vitamin K intake in children in recent years is described by Prynne et al. (Reference Prynne, Thane, Prentice and Wadsworth26). In the USA, the RDA for vitamin K in children aged 4–18 years is 55–75 μg vitamin K(27). Bounds and co-workers found an average daily intake of 51 (sd 30) μg vitamin K in American children aged 2–8 years whereas others found a median intake of 45 μg vitamin K per day in American girls aged 3–16 years(Reference Kalkwarf, Khoury, Bean and Elliot17, Reference Bounds, Skinner, Carruth and Ziegler28). In the latter study, wide ranges of the percentage of ucOC (% ucOC) were found, indicating that intakes of vitamin K were not sufficient, despite dietary intakes approximating the RDA. It could also be that the high levels of UCR and ucOC are only a reflection of a physiological situation during normal growth and bone mass acquisition. However, from an evolutionary point of view, it seems unlikely that large amounts of non-functional ucOC are meant to be synthesized. It could also be that a relative vitamin K shortage in this period has no adverse effects as long as levels of cOC (the functional form of osteocalcin) are sufficiently high. In the present study, the average cOC concentrations at baseline and after 2 years did remain constant.

In the present study, we found that vitamin K status was only related to the active form of vitamin D which is 1,25(OH)2 vitamin D levels, and not to 25(OH) vitamin D3. In the literature, the relationship between vitamin D and vitamin K remains subject to debate. Several studies suggest a contribution of vitamin D in osteocalcin expression(Reference Paredes, Arriagada, Cruzat, Villagra, Olate, Zaidi, van, Lian, Stein, Stein and Montecino29). However, vitamin D is not involved in the carboxylation of osteocalcin. The synergistic effect of the combined supplementation of vitamin D and vitamin K on bone mass has been shown in some intervention trials in adults(Reference Braam, Knapen, Geusens, Brouns, Hamulyak, Gerichhausen and Vermeer1, Reference Sato, Honda, Kaji, Asoh, Hosokawa, Kondo and Satoh30).

Our report describes the associations of vitamin K status and bone mass in peripubertal healthy children. One of the limitations of this study may be the lack of longitudinal data on physical activity. Weight-bearing physical activity is another important determinant of bone mass(Reference Bailey, McKay, Mirwald, Crocker and Faulkner31). Nevertheless, it is not likely that physical activity is also a determinant of vitamin K status of bone and therefore not a true confounder. Also, other nutritional factors like Ca metabolism (e.g. urinary Ca excretion or milk intake) or carbonated beverage consumption were not taken into account(Reference Manias, McCabe and Bishop32).

Taking together the findings from the present and other observational studies on vitamin K and bone in children, one may conclude that a suboptimal vitamin K status in children probably has a negative impact on childhood bone health. Whilst (bone) growth continues, the relative lack of vitamin K may lead to inferior bone quality/strength or suboptimal bone mineralization resulting in increased fracture risk. Indeed, an increased fracture risk is observed in healthy children in the peripubertal years because the increase of bone mass fails to keep up with the increase in height(Reference Fournier, Rizzoli, Slosman, Theintz and Bonjour33, Reference Faulkner, Davison, Bailey, Mirwald and Baxter-Jones34). Furthermore, recent data in adults suggest that vitamin K supplementation results in improved bone geometry besides its effect on bone density(Reference Knapen, Schurgers and Vermeer35). Hence, the question remains what happens to bone mass if vitamin K is supplemented in this period of life. We speculate that vitamin K supplementation in healthy adolescents will lead to improved bone health and decreased fracture risk, in analogy to the situation in another population characterized by high bone metabolism, i.e. postmenopausal women(Reference Luukinen, Kakonen, Pettersson, Koski, Laippala, Lovgren, Kivela and Vaananen15, Reference Knapen, Nieuwenhuijzen Kruseman, Wouters and Vermeer24, Reference Szulc, Arlot, Chapuy, Duboeuf, Meunier and Delmas36). An adequate vitamin K status during puberty may lead contribute to a higher peak bone mass, which is the maximal amount of bone mineral accrued during life. Achievement of optimal peak bone mass in adolescence may be a possible strategy in the prevention of osteoporosis in later life(Reference Hernandez, Beaupre and Carter37, Reference Hui, Slemenda and Johnston38). The effect of vitamin K supplementation on bone mass will need to be studied in intervention studies in the adolescent population.

Conclusion

We found that an improved vitamin K status over time is associated with a more pronounced increase in bone mass over 2 years in healthy peripubertal children. In order to determine the significance of these findings, both longitudinal observational studies and placebo-controlled randomized intervention trials in children are needed.

Acknowledgements

The authors thank Marjo Knapen for her indispensable and excellent work in data handling and Kirsten Teunissen for her excellent laboratory work. The authors declare that they have no conflicts of interest. This work was supported by funding from Danone Research Centre Daniel Carasso (NU144, Palaiseau Cedex, France).

References

1Braam, LA, Knapen, MH, Geusens, P, Brouns, F, Hamulyak, K, Gerichhausen, MJ & Vermeer, C (2003) Vitamin K1 supplementation retards bone loss in postmenopausal women between 50 and 60 years of age. Calcif Tissue Int 73, 2126.CrossRefGoogle ScholarPubMed
2Feskanich, D, Weber, P, Willett, WC, Rockett, H, Booth, SL & Colditz, GA (1999) Vitamin K intake and hip fractures in women: a prospective study. Am J Clin Nutr 69, 7479.CrossRefGoogle ScholarPubMed
3Shearer, MJ (2000) Role of vitamin K and Gla proteins in the pathophysiology of osteoporosis and vascular calcification. Curr Opin Clin Nutr Metab Care 3, 433438.CrossRefGoogle ScholarPubMed
4Wallin, R, Sane, DC & Hutson, SM (2002) Vitamin K 2,3-epoxide reductase and the vitamin K-dependent gamma-carboxylation system. Thromb Res 108, 221226.CrossRefGoogle ScholarPubMed
5Hauschka, PV, Lian, JB & Gallop, PM (1975) Direct identification of the calcium-binding amino acid, gamma-carboxyglutamate, in mineralized tissue. Proc Natl Acad Sci USA 72, 39253929.CrossRefGoogle ScholarPubMed
6Price, PA, Poser, JW & Raman, N (1976) Primary structure of the gamma-carboxyglutamic acid-containing protein from bovine bone. Proc Natl Acad Sci USA 73, 33743375.CrossRefGoogle ScholarPubMed
7Koshihara, Y & Hoshi, K (1997) Vitamin K2 enhances osteocalcin accumulation in the extracellular matrix of human osteoblasts in vitro. J Bone Miner Res 12, 431438.CrossRefGoogle ScholarPubMed
8Binkley, NC, Krueger, DC, Engelke, JA, Foley, AL & Suttie, JW (2000) Vitamin K supplementation reduces serum concentrations of under-gamma-carboxylated osteocalcin in healthy young and elderly adults. Am J Clin Nutr 72, 15231528.CrossRefGoogle Scholar
9Binkley, NC, Krueger, DC, Kawahara, TN, Engelke, JA, Chappell, RJ & Suttie, JW (2002) A high phylloquinone intake is required to achieve maximal osteocalcin gamma-carboxylation. Am J Clin Nutr 76, 10551060.CrossRefGoogle ScholarPubMed
10Sokoll, LJ, Booth, SL, O'Brien, ME, Davidson, KW, Tsaioun, KI & Sadowski, JA (1997) Changes in serum osteocalcin, plasma phylloquinone, and urinary gamma-carboxyglutamic acid in response to altered intakes of dietary phylloquinone in human subjects. Am J Clin Nutr 65, 779784.CrossRefGoogle ScholarPubMed
11Szulc, P, Chapuy, MC, Meunier, PJ & Delmas, PD (1996) Serum undercarboxylated osteocalcin is a marker of the risk of hip fracture: a three year follow-up study. Bone 18, 487488.CrossRefGoogle ScholarPubMed
12Vergnaud, P, Garnero, P, Meunier, PJ, Breart, G, Kamihagi, K & Delmas, PD (1997) Undercarboxylated osteocalcin measured with a specific immunoassay predicts hip fracture in elderly women: the EPIDOS Study. J Clin Endocrinol Metab 82, 719724.Google ScholarPubMed
13Schurgers, LJ & Vermeer, C (2000) Determination of phylloquinone and menaquinones in food. Effect of food matrix on circulating vitamin K concentrations. Haemostasis 30, 298307.Google ScholarPubMed
14Cockayne, S, Adamson, J, Lanham-New, S, Shearer, MJ, Gilbody, S & Torgerson, DJ (2006) Vitamin K and the prevention of fractures: systematic review and meta-analysis of randomized controlled trials. Arch Intern Med 166, 12561261.CrossRefGoogle ScholarPubMed
15Luukinen, H, Kakonen, SM, Pettersson, K, Koski, K, Laippala, P, Lovgren, T, Kivela, SL & Vaananen, HK (2000) Strong prediction of fractures among older adults by the ratio of carboxylated to total serum osteocalcin. J Bone Miner Res 15, 24732478.CrossRefGoogle ScholarPubMed
16O'Connor, E, Molgaard, C, Michaelsen, KF, Jakobsen, J, Lamberg-Allardt, CJ & Cashman, KD (2007) Serum percentage undercarboxylated osteocalcin, a sensitive measure of vitamin K status, and its relationship to bone health indices in Danish girls. Br J Nutr 97, 661666.CrossRefGoogle ScholarPubMed
17Kalkwarf, HJ, Khoury, JC, Bean, J & Elliot, JG (2004) Vitamin K, bone turnover, and bone mass in girls. Am J Clin Nutr 80, 10751080.CrossRefGoogle ScholarPubMed
18van Summeren, M, Braam, L, Noirt, F, Kuis, W & Vermeer, C (2007) Pronounced elevation of undercarboxylated osteocalcin in healthy children. Pediatr Res 61, 366370.CrossRefGoogle ScholarPubMed
19Coeverden, SCCMv, Netelenbos, JC, Ridder, CMd, Roos, JC, Popp-Snijders, C & Delemarre-van de Waal, HA (2002) Bone metabolism markers and bone mass in healthy pubertal boys and girls. Clin Endocrinol 57, 107116.CrossRefGoogle ScholarPubMed
20Sokoll, LJ & Sadowski, JA (1996) Comparison of biochemical indexes for assessing vitamin K nutritional status in a healthy adult population. Am J Clin Nutr 63, 566573.CrossRefGoogle Scholar
21Bouman, AA, Scheffer, PG, Ooms, ME, Lips, P & Netelenbos, C (1995) Two bone alkaline phosphatase assays compared with osteocalcin as a marker of bone formation in healthy elderly women. Clin Chem 41, 196199.CrossRefGoogle ScholarPubMed
22Van Coeverden, SC, De Ridder, CM, Roos, JC, Van't Hof, MA, Netelenbos, JC & Delemarre-Van de Waal, HA (2001) Pubertal maturation characteristics and the rate of bone mass development longitudinally toward menarche. J Bone Miner Res 16, 774781.CrossRefGoogle ScholarPubMed
23Prentice, A, Parsons, TJ & Cole, TJ (1994) Uncritical use of bone mineral density in absorptiometry may lead to size-related artifacts in the identification of bone mineral determinants. Am J Clin Nutr 60, 837842.CrossRefGoogle ScholarPubMed
24Knapen, MHJ, Nieuwenhuijzen Kruseman, AC, Wouters, RS & Vermeer, C (1998) Correlation of serum osteocalcin fractions with bone mineral density in women during the first 10 years after menopause. Calcif Tissue Int 63, 375379.CrossRefGoogle ScholarPubMed
25Nelson, DA & Koo, WW (1999) Interpretation of absorptiometric bone mass measurements in the growing skeleton: issues and limitations. Calcif Tissue Int 65, 13.CrossRefGoogle ScholarPubMed
26Prynne, CJ, Thane, CW, Prentice, A & Wadsworth, ME (2005) Intake and sources of phylloquinone (vitamin K(1)) in 4-year-old British children: comparison between 1950 and the 1990s. Public Health Nutr 8, 171180.CrossRefGoogle Scholar
27Food and Nutrition Board, Institute of Medicine (2001) Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Iron, Manganese, Molybdenum, Nickel, Silicon, Vanadium, and Zinc. Washington, DC: National Academy Press.Google Scholar
28Bounds, W, Skinner, J, Carruth, BR & Ziegler, P (2005) The relationship of dietary and lifestyle factors to bone mineral indexes in children. J Am Diet Assoc 105, 735741.CrossRefGoogle ScholarPubMed
29Paredes, R, Arriagada, G, Cruzat, F, Villagra, A, Olate, J, Zaidi, K, van, WA, Lian, JB, Stein, GS, Stein, JL & Montecino, M (2004) Bone-specific transcription factor Runx2 interacts with the 1alpha,25-dihydroxyvitamin D3 receptor to up-regulate rat osteocalcin gene expression in osteoblastic cells. Mol Cell Biol 24, 88478861.CrossRefGoogle ScholarPubMed
30Sato, Y, Honda, Y, Kaji, M, Asoh, T, Hosokawa, K, Kondo, I & Satoh, K (2002) Amelioration of osteoporosis by menatetrenone in elderly female Parkinson's disease patients with vitamin D deficiency. Bone 31, 114118.CrossRefGoogle ScholarPubMed
31Bailey, DA, McKay, HA, Mirwald, RL, Crocker, PR & Faulkner, RA (1999) A six-year longitudinal study of the relationship of physical activity to bone mineral accrual in growing children: the university of Saskatchewan bone mineral accrual study. J Bone Miner Res 14, 16721679.CrossRefGoogle ScholarPubMed
32Manias, K, McCabe, D & Bishop, N (2006) Fractures and recurrent fractures in children; varying effects of environmental factors as well as bone size and mass. Bone 39, 652657.CrossRefGoogle ScholarPubMed
33Fournier, PE, Rizzoli, R, Slosman, DO, Theintz, G & Bonjour, JP (1997) Asynchrony between the rates of standing height gain and bone mass accumulation during puberty. Osteoporos Int 7, 525532.CrossRefGoogle ScholarPubMed
34Faulkner, RA, Davison, KS, Bailey, DA, Mirwald, RL & Baxter-Jones, AD (2006) Size-corrected BMD decreases during peak linear growth: implications for fracture incidence during adolescence. J Bone Miner Res 21, 18641870.CrossRefGoogle ScholarPubMed
35Knapen, MHJ, Schurgers, LJ & Vermeer, C (2007) Vitamin K(2) supplementation improves hip bone geometry and bone strength indices in postmenopausal women. Osteoporos Int 18, 963972.CrossRefGoogle ScholarPubMed
36Szulc, P, Arlot, M, Chapuy, MC, Duboeuf, F, Meunier, PJ & Delmas, PD (1994) Serum undercarboxylated osteocalcin correlates with hip bone mineral density in elderly women. J Bone Miner Res 9, 15911595.CrossRefGoogle ScholarPubMed
37Hernandez, CJ, Beaupre, GS & Carter, DR (2003) A theoretical analysis of the relative influences of peak BMD, age-related bone loss and menopause on the development of osteoporosis. Osteoporos Int 14, 843847.CrossRefGoogle ScholarPubMed
38Hui, SL, Slemenda, CW & Johnston, CC (1990) The contribution of bone loss to postmenopausal osteoporosis. Osteoporos Int 1, 3034.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Characteristics of the study subjects at baseline and follow up (2 years)(Values are means with standard deviation or number and percentage*)

Figure 1

Table 2 Bone markers and hormones at baseline and their associations with the ratio of undercarboxylated osteocalcin to carboxylated osteocalcin (UCR)*(Values are means and standard deviations (medians and ranges for sex steroids) with regression coefficient (B ) and 95 % CI)

Figure 2

Table 3 Associations between (changes in, Δ) bone mineral content (BMC) and (changes in) the ratio of undercarboxylated osteocalcin to carboxylated osteocalcin (UCR). Values (regression coefficient (B ), 95 % CI and ) are based on linear regression analyses with BMC parameters as dependent variables and the natural log-transformed UCR as the variable of interest. Direct interpretation of the coefficients requires back transformation to original units*