|Year : 2019 | Volume
| Issue : 1 | Page : 27-34
Effect of vitamin D supplementation on bone turnover markers in children and adolescents from North India
Raman K Marwaha1, MK Garg2, A Mithal3, Sushil Gupta4, Manoj Shukla5, Aditi Chadha6
1 International Life Science-India, Lajpat Nagar, New Delhi, India
2 Department of Medicine and Endocrinology, All India Institute of Medical Sciences, Jodhpur, Rajasthan, India
3 Department of Endocriology, Medanta Hospital, Gurgram, Haryana, India
4 Department of Endocriology, Sanjay Gandhi Postgraduate Institute, Lucknow, Uttar Pradesh, India
5 Department of Dermatology, All India Institute of Medical Sciences, New Delhi, India
6 Department of Medicine, Dr. B R Sur Homeopathic Medical College, New Delhi, India
|Date of Web Publication||18-Mar-2019|
Raman K Marwaha
Flat No. 17, Gautam Apartments, Gautam Nagar, New Delhi - 110 049
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Objectives: Vitamin D is known to play an important role in bone mineral metabolism. Its deficiency may affect growth and status of bone markers in children. Hence, we undertook to study the status of bone markers in children with vitamin D deficiency (VDD) and impact of vitamin D3 supplementation on them. Materials and Methods: Total 468 out of 615 children and adolescents with VDD, who were given either of the three doses (600, 1000, and 2000) of vitamin D supplementation, were included in the study. These 468 children with pre- and postsupplementation preserved samples with available anthropometry, serum biochemistry, 25-hydroxy-vitamin D, and parathormone were evaluated for bone formation (procollagen type 1 amino-terminal propeptide [P1NP]) and resorption (β-cross laps [CTx]) markers. Results: The mean age and body mass index of these children were 11.3 ± 2.3 years (boys: 11.5 ± 2.4; girls: 12.2 ± 1.2 years; P = 0.03) and 18.1 ± 3.8 kg/m2 (boys: 18.2 ± 3.9; girls: 17.6 ± 3.2 kg/m2; P = 0.208), respectively. There were 8.8% subjects with severe, 42.7% with moderate, and 48.5% with mild VDD. There was a significant decline in serum P1NP (from 691 ± 233 ng/ml to 640 ± 259 ng/ml, P < 0.001) and CTx (from 1.67 ± 0.53 ng/ml to 1.39 ± 0.51 ng/ml, P < 0.001) following supplementation. Though decline in serum P1NP and CTx levels was observed in both boys and girls, among all three supplementation groups and VDD categories, the effect was more marked in serum CTx than P1NP levels. Conclusions: Vitamin D supplementation in VDD children resulted in decrease in both bone formation (P1NP) and resorption (CTx). The impact, however, was more marked on bone resorption than bone formation.
Keywords: β-Cross laps, bone markers, parathormone, procollagen type-1 amino-terminal propeptide, serum 25OHD, vitamin D deficiency
|How to cite this article:|
Marwaha RK, Garg M K, Mithal A, Gupta S, Shukla M, Chadha A. Effect of vitamin D supplementation on bone turnover markers in children and adolescents from North India. Indian J Endocr Metab 2019;23:27-34
|How to cite this URL:|
Marwaha RK, Garg M K, Mithal A, Gupta S, Shukla M, Chadha A. Effect of vitamin D supplementation on bone turnover markers in children and adolescents from North India. Indian J Endocr Metab [serial online] 2019 [cited 2019 Aug 19];23:27-34. Available from: http://www.ijem.in/text.asp?2019/23/1/27/254437
| Introduction|| |
Vitamin D is required by all age groups to not only maintain calcium homeostasis, bone mineralization, and skeletal health but also derive many extraskeletal benefits. Presently, vitamin D deficiency (VDD) is recognized as a global epidemic., Despite adequate sunshine, VDD has been reported among all age groups from India.,,,,, It is attributed to poor sun exposure, dark skin complexion, atmospheric pollution, vegetarian foods habits, absence of food fortification with vitamin D, and poor intake of vitamin D supplements., There is defective bone formation and mineralization in subjects with VDD. Increasing severity of VDD results in secondary hyperparathyroidism with resultant increased formation of active vitamin D for maintaining normal serum calcium levels. This would lead to increase in the bone resorption and increase in bone resorption markers., Hence, it is logical to hypothesize that vitamin D supplementation in VDD children and adolescents will result in increase in bone formation and decrease in bone resorption markers. However, the available reports in literature are conflicting. Vitamin D supplementation has been shown to decrease bone resorption markers in some studies,,, whereas one study reported decrease in both formation and resorption markers. Most studies, however, reported no change in bone resorption or formation markers with vitamin D supplementation.,,,,,,, A negative association between serum 25-hydroxy-vitamin D (25OHD) and resorption markers reported among children and adolescents with VDD or insufficiency in cross-sectional studies,,,,, no longer persisted following vitamin D supplementation. Likewise, studies conducted among vitamin D sufficient adolescents did not reveal any association between serum 25OHD and bone markers.,,,,,
In view of widely prevalent VDD in children and adolescents in India,, and conflicting observations in literature with regard to relationship between vitamin D and bone markers, we undertook this study to evaluate the correlation between serum 25OHD and bone markers and impact of vitamin D supplementation on serum bone formation [procollagen type 1 amino-terminal propeptide (P1NP)] and bone resorption [β-cross laps (CTx)] markers among VDD children and adolescents.
| Materials and Methods|| |
The present study was a subpart of another study performed in four fee paying schools in Delhi (Latitude N 28.38°, E 77.12°), India, with consent from school authorities, parents/guardians, and verbal assent from children. Parents were asked to sign the consent form after they were provided with the details of the study in the patient information sheet and their interaction with the principal investigator to clear their doubts. The details of screening, selection of subjects, and supplementation with vitamin D in the original study are shown in consort diagram [Figure 1]. Subjects suffering from any systemic illness, consuming drugs affecting bone mineral metabolism such as calcium, vitamin D, glucocorticoids, antitubercular or antiepileptics, or inability to consume vitamin D capsules orally, and having serum 25OHD >20 ng/ml were excluded from the study. Subjects were cluster randomized and divided in three groups for supplementation with soft gelatin vitamin D3 capsules (D-rise ®) every day for a period of 6 months (Group “A” –600 IU, Group “B” –1000 IU, and Group “C” –2000 IU). Supplementation of vitamin D was done for six working days per week under supervision of teachers and investigating staff. For Sundays and planned school holidays, parents were provided with the vitamin D capsules to be supplemented at home and asked to maintain monthly record. The study protocol was approved by Institute Ethical committee of the institute. This trial was registered as clinical trial registration number: CTRI: 2017/01/007681.
Anthropometry measurements such as height, weight, and body mass index (BMI) were noted at baseline. Height was measured to the nearest 0.1 cm using portable wall mounted stadiometer (Holten's Stadiometer, 200 cm/78 in, Model WS045, Narang Medical Limited, Delhi, India) with subjects standing straight with head held in the Frankfurt plane. Weight, without shoes and light clothes on, was measured to the nearest 0.1 kg, using an electronic scale (EQUINOX Digital weighing machine, Model EB6171, Equinox Overseas Private Limited, New Delhi, India). BMI was defined as the ratio of body weight-to-height square and was expressed in kg/m 2. Weight categories were defined by revised criteria by Indian Association of Pediatrics. Participants above adult equivalent of BMI of 23 were defined as overweight and those above adult equivalent of BMI of 27 were defined as obese.
Blood samples were collected in the fasting state between 08:00 h and 09:00 h, centrifuged and serum separated into four aliquots at the study site, and transported in dry ice (−60°C) to the laboratory where they were stored in −20°C. Serum calcium, phosphorus, and alkaline phosphatase (ALP) were estimated on the same day, whereas serum 25OHD and parathormone (PTH) were estimated within 1 week of sample collection. Total 468 subjects, whose untouched baseline and postsupplementation samples were available for measurement of serum P1NP and CTx later, were included in the study. Serum calcium, serum phosphate, and ALP were measured by commercially available kit using automated biochemistry analyzer Cobas C-501 (Roche Diagnostics, Manheim, Germany). The normal range for serum total calcium for 2–12 years was 8.8–10.8 and 8.4–10.5 mg/dl for 12–18-year-old children with analytical sensitivity 0.2 mg/dl, inorganic phosphorus was 3.1–5.3 mg/dl in 7–12-year-old and 2.8–4.8 in 13–16-year-old children with analytical sensitivity 0.3 mg/dl, and ALP for 10–<13 years: 129–417 U/l, 13–<15 years: 57–254 U/l, 15–<18 years: 50–117 U/l for girls; and 10–<13 years: 129–417 U/l, 13–<15 years: 116–468 U/l, 15–<18 years: 82–331 U/l for boys with analytical sensitivity 5 U/l. Serum P1NP (reference range: 5–1200 ng/ml), CTx (reference range: 0.01–6.0 ng/ml), and PTH (reference range: 10–65 pg/ml, interquartile range 34.31 pg/ml) were measured by commercially available kits (Roche Diagnostics GmbH, Sandhofer Strasse 116, D-68305, Mannheim, Germany). Intra- and interassay coefficient of variations were <5% for all assay. The serum 25OHD was assayed using chemiluminescence method (Diasorin, Stillwater, MN, USA). Intra- and interassay coefficient of variation was 3.5% and 5% for serum 25OHD. Serum 25OHD level of <20 ng/ml was defined as VDD. VDD was further classified as severe (25OHD <5 ng/ml), moderate (25OHD <10 ng/ml), and mild (25OHD <20 ng/ml). Blood samples were repeated 6 months after intervention.
Analysis was performed using SPSS 20.0 (Chicago, IL, USA). Descriptive statistics were calculated as mean and standard deviations (95% confidence interval). Differences among various parameters between genders were analyzed by Student's t test. Analysis of variance was used to study the difference in the mean of various parameters, among other groups. Paired t test was applied to calculate significance level of various parameters pre- and postsupplementation. Serum PTH was not normally distributed, hence expressed as median and range, and was analyzed with Mann–Whitney, Kruskal–Wallis, and Wilcoxon signed-rank test. Bonferroni correction was used to assess significance of bone markers between quartiles of PTH. Pearson's correlation was used to evaluate relation between various parameters and serum P1NP and CTx levels. A P < 0.05 was considered statistically significant.
| Results|| |
The baseline demographic and biochemical characteristics of 468 study subjects as per gender and VDD categories are shown in [Table 1] and [Table 2], respectively. The mean age and BMI of the children were 11.3 ± 2.3 years (boys: 11.5 ± 2.4; girls: 12.2 ± 1.2 years; P = 0.03) and 18.1 ± 3.8 kg/m 2 (boys: 18.2 ± 3.9; girls: 17.6 ± 3.2 kg/m 2; P = 0.208), respectively. Boys had significantly higher BMI, serum calcium, phosphates, and CTx levels whereas girls had higher serum ALP and PTH levels [Table 1]. Fifty-three participants (11.3%) were obese [boys: 67 (11.5%); girls: 20 (4.7%)] and 88 (18.8%) were overweight [boys: 113 (19.3%); girls: 74 (17.5%)]. There were 8.8% (41) participants with severe, 42.7% (200) with moderate, and 48.5% (227) with mild VDD. There was no significant difference in various parameters except BMI among the three VDD groups [Table 2].
|Table 2: Basic characteristics of study population according to vitamin D status|
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Serum P1NP status
A significant overall decrease in mean baseline serum P1NP level from 691 ± 233 to 640 ± 259 ng/ml (paired t test <0.0001) was noted following supplementation [Table 3]. This decrease was observed in both boys (689 ± 225 vs. 646 ± 250 ng/ml; P = 0.003) and girls (701 ± 278 vs. 607 ± 300 ng/ml P < 0001), different supplementation groups, and all three VDD categories except in mild VDD category where it did not achieve statistical significance [Table 4]. Similar decline in serum P1NP was also observed in all weight categories postsupplementation, but statistical significance was achieved in only normal weight children.
|Table 4: Effect of vitamin D supplementation on serum levels of P1NP and CTx in various groups|
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Baseline and postsupplementation values of serum P1NP within the group were no different in boys and girls, different weight categories, supplementation groups, and vitamin D deficient categories [Table 4]. Significant incremental response in serum P1NP levels with increasing serum PTH values from 1st to 4th PTH quartiles was noted both at baseline and postsupplementation. However, significant decline in serum P1NP following supplementation was limited to 1st to 4th PTH quartiles only [Table 5] and [Figure 2].
|Figure 2: Bone formation (P1NP) and bone resorption marker (CTx) (Pre- and post vitamin D supplementation) according to serum paratharmone quartiles|
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Serum CTx status
The overall mean baseline serum CTx (1.67 ± 0.53 ng/ml) decreased significantly following supplementation (1.39 ± 0.50 ng/ml, P < 0.001). This significant reduction in serum CTX was observed only in boys (1.70 ± 0.51 vs. 1.38 ± 0.51 ng/ml, P < 0.0001) but not in girls (1.47 ± 0.60 vs. 1.40 ± 0.55 ng/ml, P = 0.273), all weight categories, supplementation groups, and VDD categories in paired analysis [Table 4].
No intragroup differences were observed in the baseline and postsupplementation values of serum CTx among different supplementation groups and VDD categories. Similarly, no significant difference was noted in different weight categories in the presupplementation values, but a significant difference did show up between normal weight and obese/overweight subjects following supplementation [Table 4], P < 0.007].
Unlike P1NP, serum CTx values did not differ among different quartiles of PTH at baseline, but the values showed significant incremental increase from 1st to 4th quartile following supplementation. The serum CTx values were significantly higher in the 4th quartile of PTH when compared to the 1st quartile [Table 5] and [Figure 2].
Correlation between serum 25OHD and bone markers
Baseline serum P1NP levels were positively correlated with serum phosphates (r = 0.271, P < 0.0001), ALP (r = 0.364, P < 0.0001), PTH (r = 0.271, P < 0.0001), and CTx (r = 0.465, P < 0.0001) but not with age (r = −0.036, P = 0.434), BMI (r = −0.090, P = 0.052), serum calcium (r = −0.058, P = 0.207), and baseline 25OHD (r = −0.089, P = 0.055).
Baseline serum CTx levels were also positively correlated with age (r = 0.096, P = 0.038), serum phosphates (r = 0.270, P < 0.0001), ALP (r = 0.233, P < 0.0001), PTH (r = 0.163, P < 0.0001), and P1NP (r = 0.465, P < 0.0001). It was not correlated with BMI (r = −0.026, P = 0.570), calcium (r = −0.093, P = 0.055), and baseline 25OHD (r = −0.025, P = 0.585).
Postsupplementation serum P1NP and CTx levels maintained similar correlations in above mentioned parameters except for BMI which now had acquired a significant negative correlation with serum P1NP (r = −0.109, P = 0.018) and CTX (r = −0.1146, P = 0.002) levels.
| Discussion|| |
Vitamin D is an essential micronutrient not only for bone health but also for normal growth and development in children and adolescents. Its deficiency causes rickets in children, which is characterized by defective bone formation and mineralization and increased bone resorption due to secondary hyperparathyroidism required to maintain calcium homeostasis. With this background, it is reasonable to assume that vitamin D supplementation in VDD should affect both bone formation and resorption. Impact of supplementation on bone turn over can be seen early by evaluating bone formation and resorption markers, but its effect on bone density and fracture rate would require a large, long-term population-based study. The effect of vitamin D3 supplementation on bone markers in children, however, has not been well studied.
Significant decrease in serum P1NP, observed in boys and girls following vitamin D supplementation, was also reported in another study involving VDD youths with HIV, who were supplemented 120,000 IU/month for 12 months. In contrast, vitamin D supplementation among 14 children with rickets resulted in a transient rise initially (2–4 weeks) followed by reduction in serum P1NP with continued supplementation. Most studies, however, have reported no effect on bone formation markers (bone-specific ALP, serum osteocalcin, serum P1NP) following vitamin D supplementation.,,,,,,,,,, Absence of any impact on serum P1NP may be either due to smaller supplemental doses (100–600 IU) of vitamin D ,,,,,, shorter duration of supplementation (4–12 weeks),,,, or higher baseline serum 25OHD levels ,,,,, before starting supplementation, when compared with the present study.
The decrease in serum P1NP was significant in all three supplementation groups and VDD categories except in mild category. This can be explained based on relationship of serum P1NP with serum PTH levels. There were increasing levels of serum P1NP from 1st to 4th quartile of PTH along with a strong positive correlation with PTH (r = 0.271, P < 0.0001). Though there was a parallel decrease in serum P1NP and PTH following supplementation, decrease in serum P1NP levels was significant only in the 1st and 4th quartiles of PTH. This suggests that bone remodeling requires optimal levels of serum PTH. A low level of PTH may be associated with low bone formation and high levels of PTH with high bone turnover. Hence, suppression of PTH with vitamin D supplementation is associated with decrease in bone formation in 1st PTH quartile and decrease in bone turnover with decrease in serum PTH in 4th quartile. This would also explain absence of significant change in serum P1NP in mild VDD group (serum PTH range 12.6–122.8 with mean on 49.8 ± 21.5 pg/ml), which is associated with PTH levels in optimal range. Absence of correlation between serum P1NP and baseline serum 25OHD, observed in the present study, was also reported in a German and Swiss adolescents.,
The significant decrease in serum CTx was observed in all three supplementation groups, VDD categories, and weight categories. Viljakainen et al. similarly reported decrease in bone resorption marker (urinary deoxypyridinoline) following vitamin D supplementation for 1 year in 212 girls. A decrease in bone resorption markers was also observed in young jockeys  and adolescents with HIV. Barocelli et al., in contrast, described a transient rise in bone resorption markers [cross-linked carboxyterminal telopeptide of type I collagen and cross-linked N-telopeptides of type I collagen (NTX)] in 14 children with rickets after 2–4 weeks of vitamin D supplementation, followed by a gradual decline with continued supplementation. Most studies, however, reported no change in bone resorption markers after vitamin D supplementation.,,,,,,, The explanation for no change in serum CTx is similar to what has been described for serum P1NP.
Absence of correlation between serum CTx and baseline serum 25OHD (r = −0.025, P = 0.585) also observed in one other study. This was in contrast to a large population-based study reporting an inverse correlation between serum CTx and serum 25OHD. Lack of correlation between serum CTx values and VDD categories similarly differed from the reported lower urinary deoxypyridinoline values in Chinese girls with VDD when compared to those with normal serum 25OHD levels.
Serum PTH was a strong predictor of serum CTx (r = 0.163, P < 0.0001) and showed an incremental trend with increasing quartile of PTH in pre- and postsupplementation assessment. Rajakumar et al. also found PTH to be a significant predictor of serum CTx levels after adjusting for race, season, Tanner stage, dietary calcium, skin color, and BMI.
Baseline serum P1NP and CTx levels were not significantly different among weight categories. Why significant decrease in P1NP in normal weight children as against significant decline in serum CTx in overweight and obese kids, following supplementation, is not understood? On the contrary, Rajakumar et al. showed significant decrease in serum osteocalcin, BAP, and urine NTX in normal and obese children.
In present study, two interesting findings were (a) reduction in bone formation and resorption markers post-vitamin D supplementation, and (b) decline in bone resorption marker was significantly more than the bone formation marker in all the groups analyzed. This raises question about conventional understanding that VDD causes rickets and osteomalacia due to defective bone formation and mineralization. If it was due to defective bone formation, these markers (a) should have increased after vitamin D supplementation, and (b) baseline bone formation markers should have been lower in severe VDD compared to mild VDD subjects. The results, however, are contrary to the above assumptions. In the absence of differences in bone resorption marker among VDD categories, the decrease in serum CTx was significantly greater as compared to serum P1NP, suggesting that participants with VDD had more abnormalities of bone resorption than bone formation. Since decline in both bone formation and resorption following vitamin D supplementation suggests decrease in bone turnover, it may not be out of context to say that rickets and osteomalacia are diseases primarily of high bone turnover rather than defective bone formation. This high bone turnover is predicted by serum PTH levels rather than serum 25OHD levels. This is further corroborated by significantly high serum P1NP and serum CTx in 4th quartile of PTH when compared to other quartiles pre- and postsupplementation, and a strong positive correlation between serum P1NP and CTx (r = 0.465, P < 0.0001). Thus, it can be hypothesized that VDD is characterized by high bone turnover (bone resorption > bone formation), which manifests in the presence of high PTH levels. A similar observation had been reported by us in our previous study, where bone mineral density among adolescents became significantly lower at higher quartiles of PTH but was not affected by various levels of serum 25OHD. This study further emphasizes the fact that while defining VDD, serum PTH and/or bone markers should be taken into consideration.,
The main strength of our study was a large cohort of Indian school children with VDD evaluated for bone turnover markers and impact of vitamin D supplementation in them. The major limitations of the study were (a) noninclusion of control/placebo arm and (b) inability to assess their lifestyle and pubertal status due to social and administrative reasons.
| Conclusions|| |
Vitamin D supplementation leads to decrease in both bone formation (P1NP) and resorption (CTx) markers in children and adolescents with VDD. This effect is seen with all doses of vitamin D supplementation (600, 1000, and 2000 IU), in all VDD and weight categories. The effect is more marked on bone resorption when compared to bone formation. This suggests that VDD is characterized by bone resorption more than bone formation, which is akin to postmenopausal osteoporosis. Hence, chronic VDD in children and adolescents may predispose them to risk of osteoporosis at an early age.,
We gratefully acknowledge USV private limited, India for providing vitamin D3 capsules for the trial. We thank Mr D H Pai Panandiker, Chairman, and Ms Rekha Sinha, CEO, international Life Sciences Institute (India) for sponsoring the project. We highly appreciate the support of the principals, parents, and children for participating in this trial. We would like to put on record our appreciation for the help rendered by Ms Pamela Marwaha, Dr S K Mathur, and Ms Neeru Gandhi of Society for Endocrine Health for Elderly, Adolescents and Children (SEHEAC) for their valuable contribution toward this project.
Financial support and sponsorship
This study was financially supported by R and D Nestle, India.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Holick MF. The vitamin D deficiency pandemic and consequences for nonskeletal health: Mechanisms of action. Mol Asp Med 2008;29:361-8.
Palacios C, Gonzalez L. Is vitamin D deficiency a major global public health problem? Steroid Biochem Mol Biol 2014;144Pt A:138-45.
Cheng L. The convergence of two epidemics: Vitamin D deficiency in obese school-aged children. J Pediatr Nurs 2018;38:20-6.
Gupta R, Gupta A. Vitamin D deficiency in India: Prevalence, causalities and interventions. Nutrients 2014;6:729-75.
Puri S, Marwaha RK, Agarwal N, Tandon N, Agarwal R, Grewal K, et al.
Vitamin D status of apparently healthy schoolgirls from two different socioeconomic strata in Delhi: Relation to nutrition and lifestyle. Br J Nutr 2008;99:876-82.
Marwaha RK, Tandon N, Reddy DR, Aggarwal R, Singh R, Sawhney RC, et al.
Vitamin D and bone mineral density status of healthy schoolchildren in northern India. Am J Clin Nutr 2005;82:477-82.
Garg MK, Marwaha RK, Khadgawat R, Ramot R, Obroi AK, Mehan N, et al.
Efficacy of Vitamin D loading doses on serum 25-hydroxy vitamin D levels in school going adolescents: An open label non-randomized prospective trial. J Pediatr Endocrinol Metab 2013;26:515-23.
Marwaha RK, Tandon N, Garg MK, Kanwar RS, Narang A, Sastry A, et al.
Vitamin D status in healthy Indians aged 50 years and above. J Assoc Phys India 2011;59:706-9.
Marwaha RK, Tandon N, Chopra S, Agarwal N, Garg MK, Sharma B, et al
. Vitamin D status in pregnant Indian women across trimesters and different seasons and its correlation with neonatal serum 25(OH) D levels. Br J Nutr 2011;31:1-7.
Marwaha RK, Goswami R. Vitamin D deficiency and its health consequences in India. In: Holick MF, editor. Vitamin D: Physiology, molecular biology, and clinical applications, 2nd
ed.. New York: Humana Press; 2010. p. 529-42.
Need AG. Bone resorption markers in vitamin D insufficiency. Clin Chim Acta 2006;368:48-52.
Ryan JW, Anderson PH, Turner AG, Morris HA. Vitamin D activities and metabolic bone disease. Clin Chim Acta 2013;425:148-52.
Silk LN, Greene DA, Baker MK, Jander CB. Tibial bone responses to 6-month calcium and vitamin D supplementation in young male jockeys: A randomised controlled trial. Bone 2015;81:554-61.
Viljakainen HT, Natri AM, Kärkkäinen M, Huttunen MM, Palssa A, Jakobsen J, et al.
A positive dose-response effect of vitamin D supplementation on site-specific bone mineral augmentation in adolescent girls: A double-blinded randomized placebo-controlled 1-year intervention. J Bone Miner Res 2006;21:836-44.
Baroncelli GI, Bertelloni S, Ceccarelli C, Amato V, Saggese G. Bone turnover in children with vitamin D deficiency rickets before and during treatment. Acta Paediatr 2000;89:513-8.
Eckard AR, O'Riordan MA, Rosebush JC, Ruff JH, Chahroudi A, Labbato D, et al.
Effects of Vitamin D supplementation on bone mineral density and bone markers in HIV-infected youth. J Acquir Immune Defic Syndr 2017;76:539-46.
Neyestani TR, Hajifaraji M, Omidvar N, Nikooyeh B, Eshraghian MR, Shariatzadeh N, et al.
Calcium-vitamin D-fortified milk is as effective on circulating bone biomarkers as fortified juice and supplement but has less acceptance: A randomised controlled school-based trial. J Hum Nutr Diet 2014;27:606-16.
Hill KM, Laing EM, Hausman DB, Acton A, Martin BR, McCabe GP, et al.
Bone turnover is not influenced by serum 25-hydroxyvitamin D in pubertal healthy black and white children. Bone 2012;51:795-9.
Rajakumar K, Moore CG, Yabes J, Olabopo F, Haralam MA, Comer D, et al.
Effect of Vitamin D3 supplementation in black and in white children: A randomized, placebo-controlled trial. J Clin Endocrinol Metab. 2015;100:3183-92.
Mølgaard C, Larnkjaer A, Cashman KD, Lamberg-Allardt C, Jakobsen J, Michaelsen KF. Does vitamin D supplementation of healthy Danish Caucasian girls affect bone turnover and bone mineralization? Bone 2010;46:432-9.
Andersen R, Mølgaard C, Skovgaard LT, Brot C, Cashman KD, Jakobsen J, et al.
Effect of vitamin D supplementation on bone and vitamin D status among Pakistani immigrants in Denmark: A randomised double-blinded placebo-controlled intervention study. Br J Nutr 2008;100:197-207.
Ambroszkiewicz J, Klemarczyk W, Gajewska J, Chełchowska M, Strucińska M, Ołtarzewski M, et al
. Effect of vitamin D supplementation on serum 25-hydroxyvitamin D and bone turnover markers concentrations in vegetarian children. Med Wieku Rozwoj 2009;13:34-9.
Barnes MS, Robson PJ, Bonham MP, StrainJJ, Wallace JM. Effect of vitamin D supplementation on vitamin D status and bone turnover markers in young adults. Eur J Clin Nutr 2006;60:727-33.
Schou AJ, Heuck C, Wolthers OD. Vitamin D supplementation to healthy children does not affect serum osteocalcin or markers of type I collagen turnover. Acta Paediatr 2003;92:797-801.
Thiering E, Brüske I, Kratzsch J, Hofbauer LC, Berdel D, von Berg A, et al.
Associations between serum 25-hydroxyvitamin D and bone turnover markers in a population based sample of German children. Sci Rep 2015;5:18138.
Foo LH, Zhang Q, Zhu K, Ma G, Hu X, Greenfield H, Fraser DR. Low vitamin D status has an adverse influence on bone mass, bone turnover, and muscle strength in Chinese adolescent girls. J Nutr 2009;139:1002-7.
Rajakumar K, Holick MF, Moore CG, Cohen E, Olabopo F, Haralam MA, et al.
Impact of seasonal flux on 25-hydroxyvitamin D and bone turnover in pre- and early pubertal youth. Pediatr Int 2014;56:35-42.
Meier C, Woitge HW, Witte K, Lemmer B, Seibel MJ. Supplementation with oral vitamin D3 and calcium during winter prevents seasonal bone loss: A randomized controlled open-label prospective trial. J Bone Miner Res 2004;19:1221-30.
Woitge HW, Knothe A, Witte K, Schmidt-Gayk H, Ziegler R, Lemmer B, et al.
Circa-annual rhythms and interactions of vitamin D metabolites, parathyroid hormone, and biochemical markers of skeletal homeostasis: A prospective study. J Bone Miner Res 2000;15:2443-50.
Ginty F, Cavadini C, Michaud PA, Burckhardt P, Baumgartner M, Mishra GD, et al.
Effects of usual nutrient intake and vitamin D status on markers of bone turnover in Swiss adolescents. Eur J Clin Nutr 2004;58:1257-65.
Khadilkar V, Yadav S, Agrawal KK, Tamboli S, Banerjee M, Cherian A, et al.
Revised IAP growth charts for height, weight and body mass index for 5- to 18-year-old Indian children. Indian Academy of Pediatrics Growth Charts Committee. Indian Pediatr 2015;52:47-55.
Rosen, CJ, Abrams, SA, Aloia JF, Brannon PM, Clinton SK, Clinton SK, et al
. The 2011 report on dietary reference intakes for calcium and vitamin D from the institute of medicine: What clinicians need to know. J Clin Endocrinol Metab 2011;96:53-8.
Lips P. Vitamin D deficiency and secondary hyperparathyroidism in the elderly: Consequences for bone loss and fractures and therapeutic implications. Endocr Rev 2001;22:477-501.
Rajakumar K, Fernstrom JD, Holick MF, Janosky JE, Greenspan SL. Vitamin D status and response to Vitamin D (3) in obese vs. non-obese African American children. Obesity (Silver Spring) 2008;16:90-5.
Garg MK, Tandon N, Marwaha RK, Menon AS, Mahalle N. The relationship between serum 25-hydroxy-vitamin D, parathormone and bone mineral density in Indian population. Clin Endocrinol 2014;80:41-46.
Sai AJ, Walters RW, Fang X, Gallagher JC. Relationship between vitamin D, parathyroid hormone, and bone health. J Clin Endocrinol Metab 2011;96:E436-46.
Garg MK, Mahalle N. Calcium absorption, clinical and subclinical vitamin D deficiency. Can “Intestinal calcistat” hypothesis explain it all? Medical hypotheses. 2013;81:253-8.
Marwaha RK, Tandon N, Garg MK, Kanwar R, Narang A, Sastry A, et al.
Bone health status in healthy Indians aged 50 years and above. Osteoporos Int 2011;22:2829-36.
Mithal A, Bansal B, Kyer CS, Ebeling P. The Asia-Pacific Regional audit-epidemiology, costs, and burden of osteoporosis in India 2013: A report of International Osteoporosis Foundation. Indian J Endocrinol Metab 2014;18:449-54.
[Figure 1], [Figure 2]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]