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Minerals and vitamins in bone health: the potential value of dietary enhancement

Published online by Cambridge University Press:  01 April 2009

Jean-Philippe Bonjour*
Affiliation:
Division of Bone Diseases, University Hospital, Rue Micheli-Du-Crest, 1211Geneva, Switzerland
Léon Guéguen
Affiliation:
Human Nutrition and Food Safety, French National Institute for Agricultural Research (INRA), Paris, France
Cristina Palacios
Affiliation:
Department of Human Development, Program of Nutrition, Graduate School of Public Health, University of Puerto Rico, San Juan, PR, USA
Martin J. Shearer
Affiliation:
Vitamin K Research Unit, Centre for Haemostasis and Thrombosis, St Thomas's Hospital, London, UK
Connie M. Weaver
Affiliation:
Department of Foods and Nutrition, Purdue University, West Lafayette, IN, USA
*
*Corresponding author: Professor Jean-Philippe Bonjour, fax +41 223829973, email [email protected]
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Abstract

Nutrition is important to bone health, and a number of minerals and vitamins have been identified as playing a potential role in the prevention of bone diseases, particularly osteoporosis. Despite this, there is currently no consensus on maximum levels to allow in food or as dietary supplements. The benefits of supplementation of populations at risk of osteoporosis with Ca and vitamin D are well established. Prolonged supplementation of Ca and vitamin D in elderly has been shown to prevent bone loss, and in some intervention studies to prevent fragility fractures. Although P is essential to bone health, the average intake is considered to be more than sufficient and supplementation could raise intake to adverse levels. The role of vitamin K in bone health is less well defined, though it may enhance the actions of Ca and vitamin D. Sr administered in pharmacological doses as the ranelate salt was shown to prevent fragility fractures in postmenopausal osteoporosis. However, there is no hard evidence that supplementation with Sr salts would be beneficial in the general population. Mg is a nutrient implicated in bone quality, but the benefit of supplementation via foodstuffs remains to be established. A consensus on dietary supplementation for bone health should balance the risks, for example, exposure of vulnerable populations to values close to maximal tolerated doses, against evidence for benefits from randomised clinical trials, such as those for Ca and vitamin D. Feedback from community studies should direct further investigations and help formulate a consensus on dietary supplementation for bone health.

Type
Review Article
Copyright
Copyright © The Authors 2009

With the ageing of the population, particularly in Europe, the financial impact on national healthcare systems associated with the management of the diseases of the elderly is expected to increase dramatically in the coming years(1). Bone diseases will represent a sizable proportion of these costs. The worldwide financial impact of osteoporotic fractures is estimated to double by 2050 to reach 76·7 billion euros(24). In Europe, hospitalisation costs for hip fractures alone currently represent more than 3·5 billion euros each year(Reference Kanis and Johnell3, 4).

In 1994, the WHO defined osteoporosis as a disease ‘characterized by low bone mass and microarchitectural deterioration of bone tissue, leading to bone fragility and a consequent increase in risk of fracture’(5). In Europe, it is estimated that 179 000 men and 611 000 women suffer a hip fracture every year(Reference Melton, Gabriel and Crowson6), and these numbers are expected to double in the next 40 years, as the demographic situation in Europe evolves and the population ages(4). Although the whole population is at risk, the likelihood of developing osteoporosis increases according to various factors including sex, age, family or fracture history, and Caucasian or Asian ethnic origins(7Reference Nevitt, Cummings and Stone9). Nevertheless, preventive measures are also important since, for example, lack of exercise, smoking, and alcohol consumption have also been identified as risk factors(Reference Nguyen, Kelly and Sambrook10, Reference Law and Hackshaw11). A diet rich in vitamin D and Ca is also recognised as playing a major role in the prevention of osteoporosis(7, Reference Prentice, Schoenmakers and Laskey12).

Osteomalacia is due to a defect of bone mineralisation resulting in weakened and fragile bones and could also lead to hip fractures(Reference Favus13). It is the adult equivalent of rickets in children and affects approximately 1 in 1000 individuals in Western societies(Reference Riaz, Alam and Umer14). Like rickets, osteomalacia is mainly caused by insufficient exposure to sunlight uncompensated by the dietary intake of vitamin D(Reference Favus13). Some defects in vitamin D metabolism or action can also lead to impaired bone matrix mineralisation(Reference Favus13). Renal diseases and phosphate depletion are also among the major causes of osteomalacia(Reference Favus13). Maintaining appropriate intakes of vitamin D, if sunlight exposure is insufficient, and Ca constitutes the best prevention strategy.

Nutrition should form part of bone disease prevention strategies(Reference Huang, Himes and McGovern15), especially in the light of the ageing of the population and the effect of diet on bone health. Bone mass peaks at about the age of 18 years and, at skeletal sites such as the proximal femur, it declines thereafter with an acceleration after 50 years of age(7). The acquisition of bone mineral mass during childhood, adolescence and early adulthood is an important factor determining the risk of osteoporosis in later adult life. Nevertheless, to what extent modifications in environmental factors, such as nutrition and/or physical activity, can influence the risk of osteoporotic fracture in late adhultbood is not known(Reference Bonjour, Chevalley and Rizzoli16).

Because of the influence of cultural environment on nutritional habits, there are very differing opinions on the subject of dietary enhancement and bone health, even regarding the health benefits and safety of the numerous vitamin and mineral supplements available. Although the value of nutrients such as Ca and vitamin D for bone health is well established, a European consensus on maximum levels to allow in food supplementation is still lacking. Moreover, P, vitamin K, Sr and Mg have also been cited as playing a role in bone health. The present paper aims to review the minerals and vitamins that are currently being discussed as part of a supplementation strategy to prevent bone disease. We will therefore discuss Ca, P, vitamin D, vitamin K, Sr and Mg. For each, we examine the bone health benefits, the risks, interactions, and consequences on health, and the normal dietary intake and deficiencies, in order to review the safety and the need for supplementation. As a strategy for finding the most relevant publications we performed a detailed search in the main scientific available databases.

General description of dietary recommendation designations

In the present review, recommended dietary intake (RDI) is used as a generic designation for reference or recommended values for population nutrient intakes. Otherwise, the precise term by the national authority that sets the reference or recommended value is used. In France, RDI for Ca and P, as designated by the term ‘apports nutritionnels conseillés’, is similar to the former US RDA. In the USA and Canada, the term ‘dietary reference intake’ was more recently adopted as nutrient reference standards, in replacement of the former Canadian RDI and US RDA. Dietary reference intake includes the ‘estimated average requirement’, RDA, ‘adequate intake’ and ‘tolerable upper intake level’. As clearly defined by Barr(Reference Barr17), estimated average requirement is the average daily intake level that meets the requirements of 50 % of healthy individuals in a life stage and sex group, whereas the RDA is set at a level that will meet the requirements of almost all (97·5 %) individuals in that life stage and sex group. An adequate intake is a recommended intake level that is thought to meet the needs of almost all healthy individuals, and is set when there are insufficient data to establish an estimated average requirement and therefore an RDA. The tolerable upper intake level represents a threshold above which adverse effects of excessive intake may increase. In the USA, dietary reference intake corresponds to RDA for P and Mg and to adequate intake for Ca, vitamin D and vitamin K. In the UK, ‘reference nutrient intake’, ‘estimated average requirement’ and ‘lower nutrient reference intake’ are used for nutrients with sufficient data to set one recommended level. The term ‘safe and adequate intake’ is used when too few studies are available to set the other dietary reference values.

Calcium

Bone health and benefits

In the form of hydroxyapatite, Ca10 (PO4)6 (OH)2, Ca and P constitute the mineral substance of the skeleton and teeth, which contain 99 % of the adult body's Ca and over 80 % of its P. These two elements therefore play a major role in bone strength and are of prime nutritional importance in osteoporosis(18). Bone loss can be slowed in the elderly by Ca intake, which reduces the risk of hyperparathyroidism, which in turn promotes bone resorption. The importance of Ca supplementation for bone health is well established and, together with vitamin D, is considered as a key component of any preventive or therapeutic regimen for osteoporosis(18).

The beneficial effect of long-term Ca and vitamin D supplementation on bone and fracture risk in elderly women has also been documented in several clinical trials(18Reference Prince, Devine and Dhaliwal21). A recent report from the Women's Health Initiative (WHI) study(Reference Jackson, LaCroix and Gass22) indicated that prolonged Ca supplementation (plus vitamin D) in healthy postmenopausal women significantly improved bone mineral content (BMD) at the hip. A significant 29 % relative decrease in the risk of hip fracture was recorded, but only among participants who adhered to the Ca+vitamin D supplementation(Reference Jackson, LaCroix and Gass22). A large study in the UK, the Randomised Evaluation of Calcium Or vitamin D (RECORD) trial(Reference Grant, Avenell and Campbell23) did not find significant anti-fracture efficacy associated with supplementation, but this study had poor compliance and analysed the secondary prevention of fracture. Two recent meta-analyses of randomised controlled trials concluded that additional Ca is needed with vitamin D to reduce the risk of hip fracture and highlighted the importance of compliance with supplementation in reducing fracture risk(Reference Boonen, Lips and Bouillon24, Reference Tang, Eslick and Nowson25).

Nutritional properties

Although Ca has numerous vital functions and is implicated in the incidence of several pathological disorders, the physiological requirements for this element have been principally established on the basis of bone criteria(26Reference Guéguen and Martin28). As bone also serves as a hormonally mediated exchangeable reservoir of Ca and P, which is mainly intended to maintain blood Ca at normal levels, it is considered that, by meeting the requirements of bone, the extracellular and intracellular needs of other tissues will also be covered.

Intake from diet

A good proportion of dietary Ca (60–70 %) comes from milk and dairy products. In most European countries(Reference Pointillart and Guéguen29), cheeses in adults and yoghurts in children and teenagers are particularly important sources of Ca. With the exceptions of almonds, dried fruit, small bony fish, and a few green vegetables, common foodstuffs are poor in Ca(Reference Pointillart and Guéguen29, Reference Miller30). Where flour is fortified with Ca as in the United Kingdom, foods such as bread, biscuits and cakes can make a substantial contribution to total Ca intake. Some mineral waters are rich in calcium bicarbonate, while others are particularly rich in calcium sulfate.

RDI for Ca vary between countries and regions. There is no consensus in Europe, adult RDI varying from 700 mg/d (reference nutrient intake)(27) in the UK to 1000 mg in Austria, Germany, Switzerland and The Netherlands. In France, RDI are 900 mg/d in adults(Reference Guéguen and Martin28) and 1200 mg/d for adolescents, postmenopausal women and the elderly. The American daily adequate intakes are 1000 mg for adults, 1300 mg for adolescents, and 1200 mg for postmenopausal women and the elderly(26).

Necessity to enhance the calcium intake

Recent surveys in France have indicated that mean Ca intake is 1040 mg/d for boys and 820 mg/d for girls between 10 and 18 years of age, 850 mg/d for male adults under 65 years and 790 mg/d over 65 years, 770 mg/d for women under 50 years and 690 mg/d over 50 years, and 500 to 600 mg/d for elderly women in residential care(Reference Guéguen and Martin28). This suggests that there is a need for enhancing Ca intake, preferably by the consumption of more Ca-rich foods, in teenage girls (200–300 mg/d), postmenopausal women and the elderly (250–300 mg/d), and elderly women in residential care (500–600 mg/d).

These values relate to median intakes in individuals with a diet containing dairy products. However, a diet that does not include dairy products cannot provide more than 400–450 mg Ca/d, unless intake of Ca-rich mineral water is high. In such cases, the need for Ca enhancement is greater and could reach 650 mg/d.

Maximal levels of intake

In France, the upper limit of Ca intake deemed safe when consumed for a prolonged period is 2 g/d, compared with 2·5 g/d in the American recommendations and by the Scientific Committee on Food of the European Commission(31). This Commission considered that the data were insufficient to derive an upper limit value for children from that of 2·5 g/d set for adults(31). Hypercalcaemia, alkalosis, and renal and other ectopic calcifications may result if these limits are regularly exceeded over a long period. For example, in the WHI study, in which the average Ca intake was 2·15 g/d (combined with vitamin D) over 7 years in postmenopausal women, there was a 17 % increase in kidney stones(Reference Jackson, LaCroix and Gass22), though this may have occurred in subjects who were taking additional Ca supplementation, which was allowed in this trial. High doses of Ca can also reduce the absorption of other essential minerals, such as Fe, Zn and Mg(Reference Whiting and Wood32). The UK Food Standards Agency did not establish a safe upper limit for total dietary Ca(33), but suggests daily doses of supplementary Ca not higher than 1·5 g/d(34). A diet rich in dairy products, plus mineral water containing high concentrations of Ca, can provide more than 2 g Ca/d, and a supplement would not then be advisable. In most cases, except with a dairy-free diet, the prescribed daily dose should not exceed 400–500 mg Ca/d for nutritional purposes, which is less than the maximum dose of 800 mg/d adopted in France.

Choice of calcium supplementation

Solubility and bioavailability

The water solubility of the Ca supplement is not a precondition of its biological efficacy, since the intestinal absorption of Ca depends little on solubility in food(Reference Heaney, Recker and Weaver35). The intestinal absorption of Ca from the insoluble calcium carbonate salt is as good as that of Ca from various organic sources and from milk(Reference Allen36Reference Zhao, Martin and Weaver42). However, solubility should be taken into account for the enrichment of beverages or when supplements are presented as liquids. In the case of powder or tablets, the solubility of the salt is not determinant, except in the extreme cases of highly insoluble salts that are resistant to stomach acids.

Bioavailability in the gut and for bone is the first criterion to take into account when selecting a Ca salt. Good intestinal absorbability is required, but it is only the first step in terms of bioavailability for both bone mineral accretion and bone loss prevention, particularly in the elderly. Some dietary factors influence bone Ca accretion and/or resorption, as well as urinary Ca excretion. Thus, all these factors will determine the overall bioavailability of various Ca salts.

Mineral or organic salts

Various Ca salts are already authorised for the manufacture of food supplements: mineral salts such as carbonate, chloride, oxide, hydroxide and phosphate, and organic salts such as citrate, gluconate, glycerophosphate, pidolate and lactate. Comparative studies have been done on all these salts, and their bioavailability in the intestine is deemed good, at about 25–35 % for moderate intakes, which is of the same order of magnitude as the Ca of milk, which is often taken as a reference(Reference Guéguen and Pointillart41). Other Ca salts are the subjects of requests for exemption from Directive 2002/46/EC authorising use in food supplements, inasmuch as they are already marketed for this purpose in the European Community(43).

Several Ca salts or complexes of amino acids, glycinate, l-aspartate, l-lysinate and l-methionate, which are already authorised as sources of amino acids, pose no problem of toxicity and, despite a lack of data in human subjects, the bioavailability of Ca is probably good, but not significantly better than that of mineral salts. The malate (already authorised as a food additive, E 352), pyruvate and succinate salts of Ca are well-known organic acid salts and can be unreservedly authorised. Malic acid is abundant in various fruits and vegetables, and several studies have shown that the bioavailability of calcium citrate-malate is very good, and often greater than that of the Ca of milk(Reference Guéguen and Pointillart41, Reference Smith, Heaney and Flora44). The value of a pyruvate or succinate salt is less clear, and no evidence of the safety of a high intake has been published. Other organic sources, such as calcium ethanolamine phosphate and calcium orotate, are probably bioavailable, but nothing guarantees the safety of the anionic moiety, several grams per d of which would be ingested at the doses prescribed for Ca. A Ca chelate of amino acids, principally in the form of bisglycinate, is often presented as a source of Ca with excellent absorbability, notably due to chelation, which protects it until it reaches the site of absorption. Unfortunately, published studies are too scarce to confirm this.

Calcium silicate is authorised as an additive in food technology, but cannot be considered as a source of Ca. It is an inert and insoluble substance whose bioavailability in the gut is certainly very low. Anhydrous or hydrated calcium sulfate is already authorised in the European Union as a food additive (E 516). The absorbability of the Ca is probably good(Reference Martin, Weaver and Heaney45). However, excess sulfate is likely to increase urinary loss of Ca and therefore decrease the efficacy of its bone retention(Reference Brandolini, Guéguen and Boirie46). In addition, maximum supplementation of 800 mg Ca/d with this salt would provide nearly 2 g sulfate/d, which is close to the laxative dose, particularly as the consumption of sulfate-rich mineral water would raise intake to >3 g/d. Finally, dietary intake of sulfate well below the previous doses appears to be responsible for the production of hydrogen sulfide in the colon by sulfate-reducing bacteria, which can damage the epithelium(Reference Florin, Neale and Goretski47). The deleterious effects of excess sulfate on urinary loss of Ca and on the epithelial structure of the colon were not taken into account in an approval formulated by the European Food Safety Authority(48). Before stating that high doses of calcium sulfate are completely safe, it would be advisable to conduct further clinical studies.

Phosphorus

Bone health and benefits

Like Ca, the nutritional requirements for P are determined by bone criteria. The current French RDA are 750 mg P/d in adults and 800 mg P/d in adolescents and the elderly(Reference Guéguen and Martin28). Similar values are reported in the USA (700 mg/d in all age groups)(26), but lower values in the UK (550 mg/d in adults)(27).

In contrast to Ca, all common foodstuffs (milk, meat, eggs, vegetables and cereals) are naturally rich in P, whose mean intake in Europe ranges from 1300 to 1600 mg/d(Reference Guéguen and Martin28). P intake may be greater in the case of excessive consumption of foods (for example, ham, processed cheese, surimi) to which phosphate salts, notably polyphosphates, are used as additives. This additional intake of P from processed foods can amount to about 100 mg/d in France, but it can be much higher in the USA(Reference Calvo and Park49). P deficiency is therefore rare in humans and so supplementation would be pointless, or even harmful, except in unusual cases of low-energy diets or the regular use of antacids, which render P insoluble, or in patients with hypophosphataemic osteomalacia. A tricalcium phosphate supplement was shown to be efficacious in the prevention of hip fractures(Reference Chapuy, Arlot and Duboeuf19), but its main purpose is to supply Ca without decreasing the Ca:P ratio (close to 2 in tricalcium phosphate, compared with just 0·6 in the diet).

Risk, nutritional interactions, and consequences on bone health

Systematic excess of dietary P is inevitable since P content cannot be reduced in common foods(Reference Guéguen and Martin28). This relative excess of P, compared with Ca, is likely to increase blood phosphate levels, which could lead to Ca metabolism disorders because of a drop in the plasma concentration of ionised Ca, and secondary hyperparathyroidism. This adverse effect of excess P on bone remodelling and on the incidence of osteoporosis has been studied extensively and should not be overlooked(Reference Calvo and Park49Reference Calvo, Whiting and Barton52). Other potential consequences of P excess are ectopic calcifications, particularly in the kidney, diarrhoea, mild gastrointestinal symptoms, and interactions with the intestinal absorption of certain trace elements (Fe, Cu and Zn). P supplementation would then worsen the situation and even sometimes exceed the safety limit of 2·5 g/d adopted in France(Reference Guéguen and Martin28).

Upper tolerable intake levels for P were established in the USA in 1997 at 3 g/d for infants and adolescents and 4 g/d for adults(26). These levels took into account the observations that P is not toxic, there are few studies showing an effect of a high intake on parathyroid hormone (PTH) secretion associated with bone loss, and PTH can exert an anabolic action on osteoblastic formation. However, these high upper levels have been questioned(Reference Guéguen and Martin28). Studies indicating the absence of an effect of excess P used only moderate levels (1·6–2·3 g/d) or diets containing sufficient Ca, particularly from milk and cheese(Reference Heaney and Recker53, Reference Bizik, Ding and Cerklewski54). Conversely, a high P intake associated with low Ca and/or vitamin D supply gives rise to secondary hyperparathyroidism(Reference Calvo and Park49) favouring an increase in bone resorption or an inactivation of the first stages of bone formation(Reference Karkkainen and Lamberg-Allardt55). Moreover, excess P decreases renal synthesis of calcitriol(Reference Calvo and Park49).

The conclusions of a more recent and extensive European review of the effects of high P intakes(56) did not support the suggestion that induced temporary hyperparathyroidism due to high P intake increases bone resorption, stating that normal healthy individuals can tolerate P intake up to at least 3 g/d without adverse systemic effects. Among the thirteen cited studies concerning the effect of high P intake on serum PTH and bone, only two were less than 11 years old(Reference Whybro, Jagger and Barker57, Reference Grimm, Muller and Hein58) and did not report a significant effect. However, the Ca intake in these trials was sufficient for the requirements of young adult men (800 mg/d)(Reference Whybro, Jagger and Barker57) or very high (1995 mg/d) for young adult women(Reference Grimm, Muller and Hein58).

According to another expert group of the Food Standards Agency(33, 34), using the same published data, changes in PTH levels were found in supplemental studies in postmenopausal women with reduced BMD and a history of fractures, and in healthy men. Changes in plasma Ca and PTH have been associated with intakes ≥ 1500 mg supplemental P/d. The expert group could not establish a safe upper limit for total inorganic P, but estimated that a total intake of 2400 mg/d would not be expected to result in any adverse effect when regularly consumed over a long period. This value is in good agreement with a previous estimation(Reference Guéguen and Martin28) and takes into account all the potential deleterious effects (nephrocalcinosis and gastrointestinal symptoms) as end points to derive an upper level and a no-observed-adverse-effect level of 250 mg supplemental P/d. The maximum daily intake of 450 mg P/d from supplements defined in France corresponds to P combined with a large intake of calcium phosphate with a view to supplying Ca, and could be lowered. Higher levels of P intakes are unnecessary, even for food technology, and should be avoided.

Futhermore, a recent report suggests that higher serum P levels are associated with an increased risk of CVD(Reference Dhingra, Sullivan and Fox59). This increased risk appears to be unrelated to chronic renal failure or prior CVD. However, it is not established whether this epidemiological association is related to the P intake per se or alternatively to an anomaly in the tubular reabsorption of P, the main physiological determinant of the serum P level. Furthermore, since a high serum P concentration leads to lower circulating levels of ionised Ca, which, in turn, will tend to increase PTH secretion, the possible role of hyperparathyroidism in the incidence of CVD documented in this observational study cannot be ruled out(Reference Dhingra, Sullivan and Fox59).

Vitamin D

Vitamin D has been the focus of much interest and research in the past decade. The roles of vitamin D in Ca absorption and in preventing rickets and osteomalacia in adults are well established. Recent work on methods for vitamin D analysis of foods and serum has enabled more populations to be surveyed for vitamin D status. Surprisingly, vitamin D deficiency and insufficiency are widespread, even at geographical locations near the equator, due to the inability to synthesise adequate vitamin D on exposure to the sun because of dark skin, or habits that limit exposure to UVB radiation. Intervention and dose–response studies have shown health benefits at higher levels than were previously thought to be the upper limit deemed to be safe when exposed for a prolonged period.

Bone health and benefits

Nutritional properties

Vitamin D can come from the diet or from subcutaneous production from 7-dehydrocholecalciferol upon exposure to UVB radiation. There is rapid conversion to cholecalciferol, which is slowly converted to 25-hydroxyvitamin D (25(OH)D) by the liver. Serum levels of this metabolite are considered to be the best indicator of vitamin D status. Renal conversion of small amounts of 25(OH)D to the active form of vitamin D, 1,25-dihydroxyvitamin D (1,25(OH)2D), occurs in response to PTH levels, which increase when serum Ca levels fall or if serum concentrations of inorganic phosphate are low. This form of vitamin D acts on the intestine to enhance active Ca absorption by up-regulating synthesis of Ca transport proteins and on the bone to increase resorption. These actions occur in order to maintain serum Ca levels within the normal range. Without 1,25(OH)2D, Ca absorption would occur only by the passive, intercellular route(Reference Heaney and Weaver60).

Although rickets and osteomalacia have long been associated with vitamin D deficiency rather than inadequate production of 1,25(OH)2D, there has been a rejuvenated interest in the direct effect of 25(OH)D on bone. Adult serum 25(OH)D levels are more positively associated with Ca absorption efficiency than are serum 1,25(OH)2D levels(Reference Barger-Lux, Heaney and Lanspa61, Reference Devine, Wilson and Dick62), and supplementing with vitamin D or 25(OH)D increases Ca absorption efficiency(Reference Heaney63). In contrast, serum 1,25(OH)2D, but not 25(OH)D, predicts Ca absorption in children, as would be expected by the classic model for homeostatic regulation by the vitamin D–PTH axis(Reference Abrams, Griffin and Hawthorne64). Serum 25(OH)D levels have been inversely related to serum PTH levels in both adults(Reference Chapuy, Arlot and Duboeuf19, Reference Thomas, Lloyd-Jones and Thadhani65) and children(Reference Abrams, Griffin and Hawthorne64, Reference Guillemant, Taupin and Le66, Reference Gordon, DePeter and Feldman67). In the elderly, increased bone resorption is the main concern with secondary hyperparathyroidism. In children, despite suppression of serum PTH, vitamin D status or supplementation has little impact on bone measures(Reference Abrams, Griffin and Hawthorne64, Reference Lehtonen-Veromaa, Mottonen and Nuotio68, Reference Cheng, Tylavsky and Kroger69). One study showed a modest benefit to bone in Lebanese girls given higher levels of vitamin D3 than in other studies, i.e. 14 000 IU (350 μg)/week, for 1 year(Reference El-Hajj Fuleihan, Nabulsi and Tamim70). This resulted in significant benefits in gain of total hip bone mineral content (BMC) and area, but not at other sites including femoral neck, trochanter, and total body(Reference El-Hajj Fuleihan, Nabulsi and Tamim70).

Lean mass increased significantly with vitamin D supplementation, which can have an impact on bone through increased muscle mass stress. One study has shown significant advantages of 400 IU (10 μg)/d vitamin D supplementation on bone mineral accretion at the spine and femur in 11-year-old Danish girls(Reference Viljakainen, Natri and Karkkainen71). However, another study suggested that larger doses may be necessary to increase BMC in Pakistani immigrant adolescent girls in Denmark(Reference Andersen, Molgaard and Skovgaard72).

In contrast to children, there is increasing evidence that higher vitamin D status and vitamin D supplementation can positively influence predictors of osteoporosis and fracture in adults. In the Third National Health and Nutrition Examination Survey (NHANES III), serum 25(OH)D was positively associated with hip BMD in 13 432 subjects aged 20 years and older within the reference range of the Diasorin assay for serum 25(OH)D(Reference Bischoff-Ferrari, Dietrich and Orav73). A meta-analysis of five randomised controlled trials on hip fracture and seven on non-vertebral fracture showed that vitamin D intakes of 700–800 IU (17·5–20 μg)/d reduced the relative risk (RR) of hip fracture by 26 % (RR 0·74; 95 % CI 0·61, 0·88) and non-vertebral fracture by 23 % (RR 0·77; 95 % CI 0·68, 0·87) compared with the control group(Reference Bischoff-Ferrari, Willett and Wong74). Two large trials in the UK, the RECORD trial(Reference Grant, Avenell and Campbell23) and one by Porthouse et al. (Reference Porthouse, Cockayne and King75), and one in the USA, the WHI(Reference Jackson, LaCroix and Gass22), did not achieve significant anti-fracture efficiency with vitamin D supplementation. This may be due to low vitamin D levels of supplementation in the case of the WHI trial or to poor compliance in the RECORD and WHI trials. The size of the effect with 800 IU (20 μg) vitamin D1/d in the Porthouse et al. trial(Reference Porthouse, Cockayne and King75) was similar to that of the meta-analysis(Reference Bischoff-Ferrari, Willett and Wong74), but the CI was much wider and included the number 1. The conclusion of two other meta-analyses(Reference Boonen, Lips and Bouillon24, Reference Avenell, Gillespie and Gillespie76) underscored that the beneficial effect on hip fracture prevention required the combination of vitamin D with Ca and appeared to be stronger in frail elderly confined to institutions, as shown in the classical trial by Chapuy et al. (Reference Chapuy, Arlot and Duboeuf19).

Bischoff-Ferrari et al. (Reference Bischoff-Ferrari, Dawson-Hughes and Willett77) conducted a meta-analysis of randomised controlled trials for the relationship between serum 25(OH)D and the risk of falling. Pooled data from 1237 subjects from five trials showed that vitamin D supplementation reduced the risk of falling by 22 %(Reference Bischoff-Ferrari, Dawson-Hughes and Willett77). Fall reduction may be more pronounced in less active older women, but physical activity and vitamin D may not be related in older men(Reference Bischoff-Ferrari, Orav and Dawson-Hughes78). Assessment of lower-extremity function through functional measures, such as the sit-to-stand test and the 8-foot walk test, have been measured as predictors of fracture risk because muscle function is thought to indicate susceptibility to falls(Reference Boland79, Reference Visser, Deeg and Lips80). Muscle-specific 1-hydroxylases convert 25(OH)D into 1,25(OH)2D in muscle, and nuclear receptors for 1,25(OH)2D have been identified that lead de novo protein synthesis and improved muscle function(Reference Bischoff-Ferrari, Willett and Wong74, Reference Bischoff, Borchers and Gudat81, Reference Zehnder, Bland and Williams82). Lower-extremity function increased throughout the reference range of serum 25(OH)D, but especially up to 40 nmol/l, in 4100 ambulatory elderly adults who participated in NHANES III(Reference Bischoff-Ferrari, Dietrich and Orav73). In Lebanese children, vitamin D supplementation increased accrual of lean mass over 1 year, which explained much of the effect of vitamin D supplementation on total hip BMC and area accrual(Reference El-Hajj Fuleihan, Nabulsi and Tamim70).

Intake from diet

In the absence of adequate exposure to sunlight, the current American dietary reference intake for vitamin D in the form of cholecalciferol is 200 IU (5 μg)/d for adults, rising to 600 IU (15 μg)/d in the elderly (>70 years)(26). However, most of the daily input of vitamin D comes from cutaneous synthesis rather than from diet. Moreover, the inadequacy of food composition databases with respect to vitamin D limits an accurate estimate of intake, beyond the usual difficulties individuals experience in accurately remembering and recording their food consumption patterns. Thus, vitamin D intake from diet is not evaluated in most studies.

Natural food sources are mostly fatty fish, fish liver oils, and the fat of fish-eating animals. In countries such as Northern Europe where fatty fish is a major constituent of the diet, intakes of vitamin D have been estimated to be as high as 236 IU (5·9 μg)/d for women and 272 IU (6·8 μg)/d for men(Reference Calvo, Whiting and Barton52). In countries where fortification is prevalent, vitamin D-fortified foods are the major dietary source of vitamin D. Vitamin D status is the highest in countries with mandatory vitamin D fortification, i.e. the USA and Canada for milk and margarine, and lowest in countries with little or no vitamin D fortification (including Europe)(Reference Calvo, Whiting and Barton52). A recent estimate of average vitamin D intakes in the USA from NHANES III was < 400 IU ( < 10 μg)/d(Reference Moore, Murphy and Keast83). Intakes in UK were estimated as half that in the USA. It could be explained by less use of vitamin D supplements as well as by reduced levels of fortification of dairy products with vitamin D compared with the USA(Reference Calvo, Whiting and Barton52). The levels of fortification in the USA range from 100 IU (2·5 μg) vitamin D per cup (237 ml) of milk or fortified juice to more modest amounts in cereal bars, cheese and other processed foods(Reference Weaver and Fleet84). Quality control of the levels of vitamin D added to foods has been a problem because of the lack of a quick, reliable test for vitamin D in foods at the site of manufacture and difficulties associated with dispersing and stabilising this fat-soluble vitamin(Reference Chen, Shao and Heath85).

Necessity to supplement a normal diet

A number of individuals and groups have called for an increase in vitamin D intakes over current recommendations. The criterion for the current requirements and the proposed higher levels of vitamin D intakes are based on adequate serum levels of 25(OH)D. When the current requirements were set, the strategy was to use observed population ranges in serum levels of 25(OH)D. However, serum levels vary with habits that affect sunlight exposure, skin type and colouring, and, to a lesser extent than previously thought, geographical location relative to the equator(Reference Lips, Duong and Oleksik86).

More recently, efforts have been focused on optimal serum 25(OH)D levels for various functional outcome measures. For adults, Bischoff-Ferrari et al. (Reference Bischoff-Ferrari, Orav and Dawson-Hughes78) evaluated the evidence for a threshold serum 25(OH)D level for establishing optimal vitamin D status for multiple bone-related outcomes as outlined above, as well as other health outcomes, and concluded that serum 25(OH)D concentrations should be at least 75 nmol/l, and, better still, between 90 and 100 nmol/l. This level is in line with recommendations of others(Reference Dawson-Hughes, Heaney and Holick87Reference Vieth, Bischoff-Ferrari and Boucher89), but remains a subject of debate(Reference Dawson-Hughes, Heaney and Holick87). To achieve this level through diet would require average vitamin D intakes of 1700 IU (42·5 μg)/d(Reference Vieth, Bischoff-Ferrari and Boucher89) and possibly more for dark-skinned individuals(Reference Weaver and Fleet84). The recent emphasis on dietary sources stems from increasing reports that input from sunlight is becoming inadequate for many populations due to habits that limit sunlight exposure, skin type and pigmentation, and concern about the link between sunlight exposure and melanoma. Clearly, the intakes required to achieve the vitamin D status recommended by some cannot be achieved by diet alone given the current food supply. In fact, such intakes would be difficult to achieve from vitamin D supplements available to date. Only recently have vitamin D supplements been made commercially available that could be used to achieve intakes approaching 2000 IU (50 μg)/d. Calvo et al. (Reference Calvo, Whiting and Barton52) estimated that dietary supplements in some countries contribute 6 to 47 % of the average vitamin D intakes, and this can be predicted to grow with the increased availability of vitamin D supplements.

Risk, nutritional interactions, and consequences on bone health

Given the low levels of vitamin D in natural foods, dietary vitamin D excesses are rare. Reports of hypervitaminosis D have occurred with accidental overdoses.

The risks of hypervitaminosis D are typically associated with hypercalcaemia arising from a vitamin D-dependent increase in the intestinal absorption of Ca and bone resorption. Adverse effects can include polyuria, pain, conjunctivitis, anorexia, fever, chills, thirst, vomiting and weight loss. Hypervitaminosis D can also lead to calcification of soft tissue(26). The risk of vitamin D intoxication can be monitored by measuring several biochemical indices to ensure they fall within normal ranges. According to the US Food and Nutrition Board(26), cases of vitamin D intoxication were associated with serum 25(OH)D ranging from 400 to 1250 nmol/l and serum Ca from 2·82 to 4·00 mmol/l, i.e. markedly above the respective normal ranges.

The upper level set by the US Food and Nutrition Board in 1997 was 1000 IU (25 μg)/d for infants and 2000 IU (50 μg)/d for all other ages based on a no-observed-adverse-effect level of 2400 IU (60 μg)/d for hypercalcaemia using evidence in the literature before 1997(26). The European Commission Scientific Committee on Food also identified an upper level of 2000 IU (50 μg)/d using a similar approach(26). The UK Expert Group on Vitamins and Minerals set an even lower upper level of 1000 IU (25 μg)/d(33). Upper levels curtail food fortification, vitamin supplement manufacturers, and policy makers, with legal consequences. Significant additional information has become available since the upper levels were set in 1997 in the USA, notably several dose–response studies. Using the risk assessment methodology for the current upper levels, but with new evidence, Hathcock et al. (Reference Hathcock, Shao and Vieth90) suggested that the upper level for adults could be increased to 10 000 IU (250 μg) vitamin D3/d. The trials used to propose this level lasted for weeks or months, but not years, and none was conducted in children. Lacking longer-term data and evidence in children creates some uncertainty when considering fortification policies that would affect all individuals.

Vitamin D requirements and safety levels are dependent upon Ca intakes(Reference Weaver91). For bone health, vitamin D input is more important during dietary Ca inadequacy. A recent meta-analysis concluded that vitamin D supplementation required additional Ca to be effective and reduce risk of hip fracture(Reference Boonen, Lips and Bouillon24). Risk of hypercalcaemia due to vitamin D excess is greater with high Ca intakes and may lead to increased risk of kidney stones(Reference Jackson, LaCroix and Gass22). However, throughout life vitamin D is still essential for bone health even when Ca intake is high.

Maximum levels for supplementation

A requisite for considering increases in levels of fortification of foods or for increases in public policy recommendations for vitamin D intakes is an increase in the upper levels. A vitamin D intake recommendation of 1000 IU (25 μg)/d has been recommended(Reference Bischoff-Ferrari, Orav and Dawson-Hughes78). In the USA, vitamin D fortification is optional in most cases for milk with 100 IU (2·5 μg) per cup (236·5 ml)(Reference Calvo, Whiting and Barton92). The American dietary guidelines suggest consuming three cups of milk daily. Such a diet would provide little more than 300 IU (7·5 μg)/d and the rest would need to come from supplements in the absence of sufficient sun exposure. In this example, that would mean approximately 700 IU (17·5 μg)/d, although some vitamin D would come from other fortified foods. In European countries, supplements would need to provide ≥ 850 IU (21·3 μg) vitamin D/d. Yet, the benefits of fortification of foods with vitamin D on health outcomes have not been appropriately evaluated in any country. Only small trials in subpopulations have shown the benefit of vitamin D-fortified milk on bone(Reference Chee, Suriah and Chan93, Reference Du, Zhu and Trube94).

Vitamin K

Rationale for role of vitamin K in bone health

The rationale for a role of vitamin K in bone health originated from the isolation of a vitamin K-dependent protein from bone called osteocalcin (or bone Gla protein) in 1975. This discovery followed the unravelling of the molecular role of vitamin K as an essential cofactor for a post-translational modification, whereby target peptide-bound glutamate (Glu) residues are converted to γ-carboxyglutamate (Gla) residues(Reference Shearer95). Osteocalcin is the most abundant non-collagenous protein of the bone extracellular matrix, and is synthesised by osteoblasts. The central portion of the molecule contains a highly conserved Gla domain that facilitates high-affinity binding to hydroxyapatite. The precise molecular role of osteocalcin is unclear, but it appears to act as a regulator of bone remodelling and mineralisation(Reference Boskey, Gadaleta and Gundberg96). Another bone Gla protein, matrix Gla protein (MGP), is a powerful inhibitor of calcification of cartilage. The essential role of MGP in human bone development is demonstrated by the heterogeneous embryopathy, chondrodysplasia punctata, which is characterised by pathological skeletal calcification, including that of the growth plate(Reference Shearer97). The anticalcification activity of MGP depends on the integrity of its five Gla residues, and chondrodysplasia punctata has been shown to be caused by maternal warfarin use or vitamin K deficiency and by congenital MGP mutation(Reference Shearer97). Other Gla proteins present in bone are protein S and Gas6 and the recently discovered periostin(Reference Coutu, Wu and Monette98). Besides its central role in coagulation, protein S is synthesised by osteoblasts and hereditary protein S deficiency has been associated with osteopenia. Gas6 is known to participate in several cellular processes including bone differentiation and resorption. Periostin is secreted by bone marrow-derived mesenchymal stromal cells and, unusually for a Gla protein, contains four consensus γ-carboxylase recognition sites(Reference Coutu, Wu and Monette98). In vitro studies have shown that carboxylated periostin is localised to bone nodules formed by mesenchymal stromal cells, suggesting a role in extracellular matrix mineralisation(Reference Coutu, Wu and Monette98).

The presence of at least five Gla proteins in bone and cartilage, together with evidence of the essentiality of vitamin K-dependent modification for their function, present a powerful argument for the need for an optimal supply of vitamin K(Reference Shearer95, Reference Coutu, Wu and Monette98, Reference Berkner and Runge99). We already know that MGP plays an important role in early bone development and that a degree of undercarboxylation of osteocalcin is a common finding in many populations(Reference Vermeer, Shearer and Zittermann100), young and old. This suggests that an adequate vitamin K status may be necessary for bone health throughout life. This view is strengthened by recent evidence that periostin, the latest bone-associated Gla protein to be discovered, plays key roles in the processes of bone development and repair(Reference Coutu, Wu and Monette98).

Bone health and benefits

Nutritional properties

Vitamin K is the family name for several biologically active 2-methyl-1,4-naphthoquinones, which possess a variable isoprenoid side chain at the 3 position. Historically, they have been classified as the single plant member, phylloquinone (vitamin K1) with a phytyl side chain, and a series of bacterial menaquinones (vitamins K2) with multi-prenyl side chains. The latter are designated menaquinone-n (MK-n) according to the number (n) of prenyl units. The most common bacterial forms have long side chains, typically MK-7 to MK-9. MK-4 is not a common bacterial form, but can be synthesised in vivo from dietary phylloquinone. This seems to occur by complete side-chain removal to menadione with subsequent prenylation of this intermediate(Reference Thijssen, Vervoort and Schurgers101). Since both phylloquinone and MK-4 are substrates for γ-glutamylcarboxylase, this conversion points to a unique role for MK-4, independent of the recognised coenzyme function of vitamin K.

Different forms of vitamin K have different metabolic properties. For instance, MK-7, a constituent of the ancient Japanese food natto (fermented soyabean), has a longer half-life and greater efficacy for carboxylating osteocalcin than vitamin K1(Reference Schurgers, Teunissen and Hamulyak102). More work is needed to determine whether the in vivo synthesis of MK-4 means that this isoprenologue has unique actions intrinsic to the geranyl-geranyl side chain.

Intake from diet

The major form of vitamin K in most diets is phylloquinone from plant sources. FFQ-derived estimates of relative intakes of phylloquinone and MK in the Netherlands suggest that about 90 % of total vitamin K intakes are provided by phylloquinone, 7·5 % by MK-5 to MK-10, and 2·5 % by MK-4(Reference Schurgers, Geleijnse and Grobbee103). In Europe and the USA, at least half of total phylloquinone intakes come from vegetables and vegetable products, of which a quarter to a third comprises green leafy vegetables(Reference Booth and Suttie104Reference Thane, Bolton-Smith and Coward106). With the exception of animal livers, the most common dietary source of long-chain MK is fermented foods, such as cheeses and natto.

National surveys reveal considerable variations in phylloquinone intakes within the same population(Reference Booth and Suttie104Reference Thane, Bolton-Smith and Coward106). In two UK surveys of older (1994–5)(Reference Thane, Paul and Bates105) and younger individuals (2000–1)(Reference Thane, Bolton-Smith and Coward106) there was an approximate 10-fold difference between the lower 5th and the upper 95th, although the arithmetic means were similar at approximately 80 μg/d. Average intakes in the USA (using similar methodology) are comparable but with a trend to higher intakes in older adults(Reference Booth and Suttie104). The UK data also suggest a decline in intakes of phylloquinone in the adult population from 1986 to 2001(Reference Thane, Bolton-Smith and Coward106).

Necessity to supplement a normal diet

Current estimates of requirements are based on the coagulation function of vitamin K rather than on bone health considerations. The current UK ‘safe and adequate’ intake of 1 μg/kg body weight per d is based on limited dietary restriction studies of the intakes needed to maintain a satisfactory coagulation status and was set in 1991 before any information on dietary intakes was available. It is fortuitous that this adequate intake is virtually identical to average UK intakes(Reference Thane, Paul and Bates105, Reference Thane, Bolton-Smith and Coward106). The revised adequate intake set by the USA in 2001 on the basis of representative dietary intake data is 120 and 90 μg/d for men and women, respectively(107). While the US committee noted the interest in new indicators sensitive to vitamin K intake, such as undercarboxylated osteocalcin (GluOC), they did not use them to establish an estimated average requirement because of ‘uncertainty surrounding their true physiological significance and the lack of sufficient dose–response data’.

There is a wealth of evidence that a substantial proportion of individuals in the UK and USA fail to meet their national dietary guidelines intakes for vitamin K. In the UK over 50 % of both older(Reference Thane, Paul and Bates105) and younger adults(Reference Thane, Bolton-Smith and Coward106) had intakes below the recommended safe intake and this proportion rises to about 75 % if the benchmark for adequacy is taken as the US adequate intake values.

Population studies in different healthy groups have found that a low dietary consumption of vitamin K is associated with an increased fracture risk(Reference Feskanich, Weber and Willett108, Reference Booth, Tucker and Chen109) or a lower bone mass(Reference Booth, Broe and Gagnon110), and that an impaired vitamin K status is associated with low bone mass(Reference Booth, Broe and Peterson111) or increased bone turnover(Reference Kalkwarf, Khoury and Bean112). One caveat to these findings is that they are not consistent for the same outcome measures of fractures and BMD, or for age or sex. This may reflect a weak association between vitamin K intakes and bone health, or indicate that certain population groups are more vulnerable to vitamin K deficits than others. Another caveat is that low dietary intakes of phylloquinone could reflect a poor diet in general, and may merely reflect deficiencies of other nutrients important to bone health.

More convincing evidence has come from several epidemiological studies that have found that high circulating GluOC levels constitute an independent risk factor for bone fracture(Reference Szulc, Chapuy and Meunier113Reference Luukinen, Kakonen and Pettersson115) and low BMD(Reference Szulc, Arlot and Chapuy116, Reference Knapen, Nieuwenhuijzen Kruseman and Wouters117). The strength of these studies is that GluOC is an accepted functional marker of the vitamin K status of the bone matrix and that this association has been found in more than one country with different methodologies for measuring GluOC. This is coupled with the knowledge that increased carboxylation of osteocalcin is readily achievable by dietary supplementation with vitamin K.

Most of the vitamin K intervention studies published to date have been carried out in Japan with high pharmacological doses (generally 45 mg/d) of MK-4 (menatetrenone) as a potential anti-osteoporotic agent. These studies represent a medical intervention rather than nutritional supplementation in patients with pre-existing involutional or secondary osteoporosis or osteopenia. A recent meta-analysis of published, randomised controlled intervention trials with vitamin K suggested a strong association of menatetrenone supplementation with reduced fracture incidence, as well as an effect in reducing bone loss(Reference Cockayne, Adamson and Lanham-New118). This meta-analysis also included two positive Dutch trials using phylloquinone at doses of either 10 mg phylloquinone/d in endurance athletes or 1 mg/d in postmenopausal women. The latter 3-year intervention study did not have a vitamin K group alone, but compared a group taking combined vitamins K and D (with Ca and additional minerals) against a group receiving vitamin D with Ca and additional minerals and a group taking a placebo(Reference Braam, Knapen and Geusens119). Only participants taking combined 1 mg phylloquinone, 320 IU (8 μg) vitamin D and minerals showed a slowing of bone loss at the site of the femoral neck, but not at the lumbar spine.

There are two published randomised, controlled supplementation trials in healthy elderly subjects that have employed amounts of vitamin K that are potentially achievable from the diet(Reference Bolton-Smith, McMurdo and Paterson120, Reference Booth, Dallal and Shea121). The first was a 2-year trial carried out in healthy, older Scottish women(Reference Bolton-Smith, McMurdo and Paterson120) who were randomised to four groups to receive daily (i) placebo; (ii) 200 μg phylloquinone; (iii) 400 IU (10 μg) vitamin D3 plus 1 g Ca; or (iv) combined 200 μg phylloquinone and 400 IU (10 μg) vitamin D3 plus 1 g Ca. This study showed no significant intervention effect on bone loss between groups, but did show a significant increase in BMD and BMC in group (iv) at the site of the ultradistal radius, but not at other sites in the hip or radius(Reference Bolton-Smith, McMurdo and Paterson120). It is of interest that a meta-analysis of studies examining the effects of vitamin K antagonists also showed that the ultradistal site was the bone site that was most responsive to loss of bone after exposure to oral anticoagulants(Reference Caraballo, Gabriel and Castro122). This effect of vitamin K antagonists seems to mirror the findings of vitamin K supplementation in the Scottish women, albeit in reverse. Overall, the opposing effects of phylloquinone in this Scottish study and the effects of vitamin K antagonists on BMD were both modest. The second study was a 3-year, controlled trial in healthy elderly North American men and women(Reference Booth, Dallal and Shea121) randomised to two groups to receive daily either (i) 500 μg phylloquinone, 400 IU (10 μg) vitamin D3 plus 600 mg Ca or (ii) 400 (10 μg) vitamin D3 plus 600 mg Ca. This study showed no effect of the extra 500 μg phylloquinone (taken in addition to recommended amounts of Ca and vitamin D) on bone health as assessed by changes in BMD (femoral neck, spine, or total body) or biochemical markers of bone turnover(Reference Booth, Dallal and Shea121). There was no difference between the results in men and women.

Risks, nutritional interactions, and consequences on bone health

Concept of differential tissue requirements for vitamin K: mechanistic feasibility considerations

The ability to assess the degree of undercarboxylation of individual Gla proteins in the body has led to the concept of tissue-specific requirements for vitamin K with greater intakes being required to maintain the carboxylation of osteocalcin in bone compared with Gla coagulation proteins in the liver(Reference Vermeer, Shearer and Zittermann100). A key question is to find out whether the epidemiological associations shown for high circulating GluOC and fracture risk can be explained on a mechanistic basis. We are hampered in this regard by a lack of knowledge of the molecular function(s) of osteocalcin. For example, osteocalcin-knockout mice have an increased bone formation, and seemingly stronger bones(Reference Ducy, Desbois and Boyce123). However, new evidence suggests that osteocalcin is responsible for subtle changes in the mineralisation process and the maturation of bone mineral crystals that does not show up in most assessments of bone mineralisation(Reference Boskey, Gadaleta and Gundberg96). This might explain why some have postulated that vitamin K has a greater effect on bone quality than density, implying that BMD measurements alone may not reflect vitamin K's effects(Reference Liu and Peacock124). This view is supported by recent reports that vitamin K improves hip bone geometry and bone strength indices(Reference Kaptoge, Dalzell and Welch125, Reference Knapen, Schurgers and Vermeer126). If undercarboxylation of osteocalcin were very harmful, we might expect to see pronounced effects in patients on long-term warfarin therapy. In fact this is not the case, though a meta-analysis suggested an overall detrimental effect of warfarin on BMD(Reference Caraballo, Gabriel and Castro122).

Whether or not GluOC is detrimental to bone health, a substantial and sustained increase in the γ-carboxylation status of osteocalcin is readily achievable by dietary supplementation with nutritionally relevant amounts of phylloquinone. This was clearly seen in the Scottish(Reference Bolton-Smith, McMurdo and Paterson120) and American(Reference Booth, Dallal and Shea121) intervention studies in which daily supplementation with 200 and 500 μg phylloquinone respectively resulted in an approximate average 50 % reduction in the fraction of total osteocalcin that was undercarboxylated (%GluOC). The vitamin K2 member, MK-7, was shown to be more effective than phylloquinone in carboxylating osteocalcin when the same molar dose of 0·22 μmol/d (100 μg phylloquinone; 142 μg MK7) was given to healthy adults for 40 d(Reference Schurgers, Teunissen and Hamulyak102). Without a mechanistic explanation, however, we do not yet know what degree of osteocalcin carboxylation is optimal, particularly as the use of different methodologies for calculating %GluOC gives very different absolute values.

Nutritional interactions

There is some evidence that vitamin K may act in concert with vitamin D, Ca, and possibly other micronutrients to reduce bone loss. An enhanced effect of combined vitamins K and D was postulated in both the Dutch(Reference Braam, Knapen and Geusens119) and Scottish(Reference Bolton-Smith, McMurdo and Paterson120) supplementation studies with 1 mg and 200 μg phylloquinone/d, respectively, and has been suggested by the Japanese treatment of osteoporosis with a regimen of MK-4 combined with 1α-hydroxycholecalciferol. It is theoretically feasible that any synergy between vitamins D and K derives from separate effects exerted independently or alternatively from their concerted action on common proteins or pathways; for instance by enhancing the transcription (vitamin D) and post-translational modification (vitamin K) of osteocalcin. Previous epidemiological evidence that vitamin D might directly influence the γ-carboxylation of osteocalcin was not supported by the Scottish study(Reference Bolton-Smith, McMurdo and Paterson120).

Maximum levels for supplementation

Although not reflected by current European legislation, vitamin K has a very wide safety margin. This is best illustrated by the widespread use of 45 mg/d doses of MK-4 for the treatment of osteoporosis in Japan. For phylloquinone, regular doses of up to 10 mg/d are used to treat patients with potential malabsorption (for example, cystic fibrosis) or to reverse warfarin over-anticoagulation. In cases of poisoning with superwarfarin rodenticides, injections of 20–50 mg phylloquinone/d may be required over several weeks to stabilise coagulation. In many countries, including the USA, all newborn infants are administered phylloquinone for the prevention of vitamin K-deficiency bleeding.

A potential problem for introducing widespread vitamin K supplementation is the large number of individuals taking oral anticoagulants. The extent of the problem depends on the level of supplementation, but a detailed dose–response study suggested that food supplements providing 100 μg phylloquinone/d do not significantly interfere with oral anticoagulant therapy(Reference Schurgers, Shearer and Hamulyak127). A recent paper actually suggests that supplementation with regular daily vitamin K can have beneficial effects on the stability of anticoagulant therapy(Reference Sconce, Avery and Wynne128).

Strontium

Bone health and benefits

The possibility of a beneficial effect of stable Sr on bone and in the prevention of osteoporosis was first proposed in 1910 by Lehnerdt(Reference Lehnerdt129), who administered strontium phosphate to dogs. However, it was not until the 1950s that human evidence for the benefits of Sr on bone began to appear. First, moderate doses of strontium lactate were shown to improve the deposition of Ca in human bone(Reference Shorr and Carter130), and later a study in thirty-two patients receiving an oral dose of 1·7 g strontium lactate/d reported increased bone mass on X-ray in 78 % of cases(Reference McCaslin and Jane131). Several animal and cell-culture studies documented that Sr, particular strontium ranelate, can exert a positive effect on bone formation, while inhibiting bone resorption(Reference Grynpas, Hamilton and Cheung132Reference Skoryna, Fuskova and Skoryna136). Strontium ranelate was demonstrated to have both anti-resorptive and bone-forming activity, and was predicted to be of benefit in the treatment of bone diseases(Reference Marie, Ammann and Boivin137). The therapeutic benefits of oral administration of 2 g strontium ranelate/d in postmenopausal osteoporosis were confirmed in 2004 when a large placebo-controlled clinical trial in 1649 women reported early (after 1 year) and sustained (over 3 years) significant reduction in the risk of vertebral fracture(Reference Meunier, Roux and Seeman138). Strontium ranelate's anti-fracture efficacy was shown to extend to non-vertebral fracture in 2005, following publication of the results of a placebo-controlled study including 5091 women with postmenopausal osteoporosis(Reference Reginster, Seeman and De Vernejoul139). Treatment with 2 g strontium ranelate/d significantly reduced the risk of non-vertebral and hip fracture over 3 years(Reference Reginster, Seeman and De Vernejoul139). The vertebral, non-vertebral, and hip anti-fracture efficacy has recently been confirmed over 5 years(Reference Reginster, Felsenberg and Boonen140). The efficacy of Sr in the primary and secondary prevention of osteoporosis fracture was obtained with quantities of up to 680 mg/d corresponding to 2 g strontium ranelate/d, and a daily intake of 0·13 mmol Sr/kg per d. All the reliable human data on Sr were conducted with strontium ranelate under medical supervision in a specific population with postmenopausal osteoporosis(Reference Meunier, Roux and Seeman138Reference Nakamura141). This agent is now recognised as a drug treatment for osteoporosis in Europe.

The question of bioequivalence of the various Sr salts remains unclear. Bioavailability in animal experiments appears to vary from 5 to 25 % of the ingested dose under normal physiological conditions(Reference Venugopal and Luckey142), but comparative human absorption data are incomplete and the relative beneficial effects on bone unknown. The potential bone benefits for the general population of oral supplementation with Sr have not been assessed. It is unclear whether the benefits of strontium ranelate extend to other salts. Further evaluations including broader populations and other salts of Sr are necessary.

Intake from diet

The average intake of Sr in a normal diet is generally accepted to be between 1 and 2 mg/d in Western populations(Reference Pennington and Jones143). Consumption of vegetables grown in Sr-rich soils may increase intake(Reference Ozgur, Sumer and Kocoglu144). Sr concentrations in drinking water may vary from one geographic region to another, but are generally agreed to lead to an intake between 2 and 4 mg/d, considering that humans should drink about 2 litres/d(145). Although Sr is found in practically all foods, the concentrations remain very low. The highest concentrations are found in fish, seafood, nuts and leafy vegetables(Reference Pennington and Jones143, 146). Other vegetables, cereals and fruit also contain significant amounts of Sr, while meat and eggs have very low concentrations(Reference Varo, Saari and Paaso147).

Necessity to supplement a normal diet

Sr does not have any recognised biological role essential to health(148). No requirement for dietary supplementation with Sr has been established to date. None of the national and international organisations mentions Sr as an essential nutrient or as part of a nutritional strategy to improve bone health(2). No RDI has been established because the decision to supplement a normal diet must be made on the basis of observed deficiencies in humans and no such cases have been identified for Sr. The logical conclusion is that there is no need for supplementation in the general population, even for prevention of fracture in postmenopausal osteoporotic women for whom the strontium ranelate salt is currently used as a treatment.

Risks, nutritional interactions, and consequences on bone health

Although Sr is not toxic to humans, a number of animal studies have demonstrated the detrimental consequences of high doses of Sr (>4 mmol Sr/kg per d)(Reference Martin149). Such doses of Sr were shown to induce skeletal abnormalities(Reference Lehnerdt129, Reference Kshirsagar150). Most of these interactions concern Ca competition at the bone(Reference El Solh, Rousselet and Skoryna151) or intestinal level(Reference Morohashi, Sano and Yamada152); these interactions could induce hypocalcaemia(Reference Morohashi, Sano and Yamada152). At elevated levels, Sr replaces Ca in bone and can lead to the inhibition of calcification of epiphyseal cartilage and long-bone deformities in growing rats(Reference El Solh, Rousselet and Skoryna151, Reference Storey153). Oral administration of excess Sr in rats inhibited the increase in Ca intestinal absorption normally stimulated by vitamin D(Reference Rousselet, El Solh and Maurat154). The carbonate, gluconate and chloride salts of Sr have also been reported to inhibit vitamin D activity in rats(Reference Skoryna, Fuskova and Skoryna136), leading to bone malformation, while Sr ions have been reported to produce rickets in rats by inhibiting the renal production of vitamin D(Reference Svensson, Reinholt and Engfeldt155).

In humans, the induction of ‘Sr rickets’ has been observed in children ingesting a low-vitamin D diet for 11 months living in two different regions of Turkey with different soil concentrations of Sr(Reference Ozgur, Sumer and Kocoglu144). The proportion of children with rickets was significantly higher in the region with Sr-rich soil than in the region with Sr-poor soil(Reference Ozgur, Sumer and Kocoglu144). This indicates the possible importance of the effect of environmental Sr on bone health, and illustrates how some populations could be at high risk if Sr supplementation were implemented.

Interactions of Sr ions with lactose may increase the absorption of Sr(Reference Marcus and Wasserman156). It has been suggested that this may present a risk in overdose(Reference Kshirsagar150) since lactose decreases the discrimination of Sr and Ca during intestinal absorption, particularly in children(Reference Kshirsagar150, Reference Storey153, Reference Storey157). The vulnerability of children is reinforced by the fact that the body burden of young children is greater than in adults and so the bone consequences of Sr overdose would be more severe(148). Raised levels of Sr have been shown to have adverse effects in the bone of offspring of pregnant or lactating animals(Reference Browning158, Reference Sugihira and Suzuki159), suggesting that Sr should not be supplemented in pregnant or lactating women. In the presence of impaired kidney function Sr supplementation should also be avoided, since it could lead to osteomalacia as documented in a rat model of chronic renal failure(Reference Schrooten, Cabrera and Goodman160).

Although the detrimental effects of Sr only appear at elevated levels, some populations may be at risk if they ingested supplementary Sr without proper medical supervision. Nevertheless, perusal of the literature reveals how little is really known about Sr and its toxicity, and the studies on the element are not always reliable(148). Apart from the studies into the therapeutic applications of strontium ranelate(Reference Meunier, Roux and Seeman138, Reference Reginster, Seeman and De Vernejoul139), there are no studies investigating the safety of long-term oral exposure to other stable Sr salts in humans.

Magnesium

Mg is a nutritional bone component that has been poorly studied for its role in bone health. Because bone undergoes continuous remodelling, an adequate supply of Mg, as well as other nutrients important to bone, is needed to support bone formation. As with Ca, there is a potential risk of dietary deficiency for Mg. Studies have shown that Mg deficiency could affect bone growth and osteoblastic and osteoclastic activity, induce osteopenia and bone fragility, and alter Ca metabolism by affecting calciotropic hormones(Reference Fatemi, Ryzen and Flores161). Note that there are no reliable biomarkers of Mg status or function. RDI have been set on average intakes or balance estimates that may not, therefore, reflect biological requirements.

Bone health and benefits

Nutritional properties

Approximately 60 % of the Mg in the body is in bone. Mg influences mineral metabolism indirectly through its role in ATP metabolism and as a cofactor for over 300 proteins, the calciotropic hormones and 1,25(OH)2D. Mg also influences bone health by direct effects on bone quality, decreasing hydroxyapatite crystal size, thereby preventing the larger, more perfect mineral crystals that could lead to brittle bone. Further, Mg also can indirectly influence bone by acting as a buffer for the acid produced by the typical Western diet, since Mg is found in green, leafy vegetables, legumes and whole-grain products, nuts, seeds, fish and hard water. Recent studies have found a positive association between fruit and vegetable consumption and bone health(Reference Tucker, Hannan and Chen162Reference Macdonald, New and Fraser165).

The scant clinical data available would support a bone health benefit with dietary Mg. Small epidemiological studies have found positive associations between Mg intake and BMD. Preadolescent Mg intake is positively related with bone mass in young women(Reference Wang, Moore and Crawford166). High Mg intakes have been associated with higher BMC in Australian women(Reference Angus, Sambrook and Pocock167), higher BMD at different sites in Scottish menopausal women(Reference New, Robins and Campbell163, Reference New, Bolton-Smith and Grubb168), Italian and American white postmenopausal women(Reference Ilich, Brownbill and Tamborini169, Reference Tranquilli, Lucino and Garzetti170), and elderly American white men and women(Reference Tucker, Hannan and Chen162, Reference Ryder, Shorr and Bush171). In addition, higher Mg intakes have been found to be linked with lower bone resorption markers in Scottish women(Reference New, Robins and Campbell163, Reference New, Bolton-Smith and Grubb168).

Clinical studies with Mg supplementation have also found a positive impact on bone. Supplementation with 300 mg Mg/d for 1 year (total Mg intake including diet, 484 mg/d) significantly increased hip BMC in white adolescent girls(Reference Carpenter, DeLucia and Zhang172). Supplementation with 600 mg Mg/d (plus 500 mg Ca/d) for 0·5 to 1 year resulted in mean increases of 11 % in BMD in postmenopausal women, which persisted at 2 years' follow-up(Reference Abraham and Grewal173). Mg supplementation with 250 to 750 mg/d (total Mg intake, 450–1050 mg/d) for 1·5 years resulted in gains in BMD in most postmenopausal women, with no reported side effects(Reference Stendig-Lindberg, Tepper and Leichter174). In addition, Mg supplementation of 365 mg/d for 30 d (total Mg intake, 665 mg/d) reduced bone turnover in young men(Reference Dimai, Porta and Wirnsberger175).

Intake from diet

American RDI for Mg were increased in 1997 to 310 and 400 mg/d in younger (aged 19–30 years) female and male adults, respectively, and to 320 and 420 mg/d in female and male adults aged over 30 years(26). The European Union population reference intake for adults is 150 to 500 mg Mg/d, and the European Commission RDI is 300 mg/d(Reference Flynn, Moreiras and Stehle176).

The primary source of Mg is food, but consumption from supplements is increasing due to the addition of Mg to many commercially available products. Population studies in the USA report low Mg intakes of 326 and 237 mg/d in white men and women, respectively(Reference Ford and Mokdad177). In Europe, most countries report an intake >300 mg/d in men, except in Italy, which is below this level(Reference Elmadfa, Weichselbaum and König178). In women, Mg intake is about 300 mg/d, except in Italy, France and Spain; in the elderly, intake is below this level in most countries. In contrast, Mg intake is high in Germany, Denmark and Hungary (about 416 mg/d).

Uncertainty regarding the necessity to supplement a normal diet for bone health

According to the US RDI, Mg intake would be suboptimal in most individuals, specifically women from the southern European countries and the elderly. This is due to an increased consumption of overly refined and/or processed cereal-crop and carbohydrate food staples, which removes most of the Mg.

On the basis of these observations, one may infer that diets should be supplemented with Mg. However, a recent French study reported that recommending Mg supplements would only increase Mg intake by 10 %(Reference Touvier, Boutron-Ruault and Volatier179). Therefore, supplementing food with Mg would appear to be a better strategy to increase Mg intake to RDI levels in countries with relatively low spontaneous intake. Whether such a food fortification with Mg would improve bone health is not established.

Risk, nutritional interactions, and consequences on bone health

Mg excess from a normal diet is rare. Studies of vegetarians in Sweden and the USA report high Mg intake (440–615 mg/d), with no associated health risks(Reference Abdulla, Andersson and Asp180, Reference Haddad, Berk and Kettering181). Mg in excess or deficit in rats (levels much below or above 0·25 % dietary Mg) resulted in bone of abnormal appearance and chemical composition(Reference Clark and Belanger182). Mild diarrhoea is the most undesirable effect of orally administered easily dissociable Mg salts. No laxative effects have been observed for Mg in adult men and women, even during pregnancy and lactation, or in children aged over 4 years, at doses up to 250 mg/d, which is considered as the no-observed-adverse-effect level. No other adverse health effects have been reported with Mg supplementation, even at levels as high as 1000 mg/d.

As shown in human studies, there are significant interactions between Mg and the intestinal absorption of Fe and Zn, probably owing to the inhibition of gastric acid by Mg(Reference Thurnher and Kresbach183Reference Sturniolo, Montino and Rossetto185). Interactions with drugs such as tetracyclin, penicillin and digoxin have also been reported(Reference Griffin and D'Arcy186). It has been suggested that high-Ca diets could intensify Mg deficiency; but short- and long-term studies of Mg balance do not support this notion(Reference Andon, Ilich and Tzagournis187Reference Sojka, Wastney and Abrams189).

Maximum levels for supplementation

Assuming that future research will firmly establish the need for dietary Mg enhancement for bone health, various amounts have already been proposed. Former reports recommended Mg supplementation as high as 600 mg/d for the elderly, regardless of Mg status(Reference Abraham and Grewal173, Reference Stendig-Lindberg, Tepper and Leichter174). A safe model for Mg addition to foods has been developed in Europe, which proposes a maximum level of 240 mg/d to be added to foods(Reference Flynn, Moreiras and Stehle176). If 10 % of all fortifiable foods were fortified with Mg, 10 mg added to 100 kcal (418·4 kJ) of food portion will provide 200 mg Mg/d in a 2000 kcal (8368 kJ) diet. This would increase usual dietary Mg intake from 200–300 mg/d to 400–500 mg/d, in women and in the elderly, and to >500 mg/d in men.

Conclusion

Although the value of supplementary Ca and vitamin D in bone health is well established, there is a distinct lack of consensus regarding the other vitamins and minerals implicated in bone health. Ca and vitamin D supplementation is recommended in postmenopausal women and the elderly, and in cases of osteoporosis. However, Ca supplementation is recommended to the extent that the diet is poor in milk and dairy products. The benefits of such a programme of supplementation is supported by the results of randomised controlled trials. Vitamin D is available in the diet from some foods, but most comes from cutaneous synthesis and serum levels may vary according to individual exposure to sunlight. Current guidelines on vitamin D supplementation may not have taken into account recent evidence, and underestimate desirable intakes and maximal levels. Although P is essential to bone health, supplementation is not recommended since Western diets are almost systematically overgenerous in terms of P content due to the high natural content of most common foodstuffs and its widespread use as an additive in food technology. Vitamin K appears to enhance the actions of Ca and vitamin D, and may be important to bone health. However, there is no agreement on maximal tolerated levels, especially in individuals taking oral anticoagulants; whether the general population would benefit from vitamin K supplementation for bone health remains unclear. As regards Sr, in contrast to the other minerals and vitamins, there is no published nutritional requirement, no upper level has been defined, and there is no established lower serum concentration at which pathological symptoms appear. One Sr salt, strontium ranelate, is currently authorised for the treatment for postmenopausal osteoporosis, but there is no evidence that Sr supplementation would be beneficial to bone health in the general population. Mg is essential for skeletal health. Nevertheless, it is not firmly established that there would be a risk in the general population of dietary Mg deficiency leading to increased bone fragility. Therefore, despite the fact that in the Western diet Mg is generally lower than recommended intakes, current evidence is not strong enough to promote enhancement of this element via fortification of foodstuffs.

Acknowledgements

All authors contributed equally to the present study, with more specific responsibility for a given section: L. G. for Ca and P; C. M. W. for vitamin D; M. J. S. for vitamin K; J.-P. B. for Sr; C. P. for Mg. J.-P. B. was responsible for the editing of all sections for both scientific content and formal presentation.

This paper was initially prepared with editorial assistance and coordination from Alcimed, France, and an unrestricted educational grant from Servier.

All authors have read and approved all sections of the manuscript, and participated in the decision to submit for publication.

No other potential conflicts of interest have been reported.

References

1World Health Organization (2003) Diet, Nutrition and the Prevention of Chronic Diseases. Joint WHO/FAO Expert Consultation. WHO Technical Report Series no. 916. Geneva: WHO.Google Scholar
2International Osteoporosis Foundation (on Behalf of the European Parliament Osteoporosis Interest Group and EU Osteoporosis Consultation Panel) (2005) Osteoporosis in Europe: Indicators in Progress. Nyon, Switzerland: IOF.Google Scholar
3Kanis, JA & Johnell, O (2005) Requirements for DXA for the management of osteoporosis in Europe. Osteoporos Int 16, 229238.CrossRefGoogle ScholarPubMed
4World Health Organization (2007) Assessment of Osteoporosis at the Primary Health Care Level. Report of a WHO Scientific Group. Geneva: WHO.Google Scholar
5World Health Organization (1994) Assessment of Fracture Risk and its Application to Screening for Postmenopausal Osteoporosis. Report of a WHO Study Group. WHO Technical Report Series no. 843. Geneva: WHO.Google Scholar
6Melton, LJ III, Gabriel, SE, Crowson, CS, et al. (2003) Cost-equivalence of different osteoporotic fractures. Osteoporos Int 14, 383388.CrossRefGoogle ScholarPubMed
7World Health Organization (2003) Prevention and Management of Osteoporosis. Report of a Scientific Group. WHO Technical Report Series no. 921. Geneva: WHO.Google Scholar
8Barrett-Connor, E, Siris, ES, Wehren, LE, et al. (2005) Osteoporosis and fracture risk in women of different ethnic groups. J Bone Miner Res 20, 185194.CrossRefGoogle ScholarPubMed
9Nevitt, MC, Cummings, SR, Stone, KL, et al. (2005) Risk factors for a first-incident radiographic vertebral fracture in women > or = 65 years of age: the study of osteoporotic fractures. J Bone Miner Res 20, 131140.Google ScholarPubMed
10Nguyen, TV, Kelly, PJ, Sambrook, PN, et al. (1994) Lifestyle factors and bone density in the elderly: implications for osteoporosis prevention. J Bone Miner Res 9, 13391346.CrossRefGoogle ScholarPubMed
11Law, MR & Hackshaw, AK (1997) A meta-analysis of cigarette smoking, bone mineral density and risk of hip fracture: recognition of a major effect. BMJ 315, 841846.CrossRefGoogle ScholarPubMed
12Prentice, A, Schoenmakers, I, Laskey, MA, et al. (2006) Nutrition and bone growth and development. Proc Nutr Soc 65, 348360.CrossRefGoogle ScholarPubMed
13Favus, MJ (2006) Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 6th ed.Washington, DC: The American Society for Bone and Mineral Research.Google Scholar
14Riaz, S, Alam, M & Umer, M (2006) Frequency of osteomalacia in elderly patients with hip fractures. J Pak Med Assoc 56, 273276.Google ScholarPubMed
15Huang, Z, Himes, JH & McGovern, PG (1996) Nutrition and subsequent hip fracture risk among a national cohort of white women. Am J Epidemiol 144, 124134.CrossRefGoogle ScholarPubMed
16Bonjour, JP, Chevalley, T, Rizzoli, R, et al. (2007) Gene–environment interactions in the skeletal response to nutrition and exercise during growth. Med Sport Sci 51, 6480.CrossRefGoogle ScholarPubMed
17Barr, SI (2006) Introduction to dietary reference intakes. Appl Physiol Nutr Metab 31, 6165.CrossRefGoogle ScholarPubMed
18North American Menopause Society (2006) The role of calcium in peri- and postmenopausal women: 2006 position statement of the North American Menopause Society. Menopause 13, 862877.CrossRefGoogle Scholar
19Chapuy, MC, Arlot, ME, Duboeuf, F, et al. (1992) Vitamin D3 and calcium to prevent hip fractures in the elderly women. N Engl J Med 327, 16371642.CrossRefGoogle ScholarPubMed
20Dawson-Hughes, B, Harris, SS, Krall, EA, et al. (1997) Effect of calcium and vitamin D supplementation on bone density in men and women 65 years of age or older. N Engl J Med 337, 670676.CrossRefGoogle ScholarPubMed
21Prince, RL, Devine, A, Dhaliwal, SS, et al. (2006) Effects of calcium supplementation on clinical fracture and bone structure: results of a 5-year, double-blind, placebo-controlled trial in elderly women. Arch Intern Med 166, 869875.CrossRefGoogle ScholarPubMed
22Jackson, RD, LaCroix, AZ, Gass, M, et al. (2006) Calcium plus vitamin D supplementation and the risk of fractures. N Engl J Med 354, 669683.CrossRefGoogle ScholarPubMed
23Grant, AM, Avenell, A, Campbell, MK, et al. (2005) Oral vitamin D3 and calcium for secondary prevention of low-trauma fractures in elderly people (Randomised Evaluation of Calcium Or vitamin D, RECORD): a randomised placebo-controlled trial. Lancet 365, 16211628.Google ScholarPubMed
24Boonen, S, Lips, P, Bouillon, R, et al. (2007) Need for additional calcium to reduce the risk of hip fracture with vitamin D supplementation: evidence from a comparative metaanalysis of randomized controlled trials. J Clin Endocrinol Metab 92, 14151423.CrossRefGoogle ScholarPubMed
25Tang, BM, Eslick, GD, Nowson, C, et al. (2007) Use of calcium or calcium in combination with vitamin D supplementation to prevent fractures and bone loss in people aged 50 years and older: a meta-analysis. Lancet 370, 657666.CrossRefGoogle ScholarPubMed
26Institute of Medicine Food and Nutrition Board (1997) Dietary Reference Intakes for Calcium, Phosphorus, Magnesium, Vitamin D and Fluoride. Washington, DC: National Academy Press.Google Scholar
27Commitee on Medical Aspects of Food and Nutrition Policy (COMA) (1998) Nutrition and Bone Health: with Particular Reference to Calcium and Vitamin D. London: The Stationery Office.Google Scholar
28Guéguen, L (2001) Calcium, phosphore (Calcium, phosphorus). In Apports Nutritionnels Conseillés pour la Population Française (Recommended Nutritional Intakes for the French Population), pp. 131146 [Martin, A, editor]. Paris: Tech & Doc.Google Scholar
29Pointillart, A & Guéguen, L (2006) Le lait est-il indispensable pour satisfaire les ANC en calcium? (Is milk essential to satisfy the ANC for calcium?). Sci Aliments 26, 509515.CrossRefGoogle Scholar
30Miller, DD (1989) Calcium in the diet: food sources, recommended intakes, and nutritional bioavailability. Adv Food Nutr Res 33, 103156.CrossRefGoogle ScholarPubMed
31Scientific Committee on Food of the European Commission (2003) Opinion of the Scientific Committee on Food on the tolerable upper intake level of calcium. Tolerable upper intake levels for vitamins and minerals. http://www.efsa.europa.eu (accessed 20 September 2007).Google Scholar
32Whiting, SJ & Wood, RJ (1997) Adverse effects of high-calcium diets in humans. Nutr Rev 55, 19.CrossRefGoogle ScholarPubMed
33Expert Group on Vitamins and Minerals (2003) Safe Upper Levels for Vitamins and Minerals. London: Food Standards Agency.Google Scholar
34Food Standards Agency UK (2007) Vitamins and minerals in food supplements and fortified foods. Update on stakeholder engagement on the EC discussion document. Agenda Item 3.1. 13 July 2006. http://www.foodstandards.gov.uk (accessed 20 September 2007).Google Scholar
35Heaney, RP, Recker, RR & Weaver, CM (1990) Absorbability of calcium sources: the limited role of solubility. Calcif Tissue Int 46, 300304.CrossRefGoogle ScholarPubMed
36Allen, LH (1982) Calcium bioavailability and absorption: a review. Am J Clin Nutr 35, 783808.CrossRefGoogle ScholarPubMed
37Recker, RR, Bammi, A, Barger-Lux, MJ, et al. (1988) Calcium absorbability from milk products, an imitation milk, and calcium carbonate. Am J Clin Nutr 47, 9395.CrossRefGoogle ScholarPubMed
38Ekman, M, Reizenstein, P, Teigen, SW, et al. (1991) Comparative absorption of calcium from carbonate tablets, lactogluconate/carbonate effervescent tablet, and chloride solution. Bone 12, 9397.CrossRefGoogle ScholarPubMed
39Hansen, C, Werner, E, Erbes, HJ, et al. (1996) Intestinal calcium absorption from different calcium preparations: influence of anion and solubility. Osteoporos Int 6, 386393.CrossRefGoogle ScholarPubMed
40Mortensen, L & Charles, P (1996) Bioavailability of calcium supplements and the effect of vitamin D: comparisons between milk, calcium carbonate, and calcium carbonate plus vitamin D. Am J Clin Nutr 63, 354357.CrossRefGoogle ScholarPubMed
41Guéguen, L & Pointillart, A (2000) The bioavailability of dietary calcium. J Am Coll Nutr 19, 119S136S.CrossRefGoogle ScholarPubMed
42Zhao, Y, Martin, BR & Weaver, CM (2005) Calcium bioavailability of calcium carbonate fortified soymilk is equivalent to cow's milk in young women. J Nutr 135, 23792382.CrossRefGoogle ScholarPubMed
43European Parliament and the Council of the European Union (2002) Directive 2002/46/EC on the approximation of the laws of the member states relating to food supplementation. http://eurlex.europa.eu (accessed 28 March 2007).Google Scholar
44Smith, KT, Heaney, RP, Flora, L, et al. (1987) Calcium absorption from a new calcium delivery system (CCM). Calcif Tissue Int 41, 351352.CrossRefGoogle ScholarPubMed
45Martin, BR, Weaver, CM, Heaney, RP, et al. (2002) Calcium absorption from three salts and CaSO(4)-fortified bread in premenopausal women. J Agric Food Chem 50, 38743876.CrossRefGoogle ScholarPubMed
46Brandolini, M, Guéguen, L, Boirie, Y, et al. (2005) Higher calcium urinary loss induced by a calcium sulphate-rich mineral water intake than by milk in young women. Br J Nutr 93, 225231.CrossRefGoogle ScholarPubMed
47Florin, THJ, Neale, G, Goretski, S, et al. (1993) The sulphate content of foods and beverages. J Food Composition Anal 6, 140151.CrossRefGoogle Scholar
48European Food Safety Authority (2004) Opinion of the AFC panel related to calcium sulphate as a mineral substance in food intended for the general population. Question EFSA-Q-2003-237. http://www.efsa.europa.eu (accessed 28 March 2007).Google Scholar
49Calvo, MS & Park, YK (1996) Changing phosphorus content of the U.S. diet: potential for adverse effects on bone. J Nutr 126, 1168S1180S.CrossRefGoogle ScholarPubMed
50Calvo, MS, Kumar, R & Heath, H (1990) Persistently elevated parathyroid hormone secretion and action in young women after four weeks of ingesting high phosphorus, low calcium diets. J Clin Endocrinol Metab 70, 13341340.CrossRefGoogle ScholarPubMed
51Brixen, K, Nielsen, HK, Charles, P, et al. (1992) Effects of a short course of oral phosphate treatment on serum parathyroid hormone(1-84) and biochemical markers of bone turnover: a dose–response study. Calcif Tissue Int 51, 276281.CrossRefGoogle Scholar
52Calvo, MS, Whiting, SJ & Barton, CN (2005) Vitamin D intake: a global perspective of current status. J Nutr 135, 310316.CrossRefGoogle ScholarPubMed
53Heaney, RP & Recker, RR (1987) Calcium supplements: anion effects. Bone Miner 2, 433439.Google ScholarPubMed
54Bizik, BK, Ding, W & Cerklewski, FL (1996) Evidence that bone resorption of young men is not increased by high dietary phosphorus obtained from milk and cheese. Nutr Res 16, 11431146.CrossRefGoogle Scholar
55Karkkainen, M & Lamberg-Allardt, C (1996) An acute intake of phosphate increases parathyroid hormone secretion and inhibits bone formation in young women. J Bone Miner Res 11, 19051912.CrossRefGoogle ScholarPubMed
56European Food Safety Authority (2005) Opinion of the Scientific Panel on Dietary Products, Nutrition, and Allergies on a request of the Commission related to the Tolerable Upper Intake Levels of Phosphorus. http://www.efsa.europa.eu (accessed 20 September 2007).Google Scholar
57Whybro, A, Jagger, H, Barker, M, et al. (1998) Phosphate supplementation in young men: lack of effect on calcium homeostasis and bone turnover. Eur J Clin Nutr 52, 2933.CrossRefGoogle ScholarPubMed
58Grimm, M, Muller, A, Hein, G, et al. (2001) High phosphorus intake only slightly affects serum minerals, urinary pyridinium crosslinks and renal function in young women. Eur J Clin Nutr 55, 153161.CrossRefGoogle ScholarPubMed
59Dhingra, R, Sullivan, LM, Fox, CS, et al. (2007) Relations of serum phosphorus and calcium levels to the incidence of cardiovascular disease in the community. Arch Intern Med 167, 879885.CrossRefGoogle Scholar
60Heaney, RP & Weaver, CM (2003) Calcium and vitamin D. Endocrinol Metab Clin North Am 32, 181194, vii–viii.CrossRefGoogle ScholarPubMed
61Barger-Lux, MJ, Heaney, RP, Lanspa, SJ, et al. (1995) An investigation of sources of variation in calcium absorption efficiency. J Clin Endocrinol Metab 80, 406411.Google ScholarPubMed
62Devine, A, Wilson, SG, Dick, IM, et al. (2002) Effects of vitamin D metabolites on intestinal calcium absorption and bone turnover in elderly women. Am J Clin Nutr 75, 283288.CrossRefGoogle ScholarPubMed
63Heaney, RP (2004) Functional indices of vitamin D status and ramifications of vitamin D deficiency. Am J Clin Nutr 80, 1706S1709S.CrossRefGoogle ScholarPubMed
64Abrams, SA, Griffin, IJ, Hawthorne, KM, et al. (2005) Relationships among vitamin D levels, parathyroid hormone, and calcium absorption in young adolescents. J Clin Endocrinol Metab 90, 55765581.CrossRefGoogle ScholarPubMed
65Thomas, MK, Lloyd-Jones, DM, Thadhani, RI, et al. (1998) Hypovitaminosis D in medical inpatients. N Engl J Med 338, 777783.CrossRefGoogle ScholarPubMed
66Guillemant, J, Taupin, P, Le, HT, et al. (1999) Vitamin D status during puberty in French healthy male adolescents. Osteoporos Int 10, 222225.CrossRefGoogle ScholarPubMed
67Gordon, CM, DePeter, KC, Feldman, HA, et al. (2004) Prevalence of vitamin D deficiency among healthy adolescents. Arch Pediatr Adolesc Med 158, 531537.CrossRefGoogle ScholarPubMed
68Lehtonen-Veromaa, MK, Mottonen, TT, Nuotio, IO, et al. (2002) Vitamin D and attainment of peak bone mass among peripubertal Finnish girls: a 3-y prospective study. Am J Clin Nutr 76, 14461453.CrossRefGoogle ScholarPubMed
69Cheng, S, Tylavsky, F, Kroger, H, et al. (2003) Association of low 25-hydroxyvitamin D concentrations with elevated parathyroid hormone concentrations and low cortical bone density in early pubertal and prepubertal Finnish girls. Am J Clin Nutr 78, 485492.CrossRefGoogle ScholarPubMed
70El-Hajj Fuleihan, G, Nabulsi, M, Tamim, H, et al. (2006) Effect of vitamin D replacement on musculoskeletal parameters in school children: a randomized controlled trial. J Clin Endocrinol Metab 91, 405412.CrossRefGoogle ScholarPubMed
71Viljakainen, HT, Natri, AM, Karkkainen, M, et al. (2006) 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 21, 836844.CrossRefGoogle ScholarPubMed
72Andersen, R, Molgaard, C, Skovgaard, LT, et al. (2008) 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 100, 197207.CrossRefGoogle Scholar
73Bischoff-Ferrari, HA, Dietrich, T, Orav, EJ, et al. (2004) Positive association between 25-hydroxy vitamin D levels and bone mineral density: a population-based study of younger and older adults. Am J Med 116, 634639.CrossRefGoogle ScholarPubMed
74Bischoff-Ferrari, HA, Willett, WC, Wong, JB, et al. (2005) Fracture prevention with vitamin D supplementation: a meta-analysis of randomized controlled trials. JAMA 293, 22572264.CrossRefGoogle ScholarPubMed
75Porthouse, J, Cockayne, S, King, C, et al. (2005) Randomised controlled trial of calcium and supplementation with cholecalciferol (vitamin D3) for prevention of fractures in primary care. BMJ 330, 1003.CrossRefGoogle ScholarPubMed
76Avenell, A, Gillespie, WJ & Gillespie, LD, et al. (2005) Vitamin D and vitamin D analogues for preventing fractures associated with involutional and post-menopausal osteoporosis. The Cochrane Database of Systematic Reviews, issue 3, CD000227. http://www.mrw.interscience.wiley.com/cochrane/clsysrev/articles/CD000227/frame.html.CrossRefGoogle Scholar
77Bischoff-Ferrari, HA, Dawson-Hughes, B, Willett, WC, et al. (2004) Effect of vitamin D on falls: a meta-analysis. JAMA 291, 19992006.CrossRefGoogle ScholarPubMed
78Bischoff-Ferrari, HA, Orav, EJ & Dawson-Hughes, B (2006) Effect of cholecalciferol plus calcium on falling in ambulatory older men and women: a 3-year randomized controlled trial. Arch Intern Med 166, 424430.Google ScholarPubMed
79Boland, R (1986) Role of vitamin D in skeletal muscle function. Endocr Rev 7, 434448.CrossRefGoogle ScholarPubMed
80Visser, M, Deeg, DJ & Lips, P (2003) Low vitamin D and high parathyroid hormone levels as determinants of loss of muscle strength and muscle mass (sarcopenia): the Longitudinal Aging Study Amsterdam. J Clin Endocrinol Metab 88, 57665772.CrossRefGoogle ScholarPubMed
81Bischoff, HA, Borchers, M, Gudat, F, et al. (2001) In situ detection of 1,25-dihydroxyvitamin D3 receptor in human skeletal muscle tissue. Histochem J 33, 1924.CrossRefGoogle ScholarPubMed
82Zehnder, D, Bland, R, Williams, MC, et al. (2001) Extrarenal expression of 25-hydroxyvitamin D(3)-1 α-hydroxylase. J Clin Endocrinol Metab 86, 888894.Google ScholarPubMed
83Moore, C, Murphy, MM, Keast, DR, et al. (2004) Vitamin D intake in the United States. J Am Diet Assoc 104, 980983.CrossRefGoogle ScholarPubMed
84Weaver, CM & Fleet, JC (2004) Vitamin D requirements: current and future. Am J Clin Nutr 80, 1735S1739S.CrossRefGoogle ScholarPubMed
85Chen, TC, Shao, A, Heath, H III, et al. (1993) An update on the vitamin D content of fortified milk from the United States and Canada. N Engl J Med 329, 1507.CrossRefGoogle Scholar
86Lips, P, Duong, T, Oleksik, A, et al. (2001) A global study of vitamin D status and parathyroid function in postmenopausal women with osteoporosis: baseline data from the Multiple Outcomes of Raloxifene Evaluation clinical trial. J Clin Endocrinol Metab 86, 12121221.CrossRefGoogle ScholarPubMed
87Dawson-Hughes, B, Heaney, RP, Holick, MF, et al. (2005) Estimates of optimal vitamin D status. Osteoporos Int 16, 713716.CrossRefGoogle ScholarPubMed
88Grant, WB & Holick, MF (2005) Benefits and requirements of vitamin D for optimal health: a review. Altern Med Rev 10, 94111.Google ScholarPubMed
89Vieth, R, Bischoff-Ferrari, H, Boucher, BJ, et al. (2007) The urgent need to recommend an intake of vitamin D that is effective. Am J Clin Nutr 85, 649650.CrossRefGoogle ScholarPubMed
90Hathcock, JN, Shao, A, Vieth, R, et al. (2007) Risk assessment for vitamin D. Am J Clin Nutr 85, 618.CrossRefGoogle ScholarPubMed
91Weaver, CM (2003) 2003 W. O. Atwater Memorial Lecture: Defining nutrient requirements from a perspective of bone-related nutrients. J Nutr 133, 40634066.CrossRefGoogle Scholar
92Calvo, MS, Whiting, SJ & Barton, CN (2004) Vitamin D fortification in the United States and Canada: current status and data needs. Am J Clin Nutr 80, 1710S1716S.CrossRefGoogle ScholarPubMed
93Chee, WS, Suriah, AR, Chan, SP, et al. (2003) The effect of milk supplementation on bone mineral density in postmenopausal Chinese women in Malaysia. Osteoporos Int 14, 828834.CrossRefGoogle Scholar
94Du, X, Zhu, K, Trube, A, et al. (2004) School-milk intervention trial enhances growth and bone mineral accretion in Chinese girls aged 10–12 years in Beijing. Br J Nutr 92, 159168.CrossRefGoogle ScholarPubMed
95Shearer, MJ (1995) Vitamin K. Lancet 345, 229234.CrossRefGoogle ScholarPubMed
96Boskey, AL, Gadaleta, S, Gundberg, C, et al. (1998) Fourier transform infrared microspectroscopic analysis of bones of osteocalcin-deficient mice provides insight into the function of osteocalcin. Bone 23, 187196.CrossRefGoogle ScholarPubMed
97Shearer, 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
98Coutu, DL, Wu, JH, Monette, A, et al. (2008) Periostin, a member of a novel family of vitamin K-dependent proteins, is expressed by mesenchymal stromal cells. J Biol Chem 283, 1799118001.CrossRefGoogle ScholarPubMed
99Berkner, KL & Runge, KW (2004) The physiology of vitamin K nutriture and vitamin K-dependent protein function in atherosclerosis. J Thromb Haemost 2, 21182132.CrossRefGoogle ScholarPubMed
100Vermeer, C, Shearer, MJ, Zittermann, A, et al. (2004) Beyond deficiency: potential benefits of increased intakes of vitamin K for bone and vascular health. Eur J Nutr 43, 325335.CrossRefGoogle ScholarPubMed
101Thijssen, HH, Vervoort, LM, Schurgers, LJ, et al. (2006) Menadione is a metabolite of oral vitamin K. Br J Nutr 95, 260266.CrossRefGoogle ScholarPubMed
102Schurgers, LJ, Teunissen, KJ, Hamulyak, K, et al. (2007) Vitamin K-containing dietary supplements: comparison of synthetic vitamin K1 and natto-derived menaquinone-7. Blood 109, 32793283.CrossRefGoogle ScholarPubMed
103Schurgers, LJ, Geleijnse, JM, Grobbee, DE, et al. (1999) Nutritional intake of vitamin K1 (phylloquinone) and K2 (menaquinone) in The Netherlands. J Nutr Environ Med 9, 115122.CrossRefGoogle Scholar
104Booth, SL & Suttie, JW (1998) Dietary intake and adequacy of vitamin K. J Nutr 128, 785788.CrossRefGoogle ScholarPubMed
105Thane, CW, Paul, AA, Bates, CJ, et al. (2002) Intake and sources of phylloquinone (vitamin K1): variation with socio-demographic and lifestyle factors in a national sample of British elderly people. Br J Nutr 87, 605613.CrossRefGoogle Scholar
106Thane, CW, Bolton-Smith, C & Coward, WA (2006) Comparative dietary intake and sources of phylloquinone (vitamin K1) among British adults in 1986–7 and 2000–1. Br J Nutr 96, 11051115.CrossRefGoogle ScholarPubMed
107Institute of Medicine Food and Nutrition Board (2001) Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Manganese, Molybdenum, Nickel, Silicon, Vanadium and Zinc. Washington, DC: National Academy Press.Google Scholar
108Feskanich, D, Weber, P, Willett, WC, et al. (1999) Vitamin K intake and hip fractures in women: a prospective study. Am J Clin Nutr 69, 7479.CrossRefGoogle ScholarPubMed
109Booth, SL, Tucker, KL, Chen, H, et al. (2000) Dietary vitamin K intakes are associated with hip fracture but not with bone mineral density in elderly men and women. Am J Clin Nutr 71, 12011208.CrossRefGoogle Scholar
110Booth, SL, Broe, KE, Gagnon, DR, et al. (2003) Vitamin K intake and bone mineral density in women and men. Am J Clin Nutr 77, 512516.CrossRefGoogle ScholarPubMed
111Booth, SL, Broe, KE, Peterson, JW, et al. (2004) Associations between vitamin K biochemical measures and bone mineral density in men and women. J Clin Endocrinol Metab 89, 49044909.CrossRefGoogle ScholarPubMed
112Kalkwarf, HJ, Khoury, JC, Bean, J, et al. (2004) Vitamin K, bone turnover, and bone mass in girls. Am J Clin Nutr 80, 10751080.CrossRefGoogle ScholarPubMed
113Szulc, P, Chapuy, MC, Meunier, PJ, et al. (1996) Serum undercarboxylated osteocalcin is a marker of the risk of hip fracture: a three year follow-up study. Bone 18, 487488.CrossRefGoogle ScholarPubMed
114Vergnaud, P, Garnero, P, Meunier, PJ, et al. (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
115Luukinen, H, Kakonen, SM, Pettersson, K, et al. (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
116Szulc, P, Arlot, M, Chapuy, MC, et al. (1994) Serum undercarboxylated osteocalcin correlates with hip bone mineral density in elderly women. J Bone Miner Res 9, 15911595.CrossRefGoogle ScholarPubMed
117Knapen, MH, Nieuwenhuijzen Kruseman, AC, Wouters, RS, et al. (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
118Cockayne, S, Adamson, J, Lanham-New, S, et al. (2006) Vitamin K and the prevention of fractures: systematic review and meta-analysis of randomized controlled trials. Arch Intern Med 166, 12561261.CrossRefGoogle ScholarPubMed
119Braam, LA, Knapen, MH, Geusens, P, et al. (2003) Vitamin K1 supplementation retards bone loss in postmenopausal women between 50 and 60 years of age. Calcif Tissue Int 73, 2126.CrossRefGoogle ScholarPubMed
120Bolton-Smith, C, McMurdo, ME, Paterson, CR, et al. (2007) Two-year randomized controlled trial of vitamin K1 (phylloquinone) and vitamin D3 plus calcium on the bone health of older women. J Bone Miner Res 22, 509519.CrossRefGoogle ScholarPubMed
121Booth, SL, Dallal, G, Shea, MK, et al. (2008) Effect of vitamin K supplementation on bone loss in elderly men and women. J Clin Endocrinol Metab 93, 12171223.CrossRefGoogle Scholar
122Caraballo, PJ, Gabriel, SE, Castro, MR, et al. (1999) Changes in bone density after exposure to oral anticoagulants: a meta-analysis. Osteoporos Int 9, 441448.CrossRefGoogle ScholarPubMed
123Ducy, P, Desbois, C, Boyce, B, et al. (1996) Increased bone formation in osteocalcin-deficient mice. Nature 382, 448452.CrossRefGoogle ScholarPubMed
124Liu, G & Peacock, M (1998) Age-related changes in serum undercarboxylated osteocalcin and its relationships with bone density, bone quality, and hip fracture. Calcif Tissue Int 62, 286289.CrossRefGoogle ScholarPubMed
125Kaptoge, S, Dalzell, N, Welch, A, et al. (2005) Vitamin K and fracture risk: an effect on bone width not BMD? J Bone Miner Res 20, 1293.Google Scholar
126Knapen, MH, Schurgers, LJ & Vermeer, C (2007) Vitamin K2 supplementation improves hip bone geometry and bone strength indices in postmenopausal women. Osteoporos Int 18, 963972.CrossRefGoogle ScholarPubMed
127Schurgers, LJ, Shearer, MJ, Hamulyak, K, et al. (2004) Effect of vitamin K intake on the stability of oral anticoagulant treatment: dose–response relationships in healthy subjects. Blood 104, 26822689.CrossRefGoogle ScholarPubMed
128Sconce, E, Avery, P, Wynne, H, et al. (2007) Vitamin K supplementation can improve stability of anticoagulation for patients with unexplained variability in response to warfarin. Blood 109, 24192423.CrossRefGoogle ScholarPubMed
129Lehnerdt, F (1910) On the question of the substitution of calcium in the bones by strontium. II. Report. Strontium feeding in suckling animals, the influence of strontium on the bone system of suckled young animals. Beitr Pathol Anat 47, 215247.Google Scholar
130Shorr, E & Carter, AC (1952) The usefulness of strontium as an adjuvant to calcium in the remineralization of the skeleton in man. Bull Hosp Joint Dis 13, 5966.Google ScholarPubMed
131McCaslin, FE & Jane, JM (1959) The effect of strontium lactate in the treatment of osteoporosis. Proc Staff Meetings Mayo Clin 34, 329334.Google Scholar
132Grynpas, MD, Hamilton, E, Cheung, R, et al. (1996) Strontium increases vertebral bone volume in rats at a low dose that does not induce detectable mineralization defect. Bone 18, 253259.CrossRefGoogle Scholar
133Marie, PJ (1996) Effects of strontium on bone tissue and bone cells. In Therapeutic Uses of Trace Elements, pp. 277282 [Nève, J, Chappuis, P and Lamand, M, editors]. New York: Springer Verlag.CrossRefGoogle Scholar
134Marie, PJ, Garba, MT, Hott, M, et al. (1985) Effect of low doses of stable strontium on bone metabolism in rats. Miner Electrolyte Metab 11, 513.Google Scholar
135Marie, PJ & Hott, M (1986) Short-term effects of fluoride and strontium on bone formation and resorption in the mouse. Metabolism 35, 547551.CrossRefGoogle Scholar
136Skoryna, SC & Fuskova, M (1981) Effect of stable strontium supplementation. In Handbook of Stable Strontium, pp. 593617 [Skoryna, SC, editor]. New York: Plenum Press.CrossRefGoogle Scholar
137Marie, PJ, Ammann, P, Boivin, G, et al. (2001) Mechanisms of action and therapeutic potential of strontium in bone. Calcif Tissue Int 69, 121129.CrossRefGoogle ScholarPubMed
138Meunier, PJ, Roux, C, Seeman, E, et al. (2004) The effects of strontium ranelate on the risk of vertebral fracture in women with postmenopausal osteoporosis. N Engl J Med 350, 459468.CrossRefGoogle ScholarPubMed
139Reginster, JY, Seeman, E, De Vernejoul, MC, et al. (2005) Strontium ranelate reduces the risk of nonvertebral fractures in postmenopausal women with osteoporosis: Treatment of Peripheral Osteoporosis (TROPOS) study. J Clin Endocrinol Metab 90, 28162822.CrossRefGoogle ScholarPubMed
140Reginster, JY, Felsenberg, D, Boonen, S, et al. (2008) Effects of long-term strontium ranelate treatment on the risk of nonvertebral and vertebral fractures in postmenopausal osteoporosis: results of a five-year, randomized, placebo-controlled trial. Arthritis Rheum 58, 16871695.CrossRefGoogle ScholarPubMed
141Nakamura, T (2007) Therapeutic agents for disorders of bone and calcium metabolism. Osteoporotic fracture prevention by strontium ranelate (article in Japanese). Clin Calcium 17, 8087.Google Scholar
142Venugopal, B & Luckey, TD (1978) Metal Toxicity in Mammals. New York: Plenum Press.Google Scholar
143Pennington, JA & Jones, JW (1987) Molybdenum, nickel, cobalt, vanadium, and strontium in total diets. J Am Diet Assoc 87, 16441650.CrossRefGoogle ScholarPubMed
144Ozgur, S, Sumer, H & Kocoglu, G (1996) Rickets and soil strontium. Arch Dis Child 75, 524526.CrossRefGoogle ScholarPubMed
145Office of Health and Environmental Assessment (1990) Drinking Water Criteria Document for Stable Strontium. Washington, DC: Office of Drinking Water.Google Scholar
146Ministry of Agriculture, Fisheries and Food (1997) 1994 Total Diet Study: Metal and Other Elements, Food Safety Agency, Food Surveillance Information Sheets. London: MAFF.Google Scholar
147Varo, P, Saari, E, Paaso, A, et al. (1982) Strontium in Finnish foods. Int J Vitam Nutr Res 52, 342350.Google ScholarPubMed
148Agency for Toxic Substances and Disease Registry (2004) Toxicological Profile of Strontium. Washington, DC: US Department of Health and Human Services, Public Health Service.Google Scholar
149Martin, AD (2001) Apports Nutritonnels Conseillés pour la Population Française (Recommended Nutritional Intakes for the French Population), 3rd ed.Paris: TEC&DOC.Google Scholar
150Kshirsagar, SG (1985) Effect of age on strontium–calcium discrimination by rat tissues. Indian J Exp Biol 23, 366369.Google ScholarPubMed
151El Solh, N & Rousselet, F (1981) Effects of stable strontium administration on calcium metabolism with particular reference to low-calcium diet. In Handbook of Stable Strontium, pp. 515544 [Skoryna, SC, editor]. New York: Plenum Press.CrossRefGoogle Scholar
152Morohashi, T, Sano, T & Yamada, S (1994) Effects of strontium on calcium metabolism in rats. I. A distinction between the pharmacological and toxic doses. Jpn J Pharmacol 64, 155162.CrossRefGoogle Scholar
153Storey, E (1961) Strontium ‘rickets’: bone, calcium and strontium changes. Australas Ann Med 10, 213222.CrossRefGoogle ScholarPubMed
154Rousselet, F, El Solh, N, Maurat, JP, et al. (1975) Strontium et metabolisme calcique: interaction strontium–vitamine D (Strontium and calcium metabolism: strontium–vitamin D interaction). Comp Rend Séances Soc Biol 169, 322329.Google Scholar
155Svensson, O, Reinholt, FP, Engfeldt, B, et al. (1987) The parathyroid gland in metal rickets. A stereological study. Acta Pathol Microbiol Immunol Scand 95, 309314.Google ScholarPubMed
156Marcus, CS & Wasserman, RH (1965) Comparison of intestinal discrimination between calcium 47, strontium 85, and barium 133. Am J Physiol 209, 973977.CrossRefGoogle ScholarPubMed
157Storey, E (1962) Intermittent bone changes and multiple cartilage defects in chronic strontium rickets in rats. J Bone Joint Surg Br 44-B, 194208.CrossRefGoogle ScholarPubMed
158Browning, E (1969) Toxicity of Industrial Metals, 2nd ed.New York: Appleton-Century-Croft.Google Scholar
159Sugihira, N & Suzuki, KT (1991) Discrimination between strontium and calcium in suckling rats. Biol Trace Elem Res 29, 110.CrossRefGoogle ScholarPubMed
160Schrooten, I, Cabrera, W, Goodman, WG, et al. (1998) Strontium causes osteomalacia in chronic renal failure rats. Kidney Int 54, 448456.CrossRefGoogle ScholarPubMed
161Fatemi, S, Ryzen, E, Flores, J, et al. (1991) Effect of experimental human magnesium depletion on parathyroid hormone secretion and 1,25-dihydroxyvitamin D metabolism. J Clin Endocrinol Metab 73, 10671072.CrossRefGoogle Scholar
162Tucker, KL, Hannan, MT, Chen, H, et al. (1999) Potassium, magnesium, and fruit and vegetable intakes are associated with greater bone mineral density in elderly men and women. Am J Clin Nutr 69, 727736.CrossRefGoogle ScholarPubMed
163New, SA, Robins, SP, Campbell, MK, et al. (2000) Dietary influences on bone mass and bone metabolism: further evidence of a positive link between fruit and vegetable consumption and bone health? Am J Clin Nutr 71, 142151.CrossRefGoogle Scholar
164New, SA (2003) Intake of fruit and vegetables: implications for bone health. Proc Nutr Soc 62, 889899.CrossRefGoogle ScholarPubMed
165Macdonald, HM, New, SA, Fraser, WD, et al. (2005) Low dietary potassium intakes and high dietary estimates of net endogenous acid production are associated with low bone mineral density in premenopausal women and increased markers of bone resorption in postmenopausal women. Am J Clin Nutr 81, 923933.CrossRefGoogle ScholarPubMed
166Wang, MC, Moore, EC, Crawford, PB, et al. (1999) Influence of pre-adolescent diet on quantitative ultrasound measurements of the calcaneus in young adult women. Osteoporos Int 9, 532535.CrossRefGoogle ScholarPubMed
167Angus, RM, Sambrook, PN, Pocock, NA, et al. (1988) Dietary intake and bone mineral density. Bone Miner 4, 265277.Google ScholarPubMed
168New, SA, Bolton-Smith, C, Grubb, DA, et al. (1997) Nutritional influences on bone mineral density: a cross-sectional study in premenopausal women. Am J Clin Nutr 65, 18311839.CrossRefGoogle Scholar
169Ilich, JZ, Brownbill, RA & Tamborini, L (2003) Bone and nutrition in elderly women: protein, energy, and calcium as main determinants of bone mineral density. Eur J Clin Nutr 57, 554565.CrossRefGoogle ScholarPubMed
170Tranquilli, AL, Lucino, E, Garzetti, GG, et al. (1994) Calcium, phosphorus and magnesium intakes correlate with bone mineral content in postmenopausal women. Gynecol Endocrinol 8, 5558.CrossRefGoogle ScholarPubMed
171Ryder, KM, Shorr, RI, Bush, AJ, et al. (2005) Magnesium intake from food and supplements is associated with bone mineral density in healthy older white subjects. J Am Geriatr Soc 53, 18751880.CrossRefGoogle ScholarPubMed
172Carpenter, TO, DeLucia, MC, Zhang, JH, et al. (2006) A randomized controlled study of effects of dietary magnesium oxide supplementation on bone mineral content in healthy girls. J Clin Endocrinol Metab 91, 48664872.CrossRefGoogle Scholar
173Abraham, GE & Grewal, H (1990) A total dietary program emphasizing magnesium instead of calcium. Effect on the mineral density of calcaneous bone in postmenopausal women on hormonal therapy. J Reprod Med 35, 503507.Google ScholarPubMed
174Stendig-Lindberg, G, Tepper, R & Leichter, I (1993) Trabecular bone density in a two year controlled trial of peroral magnesium in osteoporosis. Magnes Res 6, 155163.Google Scholar
175Dimai, HP, Porta, S, Wirnsberger, G, et al. (1998) Daily oral magnesium supplementation suppresses bone turnover in young adult males. J Clin Endocrinol Metab 83, 27422748.Google ScholarPubMed
176Flynn, A, Moreiras, O, Stehle, P, et al. (2003) Vitamins and minerals: a model for safe addition to foods. Eur J Nutr 42, 118130.CrossRefGoogle Scholar
177Ford, ES & Mokdad, AH (2003) Dietary magnesium intake in a national sample of US adults. J Nutr 133, 28792882.CrossRefGoogle Scholar
178Elmadfa, I, Weichselbaum, E, König, J, et al. (2005) European nutrition and health report 2004. Forum Nutr 1220.Google ScholarPubMed
179Touvier, M, Boutron-Ruault, MC, Volatier, JL, et al. (2005) Efficacy and safety of regular vitamin and mineral supplement use in France: results from the ECCA study. Int J Vitam Nutr Res 75, 201209.CrossRefGoogle ScholarPubMed
180Abdulla, M, Andersson, I, Asp, NG, et al. (1981) Nutrient intake and health status of vegans. Chemical analyses of diets using the duplicate portion sampling technique. Am J Clin Nutr 34, 24642477.CrossRefGoogle ScholarPubMed
181Haddad, EH, Berk, LS, Kettering, JD, et al. (1999) Dietary intake and biochemical, hematologic, and immune status of vegans compared with nonvegetarians. Am J Clin Nutr 70, 586S593S.CrossRefGoogle ScholarPubMed
182Clark, I & Belanger, L (1967) The effects of alterations in dietary magnesium on calcium, phosphate and skeletal metabolism. Calcif Tissue Res 1, 204218.CrossRefGoogle ScholarPubMed
183Thurnher, H & Kresbach, E (1961) Contribution to the clinical aspects and treatment of magnesium sulfate poisoning (article in German). Wien Klin Wochenschr 73, 356357.Google Scholar
184Wallace, KL, Curry, SC, LoVecchio, F, et al. (1998) Effect of magnesium hydroxide on iron absorption following simulated mild iron overdose in human subjects. Acad Emerg Med 5, 961965.CrossRefGoogle ScholarPubMed
185Sturniolo, GC, Montino, MC, Rossetto, L, et al. (1991) Inhibition of gastric acid secretion reduces zinc absorption in man. J Am Coll Nutr 10, 372375.CrossRefGoogle ScholarPubMed
186Griffin, JP & D'Arcy, PF (1981) Handbuch der Arzneimittelinteraktionen (Handbook of Drug Interactions). Munich, Germany: Oldenburg-Verlag.Google Scholar
187Andon, MB, Ilich, JZ, Tzagournis, MA, et al. (1996) Magnesium balance in adolescent females consuming a low- or high-calcium diet. Am J Clin Nutr 63, 950953.CrossRefGoogle ScholarPubMed
188Lewis, NM, Marcus, MS, Behling, AR, et al. (1989) Calcium supplements and milk: effects on acid–base balance and on retention of calcium, magnesium, and phosphorus. Am J Clin Nutr 49, 527533.CrossRefGoogle Scholar
189Sojka, J, Wastney, M, Abrams, S, et al. (1997) Magnesium kinetics in adolescent girls determined using stable isotopes: effects of high and low calcium intake. Am J Physiol 273, R710R715.Google ScholarPubMed