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Ethnic differences in calcium, phosphate and bone metabolism

Published online by Cambridge University Press:  12 March 2014

J. Redmond*
Affiliation:
Elsie Widdowson Laboratory, Medical Research Council Human Nutrition Research, Cambridge CB1 9NL, UK
L. M. A. Jarjou
Affiliation:
Medical Research Council Keneba, The Gambia
B. Zhou
Affiliation:
Department of Public health, Shenyang Medical College, 146 Huanghe North Street, Shenyang 110034, People's Republic of China
A. Prentice
Affiliation:
Elsie Widdowson Laboratory, Medical Research Council Human Nutrition Research, Cambridge CB1 9NL, UK Medical Research Council Keneba, The Gambia
I. Schoenmakers
Affiliation:
Elsie Widdowson Laboratory, Medical Research Council Human Nutrition Research, Cambridge CB1 9NL, UK
*
*Corresponding author: J. Redmond, fax +44(0)1223437515, email jean.redmond@mrc-hnr.cam.ac.uk
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Abstract

The prevalence of osteoporosis and the incidence of age-related fragility fracture vary by ethnicity. There is greater than 10-fold variation in fracture probabilities between countries across the world. Mineral and bone metabolism are intimately interlinked, and both are known to exhibit patterns of daily variation, known as the diurnal rhythm (DR). Ethnic differences are described for Ca and P metabolism. The importance of these differences is described in detail between select ethnic groups, within the USA between African-Americans and White-Americans, between the Gambia and the UK and between China and the UK. Dietary Ca intake is higher in White-Americans compared with African-Americans, and is higher in White-British compared with Gambian and Chinese adults. Differences are observed also for plasma 25-hydroxy vitamin D, related to lifestyle differences, skin pigmentation and skin exposure to UVB-containing sunshine. Higher plasma 1,25-dihydroxy vitamin D and parathyroid hormone are observed in African-American compared with White-American adults. Plasma parathyroid hormone is also higher in Gambian adults and, in winter, in Chinese compared with White-British adults. There may be ethnic differences in the bone resorptive effects of parathyroid hormone, with a relative skeletal resistance to parathyroid hormone observed in some, but not all ethnic groups. Renal mineral excretion is also influenced by ethnicity; urinary Ca (uCa) and urinary P (uP) excretions are lower in African-Americans compared with White-Americans, and in Gambians compared with their White-British counterparts. Little is known about ethnic differences in the DR of Ca and P metabolism, but differences may be expected due to known differences in lifestyle factors, such as dietary intake and sleep/wake pattern. The ethnic-specific DR of Ca and P metabolism may influence the net balance of Ca and P conservation and bone remodelling. These ethnic differences in Ca, P and the bone metabolism may be important factors in the variation in skeletal health.

Type
Conference on ‘Nutrition and healthy ageing’
Creative Commons
Creative Common License - CCCreative Common License - BY
The online version of this article is published within an Open Access environment subject to the conditions of the Creative Commons Attribution licence http://creativecommons.org/licenses/by/3.0/
Copyright
Copyright © The Authors 2014

Abbreviations:
DR

diurnal rhythm

FGF-23

fibroblast growth factor-23

PTH

parathyroid hormone

uCa/uCr

urinary Ca/urinary creatinine

uP

urinary P

Ethnicity is generally defined as ‘the fact or sense of belonging to a particular ethnic group’( 1 ). An ethnic group shares a distinctive cultural and historical tradition, often associated with nationality, or region by which the group identifies itself and others recognise it( 1 ). This broad concept of ethnicity, encapsulating culture, lifestyle, identification, environment, biology and genetics, is what we refer to in this review.

Ethnic differences in bone health

The prevalence of osteoporosis and the incidence of age-related fragility fracture vary by ethnicity. Kanis et al. report a greater than 10-fold variation in fracture probability between countries across the world( Reference Kanis, Oden and McCloskey 2 ), and substantial differences are also seen between ethnic groups within a country. The age-adjusted incidence rates of hip and distal-forearm fractures in elderly West African men and women are shown to be substantially lower than those found in Britain( Reference Adebajo, Cooper and Evans 3 ). Similarly, Yan et al. have reported a low incidence of hip fracture in Northern China, and the overall male-to-female ratio for hip fracture incidence was 1·15:1 in contrast with that of 0·34:1–0·43:1 in populations of most Western countries( Reference Yan, Zhou and Prentice 4 ). Differences are also found within the USA between ethnic groups. Age-adjusted hip fracture rates were reported to be 57/100 000 in African-American females, compared with 140/100 000 in White-American females( Reference Silverman and Madison 5 ), with similar trends for men( Reference Barrett, Baron and Karagas 6 ). Also, Asian and Hispanic men and women living in the USA have lower hip fracture rates than their White-American counterparts( Reference Silverman and Madison 5 , Reference Kellie and Brody 7 , Reference Lauderdale, Jacobsen and Furner 8 ). It appears that across the world, White populations are consistently reported to be at a higher risk of fracture than other ethnic groups( Reference Kanis, Oden and McCloskey 2 Reference Yan, Zhou and Prentice 4 , Reference Kellie and Brody 7 , Reference Lauderdale, Jacobsen and Furner 8 ). These differences cannot be fully explained by a lower bone mass in White populations. While African-Americans tend to have a higher bone mineral density than White-Americans, this is not the case for Asian-Americans, Asians or Africans. Fracture risk is multi-factorial and only partly depends on bone mass. Other factors influencing fracture risk are likely to be involved in the observed ethnic differences in bone health.

The multitude of factors determining fracture risk can be subdivided into extra-skeletal and skeletal factors. The former include age, gender, neuromuscular coordination, falls, and in the case of a fall, adiposity and soft tissue cushioning may absorb the force and thus influence the impact on the bone. Skeletal factors include bone mass, geometry, the rate of bone turnover and mineral metabolism. Mineral and bone metabolisms are intimately interlinked and this review focuses on ethnic variation in the metabolism of the bone forming minerals, Ca and phosphate (P).

Ca and P metabolism

Bone consists of an extracellular mineralised matrix consisting of mineral salts (mainly hydroxyapatite (Ca10(PO4)6(OH)2) crystals) bound to proteins. The metabolic function of bone is crucial for Ca and P homoeostasis. Ca, P and bone metabolism are regulated by common factors, mainly parathyroid hormone (PTH), 1,25-dihydroxy vitamin D (1,25(OH)2D) and fibroblast growth factor-23 (FGF-23). The parathyroid gland detects the fluctuations in plasma ionised Ca (Ca2+) concentration through the Ca2+-sensing receptor. In response to a reduction in plasma Ca2+, PTH is secreted by the parathyroid cells. In the kidney, PTH binds to the PTH receptor and stimulates renal Ca reabsorption from the urinary filtrate( Reference Favus, Goltzman and Rosen 9 ). This occurs through a multitude of actions, including the increase of the renal Na/K/Cl2 co-transporter to stimulate paracellular Ca reabsorption, and through the transient receptor potential channel TRPV5, to stimulate luminal Ca transfer( Reference Favus, Goltzman and Rosen 9 , Reference Lambers, Bindels and Hoenderop 10 ). PTH also stimulates the renal conversion of 25-hydroxy vitamin D (25(OH)D) to 1,25(OH)2D via the up-regulation of the enzyme 25-hydroxyvitamin-D-1-α-hydroxylase. This, in turn, increases the intestinal absorption of Ca and P. Both 1,25(OH)2D and PTH act together to stimulate osteoblasts to produce factors that activate osteoclastic bone resorption( Reference Favus, Goltzman and Rosen 9 ), liberating Ca and P into the extracellular fluid( Reference Favus, Goltzman and Rosen 9 ). At the same time, factors reflecting cellular function of bone are released into plasma, known as bone turnover markers.

FGF-23 is primarily a P-regulating hormone and increases in response to a high plasma P and 1,25(OH)2D( Reference White, Econs and Rosen 11 ). In normal physiology, FGF-23 is mainly produced by the osteocytes, but the FGF-23 mRNA is also expressed in the osteoblasts and the bone lining cells( Reference Riminucci, Collins and Fedarko 12 ). FGF-23 acts on the kidney to increase renal P excretion via down-regulation of the renal type-II transporters, NaP-IIa and NaP-IIc in the proximal tubule. In addition, FGF-23 acts to decrease the plasma 1,25(OH)2D( Reference White, Econs and Rosen 11 ). The net effect is to decrease plasma P concentration. This partly counteracts the potential PTH- and 1,25(OH)2D-induced release of P from the skeleton and the up-regulation of P absorption in the intestine.

Although an elevated plasma PTH increases bone turnover, the net effect on bone depends on the pattern and the duration of exposure to a high plasma PTH. A sustained high plasma PTH concentration due to primary or secondary hyperparathyroidism can lead to bone loss, whereas anabolic effects occur with intermittent exposures( Reference Lewiecki and Miller 13 Reference Frolik, Black and Cain 16 ). Therefore, PTH may have contrasting effects on the bone depending upon the length and degree of exposure. The action of PTH may differ between different ethnic groups( Reference Cosman, Morgan and Nieves 17 ).

Modulators of Ca and P metabolism and their regulators

Hormonal regulation of mineral metabolism ensures tight control of plasma Ca and P concentrations over a wide range of nutrient intakes and absorption. The plasma concentrations of the calciotropic hormones are therefore influenced by dietary factors. Many other factors influence their concentration. Kidney function influences plasma PTH, FGF-23, 1,25(OH)2D and 25(OH)D concentrations( Reference Koizumi, Komaba and Fukagawa 18 ). Plasma PTH is also influenced by age, BMI and fasting( Reference Kamycheva, Sundsfjord and Jorde 19 ). Plasma 25(OH)D is further influenced by levels of skin exposure to UVB-containing sunshine (related to clothing, sunscreen, air pollution) and skin tone( Reference Schoenmakers, Goldberg and Prentice 20 , Reference Prentice 21 ). Some of these modulators are known to differ by ethnicity, reflecting differences in lifestyle, physiological or genetic factors. Moreover, Ca and P metabolism exhibits variation during the day and the night in healthy individuals. This is known as the diurnal rhythm (DR). Data comparing the DR between ethnic groups are limited. They may be expected to differ, as they are influenced by lifestyle factors, and will be summarised later in this review.

Diurnal rhythms of Ca and P and regulators

DR refer to patterns of physiology, activity or behaviour that follow the day–night cycles, and these may be controlled by an underlying endogenous biological mechanism, known as the circadian rhythm( Reference Refinetti 22 ). DR repeat every 24 h and are associated with external factors such as sleep–wake cycles, light–dark cycles, meals or posture.

Biological data that follow a DR usually exhibit a change over time in a smooth and continuous manner, ascending to a maximum value, the peak and decreasing to a minimum value, or nadir. The amplitude refers to the variation over the day. The average value of a measurement can be derived from the diurnal curve and is referred to as the 24-h mean, as shown in Fig. 1.

Fig. 1. Schematic representation of the diurnal rhythm of biological data.

The DR of Ca, P and bone metabolism is known to be at least partially dictated by exogenous factors, such as dietary and sleep–wake patterns. The majority of this research has been conducted in White and Western populations.

The diurnal rhythms of Ca and P metabolism

Plasma total Ca is reported to have a nadir at night and a day-time peak in men and women (see Fig. 2)( Reference Greenspan, Dresner-Pollak and Parker 23 , Reference Rejnmark, Lauridsen and Vestergaard 24 ). It remains unclear whether this is related to the DR of plasma albumin( Reference Rejnmark, Lauridsen and Vestergaard 24 , Reference Ahmad, Hopkins and Fraser 25 ). Urinary Ca (as expressed in mmol/h or as a ratio to urinary creatinine (uCa/uCr)) follows a significant DR with a night-time nadir and a day-time peak in both younger and older adults( Reference Rejnmark, Lauridsen and Vestergaard 24 , Reference el-Hajj Fuleihan, Klerman and Brown 26 , Reference Calvo, Eastell and Offord 27 ). Plasma P tends to follow a DR with an increase during the day, with a peak late in the evening and night and a nadir in the early morning, both in post-menopausal women( Reference Rejnmark, Lauridsen and Vestergaard 24 ) and healthy adult men and women( Reference Jubiz, Canterbury and Reiss 28 ). Urinary P excretion (as measured by mmol/h or as uP/uCr), exhibits a nocturnal nadir and a day-time peak( Reference Rejnmark, Lauridsen and Vestergaard 24 , Reference el-Hajj Fuleihan, Klerman and Brown 26 ); this is consistent with the DR described for uCa excretion. The nocturnal decrease in renal Ca and P excretion is likely to partly reflect the biological response to nocturnal fasting by conserving minerals at the kidney level. The nocturnal decrease in urinary mineral excretion may also be associated with the DR in plasma PTH.

Fig. 2. Diurnal variation in total plasma Ca (albumin-adjusted: bold lines and unadjusted: broken line), phosphate (P) and parathyroid hormone (PTH) (change from 24 h mean, % mean and sem) in healthy post-menopausal women. P-value indicates the significance of the diurnal variation. Reproduced from( Reference Ahmad, Hopkins and Fraser 25 ) with permission. Figure 2 was granted permission for reproduction by Copyright Clearance Center's RightsLink service by the European Journal of Endocrinology. License no.: 3213570527941.

The diurnal rhythm of parathyroid hormone

Plasma PTH concentration exhibits a well-documented DR with two peaks in healthy people, one in the afternoon/evening, and one at night (see Fig. 2)( Reference Greenspan, Dresner-Pollak and Parker 23 , Reference Rejnmark, Lauridsen and Vestergaard 24 , Reference el-Hajj Fuleihan, Klerman and Brown 26 , Reference Ledger, Burritt and Kao 29 ). The timing of the nocturnal peak of plasma PTH concentration corresponds to a decrease in uCa/uCr excretion and (with a time lag) to the decrease in uP/uCr( Reference el-Hajj Fuleihan, Klerman and Brown 26 ). This is suggestive of a physiological role for the DR of PTH in regulating renal Ca and P excretion( Reference el-Hajj Fuleihan, Klerman and Brown 26 ).

Studies of the pathological conditions have shown changes in the DR of PTH( Reference Ahmad, Hopkins and Fraser 25 , Reference Fraser, Logue and Christie 30 Reference Fraser, Ahmad and Vora 32 ). A comparative study between osteoporotic and healthy women reported a significant DR of PTH in both the groups, but with differences observed between the groups( Reference Joseph, Ahmad and Ul-Haq 33 ). In osteoporotic women, there was a higher 24-h mean of plasma PTH concentration with a smaller nocturnal increase, and the nocturnal peak occurred at an earlier time compared with healthy women( Reference Joseph, Ahmad and Ul-Haq 33 ). These findings suggest that the DR of plasma PTH may be important for overall mineral and bone metabolisms. The physiology of the DR of plasma PTH has been reviewed elsewhere in detail( Reference Fraser, Ahmad and Vora 32 ).

The diurnal rhythms of 1,25(OH)2D, vitamin D binding protein and fibroblast growth factor-23

Plasma 1,25(OH)2D and vitamin-D-binding-protein were found to have a significant DR in postmenopausal women, although the free fraction of 1,25(OH) 2D (i.e. not bound to the vitamin-D-binding-protein) did not vary over the 24-h cycle( Reference Rejnmark, Lauridsen and Vestergaard 24 ). Only one study is available which investigates the DR of FGF-23 and has reported that FGF-23 did not have any significant DR in healthy children and adults and patients with X-linked hypophosphataemia, although a significant DR was observed for its biological co-factor, Klotho( Reference Carpenter, Insogna and Zhang 34 ).

The diurnal rhythms of bone turnover markers

Biochemical markers of bone turnover exhibit a DR, with a night-time peak and a day-time nadir( Reference Greenspan, Dresner-Pollak and Parker 23 , Reference Clowes, Hannon and Yap 35 Reference Wichers, Schmidt and Bidlingmaier 37 ). In a study of healthy men, the bone resorption marker, carboxy-terminal-collagen-crosslinks had a night-time peak that was 66 % greater than the 24-h mean( Reference Wichers, Schmidt and Bidlingmaier 37 ). The DR of the bone formation markers osteocalcin and the bone-alkaline-phosphatase exhibits less variation than the DR of bone resorption, and the amplitude is typically only 10–20 % of the 24-h mean( Reference Greenspan, Dresner-Pollak and Parker 23 , Reference Gundberg, Markowitz and Mizruchi 38 ); which may relate to the differences in metabolism or excretion of the markers( Reference Clowes, Hannon and Yap 35 ).

The DR of the bone turnover markers is partially dictated by exogenous factors; it is altered by fasting and food intake( Reference Clowes, Hannon and Yap 35 , Reference Schlemmer and Hassager 39 , Reference Walsh and Henriksen 40 ). It was reported that plasma concentrations of the bone resorption marker carboxy-terminal-collagen-crosslinks, and to a lesser extent the bone formation markers procollagen-type-I-N-terminal-propeptide and osteocalcin, were significantly higher after 9 h fasting compared with the fed state( Reference Clowes, Hannon and Yap 35 ). There are acute post-prandial changes in bone turnover that may be associated with changes in the activity of mature bone cells( Reference Walsh and Henriksen 40 ). Potential mediators of this response include calciotropic hormones, growth hormone, pancreatic peptides and incretin hormones. The DR of bone resorption has also been described to be modulated by the pattern of dietary Ca intake( Reference Blumsohn, Herrington and Hannon 41 Reference Aerssens, Declerck and Maeyaert 43 ). Further information may be found in a recent review( Reference Walsh and Henriksen 40 ).

Ahmad et al. reported an association between the DR of plasma concentrations of PTH and bone turnover markers; the timing of the peak concentrations of the carboxy-terminal-collagen-crosslinks and the procollagen-type-I-N-terminal-propeptide lagged behind the peak concentration of PTH by about 3 h( Reference Ahmad, Hopkins and Fraser 25 ). The results of this study suggest that PTH may have some regulatory role in the DR of bone resorption and formation, as reflected by the markers of the bone turnover( Reference Ahmad, Hopkins and Fraser 25 ), although this has not been consistently seen( Reference Ledger, Burritt and Kao 29 ).

Taken together, these results suggest the homoeostasis of plasma Ca at night, in the absence of Ca intake, is maintained by an enhanced bone resorption and also by an enhanced renal reabsorption of Ca( Reference Bell, Williamson and Hollis 44 ). This homoeostasis is in part, but not completely, mediated via a nocturnal increase in plasma PTH. Differences in DR of Ca, P and bone metabolisms between healthy individuals and patients with osteoporosis are reported( Reference Fraser, Logue and Christie 30 , Reference Eastell, Calvo and Burritt 31 ), particularly in PTH and uCa excretions. This indicates that they may be important for Ca balance and skeletal integrity.

Little is known about the influence of ethnicity on these DR. Differences may be expected between ethnic groups due to differences in lifestyle factors, including the timing of sleep–wake patterns, the pattern of dietary intake and total dietary intake. Differences in dietary intake and other factors associated with Ca and P metabolisms may vary considerably between ethnic groups, and will be discussed in this review.

Ethnic differences in Ca and P metabolism

Ethnic differences in dietary intake

Differences in food availability, cultural preferences and socioeconomic factors contribute to differences in dietary intake between ethnic groups within and between countries.

Ca is present in a wide range of foods, although the bioavailability varies depending on the source. Milk and milk products have a high Ca content. Plant sources of Ca include pulses, whole-grains, nuts, some dried fruit, tofu and green vegetables. On the population level, Ca intakes can vary by approximately 5-fold depending on the types of foods consumed( Reference Prentice 45 ). They range from very low intakes (200–400 mg/d) in some parts of Asia (e.g. China, Japan) and Africa (e.g. The Gambia, Kenya)( Reference Prentice, Laskey and Shaw 46 Reference Zhang, Wang and Wang 51 ) with Ca from vegetables, legumes, cereals and nuts accounting for much of the intake( Reference Prentice, Laskey and Shaw 46 , Reference Zhang, Wang and Wang 51 ) to higher intakes in mostly White populations (>750 mg/d) of the USA, the UK and the Northern European countries( 52 Reference Angbratt, Timpka and Blomberg 54 ).

Protein-rich foods (milk, meat, poultry and fish) and cereal grains provide the majority of dietary phosphorus intake( Reference Knochel and Shils 55 ). The Ca:P ratio may be important, but little is known about their ethnic differences in dietary Ca:P ratio. Spencer et al., showed that although Ca balance did not change with varying intakes of dietary P, the higher P intake resulted in a significant decrease of the daily uCa output( Reference Spencer, Kramer and Osis 56 ). This may be related to the lower availability of Ca for intestinal absorption due to its binding to P. The effect of the dietary Ca:P ratio on bone health is inconclusive.

Differences in dietary intake may exist between the ethnic groups living in the same geographical region, for example, within the USA, as detailed in the next section. Within the UK, 42 % of women of African or Caribbean origin, and 36 % of women of South-Asian or other Asian ethnic origin had Ca intakes below the lower reference nutrient intake, compared with only 8 % of White-British women( 52 , Reference Nelson, Erens and Bates 57 ). Also, a Canadian study comparing Western-born Chinese, recent Chinese migrants to Canada and White-Canadians found differences in the macro- and the micro-nutrient intakes between these groups( Reference Tam, Hislop and Hanley 58 ).

In the remainder of this review, we will focus on selected ethnic groups, describing Ca and P intake and the influence this has on Ca and P regulation and bone metabolism. The focus will be to compare and contrast Ca and P metabolism between: (a) African-American and White-Americans in the USA, as an example of the differences between groups in the same geographical location; (b) African in the Gambia and White-British in the UK and (c) Chinese in Northern China and White-British in the UK, as examples of differences between the ethnic groups living in their environment of origin.

Ethnic differences in Ca and P metabolism: African-Americans compared with White-Americans

Ethnic differences in dietary Ca and P intakes in the USA

Within the USA, ethnic groups differ in dietary Ca intake. White-Americans have a Ca intake close to the recommendations (∼900 mg/d), while African-Americans have a lower Ca intake at all stages of life, as documented in the National Health and Nutrition Examination Survey( Reference Alaimo, McDowell and Briefel 53 ) and other studies( Reference Bell, Williamson and Hollis 44 , Reference Aloia, Mikhail and Pagan 59 ). African-Americans are reported to consume the same or less dietary P than White-Americans( Reference Fulgoni, Nicholls and Reed 60 ).

Some studies have reported greater fractional and total intestinal Ca absorption in African-Americans compared with White-American children and adolescents( Reference Abrams, O'Brien and Liang 61 , Reference Braun, Palacios and Wigertz 62 ). However, Bell et al. did not find any differences in fractional intestinal Ca absorption, despite the finding of lower serum 25(OH)D concentration and 24-h uCa excretion and higher serum 1,25(OH)2D in African-Americans than in White-American adolescents( Reference Bell, Yergey and Vieira 63 ).

Ethnic differences in 25(OH)D in the USA

After exposure to a single standard dose of UV radiation, there is less dermal synthesis of vitamin D3 from 7-dehydrocholesterol in darker skin because of the absorption of UVB-light by the skin pigment( Reference Clemens, Adams and Henderson 64 ), although the total capacity appears to be similar in African-Americans and White-American young adults when exposed to unlimited sunshine( Reference Brazerol, McPhee and Mimouni 65 ). Consequently, when living in temperate climates, darker skinned individuals tend to have lower plasma 25(OH)D concentrations. This is reflected in data obtained within the USA, including the National Health and Nutrition Examination Survey, where for similar amounts of UVB-containing sunshine exposure, African-Americans have lower 25(OH)D in winter and summer( Reference Aloia, Mikhail and Pagan 59 , Reference Dawson-Hughes 66 , Reference Gutierrez, Farwell and Kermah 67 ).

The lower plasma 25(OH)D concentration may also be partly explained by a higher BMI on average in African-Americans, as BMI is inversely associated with plasma 25(OH)D( Reference Arunabh, Pollack and Yeh 68 ). However, Coney et al. report that ethnic differences in plasma 25(OH)D remain after adjustment for body weight, percentage body fat and BMI( Reference Coney, Demers and Dodson 69 ). The lower 25(OH)D may be possibly explained partly by genetic variations in vitamin D synthesis, the vitamin-D-binding-protein and/or metabolism between ethnic groups( Reference Dawson-Hughes 66 , Reference Signorello, Shi and Cai 70 ).

Ethnic differences in regulatory hormones in the USA

Plasma PTH, 1,25(OH)2D and urinary cyclic-adenosine-3′,5′-monophosphate (an indicator of renal PTH activity) have been reported to be higher in African-Americans compared with White-American adults( Reference Finkelstein, Sowers and Greendale 71 Reference Bell 73 ). A lower vitamin D status, in addition to a lower Ca intake, may explain these findings( Reference Bell, Greene and Epstein 72 ), since PTH is a primary regulator of Ca metabolism, as described earlier. The higher plasma PTH in African-Americans, however, may not lead to a similarly increased rate of bone turnover or risk of osteoporosis as it does for White-Americans. A comparative study of African-American and White-American women matched for age and weight, reported that, despite having lower plasma 25(OH)D and higher plasma PTH, African-American women have a higher bone mineral density and bone mineral content and lower bone turnover rate( Reference Aloia, Mikhail and Pagan 59 ). This was confirmed by other studies reporting lower concentrations of bone turnover markers in African-Americans despite a similar or higher plasma PTH as White-Americans( Reference Bell, Greene and Epstein 72 , Reference Kleerekoper, Nelson and Peterson 74 ). This is further underpinned by the results of a controlled PTH infusion study showing a lower rise in the markers of bone resorption in African-American compared with White-American premenopausal women in response to the same amount of infused PTH( Reference Cosman, Morgan and Nieves 17 ). Furthermore, histomorphometric analysis of biopsies of the iliac crest after double-tetracycline labelling showed that the bone formation rate in African-American adults was only one-third that of White men and women( Reference Weinstein and Bell 75 ). In addition, the relationship between plasma 25(OH)D concentration and bone outcomes differs by ethnicity; a lower plasma 25(OH)D is associated with a lower bone mineral density in White-Americans, but not African-Americans( Reference Gutierrez, Farwell and Kermah 67 ). Taken together, these pieces of evidence suggest that the bone resorptive response to PTH differs between these groups, and it has been suggested that African-Americans have a relative skeletal resistance to PTH( Reference Gutierrez, Farwell and Kermah 67 ).

Ethnic differences in renal mineral excretion in the USA

Studies comparing ethnic groups in the USA have shown that the African-American adults have lower daily uCa and uP excretions across all ages( Reference Aloia, Mikhail and Pagan 59 , Reference Braun, Palacios and Wigertz 62 , Reference Bell, Greene and Epstein 72 , Reference Gutierrez, Isakova and Smith 76 ). Postmenopausal African-American women excrete on average 65 mg less uCa/d and 120 mg less uP/d than White-American women( Reference Taylor and Curhan 77 ). In steady-state conditions of mineral ion balance, the daily urinary mineral excretion equates to net absorption from dietary sources( Reference Gutierrez, Isakova and Smith 76 ); accordingly, it has been speculated that the lower urinary mineral excretion among African-Americans is due to a lower intestinal absorption of Ca and P. This, however, needs to be interpreted with consideration of dietary intake. As mentioned earlier, when compared with White-Americans, African-Americans consume less dietary Ca and the same or less dietary P( Reference Fulgoni, Nicholls and Reed 60 ). It has been demonstrated in adolescents and adult women that lower daily uCa excretion in African-Americans is primarily determined by a higher renal Ca conservation rather than lower fractional intestinal Ca absorption( Reference Bell, Yergey and Vieira 63 , Reference Dawson-Hughes, Harris and Finneran 78 ). These differences cannot be fully explained by a higher plasma PTH and a 1,25(OH)2D concentration in African-Americans. A lower 24-h Ca excretion was reported in African-Americans compared with White-American adolescent girls across a range of controlled dietary Ca intakes, and at similar concentrations of plasma 25(OH)D, 1,25(OH)2D and PTH( Reference Braun, Palacios and Wigertz 62 ). This was confirmed by a study by Gutierrez et al. examining ethnic differences in postprandial urinary fractional mineral excretion between African-American and White-American adults in samples collected for 4 h following a standardised meal( Reference Gutierrez, Isakova and Smith 76 ). Despite similar plasma PTH and FGF-23 concentrations, African-Americans had ∼35 % lower fractional Ca excretion and ∼30 % lower postprandial fractional P excretion than White-Americans( Reference Gutierrez, Isakova and Smith 76 ). These pieces of evidence suggest that African-Americans have a proportionally higher renal mineral conservation than White-Americans.

Overall, there appears to be strong evidence supporting the biologically relevant ethnic differences across all aspects of Ca and P metabolism and in the concentrations and responses to the regulators between African-Americans and White-Americans. The differences described in the skeletal responsivity to PTH, the rate of bone remodelling and the differences in Ca and P retentions may be associated with ethnic differences in bone mass and fracture risk (Table 1).

Table 1. Factors associated with ethnic differences in Ca, P and bone metabolism within the USA

PTH, parathyroid hormone.

* Arrows indicate the differences compared with White-Americans.

Ethnic differences in Ca and P metabolism: The Gambia v. the UK

Ethnic differences in dietary intake: The Gambia v. the UK

Dietary Ca intake in The Gambia, West Africa, is very low (200–400 mg/d)( Reference Yan, Schoenmakers and Zhou 47 , Reference Jarjou, Prentice and Sawo 79 , Reference Schoenmakers, Ginty and Jarjou 80 ). The main contributors to daily Ca intake are leaves, fish, locust beans, cereals, groundnuts and local salt, while milk is reported to account for only 5 % of Ca intake( Reference Prentice, Laskey and Shaw 46 ). In the UK, milk and milk products contribute substantially to dietary Ca intake (approximately 56 %). Daily Ca intake is generally close to recommendations (760–960 mg/d) with some regional variations( 52 ). We have previously reported that the dietary Ca and Ca:P intakes were lower in rural Gambian compared with White-British adolescents and older adults from Cambridge( Reference Yan, Schoenmakers and Zhou 47 , Reference Schoenmakers, Ginty and Jarjou 80 ).

Ethnic differences in 25(OH)D: The Gambia v. the UK

Vitamin D status in The Gambia is generally higher than in the UK. Plasma 25(OH)D was reported to be 60–100 nmol/l in Gambian men and women throughout the year across all ages and in pregnancy( Reference Prentice 21 , Reference Schoenmakers, Ginty and Jarjou 80 Reference Schoenmakers, Jarjou and Goldberg 83 ). In the UK, vitamin D status undergoes seasonal variation. The UK National Diet and Nutrition Survey reported mean annual 25(OH)D concentrations as 45·6 (sd 22·6)nmol/l for men and 49·6 (sd 25·6)nmol/l for women aged 19–64 years( Reference Bates, Lennox and Prentice 84 ).

Ethnic differences in regulatory factors: The Gambia v. the UK

Plasma PTH and 1,25(OH)2D concentrations are raised in Gambians compared with White-British subjects, and this is likely the result of their very low Ca intake( Reference Schoenmakers, Ginty and Jarjou 80 , Reference Aspray, Yan and Prentice 82 , Reference Prentice, Shaw and Laskey 85 ). A higher plasma PTH in the Gambia is found in conjunction with higher plasma concentrations of markers of osteoblast activity, with or without the concomitant higher markers of osteoclast activity( Reference Yan, Schoenmakers and Zhou 47 , Reference Aspray, Yan and Prentice 82 ). Therefore, it appears that the higher plasma PTH in The Gambia is associated with greater bone turnover, which is similar to the findings reported in South Africans( Reference Schnitzler 86 ), but is in contrast to the lower bone turnover and the reported skeletal resistance in African-Americans( Reference Cosman, Morgan and Nieves 17 ). These findings are confirmed by a detailed study investigating the bone response after oral-P-induced PTH secretion( Reference Yan, Schoenmakers and Zhou 47 ). This study showed no proportional differences between Gambians and White-British adults in the skeletal response to a raised plasma PTH( Reference Yan, Schoenmakers and Zhou 47 ), suggesting no difference in their relative skeletal sensitivity to PTH.

In White-British and other White populations, a high plasma PTH has been shown to be related to a lower hip bone mineral content( Reference Yan, Zhou and Wang 87 ) and pathologically elevated plasma PTH is a significant risk factor for osteoporosis and fracture( 88 ). In contrast, the chronically raised plasma PTH concentration that has been reported in the adults from The Gambia( Reference Schoenmakers, Ginty and Jarjou 80 , Reference Aspray, Yan and Prentice 82 , Reference Prentice, Shaw and Laskey 85 ), is not associated with a high incidence of fracture on a population level( Reference Aspray, Prentice and Cole 89 ). Schnitzler suggested that high bone turnover may remove fatigue damage and improve bone quality( Reference Schnitzler 86 ) and is a plausible explanation for the very low fracture rates in West Africa.

Ethnic differences in renal mineral excretion: The Gambia v. the UK

There is evidence for differences in renal mineral conservation between The Gambia and the UK. Aspray et al. found that the 24-h uCa and uP outputs were both significantly lower in the rural Gambian adult women, particularly after menopause, compared with White-British women( Reference Aspray, Yan and Prentice 82 ). Further investigations of renal Ca handling and the influence of dietary intake in elderly men and women from the Gambia and the UK showed that the 2-h fasting uCa/uCr excretion was significantly lower in Gambian subjects. The UCa/uCr remained lower in Gambian subjects even after statistical adjustment for dietary Ca intake and for glomerular filtration rate, body weight, height and body surface area( Reference Redmond, Jarjou and Palla 90 ). There were also differences in the fractional excretion of Ca (i.e. the percentage of Ca filtered by the kidney which is excreted in the urine), and in the tubular maximum of Ca (i.e. the maximum renal tubular mineral reabsorption, a threshold beyond which Ca is excreted in the urine)( Reference Redmond, Jarjou and Palla 90 ). Similar trends were observed for uP and these differences also remained after statistical adjustment for dietary intake.

Taken together, these pieces of evidence suggest important differences in the Ca and P regulatory axes between White-British and Gambian adults, and between Gambians and African-Americans.

Ethnic differences in Ca and P metabolism: China v. the UK

There are fewer data available on the differences between White-European and Chinese populations. The limited data available are summarised below.

Ethnic differences in dietary intake: China v. the UK

The traditional Chinese diet is low in Ca because of the low consumption of milk and milk products; Ca intake comes mainly from the consumption of green vegetables, legumes, cereals and small fish( Reference Zhang, Wang and Wang 51 , Reference Lau, Donnan and Barker 91 ). There is also considerable geographical dietary variation within China( Reference Hu, Zhao and Jia 48 ). Hu et al. reported that the mean Ca intake ranged from 200 to 700 mg/d depending on the region( Reference Hu, Zhao and Jia 48 ). Zhang et al. reported an increasing trend in the daily intake of Ca in Chinese adults between 1991 and 2009. Despite this, the average Ca intake in 2009 was 400 and 352 mg/d for men and women, respectively( Reference Zhang, Wang and Wang 51 ). Other studies report Ca intakes were typically below 500 mg/d( Reference Lau, Woo and Lam 92 , Reference Kruger, Ha and Todd 93 ). We have previously reported that older Chinese adults in Shenyang, Northern China have lower dietary Ca and P intakes and a lower dietary Ca:P ratio compared with their White-British counterparts( Reference Yan, Schoenmakers and Zhou 47 ).

Ethnic differences in 25(OH)D: China v. the UK

Zhang et al. reviewed publications measuring the plasma 25(OH)D in China in various age groups and in different areas of China( Reference Zhang, Stoecklin and Eggersdorfer 94 ). It was found that the vitamin D deficiency (defined as plasma 25(OH)D concentration <25 nmol/l) is observed in the Chinese population in almost all age groups and areas. For example, a high prevalence of deficiency was reported in Beijing (40°N) in the autumn and in Nanjing (latitude 31°N) during the winter months( Reference Zhang, Stoecklin and Eggersdorfer 94 ). In women from Nanjing, the mean plasma 25(OH)D concentrations were 22 and 32 nmol/l in the winter and the summer, respectively( Reference Jiang, Xu and Pan 95 ). In our studies, we have also reported significantly lower plasma 25(OH)D concentrations in the Chinese men in Shenyang (42°N) compared with their White-British counterparts in Cambridge (52°N) in late winter but not in summer( Reference Yan, Zhou and Wang 87 ).

The aetiology of vitamin D deficiency in China is likely to be multifactorial. At latitudes >30°N, there is little to no cutaneous synthesis of vitamin D during the winter; the length of the ‘UVB winter’ depends on the latitude and is longer further in the North( Reference Engelsen 96 ). In addition, there may be avoidance of skin exposure to UVB from sunshine for cultural reasons, and high levels of air pollution in some areas( Reference Zhang, Stoecklin and Eggersdorfer 94 ). Foods rich in vitamin D in the Chinese diet are scarce, and there is limited availability or consumption of vitamin D fortified products( Reference Zhang, Stoecklin and Eggersdorfer 94 ).

Ethnic differences in the regulatory factors: China v. The UK

We have previously reported that Chinese adults from Shenyang, Northern China had a higher plasma PTH concentration than White-British adults in winter months( Reference Yan, Zhou and Wang 87 ), although no ethnic differences were reported in data from the summer and winter combined( Reference Yan, Schoenmakers and Zhou 47 ). This finding is a likely result of lower Ca intake and, in winter, a lower plasma 25(OH)D in older Chinese adults than in White-British counterparts( Reference Yan, Schoenmakers and Zhou 47 , Reference Yan, Zhou and Wang 87 ). The relationship between plasma PTH and 25(OH)D differed between the two ethnic groups; Chinese adults had a higher plasma PTH for a given plasma 25(OH)D concentration( Reference Yan, Zhou and Wang 87 ). In older White-British adults, a negative relationship between PTH and the size-adjusted bone mineral content at the femoral trochanter (after adjustment for confounders) was observed, but this relationship was not seen in older Chinese adults (Fig. 3)( Reference Yan, Zhou and Wang 87 ). This finding was supported by a previous study of elderly men and women from Hong Kong where the bone mineral density at the spine and the hip was not associated with plasma PTH( Reference Woo, Lau and Swaminathan 97 ). This suggests that older Chinese adults may have a degree of resistance to the bone resorptive effects of PTH. This was however, not confirmed by a detailed study by Yan et al., as described in the next section.

Fig. 3. The relationship between Ln parathyroid hormone (PTH) and Ln bone mineral content (BMCt) at the femoral trochanter adjusting for bone area, weight, height, age and sex in Shenyang (x) and Cambridge (•) subjects. Reprinted from( 88 ) with permission from Elsevier. Figure 3 was granted permission for reproduction by Copyright Clearance Center's RightsLink service by Elsevier. License no.: 3196500798854.

Ethnic differences in renal mineral excretion: China v. The UK

There are few studies available directly comparing the differences in renal excretion in these ethnic groups. The comparative results obtained from the 2-h fasting urine samples collected from older Chinese and White-British adults suggested that there were no differences in either the uCa/uCr or the uP/uCr( Reference Yan, Schoenmakers and Zhou 47 ). Yan et al. investigated the potential skeletal resistance to PTH in older Chinese adults compared with older White-British adults by conducting a 5-d oral-P loading study to stimulate PTH secretion( Reference Yan, Schoenmakers and Zhou 47 ). No evidence was found for the differences in the skeletal response to PTH and the results did not support the hypothesis of skeletal resistance to PTH in older Chinese adults compared with older British adults. However, a potentially important difference in the renal response to PTH was found, which was greater in the Chinese group, resulting in more rapid P clearance compared with White-British( Reference Yan, Schoenmakers and Zhou 47 ).

Summary: ethnic differences in Ca and P metabolism

Older people from the Gambia and China have a lower Ca intake and concomitantly higher plasma PTH and 1,25(OH)2D concentrations than those from the UK. Yet, unlike in White-British adults, where a high PTH is considered to be a risk factor for osteoporotic fracture, this is not seen in Gambia and China, where the rates of fracture are lower than in the UK. However, while skeletal resistance to PTH is described in African-Americans, this has not been demonstrated in the small studies in older Gambian or Chinese adults.

Ethnic differences in the diurnal rhythms of Ca and P metabolism

Most of the evidence on the ethnic differences in Ca and P metabolism is derived from studies that have performed investigations under fasting conditions and at standardised times of the day, generally in the early to mid-morning. However, the markers of Ca and P metabolism exhibit a DR, as previously described. By limiting blood or urine sampling to one timepoint along a fluctuating pattern, group differences in the DR or the 24-h mean may go undetected. Little is known about ethnic differences in these DR and their potential influences on the net mineral balance and skeletal health, respectively. Differences in the DR may be anticipated due to known lifestyle differences, such as the total and the pattern of dietary Ca and P intakes, sleep/wake patterns, which are related to known differences in plasma concentrations of PTH and bone turnover markers between ethnic groups.

There is some evidence, albeit limited, to suggest ethnic differences in the DR of PTH and uCa excretion between African-American and White-American women( Reference Bell, Williamson and Hollis 44 ). In the single study investigating these differences, the 24-h mean of plasma PTH concentration was higher in African-Americans and their plasma PTH concentration did not change significantly between day-time and night-time, although uCa excretion (mmol/8 h) was lower at night compared to the day-time. In contrast, White-American women had a significant night-time increase in plasma PTH concentration and a more pronounced nocturnal decrease in uCa (mmol/8 h) than African-Americans. The differences suggest a higher renal conservation of Ca during the day in African-American compared with their White-American counterparts( Reference Bell, Williamson and Hollis 44 ).

This study also demonstrated that ethnic differences in Ca and P metabolism between African-American and White-American women depend on the time of the day. African-Americans had significantly lower uCa and uP (mmol/4 h) compared with White-Americans as measured in the morning and the day-time samples, respectively, but there were no ethnic differences found in uCa or uP (mmol/8 h) in the samples collected during the night( Reference Bell, Williamson and Hollis 44 ).

This highlights the importance of considering the influence of the DR in ethnic comparative research. Therefore, in the interpretation of the differences between ethnic groups, the timing of sample collection needs to be considered. These differences may relate to the timing of the peaks and the nadirs, the amplitude or the 24-h means of the measures of Ca, P and bone metabolism. Also, this may relate to the responses of the bone and kidney to the regulators, which may influence the net effect on Ca and P balances. To address this, we are conducting a comparative study comparing the DR of Ca and P metabolism between older adults from three ethnic groups.

The investigation of ethnic differences in the diurnal rhythms of Ca and P metabolism

In order to investigate the potential ethnic differences in the DR of Ca and P, we are investigating mineral and bone metabolism in three different ethnic groups: White-British, Gambian and Chinese older adults.

Each ethnic group is investigated in their habitual environment, thus allowing the participants to follow their normal daily routine. The participants are healthy older men and women (60–75 years). The habitual intake of key nutrients and the timing of their intake are assessed by using methods appropriate to each country, and a sleep/wake pattern questionnaire is administered. Blood samples are collected at 4-h intervals; participants were divided into two groups with a 2-h shift in their sampling times to allow for the analysis of 12 time-points over 24 h (Fig. 4). A 24-h urine collection was carried out, which was divided into seven separate timed collections. The study design allows for the analysis of Ca and P metabolism in the early morning fasting samples, as commonly collected in ethnic comparative research, but also the non-fasting samples at standardised times of the day. Biochemical analyses were performed for the markers of the mineral and the bone metabolism, and their regulators. Data analyses are currently ongoing.

Fig. 4. Timings of blood and urine collections.

The results of this study will provide information about ethnic differences in Ca, P and bone metabolism, the importance of the sampling time in ethnic comparative research and the potential influence of the DR on the differences in Ca and P metabolism. This will potentially provide mechanistic insights into ethnic differences in mineral and bone metabolism.

Conclusion

There are striking differences in Ca and P metabolism between ethnic groups, as described by using examples of the differences between the groups within the USA, and between the groups in different countries (The UK, The Gambia and China). These differences in Ca and P metabolism may be associated with the known differences in bone health in older age between these ethnic groups.

Few studies have taken into account the DR of Ca and P metabolism, which are potentially different between groups, as they may be influenced by differences in exogenous factors such as sleep and wake patterns and the absolute amounts and patterns of dietary intake of key nutrients.

Acknowledgements

We thank the Bone Research Society for their support for a research visit to Shenyang, China, through a Barbara Mawer Travel Fellowship. We wish to thank the participants of our research studies, and the members of the field staff for their assistance with conducting the studies.

Financial Support

This research was jointly funded by the Medical Research Council (MRC) and the Department for International Development (DFID) under the MRC/DFID Concordat agreement; MRC Unit Programmes U105960371 and U123261351. The MRC had no role in the design, analysis or writing of this article.

Conflicts of Interest

None.

Authorship

J. R. and I. S. drafted the manuscript; L. J., B. Z. and A. P. critically reviewed the manuscript and approved the final version.

References

1. Oxford English Dictionary (2002) 5th ed. New York: Oxford University Press.Google Scholar
2. Kanis, J, Oden, A, McCloskey, EV et al. (2012) A systematic review of hip fracture incidence and probability of fracture worldwide. Osteoporos Int 23, 22392256.Google Scholar
3. Adebajo, AF, Cooper, C & Evans, JG (1991) Fractures of the hip and distal forearm in West Africa and the United Kingdom. Age Ageing 20, 435438.CrossRefGoogle ScholarPubMed
4. Yan, L, Zhou, B, Prentice, A et al. (1999) Epidemiological study of hip fracture in Shenyang, People's Republic of China. Bone 24, 151155.CrossRefGoogle ScholarPubMed
5. Silverman, SL & Madison, RE (1988) Decreased incidence of hip fracture in Hispanics, Asians, and blacks: California Hospital Discharge Data. Am J Public Health 78, 14821483.Google Scholar
6. Barrett, JA, Baron, JA, Karagas, MR et al. (1999) Fracture risk in the U.S. Medicare population. J Clin Epidemiol 52, 243249.Google Scholar
7. Kellie, SE & Brody, JA (1990) Sex-specific and race-specific hip fracture rates. Am J Public Health 80, 326328.CrossRefGoogle ScholarPubMed
8. Lauderdale, DS, Jacobsen, SJ, Furner, SE et al. (1997) Hip fracture incidence among elderly Asian-American populations. Am J Epidemiol 146, 502509.CrossRefGoogle ScholarPubMed
9. Favus, M & Goltzman, D. (2008) Regulation of calcium and magnesium. In Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 7th ed., pp. 104108 [Rosen, C, editor]. Washington: American Society for Bone and Mineral Research.Google Scholar
10. Lambers, TT, Bindels, RJ & Hoenderop, JG (2006) Coordinated control of renal Ca2+ handling. Kidney Int 69, 650654.CrossRefGoogle ScholarPubMed
11. White, K & Econs, M. (2008) Fibroblast-growth-factor-23. In Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism, 7th ed., pp. 112116 [Rosen, C, editor]. Washington: American Society for Bone and Mineral Research.Google Scholar
12. Riminucci, M, Collins, M, Fedarko, N et al. (2003) FGF-23 in fibrous dysplasia of bone and its relationship to renal phosphate wasting. J Clin Invest 112, 683692.CrossRefGoogle ScholarPubMed
13. Lewiecki, EM & Miller, PD (2013) Skeletal effects of primary hyperparathyroidism: bone mineral density and fracture risk. J Clin Densitom 16, 2832.Google Scholar
14. Poole, KE & Reeve, J (2005) Parathyroid hormone – a bone anabolic and catabolic agent. Curr Opin Pharmacol 5, 612617.CrossRefGoogle ScholarPubMed
15. Department of Health and Human Services (2004) Bone Health and Osteoporosis. Rockville: US Department of Health and Human Services, Office of the Surgeon General.Google Scholar
16. Frolik, CA, Black, EC, Cain, RL et al. (2003) Anabolic and catabolic bone effects of human parathyroid hormone (1–34) are predicted by duration of hormone exposure. Bone 33, 372379.Google Scholar
17. Cosman, F, Morgan, DC, Nieves, JW et al. (1997) Resistance to bone resorbing effects of PTH in black women. J Bone Miner Res 12, 958966.Google Scholar
18. Koizumi, M, Komaba, H & Fukagawa, M (2013) Parathyroid function in chronic kidney disease: role of FGF23-Klotho axis. Contrib Nephrol 180, 110123.CrossRefGoogle ScholarPubMed
19. Kamycheva, E, Sundsfjord, J & Jorde, R (2004) Serum parathyroid hormone level is associated with body mass index. The 5th Tromso study. Eur J Endocrinol 151, 167172.Google Scholar
20. Schoenmakers, I, Goldberg, GR & Prentice, A (2008) Abundant sunshine and vitamin D deficiency. Br J Nutr 99, 11711173.Google Scholar
21. Prentice, A (2008) Vitamin D deficiency: a global perspective. Nutr Rev 66, S153S164.Google Scholar
22. Refinetti, R (2006) Circadian Physiology, 2nd ed. Florida: CRC Press Taylor and Francis Group.Google Scholar
23. Greenspan, SL, Dresner-Pollak, R, Parker, RA et al. (1997) Diurnal variation of bone mineral turnover in elderly men and women. Calcif Tissue Int 60, 419423.Google Scholar
24. Rejnmark, L, Lauridsen, AL, Vestergaard, P et al. (2002) Diurnal rhythm of plasma 1,25-dihydroxyvitamin-D and vitamin-D-binding protein in postmenopausal women: relationship to plasma parathyroid hormone and calcium and phosphate metabolism. Eur J Endocrinol 146, 635642.CrossRefGoogle ScholarPubMed
25. Ahmad, AM, Hopkins, MT, Fraser, WD et al. (2003) Parathyroid hormone secretory pattern, circulating activity, and effect on bone turnover in adult growth hormone deficiency. Bone 32, 170179.Google Scholar
26. el-Hajj Fuleihan, G, Klerman, EB, Brown, EN et al. (1997) The parathyroid hormone circadian rhythm is truly endogenous – a general clinical research center study. J Clin Endocrinol Metab 82, 281286.Google Scholar
27. Calvo, MS, Eastell, R, Offord, KP et al. (1991) Circadian variation in ionized calcium and intact parathyroid hormone: evidence for sex differences in calcium homeostasis. J Clin Endocrinol Metab 72, 6976.Google Scholar
28. Jubiz, W, Canterbury, JM, Reiss, E et al. (1972) Circadian rhythm in serum parathyroid hormone concentration in human subjects: correlation with serum calcium, phosphate, albumin, and growth hormone levels. J Clin Invest 51, 20402046.Google Scholar
29. Ledger, GA, Burritt, MF, Kao, PC et al. (1995) Role of parathyroid hormone in mediating nocturnal and age-related increases in bone resorption. J Clin Endocrinol Metab 80, 33043310.Google Scholar
30. Fraser, WD, Logue, FC, Christie, JP et al. (1998) Alteration of the circadian rhythm of intact parathyroid hormone and serum phosphate in women with established postmenopausal osteoporosis. Osteoporos Int 8, 121126.Google Scholar
31. Eastell, R, Calvo, MS, Burritt, MF et al. (1992) Abnormalities in circadian patterns of bone resorption and renal calcium conservation in type I osteoporosis. J Clin Endocrinol Metab 74, 487494.Google Scholar
32. Fraser, WD, Ahmad, AM & Vora, JP (2004) The physiology of the circadian rhythm of parathyroid hormone and its potential as a treatment for osteoporosis. Curr Opin Nephrol Hypertens 13, 437444.Google Scholar
33. Joseph, F, Ahmad, AM, Ul-Haq, M et al. (2008) Effects of growth hormone administration on bone mineral metabolism, PTH sensitivity and PTH secretory rhythm in postmenopausal women with established osteoporosis. J Bone Miner Res 23, 721729.CrossRefGoogle Scholar
34. Carpenter, TO, Insogna, KL, Zhang, JH et al. (2010) Circulating levels of soluble Klotho and FGF23 in X-Linked hypophosphatemia: circadian variance, effects of treatment, and relationship to parathyroid status. J Clin Endocrinol Metab 95, 352357.Google Scholar
35. Clowes, JA, Hannon, RA, Yap, TS et al. (2002) Effect of feeding on bone turnover markers and its impact on biological variability of measurements. Bone 30, 886890.CrossRefGoogle Scholar
36. Schlemmer, A, Hassager, C, Pedersen, BJ et al. (1994) Posture, age, menopause, and osteopenia do not influence the circadian variation in the urinary excretion of pyridinium crosslinks. J Bone Miner Res 9, 18831888.Google Scholar
37. Wichers, M, Schmidt, E, Bidlingmaier, F et al. (1999) Diurnal rhythm of CrossLaps in human serum. Clin Chem 45, 18581860.Google Scholar
38. Gundberg, CM, Markowitz, ME, Mizruchi, M et al. (1985) Osteocalcin in human serum: a circadian rhythm. J Clin Endocrinol Metab 60, 736739.Google Scholar
39. Schlemmer, A & Hassager, C (1999) Acute fasting diminishes the circadian rhythm of biochemical markers of bone resorption. Eur J Endocrinol 140, 332337.Google Scholar
40. Walsh, JS & Henriksen, DB (2010) Feeding and bone. Arch Biochem Biophys 503, 1119.Google Scholar
41. Blumsohn, A, Herrington, K, Hannon, RA et al. (1994) The effect of calcium supplementation on the circadian rhythm of bone resorption. J Clin Endocrinol Metab 79, 730735.Google ScholarPubMed
42. Scopacasa, F, Need, AG, Horowitz, M et al. (2012) Effects of dose and timing of calcium supplementation on bone resorption in early menopausal women. Horm Metab Res 34, 4447.Google Scholar
43. Aerssens, J, Declerck, K, Maeyaert, B et al. (1999) The effect of modifying dietary calcium intake pattern on the circadian rhythm of bone resorption. Calcif Tissue Int 65, 3440.CrossRefGoogle ScholarPubMed
44. Bell, NH, Williamson, BT, Hollis, BW et al. (2001) Effects of race on diurnal patterns of renal conservation of calcium and bone resorption in premenopausal women. Osteoporos Int 12, 4348.Google Scholar
45. Prentice, A (2007) Mining the depths: metabolic insights into mineral nutrition. Proc Nutr Soc 66, 512521.CrossRefGoogle ScholarPubMed
46. Prentice, A, Laskey, MA, Shaw, J et al. (1993) The calcium and phosphorus intakes of rural Gambian women during pregnancy and lactation. Br J Nutr 69, 885896.Google Scholar
47. Yan, L, Schoenmakers, I, Zhou, B et al. (2009) Ethnic differences in parathyroid hormone secretion and mineral metabolism in response to oral phosphate administration. Bone 45, 238245.CrossRefGoogle ScholarPubMed
48. Hu, J, Zhao, XH, Jia, JB et al. (1993) Dietary calcium and bone density among middle-aged and elderly women in China. Am J Clin Nutr 58, 217227.Google Scholar
49. Yano, K, Heilbrun, LK, Wasnich, RD et al. (1985) The relationship between diet and bone mineral content of multiple skeletal sites in elderly Japanese-American men and women living in Hawaii. Am J Clin Nutr 42, 877888.Google Scholar
50. Cheserek, M, Waudo, JN, Tuitoek, PJ et al. (2012) Nutritional vulnerability of older persons living in urban areas of Lake Victoria Basin in East Africa. J Nutr Gerontol Geriatr 31, 8696.Google Scholar
51. Zhang, J, Wang, H-J, Wang, Z-H et al. (2012) Trend in dietary calcium intake among Chinese elderly in nine provinces, from 1991 to 2009. Zhonghua Liu Xing Bing Xue Za Zhi (Chin J Epidemiol) 33, 11191122.Google ScholarPubMed
52. Department of Health. (1998) Nutrition and Bone Health with Particular Reference to Calcium and Vitamin D: Report of the Subgroup on Bone Health of the Committee on Medical Aspects of Food and Nutrition Policy. London: The Stationary Office.Google Scholar
53. Alaimo, K, McDowell, MA, Briefel, RR et al. (1994) Dietary intake of vitamins, minerals, and fiber of persons ages 2 months and over in the United States: Third National Health and Nutrition Examination Survey, 1988–91. Adv Data 258, 128.Google Scholar
54. Angbratt, M, Timpka, T, Blomberg, C et al. (2007) Prevalence and correlates of insufficient calcium intake in a Swedish population. Public Health Nurs 24, 511517.Google Scholar
55. Knochel, J (2006) Phosphorus. In Modern Nutrition in Health and Disease, 10th ed., [Shils, M, editor]. Baltimore: Lippincott Williams and Wilkins.Google Scholar
56. Spencer, H, Kramer, L, Osis, D et al. (1978) Effect of phosphorus on the absorption of calcium and on the calcium balance in man. J Nutr 108, 447457.Google Scholar
57. Nelson, M, Erens, B, Bates, B et al. (2007) Low Income Diet and Nutrition Survey: Summary of Key Findings. London: The Stationery Office.Google Scholar
58. Tam, C, Hislop, G, Hanley, AJ et al. (2011) Food, beverage, and macronutrient intakes in postmenopausal Caucasian and Chinese-Canadian women. Nutr Cancer 63, 687698.Google Scholar
59. Aloia, JF, Mikhail, M, Pagan, CD et al. (1998) Biochemical and hormonal variables in black and white women matched for age and weight. J Lab Clin Med 132, 383389.Google Scholar
60. Fulgoni, Vr, Nicholls, J, Reed, A et al. (2007) Dairy consumption and related nutrient intake in African-American adults and children in the United States: continuing survey of food intakes by individuals 1994–1996, 1998, and the National Health And Nutrition Examination Survey 1999–2000. J Am Diet Assoc 107, 256264.Google Scholar
61. Abrams, S, O'Brien, KO, Liang, LK et al. (1995) Differences in calcium absorption and kinetics between black and white girls aged 5–16 years. J Bone Miner Res 10, 829833.CrossRefGoogle ScholarPubMed
62. Braun, M, Palacios, C, Wigertz, K et al. (2007) Racial differences in skeletal calcium retention in adolescent girls with varied controlled calcium intakes. Am J Clin Nutr 85, 16571663.Google Scholar
63. Bell, NH, Yergey, AL, Vieira, NE et al. (1993) Demonstration of a difference in urinary calcium, not calcium absorption, in black and white adolescents. J Bone Miner Res 8, 11111115.Google Scholar
64. Clemens, TL, Adams, JS, Henderson, SL et al. (1982) Increased skin pigment reduces the capacity of skin to synthesise vitamin D3. Lancet 1, 7476.Google Scholar
65. Brazerol, W, McPhee, AJ, Mimouni, F et al. (1988) Serial ultraviolet B exposure and serum 25 hydroxyvitamin D response in young adult American blacks and whites: no racial differences. J Am Coll Nutr 7, 111118.Google Scholar
66. Dawson-Hughes, B (2004) Racial/ethnic considerations in making recommendations for vitamin-D for adult and elderly men and women. Am J Clin Nutr 80, 1763S1766S.Google Scholar
67. Gutierrez, O, Farwell, WR, Kermah, D et al. (2011) Racial differences in the relationship between vitamin D, bone mineral density, and parathyroid hormone in the National Health and Nutrition Examination Survey. Osteoporos Int 22, 17451753.Google Scholar
68. Arunabh, S, Pollack, S, Yeh, J et al. (2003) Body fat content and 25-hydroxyvitamin-D levels in healthy women. J Clin Endocrinol Metab 88, 157161.CrossRefGoogle ScholarPubMed
69. Coney, P, Demers, LM, Dodson, WC et al. (2012) Determination of vitamin-D in relation to body mass index and race in a defined population of black and white women. Int J Gynaecol Obstet 119, 2125.Google Scholar
70. Signorello, LB, Shi, J, Cai, Q et al. (2011) Common variation in vitamin-D pathway genes predicts circulating 25-hydroxyvitamin-D Levels among African-Americans. PLoS ONE 6, e28623.Google Scholar
71. Finkelstein, JS, Sowers, M, Greendale, GA et al. (2002) Ethnic variation in bone turnover in pre- and early perimenopausal women: effects of anthropometric and lifestyle factors. J Clin Endocrinol Metab 87, 30513056.Google Scholar
72. Bell, NH, Greene, A, Epstein, S et al. (1985) Evidence for alteration of the vitamin D-endocrine system in blacks. J Clin Invest 76, 470473.Google Scholar
73. Bell, NH (1997) Bone and mineral metabolism in African Americans. Trends Endocrinol Metab 8, 240245.CrossRefGoogle ScholarPubMed
74. Kleerekoper, M, Nelson, DA, Peterson, EL et al. (1994) Reference data for bone mass, calciotropic hormones, and biochemical markers of bone remodeling in older (55–75) postmenopausal white and black women. J Bone Miner Res 9, 17451749.Google Scholar
75. Weinstein, RS & Bell, NH (1988) Diminished rates of bone formation in normal black adults. N Engl J Med 319, 16981701.CrossRefGoogle ScholarPubMed
76. Gutierrez, O, Isakova, T, Smith, K et al. (2010) Racial differences in postprandial mineral ion handling in health and in chronic kidney disease. Nephrol Dial Transplant 25, 39703977.CrossRefGoogle ScholarPubMed
77. Taylor, EF & Curhan, GC (2007) Differences in 24-hour urine composition between black and white women. J Am Soc Nephrol 18, 654659.Google Scholar
78. Dawson-Hughes, B, Harris, SS, Finneran, S et al. (1995) Calcium absorption responses to calcitriol in black and white premenopausal women. J Clin Endocrinol Metab 80, 30683072.Google Scholar
79. Jarjou, L, Prentice, A, Sawo, Y et al. (2006) Randomized, placebo-controlled, calcium supplementation study in pregnant Gambian women: effects on breast-milk calcium concentrations and infant birth weight, growth, and bone mineral accretion in the first year of life. Am J Clin Nutr 83, 657666.Google Scholar
80. Schoenmakers, I, Ginty, F, Jarjou, LMA et al. (2010) Interrelation of parathyroid hormone and vitamin D metabolites in adolescents from the UK and The Gambia. J Steroid Biochem Mol Biol 121, 217220.Google Scholar
81. Jarjou, LM, Laskey, MA, Sawo, Y et al. (2010) Effect of calcium supplementation in pregnancy on maternal bone outcomes in women with a low calcium intake. Am J Clin Nutr 92, 450457.Google Scholar
82. Aspray, TJ, Yan, L & Prentice, A (2005) Parathyroid hormone and rates of bone formation are raised in perimenopausal rural Gambian women. Bone 36, 710720.Google Scholar
83. Schoenmakers, I, Jarjou, LMA, Goldberg, GR et al. (2013) Acute response to oral calcium loading in pregnant and lactating women with a low calcium intake: a pilot study. Osteoporos Int 24, 23012308.Google Scholar
84. Bates, B, Lennox, A, Prentice, A et al. National Diet and Nutrition Survey Headline results from Years 1, 2 and 3 (combined) of the Rolling Programme (2008/2009 – 2010/11). [Online: 03/08/2013]; available at http://transparency.dh.gov.uk/2012/07/25/ndns-3-years-report/ Google Scholar
85. Prentice, A, Shaw, J, Laskey, MA et al. (1991) Bone mineral content of British and rural Gambian women aged 18–80+ years. Bone Miner 12, 201214.Google Scholar
86. Schnitzler, CM (1993) Bone quality: a determinant for certain risk factors for bone fragility. Calcif Tissue Int 53, S27S31.Google Scholar
87. Yan, L, Zhou, B, Wang, X et al. (2003) Older people in China and the United Kingdom differ in the relationships among parathyroid hormone, vitamin-D, and bone mineral status. Bone 33, 620627.CrossRefGoogle Scholar
88. National Osteoporosis Guideline Group. (2010) Guideline for the diagnosis and management of osteoporosis.Google Scholar
89. Aspray, TJ, Prentice, A, Cole, TJ et al. (1996) Low bone mineral content is common but osteoporotic fractures are rare in elderly rural Gambian women. J Bone Miner Res 11, 10191025.Google Scholar
90. Redmond, J, Jarjou, LM, Palla, L et al. (2013) Renal conservation of calcium in Gambian compared to British older adults (Oral Presentation). Nutrition Society Summer Meeting; Newcastle, UK, July 2013.Google Scholar
91. Lau, E, Donnan, S, Barker, DJ et al. (1988) Physical activity and calcium intake in fracture of the proximal femur in Hong Kong. Br Med J 297, 14411443.Google Scholar
92. Lau, E, Woo, J, Lam, V et al. (2001) Milk supplementation of the diet of postmenopausal Chinese women on a low calcium intake retards bone loss. J Bone Miner Res 16, 17041709.Google Scholar
93. Kruger, M, Ha, PC, Todd, JM et al. (2012) High-calcium, vitamin-D fortified milk is effective in improving bone turnover markers and vitamin-D status in healthy postmenopausal Chinese women. Eur J Clin Nutr 66, 856861.CrossRefGoogle ScholarPubMed
94. Zhang, W, Stoecklin, E & Eggersdorfer, M (2013) A glimpse of vitamin-D status in Mainland China. Nutrition.CrossRefGoogle ScholarPubMed
95. Jiang, L, Xu, J, Pan, S et al. (2012) High prevalence of hypovitaminosis D among pregnant women in southeast China. Acta Paediatr 101, e192e194.Google Scholar
96. Engelsen, O. Duration of Vitamin D synthesis in human skin. 2005 [cited 2013 01/08/2013]; available at http://zardoz.nilu.no/~olaeng/fastrt/VitD.html Google Scholar
97. Woo, J, Lau, E, Swaminathan, R et al. (1994) Association between calcium regulatory hormones and other factors and bone mineral density in elderly Chinese men and women. J Gerontol 49, 189194.Google Scholar
Figure 0

Fig. 1. Schematic representation of the diurnal rhythm of biological data.

Figure 1

Fig. 2. Diurnal variation in total plasma Ca (albumin-adjusted: bold lines and unadjusted: broken line), phosphate (P) and parathyroid hormone (PTH) (change from 24 h mean, % mean and sem) in healthy post-menopausal women. P-value indicates the significance of the diurnal variation. Reproduced from(25) with permission. Figure 2 was granted permission for reproduction by Copyright Clearance Center's RightsLink service by the European Journal of Endocrinology. License no.: 3213570527941.

Figure 2

Table 1. Factors associated with ethnic differences in Ca, P and bone metabolism within the USA

Figure 3

Fig. 3. The relationship between Ln parathyroid hormone (PTH) and Ln bone mineral content (BMCt) at the femoral trochanter adjusting for bone area, weight, height, age and sex in Shenyang (x) and Cambridge (•) subjects. Reprinted from(88) with permission from Elsevier. Figure 3 was granted permission for reproduction by Copyright Clearance Center's RightsLink service by Elsevier. License no.: 3196500798854.

Figure 4

Fig. 4. Timings of blood and urine collections.