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Vitamin D research and public health nutrition: a current perspective

Published online by Cambridge University Press:  13 July 2017

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Abstract

Type
Editorial
Copyright
Copyright © The Authors 2017 

This 2017 special issue of Public Health Nutrition features nineteen research manuscripts all relevant to the role of vitamin D nutritional status in the risk and prevention of chronic diseases of public health importance. A useful barometer gauging the worldwide growing interest in vitamin D and health research is shown by over 13 000 studies abstracted in PubMed over the last 5 years alone, all with a focus on vitamin D. Vitamin D deficiency in Europe is associated with adverse health outcomes whose direct and indirect medical cost burdens have been estimated in the hundreds of billions of Euros, which underlines the importance of this work to public health( Reference Grant, Garland and Gorhan 1 ). Dedicating a special issue to these recently accepted vitamin D studies provides Public Health Nutrition editors with an opportunity to set in perspective the diverse aspects of the continued growing interest in vitamin D nutritional status, its health importance, and the impact of the many recent innovations in analytical methods, assay standardization programmes and the underlying factors contributing to the controversy over serum cut-off values defining vitamin D nutritional status. Newer standardized analytical methods now enable research exploring the many gaps in our understanding of vitamin D nutritional status which many of these papers address, as well as the association with reduced risk of disease and other beneficial health effects.

The common feature among all the papers in this special vitamin D issue is the measurement of vitamin D status or the circulating concentrations of 25-hydroxyvitamin D (25(OH)D, nmol/l or ng/ml). There is a growing demand to assess vitamin D status in order to screen for deficiency, monitor efficacy of supplementation or fortification, or assess the association between vitamin D status and chronic diseases including osteoporosis, diabetes, cancer, CVD, infection and autoimmune or neurological disorders. To meet this demand, less labour-intense assay methods have been developed along with certified external standards and proposed criteria for defining vitamin D deficiency/sufficiency( Reference Hollis 2 Reference Binkely, Dawson-Hughes and Durazo-Arvizu 5 ).

The goal of this perspective is to inform researchers about the currently accepted assay methods and quality control procedures used to determine 25(OH)D concentrations and the most widely accepted criteria for establishing vitamin D status. We present some background information describing relevant new evidence in four areas defining important public health gaps in knowledge that are addressed by many of the studies in this issue. Our intent is to provide insight into how these studies contribute to these gaps in our understanding of vitamin D status and, more importantly, how the study findings may impact public health nutrition policy and practices.

Gaps in vitamin D understanding relevant to public health

The four areas addressing critical gaps in our knowledge of vitamin D status and health that were tackled by the studies in this special issue include: (i) global vitamin D deficiency and association with health risk; (ii) impact of or need for national vitamin D food fortification; (iii) vitamin D supplement use in vulnerable populations; and (iv) season and sunlight influence year-round. Among these areas, global vitamin D deficiency and association with health risk was the most repeated manuscript focus and is clearly the most controversial. Recent evidence supports global vitamin D deficiency( Reference Hilger, Friedel and Herr 6 , Reference Cashman, Dowling and Skrabakova 7 ) and numerous systematic reviews and meta-analyses examining multiple health outcomes and mortality risk( Reference Autier, Boniol and Pizot 8 Reference Gaksch, Jorde and Grimnes 11 ) show association with vitamin D deficiency, notably when individual participant data are used in the meta-analyses( Reference Gaksch, Jorde and Grimnes 11 ). However, these findings are largely based on data from European and higher-income countries, underscoring the need for and importance of diverse geographic studies such as the ones presented in this issue.

Evidence of global vitamin D deficiency and its association with adverse health speaks to the need for national food fortification programmes, both in Europe and lower- and middle-income countries( Reference Itkonen and Lamberg-Allardt 12 , Reference Jääskeläinen, Itkonen and Lundqvist 13 ). Fortification of food is the most effective population-based approach to correcting poor vitamin D status( Reference Jääskeläinen, Itkonen and Lundqvist 13 ), while supplementation of specific groups at high risk within a population is a targeted intervention to rapidly correct serious deficiencies. Even in countries with year-round abundant sunshine for endogenous skin synthesis of vitamin D, recent findings show there is a need for national food fortification programmes in order to reach the entire population, again stressing the necessity for worldwide studies( Reference Babu and Calvo 14 ). Vitamin D supplement use faces many barriers as a population strategy to prevent vitamin D deficiency and adverse health outcomes( Reference Whiting, Vatanparast and Taylor 15 ), although supplementation may prove effective in small groups or individuals at risk( Reference Lhamo, Chugh and Tripathi 16 , Reference Viljakainen, Vaisanen and Kemi 17 ). Nevertheless, caution is warranted for individuals who self-medicate out of necessity in countries where sun is avoided, food is not fortified and vitamin D supplements are not well regulated, such as India( Reference Lhamo, Chugh and Tripathi 16 ). More geographically diverse studies are needed exploring the efficacy of vitamin D supplement use in vulnerable populations, especially during pregnancy and early infancy. Vitamin D supplement use has been shown to be effective in populations where sun exposure is limited during the winter( Reference Viljakainen, Vaisanen and Kemi 17 , Reference Pittaway, Ahuja and Becket 18 ). Seasonal changes and sunlight availability alone are unable to explain seasonal differences in countries’ population vitamin D status when their populations experience the same limited sunlight. This finding points to the need to assess other contributing sources such as diet and other confounding lifestyle factors when developing strategies to prevent vitamin D deficiency( Reference O’Neill, Kazantzidis and Ryan 19 ).

Knowledge of the effective sunlight (UVB) availability during each season has recently been used to develop an integrated predictive model of serum 25(OH)D concentrations that can be applied to fortification and supplementation strategies to prevent seasonal vitamin D deficiency( Reference Cashman, Kazantzidid and Webb 20 ). Such models were used to show similar UVB availability in northern European countries, each of which showed similar decreases with latitude and seasonal changes, but different magnitudes of seasonal fluctuations in serum 25(OH)D were observed, ostensibly due to differences in the vitamin D content of the diet( Reference O’Neill, Kazantzidis and Ryan 19 ). Yet again, these findings are based on European data, leaving a gaping hole in our understanding of the interaction between season, environment, cultural lifestyle, dietary sources and vitamin D status in other countries.

Need for global consensus on the definitions of vitamin D nutritional status

To better understand the global importance of vitamin D deficiency to public health, a consensus must be reached on the definition of what serum concentration of 25(OH)D to use to define a deficient state. Concentrations ranging from <25 to <75 nmol/l (<10 to <30 ng/ml) have been proposed as cut-off measures for deficiency using unstandardized assays reporting great variability in outcomes( Reference Sempos, Vespers and Phinney 21 ). Race, gender, age, lifestyle, physiological state and disease can impact serum 25(OH)D concentrations in individuals and populations, thus complicating efforts to reach global consensus on what serum 25(OH)D concentration constitutes a vitamin D-deficient state( 22 , Reference Holick, Binkley and Bischoff-Ferrari 23 ).

There is, however, general agreement in defining the characteristics of a vitamin D-deficient state as it relates to skeletal health that researchers may use to enable global comparisons( Reference Cashman, Dowling and Skrabakova 7 ). Established by the Institute of Medicine( 22 ) and shown in Table 1, deficiency represents concentrations not sufficient to provide protection against rickets and osteomalacia (adverse bone events; <30 nmol/l or <12 ng/ml); while sufficiency represents concentrations not at risk for adverse bone events (>50 nmol/l or >20 ng/ml)( 22 ). The Institute of Medicine report did not define optimal vitamin D status; nevertheless, other scientific experts define serum concentrations exceeding 75 nmol/l (30 ng/ml) as optimal, especially for those individuals at greater risk due to disease, race or other factors( 22 , Reference Holick, Binkley and Bischoff-Ferrari 23 ). There is growing but inconsistent evidence of associations between chronic disease conditions other than skeletal with serum concentrations below this range( Reference Newberry, Chung and Shekelle 24 ). More convincing evidence is warranted with respect to cancer risks for which lower risks have recently been reported with higher serum concentrations of 25(OH)D( Reference McDonnell, Baggerly and French 10 ); while concentrations below 75 nmol/l (30 ng/ml) determined with standardized assays have been associated with increased risk of all-cause mortality( Reference Gaksch, Jorde and Grimnes 11 ). Serum concentrations between 125 and 150 nmol/l (50 and 60 ng/ml) are defined as being safe and were used to define the Tolerable Upper Intake Level (UL), based on the belief that the risk for adverse health effects rises with vitamin D intakes above the UL( 22 , 25 ). Vitamin D toxicity is defined as serum concentrations above 250 nmol/l (100 ng/ml) and the physiological state of vitamin D toxicity is characterized by a number of serious adverse health conditions including severe hypercalcaemia( 26 ).

Table 1 Definition of vitamin D status by 25-hydroxyvitamin D (25(OH)D) concentration relevant to healthy populations

IOM, Institute of Medicine; EFSA, European Food Safety Authority.

The key to developing appropriate dietary guidelines for the prevention of vitamin D deficiency lies in the standardization of the assays used to measure 25(OH)D and the evaluation of the assay results against cut-off values for serum concentrations that correspond to well-defined vitamin D-deficient states or conditions, which may not always be specific for bone. The importance of standardizing 25(OH)D assays cannot be emphasized enough to future investigators exploring the optimal concentrations associated with reduced risk of chronic and infectious disease( Reference Sempos, Durazo-Arvizu and Binkley 27 ).

Assay variability in the clinical determination of vitamin D status and the need for standardization of analytical methods and reference materials

The common feature among all the papers in this special issue focusing on vitamin D is the measurement of vitamin D status, which is defined by the serum concentration of the intermediary metabolite of vitamin D (25(OH)D, nmol/l or ng/ml). There are numerous methods for the measurement of 25(OH)D in serum( Reference De La Hunty, Wallace and Gibson 28 Reference Carter 31 ) including high-performance liquid chromatography with UV detection (HPLC/UV), liquid chromatography–tandem mass spectrometry (LC-MS/MS) and immunoassays (radioimmunoassays (RIA), competitive protein-binding assays (CPBA), enzyme-linked immunosorbent assays (ELISA), chemiluminiscence assays (CLIA)) that are either manual or automated. LC-MS/MS (as well as HPLC) is considered the gold standard method. These two methods have the advantage that they can measure 25-hydroxycholecalciferol (25(OH)D3) and 25-hydroxyergocalciferol (25(OH)D2) separately, which is needed in specific situations. They also allow detection of other vitamin D metabolites, such as 24,25-dihydroxyvitamin D (24,25(OH)2D)( Reference Wallace, Gibson and de la Hunty 29 , 30 ).

Formerly, all methods suffered from the lack of an international common standard; this lack contributed to the variability of results of serum 25(OH)D measurements. The Vitamin D External Quality Assessment Scheme (DEQAS)( 30 ) has revealed considerable differences among these methods (both within and between laboratories), raising concerns about the comparability and accuracy of different assays and laboratories( Reference Snellman, Melhus and Gedebourg 32 Reference Heijboer, Blankenstein and Kema 35 ). LC-MS/MS analyses have shown that immunoassays display substantial interference of 24,25(OH)2D, especially at higher 25(OH)D concentrations, giving erroneously high 25(OH)D concentrations( Reference Cashman, Hayes and Galvin 36 ). Moreover, the 3-epi-25(OH)D metabolite, which is important in paediatric studies since the metabolite is highest during pregnancy and in infants and children, may interfere in some immunoassays( Reference Baily, Perumal and Yazdanpanah 37 ).

The introduction of a standard reference material for vitamin D in human serum by the US National Institute of Standards and Technology (NIST)( 38 ) has been a step forward in providing a reference measurement procedure (RMP) against which assays could be standardized( Reference Cashman, Kiely and Kinsella 39 ). The Vitamin D Standardization Program (VDSP) has developed protocols for standardizing procedures of 25(OH)D measurement in national health/nutrition surveys to promote 25(OH)D measurements that are accurate and comparable over time, location and laboratory, to improve public health practice( Reference Cashman, Kiely and Kinsella 39 ). The VDSP RMP has been joined by a number of commercial methods and laboratories that use other methods, such as DiaSorin, Liaison and Cobas, and thus their results should be comparable to LC-MS/MS with regard to 25(OH)D concentrations when the VDSP is used. In the VDSP, LC-MS/MS is the reference method. According to a reanalysis of serum 25(OH)D concentrations using the VDSP protocol, the range of mean concentrations in fourteen European studies in children and adult populations (including one study in migrants in Finland) was 38·3–65·0 nmol/l (v. 44·8–69·0 nmol/l in the originally analysed serum 25(OH)D data)( Reference Cashman, Dowling and Skrabakova 7 ).

Examining gaps in knowledge important to public health nutrition policy and application

The nineteen vitamin D research papers featured in this issue explore a number of important research gaps that are vital to our understanding of the need for food fortification or supplementation programmes in less studied low- and middle-income countries and high-risk populations in higher-income countries( Reference Saki, Dabbaghmanesh and Omrani 40 Reference Holland and Moffat 58 ). The majority of these studies examined aspects of global vitamin D deficiency and association with health risks( Reference Saki, Dabbaghmanesh and Omrani 40 , Reference Yun, Chen and He 42 , Reference Perumal, Mahmud and Baqui 43 , Reference Ahmed, Ahmed and Long 45 Reference Heath, Williamson and Kvaskoff 48 , Reference Moy, Hoe and Hairi 50 Reference Vogt, Baumert and Peter 53 , Reference Flores, Flores and Macias 56 Reference Holland and Moffat 58 ). Two explored the impact or need for a national vitamin D food fortification programme due to seasonal challenges or deviation from traditional diets( Reference Sandmann, Amling and Barvencik 44 , Reference O’Brien, Thummel and Bulkow 54 ), while one explored the efficacy of vitamin D supplement use in a vulnerable population( Reference McCormack, Mai and Chen 41 ) and two determined the influence of season and sunlight availability year-round on vitamin D status( Reference Naqvi, Solomons and Campos 49 , Reference Sudhanshu, Upadhyay and Sahu 55 ). Several studies used nationally representative data from higher-income countries that included different race/ethnicity groups, allowing assessment of confounding anthropomorphic influences such as waist circumference, BMI, serum lipids and skin pigmentation( Reference Rajan, Weishaar and Keller 46 , Reference Lee, Suh and Park 52 , Reference Vogt, Baumert and Peter 53 ).

These papers bring together valued information on vitamin D status from less studied areas of the world, including Bangladesh( Reference Perumal, Mahmud and Baqui 43 , Reference Ahmed, Ahmed and Long 45 ), China( Reference Yun, Chen and He 42 ), Guatemala( Reference Naqvi, Solomons and Campos 49 ), India( Reference Sudhanshu, Upadhyay and Sahu 55 ), Iran( Reference Saki, Dabbaghmanesh and Omrani 40 ), Malaysia( Reference Moy, Hoe and Hairi 50 ) and Mexico( Reference Flores, Flores and Macias 56 ). Many used state-of-the-art standardized assay methodology, i.e. LC-MS/MS( Reference Perumal, Mahmud and Baqui 43 , Reference Djekic-Ivankovic, Weiler and Jones 47 , Reference Heath, Williamson and Kvaskoff 48 , Reference O’Brien, Thummel and Bulkow 54 ), while others used EIA, RIA, CLIA( Reference Yun, Chen and He 42 , Reference Ahmed, Ahmed and Long 45 , Reference Naqvi, Solomons and Campos 49 Reference Vogt, Baumert and Peter 53 , Reference Sudhanshu, Upadhyay and Sahu 55 Reference Omand, To and O’Connor 57 ) or HPLC( Reference Saki, Dabbaghmanesh and Omrani 40 ) to analyse serum 25(OH)D concentrations, and some reported some standardization( Reference Djekic-Ivankovic, Weiler and Jones 47 , Reference Heath, Williamson and Kvaskoff 48 , Reference Vogt, Baumert and Peter 53 , Reference Flores, Flores and Macias 56 ). These differences emphasize our need to standardize the assays used to clearly understand the global extent of vitamin D deficiency and insufficiency. Such understanding can only be achieved if researchers agree to use the same clearly defined measures of serum 25(OH)D concentrations to indicate vitamin D deficiency, insufficiency and sufficiency, as shown in Table 1. With assay standardization and use of the same threshold values for vitamin D status, we can gain insight into global areas in need of public health nutrition policies enabling vitamin D food fortification and supplementation.

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Figure 0

Table 1 Definition of vitamin D status by 25-hydroxyvitamin D (25(OH)D) concentration relevant to healthy populations