Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-25T06:18:51.908Z Has data issue: false hasContentIssue false

Micronutrient deficiencies and health-related quality of life: the case of children with vitamin D deficiency

Published online by Cambridge University Press:  12 February 2019

Magda Aguiar
Affiliation:
Health Economics Unit, Institute of Applied Health Research, University of Birmingham, Birmingham, UK
Lazaros Andronis*
Affiliation:
Health Economics Unit, Institute of Applied Health Research, University of Birmingham, Birmingham, UK Division of Health Sciences, Warwick Medical School, University of Warwick, Coventry CV4 7AL, UK
Miranda Pallan
Affiliation:
Public Health, Epidemiology and Statistics, Institute of Applied Health Research, University of Birmingham, Birmingham, UK
Wolfgang Högler
Affiliation:
Department of Endocrinology and Diabetes, Birmingham Children’s Hospital, Birmingham, UK Institute of Metabolism and Systems Research, University of Birmingham, Birmingham, UK
Emma Frew
Affiliation:
Health Economics Unit, Institute of Applied Health Research, University of Birmingham, Birmingham, UK
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To explore the extent to which micronutrient deficiencies (MND) affect children’s health-related quality of life (HRQoL), using vitamin D deficiency (VDD) as a case study.

Design

Proxy valuation study to estimate the impact of VDD on the HRQoL of younger (0–4 years) and older (>4 years) children. We used the Child Health Utility 9 Dimension (CHU9D) questionnaire to estimate HRQoL for children within six VDD-related health states: ‘hypocalcaemic cardiomyopathy’, ‘hypocalcaemic seizures’, ‘active rickets’, ‘bone deformities’, ‘pain and muscle weakness’ and ‘subclinical VDD’.

Setting

Sampling was not restricted to any particular setting and worldwide experts were recruited.

Participants

Respondents were paediatric bone experts recruited through network sampling.

Results

Thirty-eight experts completed the survey. The health state with the largest detrimental impact (mean score (se)) on children’s HRQoL was hypocalcaemic cardiomyopathy (0·47 (0·02)), followed by hypocalcaemic seizures (0·50 (0·02)) and active rickets (0·62 (0·02) in young children; 0·57 (0·02) in older children). Asymptomatic VDD had a modest but noticeable negative impact on HRQoL, attributed mostly to tiredness in both age groups and pain in the older paediatric population.

Conclusions

Elicitation of HRQoL from clinical experts suggests a negative impact of VDD on HRQoL, even if there is no recognizable clinical manifestation. HRQoL data from populations of patients with MND will inform public health policy decisions. In some settings, routine collection of HRQoL data alongside national nutrition surveys may help capture the full burden of MND and prioritize resources towards effective prevention.

Type
Research paper
Copyright
© The Authors 2019

Micronutrient deficiencies (MND) are underlying causes of disease, with impact on the quality of life, morbidity and mortality of populations, and threatening health and well-being globally(Reference Tulchinsky1). They are a known cause of specific diseases, such as anaemia in the case of iron deficiency and osteomalacia in the case of vitamin D deficiency (VDD)(Reference Tulchinsky1), but it is the hidden burden of subclinical or undiagnosed pathology that turns MND into a public health challenge, sometimes referred to as a ‘hidden hunger’. Besides the more obvious clinical manifestations, milder MND cause a wide range of non-specific imbalances that are more difficult to recognize and lead to reduced resistance to infection, metabolic disorders and impaired growth and development(Reference Tulchinsky1Reference Branca and Ferrari3). The WHO warns of the potentially huge implications of MND in population health, which are not limited to developing countries(Reference Allen, de Benoist and Dary2). MND in children affect development and school attainment and are a general reflection of a country’s inequalities(Reference Branca and Ferrari3). Difficulties in assessing the real burden of MND might be partly overcome with the use of health-related quality of life (HRQoL) measures, which are able to capture health status beyond the clinical symptoms, as they encompass the physical, emotional and social components of well-being and health.

Vitamin D is fundamental to bone mineralization and growth(Reference Munns, Shaw and Kiely4). Vitamin D status is defined through a blood test that measures the serum concentration of 25-hydroxyvitamin D (25(OH)D). Serum level below 30 nmol/l is considered deficient(Reference D. Washington5). VDD is one of the commonest MND globally, being widespread in child and adult populations(Reference Prentice6). The overall prevalence of VDD in Europe has been estimated as 13 %(Reference Cashman, Dowling and Skrabakova7). In the UK, data from the National Diet and Nutrition Survey show that 10 % of young children (4–10 years) and 26 % of older children (11–18 years) had serum 25(OH)D below 25 nmol/l(Reference Bates, Lennox and Prentice8). Girls were found to be at higher risk than boys, with 13 % of the young girls and 39 % of the older girls presenting with low 25(OH)D (<25 nmol/l). Severe VDD in infants and children manifests as hypocalcaemic seizures(Reference Basatemur and Sutcliffe9Reference Robinson, Högler and Craig11), dilated cardiomyopathy(Reference Elidrissy, Munawarah and Alharbi12Reference Uday, Fratzl-Zelman and Roschger14) and rickets with osteomalacia(Reference Callaghan, Moy and Booth15, Reference Ward, Gaboury and Ladhani16), which in turn leads to bone deformities and muscle weakness(Reference Munns, Shaw and Kiely4, Reference Robinson, Högler and Craig11, Reference Al-Said, Al-Rached and Al-Qahtani17, Reference Ward, Das and Berry18). Mild or short periods of deficiency are often asymptomatic, and it is not known if this impacts on well-being. Symptomatic VDD in the UK, USA and Scandinavian countries occurs almost exclusively in dark-skinned populations from African, Caribbean and South-Asian backgrounds (Fitzgerald skin type IV–VI)(Reference Uday and Högler19). Although symptomatic VDD falls into a rare disease definition (incidence is below 5/100 000)(20), the prevalence of rickets is increasing in high-income countries as population structures are changing(Reference Robinson, Högler and Craig11, Reference Uday and Högler19, Reference Zylke, Rivara and Bauchner2123), with greater proportions of populations from high-risk groups (e.g. dark skin pigmentation, full-body clothing, limited sunlight exposure). The risk is aggravated by high latitude, low availability of vitamin D-rich foods(Reference Munns, Shaw and Kiely4) and diets that are poor in calcium(Reference Leung and Stanner24). The resurgence of rickets is of concern to public health and health-care agencies(23, 25).

Although the clinical outcomes of VDD in children are known, there is a lack of information on the extent to which VDD affects HRQoL(Reference Aguiar, Andronis and Pallan26). In adults, low serum 25(OH)D is associated with reduced HRQoL(Reference Rafiq, Swart and van Schoor27Reference Tolentino-Wilson and Narvacan-Montano29). This lack of HRQoL data in the paediatric population may result from the difficulties of identifying patients, because: symptoms are rare(20); VDD is under-reported in clinical settings(Reference Holick30); and there is seasonal variation in VDD status(25). The absence of HRQoL data limits the availability of cost–utility analyses needed to inform public health policies(Reference Aguiar, Andronis and Pallan26).

The current paper presents a study which aimed to estimate the HRQoL of children with VDD, through administration of a multi-attribute preference-based questionnaire to clinical experts in paediatric VDD (proxies).

The study also aimed to elucidate how VDD impacts the HRQoL of children. This will help to highlight how MND affect population health and well-being, what the obstacles are for routine data collection, and offer some suggestions for how these might be overcome.

Participants and methods

Clinical experts in paediatric bone disease were approached as proxy respondents to value VDD-related health states. Proxy elicitation is an established method of obtaining HRQoL information, particularly when patients cannot state their own preferences, as is the case for infants and young children, or for those suffering from incapacitating conditions. When using proxies, patient representatives such as health-care professionals or informal carers (typically family members and friends) are asked to complete a validated HRQoL questionnaire, either acting as they think the patient would(Reference Sneeuw, Sprangers and Aaronson31) or by providing their own perspective on the patient’s HRQoL(Reference Sneeuw, Sprangers and Aaronson31, Reference Pickard and Knight32).

In the present study, HRQoL estimates for a range of health outcomes linked to VDD were elicited for two age groups: (i) 0–4 years and (ii) >4 years. The use of proxies was necessary for the younger age group as infants and very young children are unable to provide self-reported HRQoL estimates. Proxies were also used for the older age group, as recruitment of a sufficient number of older children with VDD-related diseases/symptoms is challenging due to the rarity of VDD-associated diseases(Reference Basatemur and Sutcliffe9, Reference Robinson, Högler and Craig11, Reference Ladhani, Srinivasan and Buchanan33) and the under-reporting of VDD-related symptoms(Reference Alghadir, Gabr and Al-Eisa34).

Participants

Experts were recruited from three professional groups: the Rickets Global Consensus Group(Reference Munns, Shaw and Kiely4); the Bone and Growth Plate Working Group of the European Society of Paediatric Endocrinology(35); and the British Paediatric and Adolescent Bone Group(36). The questionnaire was initially sent to 133 experts. Further recruitment of participants was done through a snowball sampling method whereby the initial group of experts contacted were asked to forward the survey link to any other colleague whom they considered to have the relevant expertise. A further ten experts were contacted in this way.

Health state development

The health state development was divided into two phases: phase 1 involved a literature review to identify the relevant health states in children with VDD; and phase 2 was an expert consultation using an iterative approach to refine the health state descriptions. The literature review that informed phase 1 has been described elsewhere and formed part of the global rickets consensus statement(Reference Munns, Shaw and Kiely4). Criteria for health state selection were based on prevalence and severity. Five health states were initially described: (i) hypocalcaemic cardiomyopathy(Reference Elidrissy, Munawarah and Alharbi12Reference Uday, Fratzl-Zelman and Roschger14); (ii) hypocalcaemic seizures(Reference Basatemur and Sutcliffe9Reference Robinson, Högler and Craig11); (iii) active rickets with skeletal deformities(Reference Callaghan, Moy and Booth15, Reference Ward, Gaboury and Ladhani16, Reference Asch, Connor and Hamilton37); (iv) pain and muscle weakness(Reference Robinson, Högler and Craig11, Reference Al-Said, Al-Rached and Al-Qahtani17, Reference Ward, Das and Berry18); and (v) asymptomatic VDD. Based on the literature, the five health states were then divided by age group, using serum 25(OH)D below 30 nmol/l as the accepted definition of VDD(Reference Munns, Shaw and Kiely4, Reference D. Washington5). All five were described for infants and young children up to 4 years old, but only active rickets, skeletal deformities, pain and muscle weakness, and asymptomatic VDD were used for older children (aged 5–18 years). This was because VDD-related hypocalcaemic cardiomyopathy occurs almost always in infants(Reference Elidrissy, Munawarah and Alharbi12Reference Uday, Fratzl-Zelman and Roschger14, Reference Högler38) and hypocalcaemic seizures are rare in children over 5 years of age(Reference Basatemur and Sutcliffe9, Reference Högler38). In phase 2, the health state description was presented to two paediatric bone experts. Through an iterative process involving three rounds of consultation, the health state descriptions were adjusted to align with the preferred wording of clinical experts. This consultation led to the inclusion of a sixth health state in which children continue to suffer from residual leg deformities after having been treated for rickets(Reference Robinson, Högler and Craig11, Reference Callaghan, Moy and Booth15, Reference Thacher, Fischer and Pettifor39) and require long-term vitamin D supplementation. Although this health state was not identified in phase 1, the experts attributed significant clinical relevance to it, and it was therefore included in the final set of health states (Box 1).

Box 1 Final health state description

Health state valuation

Valuation of the health states was undertaken using a proxy version of the Children’s Health Utility 9 Dimension (CHU9D) instrument, a multi-attribute preference-based questionnaire. Multi-attribute preference-based questionnaires are health state classification systems that allow the indirect estimation of health state utility values, based on the public’s preferences for a given health state. Utilities quantify HRQoL through preference scores on a generic scale anchored between 0 (‘dead’) and 1 (‘perfect health’), where values below 0 represent health states that are deemed worse than dead(Reference Chao, Ekwaru and Ohinmaa28, Reference Tolentino-Wilson and Narvacan-Montano29).

The CHU9D questionnaire has been validated in the 5–18 years age group(Reference Stevens40Reference Ratcliffe, Stevens and Flynn44). A separate version of the questionnaire is available for children under 5 years(45). The CHU9D is a questionnaire with nine dimensions: worried, sad, pain, tired, annoyed, school work/homework, sleep, daily routine and activities. Each dimension has five levels (e.g. ‘Last night the child had no problems, few problems, some problems, many problems sleeping’ or ‘Last night the child couldn’t sleep at all’)(Reference Stevens46). For infants and young children, to whom dimensions such as school work and ‘feeling annoyed’ do not apply, a specific version was used which provides a short explanation of how questions should be interpreted. For example, respondents were asked to replace school work by learning activities that would apply to the younger age groups. The clinical experts were asked to value each VDD health state using the CHU9D dimensions, which enabled a utility value to be applied to each health state, using a pre-existing value set developed for the CHU9D(Reference Stevens46).

Structure of the survey

The online survey was divided into three separate sections: (i) infants and younger children (0–4 years); (ii) older children (5–18 years); and (iii) general questions regarding the respondent’s professional practice.

All respondents were asked to assess all health states using two different methods, for both age groups. First, the respondents were asked to rank the health states according to their severity, or detrimental impact upon HRQoL, with 1 corresponding to the least severe health state. Second, the respondents were asked to complete the CHU9D questionnaire considering a hypothetical patient who visited their clinic on that day. Respondents were asked to answer, based on their clinical experience, how they thought the patient would feel/perform in that given health state. The final section of the survey asked respondents about their area of expertise, their country of practice and how many cases of rickets they had seen in the last two years.

Analyses

The responses to the CHU9D questionnaire were converted into utility values by applying an established algorithm(Reference Stevens46) using the statistical software package Stata version 13. HRQoL estimates are presented as mean utility values, with the corresponding se and 95 % CI.

Results

Of the 143 experts contacted, thirty-eight (26·6 %) completed and returned the questionnaire. Table 1 presents the respondents’ areas of expertise and countries of practice. Experts from eighteen different countries responded, the majority of whom were based in the UK (23·7 %) and France (13·2 %), and 34 % in non-European countries. Most experts were either paediatric endocrinologists (39·5 %) or paediatricians with a special interest in endocrinology or bone disease (31·6 %). Most respondents (n 35, 92·1 %) had treated at least one case of rickets in the last two years. The total number of cases seen per expert ranged from 1 to 30.

Table 1 Area of expertise and country of practice of the paediatric bone experts (n 38) participating in the present study

Ranking scores

In the infants and young children group (0–4 years), hypocalcaemic cardiomyopathy was ranked as the most severe health state followed by hypocalcaemic seizures, active rickets, leg deformities, pain and muscle weakness, and the asymptomatic health state (Fig. 1).

Fig. 1 Results from the ranking exercise for young children (0–4 years) carried out by paediatric bone experts (n 38) to explore the extent to which vitamin D deficiency affects children’s health-related quality of life. 0 corresponds to the least severe condition and 6 to the most severe

For older children (5–18 years), active rickets was considered to be the most severe health state, followed by leg deformities, pain and muscle weakness, and asymptomatic VDD (Fig. 2). One respondent ranked asymptomatic VDD as the most severe. This respondent’s data have been included in Fig. 2 for completeness, but in this instance, it is assumed the question was misunderstood.

Fig. 2 Results from the ranking exercise for older children (>4 years) carried out by paediatric bone experts (n 38) to explore the extent to which vitamin D deficiency affects children’s health-related quality of life. 0 corresponds to the least severe condition and 4 to the most severe

Utility scores

The CHU9D summary results are presented in Table 2. All health states resulted in some disutility, with hypocalcaemic cardiomyopathy (0·465; 95 % CI 0·425, 0·505) and hypocalcaemic seizures (0·495; 95 % CI 0·458, 0·532) resulting in the lowest utility scores. Health states that were assessed in both age groups (active rickets, leg deformities, pain and muscle weakness, asymptomatic VDD) had similar utility scores.

Table 2 Health state utility values for young children and older children with low serum 25-hydroxyvitamin D concentration from the valuation, carried out by paediatric bone experts (n 38) using a proxy version of the Children’s Health Utility 9 Dimension instrument, to explore the extent to which vitamin D deficiency affects children’s health-related quality of life

In the younger children group, the estimates of utility scores for hypocalcaemic cardiomyopathy (0·465; 95 % CI 0·425, 0·505) and hypocalcaemic seizures (0·495; 95 % CI 0·458, 0·532) were similar, with overlapping confidence intervals. This was also the case for active rickets, and pain and muscle weakness in both age groups.

For both age groups, the asymptomatic health state was associated with some disutility and ‘feeling tired’ was the main cause of such disutility. In young children, other factors contributing to lower utility scores in the subclinical health state were ‘lower ability to join in daily activities’, ‘feeling annoyed’ and ‘feeling pain’, while in the older children group these were ‘feeling annoyed’ and ‘pain’.

Discussion

The present study is the first to report utility values for VDD health states in children. Our preliminary results are indicative of the detrimental impact of VDD upon HRQoL and its potential to contribute to the burden of disease that has not yet been measured. Given the high prevalence of VDD, even if mainly in its asymptomatic or undiagnosed form, we have highlighted the importance of intensifying research in this field.

Evidence on the utility of VDD-related health states might contribute to more efficient decisions when it comes to allocating resources to the prevention and treatment of VDD. Utilities are used to calculate quality-adjusted life years. Quality-adjusted life years are a composite outcome that combines HRQoL with length of life and are used as the measure of benefit in cost–utility analyses. Health benefit measured by quality-adjusted life years is the preferred format of information for health-care policy makers in many countries, including the UK(Reference Chao, Ekwaru and Ohinmaa28, Reference Holick30Reference Ladhani, Srinivasan and Buchanan33).

The present study highlights the importance of considering the population impact of MND upon HRQoL in children, provides novel evidence of the impact of VDD on children’s HRQoL, and opens up an opportunity to reflect on the methods used for collecting HRQoL data for paediatric populations with MND. The results show coherence with the severity of health states reported in the literature, and the narrow confidence intervals of the estimates suggest that there is agreement among experts on the impact of VDD on children’s HRQoL. The ranking exercise was introduced as a warm-up question to familiarize respondents with the health states. As expected, there was better agreement between the results of the ranking exercise and the CHU9D utility scores for the health states ranked in the extremes; i.e. the most and least severe health states: hypocalcaemic seizures, cardiomyopathy and asymptomatic VDD. While the most and least severe health state can be easily placed in the extremes of the scale, variation is expected in the mid-severe health states, where variation in the respondents’ perception of severity and within-patient variations are more likely to occur. Using the CHU9D questionnaire reduced this variation, as the health states are broken down by physical, emotional and social dimensions, which helps to value health states more objectively.

VDD is a very common MND but symptomatic complications that lead to clinical presentation or hospital admission are rare. Therefore, hidden or undiagnosed disease is widespread in the population, with 25 % of a low-risk population having osteomalacia on bone biopsy(Reference Priemel, von Domarus and Klatte47) and two-thirds of family members of infants with rickets having biochemical evidence of osteomalacia(Reference Uday, Fratzl-Zelman and Roschger14).

Our study found that subclinical health states of VDD might lead to reduced HRQoL in children, mainly due to fatigue. Although the literature is sparse, evidence from primary care units shows a link between low levels of vitamin D and fatigue in adults. A study conducted in a health centre in Oslo, Norway, found that 58 % of the patients presenting with musculoskeletal pain, fatigue and headache had insufficient levels of vitamin D (<50 nmol/l)(Reference Knutsen, Brekke and Gjelstad48). A different study in the USA found that 77·2 % of patients with fatigue symptoms had 25(OH)D<70 nmol/l and their symptoms improved after treatment with vitamin D(Reference Roy, Sherman and Monari-Sparks49). Further research should explore if the same effect occurs in children. If this is the case, improving children’s vitamin D status might have benefits beyond bone and muscle health, including general well-being and school attainment.

In the present study, clinical experts valued VDD-related health states relevant to the paediatric population. The health states associated with lower HRQoL in younger children were hypocalcaemic cardiomyopathy, hypocalcaemic seizures and active rickets. In older children, active rickets and pain and muscle weakness resulted in the lowest HRQoL. Low serum 25(OH)D alone, described as the asymptomatic health state, was valued as causing a small but significant decrement in HRQoL in both age groups.

The health states were developed using robust methodology, based on the systematic evidence-based literature review that informed the rickets global consensus recommendations(Reference Munns, Shaw and Kiely4). Given the many barriers to the collection of HRQoL data in children(Reference Ungar and Gerber50), our study offers valuable insight from a pool of informed respondents. The results show that most respondents have experience in treating symptomatic VDD, which is a rare area of expertise among paediatricians. Such rare disease expertise might explain the moderate response rate (27 %), which is nevertheless comparable to other studies(Reference Asch, Connor and Hamilton37, Reference Cunningham, Quan and Hemmelgarn51). Moreover, recruiting clinical experts is a critical step in health research and low participation rates have been reported in the literature(Reference Sneeuw, Sprangers and Aaronson31, Reference Asch, Connor and Hamilton37, Reference Cunningham, Quan and Hemmelgarn51Reference Wiebe, Kaczorowski and MacKay54). Barriers to participation are many, including lack of time or capacity, and lack of familiarity or understanding the research objectives(Reference Johnston, Liddy and Hogg52, Reference Sadler, Lee and Lim53). Network sampling has the limitation of allowing self-selection, which leads to biased estimates given by experts who share similar views, leaving those who would disagree outside the recruited sample. In order to overcome this, efforts were made to reach more than one professional group, and within each group, all individuals were invited to participate. The respondents are therefore experts with similar professional backgrounds, rather than professionals with similar points of view.

The use of proxy data in patient groups that could potentially provide self-reported estimates (i.e. the older children group) might be seen as a limitation since self-reported HRQoL is the gold-standard method and the evidence suggests that there can be disagreements between patient and proxy reports. Morrow et al. compared children’s, parents’ and doctors’ perceptions of HRQoL associated with chronic paediatric conditions and found lower agreement in the subjective components, such as emotional well-being(Reference Morrow, Hayen and Quine55). Similar findings have been reported for adult populations(Reference Sneeuw, Sprangers and Aaronson31). Nevertheless, the literature on patient v. proxy utility values is inconsistent, with some studies reporting no difference between patient and proxy(Reference Krabbe, Tromp and Ruers56), as well as under-(Reference Rowen, Mulhern and Banerjee57) and overestimation(Reference Elstein, Chapman and Chmiel58) of HRQoL by the proxy. While we acknowledge that self-reported preferences from children with VDD would potentially better reflect utility scores for VDD health states, collecting such data is impractical. Children younger than 5 years old are not able to self-report preferences for health states. Although methodologically sound, collecting utility data from older children with various VDD health states is impractical in a research context, since clinical presentation with symptomatic VDD in this age group is extremely rare despite biochemical abnormalities(Reference Robinson, Högler and Craig11, Reference Ladhani, Srinivasan and Buchanan33, Reference Siddiqui and Kamfar59). Since parents have daily contact with their children, they are a commonly used and trusted source of health state utility values in paediatric populations. Nevertheless, in our study, recruiting parents of children with VDD was not a viable option due the rarity of symptomatic VDD. To recruit a satisfactory number of parents of children experiencing each of the health states would have been impractical.

In terms of future collection of MND-associated HRQoL, in countries such as the UK it may be feasible to collect these data alongside the National Diet and Nutrition Survey, a biennial routine survey undertaken to monitor the nutritional status of the population. This could offer an efficient way of collecting cross-sectional data on HRQoL and would open numerous possibilities to study the dynamics between diets, nutritional status and HRQoL at a population level. For cases of symptomatic VDD identified in a clinical setting, collection of qualitative information during follow-up would help understand how VDD affects individuals in the long term, including delayed bone and muscle development, quality of life and productivity.

The results of the present study call for more targeted research into the impact of MND upon the HRQoL of populations to generate better data to inform public health policies and therefore more efficient use of scarce public resources.

Conclusion

By eliciting utility values from health professionals, the present study translates clinical knowledge and expertise into information that can be used to support policy makers identifying cost-effective strategies for tackling VDD. The research presented will in turn stimulate and support future studies to collect HRQoL information from MND populations, using outcome measures that generate utility values. At a time of global austerity, it is essential to ensure efficient use of scarce health-care resources, as well as adequate estimates of burden of disease.

Acknowledgements

Acknowledgements: The authors thank Professor Tom Thacher, Mayo Clinic Rochester, USA for his valuable input in the development stage of the questionnaire. They would also like to thank all the respondents who voluntarily provided their time to answer the questionnaire. Financial support: This study was funded by the College of Medical and Dental Sciences at the University of Birmingham, through an internal PhD studentship grant. The funder had no role in the design, analysis or writing of this article. Conflict of interest: None to declare. Authorship: M.A. and E.F. developed the research question. All authors contributed to the development of its methods. M.A. and W.H. developed and validated the health states. M.A. designed the survey structure, with supervision of all other authors. W.H. supported with the recruitment. M.A. carried out the data analysis. All authors discussed the interpretation of the findings. M.A. wrote the first draft of the manuscript. L.A., M.P., W.H. and E.F. revised the manuscript and contributed significantly to its scientific content. Ethics of human subject participation: The project was submitted to the University of Birmingham Ethical Review Committee (reference number ERN_16-0370). No ethics approval was required.

References

1.Tulchinsky, TH (2010) Micronutrient deficiency conditions: global health issues. Public Health Rev 32, 243255.CrossRefGoogle Scholar
2.Allen, LH, de Benoist, B, Dary, Oet al. (editors) (2006) Guidelines on Food Fortification with Micronutrients. Geneva/Rome: WHO/FAO.Google Scholar
3.Branca, F & Ferrari, M (2002) Impact of micronutrient deficiencies on growth: the stunting syndrome. Ann Nutr Metab 46, Suppl. 1, 817.CrossRefGoogle ScholarPubMed
4.Munns, CF, Shaw, N, Kiely, Met al. (2016) Global consensus recommendations on prevention and management of nutritional rickets. J Clin Endocrinol Metab 101, 394415.CrossRefGoogle ScholarPubMed
5.Institute of Medicine (2011) Dietary Reference Intakes for Calcium and Vitamin D. Washington, , DC: National Academies Press.Google Scholar
6.Prentice, A (2008) Vitamin D deficiency: a global perspective. Nutr Rev 66, 10 Suppl. 2, S153S164.CrossRefGoogle ScholarPubMed
7.Cashman, KD, Dowling, KG, Skrabakova, Zet al. (2016) Vitamin D deficiency in Europe: pandemic? Am J Clin Nutr 103, 10331044.CrossRefGoogle ScholarPubMed
8.Bates, B, Lennox, A, Prentice, Aet al. (2016) National Diet and Nutrition Survey Results from Years 5 and 6 (combined) of the Rolling Programme (2012/2013–2013/2014). London: Public Health England and Food Standards Agency.Google Scholar
9.Basatemur, E & Sutcliffe, A (2014) Incidence of hypocalcemic seizures due to vitamin D deficiency in children in the United Kingdom and Ireland. J Clin Endocrinol Metab 100, E91E95.CrossRefGoogle Scholar
10.Hatun, S, Ozkan, B, Orbak, Zet al. (2005) Vitamin D deficiency in early infancy. J Nutr 135, 279282.CrossRefGoogle ScholarPubMed
11.Robinson, PD, Högler, W, Craig, MEet al. (2006) The re-emerging burden of rickets: a decade of experience from Sydney. Arch Dis Child 91, 564568.CrossRefGoogle ScholarPubMed
12.Elidrissy, ATH, Munawarah, M & Alharbi, KM (2013) Hypocalcemic rachitic cardiomyopathy in infants. J Saudi Heart Assoc 25, 2533.CrossRefGoogle ScholarPubMed
13.Maiya, S, Sullivan, I, Allgrove, Jet al. (2008) Hypocalcaemia and vitamin D deficiency: an important, but preventable, cause of life-threatening infant heart failure. Heart 94, 581584.CrossRefGoogle ScholarPubMed
14.Uday, S, Fratzl-Zelman, N, Roschger, Pet al. (2018) Cardiac, bone and growth plate manifestations in hypocalcemic infants: revealing the hidden body of the vitamin D deficiency iceberg. BMC Pediatr 18, 183.CrossRefGoogle ScholarPubMed
15.Callaghan, AL, Moy, R, Booth, IWet al. (2006) Incidence of symptomatic vitamin D deficiency. Arch Dis Child 91, 606607.CrossRefGoogle ScholarPubMed
16.Ward, LM, Gaboury, I, Ladhani, Met al. (2007) Vitamin D-deficiency rickets among children in Canada. CMAJ 177, 161166.CrossRefGoogle ScholarPubMed
17.Al-Said, YA, Al-Rached, HS, Al-Qahtani, HAet al. (2009) Severe proximal myopathy with remarkable recovery after vitamin D treatment. Can J Neurol Sci 36, 336339.CrossRefGoogle ScholarPubMed
18.Ward, KA, Das, G, Berry, JLet al. (2009) Vitamin D status and muscle function in post-menarchal adolescent girls. J Clin Endocrinol Metab 94, 559563.CrossRefGoogle ScholarPubMed
19.Uday, S & Högler, W (2018) Prevention of rickets and osteomalacia in the UK: political action overdue. Arch Dis Child 103, 901906.CrossRefGoogle ScholarPubMed
20.NHS Choice (2015) Rickets and osteomalacia. https://www.nhs.uk/conditions/rickets-and-osteomalacia/ (accessed September 2016).Google Scholar
21.Zylke, JW, Rivara, FP & Bauchner, H (2013) Contrasts in child health care and child health research. JAMA 309, 18341836.CrossRefGoogle ScholarPubMed
22.Thacher, TD, Pludowski, P, Shaw, NJet al. (2016) Nutritional rickets in immigrant and refugee children. Public Health Rev 37, 3.CrossRefGoogle ScholarPubMed
23.The Canadian Paediatric Surveillance Program (2008) Rickets: a re-emerging public health problem in Canada? Paediatr Child Health 13, 73.CrossRefGoogle Scholar
24.Leung, G & Stanner, S (2011) Diets of minority ethnic groups in the UK: influence on chronic disease risk and implications for prevention. Nutr Bull 36, 161198.CrossRefGoogle Scholar
25.Scientific Advisory Committee on Nutrition (2016) Vitamin D and Health. London: Public Health England.Google Scholar
26.Aguiar, M, Andronis, L, Pallan, Met al. (2017) Preventing vitamin D deficiency (VDD): a systematic review of economic evaluations. Eur J Public Health 27, 292301.CrossRefGoogle ScholarPubMed
27.Rafiq, R, Swart, K, van Schoor, Net al. (2014) Associations of serum 25-hydroxyvitamin D concentrations with quality of life and self-rated health in an older population. J Clin Endocrinol Metab 99, 31363143.CrossRefGoogle Scholar
28.Chao, Y, Ekwaru, J, Ohinmaa, Aet al. (2014) Vitamin D and health-related quality of life in a community sample of older Canadians. Qual Life Res 23, 25692575.CrossRefGoogle Scholar
29.Tolentino-Wilson, O & Narvacan-Montano, C (2014) Association of 25(OH)D serum concentrations on health-related quality of life among patients with low vitamin D. J ASEAN Fed Endocrine Soc 29, 54.Google Scholar
30.Holick, MF (2002) Vitamin D: the underappreciated D-lightful hormone that is important for skeletal and cellular health. Curr Opin Endocrinol Diabetes Obes 9, 8798.CrossRefGoogle Scholar
31.Sneeuw, KC, Sprangers, MA & Aaronson, NK (2002) The role of health care providers and significant others in evaluating the quality of life of patients with chronic disease. J Clin Epidemiol 55, 11301143.CrossRefGoogle ScholarPubMed
32.Pickard, AS & Knight, SJ (2005) Proxy evaluation of health-related quality of life: a conceptual framework for understanding multiple proxy perspectives. Med Care 43, 493499.CrossRefGoogle ScholarPubMed
33.Ladhani, S, Srinivasan, L, Buchanan, Cet al. (2004) Presentation of vitamin D deficiency. Arch Dis Child 89, 781784.CrossRefGoogle ScholarPubMed
34.Alghadir, AH, Gabr, SA & Al-Eisa, ES (2017) Mechanical factors and vitamin D deficiency in schoolchildren with low back pain: biochemical and cross-sectional survey analysis. J Pain Res 10, 855865.CrossRefGoogle ScholarPubMed
35.European Society for Paediatric Endocrinology (2016) ESPE Working Group on Bone and Growth Plate. https://www.eurospe.org/about/espe-working-groups/bone-and-growth-plate/ (accessed May 2016).Google Scholar
36.Royal College of Paediatrics and Child Health (2016) British Paediatric and Adolescent Bone Group (BPABG). https://www.rcpch.ac.uk/about-us/specialty-groups-special-interest-groups#british-paediatric-and-adolescent-bone-group-bpabg (accessed May 2016).Google Scholar
37.Asch, S, Connor, SE, Hamilton, EGet al. (2000) Problems in recruiting community‐based physicians for health services research. J Gen Intern Med 15, 591599.CrossRefGoogle ScholarPubMed
38.Högler, W (2015) Complications of vitamin D deficiency from the foetus to the infant: one cause, one prevention, but who’s responsibility? Best Pract Res Clin Endocrinol Metab 29, 385398.CrossRefGoogle ScholarPubMed
39.Thacher, TD, Fischer, PR & Pettifor, JM (2002) The usefulness of clinical features to identify active rickets. Ann Trop Paediatr 22, 229237.CrossRefGoogle ScholarPubMed
40.Stevens, K (2011) Assessing the performance of a new generic measure of health-related quality of life for children and refining it for use in health state valuation. Appl Health Econ Health Policy 9, 157169.CrossRefGoogle ScholarPubMed
41.Chen, G, Flynn, T, Stevens, Ket al. (2015) Assessing the health-related quality of life of Australian adolescents: an empirical comparison of the child health utility 9D and EQ-5D-Y instruments. Value Health 18, 432438.CrossRefGoogle ScholarPubMed
42.Canaway, AG & Frew, EJ (2013) Measuring preference-based quality of life in children aged 6–7 years: a comparison of the performance of the CHU-9D and EQ-5D-Y – the WAVES Pilot Study. Qual Life Res 22, 173183.CrossRefGoogle ScholarPubMed
43.Stevens, K & Ratcliffe, J (2012) Measuring and valuing health benefits for economic evaluation in adolescence: an assessment of the practicality and validity of the Child Health Utility 9D in the Australian adolescent population. Value Health 15, 10921099.CrossRefGoogle ScholarPubMed
44.Ratcliffe, J, Stevens, K, Flynn, Tet al. (2012) An assessment of the construct validity of the CHU9D in the Australian adolescent general population. Qual Life Res 21, 717725.CrossRefGoogle ScholarPubMed
45. The University of Sheffield (n.d.) Measuring & Valuing Health. A brief overview of the Child Health Utility 9D (CHU9D). https://www.sheffield.ac.uk/scharr/sections/heds/mvh/paediatric/about-chu9d (accessed May 2016).Google Scholar
46.Stevens, K (2012) Valuation of the child health utility 9D index. Pharmacoeconomics 30, 729747.CrossRefGoogle ScholarPubMed
47.Priemel, M, von Domarus, C, Klatte, TOet al. (2010) Bone mineralization defects and vitamin D deficiency: histomorphometric analysis of iliac crest bone biopsies and circulating 25‐hydroxyvitamin D in 675 patients. J Bone Miner Res 25, 305312.CrossRefGoogle ScholarPubMed
48.Knutsen, KV, Brekke, M, Gjelstad, Set al. (2010) Vitamin D status in patients with musculoskeletal pain, fatigue and headache: a cross-sectional descriptive study in a multi-ethnic general practice in Norway. Scand J Prim Health Care 28, 166171.CrossRefGoogle Scholar
49.Roy, S, Sherman, A, Monari-Sparks, MJet al. (2014) Correction of low vitamin D improves fatigue: Effect of Correction of Low Vitamin D in Fatigue Study (EViDiF Study). N Am J Med Sci 6, 396402.CrossRefGoogle Scholar
50.Ungar, W & Gerber, A (2010) The uniqueness of child health and challenges to measuring costs and consequences. In Economic Evaluation of Child Health, pp. 332 [W Ungar, editor]. Oxford: Oxford University Press.Google Scholar
51.Cunningham, CT, Quan, H, Hemmelgarn, Bet al. (2015) Exploring physician specialist response rates to web-based surveys. BMC Med Res Methodol 15, 32.CrossRefGoogle ScholarPubMed
52.Johnston, S, Liddy, C, Hogg, Wet al. (2010) Barriers and facilitators to recruitment of physicians and practices for primary care health services research at one centre. BMC Med Res Methodol 10, 109.CrossRefGoogle ScholarPubMed
53.Sadler, G, Lee, H, Lim, Ret al. (2011) Recruiting hard-to-reach United States populations sub-groups via adaptations of snowball sampling strategy. Nurs Health Sci 12, 369374.CrossRefGoogle Scholar
54.Wiebe, ER, Kaczorowski, J & MacKay, J (2012) Why are response rates in clinician surveys declining? Can Fam Physician 58, e225e228.Google ScholarPubMed
55.Morrow, AM, Hayen, A, Quine, Set al. (2012) A comparison of doctors’, parents’ and children’s reports of health states and health-related quality of life in children with chronic conditions. Child Care Health Dev 38, 186195.CrossRefGoogle ScholarPubMed
56.Krabbe, PF, Tromp, N, Ruers, TJet al. (2011) Are patients’ judgments of health status really different from the general population? Health Qual Life Outcomes 9, 31.CrossRefGoogle ScholarPubMed
57.Rowen, D, Mulhern, B, Banerjee, Set al. (2015) Comparison of general population, patient, and carer utility values for dementia health states. Med Decis Making 35, 6880.CrossRefGoogle ScholarPubMed
58.Elstein, AS, Chapman, GB, Chmiel, JSet al. (2004) Agreement between prostate cancer patients and their clinicians about utilities and attribute importance. Health Expect 7, 115125.CrossRefGoogle ScholarPubMed
59.Siddiqui, AM & Kamfar, HZ (2007) Prevalence of vitamin D deficiency rickets in adolescent school girls in Western region, Saudi Arabia. Saudi Med J 28, 441444.Google ScholarPubMed
Figure 0

Table 1 Area of expertise and country of practice of the paediatric bone experts (n 38) participating in the present study

Figure 1

Fig. 1 Results from the ranking exercise for young children (0–4 years) carried out by paediatric bone experts (n 38) to explore the extent to which vitamin D deficiency affects children’s health-related quality of life. 0 corresponds to the least severe condition and 6 to the most severe

Figure 2

Fig. 2 Results from the ranking exercise for older children (>4 years) carried out by paediatric bone experts (n 38) to explore the extent to which vitamin D deficiency affects children’s health-related quality of life. 0 corresponds to the least severe condition and 4 to the most severe

Figure 3

Table 2 Health state utility values for young children and older children with low serum 25-hydroxyvitamin D concentration from the valuation, carried out by paediatric bone experts (n 38) using a proxy version of the Children’s Health Utility 9 Dimension instrument, to explore the extent to which vitamin D deficiency affects children’s health-related quality of life