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The social cost of high sodium diet in Singapore

Published online by Cambridge University Press:  26 May 2022

Jemima Koh Open the ORCID record for Jemima Koh [Opens in a new window] ,
Gregory Ang ,
Kelvin-Bryan Tan  and
Cynthia Chen
Jemima Koh
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore
Gregory Ang
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore
Kelvin-Bryan Tan
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore Ministry of Health, Singapore, Singapore Centre for Regulatory Excellence, Duke-NUS Medical School, Singapore, Singapore
Cynthia Chen*
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore Schaeffer Center for Health Policy and Economics, University of Southern California, Los Angeles, CA, USA Department of Non-Communicable Disease Epidemiology, The London School of Hygiene & Tropical Medicine, UK
*
*Corresponding author: Cynthia Chen, email ephchc@nus.edu.sg
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Abstract

High sodium (Na) diet is one of the leading behavioural risks of disease identified in the Singapore Burden of Disease Study. We aim to estimate the cost attributable to a high Na diet in Singapore in 2019 from a societal perspective by employing a prevalence-based approach in cost-of-illness studies. We extracted national-level healthcare data and population attributable fractions by sex and age. Costs included direct and indirect costs from inpatient treatment and productivity losses. In 2019, the annual societal cost attributable to a high Na diet was conservatively estimated to be USA$262 million (95 % uncertainty interval (UI) 218, 359 million). At least USA$67·8 million (95 % UI 48·4, 120 million) and USA$194 million (95 % UI 153, 274 million) could be saved on healthcare and indirect costs, respectively, if the daily Na intake of Singaporeans was reduced to an average of 3 g. Overall, males had higher costs compared with females at USA$221 million (95 % UI 174, 312 million) and USA$41·1 million (95 % UI 33·5, 61·7 million), respectively. Productivity loss from foregone wages due to premature mortality had the largest cost at USA$191 million (95 % UI 150, 271 million). CVD had the largest healthcare expenditure at USA$61·4 million (95 % UI 41·6, 113 million), driven by ischaemic heart disease at USA$41·0 million (95 % UI 21·4, 88·9 million). Our study found that reducing Na intake could reduce future healthcare expenditures and productivity losses. This result is vital for policy evaluation in a rapidly ageing society like Singapore, where the burden of diseases associated with high Na diet is expected to increase.

Keywords

Sodium dietPopulation attributable fractionsSocial cost
Type
Research Article
Information
British Journal of Nutrition , Volume 129 , Issue 9 , 14 May 2023 , pp. 1598 - 1606
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

Globally, the average salt consumption in 2010 was estimated at 9–12 g daily, twice of the WHO recommended daily intake of less than 5 g, approximately 2 g of sodium (Na)(13). Na is a chemical element found in salt, where 1 g of salt contains approximately 0·4 g of Na(3). There have been efforts to quantify the burden of disease attributable to dietary factors in the past decade. Among these efforts is the Global Burden of Disease (GBD) Study in 2017, where around one-third of the diet-related deaths and disability-adjusted life years (DALY) are attributable to high intake of Na (3 million deaths and 70 million DALY)(Reference Afshin, Sur and Fay4). For consistency with the GBD, we will use ‘Na’ instead of ‘salt’ throughout the paper.

In a review paper, studies have found positive associations between high Na intake and high blood pressure(Reference He, Li and MacGregor5), and non-communicable diseases such as CVD(Reference He, Li and MacGregor5,Reference Mozaffarian, Fahimi and Singh6) and stomach cancer(Reference Tsugane, Sasazuki and Kobayashi7,Reference Wang, Terry and Yan8) . These clinical outcomes due to high Na intake are mediated by various pathways such as increased blood pressure, damaged blood vessels and hormonal changes(Reference He, Tan and Ma9). Additionally, the International Study of Sodium, Potassium, and Blood Pressure found an association between age with Na intake and increased blood pressure, where ageing could delay the rise in blood pressure due to excessive Na intake(Reference Elliott, Stamler and Nichols10). Coupled with a rapidly ageing population, the burden of CVD is expected to increase with a higher prevalence of unhealthy diet(Reference Gakidou, Afshin and Abajobir11). It is thus imperative for governments to mitigate the increasing burden and cost to both society and health systems.

Regional Na consumption estimate comparisons found that several parts of Asia (e.g. East, Pacific and Central) ranked top and had distinguishably higher daily Na intake than all other regions (e.g. Africa and America)(Reference Powles, Fahimi and Micha12). Even though a high Na diet poses a significant burden from increased healthcare cost, and indirect cost from absenteeism and reduced productivity, few studies have estimated the cost attributable to a high Na diet in Asia, where Na intake is high. The cost-of-illness study using population attributable fractions (PAF) is widely used by studies to estimate the cost attributable to a known risk factor(Reference Jo13). Examples of such studies are the analysis of healthcare spending attributable to modifiable risk factors in the USA(Reference Bolnick, Bui and Bulchis14) and a global analysis to estimate disease-specific and country-specific costs attributable to physical inactivity(Reference Ding, Lawson and Kolbe-Alexander15). In Singapore, it has been applied to estimate the impact of smoking in 2014(Reference Cher, Chen and Yoong16). However, to the best of the authors’ knowledge, no local study has evaluated the cost attributable to a high Na diet.

The Singapore Health Promotion Board adopts WHO’s guidelines on Na consumption and makes an effort to reduce national Na intake through collaborations with multiple stakeholders and policymakers(17). Since Singapore’s War on Salt launched in 2011, collaborations between food manufacturers and nutrition experts have encouraged companies to develop healthier food and Na alternatives locally(17). Products like sauces and processed canned meats that carry healthier choice labels are created to help consumers identify that these products contained at least 25 % less Na than similar products(18). Despite efforts, the survey found that approximately 90 % of Singaporeans still exceeded the recommended daily Na consumption, with an average of 3·6 g in 2018(19). This intake was higher than the findings in 2010 (3·3 g)(17) and was nearly twice WHO’s recommended daily Na intake of 2 g(20). Findings in 2010 also revealed that adults aged 30–49 years had the highest daily Na intake at 3·6 g, and males had higher Na consumption compared with females (4 g v. 2·8 g)(17). Despite national efforts to reduce Na intake, many Singaporeans still exceed the recommended Na intake. As daily Na consumption differs by sex and age, it is crucial to evaluate the economic impact of high Na diet, inform public health policies and provide evidence for Na reduction interventions in the country. Thus, this paper aims to estimate the societal cost (direct and indirect) attributable to a high Na diet in Singapore, accounting for sex and age differences.

Methods

Study design

Using the prevalence-based approach in cost-of-illness studies, this paper aims to estimate the societal cost of a high Na diet in Singapore in 2019. The cost estimation used a top-down approach by incorporating aggregated sex and age group data with PAF of high Na diet to evaluate the costs attributable to a high Na diet. Following GBD’s definition, a high Na diet is defined as having more than 3 g of urinary Na per day. Components of costs included direct costs from healthcare and indirect costs from productivity losses. Direct healthcare cost cumulates medical expenditures from inpatient hospitalisation bills for all diseases associated with a high Na diet. Indirect costs include costs arising from productivity losses when a patient was absent from work due to diseases associated with a high Na diet and the costs society incurs when an individual dies prematurely from a high Na diet.

Estimation of population attributable fraction

The PAF is a crucial parameter used in our study that was estimated by the GBD study 2017(Reference Gakidou, Afshin and Abajobir11). The methodology used by the GBD to estimate PAF was detailed in the study’s appendix and will only be summarised in this paper. Defined in the study, PAF for a high Na diet represents the proportion of disease (e.g. hypertensive heart diseases, stomach cancer and ischaemic heart disease) that would be reduced in a population in a specific year (e.g. 2019) if the population had a mean urinary Na measurement of 3 g (uncertainty interval (UI) of 1–5 g). Na was measured by a 24-h urinary excretion, a gold standard to measure dietary Na intake(Reference Gakidou, Afshin and Abajobir11). Although it was quantified that an average of 95 % dietary Na is excreted in urine(Reference Vandevijvere, De Keyzer and Chapelle21), for simplicity, our study will discuss results assuming that the amount of dietary Na ingested is equivalent to the amount of urinary Na excreted.

The PAF for high Na diet for each disease, age group and sex in Singapore in 2019 is formulated by GBD as follows:

$$PA{F_{oas}} = {{\sum\nolimits_{x = 1}^u R {R_{oas}}\left( x \right){P_{as}}\left( x \right) - R{R_{oas}}\left( {TMRE{L_{as}}} \right)} \over {\sum\nolimits_{x = 1}^u R {R_{oas}}\left( x \right){P_{as}}\left( x \right)}}$$

where $PA{F_{oas}}$ is the population attributable fraction for outcome o due to a diet high in Na for age group a and sex s. $R{R_{oas}}\left( x \right)$ is the relative risk as a function of exposure level x for a diet high in Na for outcome o, age group a and sex s on a plausible range of $1$ to u. ${P_{as}}\left( x \right)$ is the proportion of population of risk group (prevalence), for age group a and sex s; $TMRE{L_{as}}$ is the theoretical minimum risk exposure level (TMREL) for a diet high in Na for age group a and sex s, defined as a mean of 3 g (UI of 1–5 g) of urinary Na a day.

The list of diseases associated with high Na can be found in online Appendix Table 1.

Data sources

PAF of high Na diet in 2019 for Singapore was retrieved from GBD online results tools(Reference Gakidou, Afshin and Abajobir11). These values were further categorised into three levels: (1) stomach cancer, (2) CVD and (3) chronic kidney diseases. Our study utilised 5-year interval PAF values for ages 20–79 and aggregated ages above 80 as a single age group. In the absence of PAF data for younger age groups, these age groups assumed values of the youngest available age group. Overall, PAF estimates of a high Na diet for various diseases are listed in online Appendix Table 1.

Inpatient hospital data, also known as Mediclaims data, were obtained from the Ministry of Health Singapore (not published). Mediclaims data contain national-level healthcare use data with detailed historical transacted bills sizes and hospitalisation information of all patient (Singapore citizens, permanent residents and foreigners) discharge information from Singapore’s public and private hospitals. Data were then categorised according to International Classification of Disease (ICD10) codes diagnosed during a hospital stay. All disease-specific ICD10 codes attributable to high Na diet were extracted from the GDB(22) and merged with the Mediclaims data by sex and age. From the Mediclaims data, we obtained inpatient bills, length of hospital stays and total inpatient volume. For indirect cost estimation, we used sex-specific mean income and labour force participation rates (LFPR) in the year 2019 from the Ministry of Manpower Singapore(23). All data obtained and cost estimations were done by sex and age groups.

Direct healthcare costs

Using Mediclaims data from the Ministry of Health Singapore, the healthcare cost attributable to a high Na diet for each disease was estimated by multiplying the mean inpatient bill with the inpatient volume and respective PAF values. The total healthcare cost was then summed across all diseases. Only the primary diagnosis codes were used for hospitalisations with multiple Na-related conditions. The formula for the total direct healthcare cost attributable to a high Na diet for the analysis in this paper is presented in Table 1.

Table 1. Cost estimation formula

PAF, population attributable fraction; LFPR, labour force participation rates; LOS, length of hospital stay.

Where $i = 1,{\rm{\;}} \ldots ,{\rm{\;}}{n_d}$ and ${n_d}\;$ represents total number of diseases; $s = 1{\rm{\;and\;}}2$ representing male and female, respectively; $a = 1, \ldots ,{\rm{\;}}{n_a}$ and ${n_a}$ represents total number of age groups with 5-year intervals starting from age 20 with the exception of ages above 80 which were aggregated as one group.

* Excluding ages 80 and above.

Indirect cost

Indirect costs were estimated using the human capital approach(Reference Zhang, Bansback and Anis24). This approach assumes the opportunity cost attributable to a high Na diet from diseases and deaths was tied to an individual’s productivity in society. This paper accounted for productivity loss from hospitalisation-related absenteeism and foregone wages due to premature mortality. Productivity losses were calculated for individuals between the ages of 20 and 79, who are economically active in the labour force. This cost cumulated represents an individual’s present and future contribution to the society’s production if he/she works in full health(Reference Jo13) by assuming future earnings as proxies for future productivity.

Cost from hospitalisation-related absenteeism

Productivity loss due to costs from hospitalisation-related absenteeism was defined as the income lost due to hospitalisation. It was estimated by multiplying the mean daily wages by the LFPR and disease-specific mean length of hospital stay. These values were further multiplied by inpatient volume and PAF values. The formula used to estimate the total productivity loss due to costs from hospitalisation-related absenteeism is found in Table 1.

Foregone wages due to premature mortality

Productivity loss due to foregone wages from premature mortality of an individual was estimated by calculating his present value of lifetime earnings from the year of death to age 79 as a proxy of his total future expected earnings. The total productivity loss due to foregone wages from premature mortality in Singapore in 2019 was estimated across all diseases attributed to a high Na diet. This was done by summing the product of the number of deaths, total expected future earnings, LFPR and overall PAF values. The present value of lifetime earnings was discounted at a rate of 3 %, and an income growth rate of 3·3 % was set as the annualised real wage changes from the Ministry of Manpower Singapore in 2019(25). The formula is presented in Table 1.

All reported costs are in US dollars (where USA$1 = SG$1·36(26)) for the year 2019. Point estimates in the model were deterministically estimated from mean values.

Sensitivity analysis

Uncertainties in the model were explored by stochastically simulating GBD and Mediclaims data using 10 000 independent draws. GBD’s PAF values were drawn from a beta distribution, while inpatient cost, length of hospital stays and the number of deaths were drawn from a log-normal distribution. Wherever possible, the parameters of the distributions were obtained from data. Otherwise, they were estimated using published 95 % UI and a package named ‘rriskDistributions’ from R(Reference Belgorodski, Greiner and Tolksdorf27). Details of parameters used in the sensitivity analysis can be found in online Appendix Table 2. Uncertainty of the model was characterised by the 95 % UI (2·5th percentile and 97·5th percentile) of the 10 000 draws. All analyses were done using R (version 3.6.3).

Results

Overall results

The societal cost attributable to high Na diet was estimated to be USA$262 million (95 % UI 218, 359 million) in Singapore (Table 2). Overall, males had a higher cost at USA$221 million (95 % UI 174, 312 million) compared with females at USA$41·1 million (95 % UI 33·5, 61·7 million). Productivity loss from foregone wages due to premature mortality had the largest proportion of the cost at USA$191 million (95 % UI 150, 271 million), followed by healthcare cost at USA$67·8 million (95 % UI 48·4, 120 million).

Table 2. Overall cost of diet high in Na (Odds ratios and 95 % uncertainty intervals)

UI, uncertainty interval.

Direct cost

Total healthcare cost attributable to a high Na diet was estimated to be USA$67·8 million (95 % UI 48·4, 120 million), where males had around three times the cost of females (USA$51·8 million v. USA$16·0 million). This is approximately 25 % of the total cost. Healthcare costs were mostly driven by CVD, USA$61·4 million (95 % UI 41·6, 113 million), followed by chronic kidney diseases, USA$4·73 million (95 % UI 3·11, 9·24 million) and stomach cancer, USA$1·70 million (95 % UI 0·818, 5·32 million) (Table 3). Main differences between sex were only observed in CVD, where males accounted for USA$48·1 million (95 % UI 28·5, 97·4 million), and females accounted for a quarter of the cost at USA$13·3 million (95 % UI 8·85, 25·4 million). When considering types of CVD, costs were highest for ischaemic heart disease at USA$41·0 million (95 % UI 21·4, 88·9 million), followed by stroke at USA$14·6 million (95 % UI 10·0, 25·8 million) (Table 3). Among individuals active in the labour force (aged 20–79 years), hospitalisation costs increased with age, and those aged 50 and above accounted for more than 90 % of the healthcare cost (Table 4).

Table 3. Direct healthcare cost and disease breakdowns (Odds ratios and 95 % uncertainty intervals)

UI, uncertainty interval.

Table 4. Total cost and hospitalisation days for age groups active in labour force – 20–79 (Odds ratios and 95 % uncertainty intervals)

UI, uncertainty interval.

* Cost for ages above 80 not presented here

Indirect cost

Males had a total of USA$2·56 million (95 % UI 1·58, 4·92 million) cost from hospitalisation-related absenteeism from diseases associated with a high Na diet while females had a total of USA$0·460 million (95 % UI 0·325, 0·844 million) (Table 2). The total number of workdays missed was 18 100 d (95 % UI 12 500, 32 900), where the number of missed workdays increased with age, with more than 80 % of total hospitalisation days from age group 50–79 (Table 4).

Foregone wages due to premature mortality amounted to a total of USA$191 million (95 % UI 150, 271 million) with males contributing USA$166 million (95 % UI 124, 241 million) and females USA$24·7 million (95 % UI 17·7, 39·5 million) (Table 2). This cost increased with age before a decrease from age 60. The age group with the highest foregone wages due to premature mortality was from ages 50–59 at USA$71·9 million (95 % UI 41·0, 123 million). The second highest foregone wages due to premature mortality were from age group 60–69 at USA$52·0 million (95 % UI 29·5, 89·3 million) followed by age group 40–49 at USA$42·4 million (95 % UI 23·2, 77·9 million) (Table 4). In all age groups, males had substantially higher foregone wages due to premature mortality compared with females.

The total cost (direct and indirect) was the highest for age group 50–59 at USA$89·5 million (95 % UI 56·1, 148 million) with males contributing at USA$77·1 million (95 % UI 43·7, 134 million) and females at USA$ 12·3 million (95 % UI 6·86, 22·9 million) (Table 4). The trend of cost across age groups for both sexes is similar, where there was an increase up to age 59.

Discussion

This is the first study in Singapore to provide a cost estimate incurred to a society relating to high Na diet. In 2019, approximately USA$262 million (95 % UI 218, 359 million) could be saved if the average Na intake of Singaporeans is reduced to 3 g/d. This value consisted of USA$67·8 million (95 % UI 48·4, 120 million) from direct healthcare costs and USA$194 million (95 % UI 153, 274 million) from indirect productivity losses. Policies to reduce Na intake could thus potentially reduce future healthcare expenditure.

Cost attributable to a high Na diet varied by sex and was skewed towards males in our study. CVD had the highest attributable direct hospitalisation cost, while age group 50–59 had the highest indirect cost. Although ages 50–59 accounted for the largest proportion of the cost, diseases caused by high Na diet happen before these ages, when unhealthy diet and lifestyle habits were cultivated(Reference Mikkilä, Räsänen and Raitakari28). Additionally, it has also been suggested that childhood dietary patterns may impact morbidities in later years(Reference Kaikkonen, Mikkilä and Raitakari29).

Our study found productivity loss attributable to high Na diet totals 18 100 d (95 % UI 12 500, 32 900) spent in hospital during the year, and 15 900 years (95 % UI 13 500, 21 400) lost due to premature death. These reduced workdays significantly impact employers and society. Thus, there is a large potential for reducing productivity loss and associated costs from new interventions in primary and secondary prevention of non-communicable diseases from a high Na diet. Given Singapore’s rapidly ageing population, high Na diet is expected to create a huge impact on Singapore’s economy due to the increased burden of disease.

Over the past decade, cost-effectiveness studies on dietary interventions at both national(Reference Asaria, Chisholm and Mathers30Reference Martikainen, Soini and Laaksonen35) and global levels(Reference Webb, Fahimi and Singh36) have provided evidence that Na reduction interventions have great potential to be cost-saving. A recent individual-based microsimulation study in Singapore found that reducing to 1·6 g of Na daily was optimal in averting CVD and DALY(Reference Tan, Quaye and Koo37). Despite promising results, these studies do not account for consumers’ reactions and pricing strategies of the food industry(Reference Cobiac, Veerman and Vos38Reference Owen, Morgan and Fischer41). An international review of eleven studies suggests that population-wide interventions on reducing Na intake were effective(Reference Wang and Labarthe42). Possible policies included government collaboration with the food industry and a Na tax(Reference Smith-Spangler, Juusola and Enns40). In Asia and Latin America with a larger participation of discretionary salt and sauces, salt reduction initiatives further included the reformulation of food products, limiting the Na content in processed foods, restrictions on importing foods high in Na, public education on the harmful effects of high Na intake, compulsory labelling of products high in Na and increased range of healthy foods with low Na(Reference Ghimire, Mishra and Satheesh43,Reference Mohan, Prabhakaran and Krishnan44) .

Since the launch of the War on Salt in 2011, Singaporeans’ average daily Na consumption has increased slightly from 3·3 g in 2010 to 3·6 g in 2018(19). The contribution of Na on DALY in Singapore has also increased from 2014 to 2019 despite an initial drop after the War on Salt(45). However, the contribution of Na on mortality has decreased during the same period(45). Further research on the impact of the War on Salt may be warranted to evaluate its effectiveness.

Reduction of Na consumption is difficult because policies to reduce Na intake also face major challenges. Many policies only target consumers but not the wider range of interconnected factors, such as food production and distribution(Reference Anand, Hawkes and De Souza46,Reference Brown, Yamey and Wamala47) . Most Na in Singaporean’s diet (60 %) comes from table salt and sauces, especially stir-fried food. Processed food such as fish balls, fish cakes, bread and noodles are estimated to contribute another 37 % of the population’s Na intake(17). Such foods are widely served at affordable and convenient food establishments where Singaporeans frequent, such as hawker centres and food courts(Reference Tan and Arcaya48). In 2022, the Health Promotion Board Singapore has re-evaluated its Na-related policies and launched a collaboration with food suppliers to encourage the use of lower-Na alternatives(49). The Healthier Ingredient Development Scheme provides grant support for suppliers to use lower-Na alternatives. Additionally, campaigns will also be conducted to the public to raise awareness of the dangers of excessive Na intake(49). In line with suggestions from review studies, providing financial support to encourage food suppliers to reformulate their food products with lower-Na alternatives and providing public education on the effects of high Na consumption are potential policies government could support to reduce Na consumption.

Understanding the impact on healthcare spending and productivity losses attributable to high Na diet, a modifiable risk factor can help to guide public health intervention programmes in Singapore. Our study identified the age groups and sex with the greatest impact to allow policymakers to streamline interventions at the right population to obtain optimal benefits. Given that the greatest contributor to early death and disability in Singapore was CVD (14·7 % of total DALY)(50), targeting the causes of CVD early can help lessen the burden on Singapore’s healthcare system. A separate simulation study projected the lifetime hospitalisation spending of older adults to be USA$24 400 (30·2 %) higher among people with disabilities(Reference Chen, Lim and Chia51).

Comparison with other countries

To the best of the authors’ knowledge, few studies evaluated the societal cost attributable to high Na diet, and none in Asia. In 2013, the Brazilian health system estimated around USA$103 million could be saved in public hospitalisation costs if Brazilians reduced their average Na intake to 2 g/d(Reference Nilson, Da Silva and Jaime52). A further study estimated USA$752 million from productivity losses of foregone wages due to premature deaths from CVD attributable to excessive Na intake in 2017(Reference Nilson, Metlzer and Labonté53). The study also estimated the hospitalisation cost to their health system attributable to a high Na diet for CVD to be USA$76·2 million. Compared with the direct healthcare cost from CVD in our study, the CVD cost to gross domestic product ratio was approximately 4·4 times higher in Singapore compared with Brazil(54). This comparison suggests that direct healthcare costs accrued due to a high Na diet in Singapore could indicate a rising public health concern. In line with the USA study(Reference Bolnick, Bui and Bulchis14), males contributed to a larger proportion of healthcare expenditures for modifiable risk factors than females. Similarly, the authors also found that CVD (i.e. ischaemic heart disease) had the largest spending attributable to modifiable risk factors compared with other diseases.

Strength and limitations

This is the first paper in Singapore to quantify the cost of a high Na diet, where approximately 90 % of Singaporeans still exceeded the recommended daily consumption. The method presented in this paper is adaptable in different settings using nationally aggregated data and publicly available PAF values from GBD’s online results tools. This approach can be considered for various diet behaviours in a country and different diseases of interest. Similar to the published study in the USA(Reference Bolnick, Bui and Bulchis14), such methods can compare different risk factors to identify the main contributors of healthcare spending in a country. However, the estimates are directly comparable across countries only if the components of costs were measured similarly.

The main limitation of this study includes the underestimation of the costs. The cost estimate in this paper is conservative as it is solely dependent on three main components (1) healthcare cost from inpatient bills, (2) cost from hospitalisation-related absenteeism and (3) foregone wages due to premature mortality. Due to a lack of data, other cost components such as outpatient hospital bills, medication, primary healthcare costs that are incurred regularly and non-healthcare costs arising from caregiver costs, transportation and sick leaves at primary care facilities and outpatient care were not considered. Our model was also limited by the lack of income data and LFPR data for ages above 79. Although excluding these age groups would underestimate the cost, it will not substantially affect the results as population above age 79 had much lower income and LFPR. Additionally, due to the lack of data, our model also assumed that diseased individuals had similar income as healthy individuals, and both groups had the same likelihood to be in the labour force. In the estimation of PAF of diet in high Na, GBD considered systolic blood pressure as a full mediator for the effects of Na. This meant that excess Na consumption leads to an increase in systolic blood pressure, which, in turn, increases the risks of various diseases(Reference He, Li and MacGregor5). In Singapore, primary healthcare is the first line of medical attention an individual seeks(Reference Tay, Sule and Chew55). The exclusion of primary healthcare medical costs (i.e. drugs) for patients meant that our healthcare cost attributable to high Na diet was severely underestimated since long-term medication costs were excluded. For example, in Brazil, the treatment cost for drugs attributed to high Na diet was USA$110 million(Reference Nilson, Metlzer and Labonté53). This is equivalent to more than half of the total cost attributable to a high Na diet. Also, adopting a human capital approach assumes that a worker is indispensable and could lead to overestimation of productivity losses if unemployment rates in a country are high(Reference Jo13).

Conclusion

In conclusion, the cost society incurred due to a high Na diet in Singapore in 2019 was estimated to be at least USA$262 million (95 % UI 218, 359 million). These estimates, although conservative, provide vital insights to purposefully design public health interventions and promotion programmes for modifiable risk factors such as a high Na diet.

Acknowledgements

We would like to thank Dr Stefan Ma and his team from the Ministry of Health Singapore for the helpful discussions that contributed to this work.

The research was supported by the Singapore Ministry of Health, Health Services Research Grant (HSRGMH18may-0002). The funding source had no role in the design and conduct of the study; collection, management, analysis or interpretation of the data; preparation, review or approval of the manuscript; and decision to submit the manuscript for publication.

Concept and design: C. C. Acquisition of data: K. B. T. Analysis and interpretation of data: J. K., G. A. and C. C. Drafting of the manuscript: J. K., G. A. and C. C. Statistical analysis: J. K., G. A., K. B. T. and C. C. Provision of study materials or patients: K. B. T. Obtaining funding: C. C. Administrative, technical or logistic support: K. B. T. Supervision: C. C.

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Supplementary material

For supplementary material referred to in this article, please visit https://doi.org/10.1017/S0007114522001568

References

World Health Organization (2018) Noncommunicable Diseases Country Profiles 2018. https://apps.who.int/iris/handle/10665/274512 (accessed July 2021).Google Scholar
World Health Organisation (2020) Salt Reduction. https://www.who.int/news-room/fact-sheets/detail/salt-reduction#:∼:text=For%20adults%3A%20WHO%20recommends%20that,relative%20to%20those%20of%20adults (accessed July 2021).Google Scholar
WHO (2012) Guideline: Sodium Intake for Adults and Children. Geneva: World Health Organisation.Google Scholar
Afshin, A, Sur, PJ, Fay, KA, et al. (2019) Health effects of dietary risks in 195 countries, 1990–2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet 393, 19581972.CrossRefGoogle Scholar
He, FJ, Li, J & MacGregor, GA (2013) Effect of longer-term modest salt reduction on blood pressure. Cochrane Database Syst Rev 346, f1325.Google ScholarPubMed
Mozaffarian, D, Fahimi, S, Singh, GM, et al. (2014) Global sodium consumption and death from cardiovascular causes. N Engl J Med 371, 624634.CrossRefGoogle ScholarPubMed
Tsugane, S, Sasazuki, S, Kobayashi, M, et al. (2004) Salt and salted food intake and subsequent risk of gastric cancer among middle-aged Japanese men and women. Br J Cancer 90, 128134.CrossRefGoogle ScholarPubMed
Wang, X-Q, Terry, PD & Yan, H (2009) Review of salt consumption and stomach cancer risk: epidemiological and biological evidence. World J Gastroenterol: WJG 15, 2204.CrossRefGoogle ScholarPubMed
He, FJ, Tan, M, Ma, Y, et al. (2020) Salt reduction to prevent hypertension and cardiovascular disease: JACC state-of-the-art review. J Am Coll Cardiol 75, 632647.CrossRefGoogle ScholarPubMed
Elliott, P, Stamler, J, Nichols, R, et al. (1996) Intersalt revisited: further analyses of 24 h sodium excretion and blood pressure within and across populations. BMJ 312, 12491253.CrossRefGoogle Scholar
Gakidou, E, Afshin, A, Abajobir, AA, et al. (2017) Global, regional, and national comparative risk assessment of 84 behavioural, environmental and occupational, and metabolic risks or clusters of risks, 1990–2016: a systematic analysis for the Global Burden of Disease Study 2016. Lancet 390, 13451422.CrossRefGoogle Scholar
Powles, J, Fahimi, S, Micha, R, et al. (2013) Global, regional and national sodium intakes in 1990 and 2010: a systematic analysis of 24 h urinary sodium excretion and dietary surveys worldwide. BMJ Open 3, e003733.CrossRefGoogle ScholarPubMed
Jo, C (2014) Cost-of-illness studies: concepts, scopes, and methods. Clin Mol Hepatol 20, 327.CrossRefGoogle ScholarPubMed
Bolnick, HJ, Bui, AL, Bulchis, A, et al. (2020) Health-care spending attributable to modifiable risk factors in the USA: an economic attribution analysis. Lancet Public Health 5, e525e535.CrossRefGoogle ScholarPubMed
Ding, D, Lawson, KD, Kolbe-Alexander, TL, et al. (2016) The economic burden of physical inactivity: a global analysis of major non-communicable diseases. Lancet 388, 13111324.CrossRefGoogle ScholarPubMed
Cher, BP, Chen, C & Yoong, J (2017) Prevalence-based, disease-specific estimate of the social cost of smoking in Singapore. BMJ Open 7, e014377.CrossRefGoogle ScholarPubMed
Health Promotion Board (2011) HPB Declares War on Salt: Singapore Residents Exceed Daily Recommended Salt Consumption by 60 %. https://www.hpb.gov.sg/article/hpb-declares-war-on-salt-singapore-residents-exceed-daily-recommended-salt-consumption-by-60 (accessed July 2021).Google Scholar
Singapore HH (2022) Make a Healthier Choice Today! https://www.healthhub.sg/live-healthy/211/make_healthier_choice%20( (accessed July 2021).Google Scholar
Health Promotion Board (2018) National Nutrition Survey 2018 Shows Gradual Improvements in Singaporeans’ Dietary Habits. https://www.hpb.gov.sg/article/national-nutrition-survey-2018-shows-gradual-improvements-in-singaporeans-dietary-habits (accessed July 2021).Google Scholar
World Health Organization (2012) Guideline: Sodium Intake for Adults and Children. Geneva: World Health Organization.Google Scholar
Vandevijvere, S, De Keyzer, W, Chapelle, J-P, et al. (2010) Estimate of total salt intake in two regions of Belgium through analysis of sodium in 24-h urine samples. Eur J Clin Nutr 64, 12601265.CrossRefGoogle ScholarPubMed
Metrics IfH, Evaluation (2017) Global Burden of Disease Collaborative Network. Global Burden of Disease Study 2016 (GBD 2016) Results. Seattle: Institute for Health Metrics and Evaluation.Google Scholar
Ministry of Manpower Singapore (2019) Labour Force in Singapore 2019. Singapore: Ministry of Manpower.Google Scholar
Zhang, W, Bansback, N & Anis, AH (2011) Measuring and valuing productivity loss due to poor health: a critical review. Soc Sci Med 72, 185192.CrossRefGoogle ScholarPubMed
Singapore MoM (2021) Summary Table: Income. Singapore: Ministry of Manpower.Google Scholar
The World Bank (2021) Official Exchange Rate (LCU per US$, Period Average). https://data.worldbank.org/indicator/PA.NUS.FCRF (accessed July 2021).Google Scholar
Belgorodski, N, Greiner, M, Tolksdorf, K, et al. (2012) Fitting distributions to given data or known quantiles. R Package 2, 2.Google Scholar
Mikkilä, V, Räsänen, L, Raitakari, O, et al. (2005) Consistent dietary patterns identified from childhood to adulthood: the cardiovascular risk in Young Finns Study. Br J Nutr 93, 923931.CrossRefGoogle ScholarPubMed
Kaikkonen, JE, Mikkilä, V & Raitakari, OT (2014) Role of childhood food patterns on adult cardiovascular disease risk. Curr Atheroscler Rep 16, 443.CrossRefGoogle ScholarPubMed
Asaria, P, Chisholm, D, Mathers, C, et al. (2007) Chronic disease prevention: health effects and financial costs of strategies to reduce salt intake and control tobacco use. Lancet 370, 20442053.CrossRefGoogle ScholarPubMed
Collins, M, Mason, H, O’Flaherty, M, et al. (2014) An economic evaluation of salt reduction policies to reduce coronary heart disease in England: a policy modeling study. Value Health 17, 517524.CrossRefGoogle Scholar
Barton, P, Andronis, L, Briggs, A, et al. (2011) Effectiveness and cost effectiveness of cardiovascular disease prevention in whole populations: modelling study. BMJ 343, d4044.CrossRefGoogle ScholarPubMed
Pearson-Stuttard, J, Kypridemos, C, Collins, B, et al. (2018) Estimating the health and economic effects of the proposed US Food and Drug Administration voluntary sodium reformulation: microsimulation cost-effectiveness analysis. PLoS Med 15, e1002551.CrossRefGoogle ScholarPubMed
Nghiem, N, Blakely, T, Cobiac, LJ, et al. (2015) Health and economic impacts of eight different dietary salt reduction interventions. PLoS One 10, e0123915.CrossRefGoogle ScholarPubMed
Martikainen, J, Soini, E, Laaksonen, D, et al. (2011) Health economic consequences of reducing salt intake and replacing saturated fat with polyunsaturated fat in the adult Finnish population: estimates based on the FINRISK and FINDIET studies. Eur J Clin Nutr 65, 11481155.CrossRefGoogle ScholarPubMed
Webb, M, Fahimi, S, Singh, GM, et al. (2017) Cost effectiveness of a government supported policy strategy to decrease sodium intake: global analysis across 183 nations. BMJ 356.Google ScholarPubMed
Tan, KW, Quaye, SED, Koo, JR, et al. (2021) Assessing the impact of salt reduction initiatives on the chronic disease burden of Singapore. Nutrients 13, 1171.CrossRefGoogle ScholarPubMed
Cobiac, LJ, Veerman, L & Vos, T (2013) The role of cost-effectiveness analysis in developing nutrition policy. Annu Rev Nutr 33, 373393.CrossRefGoogle ScholarPubMed
Bibbins-Domingo, K, Chertow, GM, Coxson, PG, et al. (2010) Projected effect of dietary salt reductions on future cardiovascular disease. N Engl J Med 362, 590599.CrossRefGoogle ScholarPubMed
Smith-Spangler, CM, Juusola, JL, Enns, EA, et al. (2010) Population strategies to decrease sodium intake and the burden of cardiovascular disease: a cost-effectiveness analysis. Ann Intern Med 152, 481487.CrossRefGoogle ScholarPubMed
Owen, L, Morgan, A, Fischer, A, et al. (2012) The cost-effectiveness of public health interventions. J Public Health 34, 3745.CrossRefGoogle ScholarPubMed
Wang, G & Labarthe, D (2011) The cost-effectiveness of interventions designed to reduce sodium intake. J Hypertens 29, 16931699.CrossRefGoogle ScholarPubMed
Ghimire, K, Mishra, SR, Satheesh, G, et al. (2021) Salt intake and salt-reduction strategies in South Asia: from evidence to action. J Clin Hypertens 23, 18151829.CrossRefGoogle ScholarPubMed
Mohan, S, Prabhakaran, D & Krishnan, A (2013) Promoting populationwide salt reduction in the South-East Asia Region: current status and future directions. Reg Health Forum 17, 73.Google Scholar
Institute for Health Metrics and Evaluation (2022) GBD Results Tool. https://ghdx.healthdata.org/gbd-results-tool?params=gbd-api-2019-permalink/6979cd1c9f39071b8d8c39828417422a (accessed April 2022).Google Scholar
Anand, SS, Hawkes, C, De Souza, RJ, et al. (2015) Food consumption and its impact on cardiovascular disease: importance of solutions focused on the globalized food system: a report from the workshop convened by the World Heart Federation. J Am Coll Cardiol 66, 15901614.CrossRefGoogle ScholarPubMed
Brown, GW, Yamey, G & Wamala, S (2014) The Handbook of Global Health Policy. Hoboken, NJ: John Wiley & Sons.CrossRefGoogle Scholar
Tan, SB & Arcaya, M (2020) Where we eat is who we are: a survey of food-related travel patterns to Singapore’s hawker centers, food courts and coffee shops. Int J Behav Nutr Physical Act 17, 114.CrossRefGoogle ScholarPubMed
Health Promotion Board Singapore (2022) Healthier Ingredient Development Scheme. https://www.hpb.gov.sg/healthy-living/food-beverage/healthier-ingredient-schemes/about-the-healthier-ingredient-development-scheme (accessed April 2022).Google Scholar
Epidemiology & Disease Control Division MoH, Singapore (2019) The Burden of Disease in Singapore, 1990–2017: an Overview of the Global Burden of Disease Study 2017 Results. Seattle, WA: IHME Google Scholar
Chen, C, Lim, JT, Chia, NC, et al. (2019) The long-term impact of functional disability on hospitalization spending in Singapore. J Econ Ageing 14, 100193.CrossRefGoogle ScholarPubMed
Nilson, EAF, Da Silva, EN & Jaime, PC (2020) Developing and applying a costing tool for hypertension and related cardiovascular disease: attributable costs to salt/sodium consumption. J Clin Hypertens 22, 642648.CrossRefGoogle ScholarPubMed
Nilson, EAF, Metlzer, AB, Labonté, M-E, et al. (2020) Modelling the effect of compliance with WHO salt recommendations on cardiovascular disease mortality and costs in Brazil. PLoS One 15, e0235514.CrossRefGoogle ScholarPubMed
The World Bank (2022) GDP (Current US$) World Bank National Accounts Data, and OECD National Accounts Data Files. https://data.worldbank.org/indicator/NY.GDP.MKTP.CD?locations=1W (accessed July 2021).Google Scholar
Tay, JC, Sule, AA, Chew, E, et al. (2018) Ministry of health clinical practice guidelines: hypertension. Singapore Med J 59, 1727.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Cost estimation formula

Figure 1

Table 2. Overall cost of diet high in Na (Odds ratios and 95 % uncertainty intervals)

Figure 2

Table 3. Direct healthcare cost and disease breakdowns (Odds ratios and 95 % uncertainty intervals)

Figure 3

Table 4. Total cost and hospitalisation days for age groups active in labour force – 20–79 (Odds ratios and 95 % uncertainty intervals)

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