Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-28T14:24:35.154Z Has data issue: false hasContentIssue false

Population-level salt intake in the WHO European Region in 2022: a systematic review

Published online by Cambridge University Press:  20 October 2022

Edwin Jit Leung Kwong
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation Melbourne School of Population and Global Health, University of Melbourne, Melbourne, VIC, Australia
Stephen Whiting
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation
Anne Charlotte Bunge
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation Stockholm Resilience Centre, Stockholm University, Stockholm, Sweden
Yana Leven
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation
Joao Breda
Affiliation:
World Health Organization Regional Office for Europe, Copenhagen, Denmark
Ivo Rakovac
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation
Francesco Paolo Cappuccio
Affiliation:
University of Warwick, WHO Collaborating Centre for Nutrition, Warwick Medical School, Coventry, UK
Kremlin Wickramasinghe*
Affiliation:
World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases, 9 Leontyevsky Pereulok, Moscow 125009, Russian Federation
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

The WHO recommends that adults consume less than 5 g of salt per day to reduce the risk of CVD. This study aims to examine the average population daily salt intake in the fifty-three Member States of the WHO European Region.

Design:

A systematic review was conducted to examine the most up-to-date salt intake data for adults published between 2000 and 2022. Data were obtained from peer-reviewed and grey literature, WHO surveys and studies, as well as from national and global experts.

Setting:

The fifty-three Member States of the WHO European Region.

Participants:

People aged 12 years or more.

Results:

We identified fifty studies published between 2010 and 2021. Most countries in the WHO European Region (n 52, 98 %) reported salt intake above WHO recommended maximum levels. In almost all countries (n 52, 98 %), men consume more salt than women, ranging between 5·39 and 18·51 g for men and 4·27 and 16·14 g for women. Generally, Western and Northern European countries have the lowest average salt intake, whilst Eastern European and Central Asian countries have the highest average. Forty-two percentage of the fifty-three countries (n 22) measured salt intake using 24 h urinary collection, considered the gold standard method.

Conclusions:

This study found that salt intakes in the WHO European Region are significantly above WHO recommended levels. Most Member States of the Region have conducted some form of population salt intake. However, methodologies to estimate salt intake are highly disparate and underestimations are very likely.

Type
Systematic Review
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

High saltFootnote 1 consumption is a major cause of hypertension (high blood pressure), which increases the risk of CVD such as stroke, myocardial infarction, heart and renal diseases(Reference Strazzullo, D’Elia and Kandala1). Modelling suggests that 3 million deaths and 70 million disability-adjusted life years globally are attributed to high Na intake(2). In the WHO European Region, CVD are the leading cause of death, premature mortality and disability(Reference Timmis, Townsend and Gale3,Reference Townsend, Kazakiewicz and Wright4) .

A dose–response relationship exists between the amount of salt consumed and both blood pressure and CVD(Reference Huang, Trieu and Yoshimura5Reference Filippini, Malavolti and Whelton7). Reductions in salt intake lead to reductions in systolic and diastolic blood pressure, in female and male adults, across ethnic groups and for both hypertensive and normotensive populations(Reference He, Li and MacGregor8Reference Joffres, Campbell and Manns10). Therefore, population-level salt reduction is recommended as it is one of the most cost-effective measures for reducing the non-communicable diseases (NCD) burden and improving population health, by lowering the incidence of CVD, including strokes(11). This is especially important during the COVID-19 pandemic, as modelling has suggested that one in five people worldwide have increased risk of severe COVID-19 if infected, due to underlying conditions such as CVD(Reference Clark, Jit and Warren-Gash12).

Salt intake is also directly associated with BMI and the prevalence of overweight and obesity, which further amplifies the significance of promoting reduction in salt consumption as a means to address both the NCD and COVID-19 pandemics(Reference Zhou, Stamler and Chan13). Therefore, NCD prevention, and more specifically population-wide salt reduction, should be a component of cities’ and countries’ COVID-19 recovery strategies, in order for societies to become healthier, more resilient and prepared for future pandemics(Reference Demaio and Kwong14,15) .

Salt reduction has been identified as a WHO Best Buy for the control and prevention of NCD in order to achieve Sustainable Development Goal target 3.4 to ‘reduce by one third premature mortality from non-communicable diseases’(16). Therefore, the WHO recommends that adults consume no more than 5 g of salt (approximately 2 g of Na)/d to reduce the risk of CVD(17). Furthermore, as a part of the WHO Global Action Plan to reduce the burden of NCD, in 2013 the World Health Assembly agreed to a global target of a 30 % reduction in population salt intake by 2025, through the implementation and scaling up of comprehensive salt reduction strategies(18).

Previous estimates indicate that salt intake around the world is nearly twice the WHO recommended limit, and whilst Member States of the WHO European Region have demonstrated significant leadership and progress in efforts to reduce salt consumption, salt intake across the Region appears to be far above the recommended level(19Reference Millett, Laverty and Stylianou24). A unified source of data on the population salt intake of every country in the Region can provide sound evidence to guide the development and monitoring of salt reduction policies. This study aims to examine the most up-to-date population salt intake data in the fifty-three Member States of the WHO European Region, providing a comprehensive overview of the existing data, highlighting gaps and issues in the evidence base and methodologies used.

Methods

We conducted a systematic review following the preferred reporting items for systematic reviews and meta-analyses (PRISMA) reporting guidelines(Reference Page, McKenzie and Bossuyt25); a protocol had not been published a priori, nor was this review registered.

Search strategy

We conducted a systematic search in the electronic databases MEDLINE, Scopus and Web of Science in February 2022 for peer-reviewed articles published between 1 January 2000 and 31 January 2022. Search strings were devised to reflect population salt intake measurements and the respective countries of the WHO European Region. Two authors (EJLK and ACB) performed the abstract and full-text screening independently, using the open-access online tool CADIMA(Reference Kohl, McIntosh and Unger26), and resolved any contradictory assessments. Data were also acquired from surveys conducted by WHO, such as the questionnaire circulated amongst members of the European Salt Action Network (ESAN), as well as the NCD Country Capacity Survey, both conducted in 2019 by the WHO Europe NCD Office. Further data were obtained from studies conducted by WHO and from national surveys via programme leaders in national institutes and health ministries. When necessary, information was verified with national experts, and global experts in salt reduction reviewed all results. A detailed outline of the search strategy is provided in online supplementary material, Supplemental Appendix 1.

Inclusion/exclusion criteria

As the main objective of this study was to identify the best available and up-to-date data on salt consumption in the fifty-three Member States of the WHO European Region, the studies were assessed against several criteria. Overall, we established the studies’ reliability and validity with the following criteria: method of measurement, sample population characteristics, year of the study and sample size. Twenty-four hour urinary collection is considered the gold standard in assessing population Na intake(Reference Campbell, He and Tan27). Other methods (biomarkers in spot urine collections, dietary surveys) are either flawed(Reference Campbell, He and Cappuccio28Reference Campbell, Whelton and Orias31) or grossly inaccurate(Reference McLean, Farmer and Nettleton32,Reference McLean, Farmer and Nettleton33) . Hence, we prioritised inclusion of studies that utilised 24 h urinary collection. However, in countries where 24 h urinary collection was not used, we selected studies using other methods.

We conducted a quality assessment of the measurement methods applied in the included studies, using the grading scale developed by Powles and colleagues(Reference Powles, Fahimi and Micha34), with slight modifications to reflect the inclusion of spot urine collection as a method of salt intake measurement for this paper. There are nine levels to this grading scale, with nine being the highest possible score, reflecting the best evidence (detailed in online supplementary material, Supplemental Appendix 2). We used this quality assessment to prioritise inclusion of studies that did not use 24 h urinary collection, where studies with a higher score were selected. Where possible, studies which have a representative population sample, have larger sample sizes or are more recent in time are also prioritised.

We included only studies published since 2000 and limited inclusion only to countries in the WHO European Region (n 53). No language limits were imposed. In the case where there are multiple sources for one country, only one study deemed to be the most accurate and reliable estimation of the population average salt intake was included. We excluded studies that did not report salt or Na intake of an adult populationFootnote 2 .

Data extraction

The available data were collected from reports by EJLK and categorised under the following headings.

  1. 1. Country of study.

  2. 2. Mean salt intake in grams per day, with separate headings for men and women if sex-disaggregated data were reported.

  3. 3. Sample size, with separate headings for men and women if sex-disaggregated data were reported..

  4. 4. SD of mean salt intake.

  5. 5. Age range of participants.

  6. 6. Year of data collection.

  7. 7. Method of measurement.

If Na intake was reported, it was converted to salt intake with the conversion of 1 g Na = 2·542 g salt, which is the ratio of the molecular weight of sodium chloride (58·44) to the molecular weight of Na (22·99)(35,36) . If Na intake was reported in mmol/d, it was converted to mg/d with the conversion of 1 mmol Na = 23 mg Na, as the molar mass of Na is 22·99 g/mol(36).

Statistical analysis

Results are reported as means, and SD or 95 % CI. Weighted means and SD (based on sample sizes and CI) were calculated if not provided. Means for the total population, if not provided, were calculated by weighting the male and female means according to the national sex ratio in the closest year to the year of data collection, and SD for the total population were calculated by weighting the male and female SD equally. All calculations were performed using Microsoft Excel 365 version 16.52. If the sample size is small (n < 100), a t-distribution was used to calculate SD from the CI, instead of a standard normal distribution. Forest plots, stratified by methods of assessment of salt intake, were also produced for the total population, as well as for males and females separately. The figures in this study were produced in R version 4.0.3, QGIS version 3.16 and Microsoft Excel 365 version 16.52.

Results

We obtained data for the population mean daily salt intake for fifty of the fifty-three Member States of the WHO European Region. A total of 3235 records were retrieved from the initial search in peer-reviewed literature databases, of which 119 were assessed against the eligibility criteria at the full-text screening stage. This revealed fifteen eligible studies from peer-reviewed literature, which were then supplemented with grey literature (n 35), consisting of unpublished data obtained from national representatives and experts (n 8) and data from both WHO and national reports (n 27). The PRISMA flow diagram (Fig. 1) provides a detailed overview of the study and data selection conducted in this review. For the three Member States which did not have data available (Kyrgyzstan, Monaco, San Marino), they were imputed with proxy data from the closest neighbouring country with a similar ethnicity and cuisine.

Fig. 1 Preferred reporting items for systematic reviews and meta-analyses (PRISMA) flow diagram. Databases searched include MEDLINE, Scopus and Web of Science for peer-reviewed articles published between 1 January 2000 and 31 January 2022

Study characteristics

The characteristics of the fifty studies identified are described in further detail in online supplementary material, Supplemental Appendix 2, with the year of data collection, method of measurement, sample size, age range of sample, sample population characteristics, sample representativeness and a quality assessment of each study’s measurement method included.

In summary, the fifty studies included in this paper were published between 2010 and 2021, and the dates of data collection were between 2007 and 2019. The characteristics of the sampled populations varied greatly, with considerable differences in sample sizes, ranging from a cohort of 113 from Ukraine to 6962 in Germany(37,Reference Johner, Thamm and Schmitz38) . Notable differences were observed in sample characteristics, from cohorts of undergraduate students in Albania(Reference Llanaj, Ádány and Lachat39) and Serbia(Reference Dorobantu, Tautu and Dimulescu40) to nationally representative samples in thirty studies. A higher proportion of women than men was also observed in most studies (n 40). The majority of studies included a wide age range of participants, with the exceptions of the undergraduate student cohorts, and the cohorts in the Belgian and Czech subsamples from the European Food Consumption Validation (EFCOVAL) project(Reference Llanaj, Ádány and Lachat39,Reference Jovičić-Bata, Grujičić and Rađen41Reference De Keyzer, Dofková and Lillegaard43) .

Mean salt intake across the WHO European Region

Data on mean salt intake were available in fifty out of fifty-three countries in the WHO European Region. Proxy data from neighbouring countries (Kazakhstan, France and Italy) were used to approximate three countries’ data (Kyrgyzstan, Monaco and San Marino), which did not have their own. Therefore, it was estimated that fifty-two out of fifty-three countries within the WHO European Region have a daily mean adult salt intake above the WHO recommended level of 5 g/d (Table 1). Salt intakes range between 5·39–18·51 g for men and 4·27–16·14 g for women. Forty-six countries have a population salt intake of at least 7·5 g/d, exceeding the recommended level by at least 50 %, and twenty-three countries have a population salt intake of at least 10 g/d, which is double the recommended level. Forty-seven out of fifty-three countries reported sex-specific data for mean adult salt intake. In almost every country, salt intake for men was higher than salt intake for women, with more than half of the countries (n 34) reporting at least a 2 g/d difference. Figure 2 shows the mean population salt intake of the Region stratified into quintiles, which are further detailed in online supplementary material, Supplemental Appendix 3.

Table 1 Daily mean salt intake in adults

Fig. 2 Map of mean population salt intake in the WHO European Region (2022). Displayed are the Member States of the WHO European Region divided into quintiles, based on their mean population salt intake. The detailed characteristics of the included studies can be found in online supplementary material, Supplemental Appendix 2

Estimation methods to measure mean population salt intake

Figure 3 shows the various methods of estimating salt intake data across the Member States of the WHO European Region. There is great variation, with nine different methods identified. Twenty-four hour urinary collection was the most common method (n 22), as we prioritised the inclusion of studies which used this gold standard method. Spot urine collection (n 10) and 24 h dietary recalls (n 8) were the next most common estimation methods. Andorra, Denmark, Finland and Latvia reported using a mixture of methods to estimate salt intake (n 4)(44Reference Joffe, Ozoliņš and Šantare47). Luxembourg was the only country to use only FFQ to estimate salt intake across the population (n 1), and only Sweden used dietary records to estimate salt intake (n 1)(Reference Amcoff, Edberg and Enghardt Barbieri48,Reference Alkerwi, Pastore and Sauvageot49) . Household budget surveys were used to estimate salt intake in North Macedonia and Poland (n 2)(50). We were unable to determine the estimation method for Cyprus and Slovakia (n 2), and primary data were not available for Kyrgyzstan, Monaco and San Marino (n 3).

Fig. 3 The different methods used to estimate salt intake data in the WHO European Region

In Fig. 4, we show the studies included, ranked by quality of assessment method, based on the collection method used. Further details of the studies and the quality assessments can be found in online supplementary material, Supplemental Appendix 2.

Fig. 4 Quality of estimation method used for measuring salt intake for all studies included

Figures 5 and 6 report forest plots of average salt consumption (and 95 % CI) by country and method of assessment. Whilst it is not possible to compare studies, there is a gradient, consistent in both men and women, in the direction of higher average estimates in countries using 24 h urinary collection compared with other methods. These trends would be expected from the evidence of regular underestimation of salt consumption by dietary methods (not allowing for discretionary sources of salt)(Reference McLean, Farmer and Nettleton32,Reference McLean, Farmer and Nettleton33) and from a systematic bias when using spot urine collections, overestimating at lower level of salt consumption and underestimating at higher level(Reference Clark, Jit and Warren-Gash12,Reference Cogswell, Wang and Chen51Reference Swanepoel, Schutte and Cockeran55) .

Fig. 5 Forest plots, with estimates of the 95 % CI (except for a few countries which have provided these data), for the total population, split by estimation method of salt intake – 24 h urinary collection, spot urine collection and dietary assessments and all other methods

Fig. 6 Forest plots, with estimates of the 95 % CI (except for a few countries which have provided these data), for male and female populations, split by estimation method of salt intake – 24 h urinary collection, spot urine collection and dietary assessments and all other methods

Discussion

This review included fifty studies in the WHO European Region that reported Na or salt intakes amongst adult populations. Overall, we observed that the mean population salt intakes across the WHO European Region almost universally exceed the WHO recommended level of 5 g/d by significant margins. The level of salt intake across the fifty-three countries varied substantially, with a distinct East-West gradient in the Region, where salt intakes in Eastern European and Central Asian countries were higher than in Western and Northern European countries, highlighting the need for greater salt reduction efforts especially in those Member States. There were considerable differences observed between sexes, as men in thirty-four countries had a higher salt intake than women by over 2 g, and in eleven countries the difference was over 3 g. However, this sex difference is expected since salt intake is measured as total intake, not adjusted for energetic intake or body mass.

It is likely that the data in the lowest quintile (online supplementary material, Supplemental Appendix 3) are confounded by underestimations, as none of these studies (n 12) estimated salt intake with 24 h urinary collection, and dietary assessments in particular are likely to underestimate true salt intake(Reference McLean, Farmer and Nettleton32,Reference McLean, Farmer and Nettleton33) . For example, this is likely the case for Malta, which used dietary recalls to estimate salt intake. However, dietary recalls are unable to assess the amount of discretionary salt added to cooking and at the table. Therefore, it is highly possible that none of the fifty-three Member States of the WHO European Region meets the WHO recommended level of 5 g/d of mean population salt intake, as the one survey that reported figures below the recommended level is likely to have underestimated the true salt intake.

A broad evidence base was incorporated in this study by being flexible on the study types and methodologies included, as it was not limited to only published literature but also included grey literature and unpublished national and WHO reports. Therefore, we were able to demonstrate the state of population monitoring of salt intake across the WHO European Region, by both providing as complete a data set as possible and highlighting the many differing methodologies utilised across the fifty-three Member States.

Despite the fact that none of the Member States of WHO European Region is likely to have met the WHO recommended level of population salt intake, it is encouraging to see that fifty out of fifty-three countries were able to report its population salt intake in some form, which is an indication of the progress and success of scaling up measuring efforts, largely driven by the coordinated actions between WHO European Region, its Member States and the ESAN(23). Only four countries had small sex-disaggregated sample sizes (n < 100), which is reassuring in terms of the included studies’ overall statistical precision and reliability. Finally, it is promising that the gold standard method of 24 h urinary collection was commonly used in the WHO European Region, with twenty-two out of fifty-three countries utilising this method to assess salt intake. Other methods not only tend to underestimate average population salt intake, but they will be less likely to detect small yet meaningful changes in average population salt consumption resulting from policy actions(Reference Swanepoel, Schutte and Cockeran55Reference Lucko, Doktorchik and Woodward59), and risk deterring further action to achieve the WHO target of 5 g/d of salt intake(Reference Cappuccio, Beer and Strazzullo58).

Whilst a key strength of this study is that a broad range of research with differing methodologies was incorporated, a significant limitation is that a majority of the included studies (n 28) utilised collection methods other than 24 h urinary collection, such as spot urine collection, dietary recall, food FFQ, dietary records, household budget surveys and also a mixture of some of these methods, which underestimate population-level salt intake(Reference McLean, Farmer and Nettleton32,Reference Huang, Crino and Wu60,Reference McLean, Cameron and Butcher61) . For example, Freedman et al. found that 24 h dietary recalls underestimate Na intake by approximately 5–10 % and FFQ underestimate by approximately 30 %(Reference Freedman, Commins and Moler62). Hence, it is likely that the values reported from many of these studies not utilising 24 h urinary collection do not accurately reflect the actual salt intake of those countries’ populations. One study also used the Kawasaki formula to convert spot urine data to an estimate of 24 h urinary Na excretions(Reference Dorobantu, Tautu and Dimulescu40). However, this method has been proven to be inaccurate and systematically biased, with overestimations at lower levels of Na and underestimations at higher levels of Na, and a potential to skew the linear relationship demonstrated between levels of Na intake and mortality(Reference He, Campbell and Ma63,Reference Polonia, Lobo and Martins64) . Additionally, according to the meta-analysis conducted by Lucko et al., approximately 93 % of dietary Na is excreted in urine, meaning that Na intake values estimated through 24 h urine collections should ideally be adjusted to most accurately reflect the true Na intake(Reference Lucko, Doktorchik and Woodward59). Furthermore, since there is no guarantee of the completeness of urine sample collections, validation markers such as creatinine ratio/total urinary creatinine can be useful in verifying the quality of the data collected, as can stringent standard operating procedures for the training of field workers and for quality control(Reference D’Elia, Obreja and Ciobanu6567).

Overall, of the fifty studies of adult salt intake identified in this article, only eighteen were given the highest measurement quality assessment scores of 8 or 9. This reveals that studies applying high-quality measurements of salt intake in WHO European Region are still lacking.

As no standardised method for estimating Na or salt intake was used between the studies included, the population salt intake values reported across the WHO European Region are not entirely immediately comparable. In order to counteract some of this inconsistency, we have ensured that where necessary, the same conversion factor to convert Na to salt was used across the studies included. In addition, not all data reported in the studies included were nationally representative, with 38 % of countries (n 20) either not providing information on the representativeness of their studies or did not conduct a nationally representative study. Some countries also had not conducted up-to-date monitoring of their salt intake, with some data being collected over 10 years ago, which suggests that some Member States in WHO European Region need to implement appropriate surveillance mechanisms more regularly for population salt intake.

Overall, the findings of this study indicate the need for Member States in the WHO European Region to conduct regular surveillance and monitoring of population salt intake to provide more up-to-date data. There is also still an overreliance on traditional nutritional surveys such as 24 h dietary recalls and FFQ to estimate salt intake. Further support, for example, by providing training on the use of WHO tools, such as the model protocol for measuring population salt intake using 24 h urinary data collections and implementation of STEPS surveys(68), should be prioritised to support Member States’ surveillance and monitoring efforts. The usage of the gold standard method of 24 h urinary collection should be strongly encouraged in studies designed to accurately measure population-level salt intake and monitor changes over time.

It is hoped that policymakers in the WHO European Region and beyond can utilise the findings of this study to obtain information on salt consumption from comparable settings, as well as to determine the next steps in the monitoring of population salt consumption and the planning of future salt reduction strategies. Currently, the evidence demonstrates that reducing dietary salt reduces blood pressure in a linear relationship for both normotensive and hypertensive populations, as well as incidences of CVD(Reference Strazzullo, D’Elia and Kandala1,Reference Huang, Trieu and Yoshimura5,Reference Filippini, Malavolti and Whelton7,Reference Aburto, Ziolkovska and Hooper9,Reference Joffres, Campbell and Manns10,Reference Stallings, Harrison and Oria69,Reference Poggio, Gutierrez and Matta70) . This means that reducing population-level salt intake is an important step in decreasing mortality and improving population health. Therefore, this study, used in conjunction with the recent systematic review by Santos et al. on salt reduction efforts around the world, can provide useful information to help countries move towards the goal of a 30 % relative reduction in salt intake by 2025 by ensuring the scale up and more effective implementation of salt reduction initiatives(18,Reference Santos, Tekle and Rosewarne71) .

Conclusion

Mean population salt intake in the WHO European Region is well above the WHO recommended level, with fifty-two out of fifty-three Member States exceeding it, and a strong likelihood of underestimation for the majority of studies included. However, it is encouraging to see that most Member States of the WHO European Region have conducted some form of population salt intake survey. To achieve the target level of salt intake recommended by the WHO, all Member States of the WHO European Region should scale up, or more effectively implement their salt reduction strategies, in accordance with the recommended interventions from the WHO Best Buys. In order to accomplish this, surveillance systems must be strengthened, and policy actions implemented across all sectors that can impact population salt intake. Future research, where practical, should utilise rigorous gold standard methods when collecting population salt intake data to ensure the highest degree of accuracy, comparability and validity.

Acknowledgements

Acknowledgements: The authors would like to acknowledge and thank the following experts for their assistance: Mr Josep Romagosa Massana, Dr Martin Krayer von Krauss, Dr Vesselka Duleva, Ms Eliza Markidou, Dr Amélie Schmitt, Prof Dr Thomas Remer, Dr Eszter Sarkadi Nagy, Ms Hólmfríður Þorgeirsdóttir, Prof Dr Ronit Endevelt, Ms Lesley Nitsan, Dr Kathy Trieu, Prof Dr Marius Miglinas, Dr Ala’a Al Kerwi, Dr Isabelle Ernens, Dr Daniel Cauchi, Dr Marieke Hendriksen, Dr Liesbeth Temme, Prof Dr Igor Spiroski, Prof Dr Haakon Meyer, Dr Jozef Suvada, Ms Zulfia Atadjanova, Dr Holly Rippin, Ms Natalia Fedkina and Ms Olga Zhiteneva. Authorship: E.J.L.K. and K.W. conceived and designed the study. E.J.L.K. and A.C.B. developed the search strategy and conducted peer-reviewed literature searches. E.J.L.K. conducted grey literature searches. E.J.L.K. and A.C.B. conducted study screening. Data charting, visualisation and analysis by E.J.L.K. with feedback by F.P.C. and S.W. I.R. provided statistical expertise and advice. Original draft written by E.J.L.K., reviewed and edited by A.C.B., F.P.C. and S.W. All authors read and approved the final manuscript. Ethics of human subject participation: Not applicable.

Financial support:

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conflict of interest:

The writing group takes sole responsibility for the content of this article, and the content of this article reflects the views of the authors only. E.J.L.K. is a consultant, and S.W., J.B., I.R. and KW are staff members of the WHO. F.P.C. is a technical advisor to the WHO and an unpaid member of Action on Salt and World Action on Salt & Health (WASH). The authors alone are responsible for the views expressed in this publication, and they do not necessarily represent the decisions or the stated policy of the WHO.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S136898002200218X

Footnotes

Disclaimer: This paper was published as part of a Supplement in the Journal of Public Health Nutrition, publication of which was supported by the World Health Organization European Office for the Prevention and Control of Noncommunicable Diseases. The papers included in this supplement were invited by the Guest Editors and have undergone the standard journal formal review process. They may be cited. The authors alone are responsible for the views expressed in this publication and they do not necessarily represent the views, decisions or policies of the institutions with which they are affiliated.

1 In this paper, salt is used to refer to different sources of Na salts (sodium chloride, sodium bicarbonate, monosodium glutamate, etc.), as Na is the chemical associated with risk. 5 g of sodium chloride (common salt) contains approximately 2 g (2000 mg) of Na.

2 There was considerable heterogeneity in both the definition of adult and the sampling age brackets across the studies included. For this study, persons 12 years and above were included, as three studies included populations below the age of 18 in a manner that made it challenging to disaggregate the data to only include persons 18 years and above.

3 Sample population includes persons 12 years and above.

4 Sample population includes persons 15 years and above.

5 Personal communication with Ms Eliza Markidou, Ministry of Health of the Republic of Cyprus. Unpublished study conducted in 2009 by the Cyprus Dietetic and Nutrition Association.

6 Personal communication with Dr Eszter Sarkadi Nagy, from the National Institute of Pharmacy and Nutrition, the successor of the National Institute for Food and Nutrition Science. Unpublished study conducted in 2010.

7 Proxy data used from Kazakhstan, due to lack of data in Kyrgyzstan.

8 Personal communication with Prof Marius Miglinas, Vilnius University. Unpublished study ‘NATRIJOD’, conducted between 2018 and 2020.

9 Supplemented by unpublished data, obtained from Dr Isabelle Ernens, Luxembourg Institute of Health.

10 Personal communication with Dr Daniel Cauchi, Ministry of Health, Malta. Unpublished study conducted between 2015 and 2017.

11 Proxy data used from France, due to lack of data in Monaco.

12 Calculations of the Department of Food and Nutrition Economics of Institute of Food and Nutrition, based on unpublished data from 2016, from the Department of Social Research and Living Conditions of the Central Statistical Office.

13 Proxy data used from Italy, due to lack of data in San Marino.

14 Personal communication with Dr Jozef Suvada, Ministry of Health, Slovak Republic.

References

Strazzullo, P, D’Elia, L, Kandala, N-B et al. (2009) Salt intake, stroke, and cardiovascular disease: meta-analysis of prospective studies. BMJ 339, b4567.CrossRefGoogle ScholarPubMed
GBD 2017 Diet Collaborators (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
Timmis, A, Townsend, N, Gale, CP et al. (2020) European society of cardiology: cardiovascular disease statistics 2019. Eur Heart J 41, 1285.10.1093/eurheartj/ehz859CrossRefGoogle Scholar
Townsend, N, Kazakiewicz, D, Wright, FL et al. (2022) Epidemiology of cardiovascular disease in Europe. Nat Rev Cardiol 19, 133143.CrossRefGoogle ScholarPubMed
Huang, L, Trieu, K, Yoshimura, S et al. (2020) Effect of dose and duration of reduction in dietary sodium on blood pressure levels: systematic review and meta-analysis of randomised trials. BMJ 368, m315.CrossRefGoogle ScholarPubMed
Wang, Y-J, Yeh, T-L, Shih, M-C et al. (2020) Dietary sodium intake and risk of cardiovascular disease: a systematic review and dose-response meta-analysis. Nutrients 12, 2934.CrossRefGoogle ScholarPubMed
Filippini, T, Malavolti, M, Whelton, PK et al. (2021) Blood pressure effects of sodium reduction: dose–response meta-analysis of experimental studies. Circulation 143, 15421567.CrossRefGoogle ScholarPubMed
He, FJ, Li, J & MacGregor, GA (2013) Effect of longer-term modest salt reduction on blood pressure. Cochrane Database Syst Rev, Issue 4, CD004937.Google ScholarPubMed
Aburto, NJ, Ziolkovska, A, Hooper, L et al. (2013) Effect of lower sodium intake on health: systematic review and meta-analyses. BMJ 346, f1326.CrossRefGoogle ScholarPubMed
Joffres, MR, Campbell, NRC, Manns, B et al. (2007) Estimate of the benefits of a population-based reduction in dietary sodium additives on hypertension and its related health care costs in Canada. Can J Cardiol 23, 437443.CrossRefGoogle ScholarPubMed
World Health Organization (2017) Tackling NCDs: ‘Best Buys’ and Other Recommended Interventions for the Prevention and Control of Noncommunicable Diseases. Geneva: World Health Organization.Google Scholar
Clark, A, Jit, M, Warren-Gash, C et al. (2020) Global, regional, and national estimates of the population at increased risk of severe COVID-19 due to underlying health conditions in 2020: a modelling study. Lancet Glob Health 8, e1003e1017.CrossRefGoogle ScholarPubMed
Zhou, L, Stamler, J, Chan, Q et al. (2019) Salt intake and prevalence of overweight/obesity in Japan, China, the United Kingdom, and the United States: the INTERMAP study. Am J Clin Nutr 110, 3440.CrossRefGoogle ScholarPubMed
Demaio, S & Kwong, E (2020) Slow-Motion Pandemic of Non-Communicable Diseases. MJA Insight+. https://insightplus.mja.com.au/2020/26/slow-motion-pandemic-of-non-communicable-diseases/ (accessed January 2022).Google Scholar
The Health Policy Partnership (2021) Out of the Ashes: Why Prioritising Non-Communicable Diseases is Central to Post-COVID-19 Recovery. London: HPP.Google Scholar
World Health Organization (2018) Saving Lives, Spending Less: A Strategic Response to Noncommunicable Diseases. Geneva: World Health Organization.Google Scholar
World Health Organization (2012) Guideline: Sodium Intake for Adults and Children. Geneva: World Health Organization.Google Scholar
World Health Organization (2017) Updated Appendix 3 of the WHO Global NCD Action Plan 2013–2020. Technical Annex (Version Dated 12 April 2017). Geneva: World Health Organization.Google Scholar
WHO Regional Office for Europe (2013) Mapping Salt Reduction Initiatives in the WHO European Region. Copenhagen: WHO Regional Office for Europe.Google Scholar
World Health Organization (2020) 11th Meeting of the WHO Action Network on Salt Reduction in the Population in the European Region (ESAN): Meeting Report. Bern, Switzerland, 7–8 May 2019. Copenhagen: WHO Regional Office for Europe.Google Scholar
Trieu, K, Neal, B, Hawkes, C et al. (2015) Salt reduction initiatives around the World – a systematic review of progress towards the global target. PLoS ONE 10, e0130247.CrossRefGoogle ScholarPubMed
He, FJ, Brinsden, HC & MacGregor, GA (2014) Salt reduction in the United Kingdom: a successful experiment in public health. J Hum Hypertens 28, 345352.CrossRefGoogle ScholarPubMed
World Health Organization (2020) Accelerating Salt Reduction in Europe: A Country Support Package to Reduce Population Salt Intake in the WHO European Region. Copenhagen: World Health Organization Regional Office for Europe.Google Scholar
Millett, C, Laverty, AA, Stylianou, N et al. (2012) Impacts of a national strategy to reduce population salt intake in England: serial cross sectional study. PLoS ONE 7, e29836.10.1371/journal.pone.0029836CrossRefGoogle ScholarPubMed
Page, MJ, McKenzie, JE, Bossuyt, PM et al. (2021) The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ 372, n71.CrossRefGoogle ScholarPubMed
Kohl, C, McIntosh, EJ, Unger, S et al. (2018) Online tools supporting the conduct and reporting of systematic reviews and systematic maps: a case study on CADIMA and review of existing tools. Environ Evid 7, 8.CrossRefGoogle Scholar
Campbell, NRC, He, FJ, Tan, M et al. (2019) The international consortium for quality research on dietary sodium/salt (TRUE) position statement on the use of 24-h, spot, and short duration (<24 h) timed urine collections to assess dietary sodium intake. J Clin Hypertens 21, 700709.CrossRefGoogle Scholar
Campbell, NRC, He, FJ, Cappuccio, FP et al. (2021) Dietary sodium ’controversy’—issues and potential solutions. Curr Nutr Rep 10, 188199.CrossRefGoogle ScholarPubMed
Campbell, NRC, He, FJ, McLean, RM et al. (2021) Dietary sodium and cardiovascular disease in China: concerns about the methods, conclusions, and evidence review. J Hypertens 39, 14661467.CrossRefGoogle Scholar
Cappuccio, FP, Campbell, NRC, He, FJ et al. (2022) Sodium and health: old myths and a controversy based on denial. Curr Nutr Rep 11, 172184.CrossRefGoogle Scholar
Campbell, NRC, Whelton, PK, Orias, M et al. (2022) 2022 World hypertension league, resolve to save lives and international society of hypertension dietary sodium (salt) global call to action. J Hum Hypertens. doi: 10.1038/s41371-022-00690-0.CrossRefGoogle ScholarPubMed
McLean, RM, Farmer, VL, Nettleton, A et al. (2017) Assessment of dietary sodium intake using a food frequency questionnaire and 24-h urinary sodium excretion: a systematic literature review. J Clin Hypertens 19, 12141230.CrossRefGoogle Scholar
McLean, RM, Farmer, VL, Nettleton, A et al. (2018) Twenty-Four-Hour diet recall and diet records compared with 24-h urinary excretion to predict an individual’s sodium consumption: a systematic review. J Clin Hypertens 20, 13601376.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
National Center for Biotechnology Information (2022) PubChem Compound Summary for CID 5234, Sodium Chloride. https://pubchem.ncbi.nlm.nih.gov/compound/Sodium-chloride (accessed January 2022).Google Scholar
National Center for Biotechnology Information (2022) PubChem Compound Summary for CID 5360545, Sodium. https://pubchem.ncbi.nlm.nih.gov/compound/Sodium (accessed January 2022).Google Scholar
WHO (2020) STEPS: Prevalence of Noncommunicable Disease Risk Factors in Ukraine 2019. Copenhagen: WHO Regional Office for Europe.Google Scholar
Johner, SA, Thamm, M, Schmitz, R et al. (2015) Current daily salt intake in Germany: biomarker-based analysis of the representative DEGS study. Eur J Nutr 54, 11091115.CrossRefGoogle ScholarPubMed
Llanaj, E, Ádány, R, Lachat, C et al. (2018) Examining food intake and eating out of home patterns among university students. PLoS ONE 13, e0197874.CrossRefGoogle ScholarPubMed
Dorobantu, M, Tautu, O-F, Dimulescu, D et al. (2018) Perspectives on hypertension’s prevalence, treatment and control in a high cardiovascular risk East European country: data from the SEPHAR III survey. J Hypertens 36, 690700.CrossRefGoogle Scholar
Jovičić-Bata, J, Grujičić, M, Rađen, S et al. (2016) Sodium intake and dietary sources of sodium in undergraduate students from Novi Sad, Serbia. Vojnosanit Pregl 73, 651656.CrossRefGoogle 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
De Keyzer, W, Dofková, M, Lillegaard, ITL et al. (2015) Reporting accuracy of population dietary sodium intake using duplicate 24 h dietary recalls and a salt questionnaire. Br J Nutr 113, 488497.CrossRefGoogle Scholar
Ministeri de Salut (2018) Enquesta Nutricional d’Andorra 2017–2018. Avaluació de L’estat Nutricional de la Població d’Andorra 2017–2018 i Avaluació de les Tendències 2005–2018 (Nutrition Survey of Andorra 2017–2018. Assessment of the Nutritional Status of the Population of Andorra 2017–2018 and Assessment of the Trends 2005–2018). Andorra la Vella: Govern d’Andorra.Google Scholar
Danmarks Tekniske Universitet Fødevareinstituttet Afdeling for Ernæring (Technical University of Denmark National Food Institute, Department of Nutrition and Dietary Habits) (2015) Danskernes Kostvaner 2011–2013: Hovedresultater (Dietary Habits in Denmark 2011–2013: Main Results). Søborg: Danmarks Tekniske Universitet Fødevareinstituttet Afdeling for Ernæring.Google Scholar
Terveyden ja Hyvinvoinnin Laitos (National Institute for Health and Welfare) (2018) Ravitsemus Suomessa – FinRavinto 2017 -Tutkimus (Nutrition in Finland – The National FinDiet 2017 Survey). Helsinki: Terveyden ja Hyvinvoinnin Laitos (National Institute for Health and Welfare).Google Scholar
Joffe, R, Ozoliņš, G, Šantare, D et al. (2009) Latvijas Iedzīvotāju Visaptverošais Pārtikas Patēriņa Pētījums, 2007–2009 (The National Food Consumption Survey of Latvia, 2007–2009). Rīga: Nacionālais Diagnostikas Centers & Pārtikas un Veterinārā Dienesta Pārtikas Centers.Google Scholar
Amcoff, E, Edberg, A, Enghardt Barbieri, H et al. (2012) Riksmaten – Vuxna 2010–2011: Livsmedels- Och Näringsintag Bland Vuxna I Sverige (Riksmaten – Adults 2010–2011: Food and Nutritional Intake among Adults in Sweden). Uppsala: Livsmedelsverket.Google Scholar
Alkerwi, A, Pastore, J, Sauvageot, N et al. (2019) Challenges and benefits of integrating diverse sampling strategies in the observation of cardiovascular risk factors (ORISCAV-LUX 2) study. BMC Med Res Methodol 19, 27.CrossRefGoogle Scholar
State Statistical Office of the Republic of Macedonia (2019) Household Budget Survey 2019. Skopje: State Statistical Office of the Republic of Macedonia.Google Scholar
Cogswell, ME, Wang, C-Y, Chen, T-C et al. (2013) Validity of predictive equations for 24-h urinary sodium excretion in adults aged 18–39 years. Am J Clin Nutr 98, 15021513.CrossRefGoogle Scholar
Ji, C, Miller, MA, Venezia, A et al. (2014) Comparisons of spot v. 24-h urine samples for estimating population salt intake: validation study in two independent samples of adults in Britain and Italy. Nutr Metab Cardiovasc Dis 24, 140147.CrossRefGoogle ScholarPubMed
Mente, A, O’Donnell, MJ, Dagenais, G et al. (2014) Validation and comparison of three formulae to estimate sodium and potassium excretion from a single morning fasting urine compared to 24-h measures in 11 countries. J Hypertens 32, 10051015.CrossRefGoogle ScholarPubMed
Petersen, KS, Wu, JHY, Webster, J et al. (2017) Estimating mean change in population salt intake using spot urine samples. Int J Epidemiol 46, dyw239.Google ScholarPubMed
Swanepoel, B, Schutte, AE, Cockeran, M et al. (2018) Monitoring the South African population’s salt intake: spot urine v. 24 h urine. Public Health Nutr 21, 480488.CrossRefGoogle Scholar
Cappuccio, FP & D’Elia, L (2018) Evaluating population salt reduction programmes worldwide: the risk of cutting corners! Public Health Nutr 21, 21612163.CrossRefGoogle ScholarPubMed
Huang, L, Woodward, M, Stepien, S et al. (2018) Spot urine samples compared with 24-h urine samples for estimating changes in urinary sodium and potassium excretion in the China salt substitute and stroke study. Int J Epidemiol 47, 18111820.CrossRefGoogle ScholarPubMed
Cappuccio, FP, Beer, M & Strazzullo, P (2019) Population dietary salt reduction and the risk of cardiovascular disease. A scientific statement from the European salt action network. Nutr Metab Cardiovasc Dis 29, 107114.CrossRefGoogle Scholar
Lucko, AM, Doktorchik, C, Woodward, M et al. (2018) Percentage of ingested sodium excreted in 24-h urine collections: a systematic review and meta-analysis. J Clin Hypertens 20, 12201229.CrossRefGoogle Scholar
Huang, L, Crino, M, Wu, JH et al. (2016) Mean population salt intake estimated from 24-h urine samples and spot urine samples: a systematic review and meta-analysis. Int J Epidemiol 45, 239250.CrossRefGoogle ScholarPubMed
McLean, R, Cameron, C, Butcher, E et al. (2019) Comparison of 24-h urine and 24-h diet recall for estimating dietary sodium intake in populations: a systematic review and meta-analysis. J Clin Hypertens 21, 17531762.CrossRefGoogle Scholar
Freedman, LS, Commins, JM, Moler, JE et al. (2015) Pooled results from 5 validation studies of dietary self-report instruments using recovery biomarkers for potassium and sodium intake. Am J Epidemiol 181, 473487.CrossRefGoogle ScholarPubMed
He, FJ, Campbell, NRC, Ma, Y et al. (2018) Errors in estimating usual sodium intake by the Kawasaki formula alter its relationship with mortality: implications for public health. Int J Epidemiol 47, 17841795.CrossRefGoogle ScholarPubMed
Polonia, J, Lobo, MF, Martins, L et al. (2017) Estimation of populational 24-h urinary sodium and potassium excretion from spot urine samples: evaluation of four formulas in a large national representative population. J Hypertens 35, 477486.CrossRefGoogle Scholar
D’Elia, L, Obreja, G, Ciobanu, A et al. (2019) Sodium, potassium and iodine intake, in a national adult population sample of the Republic of Moldova. Nutrients 11, 2896.CrossRefGoogle Scholar
D’Elia, L, Brajović, M, Klisic, A et al. (2019) Sodium and potassium intake, knowledge attitudes and behaviour towards salt consumption amongst adults in Podgorica, Montenegro. Nutrients 11, 160.CrossRefGoogle ScholarPubMed
WHO (2021) How to Obtain Measures of Population-Level Sodium Intake in 24-h Urine Samples: Protocol. Copenhagen: WHO Regional Office for Europe.Google Scholar
World Health Organization (2021) STEPwise Approach to NCD Risk Factor Surveillance (STEPS). https://www.who.int/teams/noncommunicable-diseases/surveillance/systems-tools/steps (accessed October 2021).Google Scholar
National Academies of Science, Engineering, and Medicine (2019) Sodium: dietary reference intakes based on chronic disease. In Dietary Reference Intakes for Sodium and Potassium [Stallings, VA, Harrison, M and Oria, M, editors]. Washington, DC: The National Academies Press.CrossRefGoogle Scholar
Poggio, R, Gutierrez, L, Matta, MG et al. (2015) Daily sodium consumption and CVD mortality in the general population: systematic review and meta-analysis of prospective studies. Public Health Nutr 18, 695704.CrossRefGoogle ScholarPubMed
Santos, JA, Tekle, D, Rosewarne, E et al. (2021) A systematic review of salt reduction initiatives around the world: a midterm evaluation of progress towards the 2025 global non-communicable diseases salt reduction target. Adv Nutr 12, 17681780.CrossRefGoogle ScholarPubMed
Andreasyan, D, Bazarchyan, A, Saghatelyan, A et al. (2018) Prevalence of Noncommunicable Disease Risk Factors in the Republic of Armenia. STEPS National Survey 2016. Yerevan, Avdalbekyan: National Institute of Health after Academician S, Ministry of Health, Republic of Armenia.Google Scholar
Rippin, H, Hutchinson, J, Jewell, J et al. (2017) Adult nutrient intakes from current national dietary surveys of European populations. Nutrients 9, 1288.CrossRefGoogle ScholarPubMed
WHO (2019) STEPS: Prevalence of Noncommunicable Disease Risk Factors in Azerbaijan Republic 2017. Copenhagen: WHO Regional Office for Europe.Google Scholar
WHO (2018) Prevalence of Noncommunicable Disease Risk Factors in Belarus. STEPS 2016. Minsk: WHO Regional Office for Europe.Google Scholar
Gicevic, S, Gaskins, AJ, Fung, TT et al. (2019) Fueling an epidemic of non-communicable disease in the Balkans: a nutritional survey of Bosnian adults. Int J Public Health 64, 873885.CrossRefGoogle ScholarPubMed
Duleva, V, Stavreva, S, Georgieva, R et al. (2019) Study on salt intake in Bulgarian population at the age of 15–65+ years estimated by sodium urinary excretion. Nutr Sci Prev Ther Contemp Dis, 1317.Google Scholar
Jelakovic, B, Vrdoljak, A, Pecin, I et al. (2016) Less salt - more health. Croatian action on salt and health (CRASH). J Hypertens Res 2, 6168.Google Scholar
National Institute for Health Development (2014) Estonian National Dietary Survey 2013–2014. Tallinn: National Institute for Health Development.Google Scholar
Agence nationale de sécurité sanitaire de l’alimentation, de l’environnement et du travail (French Agency for Food, Environmental and Occupational Health & Safety) (2017) Étude Individuelle Nationale des Consommations Alimentaires 3 (INCA 3) (Third National Study of Individual Food Consumption). Maisons-Alfort: Agence nationale de sécurité sanitaire de l’alimentation, de l’environnement et du travail.Google Scholar
Gamkrelidze, A, Mebonia, N, Sturua, L et al. (2018) Noncommunicable Diseases Risk-Factor STEPS Survey, Georgia, 2016. Tbilisi: National Center of Disease Control and Public Health of Georgia.Google Scholar
Vasara, E, Marakis, G, Breda, J et al. (2017) Sodium and potassium intake in healthy adults in Thessaloniki greater metropolitan area – the salt intake in Northern Greece (SING) study. Nutrients 9, 417.CrossRefGoogle ScholarPubMed
Þorgeirsdóttir, H, Valgeirsdóttir, H, Gunnarsdóttir, I et al. (2011) Hvað Borða Íslendingar? Könnun á Mataræði Íslendinga 2010–2011 (What do Icelanders Eat? A Survey of the Icelandic Diet). Reykjavík: Embætti Landlæknis, Matvælastofnun & Rannsóknastofa Í Næringarfræði Við Háskóla Íslands og Landspítala-Háskólasjúkrahús.Google Scholar
Perry, IJ, Browne, G, Loughrey, M et al. (2010) Dietary Salt Intake and Related Risk Factors in the Irish Population. A Report for Safefood. Cork: Safefood.Google Scholar
Stern, N, Buch, A, Goldsmith, R et al. (2021) The role of caloric intake in the association of high salt intake with high blood pressure. Sci Rep 11, 15803.CrossRefGoogle ScholarPubMed
Donfrancesco, C, Lo Noce, C, Russo, O et al. (2021) Trend of salt intake measured by 24-h urine collection in the Italian adult population between the 2008 and 2018 CUORE project surveys. Nutr Metab Cardiovasc Dis 31, 802813.CrossRefGoogle ScholarPubMed
Trieu, K, Ospanova, F, Tazhibayev, S et al. (2021) Sodium and potassium intakes in the Kazakhstan population estimated using 24-h urinary excretion: evidence for national action. Eur J Nutr 60, 15371546.CrossRefGoogle ScholarPubMed
Vahid, F, Brito, A, Le Coroller, G et al. (2021) Dietary intake of adult residents in Luxembourg taking part in two cross-sectional studies—ORISCAV-LUX (2007–2008) and ORISCAV-LUX 2 (2016–2017). Nutrients 13, 4382.CrossRefGoogle ScholarPubMed
Hendriksen, M, Etemad, Z, van den Bogaard, C et al. (2016) Zout-, Jodium- En Kaliuminname 2015 – Voedingsstatusonderzoek Bij Volwassenen Uit Doetinchem (Salt, Iodine and Potassium Intake 2015 – Nutritional Status Study among Adults in Doetinchem). Bilthoven: Rijksinstituut voor Volksgezondheid en Milieu.Google Scholar
Meyer, HE, Johansson, L, Eggen, AE et al. (2019) Sodium and potassium intake assessed by spot and 24-h urine in the population-based Tromsø study 2015–2016. Nutrients 11, 1619.CrossRefGoogle ScholarPubMed
Polonia, J, Martins, L, Pinto, F et al. (2014) Prevalence, awareness, treatment and control of hypertension and salt intake in Portugal: changes over a decade. The PHYSA study. J Hypertens 32, 12111221.CrossRefGoogle Scholar
Russian Federal State Statistics Service (2018) Выборочное Наблюдение Рациона Питания Населения 2018 (The Population Dietary Structure Sample Survey 2018). Moscow: Russian Federal State Statistics Service.Google Scholar
Ribič, CH, Zakotnik, JM, Vertnik, L et al. (2010) Salt intake of the Slovene population assessed by 24 h urinary sodium excretion. Public Health Nutr 13, 18031809.CrossRefGoogle ScholarPubMed
Ortega, RM, López-Sobaler, AM, Ballesteros, JM et al. (2011) Estimation of salt intake by 24 h urinary sodium excretion in a representative sample of Spanish adults. Br J Nutr 105, 787794.CrossRefGoogle Scholar
Chappuis, A, Bochud, M, Glatz, N et al. (2011) Swiss Survey on Salt Intake: Main Results. Lausanne: Service de Néphrologie et Institut Universitaire de Médecine Sociale et Préventive Centre Hospitalier Universitaire Vaudois.Google Scholar
WHO Regional Office for Europe (2021) STEPS: Распространённость Факторов Риска Неинфекционных Заболеваний В Республике Таджикистан, 2017 Г. (STEPS: Prevalence of Noncommunicable Disease Risk Factors in the Republic of Tajikistan 2017). Copenhagen: WHO Regional Office for Europe.Google Scholar
Erdem, Y, Akpolat, T, Derici, Ü et al. (2017) Dietary sources of high sodium intake in Turkey: SALTURK II. Nutrients 9, 933.CrossRefGoogle ScholarPubMed
WHO Regional Office for Europe (2019) STEPS: Распространённость Факторов Риска Неинфекционных Заболеваний В Туркменистане, 2018 г. (STEPS: Prevalence of Noncommunicable Disease Risk Factors in Turkmenistan 2018). Copenhagen: WHO Regional Office for Europe.Google Scholar
Ashford, R, Jones, K, Collins, D et al. (2020) National Diet and Nutrition Survey – Assessment of Salt Intake from Urinary Sodium in Adults (Aged 19 to 64 Years) in England, 2018 to 2019. London: Public Health England.Google Scholar
World Health Organization (2015) Определение Базового Уровня Потребления Соли Населением Узбекистана В Возрасте 18–64 Лет (Determination of Basic Level of Salt Consumption in the Population of Uzbekistan Aged 18–64). Tashkent: World Health Organization.Google Scholar
Figure 0

Fig. 1 Preferred reporting items for systematic reviews and meta-analyses (PRISMA) flow diagram. Databases searched include MEDLINE, Scopus and Web of Science for peer-reviewed articles published between 1 January 2000 and 31 January 2022

Figure 1

Table 1 Daily mean salt intake in adults

Figure 2

Fig. 2 Map of mean population salt intake in the WHO European Region (2022). Displayed are the Member States of the WHO European Region divided into quintiles, based on their mean population salt intake. The detailed characteristics of the included studies can be found in online supplementary material, Supplemental Appendix 2

Figure 3

Fig. 3 The different methods used to estimate salt intake data in the WHO European Region

Figure 4

Fig. 4 Quality of estimation method used for measuring salt intake for all studies included

Figure 5

Fig. 5 Forest plots, with estimates of the 95 % CI (except for a few countries which have provided these data), for the total population, split by estimation method of salt intake – 24 h urinary collection, spot urine collection and dietary assessments and all other methods

Figure 6

Fig. 6 Forest plots, with estimates of the 95 % CI (except for a few countries which have provided these data), for male and female populations, split by estimation method of salt intake – 24 h urinary collection, spot urine collection and dietary assessments and all other methods

Supplementary material: File

Kwong et al. supplementary material

Kwong et al. supplementary material 1

Download Kwong et al. supplementary material(File)
File 50.1 KB
Supplementary material: File

Kwong et al. supplementary material

Kwong et al. supplementary material 2

Download Kwong et al. supplementary material(File)
File 32.7 KB
Supplementary material: File

Kwong et al. supplementary material

Kwong et al. supplementary material 3

Download Kwong et al. supplementary material(File)
File 31.6 KB
Supplementary material: File

Kwong et al. supplementary material

Kwong et al. supplementary material 4

Download Kwong et al. supplementary material(File)
File 18.9 KB