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Sodium in commonly consumed fast foods in New Zealand: a public health opportunity

Published online by Cambridge University Press:  03 June 2015

Celia A Prentice ,
Claire Smith  and
Rachael M McLean
Celia A Prentice
Affiliation:
Department of Human Nutrition, University of Otago, PO Box 56, Dunedin, New Zealand
Claire Smith
Affiliation:
Department of Human Nutrition, University of Otago, PO Box 56, Dunedin, New Zealand
Rachael M McLean*
Affiliation:
Department of Human Nutrition, University of Otago, PO Box 56, Dunedin, New Zealand Department of Preventive and Social Medicine, Dunedin School of Medicine, University of Otago, Otago, New Zealand
*
*Corresponding author: Email Rachael.mclean@otago.ac.nz
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Abstract

Objective

(i) To determine the Na content of commonly consumed fast foods in New Zealand and (ii) to estimate Na intake from savoury fast foods for the New Zealand adult population.

Design

Commonly consumed fast foods were identified from the 2008/09 New Zealand Adult Nutrition Survey. Na values from all savoury fast foods from chain restaurants (n 471) were obtained from nutrition information on company websites, while the twelve most popular fast-food types from independent outlets (n 52) were determined using laboratory analysis. Results were compared with the UK Food Standards Agency 2012 sodium targets. Nutrient analysis was completed to estimate Na intake from savoury fast foods for the New Zealand population using the 2008/09 New Zealand Adult Nutrition Survey.

Setting

New Zealand.

Subjects

Adults aged 15 years and above.

Results

From chain restaurants, sauces/salad dressings and fried chicken had the highest Na content (per 100 g) and from independent outlets, sausage rolls, battered hotdogs and mince and cheese pies were highest in Na (per 100 g). The majority of fast foods exceeded the UK Food Standards Agency 2012 sodium targets. The mean daily Na intake from savoury fast foods was 283 mg/d for the total adult population and 1229 mg/d for fast-food consumers.

Conclusions

Taking into account the Na content and frequency of consumption, potato dishes, filled rolls, hamburgers and battered fish contributed substantially to Na intake for fast-food consumers in New Zealand. These foods should be targeted for Na reduction reformulation.

Keywords

SodiumSaltFast foodsTakeawayNew ZealandNutrition Survey
Type
Research Papers
Information
Public Health Nutrition , Volume 19 , Supplement 6 , April 2016 , pp. 958 - 966
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Copyright
Copyright © The Authors 2015 

Na is widely used as a food additive in processed foods to preserve, enhance flavour and palatability( Reference Henney, Taylor and Boon 1 ). Between 75 and 80 % of Na intake in the Western diet is from processed foods( Reference He and MacGregor 2 ) and therefore reducing Na in these foods through reformulation has great potential to reduce Na intakes( Reference Van Raaij, Hendriksen and Verhagen 3 ). Identifying the types of foods that contribute most to Na intake is important for tailoring the development of appropriate Na reduction strategies( Reference Webster, Dunford and Neal 4 , Reference Keogh, Lange and Hogarth 5 ). Fast foods/takeaway foods are of particular interest given that they have been found to be high in Na/salt in many countries( Reference Johnson, Angell and Lederer 6 Reference Heredia-Blonval, Blanco-Metzler and Montero-Campos 8 ). New Zealand sales data suggest that fast-food consumption increased by 10 % between 1999 and 2008( Reference De Vogli, Kouvonen and Gimeno 9 ). Results from the most recent New Zealand Adult Nutrition Survey in 2008/09 (NZANS) show that fast food is an important source of energy for some population groups (particularly young adults aged 19–30 years) and that some types of fast foods (such as hamburgers and hot chips) are more commonly consumed than others( Reference Smith, Gray and Fleming 10 ). Furthermore, consumers may not be aware of the amount of Na in takeaway and restaurant foods, and are unlikely to identify this type of food as an important contributor to overall intake( Reference Levings and Gunn 11 ).

The New Zealand and Australian governments have jointly determined a Suggested Dietary Target (SDT) of 1600 mg Na/d and an Upper Level (UL) of 2300 mg Na/d to aid in the prevention of chronic disease( 12 ). The most recent estimate of Na intake in New Zealand, determined by 24 h urine samples collected in 2012, was 3400 mg/d( Reference Skeaff, McLean and Mann 13 ). This is substantially above current recommendations. The WHO is supporting governments to implement the Global Action Plan for the Prevention and Control of Non-communicable Diseases, which would result in a 30 % reduction in salt intake (to achieve a mean intake of less than 2000 mg Na/d (5 g salt/d)) by 2025 in participating countries( 14 ). This is because high dietary Na intakes are associated with high blood pressure( Reference He, Li and Macgregor 15 ), the leading preventable risk factor for death (attributable to CVD, stroke and related conditions) worldwide( Reference Lim, Vos and Flaxman 16 ). An estimated 2·5 million deaths could be averted globally each year if this target were achieved( Reference He and MacGregor 17 ). Surveillance of dietary Na intakes and evaluation of interventions is vital to achieving this recommendation.

Population Na reduction strategies have been identified as one of the most effective and cost-effective public health strategies available to prevent chronic disease( Reference Bibbins-Domingo, Chertow and Coxson 18 , Reference Webster, Trieu and Dunford 19 ). The combination of food reformulation with improvements in food labelling and consumer education implemented in the UK by the Food Standards Agency (FSA) has resulted in a 10 % reduction in mean population salt intake (from an average of 9·5 g/d in 2000–2001 to 8·1 g salt/d in 2011)( Reference He, Brinsden and MacGregor 20 ). In New Zealand the National Heart Foundation, funded by the Ministry of Health, has worked in collaboration with the food industry to reduce the Na content of bread( 21 ) and some other manufactured foods( 22 ). However, the contribution of takeaway or fast foods to population Na intake has not been determined and the feasibility of Na reduction in this food group is unknown.

Therefore, the overall aims of the present study were to: (i) determine the Na content (per serving and per 100 g) of commonly consumed fast foods (from independent outlets and chain restaurants) in New Zealand and compare them with the UK FSA 2012 sodium targets; and (ii) estimate Na intake from savoury fast foods for the New Zealand adult population.

Methods

In summary, data were obtained from three main sources:

  1. 1. Results from the 24 h diet recall of the 2008/09 NZANS were used to identify the most commonly consumed fast foods for analysis. These data were also used for estimation of population Na consumption from savoury fast foods.

  2. 2. Of the commonly consumed savoury fast foods identified above, for food categories (n 16) that were usually sourced from chain restaurants, we identified and recorded nutrition information from company websites.

  3. 3. For food categories (n 12) that were usually sourced from independent food outlets, samples of food were purchased and analysed in the laboratory for Na content.

Methods of the 2008/09 New Zealand Adult Nutrition Survey

Sampling

The 2008/09 NZANS was a nationally representative, cross-sectional survey of 4721 New Zealand adults (aged 15 years and over)( 23 ). Participants were recruited using a three-stage, stratified, area-based sampling frame and there was an overall response rate of 61 %. Increased sampling of Māori and Pacific Island ethnic groups and some age categories (15–18 years and ≥71 years) occurred to achieve adequate numbers for robust age and ethnicity comparisons. Participants were drawn from urban and rural regions, but were restricted to persons living in private dwellings( 23 ). Informed, written consent was obtained. The New Zealand Health and Disability Multi-Region Ethics Committee granted ethical approval for the survey (MEC/08/04/049).

Dietary data collection

Dietary intake data were collected through a computer-assisted, multiple-pass 24 h diet recall administered by a trained interviewer( 23 ). The recall interview was structured in four phases. The initial phase was a ‘quick list’ of all foods, beverages and dietary supplements consumed in the preceding day (midnight to midnight). At this stage, participants were also asked where they sourced the food( 23 ). Participants could choose from several options including: (i) store/shop/market; (ii) restaurant/café; (iii) fast-food/takeaway outlet; (iv) workplace (cafeteria, catering); (v) vending machine; (vi) other (community food programme, gift, online purchases); and (vii) home/domestic (home-grown produce). Participants who reported at least one food or beverage sourced from a fast-food/takeaway outlet in the 24 h recall were classified as a ‘fast-food consumers’( Reference Smith, Gray and Fleming 10 ). In the next stage, detailed descriptions of all foods and beverages on the quick list were collected using computer-controlled questions and prompts specific to each item (including the cooking methods used, recipes for mixed dishes, additions made ‘on the plate’). In the third stage, the quantities of all foods were estimated with the aid of commonly used household measures and measurement aids( 23 ). Lastly, there was a review of the diet recall to verify that all information was recorded correctly. A repeat 24 h recall was collected on a subset (25 %) of the population( 23 ).

Identification of commonly consumed fast foods in New Zealand from the 2008/09 New Zealand Adult Nutrition Survey

For the purposes of the present study, we were only interested in savoury fast-food items. ‘Fast food’ was defined as savoury food that was reported as being sourced from a fast-food/takeaway outlet or quick-service restaurant in the first stage of the 24 h diet recall. Beverages, cakes, biscuits and puddings sourced from fast-food/takeaway outlets were not included. The foods were ranked by frequency of consumption. Using food descriptions, foods were then categorized into those from chain restaurants or independent outlets.

Determination of Na content of foods from online nutrition information (sixteen food categories)

Nutrition information on the Na content of all savoury fast-food menu items (reported in the 2008/09 NZANS) from chain restaurants were collected from company websites: McDonald’s( 24 ), Burger King( 25 ), KFC( 26 ), Domino’s( 27 31 ), Hell’s Pizza( 32 ), Pizza Hut( 33 ), Subway( 34 ) and Wendy’s( 35 ). The following information was collected on 28 December 2013 for 471 foods: brand, food type, serving size (g), Na (mg) per serving and per 100 g. When information on the Na content (such as ‘Sodium (mg) per 100 g’) was not available, this was calculated using available information. Where several serving sizes were available (e.g. ‘small’, ‘medium’ and ‘large’), information on a ‘medium’ serving was recorded. Foods from online nutrition information were categorized into sixteen food categories: (i) burgers; (ii) pizza; (iii) sandwiches; (iv) wraps; (v) breakfast muffins; (vi) garlic bread; (vii) fries/wedges; (viii) hash browns; (ix) stuffed potatoes; (x) potatoes and gravy; (xi) fried chicken; (xii) salads; (xiii) salad dressings/sauces; (xiv) onion rings; (xv) omelettes; and (xvi) chilli con carne.

Determination of Na content of foods sourced from independent outlets (twelve food categories)

The twelve most frequently reported fast-food categories from independent outlets (reported in the 2008/09 NZANS) were: (i) hot chips; (ii) battered fish; (iii) hot dogs; (iv) sausage rolls; (v) pies; (vi) fried chicken; (vii) hamburgers; (viii) egg-foo-yung; (ix) butter chicken; (x) sweet and sour pork; (xi) chop suey; and (xii) sushi. The online New Zealand Yellow Pages® ( 36 ), New Zealand Yellow Pages® Menu Restaurant Guide( 37 ) and Menumania( 38 ) were used to search for all fast-food outlets supplying the foods in two main cities in New Zealand (Wellington (population=191 000)( 39 ) and Dunedin (population=120 000)( 39 )). Microsoft® Office Excel 2013 random number generator was used to randomly select four outlets from each fast-food category (two from Wellington city and two from Dunedin city). One sample of each food type was purchased from each of the four outlets, resulting in a total of forty-eight meal samples. Samples were purchased from Wellington outlets between 3 February and 7 February 2014, and from Dunedin outlets between 10 February and 15 February 2014. The food was purchased as seasoned by staff and no specific instructions were given about salting or not salting the food.

The chosen method of laboratory Na analysis follows that described in the Official Methods of Analysis of the AOAC INTERNATIONAL( 40 ). Briefly, food samples were frozen following collection and stored at −18°C until the time of analysis. The samples were then defrosted, weighed and blended to achieve a homogeneous and evenly distributed mixture. The Na content (mg/kg) of each food was determined (on a wet-weight basis) by microwave nitric acid digestion followed by inductively coupled plasma–optical emission spectrometry, and then calculated per 100 g and per serving. A certified Standard Reference Material (National Institute of Standards and Technology Infant Formula®)( 41 ) designed for detecting minerals such as Na in a food matrix was used in daily laboratory analyses for accuracy purposes( 40 ). All laboratory analyses were conducted within the Department of Human Nutrition, Dunedin. The CV% was calculated for all of the tested products and Standard Reference Material controls (overall Na CV%: 2·48 %). Only results with a CV% within 5 % of the known Na value were included in the analysis.

Comparison with public health recommendations

Descriptive statistics were used to compare the Na content of fast foods from chain restaurants and independent outlets, both within and between food categories, with (where possible) the UK FSA 2012 sodium targets( 42 ).

Estimation of Na intake from savoury fast foods for the New Zealand adult population

In order to estimate Na intake from fast foods, an Na value per 100 g was assigned to each savoury fast food reported in the 2008/09 NZANS. One of three sources was used: (i) the New Zealand Food Composition Database( 43 ); (ii) laboratory-tested Na values; or (iii) company online nutrition information Na values. The Na value from the New Zealand Food Composition Database was used in the first instance but if the Na values were ≥10 years old or not from Australia or New Zealand, either the laboratory data or online nutrition information was used (depending on where the fast food was sourced). As it was not collected within the 24 h diet recall, information on salt added to the foods by participants was not available.

Statistical analysis

Data were calculated as Na per serving and Na per 100 g. Where the purchased serving sizes were substantially larger than those reported in the 2008/09 NZANS (this was applicable for hot chips, battered fish, egg-foo-yung, butter chicken, sweet and sour pork, chop suey, sushi and pizza), these were also calculated as ‘per serving’ using mean serving sizes reported in the 2008/09 NZANS (see online supplementary material, Supplemental Table 1). For each food category the mean Na concentration and range were calculated to show the full range of Na concentration across the different food categories.

Table 1 Mean sodium content of fast foods from New Zealand chain restaurants and UK FSA sodium targets

n, number of foods from online nutrition information; FSA, Food Standards Agency; N/A, not applicable.

* UK FSA 2012 sodium targets set for specific food categories( 42 ) (where N/A is stated, there is no set target for the food category).

Includes all types (e.g. chicken, beef, ham, egg, vegetables and sauce).

Where several serving sizes were available (e.g. ‘small’, ‘medium’ and ‘large’), a ‘medium’ serving was reported.

§ Calculated by adding together food category means and ranges.

Data were analysed using the statistical software package Stata 12·1. For the analysis of the 2008/09 NZANS, survey commands were used to allow for the complex survey design, enabling weighting to be applied so that the results were representative of the New Zealand population at the time of the survey. Na intakes from savoury fast foods were calculated for the adult population (n 4721) and for fast-food consumers (n 1076) by sex, age and ethnicity. Separate linear regression models were constructed for males and females to examine differences in Na intake from fast food, firstly by age group and secondly by ethnic group with age as a covariate. P values<0·05 were deemed to be statistically significant. Where skewed distributions occurred, the results are reported as both the mean (95 % confidence interval) and median (interquartile range) in the descriptive analysis.

Results

Na content of foods from online nutrition information

The mean Na per serving and per 100 g for fast foods and meal combinations available from chain restaurants is shown in Table 1. The fast-food category with the highest Na per serving was burgers (1026 mg/serving), which was 45 % of the recommended UL. However, when the serving sizes reported in the 2008/09 NZANS were used instead of those used in the online nutrition information, a serving of pizza provided more Na (1276 mg) than a burger and provided 55 % of the recommended UL. Salad dressings/sauces and fried chicken had the highest Na per 100 g (728 mg/100 g and 617 mg/100 g, respectively). The Na content of fast foods within the same food category varied; for example, one pizza sample had 137 mg Na/100 g, while another pizza sample (with similar toppings) had 920 mg Na/100 g. Twelve out of thirteen of the fast-food categories exceeded the UK FSA 2012 sodium targets, some more than 1·5 times (burgers, mashed potato and gravy, fried chicken and chilli con carne).

Na content of foods from independent outlets

The mean Na per serving (as purchased), per 100 g and potential meal combinations for fast foods from independent fast-food outlets are shown in Table 2. The fast-food category with the highest Na per serving was a meal of chop suey (3086 mg/serving), which contained over three times more Na than a meal of fish and chips (941 mg/serving) and provided 134 % of the recommended UL. However this reflected the large serving size, and when adjusted using serving sizes derived from the 2008/09 NZANS data, chop suey contained only half as much Na per serving (670 mg/serving) as sausage rolls (1263 mg/serving), beef hamburgers (1161 mg/serving) and mince and cheese pies (1068 mg/serving). Sausage rolls, battered hotdogs and mince and cheese pies were the highest in Na per 100 g (689 mg/100 g, 679 mg/100 g and 522 mg/100 g, respectively). There was wide variation in the Na content for the same food sourced from different outlets; for example, the range for egg-foo-yung was 159–418 mg/100 g. Ten of the twelve fast foods exceeded the UK FSA 2012 sodium targets, some by more than 1·5 times (sausage rolls, hamburgers, egg-foo-yung and sushi).

Table 2 Mean sodium content of fast foods analysed in the laboratory from independent New Zealand fast-food outlets and UK FSA sodium targets

n, number of foods sampled; FSA, Food Standards Agency.

* As purchased.

UK FSA 2012 sodium targets set for specific food categories( 42 ).

Includes samples with and without sauce.

§ Calculated by adding together food category means and ranges.

|| Value excludes one sample outlier (699 mg Na/100 g).

Na intake from savoury fast foods for the New Zealand adult population

Overall, 1076 (23 %) of participants consumed a savoury fast food in the 24 h recall of the 2008/09 NZANS. The mean daily Na intake from savoury fast foods for all adults was 283 mg/d (n 4721) and 1229 mg/d for fast-food consumers (n 1076). The mean daily Na intake from savoury fast foods among fast-food consumers (taking into account Na concentration, frequency of consumption and serving size reported in the 2008/09 New Zealand Adult Nutrition Survey) is shown in Table 3. Among fast-food consumers, 43 % reported consuming potato dishes and 24 % reported consuming filled rolls. Both hamburgers and battered fish were reported by 14 % of fast-food consumers. The mean Na intake for fast-food consumers was 194 mg from hamburgers, 183 mg from filled rolls, 161 mg from potato dishes and 129 mg from pizza.

Table 3 Mean daily Na intake from savoury fast foods among fast-food consumers (n 1076), taking into account sodium concentration, frequency of consumption and serving size reported in the 2008/09 New Zealand Adult Nutrition Survey

n, number of individuals.

* Excludes non-reporters of fast foods.

Includes hot chips/fries/wedges, hash browns, stuffed potatoes, mashed potato and gravy.

Includes mostly battered fish.

§ Meat and vegetable based (no rice/noodles).

|| Includes samosas, dumplings, spring rolls, wontons and dumplings.

The mean (95 % confidence interval) and median (interquartile range) Na intake from savoury fast foods for New Zealand adults (by sex, age and ethnicity) are shown in Table 4. Significant differences (P<0·001) in mean Na intake from savoury fast foods among the total adult population and fast-food consumers were found by sex and age, but not by ethnicity (P>0·05). Among the adult population and fast-food consumers (males and females), the 15–18 year old age group had significantly (P<0·001) higher mean Na intakes from savoury fast foods compared with those aged 51–70 years and ≥71 years.

Table 4 Mean and median sodium intake from savoury fast foods (among the total adult population and fast-food consumersFootnote *) taking into account sodium concentration, frequency of consumption and serving size reported in the 2008/09 NZANS, by sex, age and ethnicity

NZANS, New Zealand Adult Nutrition Survey; n, number of individuals; IQR, interquartile range; PI, Pacific Island ethnicity; NZEO, New Zealand European and Others (mainly Asian, Middle Eastern, Latin American and African ethnicities( 54 )).

a,b,cMean values within a column with unlike superscript letters were significantly different (P<0·001).

* Excludes non-reporters of savoury fast foods in the 2008/09 NZANS.

In the 2008/09 NZANS there was oversampling of particular subgroups of the population: Māori and Pacific ethnic groups and some age groups (15–18 years and ≥71 years).

Overall P value from the Wald test.

Discussion

The present study is the first of its kind to examine Na levels in commonly consumed savoury fast foods in New Zealand and to apply this information to national data to enable estimates of Na intake from fast foods. We found high Na levels, in comparison to the UK FSA 2012 sodium targets, for the majority of commonly consumed fast foods in New Zealand. Burgers, pizza, sausage rolls and pies had relatively high Na content per serving compared with other savoury fast foods. Most food categories showed a wide range of Na concentration. For example, pizzas ranged from 137 to 920 mg Na/100 g and burgers ranged from 241 to 760 mg Na/100 g. This suggests that there is no technical reason preventing Na reduction in savoury fast foods to levels at the lower end of the existing range( Reference Heredia-Blonval, Blanco-Metzler and Montero-Campos 8 , Reference Kanzler, Hartmann and Gruber 44 ).

The present study also shows that savoury fast food contributes substantially to population Na intake, particularly among young adults under 30 years. Potato dishes, filled rolls, hamburgers and battered fish were important contributors to Na intakes for fast-food consumers when both the Na concentration and the frequency of consumption were taken into account. They should therefore be targets for intervention in order to achieve meaningful reductions in Na intake from savoury fast foods. These results are not surprising given that hot chips/fries/wedges are an accompaniment to most fast-food meals in New Zealand and bread forms the base of many fast-food types (such as hamburgers, filled rolls and pizza bases)( Reference Smith, Gray and Fleming 10 ).

High Na/salt levels in fast foods have been widely reported. The salt content of fast foods has been found to be high in the UK and the USA, where the average takeaway meal has been found to contain more than half of the UK population intake (2009) target of 6 g salt/d (2300 mg Na/d)( Reference Johnson, Angell and Lederer 6 , Reference Jaworowska, Blackham and Stevenson 7 ). Such high salt levels of fast foods may be attributed to large serving sizes as well as a high Na concentration within the foods. Jaworowska et al. analysed purchased takeaway food in the UK and found that pizzas (the fast-food item with the highest salt content per serving) ranged from 6·97 to 12·83 g of salt (2742 to 5047 mg of Na) per serving, with the serving size ranging from 559 to 781 g( Reference Jaworowska, Blackham and Stevenson 7 ). Items such as pizza and burgers typically comprise bread, processed meats, cheese and sauces, all of which tend to be high-Na ingredients( Reference Thomson, Vannoort and Haslemore 45 ). Most studies also show large variation within the same food categories( Reference Heredia-Blonval, Blanco-Metzler and Montero-Campos 8 , Reference Kanzler, Hartmann and Gruber 44 ) and fast-food items marketed as the same product in six different countries have been found to have very different Na contents( Reference Levings and Gunn 11 , Reference Dunford, Webster and Woodward 46 ). Food sources that are the highest in Na content may not, however, be the most important sources of dietary Na at a population level because they may not be frequently consumed( Reference Henney, Taylor and Boon 1 ), and dietary patterns differ between countries and populations. For example, in the USA, pizza, chicken, burgers and Mexican dishes have been found to be the top items reported outside the home (providing 7·8 % of total Na in adult diets)( Reference Drewnowski and Rehm 47 ). This highlights the importance of using population-specific data to inform public health reformulation strategies.

Salt reduction in foods has been proven feasible in the UK and Finland( Reference Webster, Dunford and Hawkes 48 ), and it has been found that a reduction of up to one-third in the Na content of foods can be made before the sensory acceptability of food is affected( Reference Adams, Maller and Cardello 49 ). Changes may go unnoticed if reductions are made ‘little and often’( Reference He, Brinsden and MacGregor 20 ). Specifying voluntary Na content targets across a wide range of food categories may encourage sectors of the food industry to carry out reformulation work to reduce the Na content of their products. Although New Zealand lacks a wide range of specific Na targets, some companies have already committed to reformulation( 50 ). One example is ‘The Chip Group’ (formed by the partnership of the New Zealand Heart Foundation, the New Zealand Ministry of Health, New Zealand potato growers, chip manufacturers and oil suppliers) which encourages the food industry to use salt sparingly when added as a seasoning, or to use salt sachets so that consumers can control the amount of salt added to their chips( 51 ). Participation in such an initiative is likely to have large benefits among fast-food consumers, given that such a large percentage of consumers reported consuming potato dishes. Further reductions in the Na concentration in bread could impact on the Na content of filled rolls and hamburgers, which we also found to be large contributors to Na intake. Mandatory reformulation targets, such as those recently implemented in South Africa and Argentina, would provide a level playing field to ensure that companies are not penalised commercially for lowering the Na content of their foods( Reference Webster, Trieu and Dunford 19 , 52 ). In addition to reformulation, greater diversity in fast-food menus could encourage the selection of lower-Na options and these could be easily identified by including ‘at a glance’ nutrition information on fast-food packaging( Reference McLean, Mann and Hoek 53 ).

Strengths/limitations and implications for future research

There were aspects of the present study which add strength to our findings. It is the first New Zealand study to apply Na nutrition information to survey data to enable estimates of dietary Na intake from fast foods. Our study provides information on the Na content of fast foods from both chain restaurants and independent outlets. Furthermore, the food sampling protocol was informed from fast-food choices from a large national sample; therefore the foods chosen for laboratory analysis were representative of dietary choices of New Zealanders. We re-calculated as-purchased large serving sizes using average portion sizes sourced from the 2008/09 NZANS to provide realistic serving sizes. In the laboratory, a Standard Reference Material with an acceptable CV% was used and this guaranteed the accuracy of our results. Our results can therefore be used as a benchmark for future monitoring of trends in Na levels of savoury fast foods over time.

A number of limitations also exist. We have estimated Na intake from savoury fast foods for the adult population; however (i) data collected did not include discretionary salt which could be added by consumers at the table; (ii) additions to foods (such as sauces) could be made by participants at home and therefore these were not always coded as being from a fast-food outlet; and (iii) we have not captured all types of fast foods prepared outside the home (as fast-food items such as pies sourced from small local shops and supermarkets were not coded in the survey as being sourced from a fast-food outlet)( Reference Smith, Gray and Fleming 10 ). We therefore may have underestimated the population Na intake from savoury fast food. In order to estimate the Na content of fast foods from chain restaurants, we used published Na values from online nutrition information, and there was variation in whether Na reported included salt added just before serving. For food sources from independent outlets, only four samples were used in laboratory analysis to represent each food type and samples were collected from just two centres (Dunedin and Wellington). These results therefore may not be an accurate representation of foods available across the New Zealand market. Future research in this area could include larger sample sizes of foods and collection of samples from other urban and rural settings.

Conclusion

Savoury fast food is an important contributor to New Zealand population Na intake and the variability of Na content within food categories shows that Na reduction in many items is feasible. Taking into account both the Na content and frequency of consumption, potatoes, filled rolls, hamburgers and battered fish were the most important contributors to Na intake from savoury fast food for consumers in New Zealand. New Zealand should implement a coordinated government-led population salt reduction strategy which includes reformulation guided by targets across a wide range of food categories including savoury fast foods. This approach has the greatest potential to achieve the WHO 30 % reduction in population salt intake and thereby prevent significant morbidity and mortality in future years.

Acknowledgements

Acknowledgements: The authors would like to thank A. Duncan, K. Bailey, K. Columb and M. Harper (Department of Human Nutrition, University of Otago) for their laboratory assistance and advice. Financial support: Some of the data used in this study were from the 2008/09 New Zealand Adult Nutrition Survey. The New Zealand Ministry of Health funded the 2008/09 New Zealand Adult Nutrition Survey and the survey was conducted collaboratively with the University of Otago. The New Zealand Ministry of Health had no role in the design, analysis or writing of this work. The New Zealand Crown is the owner of the copyright for the survey data. The results presented in this paper are the work of the authors. Conflict of interest: The authors declare no conflict of interest. Authorship: R.M.M. and C.S. formulated the research questions and designed the study; C.A.P. collected food samples and carried out the laboratory analyses/obtained online Nutrition Information Panel data; C.A.P., R.M.M. and C.S. analysed and interpreted the results; R.M.M. and C.S. conducted statistical analyses; C.A.P. drafted the manuscript; R.M.M. and C.S. contributed to the final manuscript. Ethics of human subject participation: The 2008/09 New Zealand Adult Nutrition Survey was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the New Zealand Health and Disability Multi-Region Ethics Committee (MEC/08/04/049). Written informed consent was obtained from all participants.

Supplementary material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S1368980015001731

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Figure 0

Table 1 Mean sodium content of fast foods from New Zealand chain restaurants and UK FSA sodium targets

Figure 1

Table 2 Mean sodium content of fast foods analysed in the laboratory from independent New Zealand fast-food outlets and UK FSA sodium targets

Figure 2

Table 3 Mean daily Na intake from savoury fast foods among fast-food consumers (n 1076), taking into account sodium concentration, frequency of consumption and serving size reported in the 2008/09 New Zealand Adult Nutrition Survey

Figure 3

Table 4 Mean and median sodium intake from savoury fast foods (among the total adult population and fast-food consumers*) taking into account sodium concentration, frequency of consumption and serving size reported in the 2008/09 NZANS, by sex, age and ethnicity

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