Dietary improvement for Indigenous Australians is a priority strategy for reducing the health gap between Indigenous and non-Indigenous Australians. Overweight and obesity (11·4 %) is the second highest contributor after tobacco use (12·1 %) to the extremely high disease burden experienced by Indigenous Australians(Reference Vos, Barker and Begg1). Its contribution increases sharply from a relatively young age, driving the very high incidence of type 2 diabetes, CVD and related conditions such as kidney failure at ever younger ages. The 26 % of Indigenous Australians who live in remote areas experience a disproportionate disease burden −40 % of the excess preventable illness(Reference Vos, Barker and Begg1).
Much of this burden of disease is due to extremely poor nutrition across the life course. Measuring food consumption is necessary to monitor progress towards national dietary goals and to identify areas for improvement. However, dietary data for Indigenous Australians have not been routinely available from national nutrition surveys or any other source, with a consequent gap in information on a major determinant of health.
In remote communities, the store provides much or most of the food supply(Reference Brimblecombe, Mackerras and Clifford2, 3). There are about 175 stores in remote Australia(3). Two decades previously, the store in remote communities was shown to provide an estimate of ‘community dietary quality profile’(Reference Lee, Smith and Bryce4) and has been used to monitor the health impact of interventions to improve diet quality(Reference Rowley, Daniel and Skinner5, Reference Lee, Bailey and Yarmirr6). Likewise, in urban settings overseas, supermarket sales data have been shown to be a valid source of information on household food and nutrient availability where supermarket foods are the largest single contributor to diet(Reference Tin Tin, Ni Mhurchu and Bullen7).
The aim of the present study was to examine the feasibility of assessing dietary quality of food sales in remote stores using point-of-sale data. To do this we examined differences and consistencies in point-of-sale data across six community stores in relation to: (i) food expenditure patterns; (ii) nutrient profiles (macronutrient contribution to energy and nutrient density – nutrient per 1000 kJ); and (iii) major food sources of macro- and micronutrients.
The study was conducted under the Remote Indigenous Stores and Takeaway (RIST) project. All community stores consented to provide data for the purposes of the RIST project.
Methods
Setting
Six stores in remote Aboriginal Australia from three states and the Northern Territory, ranging in size from 185 to 880 residents of mostly Aboriginal ethnicity with comparable age and sex distributions (Australian Bureau of Statistics census data)(8) (Table 1), participated in the present study. The stores represented a cross-section of communities in different regions of remote Australia, of different sizes and store ownership structure. The distance between study stores was vast: study communities were located 300 km to nearly 3000 km in distance from Darwin (the capital of the Northern Territory). Distance from each community to the nearest food wholesaler ranged from 210 km to over 1000 km. Alcohol was not available in any stores and prohibited in five of the six communities.
*Estimated energy requirements for the different age groups (1–3 years; 4–8 years; 9–13 years; 14–18 years; 19–30 years; 31–50 years; 51–70 years; >70 years) and sex were calculated based on the Estimated Energy Requirement Tables 1–3 in the Nutrient Reference Values for Australia and New Zealand(13). For the age groups 19–30 years to >70 years, the midpoint height and weight of each adult age group were used. For <18 years, the midpoint of the estimated energy requirement range across each age and sex category (Tables 1–2 of the Nutrient Reference Values for Australia and New Zealand(13)) was used. Energy expenditure was estimated at 1·6 × BMR for both sexes and age groups. An estimated 8 % of the female population aged 14–50 years pregnant and 8 % breast-feeding was derived from Australian Bureau of Statistics 2006 birth data (Table 9·2 Indigenous registered births, Australia, p. 76)(32) and 2006 census data(8) for women aged 13–54 years.
Data collection
Electronic point-of-sale data were provided at no cost by each store for a 3-month period (July–September) in 2006 when road closure due to seasonal conditions would be minimal. A 3-month period was used to ensure adequate capture of products including those with slow stock turnover(Reference Lee, Smith and Bryce4).
All food and beverage items, with the accompanying Universal Product Code (barcode) or store-derived product code, quantity sold and dollar value (retail price), were imported into a purposely designed Access database (Microsoft® Office 2003). Unit weights were derived for all food and drink items(Reference Brimblecombe9). Volume (millilitres) was converted to weight (grams) using a specific gravity conversion factor(10). Each food and drink item was assigned a food group according to the Australian Food and Nutrient food grouping system(10).
Food and beverage weights were expressed per edible fraction and their energy and nutrient contents sourced from the Australian Food and Nutrient reference and survey databases (NUTTAB 20006, AUSNUT 2007 and AUSNUT 1999)(10). Where possible, brand-specific nutrient composition was sourced. Nutrition Information Panels and recipe development were used to derive the nutrient composition of ten food types (twenty-three food lines) not available in the food and nutrient databases. Matching of the 5569 food lines (1151 nutritionally unique items) with nutrient data was performed by two nutritionists with an agreement rate of 94 %. Average nutrient quantities per 100 g were multiplied by the edible weight of each of the food and beverage items sold(Reference Hamilton, Ni Mhurchu and Priest11) and for each food group.
Analysis
Percentage contribution of protein, total fat, saturated fat, carbohydrate and total sugar to energy content of food sales was determined for each store and for stores combined. Nutrient density (nutrient availability per 1000 kJ), which is independent of population size, was used to assess the dietary quality of food sales and for community comparisons(Reference Lee, O'Dea and Mathews12). Nutrient densities were compared with population-weighted nutrient density requirements derived from Australian nutrient reference values (Recommended Dietary Intakes (RDI) and Estimated Average Requirements (EAR))(13) and national census data for each community(8). The RDI is the average daily dietary intake level sufficient to meet the nutrient requirements of nearly all (97–98 %) healthy individuals in a particular life stage and gender group. The EAR is a daily nutrient level estimated to meet the requirements of half the healthy individuals in a particular life stage and gender group(13). Adequate Intake (AI) values were used for those nutrients where EAR and/or RDI were not available (K, dietary fibre, protein and vitamin E α-tocopherol equivalents). The midpoint of the AI range was used for Na.
Foods contributing 10 % or more of a specific nutrient were considered a major food source(14).
Results
In all communities, the store provided nearly 40 % or more of the estimated population energy requirement (range 39–153 %) according to 2006 census data (Table 1). Lower percentages were shown for Stores 2 and 4 where competing food outlets existed in the community. A lower population at the time of the study than that stated in the 2006 census for Community 6 (personal communication, community informant) explained the exaggerated percentage for population energy requirement.
In five out of six stores, beverages comprised the highest percentage of dollar sales, 21·4 (sd 1·4) %, compared with 10·4 (sd 1·9) % for fruit and vegetables (Table 2). The macronutrient profile was similar in all stores and showed a similar pattern to that reported by Lee et al. in the late 1980s for six remote stores in the Northern Territory using store invoice data(Reference Lee, O'Dea and Mathews12) (Table 3). On average carbohydrate comprised more than half of the energy from food sales and percentage to energy for protein was lower than the recommended minimal intake. Percentage fat to energy (31·8 (sd 3·2) %) was at the high end of the recommended range and similar to that reported in 1986/1987 for remote Northern Territory community stores(Reference Lee, O'Dea and Mathews12) and for wider Australia from self-reported dietary intake data(15, 16) (Table 3).
*Beverages – teas, coffees, dry beverage flavourings, fruit drinks, cordials, flavoured drink bases, soft drinks, fruit and vegetable juices and juice drinks (milk drinks are in the milk & milk products category).
†Flours, cakes, biscuits, bread, grains and starches, breakfast cereals, buns, scones, cereal-based bread equivalents, batters and pastries.
‡Savoury pastry products, pizza, sandwiches, other products where cereal is major ingredient.
§For Store 5, the percentage contribution of fruit to total food expenditure is an overestimate as fruit and vegetable sales were not individually itemised in the point-of-sale system but entered as fruit and vegetables. Fruit and vegetable sales were categorised as ‘Fruit’, but assigned a composite nutrient composition.
∥Beef, lamb, pork, veal, game, poultry, offal, battered and crumbed products, sausages and frankfurters, other processed meats.
¶Herbs and spices, vinegars, salad dressings, yeast, yeast vegetable extracts, essences.
**Includes all potato and potato products except potato crisps.
NNS, National Nutrition Survey; NA, not available.
*Macronutrients to energy for wider Australia also includes a contribution from alcohol of 3·2 %.
For all stores combined, nutrient densities, when compared with the population-adjusted nutrient densities (using EAR) or AI, were adequate for some nutrients (B-group vitamins, vitamin C, P, Fe, Zn, folate and vitamin A retinol equivalents), but limiting for Mg, K, Ca, fibre and vitamin E α-tocopherol. Na density was unacceptably high (Fig. 1). Levels of iodine, folate dietary equivalents and Fe were also lower than the adjusted RDI per 1000 kJ (Fig. 1). A similar pattern was observed for individual stores (Table 4).
NNS, National Nutrition Survey; equiv., equivalents; α-TE, α-tocopherol equivalents; RE, retinol equivalents; NA, not available.
Main food sources of each nutrient reflect both the amount of food purchased and the level of nutrient found in the food(14). Across the six stores, eighteen food types were major contributors to macro- and micronutrients (Tables 5 and 6). Due to both volume purchased and fortification, bread (mainly as white bread) was a major source of many nutrients. Fresh vegetables and fruit were either major or moderate sources of β-carotene, Mg, vitamin C and folate in all stores. Beef and/or processed meat were major protein and Zn sources in all stores, except Store 6. Processed meat (mainly as canned meat) was a moderate source of saturated fat in all stores. For all stores, milk was a major or moderate source of nearly all nutrients. In addition to milk, margarine was a major source of total fat in all stores and a moderate source of saturated fat, except for Store 2 where butter was a moderate source. Bread, savoury sauces, processed meats and baking powder (used daily for making ‘damper’ – a home-made bread product often cooked on an open fire) were either major or moderate sources of Na. Table sugar and sugar-sweetened drinks (cordials, fruit drinks and soft drinks) combined contributed 62·0 (sd 7·8) % of total sugar availability.
equiv., equivalents; RE, retinol equivalents; α-TE, α-tocopherol equivalents.
*This is likely vegetables, as point-of-sale data on fruit and vegetables for Store 5 were not itemised and vegetables in the other community stores contributed most to β-carotene.
Discussion
The present research has shown that point-of-sale data can be used to assess the dietary quality of food sales in remote community stores. It can provide valuable data on nutritional composition of food purchases, volume sold and expenditure patterns.
In the six study stores, despite some inter-community differences and variation in contribution of energy to overall community energy requirements, there were notable consistencies across communities in expenditure patterns, nutrient profile and nutrient sources: (i) high sales of refined carbohydrates (mostly bread and added sugar) that were also major sources of energy; (ii) high sales of added sugars (mostly table sugar and sugar-sweetened beverages) that were also major sources of total sugar; (iii) low sales of fruit and vegetables; (iv) few major sources of Na; and (v) several limiting nutrients, to a large extent explained by relatively low sales of wholegrain cereals and fruit and vegetables.
In many respects this reported food purchasing pattern and macronutrient profile is similar to that reported over two decades earlier by Lee et al. in six remote Northern Territory stores(Reference Lee, O'Dea and Mathews12): high relative sales of sugar-sweetened soft drinks, white bread and table sugar, and low fruit and vegetable sales, and is consistent with that reported for economically marginalised groups in Australia and other affluent Western societies(Reference Drewnowski and Specter17, Reference Giskes, Turrell and Patterson18). In Australia, the most disadvantaged population group is paying more than 40 % more for food than the urban population(19); and high-energy, nutrient-poor foods such as refined cereals, fats and added sugar foods are the cheapest source of energy(Reference Brimblecombe and O'Dea20).
Modest improvements in community-level dietary quality and corresponding changes in serum biochemical markers in remote Indigenous Australia have been achieved by targeting increased consumption of specific foods and food groups through structural and community mobilisation strategies(Reference Rowley, Daniel and Skinner5, Reference Lee, Bailey and Yarmirr6). Subsequent community-based interventions in Australia and store-based interventions overseas(Reference Gittelsohn, Song and Suratkar21) have also targeted similar foods and reported modest but positive shifts in the sales of these foods in relation to intervention effect(Reference Rowley, Su and Cincotta22–Reference Lee, Hobson and Katarski24). Most of these studies have used store invoice or point-of-sale data to measure intervention effect and have targeted specific foods or food groups rather than nutrients. The similarities in patterns of food expenditure, nutrient quality and sources of key nutrients shown in the present study suggest potential in the use of remote community store point-of-sale data to: (i) provide an estimate of population-level dietary intake and (ii) monitor trends in dietary intake across communities using key indicator foods; thus providing relatively real-time information to inform strategy and policy development for nutrition improvement in remote Aboriginal communities. Monitoring indicator foods that reflect key nutrients of concern alleviates the need for resource-intensive nutritional analysis. However, ensuring the continued relevance of indicator foods as new issues emerge or as people's food choices diversify would require periodic nutritional analysis of point-of-sale data or checking against other sources of dietary information (which to date have not been available).
The use of point-of-sale data as an estimate of population-level dietary intake depends on the contribution of the store to the overall population-level diet. In urban settings in the UK and New Zealand, supermarket sales data have been shown to be a valid source of information on household food and nutrient availability where supermarket foods contribute most to diet(Reference Tin Tin, Ni Mhurchu and Bullen7, Reference Ransley, Donnelly and Khara25). Fat and energy intakes of households that spend 60 % or more of their food money at supermarkets have reliably been estimated using sales data(Reference Ransley, Donnelly and Khara25). Individual nutrient intake has been estimated using household supermarket sales data(Reference Eyles, Jiang and Ni Mhurchu26) and an association between household obesity and higher-fat food purchasing has also been shown(Reference Ransley, Donnelly and Botham27). Further, a study in Finland reported similarity between sales of specific food products and reported dietary intake(Reference Narhinen, Berg and Nissinen28). In the 1980s in remote Australian communities, store invoice data assessed over a 3-month period were shown to provide a reliable estimate of community-level dietary intake as the store was the primary food source(Reference Lee, Smith and Bryce4). Similarly, point-of-sale data are likely to provide a strong estimate of population-level dietary quality in remote Australian communities, as the store is still the primary food source in most communities; distances between communities and neighbouring communities or towns are generally greater than 100 km; competing food businesses are uncommon; and food services such as aged-care programmes and school lunch programmes that are in operation in most communities service a small proportion of the total population(Reference Brimblecombe, Mackerras and Clifford2). The contribution of locally procured or produced food to overall diet is thought to be minimal in remote communities(Reference Lee, Smith and Bryce4); however, this has not been comprehensively examined.
There are a number of inherent limitations in using point-of-sale data to assess dietary quality of food sales that need to be considered in view of these findings. First, food sales provide an estimate of food and nutrient availability, not actual intake, as information on the volume sold and nutrient content of store foods does not always account for preparation or cooking methods, nor does it account for wastage after purchasing. Comparisons of nutrient availability with nutrient requirements may therefore be overestimated. Second, errors at the point of sale or poor maintenance of a point-of-sale system can impact on the quality of food sales data reported. For example, food items that do not have a corresponding universal product identifier (barcode) and cannot be scanned at the point of sale may be incorrectly entered into the point-of-sale system(Reference Tin Tin, Ni Mhurchu and Bullen7). This generally applies to only a small number of products as it is in the best interest of a food retail business to account for all products and ensure correct pricing. Items can also be entered into the point-of-sale system without a corresponding identifiable product description. This occurred for a minimal number of items in the present study and was rectified through identifying the product with the store manager. Items without a universal product identifier may also be given a common product code, such as occurred for fruit and vegetables in Store 5. Lastly, the weight of some food items may not be shown with the product description and must therefore be derived by other means, such as through searching a product weight online or actual weighing of the food item. Our experience in using point-of-sale data is that ongoing use of data and reporting data issues to store managers assist in improving the quality of the point-of-sale system. Rigorous data checking is needed, however, to assure data quality.
Caution must be applied in the estimates of community-level energy requirements reported in the present study as these are dependent on population size estimates which are known to be problematic for remote Australian communities(Reference Lee, Smith and Bryce4). A strength of our study is the use of nutrient density (nutrient amount per 1000 kJ), which is independent of population size and therefore allows comparison across communities(Reference Lee, O'Dea and Mathews12). A 3-month period was assessed in the present study. A longer study period and a larger sample of community stores would enable a more comprehensive evaluation of food and nutrient patterns across stores and seasonal variation to be assessed. Despite these limitations, the advantages of point-of-sale data as a measure of dietary quality exceed the limitations as traditional means of dietary assessment are notoriously incomplete, expensive and inherently challenging to conduct(Reference Beaton, Milner and McGuire29, Reference Harrison30). Caution must also be applied in making comparisons with wider Australia as the only dietary data available for the wider Australian population are now dated.
The present study has international relevance. It contributes importantly to methods in the use of point-of-sale data to assess dietary quality of food sales and population-level dietary quality. Through the study we developed an automated tool to upload point-of-sale data and assign food items to food groups and corresponding nutrient composition using step-by-step automated procedures. This tool minimises potential coding errors, allows for rigorous, step-by-step point-of-sale data checking and allows for automated and timely reporting of dietary quality. We have applied this methodology to monitor point-of-sale data longitudinally and to evaluate nutrition-related interventions on food sales in multiple stores(Reference Brimblecombe, McDonnell and Barnes31).
Conclusions
Point-of-sale data offer an objective, cost-efficient and unobtrusive measure of dietary quality of food sales which places no burden on individuals and with few of the limitations associated with individual dietary assessment methods(Reference Tin Tin, Ni Mhurchu and Bullen7, Reference Hamilton, Ni Mhurchu and Priest11). Store point-of-sale data in remote Australian communities may provide an estimate of population dietary intake, however this needs further examination. There is great potential for the development of a food and nutrition monitoring system for remote communities based on point-of-sale data in Australia and in similar overseas contexts where the store is the primary food source and where communities are distanced from alternative food sources.
Acknowledgements
Sources of funding: This work was supported by the National Health and Medical Research Council (NHMRC; grant numbers 124319 and 320860); an NHMRC Public Health Fellowship (number 545253); and the Remote Indigenous Stores and Takeaway (RIST) project. Conflicts of interest: There are no conflicts of interest. Authors’ contributions: J.B. designed the study, analysed the data and wrote the manuscript. R.L. contributed to database design and management, data analysis and the manuscript. K.O. contributed to data analysis and the manuscript. Acknowledgements: Appreciation is extended to the six community stores and respective store managers who participated in the RIST project. Thanks to Professor Ross Bailie (Menzies School of Health Research) and Carrie Turner (Senior Nutritionist, Northern Territory Department of Health) for providing feedback on an early draft of this report. Thanks also to the RIST committee members, particularly Vivienne Hobson, Dympna Leonard, Robyn Bowcock and Patricia Carter who provided feedback at various stages of the project.