Characterising the Western dietary pattern

A search through two major databases (Medline and Scopus) reveals that the terms Western diet, total Western diet and Western dietary pattern are often used interchangeably as a reference to a diet that is best described by the following passage:

Depending on research objectives, different studies use different constituents of the Western diet based mainly on American dietary data^(23–24). The research objectives broadly aim at health outcomes (body weight, type 2 diabetes, cancer, etc) or environmental outcomes (greenhouse gas emissions) of the Western diet either as a stand-alone diet or in contrast to other diets (usually Western v. the Mediterranean). Some health-related studies use randomised animal trials and decompose the diet by macronutrient content^{(Reference Shively, Appt and Vitolins25)}. Others use randomised dietary intervention where human subjects are provided with key foods or all foods^{(Reference Mattes, Shikany and Kaiser26)}. Yet others rely on self-reported food and beverage intake in household budget surveys^{(Reference Steele, Baraldi and da Costa Louzada27)}, national statistics on basic food ingredients (sweeteners and oils) and primary (unprocessed) foods reported in FBS, or both^{(Reference Tukker, Goldbohm and De Koning28–Reference Sheehy and Sharma33)}. Studies that examine the environmental consequences of the Western diet also rely largely on national statistics like FBS^{(Reference Vega Mejía, Ponce Reyes and Martinez34–Reference Sáez-Almendros, Obrador and Bach-Faig39)}.

Using American dietary data, Table 1 summarises selected decompositions of the Western diet labelled as such in the literature, their constituents and, where applicable, their respective contributions to energy intake, saturated fats, sodium and added sugars. The decompositions are by macronutrient content, by food item, by degree of processing and by contributions of good groups to the national food supply. Although different decompositions have different constituents with different levels of aggregation, there is congruence between the relatively higher contributions of sugars, oils and fats from plants, meat and eggs to the US national food supply, as reported in FBS, and the relatively higher fat and sugar contents in food items and sugar content of processed foods consumed by households.

Table 1 Alternative decompositions of the Western diet

Characterising cross-country dietary patterns

Short of nationally representative consumer-level survey data on food consumption worldwide by macronutrient, food item or degree of processing, as shown in Table 1, we follow the practice of past studies and tap into FBS to characterise cross-country dietary patterns. Of course, like any other global food consumption database, FBS has limitations^{(40–Reference Micha, Coates and Leclercq41)}. Still, it remains the only standardised, comprehensive and widely used global dietary database that is publicly available and consistent for almost every country for many years.

To characterise a country’s dietary pattern, we adopt the idea behind the Mediterranean Adequacy Index, which uses FBS data to measure a country’s adherence to the Mediterranean diet^{(Reference Da Silva, Bach-Faig and Quintana42,Reference Finardi, Bucchini and Turrini43)} , and formulate for each country a Western Diet Similarity Index (WSI) based on the food items reported in the database. FBS database contains food available from ninety-eight food items in terms of weight (g), calories (kcal), protein (g) and fats (g) per person per day by country.

To construct comparable cross-country WSI, we first adjust the calories from each of the ninety-eight food items for waste, using the waste factors from Behrens et al. ^{(Reference Behrens, Jessica and Kiefte-de Jong36)} (see online supplementary material, Supplemental Table 1), and aggregate the items into twelve bundles: cereals (CRL); roots and tubers (TBR); sugar, sugar crops and sweeteners (SUG); pulses, nuts and oil crops (PNO); vegetables and fruits (VAF); oils and fats from animal sources (OAFA); oils and fats from plant sources (OAFP), red and white meat (MEAT); seafood (SFD); eggs (EGG); milk (MILK) and a miscellaneous category (OTHER). The list of the twelve bundles and corresponding food items are shown in Supplemental Table 2.

Next, we compute a WSI for each country expressed as the proportion of per-capita total calories from animal source foods (ASF = MEAT + OAFA + MILK + EGG), plus oils and fats from plant sources (OAFP) and sweeteners (SUG). We should note that, although oil crops in PNO may suggest overlap with OAFP, which includes oils from plant sources, the oil crops in PNO are a source of vegetable protein. In contrast, oils from plants are separated oil fats that go directly into consumption or as ingredients in other processed consumer food products^{(Reference Gouel and Guimbard44)}.

The composition of WSI draws on the nutrition transition work by Popkin & Gordon-Larsen^{(Reference Popkin and Gorden-Larsen9)}. According to the authors, food groups ASF, OAFP and SUG, which serve as significant sources of fat and/or ingredients in processed foods, constitute the three principal manifestations of the nutrition transition around the world, and, hence, the higher the index, the closer a country’s dietary pattern to a Western one. However, while calories from the FBS food groups we use to construct the index encompass the food groups highlighted by Popkin & Gordon-Larsen^{(Reference Popkin and Gorden-Larsen9)}, the food groups do not allow the sorting out of another important food item in the Western diet: refined grains^{(Reference Cordain, Eaton and Sebastian45)}. Grains, as such, are reported in FBS as calories available for consumption, not actually consumed, and in what form. Since refined grains, in combination with refined oils, refined sugars and dairy products, are used to produce processed foods like bakery goods, breakfast cereals and muffins, to mention a few, WSI captures some of the elements of the omnipresent processed foods one usually associates with the Western diet, but only partially. Table 2 displays the trends in the mean, dispersion, minimum and maximum of the FBS-based WSI and kcal per capita for 172 countries between 1993 and 2013 in 5-year intervals.

Table 2 Trends in Western Diet Similarity Index (WSI) and kcal per capita, 172 countries

β-Convergence: model specification, sample data and hypotheses

β-Convergence occurs when the growth of WSI in the lower WSI countries is faster than the growth in the high WSI countries, meaning that the dietary patterns of countries with lower WSI become more similar to (or catching up with) those of countries with higher WSI. To test for β-convergence, the following regression model is estimated^{(Reference Gil, Gracia and Pérez19)}:

(1) $$\left( {{1 \over T}} \right)\ln \left( {{{WS{I_{it}}} \over {WS{I_{io}}}}} \right) = \alpha + \lambda {\rm{}}lnWS{I_{io}} + {\rm{}}{\epsilon_{it}}$$

where t ₀ is the initial year, t is the terminal year, T is the time interval between the initial and the terminal year and ${\epsilon_{it}}$ is the error term. Equation (1) says that the average logarithmic growth of WSI in country i at time t is a function of the log of the country’s initial level of WSI. For β-convergence to exist, the estimate of λ should be negative and statistically different from zero.

To link β-convergence to the nutrition transition, we allow the slope λ in equation (1) to vary quadratically with per-capita income (INC), globalisation (GLOB) and urbanisation (URB). The idea behind the quadratic specification is that initially, the slope and, hence, the speed of convergence increases with income, globalisation and urbanisation and eventually decreases as countries become more affluent, more global and more urbanised. To capture the quadratic relationship, the slope is written as

(2) $$\lambda = {\lambda _o} + {\lambda _{11}}IN{C_t} + {\lambda _{12}}{\rm{*}}IN{C^2} + {\lambda _{21}}GLO{B_t} + {\rm{\;}}{\lambda _{22}}GLOB_t^2 + {\rm{\;}}{\lambda _{31}}UR{B_t} + {\rm{\;}}{\lambda _{32}}URB_t^2$$

A negative and statistically significant λ means that countries that started initially with lower WSI are catching up with countries with higher WSI.

Once the parameters of (1), in combination with (2), are estimated, they are used to recover three additional measures that describe the growth path of WSI: $\beta = \frac{{ - \ln \left( {1 + \lambda } \right)}}/{T},\;$ the speed of convergence or average growth rate of WSI per year; and the steady-state $WS{I^*} = {e^{ - \frac{\alpha }/{\lambda }}}\;$ , i.e. the value to which WSI converges in the long run.

For data on WSI, we use the FBS data discussed earlier and consider the 1993–2013 period. We follow the econometric approach by Islam^{(Reference Islam46)} and construct a panel data by dividing the 20 years into 5-year time intervals to smooth over yearly spikes and troughs in the global food supply. In this set-up, each country in the sample has four data points, 1998, 2003, 2008 and 2013, resulting in four observations for the dependent and independent variables for each country. The four observations for the left-hand side variable for the ith country are specified as follows:

$$\ln \left( {{{WS{I_{i1998}}}}\over{{WS{I_{i1993}}}}} \right),\ln \left( {{{WS{I_{i2003}}}}\over{{WS{I_{i1998}}}}} \right),\ln \left( {{{WS{I_{i2008}}}}\over {{WS{I_{i2003}}}}} \right),\ln \left( {{{WS{I_{i2013}}}}\over{{WS{I_{i2008}}}}} \right)$$

Each right-hand side variable takes its mean value during the 5-year interval, except WSI_io which takes the value of the denominator of the ratio on the left-hand-side variable. Per capita income INC (in $1000), taken from the Penn World Table⁽⁴⁷⁾, is derived from the expenditure side real GDP at current Purchasing Power Parity. In our panel setting, this allows comparison of cross-country living standards at different points in time. Globalisation is represented by the KOF globalization index developed by the KOF Swiss Economic Institute⁽⁴⁸⁾. The index summarises for each country the extent of trade, financial, interpersonal, informational, cultural and political globalisation. The data source for urbanisation, the urban population as a percent of the total population, is the World Bank⁽⁴⁹⁾. Not all countries had complete observations on the dependent and independent variables, so those with any missing observations during any 5-year interval were excluded. Similar to Gouel & Guimbard^{(Reference Gouel and Guimbard44)}, we also excluded countries whose populations were less than one million inhabitants, as they might have ‘peculiar dietary patterns’. The final panel consists of 545 observations for 137 countries.

The first hypothesis we test is the joint significance of income, globalisation, urbanisation in explaining λ, the slope. This is represented by ${H_o}:\;{\lambda _{11}} = {\lambda _{12}} = {\lambda _{21}} = {\lambda _{22}} = {\lambda _{31}} = {\lambda _{32}}\,=\,0.$ If the hypothesis is rejected, it means that β-convergence is influenced by the three drivers of the nutrition transition.

The second hypothesis is convergence. Convergence is confirmed if the estimate of the slope $\lambda {({\hat \lambda} )}$ given by (2), is negative, i.e. $\hat \lambda = \left( {{{\hat \lambda }_0} + {{\hat \lambda }_1}GD{P_t} + {{\hat \lambda }_{12}}*GDP_t^2 + {{\hat \lambda }_2}*GLO{B_t} + {{\hat \lambda }_{22}}*GLOB_t^2 + {{\hat \lambda }_3}UR{B_t} + {{\hat \lambda }_{33}}URB_t^2} \right) < 0$ and statistically significant from zero. If true, this in an indication that countries that started with lower WSI initially are catching up with countries that started initially with higher WSI.

If convergence is confirmed, the third hypothesis is whether the global steady-state cross-country dietary pattern converges to the Western dietary pattern. This requires choosing a fixed value of WSI. A plausible value is WSI = 70 which represents the American WSI in 2013, implying that the global steady-state WSI will rest at a dietary pattern where 70 % of the calories are derived from animal sources foods, oils and fats and sweeteners. However, it turns out that the respective WSI of Iceland (72) and Switzerland (72) are slightly higher than the American WSI, and that of Australia (69) is just below it and other countries with WSI’s close by. To find out systematically which other countries’ dietary patterns are close to the American dietary pattern, we use the K-means clustering technique. In doing so, we discover fifteen countries belonging to the same cluster in which the United States appears. The cluster, which we label ‘Western diet countries’, is as follows, in descending order of WSI: Iceland (72), Switzerland (72), United States (70), Australia (69), Sweden (67), Hungary (66), France (66), Austria (66), Germany(66), Denmark (66), Czechia (65), Netherlands (65), Spain (65), Belgium (65), Finland (64) and New Zealand (64). The sixteen countries’ population-weighted average WSI is 68. Interestingly and, unsurprisingly, all countries in the cluster belong to OECD, and except for Spain, none is located in Southern Europe, a region commonly associated with the Mediterranean diet.