The Dutch Choices label

The Dutch Choices label, which is displayed in Fig. 1,Footnote * is a criteria-based labelling system that certifies whether a specific product is a healthy choice within the product category in question. It is, hence, a logo-type label that is displayed only on products that fulfil the requirements^{(Reference Kanter, Vanderlee and Vandevijvere15)}. A healthy choice is defined based on the levels of SFA, added sugar, salt, dietary fibre and/or energy in the product with the criteria for the label being revised periodically. The actual criteria applied depend on the product category being considered. The Dutch Choices, the use of which is voluntary among producers, was implemented in 2006 by a multi-stakeholder board. Membership of the Choices organization is necessary in order to be able to apply for permission to display the label, although the fee is marginal for producers and depends on the annual turnover of a company. On average, small companies pay about €900 per year. The fee increases incrementally until it reaches a maximum of €100 000 for companies in the highest turnover class. A national agent ensures that the requirements have been fulfilled prior to certifying that the producer may display the label^{(Reference Dötsch-Klerk and Jansen35)}.

Fig. 1 The Dutch Choices label

Variables

To be able to investigate whether displaying the Choices label on a product causes households to purchase more of that product, we constructed a dummy variable j ∈ (0,1), taking the value j = 1 for products that at some point got the Choices label (this is our treatment group) and j = 0 for products that did not at any time during the data period get the label (this is our control group). The j dummy is time-invariant, taking the value of 1 during the whole period if the specific type of product got the Choices label during the period of the study. In the remaining part of the paper, we refer to these as eligible (j = 1) and non-eligible (j = 0) products, respectively. We acknowledge that there may be products that did not apply for the Choices label throughout the period, even though they were eligible. Information about whether a product was eligible, regardless of whether it actually displayed the label during the data period, would have been preferable, but unfortunately this was not available.

The volume share of our treatment group products (i.e. products that at some point displayed the label) is called share_eligible, which was calculated for each individual household i in each time period t as:

(1) $$share\_eligibl{e_{it}} = {{volum{e_{it,j = 1}}} \over {\mathop \sum \nolimits_j volum{e_{it,j}}}}$$

We also constructed a dummy variable indicating whether a product within a product type actually displayed the label (k = 1) or not (k = 0). This dummy can vary over time, which implies that the product only takes the value k = 1 on the date when it obtained the label and thereafter. After constructing the dummy, we aggregated over households and calculated the fraction of the eligible products that actually displayed the label. This variable share_display_label is, hence, similar for all households and represents the supply of products that displayed the label (i.e. this is our treatment variable):

(2a) $$share\_display\_labe{l_t} = {{\mathop \sum \nolimits_i volum{e_{it,k = 1}}} \over {\mathop \sum \nolimits_i \mathop \sum \nolimits_{k} volum{e_{it,k}}}}$$

By estimating the effect of share_display_label on share_eligible, while controlling for other factors that can affect the purchase of products, we can see whether displaying the label on products (i.e. the treatment) increased the volume share of eligible products purchased for the individual households.

The share_display_label, which was constructed as an average over households, might be endogenous since the purchases of the individual household affect the overall average. This effect is, however, considered to be very small since the number of households was large and each individual household, therefore, contributed only a small fraction to the average. Still, as a sensitivity analysis, we also calculated the number of distinct products (based on the European Article Number, or EAN-code) that displayed the label at each point in time and used this as the main explanatory variable:

(2b) $$numb\_display\_labe{l_t} = \mathop \sum eancode{s_{t,k = 1}}$$

This measure prevents the endogeneity from households affecting the overall market share. However, it does have a disadvantage since, in this approach, a product that constitutes only a minor share of the market will count equally as a product that has a large market share. This implies that when we use the number of products displaying the label as explanatory variable, the size of the treatment will not be reflected in the estimation.

Statistical analysis

The explained variable, share_eligible, describes the volume share of products that at some point displayed the Choices label. This variable is restricted by the values 0 and 1 and can take any value in between. For example, households that purchased only eligible products have share_eligible = 1. Households that did not purchase any products that were eligible for the label have share_eligible = 0. Many households purchased a volume share somewhere in between. For models with explained variables that take this format, a two-sided censored Tobit model is suitable^{(Reference Tobin36)} since it does not provide predictions outside the possible range (smaller shares than 0 or larger shares than 1). This model defines the explained variable in terms of an underlying latent variable (y* = Xβ+u), where X represents the explanatory variables in the analysis (e.g. product and household characteristics) and β is a vector of coefficients to be estimated. The underlying latent variable y* is not observed, but can be expressed in terms of the observed variable y (i.e. share_eligible). The observed explained variable equals the latent variable when the latent variable is between 0 and 1, while it equals 0 for values smaller than or equal to 0 and it equals 1 for values of 1 and above. This ensures that the probabilities for all outcomes lie between 0 and 1. The two-sided Tobit model enables estimation of both the probability and the expected volume share of eligible products purchased (see equations (a1), (a2) and (a3) in the online supplementary material, Supplemental File A). Importantly, with this model specification, we can investigate whether the overall market share of products that displayed the Choices label on the packaging affected the volume share of eligible products purchased (share_eligible).

The non-linearity of the Tobit model implies that the partial effects (i.e. how changes in share_display_label affect share_eligible) depend on all explanatory variables in the model. This can be addressed by calculating the average partial effect (APE), which is obtained by calculating the partial effect for each of the households in the sample and then taking the average over all households (see equations (a4) and (a5) in Supplemental File A).

Data and empirical specification

The data used for the analysis are purchase data provided by the GfK Consumer Scan Panel in the Netherlands,Footnote * where members of the panel scan all their food purchases on a daily basis. The panel is representative of the population with respect to basic sociodemographic characteristics and covers households from the whole country. The purchase data provide information about the price and size of the product, store type, whether it is organic, and whether the product is a company brand or the store’s own brand. The panel is unbalanced, which implies that the number of households in the data set varies over time. Data also include information about the labelling status as well as the month and year that the specific product started to display the Choices label. The data cover one year prior to the introduction of the label in 2006 and the following three years after the launch until the end of 2008. The panel structure of the data enables us to control whether the overall market share of products displaying the label on the packaging affects the volume share of eligible products purchased for individual households. This is similar to estimating the average treatment effects, where the treatment groups comprise products that are eligible for the Choices label and the control group comprises the remaining products within that food group. The treatment is the actual display of the label on the packaging. The model for the latent variable, estimated for each of the food groups, is:

(3) $$\[\begin{align} \and y_{it}^{*} \and ={{\beta }_{0}}+{{\delta }_{1}}y06+{{\delta }_{2}}y07+{{\delta }_{3}}y08+\sum\limits_{m=1}^{11}{{{\delta }_{m}}{{s}_{m}}} \\ \and +{{\beta }_{1}}share\_display\_labe{{l}_{t}}+{{\beta }_{2}}share\_organi{{c}_{it}} \\ \and +{{\beta }_{3}}share\_ownlabe{{l}_{it}}+{{\beta }_{4}}share\_discoun{{t}_{it}} \\ \and +{{\beta }_{5}}share\_supe{{r}_{it}}+{{\beta }_{6}}rel\_pric{{e}_{t}}+\sum\limits_{h=1}^{H}{{{\beta }_{h}}{{s}_{h}}+{{a}_{i}}+{{u}_{it}}} \end{align}\]$$

where a_i is unobserved, time-invariant household specific heterogeneity and u_it is random noise assumed to be ∼N (0, σ ²). The remaining variables are described in Table 1. The model specification (3) is the main model. In constructing the variable share_display_label, we assume that each household has only a marginal influence on this average. For robustness, we estimate the same model (equation (3)), but replace share_display_label with numb_display_label to verify whether the results are similar. A discussion of the differences between these results is included in the ‘Results’ section.

Table 1 Description of explanatory variables in the model

* (av) for average indicates that it is a variable that is common to all households.

† (base) indicates that this is used as the base level in the estimation.

The food categories included in this analysis were selected to cover different types of food where Choices-labelled products where available. Moreover, both typically healthy and less healthy food categories were included, as well as food categories that are both part of a standard diet and other categories that are more luxurious or convenient types of food. Based on these criteria, the following five main categories were considered: milk, yoghurt, sauces, cereals and fats/oils. Data for other food categories could have been obtained, but for data quality reasons, they were considered less suitable. These five categories are subdivided into eighteen food groups, which are presented in Table 2 in the ‘Results’ section below. The data are aggregated into either monthly or quarterly volume shares depending on the shelf-life of the products in that food group and, hence, the purchase frequency. This is done mainly to ensure equality between purchase and consumption and to limit the number of zero purchases to a reasonable level. To ensure that the level of aggregation does not drive the results, models for the less frequently purchased food categories, i.e. fats/oils, cereals and sauces, are estimated based on both a monthly and quarterly aggregation level. This does not change the results. The level of aggregation is, likewise, noted in Table 2. The models we estimate are all based on equation (3), but differ in product specific explanatory variables and whether monthly or quarterly dummies were used to account for seasonality. To take into account the serial correlation induced in the model by unobserved heterogeneity, random-effects Tobit models are estimated using the statistical software package Stata version 14.2.

Table 2 Data statistics, average over the period 2005–2008

HH, households; OBS, observations.

* This is the share of months where zero purchases of eligible products are observed.

† Only averaged over January 2006 to December 2008, i.e. the period where it was possible to get the Choices label.

‡ Averaged over quarters rather than months, due to infrequent purchase rates and long shelf-life.