Study design

The current study uses a matched comparative interrupted time-series design to take advantage of changes in policies to assess any differences in countries with v. without the change^{(Reference Meyer23)}. We compare twenty-one countries, from 2002 to 2016: ten countries joining a US FTA between 2004 and 2012 (exposed group) and eleven matched countries without a US FTA as of 2016 (unexposed group). Of all twenty countries with a US FTA currently in force, ten could not be included in the exposed group – three of these countries’ agreements entered into force before the period of available data and in the other seven countries, no data were available for the outcomes of interest. The post-exposure period in each exposed country was defined as beginning on the date of entry into force of its US FTA. The treaty negotiation process can last several years, but the date of entry into force reflects the time when provisions become enforceable and is therefore most meaningful as the exposure date for the current analysis⁽²⁴⁾.

Four primary outcomes were examined: total sales of (i) minimally processed foods; (ii) processed culinary ingredients; (iii) ultra-processed products and (iv) baby food. The first three outcomes utilise the classification scheme developed by Monteiro et al., which categorises products based on the ‘extent and purpose of food processing.’^{(Reference Monteiro, Levy and Claro25)} Table 1 lists these four outcomes and the data elements summed to generate each.

Table 1 Composition of study outcomes

* Definitions of individual product categories (from Euromonitor International) are provided in the online supplementary material.

Data sources

Data for all outcomes come from the Euromonitor International Passport Global Market Information Database (GMID), which reports annual retail sales based on data compiled from company reports, industry publications, government statistics and interviews⁽²⁶⁾. This dataset is widely used in studies exploring national dietary trends as a proxy for consumption^{(Reference Stuckler, McKee and Ebrahim19–}Reference Schram, Labonte and Baker²¹⁾. The database covers eighty countries; data for 2002–2016 were available at the time of the current study. All outcomes were measured in kilograms per capita (using only the population under age 5 for baby food). Baby food data from Hong Kong were excluded because extremely high values coincided with an epidemic of infant deaths in China tied to tainted formula^{(Reference Jiang27)}, which created abnormally high demand for alternative brands available in Hong Kong.

Key confounders established by the existing literature on the relationship between trade and investment liberalisation and dietary consumption were included as covariates: gross domestic product (GDP) per capita, the proportion of the population living in an urban area (urbanisation rate) and the female labor force participation (FLFP) rate among women aged 15 and older. Covariate data are from the World Bank World Development Indicators⁽²⁸⁾ (FLFP rate), the United Nations Population Division (UNPOP)⁽²⁹⁾ (urbanisation rate) and the World Bank (GDP per capita) ⁽³⁰⁾.

Possible confounding due to membership in the following other trade and investment agreement was also explored: US BIT, EU FTA, EU international investment agreement (IIA), Switzerland FTA and Switzerland BIT. Membership in a US BIT is a potential confounder because these agreements liberalise investment opportunities for US corporations, and agreements with the EU or Switzerland may have similar effects because other leading TFBCs are based in these countries. Information on membership in these agreements was obtained from the Office of the US Trade Representative⁽¹⁵⁾, the US Office of Trade Agreements Negotiations and Compliance⁽¹⁶⁾, the European Commission⁽³¹⁾, the Switzerland State Secretariat of Economic Affairs⁽³²⁾ and the United Nations Conference on Trade and Development^(33,34) .

Matching

A limitation of this observational data is non-random assignment of the exposure, that is, countries that enter a US FTA may differ from those that do not^{(Reference Stuart35)}. Coarsened exact matching (CEM) is one approach to improve comparability across the groups and strengthen conclusions about causality, by splitting variables into meaningful categories, identifying exact matches on those categories and weighting unexposed units to reflect the number of exposed units with the same set of characteristics^{(Reference Blackwell, Iacus and King36)}.

CEM was used to identify matches based on the following variables: world region, country income level and WTO membership status. World Bank classifications were used for region and income level⁽²⁸⁾. Of sixty-five unexposed countries with all required data, eleven were matched to the exposed group using these criteria; remaining unexposed countries were excluded from the analysis because they had no match. Table 2 shows the five strata formed by CEM, the matched characteristics and the countries in each. Table 3 provides mean values of all outcome variables and covariates, by exposure group, in the baseline year, 2002.

Table 2 Exposed and unexposed group countries in each of five strata formed by coarsened exact matching

WTO, World Trade Organization; FTA, free trade agreement.

* Region and income group based on World Bank classifications for fiscal year 2016, using gross national income per capita in US$: low income (≤$1025), lower-middle income ($1026–$4035), upper-middle income ($4036–$12 475), high income (>$12 475)⁽⁴⁶⁾.

Table 3 Baseline characteristics and tests for significant group differences between exposed countries and all unexposed countries and matched unexposed countries

WTO, World Trade Organization.

Matched unexposed means and counts for all variables are weighted to reflect the number of exposed countries in each strata (in some cases, weighting results in non-integer counts). Standardised difference in means = (unexposed group mean – exposed group mean)/(combined sd).

Results from two-sided t tests (unweighted data) and adjusted Wald tests (weighted data) presented for continuous variables; results from χ2 tests (unweighted data) and F tests (weighted data) presented for categorical and binary variables.

*P ≤ 0·05; **P ≤ 0·01.

† Variable used for matching.

‡ Excludes data for Hong Kong.

Outcome models

The impact of joining a US FTA on each of the outcomes was investigated using separate linear regression models. Comparative interrupted time-series analysis relies on the inclusion of a treatment term (in this case, FTA membership) and treatment-year interaction term to compare the pre- and post-exposure level and trend, respectively, in the exposed v. unexposed groups^{(Reference Linden and Adams37)}. For exposed countries, the FTA membership variable ranged from 0 (before joining) to 1 (after joining), with a fraction reflecting the number of days in force during the year each country’s FTA entered into force. Each model incorporated the CEM weights, included potential confounders and had the following basic form:

$${\rm{Outcom}}{{\rm{e}}_{ij}} \sim {b _0} + {b _{1}}{\left( {{\rm{year}}} \right)_{j}} + {b _{2}}{\left( {{\rm{FTA}}\,{\rm{membership}}} \right)_{ij}} + {b _{3}}{\left( {{\rm{FTA}}\,{\rm{membership}} \times {\rm{year}}} \right)_{ij}} + {b _{4}}{\left( {{\rm{log}}\,{\rm{GDPpc}}} \right)_{ij}} + {b _{5}}{\left( {{\rm{urbanization}}\,{\rm{rate}}} \right)_{ij}} + {b _{6}}{\left( {{\rm{FLFP}}\,{\rm{rate}}} \right)_{ij}} + {e _{ij}}$$

where i indexes country; j indexes year (2002–2016); b’s represent model coefficients and e is the residual error. All covariates were time-varying. Alternative models explored the inclusion of membership in the other trade and investment agreements as additional covariates.

Models for each outcome were built in a forward stepwise manner, starting from a model with only the treatment and control variables described above. First, the optimal way to model the relationship to time was examined by comparing the inclusion of a linear year term and year fixed effects. To account for autocorrelation in the longitudinal data, an exchangeable structure was imposed on the residuals, after examining the shape of the autocorrelation function of each outcome. The best-performing models were selected based on Wald tests, as well as visual inspection of graphs of model-predicted values compared with observed values, by country. Model fit graphs are provided in the online supplementary material (Appendix B). The fit statistics and graphs both supported the year fixed effects model as preferable for all outcomes.

In the second step, three alternative sets of additional terms were tested to capture remaining unexplained country-specific variation: a country random intercept, a country random intercept and country random slope on year and country fixed effects. In models with a random intercept and random slope, an unstructured model was used for the covariance to permit correlation between these two parameters. Graphs of model-predicted values compared with observed values supported the model with a random intercept and random slope as the best-performing for all outcomes.

Sensitivity analyses

Two sensitivity analyses were conducted to examine the impact of modelled or missing data on the estimated treatment effects. First, the minimally processed food outcome model was re-estimated without data from the seven (out of twenty-one) countries for which any data were marked as modelled (data for this outcome only were affected); an additional country (Chile) was also excluded because its only matched unexposed country (Uruguay) was dropped by this process. As a result, this model was estimated with six exposed and seven unexposed countries. Second, the model for ultra-processed products was re-estimated without data for ready-to-drink coffee and ready-to-drink tea because of high missingness in these two products’ data.

A third sensitivity analysis was conducted to examine the influence of Venezuela as a member of the unexposed group. Venezuela is experiencing a food shortage, which started with food rationing in 2014⁽³⁸⁾, possibly making this a poor comparison country for these outcomes. Each of the outcome models was rerun with Venezuela excluded from the unexposed group and the remaining three countries in Venezuela’s strata upweighted to account for its removal. All analyses were conducted in Stata 14.2.