Step 1: Sales prediction model

The hierarchical Bayesian model to predict sales for the out-of-sample stores as a function of store- and area-level predictors of sales was described previously^{(Reference Mamiya, Schmidt and Moodie8)}. Specifically, the store-level sales of a given food category ${Q_{ij}}$ at store j located in neighbourhood i in 2012 were natural log-transformed to follow a normal distribution. A subset of the sales vector ${Q_i}$ had missing values to be predicted for out-of-sample stores and naturally treated as parameters to estimate following the Bayesian paradigm. The mean of ${Q_{ij}}$ , denoted as ${\mu _{ij}}$ , was specified as

$${\mu _{ij}} = {\beta _0} + {\phi _{c\left[ j \right]}} + {Z_i}$$

$${Z_i} = {A_i}\varphi + {S_i},$$

where the component ${\phi _{c\left[ j \right]}}$ is a random effect representing store chain c to which store j belongs. The random effect accounts for chain-level environmental features, such as product pricing, availability (number of food items) and marketing activities such as flyers and display promotions, which tend to synchronise strongly across stores sharing the same chain identification codes.

Neighbourhood-level attributes are captured by ${Z_i}$ . Its component ${A_i}$ represents a vector of a store’s neighbourhood socio-demographic and economic predictor of sales obtained from the 2011 National Household Survey⁽²⁸⁾. They are area-level median family income, education as the proportion of individuals over the age of 25 who have post-graduate certificate or diploma, population density as the number of residents per square kilometre, proportion of residents under 18 years old, family size as the mean number of family members and employment rate as the proportion of those in the labour force employed in full- or part-time work. The corresponding coefficients are denoted as $\varphi $ . An area-level random effect, ${S_i}$ , accounted for a spatially correlated latent (residual) effect in sales as described in online supplementary material, Supplemental Appendix S4 along with the specifications of prior probabilities. Codes are provided in in a separate file named as SupplementaryTextFile1_code1.docx.

Step 2: Calculation of area-level purchasing from store-level sales using the Huff gravity model

The Huff model uses travel cost and store size to model the shopping trip of residents from their residential area to stores^{(Reference Huff9)}. For a given food category, the probability, ${\pi _{ij}}$ , of residents in neighbourhood $i$ choosing each alternative store j is derived from a discrete store choice model:

$${\pi _{ij}} = {{a_j^\gamma d_{ij}^{ - \lambda }} \over {\sum\nolimits_{j = 1}^J {a_j^\gamma } d_{ij}^{ - \lambda }}},$$

for $i = \left\{ {1, \cdots ,I} \right\}$ , where I = 193 neighbourhoods and $j = \left\{ {1, \cdots ,J} \right\}$ , where J = 1097 stores for sodas and 311 stores for yogurts. The attraction of store, ${a_j}$ , is frequently measured by store size (e.g. square footage) with the coefficient ${\rm{\gamma }} \gt 0$ , which we approximated with the number of employees in each store. The variable ${d_{ij}}$ represents the travel cost as defined by the shortest street distance in kilometres between the centroid of neighbourhood i and destination store j, with the distance decay coefficient $\lambda \gt 0$ . Our definition of distance between neighbourhoods and stores accounts for travel through the nearest bridge, if stores and neighbourhoods were separated by the body of water. We calculated the shortest network path for each store-neighbourhood pair using Dijkstra’s routing algorithm available in the pgRouting module in the PostGIS geospatial database⁽²⁹⁾. These store-visit probabilities are identical for the four food categories.

Empirically evaluated and commonly used value to accurately predict store visit in an urban setting is 2·0 for the distance decay (thus power decay of 2·0), and the value of 1·0 for the attraction coefficient^{(Reference Huff9,Reference Dolega, Pavlis and Singleton30–Reference Huff and McCallum33)} . While the coefficients are ideally estimated from a shopping-related local travel data^{(Reference Nakanishi and Cooper32,Reference Huff and McCallum33)} , such data are uncommonly available to date (including our study) due to the cost of administering a large-scale mobility survey^{(Reference Huff and McCallum33)}. We therefore adopted the aforementioned values of $\lambda = 2.0$ and ${\rm{\gamma }} = 1.0$ . In sensitivity analyses, we varied the values of the attraction and distance decay parameters (online supplementary material, Supplemental Appendix S5).

The calculated store-visit probabilities were used to allocate store-level sales to surrounding neighbourhoods. For I = 193 neighbourhoods and J = 1097 (311 stores for yogurts) stores, the visit probability ${\pi _{ij}}$ populates $I \times J$ origin-destination (i.e. neighbourhood-store) matrix, whose rows are multiplied with population size of area i, ${C_i}$ :

$$G = \left[ {\matrix{ {{\pi _{11}}{c_1}} \cr {{\pi _{21}}{c_2}} \cr \vdots \cr {{\pi _{I1}}{c_I}} \cr } \matrix{ {{\pi _{12}}{c_1}} \cr {{\pi _{22}}{c_2}} \cr \vdots \cr {{\pi _{I2}}{c_I}} \cr } \matrix{ {{\pi _{13}}{c_1}} \cr {{\pi _{23}}{c_2}} \cr \vdots \cr {{\pi _{I3}}{c_I}} \cr } \matrix{ {} \cr {} \cr \ddots \cr {} \cr } \matrix{ {{\pi _{1J}}{c_1}} \cr {{\pi _{2J}}{c_2}} \cr \vdots \cr {{\pi _{IJ}}{c_I}} \cr } } \right],$$

where the measurement of C was provided by the 2011 Canadian Census⁽²⁸⁾. The column-normalised version of the matrix, ${G^*}$ (i.e. columns sum to 1, a constraint used to ensure that the store-level quantity of sales was not changed), is multiplied with the $J \times 1\;$ vector of the exponentiated predictive distribution of store-level sales $Q$ to generate the vector of area-level purchasing quantity in serving, X as

$$X =G^\ast exp\left(Q\right). $$

Thus, $\;{X_i} = \;\mathop \sum \limits_{j = 1}^J {\pi _{ij}}{C_i}exp\left( {{Q_j}} \right)$ . In other words, ${X_i}$ represents the predicted distribution of purchasing quantity for neighbourhood i calculated as the weighted sum of the posterior distribution of the vector $Q$ consisting of predicted sales from J stores, for a given food category. We then divided these quantities by the number of residents in each neighbourhood to generate our indicator of small-area purchasing that represents per-person purchasing quantity in each neighbourhood.

We note that there were fourteen inhabited small areas (fourteen rows in $G$ matrix above) that contained no supermarket, pharmacy and supercentre in the CMA of Montreal in 2012, even though residents in these areas shop at stores in surrounding areas. The gravity model allowed generating the measure of food purchasing in these areas despite not containing any stores; in other words, the computed sum of these fourteen rows across columns in the matrix is non-zero. This is because these areas received a portion of sales from each store, or ${\pi _{ij}}{C_i}exp\left( {{Q_j}} \right)$ , from other neighbourhoods proportional to the value of store visit probability and population size in these areas. These values reflect the shopping-related flow of residents across neighbourhood boundaries. Note that without consideration of mobility across neighbourhoods, the store visit probability will be binary, simplifying to ${\pi _{ij}}= 1\;$ if stores j is located in neighbourhood i, and zero otherwise. Therefore, the matrix will have a large number of zeros, unrealistically assuming that residents shop only in store(s) located in their own neighbourhood.

Step 3: Application of the indicators to a model-based small-area estimation of diabetes risk

We added the small-area indicators of purchasing into disease mapping, the primary spatial epidemiologic and geographic surveillance method to estimate areal-level disease risk using a hierarchical Bayesian model^{(Reference Waller and Carlin34)}. The above-mentioned prevalent T2D count in the i ^th area, ${y_i}$ , is assumed to follow a Poisson distribution with mean ${e_k}{\theta _k}$ , where ${e_k}$ is the expected number of cases (i.e. offset) calculated by indirect standardisation with age as detailed in online supplementary material, Supplemental Appendix S6. The outcome of interest for disease mapping, the area-specific relative risk, ${\theta _i}$ represents the deviation of risk from the expected count: an area i has higher occurrence of cases if the posterior summary of ${\theta _i}$ (e.g. 95 % credible interval (CI)) is greater than 1. The relative risk is modelled as:

$$log({\theta _i}) = {\beta _0} + {G_i}\gamma + {X_i}\beta + {b_i},$$

where ${\beta _0}$ is an intercept, and ${G_i}$ is a vector of area-level covariates associated with T2D with the corresponding coefficient vector $\gamma $ . These covariates are education and median family income used in the sale description models and the proportion of immigrants calculated from the 2011 Canadian National Household Survey⁽³⁵⁾. The covariates also include the availability of recreational facilities encouraging physical exercise (the number of facilities per resident) obtained from the Canada Business Point data, which are annually updated business enumeration data and validated previously for the accuracy of business locations^{(Reference Daepp and Black36,37)} . The availability of recreational facilities was calculated as the number of facilities divided by 1000 residents for each neighbourhood, where recreational facilities were defined based on the Standard Industry Classification codes as previously described^{(Reference Boone-Heinonen, Diez-Roux and Goff38)}. The vector of our indicators (neighbourhood-level per-resident purchasing quantity for the four food categories) and their coefficients are ${X_i}$ and $\beta $ , respectively. To account for spatial autocorrelation and Poisson overdispersion of the disease risk, we added an area-level random effect ${b_i}$ as specified in online supplementary material, Supplemental Appendix S7; codes are also provided (SupplementaryTextFile2_code2.docx).

To investigate whether the addition of our indicators improved the disease risk estimation or not, we investigated their posterior 95 % CI. To supplement model selection where we compared goodness of model fit with and without the indicators, we computed fully Bayesian estimates of pointwise predictive density by Watanabe–Akaike information criterion and approximate leave-one-out cross-validation^{(Reference Vehtari, Gelman and Gabry39,Reference Gelman, Hwang and Vehtari40)} . A lower value indicates better model fit. However, evaluating goodness of it using these metrics requires some caution, as the measures of pointwise predictive errors generally do not acknowledge the spatially structured nature of data^{(Reference Vehtari, Gelman and Gabry39,Reference Gelman, Hwang and Vehtari40)} . We also note that the fully Bayesian approach would jointly estimate the posterior distribution of T2D risk (step 3) and indicators (step 1 and 2), therefore propagating the uncertainty of step 1 and 2 to the distribution of the parameters generated in step 3. We did not take this approach and ran step 3 independently, since the indicator generation step, the main goal of this research and downstream applications of these indicators for public health research and practice (e.g. surveillance) will be inherently disjointed. This is because the indicators are likely to be a priori estimated and disseminated by analysts for use by third parties.

We note that both sales prediction and T2D model include income and education as their covariate. Thus, if the store-level sales were strongly or predominantly driven by income and education, our proposed indicators may simply represent the information (i.e. spatial distribution and posterior distribution of regression coefficients) of these two variables, which is redundant and may in fact exhibit collinearity with neighbourhood education and income in the T2D model. Therefore, we performed another sensitivity analysis, where we generated the proposed indicators with modified sales models excluding the neighbourhood-level covariates, including education and income. The estimated posterior mean and 95 % CI of the regression coefficients for income, education and the proposed indicators in the T2D model were then compared with that of the coefficients in the T2D model in the main analysis.