2.1 PopSim model overview and structure

The PopSim tool builds on the life table method described in Miller and Hurley (Reference Yin, Brauer, Zhang, Cai, Navrud, Burnett and Howard2003). In brief, the model allows users to:

1. (i) Simulate population in the USA by single year of age and gender for years between 1990 and 2060 under alternative assumptions about the degree of hazard posed by air pollution relative to baseline historical and projected Census mortality rates;

2. (ii) Estimate changes in life years relative to a fixed baseline of historical and projected Census mortality rates;

3. (iii) Apply air pollution hazards specific to cause of death and age category; and

4. (iv) Analyze the effect of alternative lag structures on the timing of mortality rate changes following changes in PM exposure (“cessation lag”).

The model includes a library of concentration-response functions for PM_2.5-related mortality, or users can specify their own. Users specify a set of national population-weighted average PM changes at up to five specific points in the study period and can specify the trajectory of PM changes between these points as either a step function or through linear interpolation between target years. If desired, users can also incorporate a PM_2.5 threshold concentration and explore the impacts of varying susceptibility to air pollution by age.

By default, all calculations and results in the model are conducted at the national level, using population-weighted average changes in PM. However, if provided with appropriately scaled life-table and air quality inputs, the model can be applied at alternative spatial scales, as we do in this study for the city of Santiago, Chile. The USA model can be used to estimate changes in mortality risk for years between 1990 and 2060 (1990 and 2050 for the international model). The temporal range provides a “run-up” period using the more highly resolved by-cause mortality data available for historical years and allows for testing of hypotheses on a retrospective and prospective basis.

The model consists of four linked components, as illustrated in Figure 1: Inputs (which includes the Hazard Estimation module); Baseline Life Table; Regulatory Life Table; and Results. The hazard estimation component of the model is integrated into the Inputs module. It applies user-specified parameters to calculate a mortality hazard adjustment factor (MHAF) that scales the baseline mortality hazard in a given year based on cumulative impacts across all previous years in the study period, according to the following equation:

(1) $$ {MHAF}_{j,t}\hskip0.35em =\hskip0.35em 1+\left[\sum \limits_{i\hskip0.35em =\hskip0.35em BaseYear}^t\left[\left({e}^{\beta *\Delta {PM}_i}-1\right)*{LAF}_{t-i+1}*{TAF}_i\right]*{ASAF}_j\right], $$

where MHAF_j,t is the Mortality Hazard Adjustment Factor for age group j in year t; β is the coefficient from epidemiologic study or user-specified (% change in mortality per μg/m³ PM_2.5); ΔPM_i is the change in PM_2.5 concentration for year i (μg/m³); LAF _t−i+1 is a Lag Adjustment Factor in year t for total PM mortality impact from year i; TAF_i is a Threshold Adjustment Factor for year i; and ASAF_j is an Age-Specific Adjustment Factor for age group j.

Figure 1. Conceptual framework for PopSim model.

To accommodate dynamic year-to-year variation in PM_2.5 concentrations, the MHAF for each calendar year is calculated as a weighted average of the mortality impact of PM changes associated in that year and all previously modeled years, with weights determined by the cessation lag structure chosen by the user. The weighted average effect estimate of the change in mortality, therefore, incorporates the effects of multiple, overlapping impacts for changes in annual average PM_2.5 prior to that year. The MHAF for each calendar year is calculated for each year of age in the cohort and is modified to reflect any additional adjustment factors specified by the user.

The lag between changes in PM_2.5 exposure and the full realization of the expected changes in mortality rates is modeled by applying a lag adjustment factor (LAF) to the relative risk (RR) calculated in each year. The LAF for a given year, t_n, represents the fraction of the total change in mortality associated with a PM_2.5 change in year t ₁ that is expected to be realized by year t_n. The threshold adjustment factor (TAF) enables the model to incorporate a threshold value for the mortality impacts of PM_2.5 concentration such that only changes above the specified threshold would result in a change in mortality. The Age-Specific Adjustment Factor (ASAF) allows users to reflect on differences in susceptibility to PM_2.5 across the population. The user can specify values for an ASAF between 0 and 2 for a specific user-defined age group, with a value of 1 meaning that the age group experiences the full mortality impact of the change in PM_2.5. Values greater than 1 indicate that an age group is more affected by changes in PM than the rest of the population and values less than 1 indicate that an age group is less affected by changes in PM.

The Baseline Life Table component represents historical population data and projection data for the USA and Santiago, Chile for the years 1990–2050. The data for Chile, as with the other countries in the International version of PopSim, is based on the Census International Database (IDB) historical population data and projection for the years 1990–2050 (U.S. Department of the Census. 2016). This database contains population data stratified by sex and year of age; mortality rates for each relevant cause, by age cohort; and natality (birth) rates by age.

For each country, the tool also includes estimates of net migration in and out of each country. For the USA, we developed net migration estimates by subtracting estimated deaths calculated using CDC mortality data from annual cohort population change reported in U.S. Census-based population estimates. For Chile, the tool includes estimates of net migration that we developed by subtracting estimated deaths calculated using historical mortality rates from the Global Burden of Disease study (2013), as estimated by Abubakar et al. (Reference Abubakar, Tillmann and Banerjee2015) and projected IDB mortality rates from the projected population. The data in this module are protected to preserve a static baseline from which gains and losses in attributable deaths, life years, and life expectancy are measured.

The Regulatory Life Table component begins with the same data contained in the Baseline component, and then applies adjustment factors (from the Hazards component) to the baseline mortality rates taken from the CDC data. As a result, the population simulation in the Regulatory component reflects the mortality rates implied by user’s scenario specifications (entered in the Inputs component). The calculations in the Regulatory and Baseline components are equivalent, with the exception of the mortality rate, which is calculated as follows:

(2) $$ {P}_{regulatory}(death)\hskip0.35em =\hskip0.35em {P}_{baseline}(death)* MHAF. $$

2.2 Application of the PopSim model

We used PopSim to explore the effect of historical PM changes on the USA population aged 0–99 from 1990 to 2015 resulting from the application of air quality policies including but not limited to the U.S. Clean Air Act (U.S. Policy scenario), and the effect of air quality management actions taken by Chile over a similar period to reduce PM_2.5 exposures to the population of Santiago, Chile aged 0–99 (Santiago Policy scenario). For the USA, we applied the domestic version of PopSim that accompanies the BenMAP-CE tool, version 1.5.0.4. For the Santiago analysis, we modified the International version of PopSim to estimate the Santiago city population from the country-level data in the PopSim tool. We scaled the Chilean population based on historic data on the proportion of the Chilean population residing in Santiago, which was relatively stable over the study period (Departamento de Demografia). Birth rates are held constant in both models. Specific model inputs for each PopSim run are presented in the Supplementary Material.

We applied the Krewski et al. (Reference Hammitt, Morfeld, Tuomisto and Erren2009) PM concentration-response (C-R) function for all-cause mortality from BenMAP-CE, which estimates a roughly 6 % increase in mortality associated with a 10 μg m⁻³ increase in annual mean PM_2.5. We coupled this function with a 20-year distributed cessation lag with no threshold or age-specific hazard adjustments. We also compared the results from the PopSim model for the USA to results derived using BenMAP-CE(U.S. EPA, 2020), where the latter represent a standard static, pulse-type of analysis.

As noted above, the baseline scenario in the PopSim models is not modifiable by the user, and since our analysis is backward-looking, we assume that PopSim’s Baseline population data already reflect the air quality changes we are analyzing. We thus designed a counterfactual scenario for both simulations in which PM_2.5 concentrations and thus the fraction of PM_2.5-attributable mortality were assumed to be constant over the analysis period, with the difference between the two scenarios representing the impact of the USA or Chilean policy implementation.

For both countries, we estimated the historical average annual population-weighted PM_2.5 concentrations for each year where data were available and used these data points to establish a PM_2.5 concentration trend over time. PopSim currently only allows for five specified changes in PM_2.5 over the study period; therefore, after developing these trend lines, we chose 6 years each for the USA and Santiago that best capture that location’s trend in PM_2.5 concentrations from 1990 forward. We assume that concentrations follow a linear trend from one chosen point to the next.

For the U.S. PopSim analysis, we used a combined dataset of modeled and monitored data to estimate average annual concentrations for each county in the USA. For the years 1990–2000, we used PM_2.5 concentrations from research associated with the Multi-Ethnic Study of Atherosclerosis (MESA) study (Kim et al., Reference Hammitt2017) that used spatio-temporal modeling to estimate measurements of PM prior to the adoption of widespread PM_2.5 monitoring in 1999. For the later period of the analysis after 2001, we relied on monitored PM concentration data from EPA’s Air Quality System (AQS) that were pre-loaded in BenMAP-CE to calculate average annual concentration for each county in the USA. To generate a single average annual population-weighted concentration for the USA for each year, we merged this county-level PM_2.5 concentration with county-level data for populations aged 30 and up. We obtained all population data from the U.S. Census, using Census data for 2010 and intercensal data for every other year (U.S. Department of the Census, 2018). Figure 2 demonstrates the roughly linear trend of average annual PM_2.5 concentration in the USA from 1990 to 2013 (R ² = 0.93). The chosen data points for input to PopSim were for 1995, 2000, 2004, 2010, and 2013. Table 1 below summarizes the years chosen, the concentrations in each year and changes in PM_2.5 concentration from the previous year in the table (labeled “Delta”). 1990 is included as the first year in the time period.

Figure 2. USA average annual PM_2.5 concentration, population weighted.

Table 1. PM_2.5 concentration inputs for U.S. PopSim model.

In the Santiago analysis, we obtained 5-year population estimates from the Chilean National Institute of Statistics (INE) and used these projections to generate Comuna-level population by age and sex from 1990 to 2015 in the Santiago Metropolitan Region (Departamento de Demografia, 2021).Footnote ¹ Population-weighting was performed as in the USA analysis. For Santiago, we apply average annual PM_2.5 concentrations for each of 11 monitors using data obtained from the Chilean Ministry of Environment. We population-weight these data using data for the given year in the Comuna where each monitor is located. In Figure 3 below, we plotted the average annual population-weighted concentration for the Santiago Metropolitan region across all monitors. We fit the concentration data over time using a spline model. The spline model has an R ² of 0.97. From this trend line, we chose 1995, 2000, 2005, 2010, and 2014 for our analysis as shown in Table 2. For both case studies, the air quality change in 2015 is assumed to persist unchanged for the remainder of the study period.

Figure 3. Santiago average annual PM_2.5 concentration, population weighted.

Table 2. PM_2.5 concentration inputs for Santiago PopSim model.

Because it calculates changes in mortality for each year and for each single year of age, PopSim can quantify and report multiple metrics to describe the survival curve shifts and corresponding lifespan changes resulting from changes in PM_2.5. These metrics include the estimated changes in the numbers of deaths annually, the number of life years, and changes to life expectancy by age compared to baseline for the USA and Santiago case studies.

We estimate the economic value of projected mortality changes based on recommendations in federal guidance for economic analyses (U.S. EPA, 2014). Such economic analyses consider the marginal rate of substitution of wealth for mortality risk, or in simpler terms, the amounts that individuals are willing to pay for small reductions in mortality risk (“Value of Statistical Life [VSL]”) and the changes in VSL over time as real income grows (“income elasticity” of willingness to pay). The VSL represents a standardized unit, normalized to represent the amount that a population of size X is willing to trade to avoid a risk of 1/X (for small changes in risk). To estimate VSL values for each year of the USA analysis, we follow the approach applied by Achakulwisut et al. (Reference Achakulwisut, Anenberg, Neumann, Penn, Weiss, Crimmins, Fann, Martinich, Roman and Mickley2019) to generate historical and projected VSL values in 2015 dollars from an assumed base VSL of $10.0 million for 2015 and an income elasticity of 0.4 consistent with the BenMAP-CE default (U.S. EPA, 2020). For Santiago, we apply this method using a VSL based on a locally conducted stated preference survey that estimated a value of $1.09 M (2015$) (Greenlab UC, 2014). For changes in the risk of attributable deaths, we apply VSL estimates; for changes in life years, we derive a unit value per statistical life year (VSLY) by dividing the VSL by the discounted number of expected remaining life years among the exposed group, following the method used in Robinson et al. (Reference Pope, Coleman, Pond and Burnett2019). This method generates a constant VSLY for each year based on a year-specific VSL, and year-specific difference between the central estimate of the median age of the population and the average life expectancy for each country from the UN World Population Prospects (Reference Stieb, Judek, Brand, Burnett and Shin2019) and World Bank World Development Indicators (2021), respectively. For the Santiago analysis, we use a combination of historical population and GDP growth data, OECD growth projections for 2021–2022, and a GDP growth rate of 3 % for 2023 and beyond based on a 10-year pre-pandemic average of the historical data (Organisation for Economic Co-operation and Development, 2020). We estimate the NPV of the reduction of PM-attributable mortality and life-years gained benefits by discounting the stream of annual monetized values to generate a metric suitable for comparing benefits and costs. We generate two NPV estimates: one using a 3 % discount rate and one using a 7 % rate.

We also conducted a sensitivity analysis of the PopSim results focused on the impact of alternative cessation lag models on results. We apply three models from work by Walton (Reference Waltonn.d.) that vary the timing and speed of risk adjustments to the USA and Santiago runs. Model A presents a steep and rapid realization of the risk reduction over 8 years; Model C presents a more gradual realization over 15 years, and the last is a steady incremental accrual over 30 years.