3.1 Estimating the age-related weight gain curve

A dependent variable conditioned only on its own previous state exhibits the “Markov Property,” which makes observations before the one period prior irrelevant to estimation. A Markov process is “memoryless” in the sense that the only data used to create an estimate come from the previous state, which means the process can be represented by the first order difference equation below (Hamilton, Reference Hamilton1994; Lay et al., Reference Lay, Lay and McDonald2016):

(1) $$ {\varepsilon}_{t+1}={P}_{t+1}^{\varepsilon_t}{\varepsilon}_t+{v}_{t+1}, $$

where in the case of BMI, $ {\varepsilon}_{t+1} $ is BMI at age t + 1,ε_t is BMI at age t, and $ {v}_{t+1} $ is a random component, which should have a mean of zero and some finite variance (Hamilton, Reference Hamilton1994). Here, $ {P}_{t+1}^{\varepsilon_t} $ is a coefficient to be estimated representing systematic weight gain between age $ t $ and t + 1 of an individual who is in BMI class ε_t at age t.

This modeling technique has a history in the study of BMI transition estimation (Tucker et al., Reference Tucker, Palmer, Valentine, Roze and Ray2006; Ma & Frick, Reference Ma and Frick2011; Sonntag et al., Reference Sonntag, Ali, Lehnert, Konnopka, Riedel-Heller and König2015; Fallah-Fini et al., Reference Fallah-Fini, Adam, Cheskin, Bartsch and Lee2017). However, these studies generally do not discuss the Markov model’s functioning at length. We provide a working example to understand both how the Markov model provides an ideal approach to estimating age-related weight gain and how it can be implemented over the course of a lifetime. Before exploring the model’s use over a lifetime, a working example may help to demonstrate the advantages of the Markov modeling approach (Fosler-Lussier, Reference Fosler-Lussier1998). We will rely on five broadly agreed-upon BMI categories for transition: underweight (under 18 kg/m²), normal weight (from 18 to 25 kg/m²), overweight (from 25 to 30 kg/m²), obese (from 30 to 35 kg/m²), and morbidly obese (greater than or equal to 35 kg/m²) (Bhaskaran et al., Reference Bhaskaran, Douglas, Forbes, dos-Santos-Silva, Leon and Smeeth2014). While these categories simply reflect clinical standards, the fact that clinical interventions generally rely on these categories as treatment thresholds and previous research has demonstrated discontinuities in the cost of weight gain by category suggests these categories are informative (Cawley & Meyerhoefer, Reference Cawley and Meyerhoefer2011; Heymsfield et al., Reference Heymsfield, Aronne, Eneli, Kumar, Michalsky, Walker, Wolfe, Woolford and Yanovski2018). However, we also note the shortcomings of BMI and these categories more generally as a measure of adiposity given that they lead to misclassification of people with high lean body mass or high adiposity but lower weights (Prentice & Jebb, Reference Prentice and Jebb2001). The lack of available alternatives in national surveys means that these imperfect proxies are perhaps the best option. Five different iterations of the model (one for each BMI category one chooses) would exist in total. The effect of previous states on the current state without applying the Markov property can be represented by the conditional probability $ P\left({State}_n|{State}_{n-1,\dots, }{State}_1\right) $ .

Even over a relatively short period of time, this method of using all the data available quickly becomes intractable. For instance, if we considered each year of life separately then after only 5 years, we would need 5⁵ or 3125 past histories to compute current BMI using the past data available. Clearly, over a lifetime a more parsimonious method is required. Applying the Markov property, for which one needs only the most recent state to predict the current state, we could treat the 5 years as an interval, and this results in needing information for only 5² or 25 past histories regardless of the length of time measured. This more manageable model is interested only in $ P\left({State}_n|{State}_{n-1}\right) $ .

We now consider whether it is reasonable to group BMI transitions over the course of a few years. One of the most remarkable facts of the current obesity epidemic is its insidious and persistent nature: over a few years, people generally do not gain much weight. But weight builds over long periods of time through a process called “age-related weight gain” (Burke et al., Reference Burke, Bild, Hilner, Folsom, Wagenknecht and Sidney1996; Gokee LaRose et al., Reference Gokee LaRose, Tate, Gorin and Wing2010). Because of the relative intractability and consistency of age-related weight gain, a subject’s weight in the last time period likely correlates extremely powerfully with their current weight (Must & Strauss, Reference Must and Strauss1999). An adult with obesity or overweight rarely goes back down to a lower BMI category, and almost never sustains this weight loss, which makes their history of weight prior to the latest period largely irrelevant (Daviglus et al., Reference Daviglus, Liu, Yan, Pirzada, Manheim, Manning and Garside2004).

It is desirable to have the time interval between observations as short as possible to avoid multiple long term weight transitions taking place between observations. Anywhere from 1 to 3 years should yield a sufficiently short time period to avoid multiple state transitions at once (Burke et al., Reference Burke, Bild, Hilner, Folsom, Wagenknecht and Sidney1996). This recommended range is based upon the assumption that permanent BMI changes only gradually from the previous time period and multiple state transitions in such a short period of time seem unlikely. These state transitions allow the researcher to form a stochastic state transition probability matrix, from which the probability of shifting from one BMI category to another based on current BMI and age can be elucidated over the course of every subject’s life. As a result, using intervals of only a few years, one should be able to capture the vast majority of BMI state transitions, while also easing data requirements considerably.

In contrast to much of the published literature, we recommend taking a nonparametric approach by allowing the data to dictate the formation of the state transition probability matrices for each age group. Alternative approaches must rely on previous estimates or a rigid functional form for a BMI-age curve. Using a rigid functional form for BMI-age can introduce misspecification bias. Using others’ estimates for this curve puts one at the mercy of bias from the imperfect study designs of others and unverifiable assumptions that often make less sense today than when those studies were current (Fernandes, Reference Fernandes2010; Sonntag et al., Reference Sonntag, Ali, Lehnert, Konnopka, Riedel-Heller and König2015; Fallah-Fini et al., Reference Fallah-Fini, Adam, Cheskin, Bartsch and Lee2017). Some have argued the country’s recent secular trend in weight gain, wherein people of every age weigh more than they did previously, could introduce bias when employing a Markov model as estimates may pick up aggregate rather than individual effects (Massachusetts Medical Society et al., Reference Majeed2017). However, because these curves will be constructed from observations of real people over time and, hence, will control for individual-invariant fixed effects, such estimates serve the purpose of accurately modeling real world weight gain trajectories.

3.2 Limitations of the Markov model in estimating age-related weight gain

There are several shortcomings of the Markov model that are important to consider. The use of the model is motivated by the relative lack of datasets combining lifetime cost and BMI information available in the US. If a dataset were to exist that allowed for an estimate of age-related weight gain over the entire lifespan of Americans as well as the associated medical costs, a curve created from the entire history of their weight gain trajectories would be more appropriate. The necessity for the Markov property to hold is the primary limitation of the model, as an individual’s past beyond the last few years could provide important information regarding their propensity to gain or lose weight over time. Additionally, the current iteration of the Markov model employed in the literature relies on data from a different nationally representative sample than the one from which the cost of obesity is estimated, which could result in a misstatement of the relationship between medical cost and weight gain over time.

3.3 Identifiability in estimating obesity’s lifetime costs

One of the main limitations of the current literature on obesity’s lifetime costs is that all of the studies rely on observational data, finding associations rather than causal estimates. Cawley and Meyerhoefer (Reference Cawley and Meyerhoefer2011) implements an instrumental variable approach to isolate exogenous variation in BMI on a cross-sectional estimate that could also be used on longitudinal data (Cawley & Meyerhoefer, Reference Cawley and Meyerhoefer2011). Causal approaches to obesity’s estimation will undoubtedly prove vital given the tendency for poorer people and minorities to utilize healthcare at lower rates. Both of these groups tend to have higher than average risk of obesity. This means that endogeneity in the estimation of obesity’s costs likely causes a severe underestimate of the true value. Therefore, Cawley and Meyerhoefer (Reference Cawley and Meyerhoefer2011) proposes the use of an instrument – the weight of an adult’s oldest biological child – to isolate random variation in weight. While an instrumental variable approach estimates only a Local Average Treatment Effect (LATE) and so can lack generalizability to a larger population, it could prove a vital innovation for future causal estimates of obesity’s lifetime costs. The burgeoning literature on mendelian randomization, where germline genetic variation acts as an instrumental variable, could also provide a valuable new tool through which to produce models that account for confounding and selection bias (Dixon et al., Reference Dixon, Hollingworth, Harrison, Davies and Smith2020; Kurz & Laxy, Reference Kurz and Laxy2020).

3.4 Estimating differential life expectancies

Naturally, a lifetime cost estimate must account for the possibility that people with obesity do not live as long as their normal weight counterparts (Flegal et al., Reference Flegal, Graubard, Williamson and Gail2005; Finkelstein et al., Reference Finkelstein, Brown, Wrage, Allaire and Hoerger2010; Abdelaal et al., Reference Abdelaal, Roux and Docherty2017). Time censoring and a skewed distribution make survival analysis, and therefore quantifying life expectancy, a difficult statistical issue that requires specific techniques (Clark et al., Reference Clark, Bradburn, Love and Altman2003). Unfortunately, the existing literature on the life expectancy penalty resulting from obesity relies on largely older data and has provided equivocal results. In fact, some studies even found an “obesity paradox” among Black males, wherein people with obesity outlive those of normal weight (Tucker et al., Reference Tucker, Palmer, Valentine, Roze and Ray2006). This undoubtedly has to do with some form of endogeneity affecting both BMI status and life expectancy. It would be difficult to fully account for such an issue in any study. However, to provide an authoritative and more recent view of the subject, we propose using the most recent life expectancies available with proportional hazards generated from National Health Interview Survey (NHIS) data and official life tables.

While other common approaches to survival analysis exist (such as Kaplan-Meier Curves), we recommend the cox proportional hazards model both because of its ubiquity in medical research and ability to account for other covariates, in particular smoking and age at entry into the dataset (Clark et al., Reference Clark, Bradburn, Love and Altman2003). Unlike other proportional hazard approaches, this model is estimated nonparametrically at baseline, which reduces the probability of misspecification. The only major assumption, proportional hazards – where hazard rates between groups do not cross conditional on covariates – is verifiable. Even if these assumptions are not met, one can interact hazard and age to allow for time-dependent covariates that may have caused nonproportionality (Bradburn et al., Reference Bradburn, Clark, Love and Altman2003).

Nevertheless, the proportional hazards approach has come under recent scrutiny for its trouble estimating small risks accurately and the improbability of its assumptions holding in sufficiently large samples (Moolgavkar et al., Reference Moolgavkar, Chang, Watson and Lau2018; Stensrud & Hernán, Reference Stensrud and Hernán2020). We argue in this context such concerns remain relatively unimportant because the relative risk of obesity at younger ages is considerable. Specifically, the relative risk of mortality for being a person with obesity compared to normal weight at younger ages tends to exceed 2, which is well beyond the “small risks” discussed by Moolgavkar et al. (Reference Moolgavkar, Chang, Watson and Lau2018)

The official U.S. Lifetables published by the National Center for Health Statistics (NCHS) provide age-specific death probabilities by gender (Arias & Xu, Reference Arias and Xu2015). Unfortunately, these data do not account for specific BMI categories or smoking status, the largest health-behavior based potential confounder in life expectancy. As a result, one can use NHIS data linked calculated hazards with corresponding linked mortality files (LMFs) in the National Death Index. The Cox proportional hazards model can be written as

(2) $$ h(t)={h}_0(t){e}^{\left({X}^{\prime}\beta \right)}, $$

where h(t) is the hazard of death at time t, $ {\displaystyle \begin{array}{l}{h}_0(.)\end{array}} $ is a base time curve adjusted by the exponential factor with $ {X}^{\prime}\beta $ as a set of covariate controls. This presumes hazards at any particular age are proportional given a specific set of covariates. The output produced by a Cox proportional hazards model, a hazard ratio, illustrates the changed hazard of an outcome occurring from a change in characteristics. For instance, a hazard ratio of three for a person with obesity would suggest that they have triple the chance of dying that year compared to a reference normal weight person with otherwise identical attributes. As a result, applying the Cox proportional hazards model to a lifetable allows for a researcher both to control for potential confounders and to address directly the impact of obesity on life expectancy. Thus, in order to determine BMI’s effects on life expectancy by age, one must apply the hazard ratios of each BMI and smoking category (and any other important confounder) to the unadjusted probability of death at any age given by the lifetables.

Depending on the data source, one could find points at which the proportional hazards assumption would likely be violated (Fontaine et al., Reference Fontaine, Redden, Wang, Westfall and Allison2003; Finkelstein et al., Reference Finkelstein, Trogdon, Brown, Allaire, Dellea and Kamal-Bahl2008). There are two common methods for handling disproportionality – an interaction between the violating variable and time, and stratification by the violating variable (Grambsch & Therneau, Reference Grambsch and Therneau1994). Because stratification does not allow for estimation of a parameter value (and we need such a value to accurately assess life expectancy effects) and creates less efficiency given the artificial constraint on the information available to the researcher, we propose adding interaction terms between age and each violating variable. This adjustment also makes intuitive sense, as BMI’s impact differs markedly based on one’s age and time spent in each state, so age interactions should provide a more precise estimation of its impact on survival probability over time. To confirm the logic of this intuition, we propose conducting likelihood ratio tests for the interaction model and Wald tests for the joint significance of the interaction variables and analyzing Akaike Information Criterion (AIC) and Bayesian Information Criterion (BIC) criteria to assess goodness of fit. After fitting this model, one simply averages the association of obesity and mortality across smoking statuses, after which estimating a median life expectancy simply requires taking the product of the probability of mortality every year times the relative risk for people with obesity.

3.5 Limitations of the Cox proportional hazards model for life expectancy

There are several important limitations to applying the Cox proportional hazards model. Firstly, the Cox proportional hazards model makes an assumption, proportional hazards, where the hazard ratio between individuals remains constant over time, that is likely to fail in practice. While there are steps to remedy this, the assumption represents an imperfect parameterization of an individual’s survival and can result in statistical bias in the model. New techniques employing nonparametric methods for survival analysis could be explored by future researchers to relax this simplifying assumption. Perhaps the most important problem that plagues any survival model is the persistence of endogeneity, for which no simple solution exists. The wide variety of estimates of survival differences between people with obesity and normal weight people could be driven in part by differences between these individuals not attributable to obesity. Lastly, the impact of obesity on survival could be contingent on the existence of other medical conditions, like pre-existing heart issues, which means the true effect could exhibit significant heterogeneity.

3.6 Estimating obesity-related costs

One of the persistent concerns when modeling healthcare data is the large number of subjects who face no medical expenditures in a given year (Buntin & Zaslavsky, Reference Buntin and Zaslavsky2004). Additional methodological issues include the data’s strict non-negativity and, due to the presence of some patients with exceptionally high medical costs, the highly skewed nature of the data. The linear conditional expectation and normality assumptions typically specified in ordinary least squares regressions are severely violated, and the literature suggests a wide variety of potential solutions to these issues. This includes log models, 2PM, and GLM. We propose the use of a 2PM estimating the probability of any medical expenditures and then the total medical expenditures conditional on having any. We propose this 2PM both because of its reliance on more reasonable assumptions and history of use in the existing literature allowing for comparability (Thorpe et al., Reference Thorpe, Florence, Howard and Joski2004; Wee et al., Reference Wee, Phillips, Legedza, Davis, Soukup, Colditz and Hamel2005; Yang & Hall, Reference Yang and Hall2007; Bell et al., Reference Bell, Zimmerman, Arterburn and Maciejewski2011; Cawley & Meyerhoefer, Reference Cawley and Meyerhoefer2011; Trogdon et al., Reference Trogdon, Finkelstein, Feagan and Cohen2012). The large number of subjects with no medical expenditures in any given year could otherwise severely bias the results without separately accounting for the possibility of no medical expenditure.

For the discrete part of the model, the dependent variable, whether a subject reports any medical expenditure, will have a generalized binomial distribution (Nelson et al., Reference Nelson, Story, Larson, Neumark-Sztainer and Lytle2008). In order to regress a binary variable, one can use a generalized linear model, where a link function transforms the binomial distribution into an approximately normal distribution. The two most popular versions of this model are the Logit and Probit models. There are relatively few practical differences between these models: a logistic error term’s distribution normally has a higher kurtosis, and interpretations of the coefficients vary. There are also slight differences in model fit. Because of their similarity, we propose the use a logit model due to its marginally superior fit and comparative ease of interpretation.

Determining an appropriate functional form of the second part of the model proves more nuanced. The two most commonly used modeling approaches are a GLM with a Gamma Log Link and a Logged Ordinary Least Squares (OLS) regression. The discussions regarding this model choice can often feel a bit murky. A helpful analogy to understand the distinction between a GLM and an OLS model is the difference between a rectangle and square. An OLS model is a GLM that requires a normal (or in this case lognormal) distribution, like how a square is a rectangle that requires equal length sides. In the general case a GLM, like how a rectangle does not require a square’s assumptions, can fit both normal and non-normal distributions. Thus, the GLM requires no retransformation into a normal distribution and has more relaxed assumptions than an OLS model, but provides less statistical efficiency as a result of the fewer assumptions regarding functional form (Manning & Mullahy, Reference Manning and Mullahy2001; Buntin & Zaslavsky, Reference Buntin and Zaslavsky2004).

The gamma distribution allows for the modeling of non-negative data without the need for a smearing retransformation. A smearing retransformation is done because logging variable results in a shift in the distribution that must be accounted for when returning to the original scale. Meanwhile, a logged OLS model brings in the upper tail of the distribution, can account to some extent for the extreme range of healthcare data, and focuses solely on positive values. However, the logged OLS also requires a smearing retransformation, which could cause bias in the presence of heteroskedasticity (Buntin & Zaslavsky, Reference Buntin and Zaslavsky2004). We recommend researchers apply a histogram of expenditure data and run Park tests to determine which distribution is best suited for the data, as this choice has varied in the literature and based on cost source.

The choice of variables to control depends on whether one applies the instrumental variables or typical associative approach but typically includes education, smoking status, marital status, geographical region, insurance status, and age, which is often modeled nonlinearly. All costs should be inflated to the most recent medical care component of the Consumer Price Index (CPI) and discounted to cohere with previous estimates.

3.7 Limitations of the 2PM for healthcare costs

While it remains the most widely used method to account for healthcare costs, the 2PM has several methodological shortcomings. Firstly, as noted by Deb and Trivedi (Reference Deb and Trivedi2002), the 2PM method of dividing between non-users and users of the healthcare system poorly reflects the actual functioning of healthcare usage over time (Deb & Trivedi, Reference Deb and Trivedi2002). Instead, a clearer division could be based on “frequent” and “infrequent” users of healthcare. This suggests that the 2PM’s estimates are contingent partly on the length of time of a given episode of disease the dataset covers. Additionally, while the 2PM will produce consistent estimates due to being fit to the empirical distribution, its reliance on researchers to specify a parametric probability distribution could lead to misspecification (Mullahy, Reference Mullahy1998).

4.1 Criteria for datasets in the age-related weight gain curve

Unfortunately, the lack of a recent, robust estimate of age-related weight gain stems primarily from the limitations of available longitudinal studies in America. Ideally, this longitudinal dataset would be nationally representative, recent, and cover subjects from early adolescence until their deaths. Because such a dataset simply does not exist in this country, we created a list of criteria to determine whether a dataset deserves inclusion in an age-related weight gain curve despite its shortcomings. Most importantly, the dataset should cover over 10 years of subjects’ lives, be relatively recent, have sufficient follow-up and low attrition rates, have a short time between observations, objectively measure height and weight, and be nationally representative. There are a variety of potential datasets suited to the task, including the Framingham Heart Study (FHS), CARDIA, the Health and Retirement Study (HRS), the Medicare Current Beneficiary Survey (MCBS), and the ARIC.

4.7 Differential life expectancies dataset

An ideal dataset to measure life expectancy differences between people with obesity and their normal weight peers would be nationally representative, contain the covariates outlined in Equation (6), rely on objectively measured height and weight, and would account for time spent with obesity. No dataset in the USA comes close to meeting all these parameters. However, the NCHS has created linked files between the National Death Index and NHIS interview files detailing all the covariates of interest. This dataset is nationally representative and contains the variables necessary for estimation; however, height and weight are self-reported, and time spent with obesity is not factored into its impact on life expectancy.