6.3.1 Identifying the Causal Effect of a Stochastic Intervention

• The stochastic intervention generates a counterfactual random variable \(Y_{d(A,W)} := f_Y(d(A,W), W, U_Y) \equiv Y_{g_{\delta}} := f_Y(A_{\delta}, W, U_Y)\), where \(Y_{d(A,W)} \sim \mathcal{P}_0^{\delta}\).

• The target causal estimand of our analysis is \(\psi_{0, \delta} := \mathbb{E}_{P_0^{\delta}}\{Y_{d(A,W)}\}\), the mean of the counterfactual outcome variable \(Y_{d(A, W)}\). The statistical target parameter may also be denoted \(\Psi(P_0) = \mathbb{E}_{P_0}{\overline{Q}(d(A, W), W)}\), where \(\overline{Q}(d(A, W), W)\) is the counterfactual outcome value of a given individual under the stochastic intervention distribution (Dı́az and van der Laan 2018).

• In prior work, Dı́az and van der Laan (2012) showed that the causal quantity of interest \(\mathbb{E}_0 \{Y_{d(A, W)}\}\) is identified by a functional of the distribution of \(O\): \[\begin{align*}\label{eqn:identification2012} \psi_{0,d} = \int_{\mathcal{W}} \int_{\mathcal{A}} & \mathbb{E}_{P_0} \{Y \mid A = d(a, w), W = w\} \cdot \\ &q_{0, A}^O(a \mid W = w) \cdot q_{0, W}^O(w) d\mu(a)d\nu(w). \end{align*}\]

• The four standard assumptions presented in are necessary in order to establish identifiability of the causal parameter from the observed data via the statistical functional. These were

  1. Consistency: \(Y^{d(a_i, w_i)}_i = Y_i\) in the event \(A_i = d(a_i, w_i)\), for \(i = 1, \ldots, n\)
  2. Stable unit value treatment assumption (SUTVA): \(Y^{d(a_i, w_i)}_i\) does not depend on \(d(a_j, w_j)\) for \(i = 1, \ldots, n\) and \(j \neq i\), or lack of interference (Rubin 1978, 1980).
  3. Strong ignorability: \(A_i \perp \!\!\! \perp Y^{d(a_i, w_i)}_i \mid W_i\), for \(i = 1, \ldots, n\).
  4. Positivity (or overlap): \(a_i \in \mathcal{A} \implies d(a_i, w_i) \in \mathcal{A}\) for all \(w \in \mathcal{W}\), where \(\mathcal{A}\) denotes the support of \(A \mid W = w_i \quad \forall i = 1, \ldots n\).

• With the identification assumptions satisfied, Dı́az and van der Laan (2012) and Dı́az and van der Laan (2018) provide an efficient influence function with respect to the nonparametric model \(\mathcal{M}\) as \[\begin{equation*}\label{eqn:eif} D(P_0)(x) = H(a, w)({y - \overline{Q}(a, w)}) + \overline{Q}(d(a, w), w) - \Psi(P_0), \end{equation*}\] where the auxiliary covariate \(H(a,w)\) may be expressed \[\begin{equation*}\label{eqn:aux_covar_full} H(a,w) = \mathbb{I}(a + \delta < u(w)) \frac{g_0(a - \delta \mid w)} {g_0(a \mid w)} + \mathbb{I}(a + \delta \geq u(w)), \end{equation*}\] which may be reduced to \[\begin{equation*}\label{eqn:aux_covar_simple} H(a,w) = \frac{g_0(a - \delta \mid w)}{g_0(a \mid w)} + 1 \end{equation*}\] in the case that the treatment is in the limits that arise from conditioning on \(W\), i.e., for \(A_i \in (u(w) - \delta, u(w))\).

6.3.2 Interpreting the Causal Effect of a Stochastic Intervention

FIGURE 5.1: Animation of how a counterfactual outcome changes as the natural treatment distribution is subjected to a simple stochastic intervention

6.4.1 Simulate Data

# simulate simple data for tmle-shift sketch
n_obs <- 1000 # number of observations
tx_mult <- 2 # multiplier for the effect of W = 1 on the treatment

## baseline covariates -- simple, binary
W <- replicate(2, rbinom(n_obs, 1, 0.5))

## create treatment based on baseline W
A <- rnorm(n_obs, mean = tx_mult * W, sd = 1)

## create outcome as a linear function of A, W + white noise
Y <- rbinom(n_obs, 1, prob = plogis(A + W))

# organize data and nodes for tmle3
data <- data.table(W, A, Y)
setnames(data, c("W1", "W2", "A", "Y"))
node_list <- list(W = c("W1", "W2"), A = "A", Y = "Y")
head(data)
#>    W1 W2        A Y
#> 1:  1  1  3.58065 1
#> 2:  1  0  3.20718 1
#> 3:  1  1  1.03584 1
#> 4:  0  0 -0.65785 1
#> 5:  1  1  3.01990 1
#> 6:  1  1  2.78031 1

We now have an observed data structure (data) and a specification of the role that each variable in the data set plays as the nodes in a directed acyclic graph (DAG) via nonparametric structural equation models (NPSEMs).

To start, we will initialize a specification for the TMLE of our parameter of interest (a tmle3_Spec in the tlverse nomenclature) simply by calling tmle_shift. We specify the argument shift_val = 0.5 when initializing the tmle3_Spec object to communicate that we’re interested in a shift of \(0.5\) on the scale of the treatment \(A\) – that is, we specify \(\delta = 0.5\).

# initialize a tmle specification
tmle_spec <- tmle_shift(
  shift_val = 0.5,
  shift_fxn = shift_additive,
  shift_fxn_inv = shift_additive_inv
)

As seen above, the tmle_shift specification object (like all tmle3_Spec objects) does not store the data for our specific analysis of interest. Later, we’ll see that passing a data object directly to the tmle3 wrapper function, alongside the instantiated tmle_spec, will serve to construct a tmle3_Task object internally (see the tmle3 documentation for details).

6.4.2 Targeted Estimation of Stochastic Interventions Effects

tmle_fit <- tmle3(tmle_spec, data, node_list, learner_list)
#> 
#> Iter: 1 fn: 1384.3571     Pars:  0.23160444 0.00001921 0.76837635
#> Iter: 2 fn: 1384.3571     Pars:  0.23160449 0.00000771 0.76838780
#> solnp--> Completed in 2 iterations
tmle_fit
#> A tmle3_Fit that took 1 step(s)
#>    type         param init_est tmle_est       se   lower   upper
#> 1:  TSM E[Y_{A=NULL}]   0.8008  0.79852 0.012841 0.77335 0.82368
#>    psi_transformed lower_transformed upper_transformed
#> 1:         0.79852           0.77335           0.82368

The print method of the resultant tmle_fit object conveniently displays the results from computing our TML estimator.

6.5.1 Initializing vimshift through its tmle3_Spec

To start, we will initialize a specification for the TMLE of our parameter of interest (called a tmle3_Spec in the tlverse nomenclature) simply by calling tmle_shift. We specify the argument shift_grid = seq(-1, 1, by = 1) when initializing the tmle3_Spec object to communicate that we’re interested in assessing the mean counterfactual outcome over a grid of shifts -1, 0, 1 on the scale of the treatment \(A\).

# what's the grid of shifts we wish to consider?
delta_grid <- seq(from = -1, to = 1, by = 1)

# initialize a tmle specification
tmle_spec <- tmle_vimshift_delta(
  shift_grid = delta_grid,
  max_shifted_ratio = 2
)

6.5.2 Targeted Estimation of Stochastic Intervention Effects

One may walk through the step-by-step procedure for fitting the TML estimator of the mean counterfactual outcome under each shift in the grid, using the machinery exposed by the tmle3 R package, or simply invoke the tmle3 wrapper function to fit the series of TML estimators (one for each parameter defined by the grid delta) in a single function call. For convenience, we choose the latter:

tmle_fit <- tmle3(tmle_spec, data, node_list, learner_list)
#> 
#> Iter: 1 fn: 1385.6999     Pars:  0.25334329 0.00004999 0.74660672
#> Iter: 2 fn: 1385.6999     Pars:  0.25334348 0.00003044 0.74662609
#> solnp--> Completed in 2 iterations
tmle_fit
#> A tmle3_Fit that took 1 step(s)
#>          type          param init_est tmle_est        se   lower   upper
#> 1:        TSM  E[Y_{A=NULL}]  0.61655  0.61587 0.0139964 0.58844 0.64330
#> 2:        TSM  E[Y_{A=NULL}]  0.74115  0.73899 0.0138954 0.71176 0.76623
#> 3:        TSM  E[Y_{A=NULL}]  0.84916  0.84362 0.0107141 0.82262 0.86462
#> 4: MSM_linear MSM(intercept)  0.73562  0.73283 0.0120791 0.70915 0.75650
#> 5: MSM_linear     MSM(slope)  0.11631  0.11388 0.0053718 0.10335 0.12440
#>    psi_transformed lower_transformed upper_transformed
#> 1:         0.61587           0.58844           0.64330
#> 2:         0.73899           0.71176           0.76623
#> 3:         0.84362           0.82262           0.86462
#> 4:         0.73283           0.70915           0.75650
#> 5:         0.11388           0.10335           0.12440

Remark: The print method of the resultant tmle_fit object conveniently displays the results from computing our TML estimator.

6.5.3 Inference with Marginal Structural Models

Since we consider estimating the mean counterfactual outcome \(\psi_n\) under several values of the intervention \(\delta\), taken from the aforementioned \(\delta\)-grid, one approach for obtaining inference on a single summary measure of these estimated quantities involves leveraging working marginal structural models (MSMs). Summarizing the estimates \(\psi_n\) through a working MSM allows for inference on the trend imposed by a \(\delta\)-grid to be evaluated via a simple hypothesis test on a parameter of this working MSM. Letting \(\psi_{\delta}(P_0)\) be the mean outcome under a shift \(\delta\) of the treatment, we have \(\vec{\psi}_{\delta} = (\psi_{\delta}: \delta)\) with corresponding estimators \(\vec{\psi}_{n, \delta} = (\psi_{n, \delta}: \delta)\). Further, let \(\beta(\vec{\psi}_{\delta}) = \phi((\psi_{\delta}: \delta))\). By a straightforward application of the delta method (discussed previously), we may write the efficient influence function of the MSM parameter \(\beta\) in terms of the EIFs of each of the corresponding point estimates. Based on this, inference from a working MSM is rather straightforward. To wit, the limiting distribution for \(m_{\beta}(\delta)\) may be expressed \[\sqrt{n}(\beta_n - \beta_0) \to N(0, \Sigma),\] where \(\Sigma\) is the empirical covariance matrix of \(\text{EIF}_{\beta}(O)\).

tmle_fit$summary[4:5, ]
#>          type          param init_est tmle_est        se   lower  upper
#> 1: MSM_linear MSM(intercept)  0.73562  0.73283 0.0120791 0.70915 0.7565
#> 2: MSM_linear     MSM(slope)  0.11631  0.11388 0.0053718 0.10335 0.1244
#>    psi_transformed lower_transformed upper_transformed
#> 1:         0.73283           0.70915            0.7565
#> 2:         0.11388           0.10335            0.1244

6.5.4 Directly Targeting the MSM Parameter \(\beta\)

Note that in the above, a working MSM is fit to the individual TML estimates of the mean counterfactual outcome under a given value of the shift \(\delta\) in the supplied grid. The parameter of interest \(\beta\) of the MSM is asymptotically linear (and, in fact, a TML estimator) as a consequence of its construction from individual TML estimators. In smaller samples, it may be prudent to perform a TML estimation procedure that targets the parameter \(\beta\) directly, as opposed to constructing it from several independently targeted TML estimates. An approach for constructing such an estimator is proposed in the sequel.

Suppose a simple working MSM \(\mathbb{E}Y_{g^0_{\delta}} = \beta_0 + \beta_1 \delta\), then a TML estimator targeting \(\beta_0\) and \(\beta_1\) may be constructed as \[\overline{Q}_{n, \epsilon}(A,W) = \overline{Q}_n(A,W) + \epsilon (H_1(g), H_2(g),\] for all \(\delta\), where \(H_1(g)\) is the auxiliary covariate for \(\beta_0\) and \(H_2(g)\) is the auxiliary covariate for \(\beta_1\).

To construct a targeted maximum likelihood estimator that directly targets the parameters of the working marginal structural model, we may use the tmle_vimshift_msm Spec (instead of the tmle_vimshift_delta Spec that appears above):

# initialize a tmle specification
tmle_msm_spec <- tmle_vimshift_msm(
  shift_grid = delta_grid,
  max_shifted_ratio = 2
)

# fit the TML estimator and examine the results
tmle_msm_fit <- tmle3(tmle_msm_spec, data, node_list, learner_list)
#> 
#> Iter: 1 fn: 1383.9032     Pars:  0.25182819 0.00001248 0.74815933
#> Iter: 2 fn: 1383.9032     Pars:  0.251828192 0.000007611 0.748164197
#> solnp--> Completed in 2 iterations
tmle_msm_fit
#> A tmle3_Fit that took 100 step(s)
#>          type          param init_est tmle_est        se   lower   upper
#> 1: MSM_linear MSM(intercept)  0.73688  0.73682 0.0120246 0.71326 0.76039
#> 2: MSM_linear     MSM(slope)  0.11604  0.11615 0.0053944 0.10558 0.12672
#>    psi_transformed lower_transformed upper_transformed
#> 1:         0.73682           0.71326           0.76039
#> 2:         0.11615           0.10558           0.12672

6.5.5 Example with the WASH Benefits Data

To complete our walk through, let’s turn to using stochastic interventions to investigate the data from the WASH Benefits trial. To start, let’s load the data, convert all columns to be of class numeric, and take a quick look at it

washb_data <- fread("https://raw.githubusercontent.com/tlverse/tlverse-data/master/wash-benefits/washb_data_subset.csv", stringsAsFactors = TRUE)
washb_data <- washb_data[!is.na(momage) & !is.na(momheight), ]
head(washb_data, 3)
#>      whz          tr fracode month aged    sex momage         momedu momheight
#> 1: -0.94 Handwashing  N06505     7  237   male     21 Primary (1-5y)    146.00
#> 2: -1.13     Control  N06505     8  310 female     26   No education    148.90
#> 3: -1.61     Control  N06524     3  162   male     25 Primary (1-5y)    153.75
#>        hfiacat Nlt18 Ncomp watmin elec floor walls roof asset_wardrobe
#> 1: Food Secure     1    25      2    1     0     1    1              0
#> 2: Food Secure     1     7      4    1     0     0    1              0
#> 3: Food Secure     0    15      2    0     0     1    1              0
#>    asset_table asset_chair asset_khat asset_chouki asset_tv asset_refrig
#> 1:           1           0          0            1        0            0
#> 2:           1           1          0            1        0            0
#> 3:           1           0          1            1        0            0
#>    asset_bike asset_moto asset_sewmach asset_mobile
#> 1:          0          0             0            0
#> 2:          0          0             0            1
#> 3:          0          0             0            0

Next, we specify our NPSEM via the node_list object. For our example analysis, we’ll consider the outcome to be the weight-for-height Z-score (as in previous sections), the intervention of interest to be the mother’s age at time of child’s birth, and take all other covariates to be potential confounders.

node_list <- list(
  W = names(washb_data)[!(names(washb_data) %in%
    c("whz", "momage"))],
  A = "momage", Y = "whz"
)

Were we to consider the counterfactual weight-for-height Z-score under shifts in the age of the mother at child’s birth, how would we interpret estimates of our parameter?

To simplify our interpretation, consider a shift (up or down) of two years in the mother’s age (i.e., \(\delta = \{-2, 0, 2\}\)); in this setting, a stochastic intervention would correspond to a policy advocating that potential mothers defer or accelerate plans of having a child for two calendar years, possibly implemented through the deployment of an encouragement design.

First, let’s try a simple upward shift of just two years:

# initialize a tmle specification for just a single delta shift
washb_shift_spec <- tmle_shift(
  shift_val = 2,
  shift_fxn = shift_additive,
  shift_fxn_inv = shift_additive_inv
)

To examine the effect modification approach we looked at in previous chapters, we’ll estimate the effect of this shift \(\delta = 2\) while stratifying on the mother’s education level (momedu, a categorical variable with three levels). For this, we augment our initialized tmle3_Spec object like so

# initialize effect modification specification around previous specification
washb_shift_strat_spec <-  tmle_stratified(washb_shift_spec)

Prior to running our analysis, we’ll modify the learner_list object we had created to include just one of the semiparametric location-scale conditional density estimators, as fitting of these estimators is much faster than the more computationally intensive approach implemented in the haldensify package (Hejazi, Benkeser, and van der Laan 2020).

# learners used for conditional density regression (i.e., propensity score),
# but we need to turn on cross-validation for this conditional density learner
hose_learner_xgb_cv <- Lrnr_cv$new(
  learner = hose_learner_xgb,
  full_fit = TRUE
)

# modify learner list, using existing SL for Q fit
learner_list <- list(Y = Q_learner, A = hose_learner_xgb_cv)

Now we’re ready to construct a TML estimate of the shift parameter at \(\delta = 2\), stratified across levels of our variable of interest:

# fit stratified TMLE
strat_node_list <- copy(node_list)
strat_node_list$W <- setdiff(strat_node_list$W,"momedu")
strat_node_list$V <- "momedu"
washb_shift_strat_fit <- tmle3(washb_shift_strat_spec, washb_data, strat_node_list,
                               learner_list)
washb_shift_strat_fit
#> A tmle3_Fit that took 1 step(s)
#>              type                             param init_est tmle_est       se
#> 1:            TSM                     E[Y_{A=NULL}] -0.57206 -0.56936 0.048211
#> 2: stratified TSM  E[Y_{A=NULL}] | V=Primary (1-5y) -0.62295 -0.69200 0.076813
#> 3: stratified TSM    E[Y_{A=NULL}] | V=No education -0.68673 -0.86672 0.128939
#> 4: stratified TSM E[Y_{A=NULL}] | V=Secondary (>5y) -0.50717 -0.40686 0.067633
#>       lower    upper psi_transformed lower_transformed upper_transformed
#> 1: -0.66385 -0.47487        -0.56936          -0.66385          -0.47487
#> 2: -0.84255 -0.54145        -0.69200          -0.84255          -0.54145
#> 3: -1.11944 -0.61401        -0.86672          -1.11944          -0.61401
#> 4: -0.53942 -0.27431        -0.40686          -0.53942          -0.27431

For the next example, we’ll use the variable importance strategy of considering a grid of stochastic interventions to evaluate the weight-for-height Z-score under a shift in the mother’s age down by two years (\(\delta = -2\)) through up by two years (\(\delta = 2\)), incrementing by a single year between the two. To do this, we simply initialize a Spec tmle_vimshift_delta similar to how we did in a previous example:

# initialize a tmle specification for the variable importance parameter
washb_vim_spec <- tmle_vimshift_delta(
  shift_grid = seq(from = -2, to = 2, by = 1),
  max_shifted_ratio = 2
)

Having made the above preparations, we’re now ready to estimate the counterfactual mean of the weight-for-height Z-score under a small grid of shifts in the mother’s age at child’s birth. Just as before, we do this through a simple call to our tmle3 wrapper function:

washb_tmle_fit <- tmle3(washb_vim_spec, washb_data, node_list, learner_list)
washb_tmle_fit
#> A tmle3_Fit that took 1 step(s)
#>          type          param   init_est   tmle_est        se      lower
#> 1:        TSM  E[Y_{A=NULL}] -0.5608084 -0.5552156 0.0469064 -0.6471504
#> 2:        TSM  E[Y_{A=NULL}] -0.5638623 -0.5644702 0.0466125 -0.6558290
#> 3:        TSM  E[Y_{A=NULL}] -0.5663920 -0.5652941 0.0466314 -0.6566901
#> 4:        TSM  E[Y_{A=NULL}] -0.5687408 -0.5681002 0.0463126 -0.6588712
#> 5:        TSM  E[Y_{A=NULL}] -0.5708337 -0.5716047 0.0468992 -0.6635256
#> 6: MSM_linear MSM(intercept) -0.5661274 -0.5649370 0.0465180 -0.6561105
#> 7: MSM_linear     MSM(slope) -0.0024929 -0.0036408 0.0012834 -0.0061563
#>         upper psi_transformed lower_transformed upper_transformed
#> 1: -0.4632807      -0.5552156        -0.6471504        -0.4632807
#> 2: -0.4731114      -0.5644702        -0.6558290        -0.4731114
#> 3: -0.4738982      -0.5652941        -0.6566901        -0.4738982
#> 4: -0.4773292      -0.5681002        -0.6588712        -0.4773292
#> 5: -0.4796839      -0.5716047        -0.6635256        -0.4796839
#> 6: -0.4737634      -0.5649370        -0.6561105        -0.4737634
#> 7: -0.0011254      -0.0036408        -0.0061563        -0.0011254