The goal of \(\texttt{expertsurv}\) is to incorporate expert opinion into an analysis of time to event data. \(\texttt{expertsurv}\) uses many of the core functions of the \(\texttt{survHE}\) package (Baio 2020). Technical details of the implementation are detailed in (Cooney and White 2023) and will not be repeated here.

The key function is `fit.models.expert`

and operates
almost identically to the `fit.models`

function of \(\texttt{survHE}\).

You can install the released version of expertsurv from GitHub with:

`::install_github("Philip-Cooney/expertsurv") devtools`

If we have elicited expert opinion of the survival probability at certain timepoint(s) and assigned distributions to these beliefs, we encode that information as follows:

```
#A param_expert object; which is a list of
#length equal to the number of timepoints
<- list()
param_expert_example1
#If we have 1 timepoint and 2 experts
#dist is the names of the distributions
#wi is the weight assigned to each expert (usually 1)
#param1, param2, param3 are the parameters of the distribution
#e.g. for norm, param1 = mean, param2 = sd
#param3 is only used for the t-distribution and is the degress of freedom.
#We allow the following distributions:
#c("normal","t","gamma","lognormal","beta")
1]] <- data.frame(dist = c("norm","t"),
param_expert_example1[[wi = c(0.5,0.5), # Ensure Weights sum to 1
param1 = c(0.1,0.12),
param2 = c(0.005,0.005),
param3 = c(NA,3))
param_expert_example1#> [[1]]
#> dist wi param1 param2 param3
#> 1 norm 0.5 0.10 0.005 NA
#> 2 t 0.5 0.12 0.005 3
#Naturally we will specify the timepoint for which these probabilities where elicited
<- 14
timepoint_expert
#In case we wanted a second timepoint -- Just for illustration
# param_expert_example1[[2]] <- data.frame(dist = c("norm","norm"),
# wi = c(1,1),
# param1 = c(0.05,0.045),
# param2 = c(0.005,0.005),
# param3 = c(NA,NA))
#
# timepoint_expert <- c(timepoint_expert,18)
```

If we wanted opinions at multiple timepoints we just include append another list (i.e. param_expert_example1[[2]] with the relevant parameters) and specify timepoint_expert as a vector of length 2 with the second element being the second timepoint.

For details on assigning distributions to elicited probabilities and
quantiles see the \(\texttt{SHELF}\)
package (Oakley 2021) and for an overview on methodological approaches
to eliciting expert opinion see (O’Hagan 2019). We can see both the
individual and pooled distributions using the following code (note that
we could have used the output of the `fitdist`

function from
\(\texttt{SHELF}\) if we actually
elicited quantiles from an expert):

```
plot_opinion1<- plot_expert_opinion(param_expert_example1[[1]],
weights = param_expert_example1[[1]]$wi)
ggsave("Vignette_Example 1 - Expert Opinion.png")
```

For the log pool we have a uni-modal distribution (in contrast to the bi-modal linear pool) which has a \(95\%\) credible interval between \(9.0−11.9\%\) calculated with the function below:

`cred_int_val <- cred_int(plot_opinion1,val = "log pool", interval = c(0.025, 0.975))`

We load and fit the data as follows (in this example considering just
the Weibull and Gompertz models), with
`pool_type = "log pool"`

specifying that we want to use the
logarithmic pooling (rather than default “linear pool”). We do this as
we wish to compare the results to the penalized maximum likelihood
estimates in the next section.

```
data2 <- data %>% rename(status = censored) %>% mutate(time2 = ifelse(time > 10, 10, time),
status2 = ifelse(time> 10, 0, status))
#Set the opinion type to "survival"
example1 <- fit.models.expert(formula=Surv(time2,status2)~1,data=data2,
distr=c("wph", "gomp"),
method="hmc",
iter = 5000,
pool_type = "log pool",
opinion_type = "survival",
times_expert = timepoint_expert,
param_expert = param_expert_example1)
```

Both visual fit and model fit statistics highlight that the Weibull model is a poor fit to both the expert opinion and data (black line referring to the \(95\%\) confidence region for the experts prior belief).

```
model.fit.plot(example1, type = "dic")
#N.B. plot.expertsurv (ported directly from survHE) plots the survival function at the posterior mean parameter values
# while it is more robust to use the entire posterior sample (make.surv), however, in this case both results are similar.
plot(example1, add.km = T, t = 0:30)+
theme_light()+
scale_x_continuous(expand = c(0, 0), limits = c(0,NA), breaks=seq(0, 30, 2)) +
scale_y_continuous(expand = c(0, 0), limits = c(0, NA), breaks=seq(0, 1, 0.05))+
geom_segment(aes(x = 14, y = cred_int_val[1], xend = 14, yend = cred_int_val[2]))
```

We can also fit the model by Penalized Maximum Likelihood approaches
through the \(\texttt{flexsurv}\)
package (Jackson 2016). All that is required that the
`method="hmc"`

is changed to `method="mle"`

with
the `iter`

argument now redundant. One argument that maybe of
interest is the `method_mle`

which is the optimization
procedure that \(\texttt{flexsurv}\)
uses. In case the optimization fails, we can sometimes obtain
convergence with the “Nelder-Mead” algorithm. If the procedure is still
failing, it may relate to the expert opinion being too informative.

It should be noted that the results will be similar to the Bayesian approach when the expert opinion is unimodal (as maximum liklelihood produces a point estimate) and relatively more informative, therefore we use the logarithmic pool which is unimodal.

We find that the AIC values also favour the Gompertz model by a large factor (not shown) and are very similar to the DIC presented for the Bayesian model.

\(\texttt{expertsurv}\) modifies some of the \(\texttt{flexsurv}\) functions, so if you wish to use revert to the original \(\texttt{flexsurv}\) functions within the same session you should run the following commands:

```
unloadNamespace("flexsurv") #Unload flexsurv and associated name spaces
require("flexsurv") #reload flexsurv
```

In this situation we place an opinion on the comparator arm.

```
param_expert_example2[[1]] <- data.frame(dist = c("norm"),
wi = c(1),
param1 = c(0.1),
param2 = c(0.005),
param3 = c(NA))
```

```
#Check the coding of the arm variable
#Comparator is 0, which is our id_St
unique(data$arm)
#> [1] 0 1
```

```
survHE.data.model <- fit.models.expert(formula=Surv(time2,status2)~as.factor(arm),data=data2,
distr=c("wei"),
method="hmc",
iter = 5000,
opinion_type = "survival",
id_St = 0,
times_expert = timepoint_expert,
param_expert = param_expert_example2)
```

We can remove the impact of expert opinion by running the same model in the \(\texttt{survHE}\) package. Alternatively we note that a \(\mathcal{Beta}(1,1)\) distribution is uniform on the survival probability and does not change the likelihood.

```
param_expert_vague <- list()
param_expert_vague[[1]] <- data.frame(dist = "beta", wi = 1, param1 = 1, param2 = 1, param2 = NA)
```

The survival function for “arm 1” has been shifted downwards slightly, however the covariate for the accelerated time factor has markedly increased to counteract the lower survival probability for the reference (arm 0).

This example illustrates an opinion on the survival difference. For illustration we use the Gompertz, noting that a negative shape parameter will lead to a proportion of subjects living forever. Clearly the mean is not defined in these cases so the code automatically constrains the shape to be positive.

```
param_expert3 <- list()
#Prior belief of 5 "months" difference in expected survival
param_expert3[[1]] <- data.frame(dist = "norm", wi = 1, param1 = 5, param2 = 0.2, param3 = NA)
survHE.data.model <- fit.models.expert(formula=Surv(time2,status2)~as.factor(arm),data=data2,
distr=c("gom"),
method="hmc",
iter = 5000,
opinion_type = "mean",
id_trt = 1, # Survival difference is Mean_surv[id_trt]- Mean_surv[id_comp]
param_expert = param_expert3)
```

As stated in the introduction this package relies on many of the core functions of the \(\texttt{survHE}\) package (Baio 2020). Because we do not not implement expert opinion with INLA and because future versions of \(\texttt{survHE}\) may introduce conflicts with the current implementation, we have directly ported the key functions from \(\texttt{survHE}\) into the package so that \(\texttt{expertsurv}\) no longer imports \(\texttt{survHE}\) (of course all credit for those functions goes to (Baio 2020) and co-authors).

In theory the same concern could apply to \(\texttt{flexsurv}\) package [flexsurv], however, this package has been released for some years and it is unlikely that the code architecture would change sufficiently to cause issues (however, for reference \(\texttt{expertsurv}\) was built with \(\texttt{flexsurv}=\text{v}2.0\)).

If you run in issues, bugs or just features which you feel would be useful, please let me know (phcooney@tcd.ie) and I will investigate and update as required.

As mentioned, I have made modifications to some of the \(\texttt{flexsurv}\) functions to accommodate exper opinion (by changing the functions within the namespace of the \(\texttt{flexsurv}\) environment). These should have no impact on the operation of \(\texttt{flexsurv}\) and these changes are only invoked when \(\texttt{flexsurv}\) is loaded. However, in the situation where you would like to revert to orginal \(\texttt{flexsurv}\) functions during the session, simply run the following:

```
unloadNamespace("flexsurv") #Unload flexsurv and associated name spaces
require("flexsurv") #reload flexsurv
```

Care should be taken, however to ensure the packages were successfully unloaded as other packages which require \(\texttt{flexsurv}\) can block the unloading to that package (which will cause an error).

As this is a Bayesian analysis convergence diagnostics should be performed. Poor convergence can be observed for many reasons, however, because of our use of expert opinion it may be a symptom of conflict between the observed data and the expert’s opinion.

Default priors should work in most situations, but still need to be considered. At a minimum the Bayesian results without expert opinion should be compared against the maximum likelihood estimates. If considerable differences are present the prior distributions should be investigated.

Because the analysis is done in JAGS and Stan we can leverage the
`ggmcmc`

package:

```
#For Stan Models # Log-Normal, RP, Exponential, Weibull
ggmcmc(ggs(example1$models$`Exponential`), file = "Exponential.pdf")
#For JAGS Models # Gamma, Gompertz, Generalized Gamma
ggmcmc(ggs(as.mcmc(example1$models$`Gamma`)), file = "Gamma.pdf")
```

Baio, Gianluca. 2020. “survHE: Survival
Analysis for Health Economic Evaluation and Cost-Effectiveness
Modeling.” *Journal of Statistical Software* 95 (14): 1–47. https://doi.org/10.18637/jss.v095.i14.

Cooney, Philip, and Arthur White. 2023. “Direct Incorporation of Expert
Opinion into Parametric Survival Models to Inform Survival
Extrapolation.” *Medical Decision Making* 1 (1):
0272989X221150212. https://doi.org/10.1177/0272989X221150212.

Jackson, Christopher. 2016. “flexsurv: A
Platform for Parametric Survival Modeling in R.” *Journal of
Statistical Software* 70 (8): 1–33. https://doi.org/10.18637/jss.v070.i08.

O’Hagan, Anthony. 2019. “Expert Knowledge Elicitation: Subjective but
Scientific.” *The American Statistician* 73 (sup1): 69–81. https://doi.org/10.1080/00031305.2018.1518265.

Oakley, Jeremy. 2021. *SHELF: Tools to Support the Sheffield
Elicitation Framework*. https://CRAN.R-project.org/package=SHELF.