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This vignette aims to clarify the usage of the
survtab_ag
and survtab
functions included in
this package. survtab_ag
estimates various survival
functions and cumulative incidence functions (CIFs) non-parametrically
using aggregated data, and survtab
is a wrapper for
survtab_ag
, to which Lexis
data is
supplied.
Two methods (surv.method
) are currently supported: The
"lifetable"
(actuarial) method only makes use of counts
when estimating any of the supported survival time functions. The
default method ("hazard"
}) estimates appropriate hazards
and transforms them into survival function or CIF estimates.
For relative survival estimation we need also to enumerate the expected hazard levels for the subjects in the data. This is done by merging expected hazards to individuals’ subintervals (which divide their survival time lines to a number of small intervals). For Pohar-Perme-weighted analyses one must additionally compute various weighted figures at the level of split subject data.
If one has subject-level data, the simplest way of computing survival
function estimates with popEpi
is by defining a
Lexis
object and using survtab
, which will do
the rest. For pre-aggregated data one may use the
survtab_ag
function instead. One can also use the
lexpand
function to split, merge population hazards, and
aggregate in a single function call and then use survtab_ag
if that is convenient.
survtab
It is straightforward to estimate various survival time functions
with survtab
once a Lexis
object has been
defined (see ?Lexis
in package Epi
for
details):
library(popEpi)
library(Epi)
data(sire)
## NOTE: recommended to use factor status variable
x <- Lexis(entry = list(FUT = 0, AGE = dg_age, CAL = get.yrs(dg_date)),
exit = list(CAL = get.yrs(ex_date)),
data = sire[sire$dg_date < sire$ex_date, ],
exit.status = factor(status, levels = 0:2,
labels = c("alive", "canD", "othD")),
merge = TRUE)
## NOTE: entry.status has been set to "alive" for all.
## pretend some are male
set.seed(1L)
x$sex <- rbinom(nrow(x), 1, 0.5)
## observed survival - explicit method
st <- survtab(Surv(time = FUT, event = lex.Xst) ~ sex, data = x,
surv.type = "surv.obs",
breaks = list(FUT = seq(0, 5, 1/12)))
## observed survival - easy method (assumes lex.Xst in x is the status variable)
st <- survtab(FUT ~ sex, data = x,
surv.type = "surv.obs",
breaks = list(FUT = seq(0, 5, 1/12)))
## printing gives the used settings and
## estimates at the middle and end of the estimated
## curves; more information available using summary()
st
##
## Call:
## survtab(formula = FUT ~ sex, data = x, breaks = list(FUT = seq(0, 5, 1/12)), surv.type = "surv.obs")
##
## Type arguments:
## surv.type: surv.obs --- surv.method: hazard
##
## Confidence interval arguments:
## level: 95 % --- transformation: log-log
##
## Totals:
## person-time:23993 --- events: 3636
##
## Stratified by: 'sex'
## Key: <sex>
## sex Tstop surv.obs.lo surv.obs surv.obs.hi SE.surv.obs
## <int> <num> <num> <num> <num> <num>
## 1: 0 2.5 0.6174 0.6328 0.6478 0.007751
## 2: 0 5.0 0.4962 0.5126 0.5288 0.008321
## 3: 1 2.5 0.6235 0.6389 0.6539 0.007748
## 4: 1 5.0 0.5006 0.5171 0.5334 0.008370
Plotting by strata (men = blue, women = red):
plot(st, col = c("blue", "red"))
Note that the correct usage of the formula
argument in
survtab
specifies the time scale in the Lexis
object over which survival is computed (here "FUT"
for
follow-up time). This is used to identify the appropriate time scale in
the data. When only supplying the survival time scale as the
right-hand-side of the formula, the column lex.Xst
in the
supplied Lexis
object is assumed to be the (correctly
formatted!) status variable. When using Surv()
to be
explicit, we effectively (and exceptionally) pass the starting times to
the time
argument in Surv()
, and
time2
is ignored entirely. The function will fail if
time
does not match exactly with a time scale in data.
When using Surv()
, one must also pass the status
variable, which can be something other than the lex.Xst
variable created by Lexis()
, though usually
`lex.Xst
is what you want to use (especially if the data
has already been split using e.g. splitLexis
or
splitMulti
, which is allowed). It is recommended to use a
factor status variable to pass to Surv()
, though a numeric
variable will work in simple cases (0 = alive, 1 = dead; also
FALSE
= alive, TRUE
= dead). Using
Surv()
also allows easy passing of transformations of
lex.Xst
, e.g. Surv(FUT, lex.Xst %in% 1:2)
.
The argument breaks
must be a named list of breaks by
which to split the Lexis
data (see
?splitMulti
). It is mandatory to assign breaks at least to
the survival time scale ("FUT"
in our example) so that
survtab
knows what intervals to use to estimate the
requested survival time function(s). The breaks also determine the
window used: It is therefore easy to compute so called period estimates
by defining the roof and floor along the calendar time scale, e.g.
breaks = list(FUT = seq(0, 5, 1/12), CAL = c(2000, 2005))
would cause survtab
to compute period estimates for
2000-2004 (breaks given here as fractional years, so 2005 is effectively
2004.99999…).
Relative/net survival estimation requires knowledge of the expected
hazard levels for the individuals in the data. In survtab
this is accomplished by passing a long-format data.frame
of
population hazards via the pophaz
argument. E.g. the
popmort
dataset included in popEpi
(Finnish
overall mortality rates for men and women).
data(popmort)
pm <- data.frame(popmort)
names(pm) <- c("sex", "CAL", "AGE", "haz")
head(pm)
## sex CAL AGE haz
## 1 0 1951 0 0.036363176
## 2 0 1951 1 0.003616547
## 3 0 1951 2 0.002172384
## 4 0 1951 3 0.001581249
## 5 0 1951 4 0.001180690
## 6 0 1951 5 0.001070595
The data.frame
should contain a variable named
"haz"
indicating the population hazard at the level of one
subject-year. Any other variables are considered to be variables, by
which to merge population hazards to the (split) subject-level data
within survtab
. These merging variables may correspond to
the time scales in the used Lexis
object. This allows for
e.g. merging in different population hazards for the same subject as
they get older.
The following causes survtab
to estimate EdererII
relative survival:
st.e2 <- survtab(Surv(time = FUT, event = lex.Xst) ~ sex, data = x,
surv.type = "surv.rel", relsurv.method = "e2",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
plot(st.e2, y = "r.e2", col = c("blue", "red"))
Note that the curves diverge due to merging in the “wrong” population hazards for some individuals which we randomized earlier to be male though all the individuals in data are actually female. Pohar-Perme-weighted estimates can be computed by
st.pp <- survtab(Surv(time = FUT, event = lex.Xst) ~ sex, data = x,
surv.type = "surv.rel", relsurv.method = "pp",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
Compare with EdererII estimates:
plot(st.e2, y = "r.e2", col = c("blue", "red"), lty = 1)
lines(st.pp, y = "r.pp", col = c("blue", "red"), lty = 2)
survtab
also allows for adjusting the survival curves by
categorical variables — typically by age groups. The following
demonstrates how:
## an age group variable
x$agegr <- cut(x$dg_age, c(0, 60, 70, 80, Inf), right = FALSE)
## using "internal weights" - see ?ICSS for international weights standards
w <- table(x$agegr)
w
##
## [0,60) [60,70) [70,80) [80,Inf)
## 1781 1889 2428 2129
w <- list(agegr = as.numeric(w))
st.as <- survtab(Surv(time = FUT, event = lex.Xst) ~ sex + adjust(agegr),
data = x, weights = w,
surv.type = "surv.rel", relsurv.method = "e2",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
plot(st.as, y = "r.e2.as", col = c("blue", "red"))
We now have age-adjusted EdererII relative/net survival estimates.
The weights
argument allows for either a list of weights
(with one or multiple variables to adjust by) or a
data.frame
of weights. Examples:
list(sex = c(0.4, 0.6), agegr = c(0.2, 0.2, 0.4, 0.2))
## $sex
## [1] 0.4 0.6
##
## $agegr
## [1] 0.2 0.2 0.4 0.2
wdf <- merge(0:1, 1:4)
names(wdf) <- c("sex", "agegr")
wdf$weights <- c(0.1, 0.1, 0.1, 0.1, 0.2, 0.2, 0.1, 0.1)
wdf
## sex agegr weights
## 1 0 1 0.1
## 2 1 1 0.1
## 3 0 2 0.1
## 4 1 2 0.1
## 5 0 3 0.2
## 6 1 3 0.2
## 7 0 4 0.1
## 8 1 4 0.1
The weights do not have to sum to one when supplied as they are
internally forced to do so within each stratum. In the
data.frame
of weights, the column of actual weights to use
must be named “weights”. When there are more than one variable to adjust
by, and a list of weights has been supplied, the variable-specific
weights are first multiplied together (cumulatively) and then scaled to
sum to one.
This adjusting can be done to any survival time function that
survtab
(and survtab_ag
) estimates. One can
also supply adjusting variables via the adjust
argument if
convenient:
st.as <- survtab(Surv(time = FUT, event = lex.Xst) ~ sex,
adjust = "agegr",
data = x, weights = w,
surv.type = "surv.rel", relsurv.method = "e2",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
Where adjust
could also be adjust = agegr
,
adjust = list(agegr)
or
adjust = list(agegr = cut(dg_age, c(0, 60, 70, 80, Inf), right = FALSE))
for exactly the same results. When adjusting by multiple variables,
one must supply a vector of variable names in data or a list of multiple
elements (as in the base function aggregate
).
One can also estimate cause-specific survival functions, cumulative incidence functions (CIFs, a.k.a. crude risk a.k.a. absolute risk functions), and CIFs based on the excess numbers of events. Cause-specific survival is close to net survival as they are philosophically highly similar concepts:
st.ca <- survtab(Surv(time = FUT, event = lex.Xst) ~ 1,
data = x,
surv.type = "surv.cause",
breaks = list(FUT = seq(0, 5, 1/12)))
st.pp <- survtab(Surv(time = FUT, event = lex.Xst) ~ 1, data = x,
surv.type = "surv.rel", relsurv.method = "pp",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
plot(st.ca, y = "surv.obs.canD", col = "blue")
lines(st.pp, y = "r.pp", col = "red")
Absolute risk:
st.cif <- survtab(Surv(time = FUT, event = lex.Xst) ~ 1,
data = x,
surv.type = "cif.obs",
breaks = list(FUT = seq(0, 5, 1/12)))
plot(st.cif, y = "CIF_canD", conf.int = FALSE)
lines(st.cif, y = "CIF_othD", conf.int = FALSE, col = "red")
The “relative CIF” attempts to be close to the true CIF without using knowledge about the types of events, e.g. causes of death:
st.cir <- survtab(Surv(time = FUT, event = lex.Xst) ~ 1,
data = x,
surv.type = "cif.rel",
breaks = list(FUT = seq(0, 5, 1/12)),
pophaz = pm)
plot(st.cif, y = "CIF_canD", conf.int = FALSE, col = "blue")
lines(st.cir, y = "CIF.rel", conf.int = FALSE, col = "red")
survtab_ag
Arguments concerning the types and methods of estimating of survival
time functions work the same in survtab_ag
as in
survtab
(the latter uses the former). However, with
aggregated data one must explicitly supply the various count and
person-time variables. Also, usage of the formula
argument
is different.
For demonstration purposes we form an aggregated data set using
lexpand
; see ?lexpand
for more information on
that function.
sire$sex <- rbinom(nrow(sire), size = 1, prob = 0.5)
ag <- lexpand(sire, birth = "bi_date", entry = "dg_date", exit = "ex_date",
status = "status", breaks = list(fot = seq(0, 5, 1/12)),
aggre = list(sex, fot))
## dropped 16 rows where entry == exit
head(ag)
## Key: <sex, fot>
## sex fot pyrs at.risk from0to0 from0to1 from0to2
## <int> <num> <num> <num> <num> <num> <num>
## 1: 0 0.00000000 336.9447 4126 12 143 12
## 2: 0 0.08333333 323.8542 3959 19 101 17
## 3: 0 0.16666667 314.1913 3822 10 86 15
## 4: 0 0.25000000 305.0373 3711 15 77 13
## 5: 0 0.33333333 296.7300 3606 16 72 13
## 6: 0 0.41666667 289.3323 3505 13 50 14
Now simply do:
st <- survtab_ag(fot ~ sex, data = ag, surv.type = "surv.obs",
surv.method = "hazard",
d = c("from0to1", "from0to2"), pyrs = "pyrs")
Or:
st <- survtab_ag(fot ~ sex, data = ag, surv.type = "surv.obs",
surv.method = "lifetable",
d = c("from0to1", "from0to2"), n = "at.risk",
n.cens = "from0to0")
Note that e.g. argument d
could also have been supplied
as
list(from0to1, from0to2)
or
list(canD = from0to1, othD = from0to2)
for identical results. The last is convenient for
e.g. surv.cause
computations:
st.ca <- survtab_ag(fot ~ sex, data = ag, surv.type = "surv.cause",
surv.method = "hazard",
d = list(canD = from0to1, othD = from0to2), pyrs = "pyrs")
plot(st.ca, y = "surv.obs.canD", col = c("blue", "red"))
One has to supply the most variables when computing Pohar-Perme
estimates (though it is probably rare to have third-source aggregated
data with Pohar-Perme weighted figures, it is implemented here to be
used as a workhorse for survtab
). For this we must
aggregate again to get the Pohar-Perme weighted counts and
subject-times:
ag <- lexpand(sire, birth = "bi_date", entry = "dg_date", exit = "ex_date",
status = "status", breaks = list(fot = seq(0, 5, 1/12)),
pophaz = popmort, pp = TRUE,
aggre = list(sex, fot))
## dropped 16 rows where entry == exit
## NOTE: 83 rows in split data had values of 'age' higher than max of pophaz's 'agegroup'; the hazard values at 'agegroup' == 100 were used for these
st.pp <- survtab_ag(fot ~ sex, data = ag, surv.type = "surv.rel",
surv.method = "hazard", relsurv.method = "pp",
d = list(from0to1 + from0to2), pyrs = "pyrs",
d.pp = list(from0to1.pp + from0to2.pp),
d.pp.2 = list(from0to1.pp.2 + from0to2.pp.2),
pyrs.pp = "ptime.pp", d.exp.pp = "d.exp.pp")
plot(st.pp, y = "r.pp", col = c("blue", "red"))
Here it is best to supply only one column to each argument since Pohar-Perme estimates will not be computed for several types of events at the same time.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.