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fhircrackr
is a package designed to help analyzing HL7
FHIR1
resources.
FHIR stands for Fast Healthcare Interoperability Resources and is a standard describing data formats and elements (known as “resources”) as well as an application programming interface (API) for exchanging electronic health records. The standard was created by the Health Level Seven International (HL7) health-care standards organization. For more information on the FHIR standard, visit https://www.hl7.org/fhir/.
While FHIR is a very useful standard to describe and exchange medical data in an interoperable way, it is not at all useful for statistical analyses of data. This is due to the fact that FHIR data is stored in many nested and interlinked resources instead of matrix-like structures.
Thus, to be able to do statistical analyses a tool is needed that allows converting these nested resources into data frames. This process of tabulating FHIR resources is not trivial, as the unpredictable degree of nesting and connectedness of the resources makes generic solutions to this problem not feasible.
We therefore implemented a package that makes it possible to download FHIR resources from a server into R and to tabulate these resources into (multiple) data frames.
The package is still under development. The CRAN version of the
package contains all functions that are already stable, for more recent
(but potentially unstable) developments, the development version of the
package can be downloaded from GitHub using
devtools::install_github("POLAR-fhiR/fhircrackr")
.
This vignette is an introduction on the basic functionalities of the
fhircrackr
and should give you a broad overview over what
the package can do. For more detailed instructions on each subtopic
please have a look the other vignettes. This introduction covers the
following topics:
Prerequisites
Downloading resources from a FHIR server
Flattening resources
Multiple entries
Saving and loading downloaded bundles
The complexity of the problem requires a couple of prerequisites both
regarding your knowledge and access to data. We will shortly list the
preconditions for using the fhircrackr
package here:
First of all, you need the base URL of the FHIR server you want
to access. If you don’t have your own FHIR server, you can use one of
the available public servers, such as
https://hapi.fhir.org/baseR4
or
http://fhir.hl7.de:8080/baseDstu3
. The base URL of a FHIR
server is often referred to as [base].
To download resources from the server, you should be familiar
with FHIR
search requests. FHIR search allows you to download sets of
resources that match very specific requirements. The
fhircrackr
package offers some help building FHIR search
requests, for this please see the vignette on downloading FHIR
resources.
In the first step, fhircrackr
downloads the
resources in xml format into R. To specify which elements from the FHIR
resources you want in your data frame, you should have at least some
familiarity with XPath expressions. A good tutorial on XPath expressions
can be found here:
https://www.w3schools.com/xml/xpath_intro.asp.
In the following we’ll go through a typical workflow with
fhircrackr
step by step. The first and foremost step is of
course, to install and load the package:
To download resources from a FHIR server, you need to send a FHIR
search request using fhir_search()
. This introduction will
not go into the details of building a valid FHIR search request. For
that, please see the vignette on downloading FHIR resources or have a
look at ?fhir_url
. Here we will use a simple example of
downloading all Patient resources from a public HAPI server:
request <- fhir_url(url = "http://fhir.hl7.de:8080/baseDstu3", resource = "Patient")
patient_bundles <- fhir_search(request = request, max_bundles = 2, verbose = 0)
The minimum information fhir_search()
requires is a url
containing the full FHIR search request in the argument
request
which you can build by a call to
fhir_url()
or by providing an explicit string. In general,
a FHIR search request returns a bundle of the resources you
requested. If there are a lot of resources matching your request, the
search result isn’t returned in one big bundle but distributed over
several of them. If the argument max_bundles
is set to its
default Inf
, fhir_search()
will return all
available bundles, meaning all resources matching your request. If you
set it to 2
as in the example above, the download will stop
after the first two bundles. Note that in this case, the result may
not contain all the resources from the server matching your
request.
If you want to connect to a FHIR server that uses basic
authentication, you can supply the arguments username
and
password
. If your server uses some form of bearer token
authorization, you can supply the token in the argument
token
.
As you can see in the next block of code, fhir_search()
returns a fhir_bundle_list
object, which is basically a
list of xml objects where each list element represents one bundle of
resources, so a list of two xml objects in our case:
length(patient_bundles)
#> [1] 2
patient_bundles
#> An object of class "fhir_bundle_list"
#> [[1]]
#> A fhir_bundle_xml object
#> No. of entries : 20
#> Self Link: http://hapi.fhir.org/baseR4/Patient
#> Next Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#>
#> {xml_node}
#> <Bundle>
#> [1] <id value="ce958386-53d0-4042-888c-cad53bf5d5a1"/>
#> [2] <meta>\n <lastUpdated value="2021-05-10T12:12:43.317+00:00"/>\n</meta>
#> [3] <type value="searchset"/>
#> [4] <link>\n <relation value="self"/>\n <url value="http://hapi.fhir.org/b ...
#> [5] <link>\n <relation value="next"/>\n <url value="http://hapi.fhir.org/b ...
#> [6] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837602"/ ...
#> [7] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/example-r ...
#> [8] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837624"/ ...
#> [9] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837626"/ ...
#> [10] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837631"/ ...
#> [11] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837716"/ ...
#> [12] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837720"/ ...
#> [13] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837714"/ ...
#> [14] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837721"/ ...
#> [15] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837722"/ ...
#> [16] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837723"/ ...
#> [17] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837724"/ ...
#> [18] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/cfsb16116 ...
#> [19] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837736"/ ...
#> [20] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837737"/ ...
#> ...
#>
#> [[2]]
#> A fhir_bundle_xml object
#> No. of entries : 20
#> Self Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#> Next Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#>
#> {xml_node}
#> <Bundle>
#> [1] <id value="ce958386-53d0-4042-888c-cad53bf5d5a1"/>
#> [2] <meta>\n <lastUpdated value="2021-05-10T12:12:43.317+00:00"/>\n</meta>
#> [3] <type value="searchset"/>
#> [4] <link>\n <relation value="self"/>\n <url value="http://hapi.fhir.org/b ...
#> [5] <link>\n <relation value="next"/>\n <url value="http://hapi.fhir.org/b ...
#> [6] <link>\n <relation value="previous"/>\n <url value="http://hapi.fhir.o ...
#> [7] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837760"/ ...
#> [8] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837766"/ ...
#> [9] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837768"/ ...
#> [10] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837781"/ ...
#> [11] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837783"/ ...
#> [12] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837784"/ ...
#> [13] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837787"/ ...
#> [14] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837788"/ ...
#> [15] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837789"/ ...
#> [16] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837790"/ ...
#> [17] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837791"/ ...
#> [18] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837792"/ ...
#> [19] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837793"/ ...
#> [20] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837794"/ ...
#> ...
If for some reason you cannot connect to a FHIR server at the moment
but want to explore the following functions anyway, the package provides
two example lists of bundles containing Patient and MedicationStatement
resources. See ?patient_bundles
and
?medication_bundles
for how to use them.
Now we know that inside these xml objects there is the patient data
somewhere. To bring it into a tabular format, we will use
fhir_crack()
which creates one table per resource type
requested in the design
argument. The most important
argument fhir_crack()
takes is bundles
, the
list of bundles that is returned by fhir_search()
. The
second important argument is design
, an object that tells
the function which data to extract from the bundle and how.
fhir_crack()
returns (a list of) data.frames or data.tables
(if argument data.table = TRUE
).
The object that is passed to the design
argument can be
of class fhir_table_description
or
fhir_design
. A fhir_table_description
is used
when you want to extract just one resource type, resulting in a single
table. A fhir_design
is basically a named list of
fhir_table_descriptions
and is used when you want to
extract several resource types at once, resulting in a named list of
tables.
The details of what the different elements of a
fhir_table_description
or fhir_design
mean are
described in the vignette on flattening resources. Please refer to this
document for more information, as we will just use one simple example
here.
#define table_description
table_description <- fhir_table_description(
resource = "Patient",
cols = c(
id = "id",
use_name = "name/use",
given_name = "name/given",
family_name = "name/family",
gender = "gender",
birthday = "birthDate"
),
sep = " ~ ",
brackets = c("<<", ">>"),
rm_empty_cols = FALSE,
format = 'compact',
keep_attr = FALSE
)
#have a look
table_description
#> A fhir_table_description with the following elements:
#>
#> resource: Patient
#>
#> cols:
#> ------------ -----------------
#> column name | xpath expression
#> ------------ -----------------
#> id | id
#> use_name | name/use
#> given_name | name/given
#> family_name | name/family
#> gender | gender
#> birthday | birthDate
#> ------------ -----------------
#>
#> sep: ' ~ '
#> brackets: '<<', '>>'
#> rm_empty_cols: FALSE
#> format: 'compact'
#> keep_attr: FALSE
Each of the five style elements sep
,
brackets
, remove_empty_columns
,
format
and keep_attr
in
table_description
can also be controlled directly by the
argument of the same name of fhir_crack()
. If one of these
function arguments is NULL
(the default value for each
argument), the corresponding value specified from the
table_description
will be used. If the argument in
fhir_crack
is set, the corresponding value in
fhir_table_description
will be overruled. If both the
fhir_crack
function argument and the corresponding
component in fhir_table_description
are NULL
,
the respective default value (sep = ':::'
,
brackets = NULL
, rm_empty_cols = TRUE
,
format = 'compact'
, keep_attr = FALSE
) will be
applied.
After it is defined, the fhir_table_description
can be
used in fhir_crack()
like this:
#flatten resources
patients <- fhir_crack(bundles = patient_bundles, design = table_description, verbose = 0)
#have look at the results
head(patients)
#> id use_name
#> 1 <<1>>2072744 <<1.1>>official
#> 2 <<1>>2431578 <<1.1>>official
#> 3 <<1>>2431568 <<1.1>>official ~ <<2.1>>usual ~ <<3.1>>maiden
#> 4 <<1>>2431577 <<1.1>>official
#> 5 <<1>>2431757 <<1.1>>old
#> 6 <<1>>2431759 <<1.1>>official
#> given_name
#> 1 <<1.1>>K ~ <<1.2>>Kari
#> 2 <<1.1>>Roman
#> 3 <<1.1>>Peter ~ <<1.2>>James ~ <<2.1>>Jim ~ <<3.1>>Peter ~ <<3.2>>James
#> 4 <<1.1>>Ganpat ~ <<1.2>>Malekar
#> 5 <NA>
#> 6 <<1.1>>ABC
#> family_name gender birthday
#> 1 <<1.1>>Nordmann <<1>>female <<1>>2018-09-12
#> 2 <<1.1>>Smith <<1>>male <<1>>2021-07-19
#> 3 <<1.1>>Chalmers ~ <<3.1>>Windsor <<1>>male <<1>>1974-12-25
#> 4 <<1.1>>Malekar <<1>>male <<1>>1996-02-07
#> 5 <<1.1>>murali <<1>>male <NA>
#> 6 <<1.1>>XYZ <<1>>male <<1>>1998-01-03
A particularly complicated problem in flattening FHIR resources is caused by the fact that there can be multiple occurrences of the same FHIR element within one resource. For a more detailed description of this problem, please see the vignette on flattening resources.
In general, fhir_crack()
will paste multiple entries for
the same attribute together in the table, using the separator provided
by the sep
argument.
Let’s have a look at the following simple example, where we have a
bundle containing just two Patient resources. The example is part of the
fhircrackr
package and you can make it available like
this:
This represents a bundle list with only one very simple bundle of just two Patient resources which looks like this:
<Bundle>
<Patient>
<id value='id1'/>
<address>
<use value='home'/>
<city value='Amsterdam'/>
<type value='physical'/>
<country value='Netherlands'/>
</address>
<name>
<given value='Marie'/>
</name>
</Patient>
<Patient>
<id value='id3'/>
<address>
<use value='home'/>
<city value='Berlin'/>
</address>
<address>
<type value='postal'/>
<country value='France'/>
</address>
<address>
<use value='work'/>
<city value='London'/>
<type value='postal'/>
<country value='England'/>
</address>
<name>
<given value='Frank'/>
</name>
<name>
<given value='Max'/>
</name>
</Patient>
</Bundle>
The first resource has just one entry for the address attribute. The second Patient resource has an address attribute with three entries containing different elements and also two entries for the name attribute.
This is where the style elements of the
table_description
comes into play:
table_description <- fhir_table_description(
resource = "Patient",
brackets = c("[", "]"),
sep = " | ",
rm_empty_cols = FALSE,
format = 'compact',
keep_attr = FALSE
)
df <- fhir_crack(bundles = bundles, design = table_description, verbose = 0)
df
#> address.city address.country
#> 1 [1.1]Amsterdam [1.1]Netherlands
#> 2 [1.1]Berlin | [3.1]London [2.1]France | [3.1]England
#> address.type address.use id name.given
#> 1 [1.1]physical [1.1]home [1]id1 [1.1]Marie
#> 2 [2.1]postal | [3.1]postal [1.1]home | [3.1]work [1]id3 [1.1]Frank | [2.1]Max
Multiple entries are pasted together with the specified separator
string (in this case: " | "
) in between and the indices
(inside the specified bracket strings (here: "["
and
"]"
)) display the entry the value belongs to. That way you
can see that Patient resource 2 had three entries for the attribute
address
and you can also see which attributes belong to
which entry.
If you know beforehand that you only need home addresses, you can use predicates in your XPath expressions that filter for that and avoid multiple entries in your table:
table_description <- fhir_table_description(
resource = "Patient",
cols = c(
id = "id",
city = "address[use[@value='home']]/city",
type = "address[use[@value='home']]/type",
country = "address[use[@value='home']]/country",
name = "name/given"
)
)
df_filtered <- fhir_crack(bundles = bundles, design = table_description, verbose = 0)
df_filtered
#> id city type country name
#> 1 id1 Amsterdam physical Netherlands Marie
#> 2 id3 Berlin <NA> <NA> Frank:::Max
If you can’t filter during cracking, there are several options to deal with the resulting multiple entries in your table.
If the table produced by fhir_crack()
contains multiple
entries, you’ll probably want to divide these entries into distinct
observations at some point. This is where fhir_melt()
comes
into play. fhir_melt()
takes an indexed table with
multiple entries in one or several columns
and spreads (aka
melts) these entries over several rows.
fhir_melt(
indexed_data_frame = df,
columns = "address.city",
brackets = c("[", "]"),
sep = " | ",
all_columns = FALSE
)
#> resource_identifier address.city
#> 1 1 [1]Amsterdam
#> 2 2 [1]Berlin
#> 3 2 <NA>
#> 4 2 [1]London
The new variable resource_identifier
maps which rows in
the created table belong to which row (usually equivalent to one
resource) in the original table. brackets
and
sep
have to be the same character vectors that have been
used to build the indices with fhir_crack()
.
columns
is a character vector with the names of the
variables/columns you want to melt. You can provide more than one column
here but it makes sense to only have variables from the same repeating
attribute together in one call to fhir_melt()
:
cols <- c("address.city", "address.use", "address.type", "address.country")
fhir_melt(
indexed_data_frame = df,
columns = cols,
brackets = c("[", "]"),
sep = " | ",
all_columns = FALSE
)
#> resource_identifier address.city address.use address.type address.country
#> 1 1 [1]Amsterdam [1]home [1]physical [1]Netherlands
#> 2 2 [1]Berlin [1]home <NA> <NA>
#> 3 2 <NA> <NA> [1]postal [1]France
#> 4 2 [1]London [1]work [1]postal [1]England
With the argument all_columns
you can control whether
the resulting table contains only the molten columns or all columns of
the original table:
molten <- fhir_melt(
indexed_data_frame = df,
columns = cols,
brackets = c("[", "]"),
sep = " | ",
all_columns = TRUE
)
molten
#> address.city address.country address.type address.use id
#> 1 [1]Amsterdam [1]Netherlands [1]physical [1]home [1]id1
#> 2 [1]Berlin <NA> <NA> [1]home [1]id3
#> 3 <NA> [1]France [1]postal <NA> [1]id3
#> 4 [1]London [1]England [1]postal [1]work [1]id3
#> name.given resource_identifier
#> 1 [1.1]Marie 1
#> 2 [1.1]Frank | [2.1]Max 2
#> 3 [1.1]Frank | [2.1]Max 2
#> 4 [1.1]Frank | [2.1]Max 2
Values on the other variables will just repeat in the newly created rows. For more information please see the vignette on flattening resources.
Once you have sorted out the multiple entries, you might want to get
rid of the indices in your data frame. This can be achieved using
fhir_rm_indices()
:
fhir_rm_indices(indexed_data_frame = molten, brackets = c("[", "]"))
#> address.city address.country address.type address.use id name.given
#> 1 Amsterdam Netherlands physical home id1 Marie
#> 2 Berlin <NA> <NA> home id3 Frank | Max
#> 3 <NA> France postal <NA> id3 Frank | Max
#> 4 London England postal work id3 Frank | Max
#> resource_identifier
#> 1 1
#> 2 2
#> 3 2
#> 4 2
Again, brackets
should be given the same character
vector that was used for fhir_crack()
and
fhir_melt()
respectively.
Since fhir_crack()
ignores all data that are not
specified in design
, it makes sense to store the original
search result for reproducibility and in case you realize later on that
you need elements from the resources that you haven’t extracted at
first.
There are two ways of saving the FHIR bundles you downloaded: Either you save them as R objects, or you write them to an xml file.
If you want to save the list of downloaded bundles as an
.rda
or .RData
file, you can’t just use R’s
save()
or save_image()
on it, because this
will break the external pointers in the xml objects representing your
bundles. Instead, you have to serialize the bundles before saving and
unserialize them after loading. For single xml objects the package
xml2
provides serialization functions. For convenience,
however, fhircrackr
provides the functions
fhir_serialize()
that can be used directly on the bundles
returned by fhir_search()
and
fhir_unserialize()
:
#serialize bundles
serialized_bundles <- fhir_serialize(bundles = patient_bundles)
#have a look at them
head(serialized_bundles[[1]])
#> [1] 58 0a 00 00 00 03
#create temporary directory for saving
temp_dir <- tempdir()
#save
saveRDS(serialized_bundles, file = paste0(temp_dir, "/bundles.rda"))
If you reload this bundle, you have to unserialize it before you can work with it:
#unserialize
bundles <- fhir_unserialize(bundles = serialized_bundles_reloaded)
#have a look
bundles
#> An object of class "fhir_bundle_list"
#> [[1]]
#> A fhir_bundle_xml object
#> No. of entries : 20
#> Self Link: http://hapi.fhir.org/baseR4/Patient
#> Next Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#>
#> {xml_node}
#> <Bundle>
#> [1] <id value="ce958386-53d0-4042-888c-cad53bf5d5a1"/>
#> [2] <meta>\n <lastUpdated value="2021-05-10T12:12:43.317+00:00"/>\n</meta>
#> [3] <type value="searchset"/>
#> [4] <link>\n <relation value="self"/>\n <url value="http://hapi.fhir.org/b ...
#> [5] <link>\n <relation value="next"/>\n <url value="http://hapi.fhir.org/b ...
#> [6] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837602"/ ...
#> [7] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/example-r ...
#> [8] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837624"/ ...
#> [9] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837626"/ ...
#> [10] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837631"/ ...
#> [11] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837716"/ ...
#> [12] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837720"/ ...
#> [13] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837714"/ ...
#> [14] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837721"/ ...
#> [15] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837722"/ ...
#> [16] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837723"/ ...
#> [17] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837724"/ ...
#> [18] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/cfsb16116 ...
#> [19] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837736"/ ...
#> [20] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837737"/ ...
#> ...
#>
#> [[2]]
#> A fhir_bundle_xml object
#> No. of entries : 20
#> Self Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#> Next Link: http://hapi.fhir.org/baseR4?_getpages=ce958386-53d0-4042-888c-cad53bf5d5a1 ...
#>
#> {xml_node}
#> <Bundle>
#> [1] <id value="ce958386-53d0-4042-888c-cad53bf5d5a1"/>
#> [2] <meta>\n <lastUpdated value="2021-05-10T12:12:43.317+00:00"/>\n</meta>
#> [3] <type value="searchset"/>
#> [4] <link>\n <relation value="self"/>\n <url value="http://hapi.fhir.org/b ...
#> [5] <link>\n <relation value="next"/>\n <url value="http://hapi.fhir.org/b ...
#> [6] <link>\n <relation value="previous"/>\n <url value="http://hapi.fhir.o ...
#> [7] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837760"/ ...
#> [8] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837766"/ ...
#> [9] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837768"/ ...
#> [10] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837781"/ ...
#> [11] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837783"/ ...
#> [12] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837784"/ ...
#> [13] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837787"/ ...
#> [14] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837788"/ ...
#> [15] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837789"/ ...
#> [16] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837790"/ ...
#> [17] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837791"/ ...
#> [18] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837792"/ ...
#> [19] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837793"/ ...
#> [20] <entry>\n <fullUrl value="http://hapi.fhir.org/baseR4/Patient/1837794"/ ...
#> ...
After unserialization, the pointers are restored and you can continue
to work with the bundles. Note that the example bundles
medication_bundles
and patient_bundles
that
are provided with the fhircrackr
package are also provided
in their serialized form and have to be unserialized as described on
their help page.
If you want to store the bundles in xml files instead of R objects,
you can use the functions fhir_save()
and
fhir_load()
. fhir_save()
takes a list of
bundles in form of xml objects (as returned by
fhir_search()
) and writes them into the directory specified
in the argument directory
. Each bundle is saved as a
separate xml-file. If the folder defined in directory
doesn’t exist, it is created in the current working directory.
To read bundles saved with fhir_save()
back into R, you
can use fhir_load()
:
fhir_load()
takes the name of the directory (or path to
it) as its only argument. All xml-files in this directory are read into
R and returned as a list of bundles in xml format just as returned by
fhir_search()
.
This work was carried out by the SMITH consortium and the cross-consortium use case POLAR_MI; both are part of the German Initiative for Medical Informatics and funded by the German Federal Ministry of Education and Research (BMBF), grant no. 01ZZ1803A , 01ZZ1803C and 01ZZ1910A.
FHIR is the registered trademark of HL7 and is used with the permission of HL7. Use of the FHIR trademark does not constitute endorsement of this product by HL7↩︎
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.