FHIR:Vprepub-1.0 FHIR Profiling Guidelines STU3: verschil tussen versies

Introduction

FHIR requires profiling. To do profiling in a comparable way we need conventions. This page lays out these conventions.

Canonical URL

Any conformance resource needs a canonical URL. This preferably leads somewhere but does not have to be processable. For Nictiz profiles we SHALL use the following structure:

• For HCIM/zib related profiles (this should be the majority of profiles):
  http://[domain]/fhir/StructureDefinition/zib-[English hcim/zib name]
• For extensions pertaining to 1 HCIM/zib:
  http://[domain]/fhir/StructureDefinition/zib-[English hcim/zib name]-[English hcim/zib concept name]
• For extensions pertaining to multiple HCIM/zib:
  http://[domain]/fhir/StructureDefinition/[purpose]
• For other profiles:
  http://[domain]/fhir/StructureDefinition/[project]-[name]
• For value sets related to HCIMs/zibs:
  http://decor.nictiz.nl/fhir/ValueSet/[value set OID]--[effective date as yyyymmddhhmmss]

Where:

• [domain] is "nictiz.nl"
• [project] is preferably the same as its matching ART-DECOR project prefix

This convention aligns with international initiatives such as DAF and QiCore and has been confirmed/advised by Grahame Grieve.

Canonical URL's are about the identity of artefacts, not necessarily about retrieval location. URIs for the latter (for artefacts living in ART-DECOR) are described in ART-DECOR FHIR_URIs.

Versioning intro

The HL7® FHIR® specification specifies a lot of things related to versions. This text aims to stay aligned with the latest insights. Readers should first get acquainted with the core FHIR specification before reading here: http://hl7.org/fhir/versions.html

Versions of the profiles

Versions of the profiles may occur for any of the following reasons:

• New releases of the underlying HCIMs/zibs are normally followed by an update to the representing profiles
• Identified issues in existing profiles may require an update
• HL7® FHIR® updates may lead to an update of the profiles. We do not automatically follow every FHIR version as it is released

Version updates first and foremost affects the version element found in all conformance resources (profiles, value sets, extensions, search parameter, operation definition etc.). The update normally does not affect the canonical uri of the conformance resource. Conformance resources create a web of interrelated artifacts. Any resource that references another resource, e.g. Patient referencing Practitioner for the general practitioner, normally does so without a version indicator (uri|version). This means that any reference points dynamically to 'the latest version' of the artifact. If you were to build a consistent set of versions you would need to add the version to any reference in the set of conformance resources, and update the full set after any updating any particular part.

Around the advent of FHIR R4, the follow up of STU3, there will be a new versioning layer that allows packaging of profiles into a consistent set without affecting the profiles itself. The packaging mechanism will be tested in May 2018, and should greatly simplify specification and implementation of versions.

Versions in instances

To understand how instances of resources are interpreted by a receiving server we should look at two things:

• The indicator for the profile that the sender added to the instance (if any). This indicator would be in the Resources.meta.profile element and may include a version, e.g.
  <profile value="http://fhir.nl/fhir/StructureDefinition/nl-core-patient"/>
• The profile (versions) that the server defaults to in the absence of a profile indicator in the instance

If the server does not support the profile (version) as indicated in the instance it may do any of the following things. See also the relevant section in the FHIR specification.

1. Try to support the instance based on what it can support. This may lead to ignoring any element it doesn't know, except for modifierElements. If modifier elements are encountered, the instance should be rejected
2. Reject the instance

Note: as specified in the core FHIR specification, the server SHALL use its CapabilityStatement to indicate its behavior around unsupported elements (ignore or reject)

Associating functional definition to StructureDefinition

Any StructureDefinition that profiles a Resource does so because there is some kind of logical definition dictating how. These functional definitions are known as Clinical Building Blocks, Health Information models or in Dutch Zorginformatiebouwstenen or ZIB's. Profiles SHALL have a traceable relationship with their functional counterpart(s).

The FHIR specification contains several solutions for this problem, ConceptMap (>=STU1), StructureMap (>=STU3), ElementDefinition.mapping. Neither of these solutions are mature and cover our use case.

• ConceptMap: works best for value sets and codes
• StructureMap: overcomplicated and unclear how to apply and whether or not this has a future
• ElementDefinition.mapping: is a free text mapping inside the profile. This means we cannot add mappings to profiles from third parties without updating their resource

Proposed way forward:

1. The functional definitions live in ART-DECOR and every concept in this functional definition has a versioned id
2. The technical FHIR profile elements we want to map to have an optional @id attribute, but according to Tracker#9843 it is a required item for profiles (StructureDefinition)
3. In our own profiles we can make sure we populate this Element/@id and associate the functional concept on id / id basis. We found that DAF Profiles populate these ids as well.
   • Example: <element id="Patient:DAF-Patient.extension:race">...</element>
   • Example: <element id="2.16.840.1.113883.3.1937.99.62.3.2.3--20110128000000">
4. In profiles we reference from third parties that do not have this Element/@id populated we need less precise method. We will deal with that when we need to

Translating DECOR to FHIR

Status: proposal

Quite often we will populate FHIR artefacts from DECOR artefacts. In such cases, FHIR identification must be derived from DECOR identification.

DECOR uses the attributes id and effectiveDate to identify concepts, datasets, transactions, valueSets and templates. The artefacts with the same id but different effectiveDates are subsequent versions of the same artefact (though artefacts can also get a new id for a new version, such as when a new dataset is derived from an older one).

In FHIR. every resource can have an id, which is the "logical id" of the resource. This id never changes once assigned, like DECOR id and effectiveDate. Resources usually have an url too, which also identifies the resource, but should be resolvable. The URL can contain the id.

The following ART-DECOR artefacts map to FHIR artefacts:

The following FHIR attributes are constructed in the following way, when generated from ART-DECOR. Non-digits are stripped from the timestamp in @effectiveDate because they violate the FHIR rules for id.

Status is translated from DECOR to FHIR:

Profile meta data

• URL: see above
• Resource ID: n/a
• Name: see above
• Description: An enter resource type resource as defined by the Dutch Clinical Building Building Block Zorginformatiebouwsteen naam version
• Version: as applicable to the profile, not the CBB it refers to
• Publishing: publishing date (should find way to align across all CBB profiles)
• Lifecycle status: as applicable (normally draft or active)
• Experimental: normally false or null
• Display label: null
• Requirements: null (is already evident by the description)
• Copyright: CC0
• Publisher: Nictiz
• Contact information: n/a
• Use context: n/a
• Terminology codes: n/a
• Mappings: uri to the version of the CBB specification
  <mapping>
      <identity value="zib-patient"/>
      <uri value="https://zibs.nl/wiki/Contactpersoon(NL)"/>
      <name value="Zorginformatiebouwsteen Contactpersoon"/>
  </mapping>
• Identifiers: n/a
• Meta data: tbd
• Implicit rules (URI): n/a
• Language: n/a (most content is en-US from the core, some is nl-NL from the CBBs)
• Kind: n/a (auto handled by Forge)
• Constrained Type: n/a (auto handled by Forge based on selection at creation time)
• Abstract: false
• Base: n/a (auto handled by Forge based on selection at creation time)
• FHIR version: n/a (auto handled by Forge based on selection at creation time) - initially 1.0.2 DSTU2

Miscellaneous

• We only profile elements, cardinalities and bindings that require profiling. We leave other elements, cardinalities and bindings as-is
• For elements that map to Clinical Building Blocks (CBB) we copy the name from the CBB element into the profile element.name.
  • For now we do not copy the description of the CBB elements into the profile. This is to avoid maintenance/synching problems. The CBB descriptions however shall be available at publication.
• FHIR URI Strategy (draft document with potentially good info)
• When adding invariants we use "cbb-[cbb-name]-[number]" as a key. Example: cbb-alert-1
• For vocabulary bindings to CBB ValueSets we use binding strength "extensible".
• For FHIR base resource elements with datatype code and binding required it may be that the CBB has other/additional codes to specialize the FHIR codes. To conform to FHIR and the CBB we will use the FHIR required element and binding and specify the mapping. We will use 1 extension to cover this use case.
  • Extension URI http://nictiz.nl/fhir/StructureDefinition/code-specification
  • The extension is of datatype CodeableConcept which also support text as fallback
  • The extension receives its ValueSet binding in the context of the profile element and does not have a binding internally
  • The extension is only required to be present when the extension actually holds a specialization, e.g. CRITH + fatal. It is optional when the mapping is equal
  • The mapping shall be documented in a ConceptMap
  • Example AllergyIntolerance.criticality

Open vs. Closed Modeling

We have chosen for "open" modeling for the ZIBs, since they are very general en not meant for one specific sue case. Excluding unspecified elements here is not an option, since we expect derived profiles for more specific use cases that may need those elements.

Cardinality/conformance mapping table

Cardinality applies to the number of occurrences that an element MAY/SHOULD/SHALL have. Minimum cardinality is integer 0. Maximum cardinality is "n" or "*" (exact character depends on tooling). If the minimum cardinality is higher than 0, then an element has to be present.

Conformance applies to what a system MAY/SHOULD/SHALL support. When data for an element is missing, e.g. because it is not applicable, then the element may be absent, but when conformance MustSupport is active, then a conformant application SHALL support it. Contrary to V3, there is no concept of NullFlavor in FHIR, so whenever an element is 1..1 in FHIR, there is no escape through NullFlavor: a value SHALL be present.

Reference: ElementDefinition.mustSupport

This poses a need for a mapping table from cardinality/conformance in CBBs (ZIBs) versus that in profiles.

Data type mapping table

DECOR defines a set of data types. In most cases the mapping to FHIR is straightforward, though there are a number of cases which are not as clear-cut. When defining extensions, or specifying the datatype of an Observation or Questionnaire.item in FHIR, a mapping to the relevant FHIR datatype needs to be done. There we need for a mapping table for datatypes in CBBs (ZIBs) versus those in profiles.