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CIMI Practitioners' Guide

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<<<CIMI Practitioners' Guide is under construction>>>
<<<        2017-02-12-DRAFT-A  >>>

Introduction

The Integration of Information Models and Tools (IIM&T) Project


This Practitioners' Guide is intended to keep HL7 Clinical Information Models and Tools (IIM&T) Project’s co-sponsors, stakeholders and proponents informed and engaged regarding understanding and using the Common Logical Information Model CLIM (SOLOR, FHIM, CIMI, CQF, DCM). Formulated by SMEs and endorsed by a solid base of stakeholders, this guide supports communications which is one of the three tenets of this project. The other two, namely, the integration work itself, supplemented by governance capitalizes on near term efforts to progress the project’s accomplishments and challenges, and is showcased here. While injection of resources are certainly needed and more stakeholders who will push for this work, we are maling the most of here-and-now efforts and meetings to demonstrate the merits of the integration of information models, enabled by tooling in order to bolster implementation assets such as but not limited to FHIR. Contributions are in turn acknowledged. We know this area is complex, and is not well understood and offer this insight to assist. We believe there are too many efforts trying to build the ultimate skyscraper, starting however on the third floor, without a sufficient foundation. To better our current delivery systems and position us for the ultimate Learning Health System where the data demands and stakeholders are greater, this effort offers what is regarded as the missing link; the foundation to semantic interoperability. Your feedback and suggestions in this quest to communicate the evolution of this work are welcome.


Acknowledgement

Collaboration that Grows with a Strong SME Base

  • the contents of this Guide came from
    • CIMI Co-Chairs
    • Linda Bird BIT, IHTSDO
    • Galen Mulrooney, FHA and VA contractor
    • Richard Esmond, PenRad LLC
    • Stanley Huff, Intermountain Healthcare
  • Members of the following SDOs
    • IHTSDO, POC: Linda Bird BIT
    • HL7 Work Groups (PC, CDS, CIC, EHR, SOA, Vocab)
    • The Open Group Healthcare Forum, Jason Lee POC
    • ISO/CEN, POCs: Gerard Freriks, William Goossen, Gary Dickinson
  • Federal Agency staff and contractors
    • Department of Defense
    • Veterans Administration
    • Interagency Program Office
    • ONC OST
    • Federal Health Architecture (FHA)
    • MITRE
  • Members of the following Healthcare Organizations** Intermountain Healthcare
    • PenRad, Inc., Results4Care
    • HSPC and other interested parties
  • Faculty, Staff and Students
    • The University of Utah


Scope

CIMI considers its work in the "Universal Realm”; where, current work might be considered "US Realm".

  1. CIMI uses International Standards, when available.
  2. CIMI is using a SNOMED extension including LOINC and RxNorm (SOLOR).
    1. SNOMED and LOINC are used beyond the US, such as Canada and UK.
    2. RxNorm is the most international medication terminology available
    3. RxNorm includes chemical ingredients, which are international; where, US pharmaceutical units, packaging and manufacturers can be replaced by foreign equivalents
  3. Technically, CIMI's SOLOR semantic-bindings are completely defined; where,
    1. SOLOR follows the SNOMED observation model with explicit context expressions (e.g., body site)
    2. CIMI's SOLOR terminology bindings are exemplars; where, incomplete exemplars lead to inconsistent implementation artefacts, such as FHIR or CDA profiles and extensions.


Situation

  • CIMI's Goal is to help people live the healthiest lives possible,
    • by enabling a “Learning Health System” supporting areas such as, but not limited to, Precision Medicine, CDS, Genomic/Omic, EHR and Ancillary systems; where,
  • CIMI's Approach capitalizes on the inroads made with the exchange of data, standards and standards adoption, and,
    • brings back a focus on data in order to make additional and necessary advancements and
    • requires data that is computable, usable, extensible, and interpretable across disparate systems - a state that currently does not exist.
  • CIMI's IT Objective is to make computable healthcare-data efficiently-and-effectively available when it is needed, where it needed and how it is needed to
    • integrate existing healthcare-related information models, with semantically-consistent data,
      • including appropriate provenance data (who, what, when, where, why, how)
      • to support development (implementation and test) projects
    • support Model Driven Development pilot-projects across healthcare related platforms,
      • using seamless model-instantiated tooling to generate implementation profiles and extension (e.g., FHIR, CDA, etc.)
    • promote the development and use of free and open models, that are foundational to computable-interoperability
    • maintain a clean separation of clinical model semantics using a SNOMED extension including LOINC and RxNorm (SOLOR)
    • build upon and improve existing work; in particular US Core and FHIR core
    • establish the Integration of SOLOR+FHIM+CIMI+CQF+US Core as the enabling foundation for
      • Detailed Clinical Models (DCMs) for semantic-interoperability and
      • Knowledge Artifacts (KNARTs) for analytics and reasoning
    • align models and tooling to seamlessly extend the usability of these assets
    • use model-instantiated tools to generate consistent-and-traceable standards-and-implementation artifacts
    • advance in constructive steps through pilots and agile development-cycles of build, test, learn, plan and deploy cycles
    • support pilot projects with appropriate Communications and Governance strategies


Charter

CIMI will coordinate activities with other workgroups to establish aligned logical models and standards that support computable data-sharing in support of consistent health processes and achievement of improved patient outcomes. This coordination will encourage harmonized standards to manage data capture, clinical workflow and interoperability.


Products, Benefits and Contributions

The CIMI workgroup will coordinate with relevant groups related to

  1. Harmonized healthcare logical models, resulting in consistent computable implementation standards, profiles, extensions and guides to enable improvement in health care processes and patient health outcomes.
  2. CIMI curated Architecture (Principles, Reference Archetypes, Semantic-Anchor Patterns, Processes), documentation and training.
  3. Model driven development methodologies and tools related to HL7 standards and artifacts.


Projects

CIMI_Projects_Mind_Map.jpg

Plans

CIMI_Plans-Schedule.jpg

Principles

<<< work in progress >>>


ASSERTION vs. EVALUATION_RESULT criteria

  1. 'Reasoning' vs. 'Finding', 'Subjective' vs. 'Objective', 'Fact-ish' vs. 'Judgement-ish' categories work > 80% of the time; but, they are not reliable criteria for a small set of "edge cases'.
    1. In most cases it is obvious, when to use ASSERTION (e.g., 'Reasoning', 'Subjective', 'Judgement-ish' things, such as DIAGNOSIS, PROBLEM, COMPLAINT, FAMILY_HISTORY)
      1. The Patient DISCHARGE_DIAGNOSIS is ... (implying the set of findings defining the DISCHARGE_DIAGNOSIS)
      2. John has blue eyes
    2. In the small number of cases, where it is not obvious when to use ASSERTION, CIMI prefers
      1. ASSERTIONS be used when the answer to an EVALUATION_RESULT is 'Present' or 'Absent', 'Yes' or 'No', 'True' or 'False', etc.
    3. Although theoretically possible; but for practical implementation reasons, CIMI does not support round-trip conversion between EVALUATION_RESULT and ASSERTION structures, as shown by the set of ATTRIBUTE vs. EVALUATION_RESULT attributes shown above.

Legends

UML

CIMI_UML_Relationships.jpg


  • UML models are being used for CIMI BMM; where, UML relationships are shown above:
  • Many figures were done in the FreeMind open-source Mind Maps; where, the legend, download information and basic structure are given below.


Mind Maps

CIMI_Legend_Mind_Map.jpg

Architectural Framework


CIMI BMM 5 Layers


The CIMI Architecture consists of the three Basic Meta Model (BMM) Reference Model layers and two Archetype layers shown here.

The CIMI Reference Model is expressed using the OpenEHR Basic Metamodel (BMM) Language. The archetype layers are expressed using the OpenEHR Archetype Definition Language (ADL). While reference model modules define classes, attributes, and class hierarchies, the archetype layers only specify progressive constraints on the reference model but do not introduce new classes, attributes, and class-class relationships.

  1. The CIMI Core BMM Reference Model provides the core granularity of the CIMI model and introduces its top-level classes such as the DATA_VALUE class and the LOCATABLE class. This reference layer module defines the CIMI primitive types and core data types.
  2. The CIMI Foundational BMM Reference Model is closely aligned to ISO13606 and the OpenEHR Core Reference Model. It defines foundational CIMI clinical documents and clinical record patterns. It also introduces the PARTY, ROLE, and PARTY_RELATIONSHIP patterns and defines the top-level CLUSTER class for complex CIMI type hierarchies. CQI Knowledge Artifacts may also leverage this layer.
  3. The CIMI Clinical BMM Reference Model consists of the classes derived from existing CIMI archetypes, the FHIM, QUICK, vMR, and QDM. This layer defines the set of 'schematic anchors' (to borrow Richard Esmond's term) or core reference model patterns from which all CIMI archetype hierarchies and ultimately Detailed Clinical Models (DCMs) derive. Requirements for this layer come from FHIM, vMR, QDM, QUICK, FHIR US Core, SDC, etc...
    1. The 'goal' is to define the reference models with low FHIR transformation costs where feasible noting that we will inherently have some divergence due to the different requirements underlying both models.
    2. Galen points out that, FHIM’s expressivity will not carry over to CIMI DCMs given the models' different requirements (e.g., FHIM includes finance and accounting).
  4. The CIMI Foundational Archetype Patterns define the top-level constraints on the CIMI Reference Model. These typically consist of attribute formal documentation and high level attribute semantic and value set bindings. Archetypes at this layer will provide the foundational requirements for future US Core and QI Core profiles. Future pilots will explore the generation of US Core and QI Core archetypes from these CIMI archetypes.
  5. The CIMI Detailed Clinical Model Layer represents the set of leaf-level constraining profiles on the foundational archetypes to create families of archetypes that only vary in their finest terminology bindings and cardinality constraints. This layer is intended to support clinical interoperability through an unambiguous specification of model constraints for information exchange, information retrieval, and data processing.

From layers 1-5, we define the set of transformations (e.g., SIGG (MDHT, MDMI)) to generate the corresponding FHIR profiles including the US Core and QI Core profile sets. Note that FHIR profiles can be generated from the various levels of the archetype hierarchy depending on requirements. The lower down in the hierarchy, the more prescriptive the profile is in terms of constraints. Much like ADL Archetypes, FHIR profiles can be layered.

It is important to note that some FHIR profiles may be derived from the Foundational Archetype Layer (e.g., US Core, some QI Core profiles, some CQIF profiles on PlanDefinition, Questionnaire and ActivityDefinition, etc...) and others from the DCM Layer (e.g., bilirubin, HgA1c, etc...). In other words, the arrow for FHIR Profiles stems out of the outer box rather than the last of the inner boxes (the DCM box).


BMM Hierarchy

The CIMI Reference Model is done in UML and contains three Basic Meta-Model (BMM) hierarchical layers of Pattern structures aka Clinical Pattern structures:

  1. Each Pattern contains a single class or group of related classes that can be constrained by ADM or AML archetypes in order to define a family of related and consistent Detailed Clinical Models (DCMs), such as types of
    1. Lab Orders,
    2. Procedures,
    3. Skin Wounds, etc.
  2. The three layer CIMI Reference Model contains modular sets of (Clinical) Patterns, which can be used to create leaf-level DCMs:
    1. Core BMM Reference Model Level-1 defines core types and two root classes:
      1. Data Types
      2. Data Value Types
      3. LOCATABLE class, from which the majority of CIMI domain classes derive and
      4. ASSOCIATION_CLASS from which we derive
    2. Foundational BMM Reference Model Level-2 defines the foundational underpinnings of the CIMI model.
      1. This structure aligns with the ISO 13606 EHR and the OpenEHR Reference Models.
      2. The Foundation Reference Model defines the top-level hierarchies to derive lower-level classes and clinical patterns:
      3. CLUSTER,
      4. COMPOSITION,
      5. CONTENT,
      6. PARTY,
      7. ACTOR,
      8. ROLE,
      9. PARTICIPATION, and
      10. PARTY_RELATIONSHIP.
    3. Clinical BMM Reference Model Level-3 builds upon the Level-1 Core and Level-2 Foundation to specify the Level-4 CIMI Preferred Archetypes aka Semantic Anchors for DCMs.
  3. The CIMI Core and Foundational reference modules provide the core semantics, structure, and granularity of the CIMI model.
  4. the CIMI Clinical Reference Model module provides an intuitive domain semantic-anchor view for DCMs.
  5. This modular approach allows for
    1. additional, domain-specific Level-3 Reference Archetypes and Level-4 Patterns
    2. alternate iso-semantic patterns to be introduced at the appropriate level in the model.
    3. Over time, it can be expected that the layers will hierarchically become more stable
      1. Level-1 Core BMM purposely being most stable.
      2. Level-2 Foundation BMM might change, such as when new underlying taxonomy-structures are added.
      3. Level-3 Clinical BMM might change, such as when new clinical disciplines and data-structures are added.
      4. Level-4 Reference Archetypes changing, such as when new domains are added.
      5. Level-5 DCMs under a constant-state of flux, such as when new information-exchange requirements are added.
    4. If change occurs, it should be backward-compatible with-respect-to lower layers and legacy-DCMs.

Archetype Hierarchy

The CIMI archetype hierarchies form the second part of the CIMI model. These hierarchies serve two primary purposes:

  1. They enable the progressive application of constraints on reference clinical patterns including the specification of terminology constraints that assign formal meanings to both model attributes and their range.
  2. They allow for the definition of sets of models whose members vary solely based on the constraints they apply to a common underlying reference model pattern. Archetypes can specialize more general archetypes in ADL. They do so by progressively constraining the underlying reference model pattern in a manner that is consistent with and not contradictory to the constraints specified in archetypes higher up in the hierarchy. Examples of constraint refinements are listed below:
    1. A top-level archetype restricts the range of Ingredient.substanceCode to the set of all concepts subsumed by the SNOMED CT concept ‘Pharmaceutical/biologic product’. A downstream specialization of this archetype restricts the Ingredient.substanceCode to ‘Metoprolol’.
    2. A top-level archetype assigns the SNOMED CT concept ‘Procedure site (attribute)’ as the semantic binding of the attribute Procedure.site. A downstream specialization of this Detailed Clinical Models (DCMs), highly specific models that enable the interoperable exchange of clinical information, typically reside at the leaf-level of CIMI archetype hierarchies. The cumulative constraints applied on a DCM are intended to be precise enough to allow for the unambiguous exchange of interoperable clinical information and thus constitute highly specific constraints on the underlying reference model pattern.

Introduction

Core Modeling Principles

The following principles guide CIMI’s modeling approach:

  1. CIMI favors a design by specialization over a design by constraint approach. This approach is summarized as follows:
    1. if a class has a number of specializations, each requiring a different set of attributes, common attributes are represented in the parent class while child attributes are added to the appropriate specializations. An alternative approach may be to include the union of all attributes in a single class and constrain attributes out at the archetype level.
      1. The former approach is preferred over the latter except in certain cases.
      2. For instance, if a specialization differs from its parent by a single attribute, the inclusion of the attribute in the parent class may be preferred over the creation of a new class.
  2. CIMI generally favors the definition of explicit attributes in the reference model over the slicing of lists in archetype definitions. The attribute subset pattern is achieved by defining a multi-cardinality attribute in the reference model and specifying subsets of the list elements in archetypes.
    1. For instance, one may specify that the LOCATABLE class, the supertype of all CIMI classes, has an attribute called participation of type PARTICIPATION and whose cardinality is 0..*.
    2. In an archetype, one may then constrain the participation attribute in the following manner.
      1. The first element of the list represents the author.
      2. The second element represents the data enterer.
      3. The third element represents the location where the authoring activity took place.
      4. The fourth element of the list represents the system where the information was recorded.
      5. While such subsets are allowed in both UML and ADL, CIMI generally avoids their use and favors the explicit representations of such subsets as full-fledged attributes in the model. For instance, CIMI explicitly adds an attribute for the
        1. agent of an activity,
        2. the location of an activity,
        3. the entity involved in the performance of the activity, and so on.
    3. The motivation for this approach stems from the fact that CIMI is a logical model rather than a physical model and favors greater reference model expressivity over physical patterns that enable better economies of structure.
  3. CIMI may offer a number of variants for a given attribute.
    1. For instance, CIMI defines bodyLocation: AnatomicalLocation and bodyLocationPrecoord:
      1. CODED_TEXT to support both a coded and a post-coordinated anatomical location.
    2. Similarly, Assertion.dueToCode:CODED_TEXT and Assertion.dueTo:
      1. ClinicalStatement allow users to link an assertion to another clinical statement or simply define its type to be CODED_TEXT.
    3. Archetypes will need to specify a single property in such cases in order to avoid semantic collision.


Terminology Alignment

Information models are often developed independently of clinical ontologies. As a result, many information models align poorly with the terminologies or ontologies upon which they ultimately depend for their formal semantics. Moreover, by not explicitly specifying the model’s semantics, the meaning of the model is left open for interpretation during implementation further hindering interoperability. In an effort to better align models of use with models of meaning, the Clinical Information Model is designed to align closely with the SNOMED CT Concept Model wherever such an overlap exists. In CIMI, the model’s formal semantics are specified through terminology bindings defined at the archetype level. These terminology bindings occur at three levels:

  1. To define the relationship between the attribute and its class. CIMI model attributes are aligned with their corresponding SNOMED CT concept model attributes when such a correspondence exists.
    1. An example in the CIMI Finding Assertion Model, the body site data element aligns with the SNOMED CT concept 363698007|Finding site (attribute)|from the SNOMED CT Clinical finding concept model.
  2. To define the semantics that the attribute can contain. CIMI model attribute ranges are aligned with the ranges specified for their corresponding SNOMED CT concept model attribute when such a correspondence exists. Using the example above, the range for the Body Site is the range defined in the SNOMED CT technical guide for Finding Site Anatomical or acquired body structure | 442083009 (<<)
  3. To define the post-coordinated representation of some of the semantics of the archetype using the SNOMED CT concept model. CIMI preferred models favor post-coordination in the model rather than in the terminology.
    1. In some cases, CIMI archetypes may be associated with SNOMED CT expressions, provided that the expression conforms to the constraints specified for the flattened archetype.
    2. For instance, a CIMI Clinical Statement may be associated with a SNOMED CT Situation with Explicit Context expression or a pre-coordinated code.
    3. We are currently investigating the use of SNOMED CT Templates for such bindings



Core BMM

The CIMI Core BMM Reference Model provides the core granularity of the CIMI model and introduces its top-level classes such as the DATA_VALUE class and the LOCATABLE class. This reference layer module defines the CIMI primitive types and core data types.


CIMI_Core_BMM_Mind_Map.jpg


CIMI_Core_BMM_Data_Value_Types_Mind_Map.jpg


CIMI2017-01StyleGuide-04 Core BMM.jpg


CIMI2017-01StyleGuide-02 Primitive Types.jpg


CIMI2017-01StyleGuide-03 Data Value Types.jpg

Foundation BMM

The CIMI Foundational BMM Reference Model is closely aligned to ISO13606 and the OpenEHR Core Reference Model. It defines foundational CIMI clinical documents and clinical record patterns. It also introduces the PARTY, ROLE, and PARTY_RELATIONSHIP patterns and defines the top-level CLUSTER class for complex CIMI type hierarchies. CQI Knowledge Artifacts may also leverage this layer.


CIMI_Foundation_BMM_2_Mind_Map.jpg


CIMI Foundation Reference Model_UML

Clinical BMM

  • The CIMI Clinical BMM Reference Model consists of the classes derived from existing CIMI archetypes, the FHIM, QUICK, vMR, and QDM. This layer defines the set of 'schematic anchors' (to borrow Richard Esmond's term) or core reference model patterns from which all CIMI archetype hierarchies and ultimately Detailed Clinical Models (DCMs) derive. Requirements for this layer come from FHIM, vMR, QDM, QUICK, FHIR US Core, SDC, etc...
    • The 'goal' is to define the reference models with low FHIR transformation costs where feasible noting that we will inherently have some divergence due to the different requirements underlying both models.
    • Galen points out that, FHIM’s expressivity will not carry over to CIMI DCMs given the models' different requirements (e.g., FHIM includes finance and accounting).


Clinical_Statement Overview

CIMI_Clinical_BMM_Context_Mind_Map

Clinical_Statement (Top View)

CIMI_Clinical_BMM_Clinical_Statement_Mind_Map.jpg

Clinical_Statement-Topic

CIMI_Clinical_BMM_Clinical_Statement_Topic_Mind_Map.jpg

Clinical_Statement-Association

CIMI_Clinical_BMM_Clinical_Statement_Association_Mind_Map.jpg

Clinical_Statement-Context

CIMI_Clinical_BMM_Clinical_Statement_Context_Mind_Map.jpg


Clinical_Statement-Data_Packages

CIMI_Clinical_BMM_Clinical_Data_Structure_Packages_1_Mind_Map.jpg


CIMI_Clinical_BMM_Clinical_Data_Structure_Packages_2_Mind_Map.jpg

Foundation Archetypes

CIMI_Foundational_Architype_Patterns_Mind_Map.jpg
  • The CIMI Foundational Archetypes Patterns define the top-level constraints on the CIMI Reference Model. These typically consist of attribute formal documentation and high level attribute semantic and value set bindings. Archetypes at this layer will provide the foundational requirements for future US Core and QI Core profiles. Future pilots will explore the generation of US Core and QI Core archetypes from these CIMI archetypes.

Detailed Clinical Models (DCMs)

  • The CIMI Detailed Clinical Model Layer represents the set of leaf-level constraining profiles on the foundational archetypes to create families of archetypes that only vary in their finest terminology bindings and cardinality constraints. This layer is intended to support clinical interoperability through an unambiguous specification of model constraints for information exchange, information retrieval, and data processing.

Skin-Wound DCM

  • 2917-02-09-1000 ET Patient Care Workgroup Telecom
  • Attendees: Jay, Susan, Richard, Claude, Steve
  1. Skin Wound content & scope
    1. Braden
    2. Skin Assessment
    3. Wound Assessment, with Pressure Ulcer specialization
    4. No Skin Risk Assessment (out of scope)
  2. Schedule
    1. Feb 13: Requirements UML and Terminology spreadsheet finished
    2. Feb 13 to Mar 3 - VA verification and validation of spreadsheet
      1. Diagram
      2. Data-Element and Value-Set Spreadsheet
    3. Mar 8: Presented at LOINC conference by Susan

UML

Skin Wound UML Requirements


Mind Map

Skin Wound Context Mind Map.jpg


Skin Wound Detail-1


Skin Wound Detail-2


Skin Wound Detail-3

Tools

FHA sponsored FHIM and SIGG (MDHT and MDMI) have the capability for generating FHIR implementation models. With the adoption of CIMI information requirements (informed by FHIM), SIGG can generate CIMI archetypes and FHIR Structure Definitions (FSDs) and compare them to their source archetypes to confirm the process.

  • FHIM & MDHT could then serve as one of the “translator” tools.
  • MDMI can serve as one of the "mapping" tool.
  • Part of the tool authoring activity is to add new SOLOR terminology content as necessary to meet requirements derived from existing specifications; where,
    • there is a versioning and publication step between the SOLOR box/layer and the CLIM box/layer. 
    • there is a versioning and publication step between the CLIM box/layer and MDHT/MDMI; where, the arrows metaphor conveys the publication step. 
  • IHTSDO workbench with ISAAC plugin authoring tools are in the SOLOR box/layer. 
  • ADL workbench, enterprise architect UML tool, etc. need to be able to import SOLOR content, so they can build the profiles using the SOLOR terminology foundation…
Tools
  • SOLOR (SnOmed LOinc, Rxnorm) terminology authoring project can provide the terminology foundation for FHIM, CQF, DCMs and FHIR profile and extension development. SOLOR creates Lightweight Expression of Granular Objects (LEGOs) with description-logic semantics aka SNOMED expressions; where, SOLOR can be treated as a single, coherent terminology systems that covers essential healthcare domains.
  • FHIM is FHA's Federal Healthcare Information Model, which is a high-level logical healthcare model, which covers approximately 36 clinical domains and has been vetted by Federal Agency SMEs and clinicians. Details are available at www.FHIMS.org
  • CIMI is Clinical Information Model Initiative which defines Terms-of-Reference AKA Principles, modeling style guidelines, a CIMI Core Reference Model, Reference Archetypes, Patterns and Detailed Clinical Models (DCMs); where, a CIMI Model is a clear, complete, concise, correct and consistent logical semantic-and-syntactic description of a healthcare concept, which can be instantiated as a computable implementation object that is interoperable among systems.
  • CQF is Clinical Quality Framework to support Continuous Quality Improvement (CQI) with a Quality Improvement and Clinical Knowledge or QUICK data model, Clinical Quality Language (CQL) supporting clinical decision support (CDS) and clinical quality measures (CQM).
  • FHIR defines a set of "Resources" that represent granular clinical concepts; where, CIMI's CLIM and tooling can be used to create consistent FHIR and other implementation paradig profiles and extensions. SIGG creates FHIR Structure Definitions (FSDs); where, FHIR tools can convert FSDs into FHIR Resource extensions and profiles. FHIR Core Resources, Profiles and Extensions can be managed in isolation, or aggregated into complex documents.

The following is a list of authoring tools that might be pertinent to investigate as we develop CIMI tooling:

References


Jan - Sept CIMI Investigative Study / Task Force Supporting documents


Appendix A

IT Objectives


Our IT objective is to make the appropriate data available when it is needed, where it needed and how it is needed. We plan to integrate existing models, with semantically-consistent computable-data, including provenance data (who, what, when, where, why, how) across different platforms, e.g., population health, Clinical Decision support, EHR patient documentation systems, etc. using tooling to generate various implementation styles, including HL7 Fast Healthcare Interoperable Resources (FHIR).


IT Objectives


Our IT objective is to make the appropriate data available when it is needed, where it needed and how it is needed. We plan to integrate existing models, with semantically-consistent computable-data, including provenance data (who, what, when, where, why, how) across different platforms, e.g., population health, Clinical Decision support, EHR patient documentation systems, etc. using tooling to generate various implementation styles, including HL7 Fast Healthcare Interoperable Resources (FHIR).


High Level Architectural View

CIMI_High_Level_Architecture.jpg


  • The High-Level Architectural-View slide shows how CIMI-FHIM-SOLOR-CQF Integration enables Consistent “Foundational Health Information” and “Common Clinical Information” to support Computable Semantic-Interoperability in “Continuum of Care” Implementations and aggregated, portable and computable patient-records, care plans, clinical knowledge and other shared healthcare information.
  • The top Business Architecture typically includes:
    • Legal, ethical requirements, policies and rules
    • Societal/organizational (e.g., cities, states and countries) requirements
    • EHR-system requirements
      • Vocabulary (Shared: Syntax, words, phrases)
      • Ways to present and enter data via screens, forms, etc.
      • Notions about archiving/documentation/information security
      • Care quality measurement and improvement through clinical knowledge
  • The center Information architecture, includes:
    • FHIM, EHRS-FM and CQF, which consolidate Health domain requirements
    • CIMI and LEGO; where, LEGO is the Q&A subset of CIMI, using the CIMI Observation Model and Description Logic.
    • Other Info Models, e.g., CQF, SDC, DAF, V2, CCD, etc. –
    • SOLOR Terminology and Value Sets based on SNOMED-CT expressions.
  • The bottom Solution Architecture includes:
    • EHR-systems with CCDA, FHIR, NIEM, JSON API, RDF, HL7 V2 & V3 interfaces among EHR-system Services.
    • Supporting services (Terminologies, Terminology servers (e.g., SOLOR), Value set servers, Protocol servers, Clinical guideline servers, clinical decisions support servers, Presentation/data input services, Exchange services)
    • Technical Infrastructural services: networks, internet, information security,
    • Hardware and Software


<<<with a clear separation of semantics.>>>


Problem: Skyscraper Analogy

CIMI_Problem-Skyscraper Analogy.jpg


  • BLUF (Bottom Line Up Front): As is: no shared terminology content (floor 1), no shared information models (floor 2), then they are building from the 3rd floor up. No shared value from the 3rd floor up. 
  • Future State: shared terminology content (floor 1), shared information models (floor 2), sharable value built on floors above. 
  • In a perfect world the following would be done concurrently and with close collaboration
    • Recommended Solution Part 1: We integrate SOLOR into FHIM, Concurrently, resolving SOLAR gaps
    • Recommended Solution Part 2: We integrate CIMI, FHIM and CQF 
    • Recommended Solution Part 3: We follow Agile refinement cycles through pilots and implementations
    • Recommended Solution Part 4: We develop adequate documentation, test cases, fixtures and supporting resources
  • In the real world, we are asking:
    • the Federal Partners to provide resources to make efficient and effective progress in the near, mid and long term.
    • the Federal Partners to work together to deliver—in an ongoing way—a single integrated terminology system (SOLOR), that meets all US regulatory equirements, while simplifying implementation for developers.
    • the FHA to facilitate Federal Partner governance and configuration management of this work
    • The ONC OTS to endorse this initiative and facility resources
    • We are asking the IPO to provide coordination and facilitation
    • We are asking HL7 to facilitate
      • international, commercial and academic peer review and
      • ballot governance and configuration management.
      • Coordination of an ISO ballot (this will be several years from now)
  • Analogy of the Challenge: Today’s efforts occur as if we’re always trying to build the ultimate skyscraper, starting on the 3rd Floor.
    • Inconsistencies exist/become extended producing transformational (mapping) efforts = models, models everywhere
    • The problem is that today’s healthcare systems do not capture information and its context consistently, and consequently, they cannot easily share-or-merge information from different sources to create a computable operational-picture (aka longitudinal patient-records, care plans, clinical knowledge and other shared healthcare information across time, multiple care locations and differing contexts).
    • If continued and unchecked, even the best of implementation accelerators, like FHIR with its extensions and profiles, allow far too much implementation variation; where, each project often creates, from scratch, yet, another information model, e.g. through a mapping exercise.
    • The missed opportunity is to leverage a shared logical Reference Information Model minimizing the duplicative-work, avoiding inconsistencies and avoiding the necessity to engage these SMEs, these resources and our larger community. This is the “models, models everywhere phenomenon ”.
    • As an example, Standards, in general, use different formats and rules for ‘simple’ things like: name, address, dates. Resulting in EHR-systems that after decades cannot uniformly exchange this ‘simple’ ubiquitous data; let alone ‘complex’ clinical health data.
      • the HL7 EHR Interoperability workgroup, in its analysis “Record Entry Lifecycle Event Metadata using FHIR,” found substantial provenance (who, what, when, where and how) inconsistencies among FHIR resources .
      • The SOLOR/LEGO team found FHIR tries to define things such as attributes for anatomy, that are not based on a particular model of anatomy, and thus you get semantic overlap, with the burden of reconciliation, which may not even be possible, if left to the end user.

SOLOR Standardizes Terminology

CIMI_SOLOR_Terminology_Foundation.jpg


  • Gentamicin is an example of the non-consistant terminologies
  • Why we can simplify now?
    • Licensing models have changed so we can implement native standards
    • LOINC and SNOMED are integrating content via a shared logical model
    • RxNorm can be extracted into a shared logical model
    • SNOMED + LOINC + RxNorm + post-coordination provides comprehensive coverage for typical clinical data representation requirements 
  • In distinguishing terminology and model capability: Concrete Example
    • In SOLOR / RxNorm = description of dosage of penicillin and what it means;
    • With the use of the FHIM it will tell you if its part of substance administration and/or adverse event.
    • RxNorm doesn’t do that
  • CIMI can offer a DCM that providers can use in the detailed execution of a particular domain


Integrated Model Stack

CIMI_Integrated_Model_Stack.jpg


As shown in this figure,

  • each model contributes to an Integrated Model Stack, the proposed operational architecture involves the definition of clinical knowledge in the form of formally modeled information artifacts that could be used in compose-able health records, care plans and other shared clinical data.
  • the combination of SOLOR, FHIM, CIMI DCMs and CQF KNARTs while complementary fulfill a different information modeling contribution.
  • SOLOR is SNOMED with an extension for LOINC and RXNorm.
  • FHIM is Federal Health Information Model
  • CIMI DCMs is Clinical Information Model Initiative Detailed Clinical Model
  • CQF KNARTs is Clinical Quality Framework Knowledge Artefacts

Federated Information Model Development

CIMI_Federated_Information_Model_Development.jpg


Consistent FHIR extensions-and-Profiles can be achieved by:

  • Following CIMI Principles and Reference Architecture (see principles and Architectural Framework sections)
  • Using Model Driven Development tools, such as SIGG (MDHR, MDMI) (see tools section)
  • Governance and Configuration Management of artefacts. (see Governance section)

Federated Software Development

CIMI_Federated_Software_Development.jpg


  • Ideally, implementers can meet Project Needs by reusing FHIR Extensions and Profiles, from a FHIR Artefact repository
  • Alternately,
    • CLIM models can be refined to meet requirements,
    • Tools (e.g., SIGG) can use CLIM models to create needed implementation FHIR artefacts.


Federated FHIR Extensions-and-Profiles Development-Lifecycle

CIMI_Model_Development_Lifecycle.jpg


IIM&T Software Development "on FHIR"

File:CIMI Software Development on-FHIR.jpg


  1. The Figure shows potential Use-Case processes and products; where,
    1. Path 1 7  8 represents the ideal case; where, reusable FHIR-based components are available.
    2. Path 1  2  3  4  7  8 is when new requirements are met locally; but, HL7 Items A-C are not updated.
    3. Path 1  2  3  4  5 6  7  8 is when new requirements are met locally; and, HL7 Items A-C are updated.
    4. Step 9 is periodically done to configuration manage, version control, publish and standardize HL7 Items A-C.
  2. Our objectives are
    1. CLIM and FHIR artifacts are tool based and feely available .
    2. To produce quality documentation and training videos to enable:
      1. 1, 2, 3, 4 done by Clinical Business-Analysts
      2. 2, 3 and 4 governance done by the organizations doing the work
      3. 5, 6 and 9 governance done by the appropriate HL7 workgroups
      4. 7 and 8 done by Software Developers
  3. At the January HL7 Workgroup meeting CIC requested further clarification / detail of the Figure to indicate where and how clinicians can efficiently participate in the process.
    1. As an example, when Michael van der Zel does Business Analysis / FHIR Development, he generally follows these steps:
      1. Understand and document the business process (aka Use-Case) (Figure, process 1)
      2. Detail the process into steps
        1. EHRS-FM might help determine functional requirements and their conformance criteria
        2. Determine the needed information for each of the process steps (inputs and outputs)
        3. EHRS-FM can help because it has a mapping to FHIM and FHIM has a mapping to FHIR
        4. FHIM might also be used directly
        5. Find existing models and terminology (DCM, FHIR, etc., (Figure, Items A. and C.)
        6. Create / adjust / profile DCM or terminology, if needed (Figure, processes 2 & 3)
        7. Find mapped FHIR resources or map / create / profile FHIR Resources from DCM logical models identified in previous steps. (Figure, process 4)
        8. Use existing FHIR implementation to realize the system (deploy the profiles) (Figure 1, process 7 and Item C)
        9. Do Connecthatons (Figure, process 8)
    2. Michael believes the process analysis step is very important and should be made explicit; where, CIMI’s CLIM is about logical models that are transformed (using predefined mappings) to implementation models (FHIR profile Resources). For the transformation of CLIM, we will explore the use of the SIGG and FHIR tooling. So, we intend to express CLIM as FHIR Logical Models AKA FHIR Logical Structure Definitions), using SIGG tooling, and then use FHIR mapping to generate FHIR resource profiles, analogous to what ClinFhir (David Hay) is doing. For testing software, Michael thinks the Connectathons are very important.
  4. Following the Figure, a software (SW) project will follow some combination of these use case steps:
    1. Do Business and FHIR Analysis to determine system requirement-specifications and conformance criteria (Figure 1, process 1); where, EHRS-FM might be used; because, it is traceable to CLIM (FHIM) and CLIM will be traceable to FHIR.
      1. Note that the HL7 Service Aware Interoperability Framework (SAIF) Enterprise Compliance and Conformance Framework (ECCF) can be used to maintain a project’s requirements-specifications, design and test artifacts.
    2. Maintain the FHIM, CIMI, CQF, etc. models (Figure 1, process 2) to meet the requirements; where, these models may be updated and bound to SOLOR . This work can be done with an UML tool or the OpenEHR ADL workbench.
    3. Maintain SOLOR (SNOMED with extensions for LOINC and RxNorm shown as Figure 1, process 3). If appropriate SOLOR concepts which do not exist, can be added using the IHTSDO workbench with ISAAC plugin. Processes 2 and 3 are closely related and may iterate back and forth or may be done simultaneously.
    4. Use SIGG (MDHT, MDMI) to generate the needed implementation artifacts (e.g., FHIR structure definitions for profiles or extensions, CDA or NIEM IEPD specifications can also be done).
    5. Governance involves change control, configuration management and version control; where, CLIM governance is generally federated. That is, local development organizations govern their own artifacts and may wish to provide versions to HL7. Appropriate HL7 workgroups govern HL7 artifacts and ballots.
    6. Similarly, FHIR governance is generally federated; where, local development organizations govern their own artifacts and may wish to provide versions to HL7. At HL7, FHIR-compliant reusable-artifacts are governed by the FHIR workgroup.
    7. Develop software components are generally done by commercial, government and academic organizations and their contractors. HL7 provides artifacts, documentation and training to empower these efforts.
    8. Test and use software components is generally done by commercial, government and academic organizations and their contractors.
    9. Periodically, CIMI and FHIM artifacts are balloted as HL7 and/or ISO standard, which include the set of clinical domain information models (e.g., FHIM covers 30+ domains), CIMI DCMs with SOLAR derived terminology value-sets. Having standard requirements-specification conformance criteria traceable to FHIR implementation artifacts can maximize efficiency and effectivity of multi-enterprise clinical-interoperability. These tool-based standardized clinical interoperability artifacts can be augmented with business, service and resource requirements-specifications conformance-criteria models and implementation artifacts. HL7 and its workgroups have identified best-practice principles and tools supporting its clinical-artifacts, which can provide standardized approaches for government, industry and academic organizations to adopt, train and use. These standard use-cases, conformance criteria models and implementation artifacts can be used and maintained within an HL7 Service Aware Interoperability Framework (SAIF) and Enterprise Compliance and Conformance Framework (SAIF) to support specific business use-cases, process models, acquisitions and/or developments.


FHIR Clinical Reasoning

  • In the September 2016 ballot cycle, CQF balloted the FHIR-Based Clinical Quality Framework (CQF-on-FHIR) IG as an STU (Standard for Trial Use). This guidance was used to support the CQF-on-FHIR and Payer Extract tracks in the September 2016 FHIR connect-a-thon. The guidance in the FHIR STU was prepared as a Universal Realm Specification with support from the Clinical Quality Framework (CQF) initiative, which is a public-private partnership sponsored by the Centers for Medicare & Medicaid Services (CMS) and the U.S. Office of the National Coordinator for Health Information Technology (ONC) to identify, develop, harmonize, and validate standards for clinical decision support and electronic clinical quality measurement.
  • Part of the reconciliation for the CQF-on-FHIR IG September ballot involved incorporating the contents of the IG as a new module in FHIR, the FHIR Clinical Reasoning module.

The Clinical Reasoning module provides resources and operations to enable the representation, distribution, and EVALUATION_RESULT of clinical knowledge artifacts such as clinical decision support rules, quality measures, order sets, and protocols. In addition, the module describes how expression languages can be used throughout the specification to provide dynamic capabilities. Clinical Reasoning involves the ability to represent and encode clinical knowledge in a very broad sense so that it can be integrated into clinical systems. This encoding may be as simple as controlling whether a section of an order set appears based on the specific conditions that are present for the patient in content in a CPOE system, or it may be as complex as representing the care pathway for patients with multiple conditions.

  • The Clinical Reasoning module focuses on enabling two primary use cases:
    • Sharing - The ability to represent clinical knowledge artifacts such as decision support rules, order sets, protocols, and quality measures, and to do so in a way that enables those artifacts to be shared across organizations and institutions.
    • EVALUATION_RESULT - The ability to evaluate clinical knowledge artifacts in the context of a specific patient or population, including the ability to request decision support guidance, impact clinical workflow, and retrospectively assess quality metrics.
  • To enable these use cases, the module defines several components that can each be used independently, or combined to enable more complex functionality. These components are:
    • Expression Logic represents complex logic using languages such as FHIRPath and Clinical Quality Language (CQL).
    • Definitional Resources describe definitional resources, or template resources that are not defined on any specific patient, but are used to define the actions to be performed as part of a clinical knowledge artifact such as an order set or decision support rule.
    • Knowledge Artifacts represent clinical knowledge artifacts such as decision support rules and clinical quality measures.
  • For 2017, the Clinical Quality Framework initiative will continue to develop the FHIR Clinical Reasoning module and related standards. Specifically, the reconciled changes to the CQF-IG will be applied to the FHIR Clinical Reasoning module and published as part of FHIR STU3 in March 2017. The QI Core profiles will be updated to derive directly from US Core, and the QUICK tooling will be updated to provide conceptual documentation, as well as logical models suitable for use in authoring and evaluating CDS and CQI knowledge artifacts. The CQF initiative is actively working with multiple groups to continue to refine and implement the resources and guidance provided by the FHIR Clinical Reasoning module, including the National Comprehensive Cancer Network, the Centers for Disease Control and Prevention, and the National Committee for Quality Assurance.

SIGG (MDHT, MDMI) Tool

While the overall development plan for SIGG (MDHT, MDMI) has not changed, the timeline and/or path must shift in 2017. FHA will need to cease developmental funding of SIGG this month (January) due to other emergent priorities and the SIGG team is wrapping up final development activity and the documentation component in preparation for disengagement. If the JIF proposal is accepted or the IPO can provide for further development under the FPG JET moving forward, then the SIGG is prepared to continue SIGG development unabated.

Currently the SIGG and the components of the SIGG are being used, and extended, in the following projects:

  1. FHIR Proving Ground IPO Jet – MDMI Models are being developed for DoD DES native format and the VA eHMP native format to provide data in conjunction with existing MDMI Models for FHIR Profiles. The use case is a complete round-trip starting with a FHIR query from a FHIR Server, accessing a native server with its native access language, and returning the result to the FHIR service as a FHIR payload. This project has extended the use of SIGG to include not only payload Semantic Interoperability but also a prototype for query Semantic Interoperability. Additionally, there was an alternative approach to the SIGG that was evaluated in this process, and the SIGG was selected as the superior solution.
  2. SAMHSA / AHIMA Case Definition Templates – The SIGG tooling, also branded as the SAMHSA Semantic Interoperability Workbench, is being extended to let Subject Matter Experts define and build special purpose templates for clinical pathways. The resulting templates are called Case Definition Templates. In the selection of the appropriate tooling for the project, 11 other products were evaluated.
  3. HL7 Structured Documents CDA on FHIR Working Group – The SIGG is being used by the working group to replace manually developed spreadsheets using automatically generate spreadsheets from the CCDA and FHIR MDMI Models. This will support the iterative development process of the Working Group as well as providing more detailed and precise information for the community.
  4. VA VLER – The use of the SIGG is being investigated by VA Subject Matter Experts to replace a process that uses manually development spreadsheets for mappings between VLER and CCDA data formats.
  5. HL7 FHIR RDF Working Group – Current members of the SIGG team and the HL7 FHIR RDF team are exploring how components of the SIGG and the SHEX / RDF technology can be coupled together to provide even broader capabilities.

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