1. openEHR �a primer Thomas Beale
Utrecht 2007
2. Introductions Thomas Beale
Chief Technology Officer �Ocean Informatics (Aus, UK)
Senior Researcher, Centre for Health Informatics, UCL (UK)
Chair ARB openEHR Foundation
5 years intl standards work
20 years in software engineering
13 years working with clinical people
3. What is openEHR Today?
5. The openEHR Foundation Non-profit organisation based at University College, London (UCL)
Established by UCL and Ocean nformatics in 2000 to own the IP
800+ Members from 71 countries
All specifications & schemas publicly available
Software open source (GPL, LGPL, MPL)
6. openEHR Deliverables
7. Activities
8. History of openEHR Sep 2001 Specification development starts
Feb 2003 Formal Change Request system
196 CRsinitial schemas, implementations
10 Feb 2006 Release 1.0
51 CRsheavy testing
Implementation in Java, C#, XML-schema
15 Apr 2007 Release 1.0.1
Stabilised; 4 Archetype parsers; 5+ implementations emerging, some commercial
ADL spec ? CEN EN13606-2 ? ISO
9. What is openEHR for?
10. Challenges in e-Health Today Semantic interoperability: �how do computers know what our data mean?
Patient-centric view: how to build a patient-centric longitudinal EHR across enterprises?
For decision support, Care pathways, Medical research
Continual change and complexity:�how to build systems that keep up with reality?
11. Semantic Interoperability An e-health environment needs to establish common meaning of data everywhere
Its no use knowing what the meaning is in one place; it must be known from data capture to all uses, and all the plumbing in between
We need end-to-end semantic coherence
Meaning = structure + context + semantics
13. and the distributed environment Shared EHR = openEHR
Semantic interoperability
Federated viewing is not a shared EHR
Data transformation
Data integration (linking)
Versions, update, accountability (tracability)
Heterogeneous login/security models
Heterogeneous query models
PerformanceShared EHR = openEHR
Semantic interoperability
Federated viewing is not a shared EHR
Data transformation
Data integration (linking)
Versions, update, accountability (tracability)
Heterogeneous login/security models
Heterogeneous query models
Performance
14. at various levels Shared EHR = openEHR
Semantic interoperability
Federated viewing is not a shared EHR
Data transformation
Data integration (linking)
Versions, update, accountability (tracability)
Heterogeneous login/security models
Heterogeneous query models
PerformanceShared EHR = openEHR
Semantic interoperability
Federated viewing is not a shared EHR
Data transformation
Data integration (linking)
Versions, update, accountability (tracability)
Heterogeneous login/security models
Heterogeneous query models
Performance
15. as well as across functions.
16. Patient-centric View what happens
17. Patient-centric View what we need
18. Change and Complexity Snomed-ct has 500,000 concepts & 1,000,000 relationships.and is under continual heavy revision
ICD10 has 75,000 conditions and ICD11 is on the way
There are no standards for questions on most hospital forms
There are 500 common lab tests, many changing, new ones emerging
Hospital business processes changing
19. Information complexity: timing If you think about the seemingly simple concept of communicating the timing of a medication, it readily becomes apparent that it is more complex than most expectIf you think about the seemingly simple concept of communicating the timing of a medication, it readily becomes apparent that it is more complex than most expect
20. Information complexity: timing
21. Information complexity: timing
22. Information complexity: timing
23. Information complexity: timing and therefore it has not been easy to express and share this information accurately and reproducibly. However Archetypes are designed to do this.
and therefore it has not been easy to express and share this information accurately and reproducibly. However Archetypes are designed to do this.
24. openEHR Health Computing Platform
25. openEHR Health Information Platform
26. Key Innovations Two-level Modelling separation of models of information into 2 layers:
Hard-coded information model (domain-invariant)
Archetypes (domain-specific)
Software is only built from the first layer
Scientific process model of basic information
Distributed Semantics
27. The Reference Model
28. Reference Model
29. Structure of one EHR
30. Structure of one Composition
31. Analytical Paradigm for clinical recording
32. Entry types based on process There are three categories of archetypes each corresponding to classes in the reference model - that are useful to understand when starting out.
Thematic archetypes of Compositions which correspond to commonly used clinical documents, such as antenatal visit or care plan.
Organisational archetypes of Sections these are effectively used to assist with human navigation within EHRs and correspond to document headings, for example antenatal examination or summary.
Descriptive archetypes of Entries these are the most common and are fundamental building blocks of EHRs. There are four types of Entry archetypes:
Observations recording measurable or observable data e.g. blood pressure, symptoms or weight;
Evaluations recording clinically interpreted findings e.g. adverse event or assessment of risk;
Instructions recording the initiation of a workflow process, such as a medication order or referral;
Actions recording clinical activities e.g. procedure or medication administration. Actions complement the instruction and can record the ensuing state of the instruction, such as completed or cancelled.There are three categories of archetypes each corresponding to classes in the reference model - that are useful to understand when starting out.
Thematic archetypes of Compositions which correspond to commonly used clinical documents, such as antenatal visit or care plan.
Organisational archetypes of Sections these are effectively used to assist with human navigation within EHRs and correspond to document headings, for example antenatal examination or summary.
Descriptive archetypes of Entries these are the most common and are fundamental building blocks of EHRs. There are four types of Entry archetypes:
Observations recording measurable or observable data e.g. blood pressure, symptoms or weight;
Evaluations recording clinically interpreted findings e.g. adverse event or assessment of risk;
Instructions recording the initiation of a workflow process, such as a medication order or referral;
Actions recording clinical activities e.g. procedure or medication administration. Actions complement the instruction and can record the ensuing state of the instruction, such as completed or cancelled.
33. Ontology of Entry data
34. Core clinical Entry semantics
35. Standard state machine
36. Security Features
37. Distributed versioning
38. Archetypes
39. Principle The components of the Reference Model are like LEGO brick specifications
Archetypes = instructions/designs constraining the use of LEGO pieces to create meaningful structures
40. Language (ADL)
46. Queries
47. Queries from Archetypes
48. EHR Query Language (EQL) SELECT
o/data[at0001]/events[at0002]/time, o/data[at0001]/events[at0002]/data[at0003]/items[at0013.1]/value
FROM
Ehr[uid=@EhrUid] CONTAINS Composition c[openEHR-EHR-COMPOSITION.encounter.v1] CONTAINS Observation o[openEHR-EHR-OBSERVATION.laboratory-lipids.v1]
49. Archetype-based Queries We can now write portable queries in terms of semantic elements rather than only in terms of underlying information model
Queries can be built by domain users, not IT people
50. Templates
51. Archetypes and Templates
53. Archetypes are semantic �single-source models
54. The openEHR EHR
55. A Universal EHR
56. Conclusions Methodology of 2-level modelling works; 3 years experience; now in use in NHS
Archetypes and templates provide control over data entry, persistence, querying and terminology binding
For the first time, clinical professionals can substantially define the semantics of their own information systems: archetypes, templates and queries
57. Questions
