The openEHR Developers' workshop

Shinji Kobayashi^a, Pablo Pazos^b, Koray Atalag (Deactivated)^c, Sebastian Garde^d, Ian McNicoll^e, Erik Sundvall ^f,g

^_aThe EHR Research Unit, Kyoto University, Japan, ^bCaboLabs, ^cUniversity of Auckland, ^dOcean Informatics, ^eHandiHealth, ^fLinköping University, ^gRegion Östergötland

Abstract and Objective

The openEHR project is well-known as a set of specifications to build future-proof and semantically interoperable electronic health record systems and is related to the family of ISO 13606 standards. This workshop will discuss implementations of the openEHR specifications with the following contents.

Learning objectives

• What archetypes are and how to operate standardized clinical models to assure semantic interoperability between EHR systems and why healthcare needs a mix of people, process and technology change and the role of the openEHR project.
• The openEHR implementation technologies with various development communities.
• State of the Art of the openEHR specifications
• Current software engineering technologies around the openEHR implementations

Expected outcomes

• Further understanding of the openEHR specification and its implementation technologies
• Evaluation the conformance to the specifications and more features of each technology.
• Sharing experience and passion with speakers and participants.

Keywords:

openEHR, archetype, open-source software, clinical standard

Workshop description

1.       Overview of the openEHR project

The openEHR project(1)  is well known as a development source for the ISO 13606 standards(2). These standards are considered the technology basis of clinical information models which enable the interoperability for electronic healthcare applications. A number of projects have been implementing the openEHR specifications with various approaches. Development projects related to the openEHR are spreading worldwide. The core reference implementation has been implemented using Eiffel and is recognized as a reference implementation of the openEHR specifications. Java and C# are also being used in a number of reference implementations. These core implementations are provided as open-source software. This momentum provided an evidence that the openEHR specification are being widely accepted and gaining worldwide interest. On this steady international growth, we are taking this opportunity to introduce these specifications to a wider audience and explain their features. Even though these projects are still ongoing and have not yet completed their missions, developers, whether they are involved in openEHR or not, will benefit from the sharing of experiences and  discussions about the implementation of the openEHR specifications.

2 The workshop structure and arguments

This workshop will be consisted with the following contents. At first, we introduce openEHR architectural overview and the second, each speaker make presentation of each project.

2.1 The openEHR architecture overview

The core technology of openEHR specification features a two-level modeling system, named as ‘archetype-based systems’. With regards to this archetype-based technology, technological implementation is clearly isolated from clinical concern and assures future-proof semantic interoperability. In this workshop, we will overview this archetype-based technology.

• What archetype is.
• Why archetypes assures semantic interoperability in future.
• How to implement archetype-based systems.
• Upcoming ADL(ARchetype Definition Language) 2.0 and AOM(Archetype Object Model) 2.0.

2.2 Overview of each implementation project

Clinical Knowledge Manager (Sebastian Garde)

To be able to exchange clinical information in a semantically safe way across different openEHR-based systems, it is important to agree on the clinical concepts. Ideally, such concepts (formally expressed in openEHR archetypes) are developed in collaboration - regionally, nationally and internationally. To enable this, the Clinical Knowledge Manager (CKM) has been developed as a web-based system for collaborative development, management, review and publishing of openEHR archetypes and other clinical knowledge resources. CKM is used internationally by the openEHR foundation as well as in several national programmes. CKM supports the 'federation' of archetypes, so that the various programmes can work independently and to their own timelines, while sharing arhcetypes with each other where possible.

New archetype and template tools (Erik Sundvall)

An introduction to the new archetype and template tool project intended supporting new features in the archetyping formalism ADL/AOM 2.0 (previously called ADL 1.5). The  open source project targets fundamental parts of a modular editing framework that can be extended for different user needs and different reference models (e.g. CIMI, ISO13606 and openEHR)

HANDI-HOPD - building apps on an openEHR platform (Ian McNicoll)

HANDI-HOPD is a demonstrator based on SMART, FHIR and openEHR APIs, designed to allow training and experimentation in an open-standards/vendor-neutral environment. It exposes a set of simple Restful APIs which are easy to consume in modern languages/ frameworks. HANDI-HOPD is being used as the basis of the NHS England Code4Health project which aims to give clinicians the skills and knowledge to allow them to participate more directly in design of their systems. 

Development of an openEHR-based Open Source EHR Platform and openEHR EMR frameworks

Since 2009 we have developed several Clinical Information System projects based on openEHR. We started focusing on R&D, and now reusing that experience (and code) to build a service oriented (REST and SOAP), open source, and general purpose EHR platform to help developers to create shared EHRs that will be standard-compliant from scratch. That platform will support many EMR applications and devices. We are also creating tools to help on the application development itself, providing frameworks, libraries and tools.

Working with openEHR Semantically (Koray Atalag)

We have used openEHR to model and persist experimental data that underpins computational physiology models (e.g. VPH, Human Physiome). The idea is then to link both experimental and real-world clinical information to these quantitative and predictive models to create a new breed of decision support tools that can deliver highly personalised and precision medicine. We have had some key important learnings while representing such models and especially when semantically annotating them - which in openEHR world corresponds to term and constraint bindings and data instance level term mappings. We will explain our methodology and discuss lessons learned which we hope will facilitate the use of openEHR in Semantic Web environments.

2.3 Workshop speakers

• Shinji Kobayashi, MD, PhD - Kyoto University, Japan
• Pablo Pazos, Ingeniero en Computación, openEHR en español, CaboLabs, ACHISA
• Koray Atalag (Deactivated), MD, PhD, FACHI - University of Auckland, New Zealand
• Sebastian Garde, Dr. sc. hum., Dipl.-Inform. Med., FACHI - Ocean Informatics
• Ian McNicoll MBChB,MSc, HandiHealth CIC, UK
• Erik Sundvall, MSc, PhD - Linköping University and Region Östergötland, Sweden

3 Specific Educational Goals

The educational goal of this workshop is not only to learn openEHR technology, but implementation technology of standardized clinical models for semantic interoperability.

4 Expected Attendees

Expected attendees of this workshop are mainly developers who are interested in openEHR archetype technology, implementation of clinical models or open-source software projects in medical domain. The knowledge of the openEHR specification/technology is helpful to understand, but not required.

Because the workshop will present the state-of-the-art of implementation technologies in health care, attendees can learn the cutting edge of EHR system and software technology.

Resources