Applied Radiology

Dr. Wendler is a Senior Scientist in Philips Research Laboratories, Hamburg, Germany.

W e live in a world of rapid change. In the healthcare system--and in radiology as an integral part of it--we are facing a challenging situation of shrinking budgets, increasing cost pressure, and growing demands to increase the efficiency and quality of services. Reacting to these challenges, healthcare enterprises increasingly rely on Information Technology (IT) solutions. In digital radiology, IT environments integrate various application systems: hospital information systems (HIS), radiology information systems (RIS), picture archiving and communication systems (PACS), and imaging modalities. These systems provide integration on the information level, and are based on working standards that support data exchange (DICOM [Digital Imaging and Communication in Medicine] and HL-7 [Health Level 7]). Access to information is an important aspect for radiology, but not the only one. The transition from film-based to digital imaging systems is more than a change of technology for storage, distribution, and display of data. Simultaneously, we see that the processes in radiology and the organization of work change as well. Even more, under new socioeconomic boundary conditions, healthcare institutions are forced to optimize or completely redesign departmental processes to meet their essential medical and commercial targets. Increasingly, business process re-engineering (BPR) and process automation (Workflow Management) are seen as key factors for the successful operation of digital imaging departments and hospitals. This is in line with observations from other industries (e.g., banking or insurance), which are related to medicine in the sense that professionalism and success are based on a strict approach to customer orientation and cost effectiveness.

Managing processes: Where are we now?

Current IT solutions for radiology are rarely designed to explicitly and dynamically support changing processes and flexible organizations. Reports on efficiency improvement and cost reduction after IT installations do not sound overly enthusiastic. Usually, workflow aspects are dealt with in time-consuming and expensive projects, rather than in products that would support this important aspect of system integration. We lack effective concepts to deal with business processes on the departmental level. Functionally, workflow aspects are spread over the entire information system environment, with clear drawbacks, such as: 1) preventing an overall and integrated view of processes and organizations;
2) creating overlap of the existing workflow functionality implemented in the various subsystems, especially in multi-vendor environments; and 3) preventing an adaptation to the specific and changing needs of the institution (process re-engineering and optimization).

What we have achieved so far is integration on the data level, and the standards that support data exchange have improved significantly over the past few years. DICOM, however, the essential "data-driven" standard for radiology, offers very little support for workflow. We have seen attempts to extend DICOM in the workflow direction; however, these extensions do not appear general enough to meet requirements of future workflow-driven systems.

What kind of systems do we envision?

There are demands to move forward and take the next logical step from pure data management to an environment with integrated data and workflow services. What we want are information systems that are explicitly designed to: 1) contribute to efficiency, cost-effectiveness, and a high standard of medical
services; 2) flexibly support the key processes and organization in changing medical institutions; and 3) support the radical re-engineering, permanent optimization, and automation of processes to meet economic and medical needs.

Workflow Management Services with model-based enactment of workflow have to be integral parts of medical IT solutions. Workflow architectures and standards are needed to support this.

What is workflow?

Unfortunately, the term workflow is frequently misused to describe certain aspects of data flow. We suggest using the standard workflow vocabulary as defined by the Workflow Management Coalition, ^1,2 the most important standardization body in this area: workflow is the automation of a business process, in whole or part, during which documents, information, or tasks are passed from one participant to another for action, according to a set of procedural rules.

Workflow deals with processes, and the flow of data is just one aspect of it. Other aspects include: Modelling the sequence of activities and subactivities (process models); modelling all aspects of human resources (organizational models); management of operational units (equipment, devices, tools), locations (rooms, workplaces), and materials (consumables); organization and tracking of patient flow; and the adherence to all kind of medical, political, economic, legal, and time constraints.

Figure 1 depicts an extremely simplified typical workflow-centric view of radiology that emphasizes the process aspect. ³ The left and right sides of the diagram show application system components implemented as functional modules of RIS, PACS, and imaging modalities. As shown, these components are needed in well-defined activities of the diagnostic process. In the middle the process itself is illustrated, represented by explicit process models that are enacted at run time using a workflow management system (WfMS). In figure 1, the conceptual independence of an autonomous workflow management service and the application systems becomes obvious.

At run time of an IT environment, previously defined process models are selected, initiated, and enacted. In radiology, a typical trigger event to start a particular process is the registration of a request for a specific kind of radiological study. After process start, the sequence of events follows the process model accordingly. The activities that represent each step are either fully automated (e.g., pre-fetching images, which is performed by a PACS component) or done manually by workflow participants. In the latter case, work items are passed to workflow participants in terms of worklists, which are presented to users in the appropriate look-and-feel of their dedicated application system. Typical examples are worklists like "Cases to be reported" in a softcopy diagnosis PACS workstation, or "Scheduled patients to be registered" in a RIS.

A workflow service can be built using workflow management technology and commercial off-the-shelf WfMS. In general, these systems allow users to define, create, and manage the execution of workflow through the use of software, running on one or more workflow engines, which are able to interpret process definitions, interact with workflow participants, and, where required, invoke the use of IT tools and applications. Some basic terminology issues for WfMS are presented in figure 2.

In particular, workflow management systems provide: 1) build-time tools to model processes in terms of activities and state-transitions, and model the organization in terms of organizational units and workflow participants; and 2) run-time tools (workflow engines) to match workflow participants and activities, put processes into action, and provide worklists according to the state of processes.

Until now, workflow management systems have proven their usefulness outside the healthcare domain. There are more than 100 commercially available WfMS on the market, with very different implementation strategies and modelling paradigms. Application-independent and process-oriented systems look promising as candidates for use in radiology.

Workflow-enabled application systems

Following the workflow approach, future application systems need to fit into workflow architectures. These "workflow-enabled"applications need--in addition to data-oriented (DICOM) interfaces--connections to the department's or the hospital's workflow enactment service. A set of standard interfaces has been defined by the Workflow Management Coalition. ² These interfaces have to play an essential role in workflow architectures, although up to now they have only been implemented by a few WfMS manufacturers and still have to mature. The definition and consolidation of workflow architectures is certainly one of the next steps for the introduction of workflow management in radiology.

Conclusion

Fully digital radiology departments potentially work more efficiently, at a lower cost, and offer new options to improve the services. Introducing information technology as such, however, will not automatically improve processes. Current IT solutions in radiology are predominantly data-focused. For the challenges of the future we need process integration in addition to data integration. The design of information systems needs to support re-engineering and process automation. As a starting point, it will be essential to think "process-oriented" and understand healthcare processes, which requires a deep knowledge of current processes and an awareness of changes and future trends that will shape and automate future processes. Workflow management appears to be a promising approach to support processes in the healthcare domain, and a valuable contribution to increase efficiency and reduce costs. It appears attractive for the automation of the majority of structured, routine processes in radiology. For processes of ad-hoc nature (e.g., in emergency situations), it must be complemented by groupware concepts.

WfM can be implemented by Workflow Management Systems, which should be integrated as separate, autonomous system components. They should be independent of the capabilities and limitations of the attached application systems (RIS, PACS, and imaging modalities), and should provide scalability to the enterprise level (as radiology is a sub-process within a healthcare enterprise). Autonomous workflow services will facilitate the implementation of workflow management in multivendor environments, and will enable the use of commercial off-the-shelf Workflow Management Systems with powerful build-time and run-time tools. This concept calls for common architectures and standardized interfaces between the WfMS and the various "workflow-enabled" application systems. It is recommended to adopt and apply the existing standards defined by the Workflow Management Coalition, in addition to the data-oriented standards we already have. AR

References

1. Lawrence P: Workflow Handbook 1997, Chichester, England, John Wiley & Sons Ltd., 1997.

2. Workflow Management Coalition: http://www.aiim.oriz/wfmc/.

3. Wendler T, Meetz K, Schmidt J: Workflow management systems in radiology. Proc SPIE Med Imaging 1998 3339:216-225, 1998.