Core curriculum for medical physicists in radiology. Recommendations from an EFOMP/ESR working group.

Some years ago it was decided that a European curriculum should be developed for medical physicists professionally engaged in the support of clinical diagnostic imaging departments. With this in mind, EFOMP (European Federation of Organisations for Medical Physics) in association with ESR (European Society of Radiology) nominated an expert working group. This curriculum is now to hand. The curriculum is intended to promote best patient care in radiology departments through the harmonization of education and training of medical physicists to a high standard in diagnostic radiology. It is recommended that a medical physicist working in a radiology department should have an advanced level of professional expertise in X-ray imaging, and additionally, depending on local availability, should acquire knowledge and competencies in overseeing ultrasound imaging, nuclear medicine, and MRI technology. By demonstrating training to a standardized curriculum, medical physicists throughout Europe will enhance their mobility, while maintaining local high standards of medical physics expertise. This document also provides the basis for improved implementation of articles in the European medical exposure directives related to the medical physics expert. The curriculum is divided into three main sections: The first deals with general competencies in the principles of medical physics. The second section describes specific knowledge and skills required for a medical physicist (medical physics expert) to operate clinically in a department of diagnostic radiology. The final section outlines research skills that are also considered to be necessary and appropriate competencies in a career as medical physicist.

Introduction

The medical physicist in radiology is essential for enabling the practice of safe, state-of-the-art medical imaging. Medical physicists in radiology are members of the multi-disciplinary clinical teams that are responsible for radiology services to patients. Their role is to provide critical scientific input on the physical processes and technology that underpin the whole radiology service. Generally, the medical physicists in radiology design and develop the framework of medical imaging, image processing, image distribution, image storage, radiation dosimetry, quality assurance of the imaging equipment, information and communication technology (ICT) aspects of the imaging process, and radiation protection of the patient and operator. Specifically, the medical physicists in radiology provide expert advice on the development, implementation, and improvement of imaging techniques and processes. They also provide expert input for applications of medical imaging outside the radiology department. Medical physicists in radiology have a leading role in the strategic planning, testing, safe use, and optimization of advances in medical imaging technologies and techniques.

Both initial and continuing education and training are necessary in order to acquire and maintain sufficient knowledge and an appropriate level of knowledge and competence. The objective of our work was to develop a core curriculum for the education and training of European medical physicists in radiology. This core curriculum for medical physicists in radiology is issued jointly by the European Federation of Organisations for Medical Physics (EFOMP) and the European Society of Radiology (ESR). It provides guidelines for the education and training of medical physicists in medical imaging. These recommendations accommodate the contemporary requirements for the knowledge and competency needs in this rapidly evolving field of medicine.

Materials and methods

In 2004, a European expert group published the first European core curriculum for medical physicists in radiotherapy [1], and they recently finalized a revised and updated version of this curriculum [2]. The curriculum for medical physics in radiotherapy was developed and revised jointly by EFOMP and the European Society for Radiotherapy and Oncology (ESTRO). Another expert group for the development of a European core curriculum for medical physicists in radiology was initiated and installed by the EFOMP with participation of ESR. The radiology medical physics group represents experts in general projection radiography, mammography, diagnostic fluoroscopy, interventional radiology, computed tomography, magnetic resonance imaging, ultrasound imaging, and radiation protection.

The basis for a draft curriculum on radiology medical physics was laid during meetings of the expert group, and in a later phase written feedback from the experts was used to finalize the curriculum. It was decided to develop a curriculum that was consistent in structure and format with the revised radiotherapy medical physics curriculum.

It was also decided that the curriculum should define general competencies; specific knowledge, skills, and competencies in medical physics; and a research project.

Results

A curriculum for the education and training of medical physicists in radiology was established [3]. The medical physicist in radiology must be able to work together with the multi-disciplinary team in the clinical application of medical imaging and participate in the organizing and structuring of the medical imaging process. The physicist should also ensure that the well-being, interests, and dignity of patients are promoted and safeguarded at all times.

To support these requirements, the first part of the curriculum presents general competencies, subdivided into two sections: organization and professionalism. The second part defines specific knowledge, skills, and competencies in medical physics required to operate clinically in a department of radiology. This part is subdivided into the sections fundamental knowledge and applied knowledge. A medical physicist requires clinical and analytical skills and is also expected to remain abreast of developments in medical imaging. Both aspects of the job can be trained through the development of research skills. These need not necessarily be acquired through abstract academic research but can equally likely be developed through applied clinical problems. Thus, the third and final part of the curriculum describes a research project where these skills are developed. Table 1 gives an overview of the structure of the curriculum.

Table 1

The structure of the core curriculum for medical physicists in radiology

I. INTRODUCTION

II. GENERAL COMPETENCIES

Organization

Professionalism

III. RADIOLOGY PHYSICS KNOWLEDGE, SKILLS, AND COMPETENCIES

Fundamental knowledge

1. Fundamentals of human anatomy, physiology, and pathology

2. Fundamentals of clinical care

3. Principles of radiobiology

4. Overview of radiation physics

5. Fundamentals of medical imaging

6. Statistical methods

7. Principles of quality management in health care

8. General principles of risk management and safety in health care

9. Evidence-based medicine

10. Information and communication technology

Applied knowledge

11. Dosimetry

12. Medical X-ray imaging

12.1. General principles of X-ray imaging and X-ray equipment

12.2. General projection radiography

12.3. Mammography

12.4. Fluoroscopy

12.5. Computed tomography

13 Magnetic resonance imaging

14 Ultrasound imaging

15 Radiation protection

16 Diagnostic image display and image processing

IV. RESEARCH PROJECT

Discussion

The European core curriculum for medical physicists in radiology can be used when national curricula are being developed. The core curriculum supports the harmonization of education and training of European medical physicists in radiology, it may help to improve their mobility within Europe, and it provides the basis for improved implementation of articles in European medical exposures directives that are related to the medical physics expert. The core curriculum aims at bringing the medical physicist in radiology up to the level of a qualified medical physicist. A qualified medical physicist is an individual who is competent to practice independently and to register as a medical physicist, in one or more of the subfields of medical physics. To act as an expert, further experience is required, and an involvement in a program for continuing professional development is highly recommended.

Radiology involves many subspecialties including radiography, mammography, computed tomography, X-ray guided interventions, and pediatric radiology but also magnetic resonance imaging (MRI) and ultrasound imaging. The medical physicist in radiology who is recognized as a medical physics expert must have a high level of expertise in X-ray imaging. In addition, but depending on local conditions, it may also be desirable or even required that the medical physicist in radiology acquires a certain level of expertise in MRI, ultrasound imaging, and nuclear medicine. Consequently, a trainee is not expected to cover all elements of this curriculum. The curriculum can be downloaded from: www.efomp.org and www.myesr.org.