The professional and organizational future of imaging

Radiology is a referral specialty. With few exceptions, the radiologist depends on other physicians for requests for imaging examinations. This historical mode of practice is under threat. As described before, there are potent incentives for nonradiologists to take on imaging technologies and “self-refer” for imaging procedures rather than sending their patients to a radiologist [8, 19].

There is evidence that self-referral of imaging services is often economically motivated, leads to overuse of services, and creates unjustified health care expenses that are borne by health care payers and, ultimately, by patients [1, 8]. It is also suggested that “the accuracy of imaging procedures is compromised because many self-referring physicians do not have the imaging training or expertise either to provide procedural and interpretive services at the same level of quality as do radiologists or to detect abnormalities other than those specific to their specialty. This reduction in accuracy puts patients at risk, increases the cost of health care, and erodes the public's confidence in the quality and safety of imaging services” [1].

Self-referral politics represents the cornerstone of turf wars, since radiologists, having no beds and no consultations, are unable to self-refer patients [2]. In 1990 B.J. Hillman et al., using a large private-insurance database, evaluated a series of 65,517 episodes of patients treated by 6,419 physicians for acute upper respiratory symptoms, pregnancy, low-back pain, or prostatism, and analyzed the corresponding imaging modalities, which included chest X-ray, obstetrical ultrasound, lumbar spine radiographs, intravenous pyelograms, cystography, and ultrasound [20]. This paper strikingly demonstrated that physicians practicing self-referral requested 4 to 4.5 times more imaging examinations than physicians referring patients to radiologists [2, 20]. The same study showed that resulting charges per patient were 4.4 to 7.5 times higher for self-referring physicians [20]. In aggregate, these data raised the specter of overutilization related to the incentive for inappropriate self referral [9].

Residents in radiology have much to learn because the specialty is defined both by imaging technologies and by procedures that are becoming more numerous and sophisticated. According to Hendee, “to master all of these technologies and procedures, as well as to become expert in one or more, requires 5 years of intense residency training and, for most radiologists, additional years in organ-oriented sub-specialty fellowships” [1]. This amount of training, however, provides only a foundation to practice the radiologic specialty; a continuous expansion and refinement of the knowledge of the radiologist is required over the duration of practice [1]. Hendee goes even further by stating that “the development of knowledge in the acquisition and interpretation of clinical images is a full-time effort” [1]. Knowledge in medical imaging is not something that can be acquired as a sideline to the practice of another medical specialty. Thus, it is understandable that the knowledge of radiologists is superior to that of other specialists who perform imaging and interpret images [1, 6].

A number of disorders may not be confined to one organ system, and there may also be circumstances in which the patient imaging examination identifies other abnormalities that were unsuspected and potentially life-threatening or unrelated to the symptoms being investigated. In these circumstances the radiologist—having a broad perspective and a wide knowledge of anatomy, pathology, and imaging signs—delivers an added value compared to a subspecialized clinician. It is important that there is good oversight to avoid the patient having unnecessary examinations and being referred to a variety of other physicians [6].

Medical imaging employs highly complex technologies that are increasingly driven by the sophisticated computer and image-processing systems that are used for the acquisition and display of imaging data for interpretation. Understanding the acquisition and display processes and having a working knowledge of the complex interactions among these processes helps to ensure that optimal images are acquired for the medical conditions being investigated and that the images depict pathologic conditions in the patient and not errors in the processes of acquiring, manipulating, and displaying imaging data [1]. Radiologists have been dedicated to maintaining and continuously improving imaging protocols [6].

In this endeavor radiologists have always closely cooperated with many other scientists, including clinical physicists, MR physicists, IT professionals, and image processing specialists. Many of the technological advancements as well as optimization would not have been possible without this decade-long cooperation. Indeed, some of these related professions are presently fully integrated within large radiological departments.

The workflow of an imaging service includes monitoring of the appropriateness of referral, quality assurance for professional and technical staff, report generation, archiving, and last but not least supervision and consultation by highly trained super-specialized radiologists (Fig. 1, adapted from [6]). For some parts of the process, information technology solutions may be beneficial and already available or under development [electronic order entry, automated decision support, computer aided detection (CAD)] [6].

In radiology, the safety of patients and health care personnel permeates most features of the imaging process. According to Hendee, “it includes using the lowest dose of ionizing radiation possible to either achieve the images necessary to arrive at a correct diagnosis or conduct an interventional procedure successfully. Each image should be obtained at the lowest dose consistent with sufficient image quality, a minimum number of images should be acquired consistent with the successful completion of an examination or procedure, and requests for unnecessary or inappropriate examinations should be refused. Every radiologic examination—even those that are performed with US and MR imaging, which do not employ ionizing radiation—expose patients to some element of risk. That risk comes from unwarranted exposure to radiation, as well as from false-positive results that lead to follow-up procedures and false-negative results that fail to demonstrate evidence of disease and injury. Knowledge about why, when, where, how, and for whom imaging should be employed is part of each radiologist’s training” [1].

Thus a quality radiology practice will consistently perform the right procedure at the right time for the right patient, the radiology report will be timely and accurate, and the patient will receive optimal personal care [4, 6, 21]. However, this ideal is not reality, and even 99.99% reliability in a large practice will result in a significant number of adverse events [4]. Accountability of radiology departments is granted by the provider-customer relationship between referring physician and radiologist. Optimization of quality and safety requires a proactive systematic study of workflow, identification of weaknesses that could lead to suboptimal performance, and risk assessment [4]. Certainly, many of the well-known problems in radiology, such as lost or unavailable images and reports, delayed communication of results, and lack of patient information, have all been reduced with implementation of hospital and radiology information systems, voice recognition dictation systems, and picture archiving and communication systems. The quality of care and service has increased, and operational costs have decreased [22].

Quality standards should also assist in determining the technical specifications of new equipment being purchased, based on the facility's clinical imaging requirements. Guidelines should cover the general requirements specified for equipment selection with a view (1) to upgrading or maintaining standards for diagnostic imaging quality, i.e., the system design, construction, and performance, (2) to the extent and cost of service contracts and qualifications and availability of service personnel, and (3) to the cost of the system, system components and ancillary equipment as well as the cost of delivery and installation [23].

Increasingly, customers of imaging services look for timeliness and access [6]. Success of an integrated, comprehensive practice of imaging is related to a “365 by 24” (all day, every day) service that is not only valued but also needed by most referring physicians. In order to provide this continuous service, radiology needs a sufficient flow of patients in all possible technologies and indications also during office hours, particularly for training purposes and preserving expertise for emergency situations [6].

The large variety of procedures and the high levels of expertise available in subspecialized services have to be available also and particularly for emergency situations. For such levels of coverage, a minimum number of trained staff has to be available. This infrastructure is greatly appreciated by nonradiologist physicians and by health service administrators. The costs, however, may be substantial and a potent incentive for consolidated radiology departments.

An integrated comprehensive imaging service does not exclude the possibility of decentralizing some of the facilities (equipment) within the hospital [6]. Medicine will begin to take advantage of anytime/anywhere image interpretation enabled by digital acquisition and transmission [24]. Patient-focused decentralized care provides that patients in a given department rarely need to leave their hospital floor, as most of their needs (including administrative and discharge procedures, nutrition, patient support, and laboratory and simple radiographic services) are available on the floor. This method relies on decentralization of services by using mobile X-ray or ultrasound equipment handled by trained professionals belonging to the central imaging facility. Similarly, for image-guided interventions that have to be performed in special locations (operating theaters), radiographers and radiologists would follow the needs of the patient [6].

However, decentralization in radiology is wasteful and inefficient. It can make radiology departments smaller and less stimulating and employees less committed. When specialized work tasks are decentralized and stability in the work force is low, the risk is that specialized work tasks will not be done well. In a central department, technologists usually cover for each other during temporary absences and consult over technical problems. In the decentralized scheme, the technologist is isolated and works without direct supervision [6].

Radiology is a high efficiency, high throughput service. The large volume of procedures as well as clustering of radiological equipment allows optimized use of the scarce trained paramedical and medical personnel. Moreover, more equipment in the same modality offers the possibility of successive investment, allowing for the use of state-of-the-art technology whenever necessary. These advantages are not available for small decentralized facilities [6].

Legislation in a free-market economic system does not tolerate attempts by entities to restrain or limit competition among providers of goods or services. Accordingly, a restraint or limitation on competition generally will be allowed only if it serves some important purpose. Over the years, health care organizations have recognized that a limitation on competition is acceptable if it protects a party from unfair competition. In this context, self-referral can be regarded as unfair internal competition with regard to services provided by a referral-based radiology department. Individual and interdepartmental economic competition and new technologies may renew competitive forces to obtain leadership positions and market share. These forces can become overwhelming and may stimulate detrimental competition for patients, space, and resources [6]. Moreover, internal competition among specialists interested in imaging may result in disagreements and may even begin to strain normally collegial relationships. On the other hand, a mutually beneficial arrangement among the specialties requires minimization of internal competition as well as adequate patient volume and economic resources for all participants. Competition must be therefore based externally on quality and cost, not internally among members of the group [25].

Radiology strives towards preservation of the integrity of the profession as a distinct clinical specialty. Large examination volumes and extended collaboration with clinical specialists within multidisciplinary groups allows for high quality subspecialized training of radiologists for different organ systems and diseases. System- or disease-based radiologists should take the lead in innovation, development, and validation of new imaging technologies. The aim of radiologists is to serve the needs of the referring physicians by delivering high-quality examinations and reports and particularly by providing highly specialized consulting services. For historical and practical reasons, some of the areas of diagnostic imaging and image-guided interventions are provided directly by clinical specialists including dedicated ultrasound procedures or cardiac catheterization. In other instances, X-ray fluoroscopy is made available for diagnostic and particularly image-guided intervention purposes under the management of the radiology department and assistance of paramedical personnel, however, without involvement of radiologists. Such limited decentralized services are based upon mutual agreement between different clinical departments and the department of radiology. Finally, in some specific areas such as noninvasive cardiac imaging and endovascular interventions, a far-reaching collaboration between radiologists and clinical specialists on an equal basis seems to be the best approach for delivering high-quality patient care. Nuclear physicians deliver additional diagnostic imaging services as a second distinct medical imaging specialty. Despite the emergence of hybrid imaging modalities (PET-CT, SPECT-CT, MR-PET), nuclear medicine remains for the time being a separate specialty. There are Europe-wide as well as national trends to re-merge radiology and nuclear medicine into one imaging specialty in the future; however, the discussion of this issue is outside the scope of this paper.

From a management and organization point of view, a unified and centralized structure including all image-producing and related specialties into one single enterprise-wide “imaging facility” seems beneficial (Fig. 2, modified from [6]). Such an approach would guarantee comparable workflow with standardized referral procedures, acquisition protocols, data storage, image post-processing, image interpretation, and consulting services. Such a centralized organization would also guarantee high quality equipment operation by trained paramedic personnel, quality assurance and maintenance by clinical physicists and medical technicians.