Subspecialties: Clinical radiation therapy, radiation and cancer biology, radiation physics
Cancers treated: Many cancers, but particularly brain cancer, head and neck cancers, lung cancer, breast cancer, prostate cancer, skin cancers, rectum cancer, cervical cancer, and uterine cancer , as well as lymphomas and sarcomas
Training and certification: The structure of accredited radiation oncology programs and residencies varies. In North America, most radiation oncologists have completed a radiation oncology residency in a program approved by the Accreditation Council for Graduate Medical Education (ACGME), the American Board of Radiology (ABR), or the Royal College of Physicians and Surgeons of Canada.
Radiation oncologists must possess a broad and deep command of both cancer biology and imaging technology. They study the etiology of cancer; its evaluation, diagnosis, and treatment in a clinical setting; the ways radiation interacts with various cancers at all levels, from molecular to multicellular; the physics of radiotherapeutic technologies and associated machines such as linear accelerators and hyperthermia devices; techniques such as interstitial brachytherapy, intraoperative radiotherapy, and stereotactic radiosurgery; and a host of other disciplines associated with radiation therapy, such as nuclear medicine, oncology, diagnostic radiology, and surgical pathology.
During postdoctoral training, students may elect to focus on research, as in radiation biology; on the integration of advanced technologies and radiation physics with clinical research; or on clinical practice. Most residencies in clinical radiation oncology require at least three, more often four, years to complete, usually following a first postgraduate year (PGY-1) of surgical, medical, or flexible internship.
After receiving their primary certification, radiation oncologists usually must renew certification every several years, depending on their subspecialties. The American Board of Radiology, for example, requires its diplomates to satisfy its “maintenance of certification” (MOC) program to maintain their primary certification.
Services and procedures performed: All radiation oncologists participate in the evaluation, staging, treatment, and therapy of their patients. They are the overseers of the cancer patient’s radiation oncology team, ensuring the precision and accuracy of radiation treatment, and they work with physicians treating the patient’s cancer in other ways. Throughout the course of radiation therapy, radiation oncologists are responsible for monitoring the patient’s progress, side effects, and treatment to meet two goals: that the cancer is effectively halted or reduced in size, and that the patient’s comfort is at the same time adequately addressed. The balance of these objectives is essential to achieving the best outcome.
Radiation oncologists head a team of medical professionals who together design and deliver the patient’s radiation treatments. In concert with the patient’s primary oncologist, the radiation oncologist learns about the specifics of the patient’s cancer to determine the role radiation therapy will play in its treatment, then meets with the patient to evaluate his or her probable response to radiation therapy. Along with a radiation physicist and a dosimetrist, the radiation oncologist will then design the treatment plan, which involves simulations, immobilization devices, calculating radiation dosages, and conducting periodic checks to confirm accurate delivery of treatment.
The types of procedures radiation oncologists design and perform with the radiology team fall into two major categories. In the various forms of external beam radiation, the most common type of radiotherapy, the radiation oncologist uses a machine similar to an X-ray machine to direct high-energy X and gamma rays to the specific area of the body where the tumor resides. Treatments are given on a daily basis, usually for one to eight weeks and sometimes more than once a day, depending on the tumor and its aggressiveness.
Brachytherapy, also known as internal, implant, interstitial, or intracavitary radiation therapy, is the other main form of radiotherapy. The radiation oncologist implants, in the form of capsules called needles or seeds, a small amount of a radioactive substance in the body near the tumor while the patient is under general anesthesia. Among the radioactive materials used are cesium, iridium, iodine, phosphorus, and palladium.
Other procedures include electron therapy, including total skin treatment; radioimmunotherapy, in which monoclonal antibodies are enlisted to deliver the radiation by binding to the tumor cells; proton beam therapy, which uses protons to deliver higher doses of radiation to tumors than can be accomplished using conventional X and gamma radiation; neutron therapy, which can work in oxygen-free environments, such as the depths of a large tumor, to deliver radiation to cancers that cannot be treated by other forms of radiation; and stereotactic radiosurgery, such as the Gamma Knife, used to treat head and neck cancers by delivering a very high dose of radiation targeted directly at a tumor and sparing surrounding, healthy tissue.
Finally, radiation oncologists offer palliative treatment for those whose outcome is not expected to be survival but whose pain can be ameliorated by halting the growth of a tumor or shrinking its size.
Related specialties and subspecialties: Many radiotherapy subspecialists work with the radiation oncologist. While radiation oncologists oversee care and integrate it with that of surgeons, chemotherapy oncologists, and other physicians, the day-to-day application of radiotherapy to the patient’s tumor is often carried out by others on the radiology team.
First, radiation physicists, certified by the American Board of Radiology or the American Board of Medical Physics, work directly with the radiation oncologist, oversee dosimetrists, develop quality-control programs for procedures, and perform safety tests on equipment. Their education usually consists of four years of college, two to four years of graduate school, and one or two years of clinical physics training.
Radiation therapists, under the supervision of radiation oncologists, administer the daily treatments, keep records, and check the performance of machines. They typically have two to four years of college education and have been certified by the American Registry of Radiologic Technologists. Many states also require licensing for radiation therapists.
Dosimetrists calculate dosages and durations of radiation with the goal of doing the greatest damage to the tumor while limiting damage to normal tissue. Because of the complexity of determining treatment dosages, dosimetrists often start as radiation therapists and, with additional training, advance to dosimetry. There are also intensive dosimetry programs lasting one to two years. Dosimetrists are certified by the Medical Dosimetrist Certification Board.
Radiation oncology nurses are charged with caring for radiation patients from before the beginning of treatment through its completion. They are also the patient’s first line of communication regarding what to expect during the procedure and how to identify and evaluate side effects. All radiation oncology nurses are registered nurses, and most are also accredited in the specialty of oncology nursing, which requires the completion of a master’s degree program.
Cukier, Daniel. Coping with Chemotherapy and Radiation Therapy. 4th ed. New York: McGraw, 2004. Print.
Delfino, Michelangelo, and Mary E. Day. Cancer: We Live and Die by Radiation. Mountain View: MoBeta, 2006. Print.
Halperin, Edward C., et al. Perez and Brady's Principles and Practice of Radiation Oncology. 6th ed. Lippincott, 2013. Print.
Hoppe, Richard T., Theodore L. Phillips, and Mack Roach, III. Leibel and Phillips Textbook of Radiation Oncology. 3rd ed. Philadelphia: Saunders, 2010. Print.
Hristov, Boris, Steven H. Lin, and John P. Christodouleas. Radiation Oncology: A Question-Based Review. 2nd ed. Philadelphia: Wolters, 2015. Print.
Parker, Robert G., N. A. Janjan, and M. T. Selch. Radiation Oncology for Cure and Palliation. New York: Springer, 2003. Print.
Schlegel, W., T. Bortfeld, and A. -L. Grosu, eds. New Technologies in Radiation Oncology. New York: Springer, 2006. Print.
Small, William, Jr., Tim R. Williams, and Eric D. Donnelly. Radiation Oncology: Difficult Cases and Practical Management. New York: Demos, 2013. Print.
American Board of Radiology
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http://www.theabr.org, 5441 East Williams Circle, Tucson, AZ 85711.
American College of Radiology
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http://www.acr.org, 1891 Preston White Drive, Reston, VA 20191.
American Society for Therapeutic Radiology and Oncology
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http://www.astro.org, 8280 Willow Oaks Corporate Drive, Suite 500, Fairfax, VA 22031.
International Radiosurgery Support Association
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http://www.irsa.org, P. O. Box 5186, Harrisburg, PA 17110.
National Association for Proton Therapy
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http://www.proton-therapy.org, 1301 Highland Drive, Silver Spring, MD 20910.
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