Fractionated total body irradiation (TBI) in conjunction with the use of chemotherapeutic agents has proven useful for cytoreduction and immunosuppression prior to bone marrow or peripheral blood stem cell transplantation for hematologic and other malignancies and for various genetic disorders. Unique features of TBI, rendering it a valuable component of transplant preparative regimens, in contrast to chemotherapy, include:
- No sparing of "sanctuary" sites (e.g., testes)
- Dose homogeneity regardless of blood supply
- No known cross-resistance with other agents
- No problems with excretion or detoxification
- Ability to tailor the dose distribution by shielding specific organs or by "boosting" sites
Single fraction low dose TBI has recently emerged as an effective form of immunosuppression (with or without chemotherapy) prior to allogeneic stem cell transplantation in nonmyeloablative approaches.
The purposes of TBI are primarily to immunosuppress (in allogeneic transplants) and to cytoreduce (eradicate malignant cells or, occasionally, cell populations with genetic disorders).
It is essential that the complicated treatment and care of the patient receiving a transplant regimen containing TBI is well coordinated among the various services (medical oncology, radiation oncology, etc.) and caregivers (physicians, nurses, physicists, psychologists, dieticians, etc). Unlike most other treatment delivered by a radiation oncologist, fractionated TBI delivers results in myeloablation that is potentially lethal without intensive medical support and stem cell backup. Incorrectly delivered TBI may result in fatal toxicity as well. Thus, great care must be taken by the entire TBI team to assure the best possible multidisciplinary treatment plan with attention to all facets of TBI.
Although the techniques vary widely from institution to institution, certain basic principles apply, such as the achievement of dose homogeneity throughout the body, with the exception of shielded or boosted areas. The planning and performance of TBI is a team effort that requires close interaction and coordination among the radiation oncologist, the medical physicist, dosimetrists, nurses, and radiation therapists.
This guideline describes a quality assurance program for TBI and is supplementary to the ACR Practice Guideline for Radiation Oncology (see National Guideline Clearinghouse summary) and the ACR Technical Standard for the Performance of Radiation Oncology Physics for External Beam Therapy.
Process of Total Body Irradiation
The use of TBI is a complex process involving many trained personnel who carry out highly coordinated activities.
- Clinical Evaluation
The initial evaluation should include a detailed history, including a review of issues that may impact upon treatment tolerance (previous radiotherapy to sensitive organs, factors affecting pulmonary, renal or hepatic function, and exposure to infectious agents); physical examination; review of all pertinent diagnostic and laboratory tests; and communication with the referring physician and other physicians involved in the patient's care in accordance with the ACR Practice Guideline for Communication: Radiation Oncology. Careful review of the applicable protocol for the particular disease being treated is essential since standardized institutional or cooperative group protocols are the norm for transplantation.
As with delivery of any chemotherapy or radiotherapy, policies and procedures should be in place to determine whether a female patient is pregnant before initiating any component of a transplant program, including TBI. If the patient is determined to be pregnant, alternative therapies in an effort to preserve the pregnancy versus termination of pregnancy and continuation with transplantation must be decided upon.
- Informed Consent
Prior to simulation and treatment, informed consent must be obtained and documented and must be in compliance with applicable laws, regulations, or policies. This should include a detailed discussion of the benefits and potential tissue-specific acute and late toxicities of TBI, as well as the details of, rationale for, and alternatives to TBI.
- Treatment Planning
Treatment planning for TBI requires detailed knowledge of the specific transplant program to be followed (either on or off of a clinical trial). Specific treatment parameters to be determined in advance of treatment include: field size, dose per fraction, dose rate, total dose, fractions per day, interval between fractions, if relevant, beam energy, geometry to achieve dose homogeneity, bolus or beam spoilers to increase skin dose, shielding and dose compensation requirements (e.g., lungs, kidneys), and boost specifications (e.g., testes). Patient thickness measurements should be obtained at the prescription point (often at the level of the umbilicus), and at other points of interest for possible dose calculations and homogeneity determinations such as head, neck, mid-mediastinum, mid-lung, pelvis, knee, ankle, etc. Patient height is recorded in order to determine the appropriate source-to-patient distance to appropriately fit the patient within the beam with sufficient margin around the patient (>5 cm, usually).
- Simulation of Treatment
For lung or other organ blocking, simulation or other treatment planning is generally done in the treatment position (i.e., if the patient is standing for TBI, the simulation should be done in the standing position if possible). If the planning session is performed in another position, positional differences in organ location should be taken into account, and the medical physicist should be consulted. Reference points for block placement at the time of treatment should be marked on the patient's body for reproducibility.
- Calculations
Calculations are performed by the medical physicist or his or her designee to determine beam-on time to achieve the prescribed dose, dose homogeneity in the locations specified by the protocol, and doses at any other points of concern. A medical physicist or a dosimetrist who did not perform the initial computation shall independently check the calculation before the first fraction is delivered. In vivo dosimetry may aid in assessment of dose homogeneity. Every effort should be made to maintain dose inhomogeneity to within +/-10%.
- Treatment Aids
Special TBI stands or tables are often used to aid in immobilization, placement of organ shields, and patient support and comfort.
- Treatment Delivery
TBI containing myeloablative transplant programs typically utilize fractionated or hyperfractionated regimens (twice a day or three times a day) over several days in order to minimize both acute and chronic toxicities and to minimize overall treatment time. Prior to treatment, any shielding of normal organs should be checked with portal images. In the setting of single fraction low-dose TBI, where total doses are typically only 200 cGy, organ shielding is not utilized. Dosimetry should be checked against department protocols to verify dose delivery at the extended distances that are usually used for treatment. A medical physicist should be available during all treatments in case of questions regarding dosimetric details, equipment function, patient setup, etc. Treatments are carried out by the radiation therapist per the ACR Practice Guideline for Radiation Oncology.
A physician should be in close proximity to manage any problems related to treatment. Avoidance of medications that may cause orthostatic hypotension (such as phenothiazines), and the administration of intravenous (IV) fluids for hydration or transfusions for anemia may help to prevent syncope or near-syncopal episodes when the patient is treated in the standing position.
Qualifications and Responsibilities of Personnel
Application of this guideline should be in accordance with the ACR Practice Guideline for Radiation Oncology.
- Radiation Oncologist
The radiation oncologist shall have had training in TBI procedures prior to embarking on any of these regimens.
The responsibilities of the radiation oncologist include:
- Consultation and decision-making regarding the course of treatment.
- Coordination of the patient's care with the transplantation service.
- Participation in the treatment planning process (immobilization techniques, simulation, block design, prescription, etc.).
- Review and verification of portal images.
- Clinical assessment of the patient's tolerance during the treatment course.
- Qualified Medical Physicist
The responsibilities of the Qualified Medical Physicist include:
- Establishment and management of a quality assurance program for TBI performance.
- Acting as a technical resource for planning of immobilization devices, dosimetry techniques, shielding, dose compensation devices, and bolusing methods.
- Calibration of the external beam delivery system.
- Direct supervision of dosimetry measurements and calculations for TBI delivery.
- Dosimetrist
The responsibilities of the dosimetrist include:
- Generation of the dose calculations for treatment.
- Dosimetry measurements.
- Radiation Therapist
The responsibilities of the radiation therapist include:
- Setting up the patient in the treatment position, including using appropriate treatment devices.
- Performance of imaging procedures to verify the setup and blocking, if any.
- Treatment of the patient according to the prescription and plan provided.
- Continuing monitoring and evaluation of the patient during the treatments.
- Verification that the prescribed and calculated treatment distances match the utilized treatment distances.
- Nurse
The responsibilities of the nurse may include:
- Monitoring the patient's tolerance of the procedure to promote adequate supportive care.
- Communicating any special precautions to the rest of the team regarding the care of immunosuppressed patients.
Equipment
High-energy photon beams are used for TBI, generally delivered by linear accelerators in the range of 4–18 MV or by a Co-60 unit. Additional equipment may include a fluoroscopy or computed tomography (CT) simulator, immobilization devices, equipment for the manufacture of shielding, computers for dose calculations, a beam spoiler, custom bolus, custom compensators, and dosimetry and calibration devices. A backup beam delivery system must be available in case of unanticipated machine failure.
Patient and Personnel Safety
- Safety measures should be in accordance with the ACR Practice Guideline for Radiation Oncology.
- Special Patient Protection Measures
- Charting systems for prescription; delineation of treatment parameters of the setup; including any position settings of the TBI stand; and treatment delivery record, including time of delivery for multiple treatments in a day.
- Physics program for calibration of the treatment machine, independent checking of dose calculations, and monitoring of dose delivery to the patient.
- Visual and audio contact with the patient during treatment.
Documentation
Reporting should be in accordance with the ACR Practice Guideline for Communication: Radiation Oncology.
Educational Program
Continuing medical education programs should include radiation oncologists, physicists, dosimetrists, nurses, and radiation therapists. The program should be in accordance with the ACR Practice Guideline for Continuing Medical Education (CME).
Quality Control and Improvement, Safety, Infection Control, and Patient Education Concerns
See the "Description of the Implementation Strategy" field, below.