Among others, one particular advantage of whole-body magnetic resonance imaging (wbMRI) is the absence of ionizing radiation, a factor that is especially relevant in pediatric imaging, due to the increased sensitivity of children to ionizing radiation. Another important advantage is the high accuracy of the method in the investigation of bone marrow and solid organs, besides the better contrast resolution for soft tissues as compared with other techniques. There is a particular interest in the role played by this method in the field of pediatric oncology (for example, in cases of lymphoma, neuroblastoma, sarcoma and Langerhans' cell disease). Main disadvantages of wbMRI include the relatively long images acquisition time and motion artifacts (requiring patient's cooperation or general anesthesia). However, the developments in computational and imaging techniques, including additional sequences (fat saturation, diffusion-weighted imaging and use of gadolinium enhancement) have reduced the impact of some of these challenges.
An accurate staging and a careful follow-up are essential for patients with neoplastic disease, to evaluate the prognosis and make a decision about the most appropriate therapeutic approach to be adopted. Imaging methods play a fundamental role in such evaluation steps. Computed tomography (CT) and, recently, positron emission tomography (PET/CT) has been widely utilized as an integrated diagnostic approach in cases of systemic cancer( 1 , 2 ). In particular, up to the present moment, the use of the radiopharmaceutical 18-fluorodeoxyglucose (FDG) has given a relevant contribution in the Field of oncological imaging and has widely been indicated. However, such technique utilizes high ionizing radiation doses and presents some limitations regarding spatial and contrast resolution, besides false negative and false positive results in the evaluation of the skull and upper abdomen, already described in the literature( 3 ). For these reasons, MRI, that is free from ionizing radiation, and presenting high contrast and spatial resolution for soft tissues, is an useful application for detecting and staging malignant tumors and can overcome the limitations of FDG-PET/CT( 4 ). In a recent meta-analysis, wbMRI showed to be as effective as PET/CT in oncology( 5 ). This same study suggests that larger prospective studies and, particularly, a cost-effectiveness analysis comparing the methods are necessary to determine which should be the standard investigation method( 5 ). Even in the assessment of the chest, where only recently MRI has been introduced, several publications show the interest of Brazilian authors, particularly in the area of thoracic oncology( 6 - 16 ). In pediatrics, due to the absence of radiation, wbMRI has shown unquestionable advantages as compared with PET/CT( 1 , 6 ).
Also, it is important to consider the cost of image methods. As a function of the nature and complexity of the imaging system, as well as of the intrinsic maintenance costs, MRI is unavoidably more expensive than CT. However, it is less expensive than PET/CT. Additionally the PET/CT apparatuses include a higher number of components and the demand for a continuous production of radiopharmaceuticals makes it intrinsically more expensive. Owing to the imaging system itself and to the absence of radiopharmaceutical manipulation, MRI is also safer than PET/CT. It was demonstrated that, differently from the ionizing radiation utilized in CT, the powerful magnetic field and the radiofrequency energy of MRI do not cause cancer or fetal abnormalities( 1 , 6 ). It is important to observe that, although it is known that CT causes cancer, the exact risk of developing cancer due to exposure to CT or repeated tomographic scans is still to be established( 1 , 6 ).
In the present issue of Radiologia Brasileira, Teixeira et al.( 17 ) report a very interesting review about wbMRI in pediatrics. The authors reviewed the role played by the method in oncology - in the diagnosis and screening for tumors in patients with genetic syndromes; in the evaluation of therapeutic response; and in the post-therapeutic follow-up - as well as in the management of non neoplastic lesions - multifocal osteomyelitis; vascular malformations; and syndromes affecting multiple regions of the body. The mentioned review is an interesting guide for those who want to be familiar with the method and also adds special attention to technical aspects, which represent one of the main obstacles to the dissemination of the technique. Finally, the article demonstrates that, in pediatrics, MRI should soon replace PET/CT considering their similar accuracy level and the absence of ionizing radiation.
References
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Publication Dates
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Publication in this collection
May-Jun 2015