Radiotherapy (RT) is a crucial part of cancer treatment, but its use becomes more complex during pregnancy. While RT plays an essential role in treating cancer, it demands meticulous planning, strict adherence to safety guidelines, and precision when administered to pregnant patients. Pregnancy introduces unique challenges to radiation therapy because of the potential risks it poses to the developing fetus. Ionizing radiation can be harmful, but medical physicists are trained to minimize these risks during maternal treatment. They are responsible for ensuring that radiation is delivered safely and effectively, particularly for patients in critical condition. This study focuses on the planning and delivery of a tailored radiation treatment that prioritizes the safety of both the mother and the fetus. It explores various strategies for organizing and administering RT in pregnant patients, with a strong emphasis on safety and precision. The document outlines recommended treatment approaches, best practices in dosimetry, and essential safety protocols for medical physicists who manage radiation therapy in pregnant individuals. It also highlights the vital role these specialists play in maintaining the highest standards of professional expertise delivering training, and developing protocols to reduce potential risks. Ultimately, this paper serves as a comprehensive overview of how to safely implement radiotherapy in pregnancy, underscoring the importance of specialized planning, radiation protection, and the continuous involvement of medical physicists in safeguarding both maternal and fetal health.
References
[1]
United Nations Scientific Committee on the Effects of Atomic Radiation (2010) Sources and Effects of Ionizing Radiation: UNSCEAR 2010 Report to the General Assembly. United Nations. https://www.unscear.org
[2]
International Commission on Radiological Protection (2000) Pregnancy and Medical Radiation (ICRP Publication 84). Pergamon Press. https://www.icrp.org/publication.asp?id=ICRP%20Publication%2084
[3]
National Council on Radiation Protection and Measurements (2013) Preconception and Prenatal Radiation Exposure: Health Effects and Protective Guidance (NCRP Report No. 174). NCRP. https://ncrponline.org
[4]
Kal, H.B. and Struikmans, H. (2005) Radiotherapy during Pregnancy: Fact and Fiction. The Lancet Oncology, 6, 328-333.
[5]
Stovall, M., Blackwell, C.R., Cundiff, J., Novack, D.H., Palta, J.R., Wagner, L.K. and Shalek, R.J. (1995) Fetal Dose from Radiotherapy with Photon Beams: AAPM Task Group 36. Medical Physics, 22, 63-82.
[6]
Marcie, R. and Clairand, I. (2008) Estimation of the Dose to the Fetus Due to Radiotherapy Treatment. Radiation Protection Dosimetry, 132, 253-260.
[7]
Antypas, C. and Pantelis, E. (2008) Monte Carlo Dosimetry for Radiotherapy: Applications and Uncertainties. Journal of Medical Physics, 33, 71-79.
[8]
International Atomic Energy Agency (2012) Radiation Protection in Medicine: Training Materials for Health Professionals. IAEA. https://www.iaea.org/publications
[9]
ICRU (International Commission on Radiation Units and Measurements) (2010) Prescribing, Recording, and Reporting Photon-Beam Intensity-Modulated Radiation Therapy (IMRT) (ICRU Report 83). https://www.icru.org
[10]
American Association of Physicists in Medicine (1997) Fetal Dose from Radiotherapy with Photon Beams: Report of AAPM Task Group No. 36. https://www.aapm.org/pubs/reports
[11]
Dhaka Medical College Hospital (2022) Clinical Case Record: Cervical Cancer Management in Pregnancy, 20-Week Gestation. Unpublished Internal Report.
[12]
National Institute of Cancer Research & Hospital (NICRH) (2021) Radiotherapy Planning and Ethical Case Review for Early Pregnancy Breast Cancer. Institutional Case Archive.
[13]
Chittagong Medical College Hospital (2023) Emergency RT Planning for Glioblastoma in Late-Term Pregnancy. Internal Medical Physicist Team Report.
