Japanese structure survey of radiation oncology in 2015

Abstract This article describes the ongoing structure of radiation oncology in Japan in terms of equipment, personnel, patient load and geographic distribution to identify and overcome any existing limitations. From May 2016 to August 2018, the Japanese Society for Radiation Oncology conducted a que...

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Bibliographic Details
Published in:Journal of radiation research 2022-03, Vol.63 (2), p.230-246
Main Authors: Numasaki, Hodaka, Nakada, Yoshihiro, Okuda, Yasuo, Ohba, Hisateru, Teshima, Teruki, Ogawa, Kazuhiko
Format: Article
Language:English
Subjects:
Fundamental Radiation Science
Humans
Iridium Radioisotopes
Japan - epidemiology
Physicists
Radiation
Radiation Oncology
Radiotherapy
Surveys
Surveys and Questionnaires
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Summary:Abstract This article describes the ongoing structure of radiation oncology in Japan in terms of equipment, personnel, patient load and geographic distribution to identify and overcome any existing limitations. From May 2016 to August 2018, the Japanese Society for Radiation Oncology conducted a questionnaire based on the Japanese national structure survey of radiation oncology in 2015. Data were analyzed based on the institutional stratification by the annual number of new patients treated with radiotherapy per institution. The estimated annual numbers of new and total (new plus repeat) patients treated with radiation were 225 000 and 271 000, respectively. Additionally, the estimated cancer incidence was 891 445 cases with approximately 25.2% of all newly diagnosed patients being treated with radiation. The types and numbers of treatment devices actually used included linear accelerator (linac; n = 936), Gamma Knife (n = 43), 60Co remote afterloading system (RALS; n = 21), and 192Ir RALS (n = 129). The linac system used dual-energy functions in 754 units, 3D conformal radiotherapy functions in 867, and intensity-modulated radiotherapy (IMRT) functions in 628. There were 899 Japan Radiological Society/Japanese Society for Radiation Oncology-certified radiation oncologists (RO), 1213.9 full-time equivalent (FTE) ROs, 2394.2 FTE radiotherapy technologists (RTT), 295.7 FTE medical physicists, 210.2 FTE radiotherapy quality managers, and 906.1 FTE nurses. The frequency of IMRT use significantly increased during this time. In conclusion, the Japanese structure of radiation oncology has clearly improved in terms of equipment and utility although there was a shortage of personnel in 2015.
ISSN:0449-3060
1349-9157
1349-9157
DOI:10.1093/jrr/rrab129