Dosimetry in Brachytherapy – An International Code of Practice for Secondary Standards Dosimetry Laboratories and Hospitals
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Dosimetry in Brachytherapy – An International Code of Practice for Secondary Standards Dosimetry Laboratories and Hospitals - IAEA
Dosimetry in Brachytherapy –
An International Code
of Practice for Secondary
Standards Dosimetry
Laboratories and Hospitals
TECHNICAL REPORTS SERIES NO. 492
Dosimetry in Brachytherapy –
An International Code
of Practice for Secondary
Standards Dosimetry
Laboratories and Hospitals
INTERNATIONAL ATOMIC ENERGY AGENCY
VIENNA, 2023
COPYRIGHT NOTICE
All IAEA scientific and technical publications are protected by the terms of the Universal Copyright Convention as adopted in 1952 (Berne) and as revised in 1972 (Paris). The copyright has since been extended by the World Intellectual Property Organization (Geneva) to include electronic and virtual intellectual property. Permission to use whole or parts of texts contained in IAEA publications in printed or electronic form must be obtained and is usually subject to royalty agreements. Proposals for non-commercial reproductions and translations are welcomed and considered on a case-by-case basis. Enquiries should be addressed to the IAEA Publishing Section at:
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© IAEA, 2023
Printed by the IAEA in Austria
December 2023
STI/DOC/010/492
IAEA Library Cataloguing in Publication Data
Names: International Atomic Energy Agency.
Title: Dosimetry in brachytherapy – an international code of practice for secondary standards dosimetry laboratories and hospitals / International Atomic Energy Agency.
Description: Vienna : International Atomic Energy Agency, 2023. | Series: Technical reports series (International Atomic Energy Agency), ISSN 0074-1914 ; no. 492 | Includes bibliographical references.
Identifiers: IAEAL 23-01619 | ISBN 978-92-0-113923-8 (paperback : alk. paper) | ISBN 978-92-0-114023-4 (pdf) | ISBN 978-92-0-114123-1 (epub)
Subjects: LCSH: Radiation dosimetry. | Radioisotope brachytherapy. | Radiation — Measurement. | Radiotherapy.
Classification: UDC 615.849 | STI/DOC/010/492
FOREWORD
One of the key roles of the IAEA is to improve the traceability, accuracy, and consistency of clinical radiation dosimetry measurements in Member States. With reference to harmonization of dosimetry in external radiotherapy beams, the IAEA has disseminated a number of international codes of practice, which are published in the IAEA’s Technical Report Series (TRS), providing detailed descriptions of the instruments and steps to be taken for absorbed dose determination in water.
Technical Reports Series No. 277 (second edition), Absorbed Dose Determination in Photon and Electron Beams and Technical Reports Series No. 381, The Use of Plane Parallel Ionization Chambers in High Energy Electron and Photon Beams, both published in 1997, were based on air kerma calibration standards. Technical Reports Series No. 398, Absorbed Dose Determination in External Beam Radiotherapy, which was published in 2000, was based on the application of standards of absorbed dose to water. More recently, Technical Reports Series No. 483, Dosimetry of Small Static Fields Used in External Beam Radiotherapy, was published to provide information on the dosimetry of small static photon fields used in newer techniques and technologies.
The brachytherapy process also requires consistent reference dosimetry that is traceable to metrological primary standards. IAEA-TECDOC-1274, Calibration of Photon and Beta Ray Sources Used in Brachytherapy has been a key resource for brachytherapy dosimetry since 2002. However, several new developments have taken place, in terms of available dosimetry standards, detectors, radioactive sources, and brachytherapy technologies. Following recommendations from the 17th Scientific Committee of the IAEA/WHO Network of Secondary Standards Dosimetry Laboratories (2016), it was decided to prepare an international code of practice for brachytherapy dosimetry.
This code of practice is addressed to both secondary standards dosimetry laboratories and hospitals and is based on the use of well-type re-entrant ionization chambers. It applies to all brachytherapy sources with intensities measurable by such detectors. The dosimetry formalism; common procedures for reference dosimetry and for calibration; reference-class instrument assessment; and commissioning of the well-type chamber system are described. Guidance and recommendations provided here in relation to identified good practices represent expert opinion but are not made on the basis of a consensus of all Member States.
Miniature systems that use low-energy X ray sources, usually referred to as electronic brachytherapy, are discussed in this publication. However, work is still needed at the metrological level to provide a standardized and well established approach for their dosimetry. Therefore, even if much of the content of this publication might be relevant, electronic brachytherapy sources are not included in the main section of this publication. Beta emitting ophthalmic eye plaques and applicators are also excluded from the main section. Detectors different from well-type chambers are used for their calibration. Other suitable detectors that could be used are also discussed in this publication.
The IAEA wishes to express its gratitude to all those who contributed to the drafting and review of this publication, in particular T. Bokulic (Croatia), L. A. DeWerd, (United States of America), M. McEwen (Canada), M. J. Rivard (United States of America), T. Sander (United Kingdom), T. Schneider (Germany) and P. Toroi (Finland). The IAEA also wishes to acknowledge the following people for their valuable comments and suggestions: J. T. Alvarez-Romero (Mexico), Sudhir Kumar (India), and E. Mainegra-Hing (Canada). The IAEA officer responsible for this publication was M. Carrara of the Division of Human Health.
EDITORIAL NOTE
Although great care has been taken to maintain the accuracy of information contained in this publication, neither the IAEA nor its Member States assume any responsibility for consequences which may arise from its use.
This publication does not address questions of responsibility, legal or otherwise, for acts or omissions on the part of any person.
Guidance and recommendations provided here in relation to identified good practices represent expert opinion but are not made on the basis of a consensus of all Member States.
The use of particular designations of countries or territories does not imply any judgement by the publisher, the IAEA, as to the legal status of such countries or territories, of their authorities and institutions or of the delimitation of their boundaries.
The mention of names of specific companies or products (whether or not indicated as registered) does not imply any intention to infringe proprietary rights, nor should it be construed as an endorsement or recommendation on the part of the IAEA.
The IAEA has no responsibility for the persistence or accuracy of URLs for external or third party Internet web sites referred to in this book and does not guarantee that any content on such web sites is, or will remain, accurate or appropriate.
The authoritative versions of the publications are the hard copies issued and available as PDFs on www.iaea.org/publications.To create the versions for e-readers, certain changes have been made, including the movement of some figures and tables.
CONTENTS
1. INTRODUCTION
1.1. Background
1.2. Objectives
1.3. Scope
1.4. Structure
2. BRACHYTHERAPY RADIOACTIVE SOURCES
2.1. Main photon-emitting radioactive sources
2.2. Beta-emitting radioactive sources
2.3. Other photon-emitting radioactive sources
3. QUANTITIES AND UNITS
3.1. Reference air kerma rate and air kerma strength
3.2. Absorbed dose to water and the dose rate constant
3.3. Recommended calibration quantities
3.4. Nuclear decay: half-lives and date and time standard
4. INSTRUMENTATION
4.1. The re-entrant well-type ionization chamber dosimetry system
4.2. Reference-class well-type ionization chambers
4.3. HDR brachytherapy delivery equipment
4.4. Instruments for air density and relative humidity measurements
5. DOSIMETRY FRAMEWORK
5.1. Classification of instruments and standards
5.2. The international measurement system
6. ESTABLISHMENT AND DISSEMINATION OF CALIBRATION QUANTITIES
6.1. Establishment of primary calibration standards
6.2. Calibration of the well-type chamber dosimetry system
6.3. Request for dosimetry system calibration
6.4. Information provided in the calibration certificate of the dosimetry system
7. DOSIMETRY FORMALISM
7.1. Formalism based on standards of reference air kerma rate
7.2. Source model correction factor
7.3. Source decay correction factor
7.4. Formalism based on standards of absorbed dose rate to water
7.5. Determination of the reference source strength
7.6. Calibration of the well-type chamber dosimetry system
7.7. Cross-calibration of the well-type chamber dosimetry systems
8. CODE OF PRACTICE FOR WELL-TYPE CHAMBER CALIBRATION AND SOURCE STRENGTH MEASUREMENT
8.1. Experimental set-up and equipment preparation
8.2. Well-type chamber measurements
8.3. Source model correction for air kerma rate measurements
8.4. Short term repeatibility checks of the well-type chamber instrumentation
8.5. Long term stability checks of the well-type chamber instrumentation
8.6. Source exchange and the vendor source certificate
9. ESTIMATED UNCERTAINTIES IN THE DETERMINATION OF THE REFERENCE AIR KERMA RATE UNDER REFERENCE CONDITIONS
10. APPLICATION OF REFERENCE QUANTITIES IN THE HOSPITAL
10.1. Photon-emitting radioactive sources
10.2. Beta-emitting radioactive sources
10.3. Brachytherapy source registries
10.4. Typical uncertainties in patient dosimetry
Appendix I: ANTIQUATED QUANTITIES AND UNITS
Appendix II: ESTABLISHMENT OF PRIMARY CALIBRATION STANDARDS FOR RADIOACTIVE BRACHYTHERAPY SOURCES
Appendix III: X-RAY EMITTING ELECTRONIC SOURCES
Appendix IV: OTHER DETECTOR SYSTEMS FOR BRACHYTHERAPY
Appendix V: THE AAPM TG-43 ALGORITHM FOR DOSE DISTRIBUTION CALCULATION IN BRACHYTHERAPY
Appendix VI: EXPRESSION OF UNCERTAINTIES
REFERENCES
ABBREVIATIONS
CONTRIBUTORS TO DRAFTING AND REVIEW
1. INTRODUCTION
1.1. Background
Brachytherapy is a specific modality of radiation therapy in which small encapsulated radiation sources are inserted into or near the volume to be treated [1]. Historically, the term brachytherapy referred to the use of radioactive sources. They were in fact the only sources of radiation that could be achieved in small dimensions available at the time of brachytherapy inception, which was at the beginning of the twentieth century. More recently, miniature systems that use electronically created low energy X rays instead of radionuclides were designed [2]. At the time of writing, a few of such devices are capable of performing intracavitary or intraoperative brachytherapy treatments [3] but radionuclides remain the primary sources used.
The clinical efficacy of brachytherapy is attributable to its capability of delivering a high radiation dose to the treated volume, while limiting the absorbed dose to surrounding tissues. Brachytherapy has shown its effectiveness, especially for the treatment of specific disease sites in the body. For example, there is a high incidence of advanced cervical cancer [4] which is best treated with a combination of external beam radiotherapy (EBRT) and brachytherapy [5, 6]. Apart from cancers of the cervix uteri, major indications for brachytherapy are endometrial, breast and prostate cancer [7]. For prostate cancer treatment, for instance, high risk groups of patients treated with EBRT and boosted with brachytherapy showed significantly better outcomes than those treated with EBRT alone or undergoing radical prostatectomy [8]. Further, small tumours that are accessible for implantation can in many cases be treated with brachytherapy as monotherapy [7].
Brachytherapy is an essential modality in low and middle income countries with a high incidence of cervical or oesophageal cancer. It is also broadly disseminated in high income countries. According to the Directory of Radiotherapy Centres (DIRAC) maintained by the International Atomic Energy Agency [9], currently 3345 brachytherapy facilities are available worldwide, with 65% of these being in high income countries and 35% in low and middle income countries. Most brachytherapy procedures are now performed using high dose rate (HDR) remote afterloaders. Remote afterloading low dose rate (LDR) equipment has been discontinued by the manufacturers, leaving HDR or pulsed dose rate (PDR) brachytherapy as the major alternative technologies and restricting LDR applications to manual procedures using low energy sources.
Since HDR brachytherapy techniques deliver very high dose rates to the point of prescription (i.e. they can reach a few hundreds of Gy h–1 at 1 cm distance from the source) [10], mistakes can lead to a wrong dose delivery with the potential for adverse effects [11]. According to the International Commission on Radiological Protection (ICRP) [12], more than 500 HDR accidents (including one death) have been reported along the entire chain of procedures
. The involved dose rates with LDR sources are significantly lower than with HDR, but applications with such types of sources may also be the subject of misadministration, leading possibly to adverse consequences [13–15]. Even if most radiation incidents were caused by human errors, appropriate dosimetry is essential to reduce the risk of misadministration. Source strength measurement is therefore considered a fundamental part of a general quality assurance (QA) programme for brachytherapy treatments, in order to deliver the prescribed dose to the target tissues [16–19]. End user dosimetry of brachytherapy sources is necessary to ensure traceability through secondary standards dosimetry laboratories (SSDLs) to the internationally accepted standards of primary standards dosimetry laboratories (PSDLs).
The majority of HDR systems in use worldwide are ¹⁹²Ir radionuclide based. A very small number of these are PDR systems, which combine the advantages of HDR stepping source dosimetry principles and safety with the favourable radiobiological properties of LDR brachytherapy applications [20]. Because of the relatively short half-life and the need for regular source replacement of ¹⁹²Ir, other radionuclides, such as ⁶⁰Co [21–23], or X-ray electronic brachytherapy (eBT) devices [3, 24] have been suggested for performing HDR treatments. Other radioactive photon-emitting sources, with lower energies and dose rates than ¹⁹²Ir and ⁶⁰Co, are also widely available [25]. Each of these types of sources have their own dosimetry requirements for the PSDLs, the SSDLs and hospitals.
Beta emitting radionuclides such as ⁹⁰Sr/⁹⁰Y and ¹⁰⁶Ru/¹⁰⁶Rh are used for specialized procedures, especially concerning intravascular applications [26] (⁹⁰Sr/⁹⁰Y) or ophthalmic treatments [27, 28] (both ⁹⁰Sr/⁹⁰Y and ¹⁰⁶Ru/¹⁰⁶Rh). Beta particles generally require dosimetry at the millimetre range, whereas photon sources extend further, with an application distance that might reach up to a few centimetres in some cases. The use of surface applicators for treatments using brachytherapy sources is also growing and requires its own consideration [29]. There have been many new radioactive sources introduced, many of which have still not found a place in the community for various reasons [30–35]. In addition to the standard source strength-specifying quantity of reference air kerma rate (RAKR) or air kerma strength (AKS), the other quantity that has been suggested is absorbed dose to water. The appropriate sections below consider these in more detail.
The expansion of the use of various sources has greatly increased around the world, but some of the available brachytherapy codes of practice are on the order of 20 years old and need updating [36, 37]. The need for an international dosimetry code of practice has become evident, especially for the standardization of quantities and dosimetry procedures.
1.2. Objectives
The present International Code of Practice for Brachytherapy Dosimetry is aimed to enable common procedures to perform dosimetry of radioactive sources used in brachytherapy, excluding beta-emitting eye plaques and applicators, as well as stranded seeds and mesh type sources. Targeted radionuclide therapy and miniature X-ray brachytherapy devices, known also as electronic