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ASTM ISO/ASTM52116-13(2020)

(Practice)

Standard Practice for Dosimetry for a Self-Contained Dry-Storage Gamma Irradiator

Standard Practice for Dosimetry for a Self-Contained Dry-Storage Gamma Irradiator

SIGNIFICANCE AND USE
4.1 The design and operation of a self-contained irradiator should ensure that reproducible absorbed doses are obtained when the same irradiation parameters are used. Dosimetry is performed to determine the relationship between the irradiation parameters and the absorbed dose.  
4.1.1 For most applications, the absorbed dose is expressed as absorbed dose to water (see ISO/ASTM Practice 51261). For conversion of absorbed dose to water to that to other materials, for example, silicon, see Annex A1 of ISO/ASTM Practice 51261.  
4.2 Self-contained dry-storage gamma irradiators contain properly shielded radioactive sources, namely  137Cs or  60Co, that emit ionizing electromagnetic radiation (gamma radiation). These irradiators have an enclosed, accessible irradiator sample chamber connected with a sample positioning system, for example, irradiator drawer, rotor, or irradiator turntable, as part of the irradiation device.  
4.3 Self-contained dry-storage gamma irradiators can be used for many radiation processing applications, including the calibration irradiation of dosimeters; studies of dosimeter influence quantities; radiation effects studies, and irradiation of materials or biological samples for process compatibility studies; batch irradiations of microbiological, botanical, or in-vitro samples; irradiation of small animals; radiation “hardness” testing of electronics components and other materials; and batch radiation processing of containers of samples.
Note 1: Self-contained dry-storage gamma irradiators contain a sealed radiation source, or an array of sealed radiation sources securely held in a dry container constructed of solid materials. The sealed radiation sources are shielded at all times, and human access to the chamber undergoing irradiation is not physically possible due to the irradiator’s design configuration (see ANSI/HPS N43.7).
Note 2: For reference–standard dosimetry, the absorbed dose and absorbed-dose rate can be expressed in water or o...
SCOPE
1.1 This practice outlines dosimetric procedures to be followed with self-contained dry-storage gamma irradiators. For irradiators used for routine processing, procedures are given to ensure that product processed will receive absorbed doses within prescribed limits.  
1.2 This practice covers dosimetry in the use of dry-storage gamma irradiators, namely self-contained dry-storage 137Cs or  60Co irradiators (shielded freestanding irradiators). It does not cover underwater pool sources, panoramic gamma sources, nor does it cover self-contained bremsstrahlung X-ray units.  
1.3 The absorbed-dose range for the use of the dry-storage self-contained gamma irradiators covered by this practice is typically 1 to 105 Gy, depending on the application. The absorbed-dose rate range typically is from 10–2 to 103 Gy/min.  
1.4 For irradiators supplied for specific applications, specific ISO/ASTM or ASTM practices and guides provide dosimetric procedures for the application. For procedures specific to dosimetry in blood irradiation, see ISO/ASTM Practice 51939. For procedures specific to dosimetry in radiation research on food and agricultural products, see ISO/ASTM Practice 51900 . For procedures specific to radiation hardness testing, see ASTM Practice E1249. For procedures specific to the dosimetry in the irradiation of insects for sterile release programs, see ISO/ASTM Guide 51940. In those cases covered by ISO/ASTM 51939, 51900 , 51940, or ASTM E1249, those standards take precedence.  
1.5 This document is one of a set of standards that provides recommendations for properly implementing and utilizing dosimetry in radiation processing. It is intended to be read in conjunction with ASTM E2628, “Practice for Dosimetry in Radiation Processing”.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate ...

General Information

Status
Published
Publication Date
30-Jun-2020
ICS
17.240 - Radiation measurements
Technical Committee
E61 - Radiation Processing
Drafting Committee
E61.04 - Specialty Application
Current Stage
Ref Project

Relations

Refers
ASTM E170-17 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2017
Refers
ASTM E170-16a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Oct-2016
Refers
ASTM E170-16 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Feb-2016
Refers
ASTM E170-15a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2015
Refers
ASTM E170-15 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Mar-2015
Refers
ASTM E170-14a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Oct-2014
Refers
ASTM E170-14 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2014
Refers
ASTM E1249-10 - Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 Sources
Effective Date
01-Dec-2010
Refers
ASTM E170-10 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2010
Refers
ASTM E170-09a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Aug-2009
Refers
ASTM E2628-09 - Standard Practice for Dosimetry for Radiation Processing
Effective Date
15-Aug-2009
Refers
ASTM E170-09 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Jun-2009
Refers
ASTM E170-08d - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Nov-2008
Refers
ASTM E170-08c - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2008
Refers
ASTM E170-08b - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-May-2008

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ASTM ISO/ASTM52116-13(2020) - Standard Practice for Dosimetry for a Self-Contained Dry-Storage Gamma IrradiatorASTM ISO/ASTM52116-13(2020) - Standard Practice for Dosimetry for a Self-Contained Dry-Storage Gamma Irradiator
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ASTM ISO/ASTM52116-13(2020) - Standard Practice for Dosimetry for a Self-Contained Dry-Storage Gamma Irradiator
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
ISO/ASTM 52116:2013 (Reapproved 2020)(E)
Standard Practice for
Dosimetry for a Self-Contained Dry-Storage Gamma
Irradiator
This standard is issued under the fixed designation ISO/ASTM 52116; the number immediately following the designation indicates the
year of original adoption or, in the case of revision, the year of last revision.
1. Scope responsibility of the user of this standard to establish appro-
priate safety, health, and environmental practices and deter-
1.1 This practice outlines dosimetric procedures to be fol-
mine the applicability of regulatory limitations prior to use.
lowed with self-contained dry-storage gamma irradiators. For
1.7 This international standard was developed in accor-
irradiators used for routine processing, procedures are given to
dance with internationally recognized principles on standard-
ensure that product processed will receive absorbed doses
ization established in the Decision on Principles for the
within prescribed limits.
Development of International Standards, Guides and Recom-
1.2 This practice covers dosimetry in the use of dry-storage
mendations issued by the World Trade Organization Technical
gamma irradiators, namely self-contained dry-storage Cs or
Barriers to Trade (TBT) Committee.
Co irradiators (shielded freestanding irradiators). It does not
cover underwater pool sources, panoramic gamma sources, nor
2. Referenced documents
does it cover self-contained bremsstrahlung X-ray units.
2.1 ASTM Standards:
1.3 The absorbed-dose range for the use of the dry-storage
E170 Terminology Relating to Radiation Measurements and
self-contained gamma irradiators covered by this practice is
Dosimetry
typically 1 to 10 Gy, depending on the application. The
E1249 Practice for Minimizing Dosimetry Errors in Radia-
–2 3
absorbed-dose rate range typically is from 10 to 10 Gy/min.
tion HardnessTesting of Silicon Electronic Devices Using
Co-60 Sources
1.4 For irradiators supplied for specific applications, spe-
E2628 Practice for Dosimetry in Radiation Processing
cific ISO/ASTM or ASTM practices and guides provide
E2701 Guide for Performance Characterization of Dosim-
dosimetric procedures for the application. For procedures
eters and Dosimetry Systems for Use in Radiation Pro-
specific to dosimetry in blood irradiation, see ISO/ASTM
cessing
Practice 51939. For procedures specific to dosimetry in radia-
tionresearchonfoodandagriculturalproducts,seeISO/ASTM
2.2 ISO/ASTM Standards:
Practice 51900 . For procedures specific to radiation hardness
51261 Practice for Calibration of Routine Dosimetry Sys-
testing, see ASTM Practice E1249. For procedures specific to
tems for Radiation Processing
the dosimetry in the irradiation of insects for sterile release
51539 Guide for Use of Radiation-Sensitive Indicators
programs,seeISO/ASTMGuide51940.Inthosecasescovered
51707 Guide for Estimating Uncertainties in Dosimetry for
by ISO/ASTM 51939, 51900 , 51940, or ASTM E1249, those
Radiation Processing
standards take precedence.
51900 Guide for Dosimetry in Radiation Research on Food
and Agricultural Products
1.5 This document is one of a set of standards that provides
51939 Practice for Blood Irradiation Dosimetry
recommendations for properly implementing and utilizing
51940 Guide for Dosimetry for Sterile Insects Release Pro-
dosimetry in radiation processing. It is intended to be read in
grams
conjunction with ASTM E2628, “Practice for Dosimetry in
Radiation Processing”.
2.3 International Commission on Radiation Units and Mea-
surements (ICRU) Reports:
1.6 This standard does not purport to address all of the
ICRU 85a Fundamental Quantities and Units for Ionizing
safety concerns, if any, associated with its use. It is the
Radiation
This practice is under the jurisdiction of ASTM Committee E61 on Radiation
Processing and is the direct responsibility of Subcommittee E61.04 on Specialty For referenced ASTM and ISO/ASTM standards, visit the ASTM website,
Application, and is also under the jurisdiction of ISO/TC 85/WG 3. www.astm.org, or contact ASTM Customer Service at service@astm.org. For
Current edition approved July 1, 2020. Published September 2020. Originally Annual Book of ASTM Standards volume information, refer to the standard’s
published as ASTM E 2116–00. Last previous ASTM edition E 2116–00. The Document Summary page on the ASTM website.
present International Standard ISO/ASTM 52116:2013(20)(E) replaces E 2116-00 International Commission on Radiation Units and Measurements (ICRU), 7910
and is a reapproval of the last previous edition ISO/ASTM 52116:2013(E). Woodmont Ave., Suite 800, Bethesda, MD 20810, U.S.A.
© ISO/ASTM International 2020 – All rights reserved
ISO/ASTM 52116:2013 (2020)(E)
2.4 ANSI Standards: performedtodeterminetherelationshipbetweentheirradiation
ANSI/HPS N43.7 Safe Design and Use of Self-Contained, parameters and the absorbed dose.
Dry Source Storage Gamma Irradiators (Category I)
4.1.1 For most applications, the absorbed dose is expressed
as absorbed dose to water (see ISO/ASTM Practice 51261).
2.5 Joint Committee for Guides in Metrology (JCGM)
For conversion of absorbed dose to water to that to other
Reports:
materials, for example, silicon, see Annex A1 of ISO/ASTM
JCGM 100:2008, GUM 1995 with minor corrections, Evalu-
Practice 51261.
ation of measurement data – Guide to the Expression of
Uncertainty in Measurement
4.2 Self-contained dry-storage gamma irradiators contain
137 60
JCGM 100:2008, VIM International vocabulary of metrol-
properly shielded radioactive sources, namely Cs or Co,
ogy – Basis and general concepts and associated terms
that emit ionizing electromagnetic radiation (gamma radia-
tion). These irradiators have an enclosed, accessible irradiator
3. Terminology
sample chamber connected with a sample positioning system,
3.1 Definitions: for example, irradiator drawer, rotor, or irradiator turntable, as
3.1.1 absorbed-dose mapping—measurement of absorbed part of the irradiation device.
dose within an irradiated product to produce a one-, two-, or
4.3 Self-contained dry-storage gamma irradiators can be
three-dimensionaldistributionofabsorbeddose,thusrendering
used for many radiation processing applications, including the
a map of absorbed-dose values.
calibration irradiation of dosimeters; studies of dosimeter
3.1.2 calibration—[VIM, 6.11] set of operations under
influence quantities; radiation effects studies, and irradiation of
specified conditions, which establishes the relationship be-
materials or biological samples for process compatibility
tween values indicated by a measuring instrument or measur-
studies; batch irradiations of microbiological, botanical, or
ing system, and the corresponding values realised by standards
in-vitro samples; irradiation of small animals; radiation “hard-
traceable to a nationally or internationally recognised labora-
ness” testing of electronics components and other materials;
tory.
and batch radiation processing of containers of samples.
3.1.2.1 Discussion—Calibration conditions include environ-
NOTE 1—Self-contained dry-storage gamma irradiators contain a sealed
mental and irradiation conditions present during irradiation,
radiation source, or an array of sealed radiation sources securely held in a
storageandmeasurementofthedosimetersthatareusedforthe
dry container constructed of solid materials. The sealed radiation sources
generation of a calibration curve. To achieve stable environ-
are shielded at all times, and human access to the chamber undergoing
irradiation is not physically possible due to the irradiator’s design
mental conditions, it may be necessary to condition the
configuration (see ANSI/HPS N43.7).
dosimeters before performing the calibration procedure.
NOTE 2—For reference–standard dosimetry, the absorbed dose and
3.1.3 dose uniformity ratio—ratio of the maximum to the
absorbed-dose rate can be expressed in water or other material which has
minimum absorbed dose within the irradiated product.
similarradiationabsorptionpropertiestothatofthesamplesordosimeters
being irradiated. In some cases, the reference-standard dosimetry may be
3.1.4 measurement management system—set of interrelated
performed using ionization chambers, and may be calibrated in terms of
–1
or interacting elements necessary to achieve metrological
exposure (C kg ), or absorbed dose to air, water or tissue (Gy).
confirmation and continual control of measurement processes.
Measurements performed in terms of exposure apply to ionization in air,
and care should be taken to apply that measurement to the sample being
3.1.5 transit dose—absorbed dose delivered to a product (or
irradiated.
a dosimeter) while it travels between the non-irradiation
position and the irradiation position, or in the case of a
5. Types of facilities and modes of operation
movable source while the source moves into and out of its
5.1 Facility Types—Typical self-contained dry-storage
irradiation position.
gamma irradiators are illustrated in Annex A1. These irradia-
3.2 Definitions of other terms used in this standard that
tors house the radiation source(s) in a protective lead shield (or
pertain to radiation measurement and dosimetry may be found
other appropriate material), and usually have a sample posi-
in ASTM Terminology E170. Definitions in ASTM Terminol-
tioning mechanism tied to an accurate calibrated reset timer to
ogy E170 are compatible with ICRU 85a; that document,
lowerorrotatethesampleholderfromtheload/unloadposition
therefore, may be used as an alternative reference.
to the irradiation position and back to the load/unload position.
Details on the calibration of dosimetry systems and dose
4. Significance and use
mapping in such irradiators may be found, respectively in
4.1 The design and operation of a self-contained irradiator
ISO/ASTM Guide 51261 and in this practice. Details on the
should ensure that reproducible absorbed doses are obtained
designs of such irradiators and on safety considerations in the
when the same irradiation parameters are used. Dosimetry is
use of such irradiators may be found in ANSI/HPS N43.7.
5.2 Modes of Operation—Three common modes of opera-
tion are described. This does not purport to include all modes
Available from the Health Physics Society, http://hps.org.
of operation.
Document produced by Working Group 1 of the Joint Committee for Guides in
Metrology (JCGM/WG 1). Available free of charge at the BIPM website (http://
5.2.1 One method of use is to rotate the sample holder on an
www.bipm.org).
irradiator turntable in front of the source such that the only
Document produced by Working Group 2 of the Joint Committee for Guides in
pointsthatremainafixeddistancefromthesourcearealongan
Metrology (JCGM/WG 2). Available free of charge at the BIPM website (http://
www.bipm.org). axis of rotation (ANSI/HPS N43.7).
© ISO/ASTM International 2020 – All rights reserved
ISO/ASTM 52116:2013 (2020)(E)
NOTE 4—Table A2.1 gives some recommended steps in the following
5.2.2 A second method is to distribute the source in an
areas: installation qualification, operational qualification, performance
annular array, resulting in a relatively uniform absorbed-dose
qualification, and routine product processing.
distribution. In this design, the irradiator turntable normally
8.2 Equipment Documentation—Establish and document an
would not be necessary.
IQ program that includes descriptions of the instrumentation
5.2.3 A third method is to use opposed sources with
and equipment installed at the facility. This documentation
appropriate beam flattening to obtain a uniform dose through-
shall be retained for the life of the facility. At a minimum, it
out the sample.
shall include:
6. Radiation source characteristics 8.2.1 A description of the irradiator’s specifications, char-
acteristics and parameters, including any modifications made
6.1 The radiation sources used in the irradiation devices
60 during or after installation,
considered in this practice consist of sealed elements of Co
8.2.2 A description of the location of the irradiator within
or Cs, which are typically linear rods or pencils arranged
the operator’s premises,
singly or in a planar array or cylindrical array.
8.2.3 Operating instructions and standard operating proce-
6.2 Cobalt-60 emits photons with energies of approximately
dures for the irradiator and associated measurement
1.17 and 1.33 MeV in nearly equal proportions; cesium-137
instruments,
emits photons with energies of approximately 0.662 MeV.
8.2.4 Licensing and safety documents and procedures, in-
60 137
cluding those required by regulatory and occupational health
6.3 The radioactive decay half-lives for Co and Cs are
regularly reviewed and updated. The most recent publication and safety agencies,
8.2.5 A description of a calibration program to ensure that
by the National Institute of Standards and Technology gave
values of 1925.20 (6 0.25) days for Co and 11018.3 (6 9.5) all processing equipment that may influence absorbed-dose
137 137
delivery is calibrated periodically (for example, the timer
days for Cs. In addition, the Cs radiation source may
containradioimpuritieswhichshouldbequalifiedbythesource mechanism),
manufacturer. 8.2.6 Operating procedures and calibration procedures for
60 137 associated measurement instruments or systems.
6.4 For pure Co and Cs gamma sources, the only
variation in the source strength is the known reduction in the 8.3 Equipment Testing and Calibration—Test all processing
activity caused by radioactive decay. The reduction in the equipment and instrumentation that may influence absorbed
source strength and the required increase in the irradiation time dose in order to verify satisfactory operation of the irradiator
to deliver the same dose may be calculated or obtained from within the design specifications.
tables provided by the irradiator manufacturer. 8.3.1 Implement a documented calibration program to en-
sure that all processing equipment and instrumentation that
7. Dosimetry systems
may influence absorbed-dose delivery are calibrated periodi-
cally.
7.1 The basic requirements that apply when making ab-
8.3.2 If any modification or change is made to the irradiator
sorbed dose measurements are given in ASTM E2628. ASTM
equipment or measurement instruments during the installation
E2628 also provides guidance on the selection of dosimetry
qualification phase, they shall be re-tested.
systems and describes the classification of dosimeters based on
two criteria. Users are directed to other standards that provide
8.4 For self-contained irradiators, so
...

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4.1 The Fricke dosimetry system provides a reliable means for measurement of absorbed dose to water, based on a process of oxidation of ferrous ions to ferric ions in acidic aqueous solution by ionizing radiation (ICRU 80, PIRS-0815, (4)). In situations not requiring traceability to national standards, this system can be used for absolute determination of absorbed dose without calibration, as the radiation chemical yield of ferric ions is well characterized (see Appendix X3).  
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1.3 The practice describes the spectrophotometric analysis procedures for the Fricke dosimetry system.  
1.4 This practice applies only to gamma radiation, X-radiation (bremsstrahlung), and high-energy electrons.  
1.5 This practice applies provided the following are satisfied:  
1.5.1 The absorbed dose range shall be from 20 Gy to 400 Gy (1).2  
1.5.2 The absorbed dose rate does not exceed 106 Gy·s−1 (2).  
1.5.3 For radioisotope gamma sources, the initial photon energy is greater than 0.6 MeV. For X-radiation (bremsstrahlung), the initial energy of the electrons used to produce the photons is equal to or greater than 2 MeV. For electron beams, the initial electron energy is greater than 8 MeV.  
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4.1 Standards such as ISO 11137-1 (radiation sterilization of health care products) and ISO 14470 (irradiation of food) contain requirements that dosimetry used in the development, validation, and routine control of the process shall have measurement traceability to national or international standards and shall have a known level of uncertainty. The magnitude of the measurement uncertainty is important for assessing the results of the measurement system.  
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1.1 This standard provides guidance on the use of concepts described in the JCGM (Joint Committee for Guides in Metrology) Evaluation of Measurement Data – Guide to the Expression of Uncertainty in Measurement (GUM) to estimate the uncertainties in the measurement of absorbed dose in radiation processing.  
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1.3.1 Key components of uncertainty are derived as part of the derivation of the uncertainty budget. This standard identifies which components of uncertainty are carried forward as part of other analyses (e.g., assessment of process capability and process targets, and process variability), and which components from other standards are brought forward into this standard (e.g., precision of the dose measurement, calibration curve fit, and indirect measurement of dose).  
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SIGNIFICANCE AND USE
4.1 Various products and materials are routinely irradiated at pre-determined doses at electron beam facilities to preserve or modify their characteristics. Dosimetry requirements may vary depending on the radiation process and end use of the product. A partial list of processes where dosimetry may be used is given below.  
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Note 2: Dosimetry with measurement traceability and known uncertainty is required for regulated radiation processes such as sterilization of health care products (see ISO 11137-1 and Refs (1-36)) and preservation of food (see ISO 14470 and Ref (4)). It may be less important for other processes, such as polymer modification, which may be evaluated by changes in the physical and chemical properties of the irradiated materials. Nevertheless, routine dosimetry may be used to monitor the reproducibility of the treatment process.
Note 3: Measured dose is often characterized as absorbed dose in water. Materials commonly found in single-use disposable medical devices and food are approximately equivalent to water in the absorption of ionizing radiation. Absorbed dose in materials other than water may be determined by applying conversion factors (5, 6).  
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1.5 This document is one of a set of standards that provides recommendations for properly implementing and utilizing dosimetry in radiation processing. It is intended to be read in conjunction with ISO/ASTM 52628, “Practice for Dosimetry in Radiation Processing”.
Note 1: For guidance in the calibration of routine dosimetry systems, see ISO/ASTM Practice 51261. For further guidance in the use of specific dosimetry systems, see relevant ISO/ASTM Practices. For discussion of radiation dosimetry for pulsed radiation, see ICRU Report 34.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and env...

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ASTM ISO/ASTM51608-15(2022)(Practice)
Standard Practice for Dosimetry in an X-Ray (Bremsstrahlung) Facility for Radiation Processing at Energies between 50 keV and 7.5 MeV

SIGNIFICANCE AND USE
4.1 A variety of products and materials are irradiated with X-radiation to modify their characteristics and improve the economic value or to reduce their microbial population for health-related purposes. Dosimetry requirements might vary depending on the type and end use of the product. Some examples of irradiation applications where dosimetry may be used are:  
4.1.1 Sterilization of health care products;  
4.1.2 Treatment of food for the purpose of parasite and pathogen control, insect disinfestation, and shelf life extension;  
4.1.3 Disinfection of consumer products;  
4.1.4 Cross-linking or degradation of polymers and elastomers;  
4.1.5 Curing composite material;  
4.1.6 Polymerization of monomers and oligomer and grafting of monomers onto polymers;  
4.1.7 Enhancement of color in gemstones and other materials;  
4.1.8 Modification of characteristics of semiconductor devices; and  
4.1.9 Research on materials effects of irradiation.
Note 3: Dosimetry with measurement traceability and with known measurement uncertainty is required for regulated irradiation processes, such as the sterilization of health care products and treatment of food. Dosimetry may be less important for other industrial processes, such as polymer modification, which can be evaluated by changes in the physical properties of the irradiated materials. Nevertheless, routine dosimetry may be used to monitor the reproducibility of the radiation process.  
4.2 Radiation processing specifications usually include a pair of absorbed-dose limits: a minimum value to ensure the intended beneficial effect and a maximum value that the product can tolerate while still meeting its functional or regulatory specifications. For a given application, one or both of these values may be prescribed by process specifications or regulations. Knowledge of the dose distribution within irradiated material is essential to help meet these requirements. Dosimetry is essential to the radiation process since it i...
SCOPE
1.1 This practice outlines the dosimetric procedures to be followed during installation qualification, operational qualification, performance qualification and routine processing at an X-ray (bremsstrahlung) irradiator. Other procedures related to operational qualification, performance qualification and routine processing that may influence absorbed dose in the product are also discussed.
Note 1: Dosimetry is only one component of a total quality assurance program for adherence to good manufacturing practices used in radiation processing applications.
Note 2: ISO/ASTM Practices 51649, 51818 and 51702 describe dosimetric procedures for electron beam and gamma facilities for radiation processing.  
1.2 For radiation sterilization of health care products, see ISO 11137-1, Sterilization of health care products – Radiation – Part 1: Requirements for development, validation and routine control of a sterilization process for medical devices. In those areas covered by ISO 11137-1, that standard takes precedence.  
1.3 For irradiation of food, see ISO 14470, Food irradiation – Requirements for development, validation and routine control of the process of irradiation using ionizing radiation for the treatment of food. In those areas covered by ISO 14470, that standard takes precedence.  
1.4 This document is one of a set of standards that provides recommendations for properly implementing and utilizing dosimetry in radiation processing. It is intended to be read in conjunction with ISO/ASTM Practice 52628, “Practice for Dosimetry in Radiation Processing”.  
1.5 In contrast to monoenergetic gamma radiation, the X-ray energy spectrum extends from low values (about 35 keV) up to the maximum energy of the electrons incident on the X-ray target (see Section 5 and Annex A1).  
1.6 Information about effective or regulatory dose limits and energy limits for X-ray applications is not within the scope of this practice.  
1.7 This ...

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ASTM ISO/ASTM51939-22(Practice)
Standard Practice for Blood Irradiation Dosimetry

SIGNIFICANCE AND USE
4.1 Blood and blood components are irradiated to predetermined absorbed doses to inactivate viable lymphocytes to help prevent transfusion-induced graft-versus-host disease (GVHD) in certain immunocompromised patients and those receiving related-donor products (1, 2).9  
4.2 The assurance that blood and blood components have been properly irradiated is of crucial importance for patient health. This shall be demonstrated by means of accurate absorbed-dose measurements on the product, or in simulated product.  
4.3 Blood and blood components are usually irradiated using gamma radiation from 137Cs or 60Co sources, or X-radiation from X-ray units.  
4.4 Blood irradiation specifications include a lower limit of absorbed dose, and may include an upper limit or central target dose. For a given application, any of these values may be prescribed by regulations that have been established on the basis of available scientific data (see 2.6).  
4.5 For each blood irradiator, an absorbed-dose rate at a reference position within the canister is measured as part of irradiator acceptance testing using a reference-standard dosimetry system. That reference-standard measurement is used to establish operating parameters so as to deliver specified dose to blood and blood components.  
4.6 Absorbed-dose measurements are performed within the blood or blood-equivalent volume for determining the absorbed-dose distribution. Such measurements are often performed using simulated product (for example, polystyrene is considered blood equivalent for 137Cs photon energies).  
4.7 Dosimetry is part of a measurement management system that is applied to ensure that the radiation process meets predetermined specifications (see ISO/ASTM Practice 52628).  
4.8 Blood and blood components are usually irradiated in chilled or frozen condition. Care should be taken, therefore, to ensure that the dosimeters and radiation-sensitive indicators can be used under such temperature conditions.  
4.9 Proper ...
SCOPE
1.1 This practice outlines the irradiator installation qualification program and the dosimetric procedures to be followed during operational qualification and performance qualification of the irradiator. Procedures for the routine radiation processing of blood product (blood and blood components) are also given. If followed, these procedures will help ensure that blood product exposed to gamma radiation or X-radiation (bremsstrahlung) will receive absorbed doses with a specified range.  
1.2 This practice covers dosimetry for the irradiation of blood product for self-contained irradiators (free-standing irradiators) utilizing radionuclides such as 137Cs and  60Co, or X-radiation (bremsstrahlung). The absorbed dose range for blood irradiation is typically 15 Gy to 50 Gy.  
1.3 The photon energy range of X-radiation used for blood irradiation is typically from 40 keV to 300 keV.  
1.4 This practice also covers the use of radiation-sensitive indicators for the visual and qualitative indication that the product has been irradiated (see ISO/ASTM Guide 51539).  
1.5 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for dosimetry performed for blood irradiation. It is intended to be read in conjunction with ISO/ASTM Practice 52628.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides ...

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ASTM
ASTM ISO/ASTM51607-22(Practice)
Standard Practice for Use of an Alanine-EPR Dosimetry System

SIGNIFICANCE AND USE
4.1 The alanine-EPR dosimetry system provides a means for measuring absorbed dose. It is based on the measurement of specific stable free radicals in crystalline alanine generated by ionizing radiation.  
4.2 Alanine-EPR dosimetry systems are used in reference- or transfer-standard or routine dosimetry systems in radiation applications that include: sterilization of medical devices and pharmaceuticals, food irradiation, polymer modifications, medical therapy and radiation damage studies in materials (1, 13-15).
SCOPE
1.1 This practice covers dosimeter materials, instrumentation, and procedures for using the alanine-EPR dosimetry system to measure the absorbed dose in the photon or electron radiation processing of materials. The alanine system is based on electron paramagnetic resonance (EPR) spectroscopy of free radicals derived from the amino acid alanine.2  
1.2 The alanine dosimeter is classified as a type I dosimeter as it is affected by individual influence quantities in a well-defined way that can be expressed in terms of independent correction factors (see ISO/ASTM Practice 52628). The alanine dosimeter may be used in either a reference standard dosimetry system or in a routine dosimetry system.  
1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 “Practice for Dosimetry in Radiation Processing” for alanine dosimetry system. It should be read in conjunction with ISO/ASTM 52628.  
1.4 This practice covers the use of alanine-EPR dosimetry systems under the following conditions:  
1.4.1 The absorbed dose range is between 0.001 kGy and 150 kGy.  
1.4.2 The absorbed dose rate is up to 1 × 102 Gy s-1 for continuous radiation fields and up to 3 × 1010 Gy s-1 for pulsed radiation fields (1-4).3  
1.4.3 The radiation energy for photons and electrons is between 0.1 MeV and 30 MeV (1, 2, 5-8).  
1.4.4 The irradiation temperature is between –78 °C and +70 °C (2, 9-12).  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM ISO/ASTM51650-21(Practice)
Standard Practice for Use of a Cellulose Triacetate Dosimetry System

SIGNIFICANCE AND USE
4.1 The CTA dosimetry system provides a means for measuring absorbed dose based on a change in optical absorbance in the CTA dosimeter following exposure to ionizing radiation (2-10).  
4.2 CTA dosimetry systems are commonly used in industrial radiation processing, for example in the modification of polymers and sterilization of health care products.  
4.3 CTA dosimeter film can be particularly useful in absorbed dose mapping because it is available in a reel of 100 m whereby the user can cut any length of strip for use. When the CTA film is measured using a strip measurement device with a narrow distance interval (for example, 2 mm), it can provide high resolution results in a linear direction.  
4.4 CTA is used to measure relative dose such as depth dose profiles in electron beam and reference phantom tests to assess irradiator changes in gamma.  
4.5 When CTA is used as a routine monitoring dosimeter the user must take into consideration the effects of the multiple influence quantities that can affect the result and use appropriate techniques, as discussed herein, for characterizing and mitigating such influences and understanding their contribution to measurement uncertainty. Without such effort the dosimetry system may not meet the user’s requirements for dosimetric release of some types of products (for example, health care products).
SCOPE
1.1 This is a practice for using a cellulose triacetate (CTA) dosimetry system to measure absorbed dose in materials irradiated by photons or electrons in terms of absorbed dose to water. CTA is used as a routine dosimetry system or used for relative dose measurements (that is, non-traceable dose measurements).  
1.2 The CTA dosimeter is classified as a type II dosimeter on the basis of the complex effect of influence quantities on its response (see ISO/ASTM Practice 52628).  
1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 “Practice for Dosimetry in Radiation Processing” for a CTA dosimetry system. It is intended to be read in conjunction with ISO/ASTM 52628.  
1.4 This practice covers the use of CTA dosimetry systems under the following conditions:  
1.4.1 The absorbed dose range is 10 kGy to 300 kGy.
Note 1: The dosimeter film irradiated to doses exceeding 200 kGy becomes brittle to some degree and must be handled with care. This may limit the practical dose range depending on the type of testing and handling required.  
1.4.2 The absorbed-dose rate range is 3 Gy/s to 4 ×1010 Gy·s (1).2  
1.4.3 The photon energy range is 0.1 to 50 MeV.  
1.4.4 The electron energy range is 0.2 to 50 MeV.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM ISO/ASTM51956-21(Practice)
Standard Practice for Use of a Thermoluminescence-Dosimetry System (TLD System) for Radiation Processing

SIGNIFICANCE AND USE
4.1 In radiation processing, TLDs are mainly used in the irradiation of blood products (see ISO/ASTM Practice 51939) and insects for sterile insect release programs (see ISO/ASTM Guide 51940). TLDs may also be used in other radiation processing applications such as the sterilization of medical products, food irradiation, modification of polymers, irradiation of electronic devices, and curing of inks, coatings and adhesives. (See ISO/ASTM Practices 51608, 51649, and 51702.)  
4.2 For radiation processing, the absorbed-dose range of interest is from 1 Gy to 100 kGy. Some TLDs can be used in applications requiring much lower absorbed doses (for example, for personnel dosimetry), but such applications are outside the scope of this practice. Examples of TLDs and applicable dose ranges are given in Table 1. Information on various types of TLDs and their applications can be found in Refs (1-10).7 (A) This table is taken from Ref (6). Ranges are approximate, and may vary with batch. Supralinearity refers to a region where the slope of the response versus dose curve is greater than that for the linear region.  
4.3 Information on other dosimetry systems used for radiation processing can be found in ICRU Report 80.
SCOPE
1.1 This practice covers procedures for the use of thermoluminescence dosimeters (TLDs) to measure the absorbed dose in materials irradiated by photons or electrons in terms of absorbed dose to water. Thermoluminescence-dosimetry systems (TLD systems) are generally used as routine dosimetry systems.  
1.2 The thermoluminescence dosimeter (TLD) is classified as a type II dosimeter on the basis of the complex effect of influence quantities on the dosimeter response. See ISO/ASTM Practice 52628.  
1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 “Practice for Dosimetry in Radiation Processing” for a TLD system. It is intended to be read in conjunction with ISO/ASTM 52628.  
1.4 This practice covers the use of TLD systems under the following conditions:  
1.4.1 The absorbed-dose range is from 1 Gy to 10 kGy.  
1.4.2 The absorbed-dose rate is between 1 × 10-2 and 1 × 1010 Gy s-1.  
1.4.3 The radiation-energy range for photons and electrons is from 0.1 to 50 MeV.  
1.5 This practice does not cover measurements of absorbed dose in materials subjected to neutron irradiation.  
1.6 This practice does not cover procedures for the use of TLDs for determining absorbed dose in radiation-hardness testing of electronic devices or for clinical dosimetry. Procedures for the use of TLDs for radiation-hardness testing are given in ASTM Practice E668. Procedures for use of TLDs in clinical dosimetry are given in ISO 28057.  
1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.8 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM ISO/ASTM51401-21(Practice)
Standard Practice for Use of a Dichromate Dosimetry System

SIGNIFICANCE AND USE
4.1 The dichromate system provides a reliable means for measuring absorbed dose to water. It is based on a process of reduction of dichromate ions to chromic ions in acidic aqueous solution by ionizing radiation.  
4.2 The dosimeter is a solution containing silver and dichromate ions in perchloric acid in an appropriate container such as a sealed glass ampoule. The solution indicates absorbed dose by a change (decrease) in optical absorbance at a specified wavelength(s) ((3), ICRU Report 80). A calibrated spectrophotometer is used to measure the absorbance.
SCOPE
1.1 This practice covers the preparation, testing, and procedure for using the acidic aqueous silver dichromate dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. For simplicity, the system will be referred to as the dichromate system. The dichromate dosimeter is classified as a type I dosimeter on the basis of the effect of influence quantities. The dichromate system may be used as either a reference standard dosimetry system or a routine dosimetry system.  
1.2 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the dichromate dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628.  
1.3 This practice describes the spectrophotometric analysis procedures for the dichromate system.  
1.4 This practice applies only to gamma radiation, X-radiation/bremsstrahlung, and high energy electrons.  
1.5 This practice applies provided the following conditions are satisfied:  
1.5.1 The absorbed dose range is from 2 × 10 3 to 5 × 104 Gy.  
1.5.2 The absorbed dose rate does not exceed 600 Gy/pulse (12.5 pulses per second), or does not exceed an equivalent dose rate of 7.5 kGy/s from continuous sources (1).2  
1.5.3 For radionuclide gamma sources, the initial photon energy shall be greater than 0.6 MeV. For bremsstrahlung photons, the initial energy of the electrons used to produce the bremsstrahlung photons shall be equal to or greater than 2 MeV. For electron beams, the initial electron energy shall be greater than 8 MeV.  
Note 1: The lower energy limits given are appropriate for a cylindrical dosimeter ampoule of 12 mm diameter. Corrections for displacement effects and dose gradient across the ampoule may be required for electron beams (2). The dichromate system may be used at lower energies by employing thinner (in the beam direction) dosimeter containers (see ICRU Report 35).  
1.5.4 The irradiation temperature of the dosimeter shall be above 0 °C and should be below 80 °C.  
Note 2: The temperature coefficient of dosimeter response is known only in the range of 5 to 50 °C (see 5.2). Use outside this range requires determination of the temperature coefficient.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. Specific precautionary statements are given in 9.3.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM ISO/ASTM51702-13(2021)(Practice)
Standard Practice for Dosimetry in a Gamma Facility for Radiation Processing

SIGNIFICANCE AND USE
4.1 Various products and materials routinely are irradiated at predetermined doses in gamma irradiation facilities to reduce their microbial population or to modify their characteristics. Dosimetry requirements may vary depending upon the irradiation application and end use of the product. Some examples of irradiation applications where dosimetry may be used are:  
4.1.1 Sterilization of medical devices,  
4.1.2 Treatment of food for the purpose of parasite and pathogen control, insect disinfestation, and shelf life extension,  
4.1.3 Disinfection of consumer products,  
4.1.4 Cross-linking or degradation of polymers and elastomers,  
4.1.5 Polymerization of monomers and grafting of monomers onto polymers,  
4.1.6 Enhancement of color in gemstones and other materials,  
4.1.7 Modification of characteristics of semiconductor devices, and  
4.1.8 Research on materials effects.
Note 3: Dosimetry is required for regulated irradiation processes such as sterilization of medical devices and the treatment of food. It may be less important for other industrial processes, for example, polymer modification, which can be evaluated by changes in the physical and chemical properties of the irradiated materials.  
4.2 An irradiation process usually requires a minimum absorbed dose to achieve the intended effect. There also may be a maximum absorbed dose that the product can tolerate and still meet its functional or regulatory specifications. Dosimetry is essential to the irradiation process since it is used to determine both of these limits and to confirm that the product is routinely irradiated within these limits.  
4.3 The absorbed-dose distribution within the product depends on the overall product dimensions and mass, irradiation geometry, and source activity distribution.  
4.4 Before an irradiation facility can be used, it must be qualified to determine its effectiveness in reproducibly delivering known, controllable absorbed doses. This involves testing the pro...
SCOPE
1.1 This practice outlines the installation qualification program for an irradiator and the dosimetric procedures to be followed during operational qualification, performance qualification, and routine processing in facilities that process products with ionizing radiation from radionuclide gamma sources to ensure that product has been treated within a predetermined range of absorbed dose. Other procedures related to operational qualification, performance qualification, and routine processing that may influence absorbed dose in the product are also discussed.
Note 1: Dosimetry is only one component of a total quality assurance program for adherence to good manufacturing practices used in radiation processing applications.
Note 2: ISO/ASTM Practices 51818 and 51649 describe dosimetric procedures for low and high enery electron beam facilities for radiation processing and ISO/ASTM Practice 51608 describes procedures for X-ray (bremsstrahlung) facilities for radiation processing.  
1.2 For the radiation sterilization of health care products, see ISO 11137-1. In those areas covered by ISO 11137-1, that standard takes precedence.  
1.3 This document is one of a set of standards that provides recommendations for properly implementing and utilizing dosimetry in radiation processing. It is intended to be read in conjunction with ASTM Practice E2628.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization...

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