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Year : 2019  |  Volume : 42  |  Issue : 3  |  Page : 68-76  

International Atomic Energy Agency's Analytical Laboratories for the Measurement of Environmental Radioactivity network: Experiences and perspectives in the North and Latin America region

1 Canadian Nuclear Safety Commission, Ottawa, Canada
2 Nuclear and Energy Research Institute, Sai Paulo, Brazil
3 Radiation Protection and Dosimetry Institute, Rio de Janeiro, Brazil
4 National Atomic Energy Commission, Buenos-Aires, Argentina
5 Center for Radiation Protection and Hygiene, Havana, Cuba
6 National Institute for Nuclear Research, Mexico
7 Nuclear Safety and Safeguard Commission, Mexico
8 Research Center for Nuclear, Atomic and Molecular Science, University of Costa Rica, San Jose, Costa Rica
9 Ministry of Industry and Mining, Montevideo -, Uruguay
10 Chilean Nuclear Energy Commission-Chile, Austria
11 International Atomic Energy Agency (IAEA) Seibersdorf laboratories, Austria

Date of Submission15-Jul-2019
Date of Decision03-Aug-2019
Date of Acceptance02-Sep-2019
Date of Web Publication06-Nov-2019

Correspondence Address:
Dr. Said Hamlat
280 Slater Street, P.O. Box 1046, Station B, Ottawa, Ontario K1P 5S9
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Source of Support: None, Conflict of Interest: None

DOI: 10.4103/rpe.RPE_24_19

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The International Atomic Energy Agency (IAEA) Network of Analytical Laboratories for the Measurement of Environmental Radioactivity (ALMERA) is a worldwide network of laboratories capable of providing reliable and timely analysis of radionuclides in environmental samples during normal or accidental/intentional events that result in the release of radioactivity in the environment. ALMERA is coordinated by the Environment Laboratories of the IAEA and organized into five regional groups, including the North and Latin America region (NLAR), led by the Canadian Nuclear Safety Commission. Capacity building in the NLAR for the measurements of environmental radioactivity is achieved through qualitative study that consists of experiences of ALMERA core activities and perspectives of the regional initiatives, respectively. Outcomes' analysis showed that the ALMERA core activities have contributed to the improvements of the analytical capacity and capability, and the regional initiatives assisted in the strengthening of the collaboration and networking, in the NLAR region. The immediate impact of these achievements consisted of gaining technical competence in measuring environmental radioactivity and establishing a network of laboratories. In the long term, sustained efforts between ALMERA and the regional coordination will continue upgrading national and regional competence in the radio analytical services.

Keywords: Analytical Laboratories for the Measurement of Environmental Radioactivity, capacity building, collaboration, environmental radioactivity measurements, networking

How to cite this article:
Hamlat S, Pan P, Ferreira A, Mazzilli B, St-Amant N, Cerutti G, Gómez I M, Ruiz Esparza L J, Ponce E Q, Cubero M, Odino R, Pinones O, Pitois A, Rinker M. International Atomic Energy Agency's Analytical Laboratories for the Measurement of Environmental Radioactivity network: Experiences and perspectives in the North and Latin America region. Radiat Prot Environ 2019;42:68-76

How to cite this URL:
Hamlat S, Pan P, Ferreira A, Mazzilli B, St-Amant N, Cerutti G, Gómez I M, Ruiz Esparza L J, Ponce E Q, Cubero M, Odino R, Pinones O, Pitois A, Rinker M. International Atomic Energy Agency's Analytical Laboratories for the Measurement of Environmental Radioactivity network: Experiences and perspectives in the North and Latin America region. Radiat Prot Environ [serial online] 2019 [cited 2022 Jul 5];42:68-76. Available from: https://www.rpe.org.in/text.asp?2019/42/3/68/270442

  Introduction Top

The North and Latin America region widely uses nuclear applications in the medical, industrial, and research sectors for socioeconomic development including an extractive industry (e.g., mines, oil and gas, phosphate, and minerals), as well as research reactors and/or nuclear power plants. To verify that the health and safety of people and the environment are protected, monitoring programs are developed, implemented, and maintained by national institutions, stakeholders, or regulatory bodies.

The effective implementation of these monitoring programs requires laboratories with adequate capacity and capability to perform radioanalytical analyses with precision, accuracy, and using a variety of internationally validated radioanalytical procedures.

To address this growing need for measurement of radioactivity in environmental samples, a worldwide network of analytical laboratories was formed under the ages of the International Atomic Energy Agency (IAEA). This network was named “Analytical Laboratories for the Measurement of Environmental Radioactivity (ALMERA).” Its main goal is to pool the resources of participating laboratories to provide reliable and timely determination of radionuclides in samples used for both routine and emergency environmental monitoring.[1]

The IAEA supports the ALMERA laboratories in their routine and emergency response environmental monitoring activities by organizing proficiency tests (PTs) and interlaboratory comparison exercises; developing validated analytical procedures for environmental radioactivity measurement; and organizing training courses and workshops (TW). The network also acts as a forum for sharing knowledge and expertise.

As of January 2019, the ALMERA network consists of 180 laboratories representing 90 countries, with membership not limited to one laboratory per country.[2] For example, Europe (93), North and Latin America (16 laboratories), Asia Pacific (34), Middle East (13), and Africa (10).

The IAEA's Environment Laboratories are the central coordinator of the ALMERA network's activities, supported by five regional coordinating laboratories that are appointed for a period of 5 years. These laboratories are designated “as regional groups” and include Africa, Middle East, North and Latin America, Europe, and Asia Pacific [Figure 1].[3]
Figure 1: Analytical Laboratories for the Measurement of Environmental Radioactivity network coordination structure

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The majority of the North and Latin America laboratories (NLAR) joined the ALMERA network at different time periods, and their effective participation varies from country to country.

In 2019, the NLAR consist of 11 countries: Argentina, Brazil, Canada, Chile, Costa Rica, Cuba, Jamaica, Mexico, Peru, Uruguay, and Venezuela, ranging from 1 to 3 laboratories per country [Figure 2].[4]
Figure 2: Analytical Laboratories for the Measurement of Environmental Radioactivity membership in the North and Latin America Region. North America 4: Canada 2, Mexico 2. Central America 1: Costa Rica. Caribbean 3: Cuba 2, Jamaica 1. South America 8: Brazil 3, Peru, Argentina, Chile, Uruguay, Venezuela

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The aim of this paper is to analyze and consolidate experiences and perspectives of the ALMERA core activities and the regional coordination initiatives, respectively.

  Materials and Methods Top

Considerable resources have been invested in recent years to improve laboratory capacity building in the ALMERA network. This qualitative study, focusing on the NLAR region, included two main data sources: experiences of the ALMERA core activities and perspectives of the coordination initiatives.

Experiences: ALMERA core activities

The IAEA helps the ALMERA network of laboratories to maintain their readiness by developing activities, including organization of PTs as a tool for external quality control (QC), development of standardized methods for sample collection and analysis, training and workshops for knowledge transfer and organization of meetings for review achievements, planning activities, and sharing experiences.

Proficiency tests

PTs are organized annually for members of the ALMERA network. Two types of reporting timelines are requested: (a) rapid reporting, within 3 days of sample reception; this reporting concerns gamma-ray-emitting radionuclides and aims to test the rapid response capacity of a laboratory; and (b) normal reporting, within 3–4 months of receipt of the samples (depending on the exercise), for all radionuclides.[5]

These exercises are designed to monitor and demonstrate performance and analytical capabilities of participating laboratories and to identify gaps and problem areas for which further development is required. In this context, two ALMERA PTs are presented in the results and discussion section.


The procedures cover the determination of a large number of radionuclides from natural and anthropogenic origin in a wide range of environmental matrices, for both routine and emergency situations. Such tested and validated analytical procedures are essential tools for the production of reliable and comparable environmental radioactivity measurements.[6]

Training courses and workshops

TW are regularly organized to give laboratory personnel the opportunity to refresh and update their knowledge, expertise, and skills in their relevant work-related areas. The training courses may involve laboratory practical training, field work exercises, and real case studies or lectures, depending on the course content addressed by the training course or workshop. The training courses are tailored to the needs of the ALMERA laboratories.[7]

Coordination meetings

The annual coordination meetings are held to review achievements and establish a future work plan for developing the network's activities. These activities include all ALMERA core activities described above. The meetings also provide a forum for sharing knowledge and expertise within this large network of expert laboratories.[8]

Perspectives: NLAR coordination initiatives

The development of the coordination initiatives resulted from the joint efforts between the regional coordinator and the member laboratories. The approach to seek input from a variety of members consisted of two parts. In the first part, survey questionnaires to assess capacities and capabilities of the laboratories were designed and processed. In the second part, an annual reporting was launched to picture needs and priorities.

  Results and Discussion Top

Experiences: ALMERA core activities

Proficiency tests

[Table 1] lists the IAEA PTs and interlaboratory comparison exercises organized from 2005 to 2018.[5] The PTs consisted of different exercises, including natural and artificial radionuclides in different matrices and samples (e.g., soil, water, vegetation, unprocessed food products, and aerosols). At least one exercise is organized per year by the IAEA for the ALMERA network.

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The design and process of organizing and administering PTs is well described in the IAEA publications.[9] From 2005 to 2018, ALMERA organized and administered 17 PTs. The number of participants ranged from 10 (2005) to 106 (2015), representing 10 and 47 member states, respectively.

The North and Latin America region participation NLAR scores varied from 2 (2005) to 18 (2015–2018). The total participants were 1083 and 177 for ALMERA and NLAR, respectively. The NLAR attendance represents approximately 16% of the total participation. This attendance is significant and comparable to the other regions (with the exception of Europe and Asia pacific) despite the average capacity and capability levels in the region.

[Table 1] provides a list of PTs organized trough ALMERA during the period 2005–2018. For illustration purposes, results and challenges of the two PT exercises focusing on gamma- and alpha-/beta-emitting radionuclides analyses are summarized below.

Test 1 (2006): Determination of gamma-emitting radionuclides in water, soil, and grass

In this PT, 677 results were reported from 38 laboratories belonging to 29 different countries. The members were requested to analyze54 Mn-,60 Co,65 Zn,109 Cd,134 Cs,137 Cs,241 Am, and210 Pb in three matrices: water, soil, and grass. The methodology and the detailed results are presented in an IAEA report.[10] [Table 1]a summarizes the evaluation of the reported results.

Most participants in this PT were able to quantify all the nuclides in the three matrices with acceptable trueness and precision. The overall evaluation showed that 78% of all reported results fulfilled the PT.

The evaluation results demonstrate that the measurement results of40 K,54 Mn,60 Co,65 Zn,134 Cs,137 Cs, and241 Am are acceptable. However, the results for109 Cd and210 Pb in soil and water were not acceptable.

For109 Cd, there was overestimation of the peak area due to unresolved interference around the 88 keV region in a densely populated X-ray region which is dificult to resolve. With respect to210 Pb, results show a significant bias and incomparability between the laboratories. This can be attributed to inappropriate detector calibration in the low energy range and to the overestimation or underestimation of the self-attenuation factor.

Regarding a grass sample, the laboratories showed the lowest performance (only 68% of the laboratories produced an acceptable result) for137 Cs. This can be due to an incorrect calibration for this type of matrix and/or to an incorrect evaluation of the moisture content.

As an indication, the NLAR scores are presented in parentheses in [Table 1]a. The participation is very low and performance is acceptable and comparable to the ALMERA compilation.

Test 2 (2011): Determination of natural and artificial radionuclides in soil and water

Fifty-one of the 57 ALMERA laboratories initially reported their results to IAEA. The PT consisted of three water samples and one soil sample. The participating laboratories were requested to analyze3 H,Co 60,134 Cs,137 Cs, and152 Eu in water and40 K,90 Sr,137 Cs,210 Pb,226 Ra,234 U, and238 U, in soil. The detailed results along with the statistical performance evaluation were compiled and presented in the IAEA report.[11] [Table 1]b summarizes the evaluation of the reported results.

The overall performance evaluation of the 51 reported laboratories showed that 64% was acceptable, 15% was not acceptable, 5% was warning, and 16% was not reported.

The radionuclides requiring chemical processing of the sample are more difficult to handle. This is demonstrated by a relatively wide range of reported results. Thus, the laboratories should pay attention to the analytical work, and the provider should share information about the sample to improve results.

The issues that need improvement in the QC program are related to:

  • The correction of the true coincidence summing effects for the determination of the cascade gamma emitting radionuclides
  • The determination of the low energy gamma-emitting radionuclides.

Another issue is related to the radon-radium equilibrium in the sample, which deals with the sample preparation and the usage of appropriate (radon tight) sample holder, especially if the radon exhalation of the sample is high.

Similar to the test 1, the NLAR scores are indicated in parentheses in [Table 1]b. The performance of the reported results is low to average, and the percentage of not reported results is very high. This could be due to the limited capacity and capability of the major member laboratories at that time. Over the last recent years, the increase of the membership and the number of reported results showed significant performance improvement.


Tested and validated analytical procedures are important tools for the production of reliable, comparable, and “fit for purpose” analytical measurements. However, finding and choosing a procedure can be a challenge due to a wide variety of technologies available and the rapidity of developments in the field. [Table 2] reports the most recent set of procedures for determination of radionuclides in environmental samples, both for routine environmental monitoring and emergency monitoring. The methodology used for development and validation of the ALMERA analytical procedures follows the IAEA publication procedure.[12]
Table 2: Developed and published procedures

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These procedures cover the determination of a large number of radionuclides from natural and anthropogenic origin in a wide range of environmental matrices. They are published as IAEA documents and are available online on the IAEA website as a service to the international community.[6] These documents are also made available to laboratories wishing to use procedures that have been validated by a large number of laboratories and therefore could be regarded as having been widely tested. NLAR showed a great interest in the techniques to their specific routine and emergency analysis.[13],[14] Most of the laboratories in the region are either already using these procedures or are looking for the means to develop them.

Training and workshops

The IAEA workshops and training (TW) courses aim at giving the opportunity to scientists from the ALMERA analytical laboratories to refresh and update their knowledge and skills in areas of interest to members of the ALMERA network. The TW consists of combination of lectures and practical exercises. The TW courses organized over the decade are listed in [Table 3].[7] According to this table, 14 ALMERA training sessions were carried out through combinations of theory and practical exercises in different radioanalytical techniques. The training sessions were conducted in 2 phases: the first was on the basics, including good laboratory practice, safety, quality systems, record keeping, basic laboratory techniques, and manual testing methods. The second phase included instrument operations, maintenance, troubleshooting, and documentation. In addition, training sessions were also conducted to specifically address deficiencies identified during assessments and to introduce instrumentation and quality assurance (QA). [Table 3] shows that 362 member laboratories have been trained, including 25 from NLAR. These trained personnel, in turn, transfer and implement knowledge and good practices, respectively.
Table 3: Training and workshops

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This was highlighted through the surveys and annual reporting.[13],[14] The NLAR participation is satisfactory regardless limited financial support. In the future, the NLAR participation would increase through the implementation of the IAEA technical cooperation activities.

Coordination meetings

The annual coordination meetings of the ALMERA network take place on rotation in different countries within regional network groups. These events aim at assessing the current status of the ALMERA network and at defining the future activities of the network. The annual coordination meetings with associated hosting locations are listed in [Table 4].[8]
Table 4: Coordination meetings

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The meetings review the implementation of the ALMERA activities and define a work plan for the future development of the network's activities.[15]

The 15 coordination meetings took place at different locations in the member states. The attendance at each meeting ranged from 27 to 84 participants, representing 17–50 different laboratories. The meetings were attended by 70 participants from North and Latin America region, representing 8.6% of the total ALMERA participation (813).

The NLAR attendance is low to medium. Similar to the observation in the training component, attendance would improve through the implementation of the technical cooperation activities.

The meetings outcomes are compiled in the meeting minutes that are drafted by the central coordinator for all ALMERA members, and the regional coordinator drafts the summary for NLAR.[15] Both are circulated to the regional members for information and consideration. The implementation of the work plan is monitored by the regional coordinator, which in turn, consolidates a regional report to the central coordinator and regional laboratory members.[14]

Perspectives: NLAR coordination initiatives

The analysis and results of the survey questionnaires, in terms of strengths and weaknesses, of the regional capacity and capability are summarized in [Table 5].
Table 5: Analysis outcomes

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Overall (strengths), the regional laboratory infrastructure ranged from advanced (experienced) to basic capacities and/or capabilities. Furthermore, challenges (weaknesses) were identified in responding to the routine and/or emergency needs nationally and regionally. These include lack of resources in the region, capabilities, and competency in new and/or basic laboratories. To overcome these challenges and take the chance of opportunities, improvement initiatives are being developed.

Collaboration and networking initiatives

Collaboration and networking under NLAR are intended to strengthen the analytical capability of the region and to complement ALMERA core activities. This will be achieved by the establishment of the following collaborative activities that result in IAEA support, sharing of expertise, experience, and analytical capacities and capabilities.

International Atomic Energy Agency technical cooperation

The NLAR region designed a regional project on strengthening quality management and networking in radio analytical laboratories in Latin America and the Caribbean. The project aims to support the development of radio analytical capacity and its application to significant national and regional problems, by developing harmonized capacity and capability in the radio analytical measurements according to ISO/IEC 17025 international standard.[16] The specific needs include (1) quality-assured radioanalytical measurements according to international quality standards, (2) capacity for monitoring and analysis of radionuclides for routine/emergency situations and naturally occurring radioactive material (NORM) industry impacts, (3) other applications of radioanalytical techniques to food, agriculture, and industries, (4) reinforcing regional collaboration and networking for sharing experiences, practices, and expertise and harmonizing regional analytical methodologies. As a result of the project, full upgrading and strengthening of competency and capability in measuring environmental radioactivity at both national and regional levels is expected to be achieved.

Mentorship program

Laboratory-mentoring program is an important vehicle to the new and/or basic laboratories to bring them to the average level in the region. This will focus on the implementation of existing and harmonized ALMERA good laboratory practices and enable scientists to acquire capacity and facilitate the transfer of knowledge from the advanced countries to the countries where the expertise is needed. The development of this program will include well-defined goals, standardized approach across laboratories, and measurement of progress, reporting mechanism and selection of trained mentors. These elements will differ in application, depending on laboratories' needs and available resources. The lessons learned and achieved results in this program, including challenges; best practices and recommendations will be used for improvement and possible extension to the advanced laboratories, if required.

Thematic groups

The thematic group(s) (TGs) can be defined as group of experts able to provide expert services to the region for which the NLAR/ALMERA support may be sought within the context of designated groups. The overall objectives are (a) foster collaboration when conducting new activities within the region; (b) enhancing regional self-reliance; and (c) acting as a body of knowledge in the field, to disseminate innovation and improved practices within the laboratories in the region. This initiative is intended to support the implementation of the regional project work plan, to respond to regional needs and priorities in different areas. The TGs will focus on, for example, evaluation and management of NORM wastes; QA and QC; radiometric analysis (as required). More TGs and subspecific areas can be added to respond to other needs of the NLAR laboratory members. The impact in the region will be monitored and considered for further improvement initiatives and perspectives.

  Conclusions Top

The key concluding remarks from experiences and perspectives of ALMERA in the NLAR are summarized as follows:

  • ALMERA core activities helped the NLAR region to gain knowledge, implement harmonized laboratory practices, and improve QA/QC practices
  • Regional coordination with assistance of member laboratories taking ownership of the regional program design, planning, implementation and monitoring using regional needs, priorities and challenges
  • Cooperation project will strengthen radio analytical capabilities and promote cooperation among the countries for measurement of radionuclides in NORM, environmental and other samples types
  • Collaboration will help build a network of expertise among laboratories, sharing of information and knowledge transfer, and upgrade capacity in the basic and emerging laboratories
  • PT exercises provided the possibility for the members to quantify their levels of analytical performance and a step forward in the improvement of the comparability of results among the network members in the analyses of radionuclides.


The region is grateful for the assistance and technical support provided by the IAEA ALMERA central coordination in Monaco and Seibersdorf and other NLAR members.

Financial support and sponsorship


Conflicts of interest

There are no conflicts of interest.

  References Top

Available from: https://nucleus.iaea.org/rpst/referenceproducts/almera/index.htm. [Last accessed on 2019 Sep 16].  Back to cited text no. 1
Available from: https://nucleus.iaea.org/rpst/referenceproducts/almera/ALMERA_Member_Laboratories/index.htm. [Last accessed on 2019 Sep 16].  Back to cited text no. 2
Available from: https://nucleus.iaea.org/rpst/referenceproducts/almera/ALMERA_Structure/index.htm. [Last accessed on 2019 Sep 16].  Back to cited text no. 3
Available from: https://www. 123rf.com/photo_13288582 _a-map-north-and-south-america.html. [Last accessed on 2019 Sep 16].  Back to cited text no. 4
Available from: https://nucleus.iaea.org/rpst/referenceproducts/almera/ALMERA Proficiency Tests/index.htm. [Last accessed on 2019 Sep 16].  Back to cited text no. 5
Available from: https://nucleus.iaea.org/rpst/referenceproducts/almera/ALMERA_Workshops/index.htm. [Last accessed on 2019 Sep 16].  Back to cited text no. 7
Osvath I, Tarjan S, Pitois A, Groening M, Osborn D. IAEA's ALMERA network: Supporting the quality of environmental radioactivity measurements. Appl Radiat Isot 2016;109:90-5.  Back to cited text no. 9
IAEA-ALMERA Proficiency Test: Determination of gamma-emitting radionuclides. IAEA-AL/170, CU; 2006-04.  Back to cited text no. 10
IAEA-ALMERA Proficiency Test: Determination of Natural and Artificial Radionuclides in Soil and Water. IAEA-TEL/IAEA/AQ/32; 2011-04.  Back to cited text no. 11
Pitois A, Osvath I, Tarjan S, Groening M, Osborn D. Role of the IAEA's ALMERA network in harmonization of analytical procedure applicable worldwide for radiological emergencies. Radiat Prot Environ 2016;39:53-61.  Back to cited text no. 12
  [Full text]  
NLAR/ALMERA. Survey Questionnaires 1 and 2. Internal Reports; September 2014 and October 2017.  Back to cited text no. 13
NLAR/ALMERA. North and Latin America Region. Regional Annual Progress Report; December 2019.  Back to cited text no. 14
Network of Analytical Laboratories for the Measurement of Environmental Radioactivity (ALMERA-IAEA). Minutes of the 14th ALMERA Coordination Meeting. Swedish Radiation Safety Authority. Sweden; 23- 25 October 2017.  Back to cited text no. 15
ISO/IEC 17025. General Requirements for the Competence of Testing and Calibration Laboratories. Available from: http://nbsm.gov.np/uploads/files/ISO_IEC_17025_2017(E)-Character_PDF_document.pdf. [Last accessed on 2019 Sep 16].  Back to cited text no. 16


  [Figure 1], [Figure 2]

  [Table 1], [Table 2], [Table 3], [Table 4], [Table 5]


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