Category: IAEA

Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

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Isotopes, like everything around us, are varieties of atoms – the smallest particles of matter that retain all the chemical properties of an element. Isotopes are forms of the same chemical element that have certain properties.

The periodic table presents various chemical elements.

Each element differs from another in the number of protons, neutrons and electrons in its composition. Each chemical element's atom contains a certain number of protons and electrons, but the number of neutrons – which is important – can vary.

Atoms with the same number of protons and different numbers of neutrons are called isotopes. They have almost the same chemical properties, but differ in mass, and therefore in physical properties.

There are stable isotopes, which are not radioactive, and unstable isotopes, which, on the contrary, emit radiationThe latter are called radioisotopes.

Read more about isotopes Here.

Please note: This information is raw content obtained directly from the source of the information. It is an accurate report of what the source claims and does not necessarily reflect the position of MIL-OSI or its clients.

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

With the support of the IAEA, specialists from nine countries in Southern and Eastern Europe were trained application of the deuterium dilution method to assess body composition. (Photo: IAEA)

Deuterium can be used in research to improve the assessment of diet quality; to understand whether weight gain (or loss) is due to fat or muscle; whether breastfeeding campaigns are effective; and whether certain population groups are at risk of high vitamin A intake. This information allows health professionals to adjust existing nutrition programs and interventions or develop new, more effective ones.

To assess body composition and determine the proportion of fat in a person's body mass, the deuterium label dilution method is used. Water in the human body contains a natural amount of deuterium. By drinking a small amount of deuterium oxide – water labeled with deuterium – you can measure the concentration of deuterium in saliva or urine and determine the ratio of fat to lean tissue in the body. You can find out more about how this method works at this link.

Deuterium can also be used to estimate the amount of breast milk consumed and to determine whether a baby is being fully breastfed. of this article You can learn more about how the maternal deuterium oxide method works.

In addition, vitamin A can also be labeled with deuterium, which allows for precise determine its content in the human body.

Please note: This information is raw content obtained directly from the source of the information. It is an accurate report of what the source claims and does not necessarily reflect the position of MIL-OSI or its clients.

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

Members of the Rhisotope Project tag rhinoceros horns with radioactive isotopes. Martin Klinenböck/IAEA

With support from the International Atomic Energy Agency (IAEA), a South African university has launched a pioneering project to combat the illegal wildlife trade in endangered rhinos. The project uses existing nuclear security infrastructure to safely inject radioactive isotopes into rhino horns to prevent and detect poaching.

With more than 10,000 rhinos killed by poaching in the last decade, South Africa – home to the world’s largest rhino population – remains an attractive destination for criminals involved in the illegal trade in rhino horn. In the first quarter of 2025 alone, the South African Department of Environment, Forestry and Fisheries reported 103 incidents of rhino poaching. To support conservation and law enforcement efforts, the University of the Witwatersrand has turned to radiation for this project.

In 2021, after two years of initial testing, Project Nosotope began to be implemented, tagging rhino horns with radioactive material. This makes the horns detectable by radiation portal monitors (RPMs) already installed at border crossings, seaports and airports around the world. These RPMs, which are typically used to detect nuclear and other radioactive material, can now be used to combat wildlife crime.

The IAEA’s support for the Nosotope project is part of the Agency’s critical work to strengthen global nuclear security. With millions of people and vehicles crossing borders every day, the use of RPMs – some 10,000 devices worldwide – has become a key tool for detecting unauthorized cross-border movement of nuclear and other radioactive material.

“Project Nosotope is an example of how nuclear science and nuclear security infrastructure can be used in innovative ways to address global challenges,” said IAEA Director General Rafael Mariano Grossi. “The IAEA helps countries get the most out of nuclear technology. By using existing nuclear security infrastructure in innovative ways, we can help protect one of the world’s most iconic animals, which is on the brink of extinction.”

Last week, at an event at the Waterberg Biosphere Reserve in Limpopo Province, about 250 kilometres north of Johannesburg, the University of the Witwatersrand announced the results of a thorough safety assessment of the pilot phase of the project. Radioisotopes were injected into 20 rhinos last June. Ghent University, Belgium, compared health monitoring and cytology results in a group of 15 tagged animals with a group of five rhinos that were not injected. The tests showed that the method was non-invasive and posed no risk to the rhinos’ health.

“This is an international group of like-minded people trying to make a real difference to the poaching crisis,” explains James Larkin, director of the Radiation and Medical Physics Unit at the University of the Witwatersrand. “We started by asking: what if radiation could protect rather than harm? What if rhino horns could be tagged so they could be tracked, and thus preventative action taken against illegal trade? After two years of digital modelling, safety testing and detection simulations, we are now ready to begin implementing the technology to actually protect rhinos from poachers.”

Furthermore, the success of the project opens up the possibility of using this method in the future on other endangered species.

"The technique could be adapted to protect other endangered species, such as elephants or pangolins," Larkin said.

The IAEA provides technical and financial support for these efforts through its coordinated research project "Promoting Trade Safety and Security Using Nuclear Material Detection Technologies – Detecting Contraband of Radioactive, Nuclear and Other Materials"In addition, as part of this work, the Agency assists countries in their efforts to optimize radiation detection through its minimum detectable quantity and alarm thresholds tool, which enables the detection of isotopically labeled rhino horns.

“Project Nosotope leverages the entire global nuclear security network,” said Elena Buglova, Director of the IAEA’s Division of Nuclear Security. “The nuclear security infrastructure that exists in many countries around the world to detect smuggling of nuclear and other radioactive material can be used to detect trafficking in rhino horn and any other contraband that may be transported with it. Commitment to nuclear security pays off in many ways.”

The original video footage and photographs can be viewed Here.

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

Of the 190 States in which the IAEA applied safeguards in 2024, 182 had CSAs in force, of which 137 also had APs in force. For 75 of these 137 States, the IAEA concluded that “all nuclear material in these States continues to be used in peaceful activities”. In addition, the Agency was able to make this conclusion, also known as an “expanded conclusion”, for the first time, for Morocco. For 61 States, the IAEA could only conclude that declared nuclear material continues to be used in peaceful activities in these States, as the assessment to ensure that each State does not contain undeclared nuclear material and activities is ongoing.

For 31 States with CSAs in place but no APs in place, the IAEA was able to conclude that the declared nuclear material remains in peaceful activities.

As of the end of 2024, three non-nuclear-weapon States party to the Treaty on the Non-Proliferation of Nuclear Weapons (NPT) have not yet brought into force a CSA in accordance with Article III of that Treaty. For these States, the IAEA has been unable to make any safeguards conclusions.

For three States in which the IAEA implemented safeguards under item-specific safeguards agreements (Israel, India and Pakistan), the Agency concluded that “in these States, nuclear material, facilities or other items to which safeguards were applied continue to be used in peaceful activities.”

Safeguards were also applied to five NPT nuclear-weapon States that had voluntary offer safeguards agreements in force. For these five States (China, France, the Russian Federation, the United Kingdom and the United States), the IAEA concluded that “at selected facilities in these States, nuclear material to which safeguards were applied remains in peaceful activities or has been removed from safeguards as provided for in the agreements.”

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

TIC2026 will bring together nuclear safety regulators, plant designers and operators, technical support organisations and other stakeholders from various countries, as well as international organisations. The aim is to increase knowledge on key topics related to the safety of nuclear installation design, safety assessment, siting, construction, operation and regulation of both existing and new nuclear installations.

According to the boss IAEA Safety Assessment Sections Ana Gomes, “The Conference will provide a comprehensive forum where nuclear safety stakeholders representing different generations of nuclear projects and a wide range of nuclear safety areas will be able to address a wide range of nuclear safety issues, making it a truly inclusive event.”

Please note: This information is raw content obtained directly from the source of the information. It is an accurate report of what the source claims and does not necessarily reflect the position of MIL-OSI or its clients.

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

Those wishing to submit abstracts of their papers for the conference are advised to pay attention to the following topics.

— Regulatory competence. Key competencies required for regulators to operate effectively, with a particular focus on regulatory culture and human resource development.

— Regulatory flexibility. Strategies and approaches by regulatory bodies to increase flexibility and effectively respond to and anticipate changes brought about by innovation and new technologies.

— Strengthening the links. The role of regulators in strengthening the links within their “ecosystems” to create enabling conditions and promote the sustainable use of nuclear and radiation technologies.

“The participants’ input will be key to advancing the discussion among nuclear and radiation safety regulators to analyse, identify and propose solutions to critical regulatory issues,” said Jiang Fuming, Director of the IAEA Office of Safety and Security Coordination. “Participants will have the opportunity to directly interact with representatives of the global regulatory community.”

Abstracts of up to 600 words should be submitted electronically via the IAEA web-based submission system (IAEA-indico). The procedure for submitting abstracts can be found at website conferences.

Please note: This information is raw content obtained directly from the source of the information. It is an accurate report of what the source claims and does not necessarily reflect the position of MIL-OSI or its clients.

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Translation. Region: Russian Federal

Source: International Atomic Energy Agency –

An important disclaimer is at the bottom of this article.

A new IAEA research project is investigating the nutritional impact of radiation therapy on cancer patients. Photo: Shutterstock

IAEA launchesnew five-year coordinated research projectto improve nutritional quality and clinical outcomes in patients undergoing radiation therapy. If this project can provide insight into how radiation therapy affects body composition and clinical outcomes, it will help guide cancer centers in implementing palliative care programs.

Research shows that 20-40 percent of cancer deaths are caused not so much by the cancer itself as by poor nutrition, so addressing nutritional issues will be critical to increasing survival.

Cancer remains a major global health problem, accounting for nearly 17 percent of deaths worldwide. It is a particularly pressing issue for people living in low- and middle-income countries (LMICs), who often have limited or no access to radiotherapy, a common treatment for many cancers.

To ensure that cancer care reaches those who need it most, the IAEA launched an initiative in 2022 "Rays of Hope"However, despite the potential effectiveness of radiation therapy, when treating some types of tumors it can lead to changes in body composition – this is the ratio of fat, muscle, bone and other tissues in the body – in particular muscle mass.

“Recent data, mainly from high-income countries, indicate that radiotherapy-induced changes in body composition lead to adverse clinical outcomes, including increased toxicity, treatment interruption and decreased survival,” says Timoaki Tamaki, Head of the IAEA’s Applied Radiobiology and Radiotherapy Section, Department of Human Health.

“It is noteworthy that only limited data are available from low- and middle-income countries, where cancer patients often face additional barriers to care and experience poorer treatment outcomes,” said Cornelia Loechl, Head of the Health-Related Nutrition and Environment Research Section, Division of Human Health, IAEA. “Raising awareness and promoting a better understanding of the proven clinical and economic benefits is essential to ensure continued investment in cancer nutrition.”

A new coordinated research project (CRP) will provide contextually relevant evidence to support nutrition considerations in cancer care. Specific research objectives include:

To assess the effects of radiation therapy on body composition and energy expenditure using nuclear techniques used in nutritional research; To study the etiologic factors associated with changes in body composition in patients undergoing radiation therapy; To investigate the effects of body composition on clinical, functional, and self-reported health outcomes in patients undergoing radiation therapy; To determine the efficacy and feasibility of assessing body composition to detect loss of muscle mass and strength (sarcopenia) in patients undergoing radiation therapy.

How to participate in this PKI

This CRP is open to all member countries. Research contracts will be awarded to LMICs, while high-income countries will be able to enter into research agreements. Participating institutions must meet the criteria specified in the Other Resources section.

Research institutes interested in participating in this CRP should submit their proposal for a research contract or agreement by email toIAEA Research Contracts Sectionno later than July 31, 2025, using the appropriate form at web portal DKI. The same form can be used for both a research and a technical contract. The IAEA encourages institutes to involve women and young professionals in their proposals to the extent possible.

For further information related to this CRP, potential candidates should use the feedback form on the pagePKI.

Please note: This information is raw content obtained directly from the source of the information. It is an accurate report of what the source claims and does not necessarily reflect the position of MIL-OSI or its clients.

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