ECRR 2006.Chernobyl: 20 Years On

Publications Chernobyl: 20 Years On

ECRR 2006

NEW PUBLICATION REVEALS TRUE CONSEQUENCES OF RADIOACTIVE EXPOSURES

The Chernobyl accident contaminated large parts of the

Soviet Union and Europe. Radioactivity was ultimately

detected everywhere in the northern hemisphere. Doses to

the emergency workers from external gamma-rays and

internal fission-product radionuclides were significantly

high, many died at the time. 20 years later, many

liquidators still die and all are ill. The radionuclide

contamination of the environment was significant and

long-lasting. This resulted in chronic internal low dose

exposure to millions of people, to animals and plants.

Foodstuffs became contaminated with Caesium-137,

Strontium-90 and uranium fuel particles containing a range

of novel radioactive elements.

Rather than use this opportunity to investigate the health effects of these exposures, the international radiation risk community has

ignored the many reports of ill-health emerging from the contaminated territories. International and National bodies (e.g. ICRP,

UNSCEAR, BEIR, WHO), whose remit is the evaluation of ionising radiationeffects on health, have glossed over, marginalized,

ignored or denied the existence of the terrible consequences of the Chernobyl fallout. Research papers have been excluded from official

reports. Cries for help have been dismissed asdue to ‘Radiophobia’. Research into these effects has been mainly published in Russian

language journals; these valuable contributions have (perhaps purposely) rarely been translated into English. To do so would have been

fatal to the nuclear industry, which routinely discharges the same radioactive substances into the environment under license. This new

ECRR publication presents the true consequences of the Chernobyl accident. Eminent scientists examine and review the data and show

that, rather than fading away, the effects are only beginning to show themselves. The phenomenon of ‘genomic instability’, discovered

in the laboratory in the UK in the 1990s, is seen now in its terrible effects on the animals, plants and human victims of the Chernobyl

exposures. It is seen at doses that would have been, and still are, dismissed as vanishingly small by the current radiation protection laws.

Here are data from the real world: the world of the Chernobyl laboratory. The lessons contained in these chapters should be borne in mind

by policy makers who are, even now, discussing new investments in nuclear energy and ways in which historic and future radionuclide

waste can be disposed of into the environment. The committee recommends this book to scientists, policymakers and concerned members

of the public, in the hope that the huge amount of work carried out by scientists publishing their results in Russian language journals and

others studying the effects of the Chernobyl accident will influence their decisions in this important area of public health.

CONTENTS

1. Alexey V. Yablokov

Russian Academy of Sciences, and Centre for Russian Ecological Policy, Moscow

The Chernobyl Catastrophe - 20 Years After (43 pages, 33 tables, 1 diagram 191 Refs)

2. E.B. Burlakova and A.G Nazarov

Emanuel Institute of Biochemical Physics, Russian Academy of Sciences , Moscow and “Union of Chernobyl” Moscow committee

Is it Safe to Live in Territories Contaminated with Radioactivity? Consequences of the Chernobyl Accident 20 Years Later (11 pages, 4 tables,

23 Refs)

3. Konstantin N. Loganovsky

Department of Radiation Psychoneurology, Institute for Clinical Radiology, Research Centre for Radiation Medicine, Academy of Medical Sciences

of Ukraine

Mental, Psychological and Central Nervous System Effects of the Chernobyl Accident Exposures (28 pages 163 refs)

4. Eugene Yu. Krysanov,

Institute of Ecology and Evolution, Russian Academy of Sciences

The Influence of the Chernobyl Accident on Wild Vertebrate Animals. (6 pages 28 refs)

5. G.P.Snigiryova and V.A.Shevchenko

Federal State Institution Russian Scientific Centre of Roentgenology & Radiology Roszdrav and Vavilov Institute of General Genetics, Moscow, Russia

Chromosome Aberrations in the Blood Lymphocytes of People Exposed as a Result of the Chernobyl Accident (10 pages 3 tables 22 refs)

6. Inge Schmitz-Feuerhake

Chair, ECRR, Department of Physics, University of Bremen, Germany

Teratogenic Effects After Chernobyl (11pages 6 tables 65 refs)

7. D.M.Grodzinsky

General Secretary, Division of Biology, Ukrainian National Academy of Sciences

Reflections of the Chernobyl Catastrophe on the Plant World: Special and General Biological Aspects (8 pages 10 tables 9 figures 11 refs)

8. Chris Busby

Scientific Secretary, ECRR, University of Liverpool and Green Audit, Aberystwyth, UK

Infant Leukaemia in Europe After Chernobyl and its Significance for Radioprotection; a Meta-Analysis of Three Countries Including New

Data from the UK. (7 pages 7 tables, 1 fig 15 refs)

9. Alexey V. Yablokov.

Institute of Ecology and Evolution, Russian Academy of Sciences

The Health of the Chernobyl Liquidators- a Metaanalysis (25 pages 17 tables 124 refs)

10 Tetsuji Imanaka

Research Reactor Institute, Kyoto University, Japan

Did Acute Radiation Syndrome Occur Among the Inhabitants of the 30 km Zone? (9 pages 2 tables 4 figs 19 refs)

11 Helmut Küchenhoff, Astrid Engelhardt, Alfred Körblein

Combined Spatial-temporal Analysis of Malformation Rates in Bavaria After the Chernobyl Accident (9 pages 3 figs 8 refs)

12. V.B. Nesterenko and A.V. Nesterenko

Institute ‘Belrad’ and Belarus Academy of Sciences

Radioecological Effects in Belarus 20 Years After the Chernobyl Catastrophe: The Need for Long-term Radiation Protection of the Population

(37 pages 3 tables 24coloured maps/ figures 21 refs)

13. Alfred Koerblein

Studies of Pregnancy Outcome Following the Chernobyl Accident (17 pages 1 table 16 figs 29 refs)

14. Rosalie Bertell

The Death Toll of the Chernobyl Accident

“In 20 years it has become clear that not tens, hundreds or thousands, but millions of people in the Northern hemisphere have suffered and will suffer from the Chernobyl catastrophe...Official secrecy (until May 23rd, 1989) and irreversible state falsification of medical data during the first three years after the catastrophe, as well as an absence of authentic medical statistics in the former USSR, highlights the inadequacy of material concerning primary epidemiological consequences of this catastrophe...

...The … average age of 162 liquidators who died during last 10 years in the town of Tollyaty (Samarskaya province, Russia) was about 46.2 years old (Tymonin, 2005). The average lifespan for 169 liquidators from nuclear industry institutes who died between 1986 – 1990 was 45.5 years (Tukov et al., 2000). In the Kaluga province - National register data, - the average age of death for 84.7 % of liquidators was only 30 - 39 years old (Lushnykov and Lantzov, 1999)... A.V. Yablokov

“The dose dependence of the radiation effect may be non-linear, non-monotonic and polymodal in character...Over certain dose ranges, low-level irradiation is more effective with regard to the results of its action on an organism or a population than acute high-level radiation...

...Radiation-induced changes in the population structure result in an unpredictable response of the population to various events. In the work by A.P. Akif'ev et al. [12], an apparently healthy population of the posterity of exposed Drosophila exhibited a so-called ‘populational breakdown’ in one of its generations and was ruined by a law other than that for other generations. In the work by I.I. Pelevina et al. [13], it was shown that 15 generations of cells irradiated with the doses 10 to 50 cGy "remember" the irradiation and respond to external stimuli differently than the control...

....The results of surveys and biological monitoring of children and adults of Chernobyl point unambiguously to a steady, rapid and dramatic (for an individual human life) deterioration of health of all victims of the radiation impact of the Chernobyl accident...” E.B. Burlakova & A.G. Nazarov

“According to a wide range of scientific data reviewed, the following hypotheses can be proposed: 1) exposure to low-dose ionizing radiation is a risk factor for accelerated aging processes and neurodegeneration; 2) aging and neurodegeneration processes after exposure to ionizing radiation could be enhanced by the synergetic influence of heterogeneous pathogenetic factors, such as immunological, oxidative stress and molecular-genetic changes.” K.N. Loganovsky

“The detected cytogenetic effects of chronic low-intensive irradiation in the germ and somatic cells of wild animals exceeded the expected levels deduced from extrapolation of the data from the high-dose range of acute or chronic irradiation. In wild murine rodents increased frequencies of cytogenetic injuries in somatic and germ cells, as well as embryonal lethality, were shown to remain over the life spans of no less than 22 generations (Goncharova & Ryabokon, 1998)...” E. Yu. Krysanov

“In addition, a view of the radiobiological processes induced in plants by chronic irradiation should elucidate the main tendencies in the formation of late effects of irradiation. As this takes place we bear in mind that these late effects in plants could not be related to ‘radio-phobia’, as it is called, as there is a tendency to assign the cause of injuries observed after the Chernobyl catastrophe merely to a fear of irradiation. We have seen, since the accident, clear and diverse effects of irradiation in plants over time...

...It appears that there are two adaptive strategies to stress impacts in plants, namely; ontogenetic and population or phylogenetic adaptation. The first type of adaptive strategy is revealed by radioadaptation and resides in an augmentation of radioresistance after irradiation in low doses. The second type of adaptive strategy lies in an increase in frequency of genetic diversification, which enlarges the possibilities for active natural selection...” D.M. Grodzinsky

“Using new infant leukaemia data from the UK supplied by the Childhood cancer research Group, Oxford, it is possible to combine the populations of Germany, Greece and the UK and carry out a meta analysis of infant leukaemia in those children who were in the womb at the time of the fallout. Using published exposure doses to the foetus the infant leukaemia yield in Europe is more than 160 times higher than that predicted on the basis of the external irradiation yields found by the obstetric X-ray data studies. This means that the ICRP risk model is in error here by a factor of at least 160. The dose response is biphasic...” C. Busby

“Clearly, the true damage to health attributable to the Chernobyl disaster has been kept from the general public through poor and incomplete scientific investigation...” R. Bertell

The European Committee on Radiation Risk (Comité Européen sur le Risque de l’Irradiation)

The European Committee on Radiation Risk was formed in 1997 following a resolution made at a conference in Brussels arranged by the Green Group in the European Parliament.

The ECRR's remit is:

• To independently estimate, based on its own evaluation of all scientific sources, in as much detail as necessary and using the most appropriate

scientific framework, all of the risks arising from exposure to radiation, taking a precautionary approach.

• To develop the best scientific predictive model of detriment following exposure to radiation,

presenting observations which appear to support or challenge this model, and highlighting areas of research which are needed to further complete

the picture.

• To develop an ethical analysis and philosophical framework to form the basis of its policy recommendations, related to the state of scientific

knowledge, lived experience and the Precautionary Principle.

• To present the risks and the detriment model, with the supporting analysis, in a manner to enable and assist transparent policy decisions to be

made on radiation protection of the public and the wider environment.

The Committee now has more than 50 experts from many countries collaborating on the issue of radiation risk and has set up a number of

sub-committees and groups. The Committee’s risk model was presented in 2003 in Brussels and is published as the ECRR2003 Recommendations:

the Health Effects of Ionising Radiation Exposure at Low Dose for Radiation Protection Purposes: Regulators' Edition (ISBN 1897761 24 4).

The report, now in its second printing, has been widely circulated. It is published in French, Russian, Spanish and Japanese. The price of the

English edition is £45 with a concession price of £15 for students/ NGOs. It is available by order from any bookseller or direct by emailing an

order to admin@euradcom.org or from the publishers, Green Audit, at the address below.

The Committee wishes to emphasise that the health phenomena described in the Chernobyl sub-Committee's present work are predicted

and explained by the radiation risk model put forward in the ECRR2003 Recommendations. This is in marked contrast to the dissonance between

the predictions of the International Commission on Radiological Protection and the levels of disease widely observed since the catastrophe.

ECRR 2006. Chernobyl: 20 Years On

ECRR Chernobyl 20 Years On: Health Effects of the Chernobyl Accident
European Committee on Radiation Risk
Documents of the ECRR 2006 No1
Edited by C.C.Busby and A.V. Yablokov
Published on behalf of the European Committee on Radiation Risk
Comité Européen sur le Risque de l’Irradiation, Brussels
by Green Audit, 2006.

A major contribution, containing the results of three years' research by the Chernobyl sub-Committee of the ECRR.

ISBN: 1-897761-25-2

In view of the disinformation about the effects of the Chernobyl disaster which are being disseminated by various official bodies, the Committee wishes to make this information available to the widest possible readership.

The entire book is now a free download: a 4Mb pdf. Click here ADD HYPERLINKs
information on PDFs

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