If one person drank every drop of tritium water that leaked from Vermont Yankee...

Comment: Let's take cancer clusters seriously this time

* 26 April 2008 by Ian Fairlie
* Magazine issue 2653. Subscribe and get 4 free issues.

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Studies in the 1980s revealed increased incidences of childhood leukaemia near nuclear installations at Windscale (now Sellafield), Burghfield and Dounreay in the UK. Later studies near German nuclear facilities found a similar effect. The official response was that the radiation doses from the nearby plants were too low to explain the increased leukaemia. The Committee on Medical Aspects of Radiation in the Environment, which is responsible for advising the UK government, finally concluded that the explanation remained unknown but was not likely to be radiation.

There the issue rested, until a recent flurry of epidemiological studies appeared. Last year, researchers at the Medical University of South Carolina in Charleston carried out a meta-analysis of 17 research papers covering 136 nuclear sites in the UK, Canada, France, the US, Germany, Japan and Spain. The incidence of leukaemia in children under 9 living close to the sites showed an increase of 14 to 21 per cent, while death rates from the disease were raised by 5 to 24 per cent, depending on their proximity to the nuclear facilities (European Journal of Cancer Care, vol 16, p 355).

This was followed by a German study which found 14 cases of leukaemia compared to an expected four cases between 1990 and 2005 in children living within 5 kilometres of the Krümmel nuclear plant near Hamburg, making it the largest leukaemia cluster near a nuclear power plant anywhere in the world (Environmental Health Perspectives, vol 115, p 941).

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If radiation is indeed the cause of the cancers, how might local residents have been exposed? Most of the reactors in the KiKK study were pressurised water designs notable for their high emissions of tritium, the radioactive isotope of hydrogen. Last year, the UK government published http://www.hpa.org.uk/webc/HPAwebFile/HPAweb_C/1197382221858">a report on tritium which concluded that its hazard risk should be doubled. Tritium is most commonly found incorporated into water molecules, a factor not fully taken into account in the report, so this could make it even more hazardous.

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Tritium Hazard Report: Pollution and Radiation Risk from Canadian Nuclear Facilities

12 June 2007

The report concludes that official attitudes on tritium are unscientific and incorrect, that tritium’s hazardous nature should be fully acknowledged by radiation protection agencies in Canada, and that tritium’s dose coefficient should be increased substantially.

This report on tritium releases in Canada is in two parts. Part 1 discusses tritium discharges from nuclear facilities in Canada and compares them with those from reactors in other countries. It examines the resulting tritium concentrations in drinking water, air and in food near Canadian nuclear stations. Although tritium releases from Candu facilities are very large, radiation protection regulators continue to maintain that these releases are of little concern because tritium’s radiation doses and its resulting hazards are small. Part 2 examines these contentions in considerable detail. It shows that tritium’s radiation “doses” are, questionably, estimated to be several hundreds of times lower than most other radioactive elements. Radiation and radioactivity (including risks, doses, biology and epidemiology) are complex matters which are often difficult to grasp. Therefore Part 2 is designed to be read primarily by health physicists and radiation protection scientists. However, efforts have been made to make this report more accessible to the wider public. In particular, technical terms have been explained and scientific jargon has been avoided. The report concludes that official attitudes on tritium are unscientific and incorrect, that tritium’s hazardous nature should be fully acknowledged by radiation protection agencies in Canada, and that tritium’s dose coefficient should be increased substantially

http://www.greenpeace.org/raw/content/canada/en/documents-and-links/publications/tritium-hazard-report-pollu.pdf">Download Document

Background information on the KiKK study

Why carry out a new study?

The discussion about increased cancer rates in the vicinity of nuclear power plants has continued since the use of nuclear energy has been considered to be a problematic issue. For instance, in 1987 and 1989 British studies reported a statistically significant increase of childhood leukaemia within a radius of 10 miles around nuclear facilities in England and Wales. In 1992, an analogously performed ecological study of the German Childhood Cancer Registry (GCCR) for the period from 1980 to 1990 observed a statistically significant increased incidence rate for leukaemias among children below five years of age within the 5-km-zone around the sites.

Since these results were discussed very controversially and since at the same time a statistically significant increase in leukaemias occurred in the vicinity of the Krümmel nuclear power plant, a second ecological study was published in 1997. This study was again carried out by the GCCR, and it included data for the subsequent period of five years, i. e. from 1991 – 1995.

The discussion about a possible link between the occurrence of cancer in children and their residence in the vicinity of nuclear facilities in normal operation did not stop after the second study had been published. Moreover, the data of the GCCR were exploratively evaluated by other working groups.

The results of the GCCR studies and their re-evaluation by third parties were debated in the public and in the media. The question was if these results were chance findings or if their interpretation was governed by political motivation.

In 2001, upon invitation of the President of the Federal Office for Radiation Protection, Wolfram König, a „Round Table“ with various groups took place in Kassel. Here BfS decided to commission a study on the basis of these findings, although the study was to be methodically more ambitious. In order to gain more reliable results a so-called case-control-study was developed. This so-called KiKK-study (Kinderkrebs in der Umgebung von Kernkraftwerken – Childhood Cancer in the Vicinity of Nuclear Power Plants) started in 2003. The study design was developed by a multidisciplinary panel of experts consisting of 12 members. BfS acted on that suggestion and, following an invitation to tender, charged the German Childhood Cancer Registry (GCCR) in Mainz with the implementation of this study. After four years of research and altogether five meetings of the panel of experts, the GCCR submitted the final report in November 2007. At the same time, two scientific publications concerning the study will be published in mid-December.

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Monday, January 25, 2010

Yankee Swap: tritium contaminated water anyone?

First published in the Montague Reporter

First we hear about tens of thousands of picocuries* in the groundwater beneath http://www.burlingtonfreepress.com/article/20100116/NEWS02/1160313/Search-on-for-Vermont-Yankee-tritium-leak">Vermont Yankee Nuclear Power plant, next it’s over one hundred gallons of water contaminated with over 2 million picocuries in some sort of concrete trench. Oops. Besides sloppy practices, lax monitoring, shoddy construction, and obfuscation (what underground pipes?) what do these numbers mean? Should we worry about all that tritium? And what the heck is a picocurie anyway?

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Tritiated water is particularly insidious. The tritiated water lurking below Vermont Yankee for example, could be absorbed by the root systems of nearby plants, or imbibed by unsuspecting animals. Once consumed, distributes rapidly throughout the body of plant or animal. Additionally, ingestion of tritiated water, can lead to incorporation of tritium into organic materials like DNA, proteins and amino acids. Only, unlike hydrogen, tritium will eventually decay, leaving behind an atom of helium and releasing a beta particle with enough energy to break nearby chemical bonds.

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The human genome is contained within the DNA of our 46 chromosomes located in a cell’s nucleus. Replication of these chromosomes during cell division is a critical process, requiring a number of complex biochemical interactions including copying and construction of identical chromosomal pairs that are then split off into the newly divided cell. Because integrity of the genetic material is essential to life, not only are there biochemical systems involved in maintaining chromosomes during division, but there are also a number of mechanisms by which errors may be repaired.

Say a few molecules of tritium enter the cell and cozy up to nuclear DNA. At some point in their unstable life-time they will disintegrate, releasing their energized electrons. Should the cells’ chromosomes be in their pathway, the transfer of energy from electron to chromosome may be enough to break off a bit of chromosome. Sometimes, depending on conditions within the cell and location of the break, the broken pieces may rejoin the chromosome, leaving little or no evidence of damage; other times a broken piece remains separate, becoming a chromosomal deletion; or both the deleted piece and the damaged chromosome will be copied as if nothing happened, only it will be altered. Or, instead of direct interference with DNA, emitted electrons may interact with other molecules such as oxygen, causing “indirect” damage by creating highly reactive oxygen radicals.

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According to the National Council on Radiation Protection and Measurements (NCRP), the average radioactivity per short ton of coal is 17,100 millicuries/4,000,000 tons, or 0.00427 millicuries/ton. This figure can be used to calculate the average expected radioactivity release from coal combustion. For 1982 the total release of radioactivity from 154 typical coal plants in the United States was, therefore, 2,630,230 millicuries.

A retrospective view of the Chernobyl accident of Apr 26, 1986 assesses the total radiation release at about 100 megaCuries or 4 x 1018 becquerels, including some 2.5 MCi of cesium-137. The cesium is the most serious release in terms of long term consequences. The total release was around 4% of the total accumulated activity of the core and compares to a release of 15 Ci at Three Mile Island. The release was then about 7 million times that at TMI. Anspaugh, et al. suggest that essentially all the noble gases and about half of the volatile elements (iodine-131, cesium-134 and cesium-137) were released . The cesium release from all of the atmospheric weapons tests is estimated to be about 30 MCi. The noble gas releases were estimated by Levi to be 45 MCi of xenon-133 and 5 MCi of krypton-85. About 3-5% of the core inventory of the relatively refractory elements such a strontium, plutonium, and ruthenium were released, much more than from a light water reactor meltdown.

Thus, by combining U.S. coal combustion from 1937 (440 million tons) through 1987 (661 million tons) with an estimated total in the year 2040 (2516 million tons), the total expected U.S. radioactivity release to the environment by 2040 can be determined. That total comes from the expected combustion of 111,716 million tons of coal with the release of 477,027,320 millicuries in the United States. Global releases of radioactivity from the predicted combustion of 637,409 million tons of coal would be 2,721,736,430 millicuries.

Annals of the New York Academy of Sciences
Volume 1181 Issue Chernobyl
Consequences of the Catastrophe for People and the Environment, Pages 31 - 220

Chapter II. Consequences of the Chernobyl Catastrophe for Public Health

Alexey B. Nesterenko a , Vassily B. Nesterenko a ,† and Alexey V. Yablokov b
a
Institute of Radiation Safety (BELRAD), Minsk, Belarus b Russian Academy of Sciences, Moscow, Russia
Address for correspondence: Alexey V. Yablokov, Russian Academy of Sciences, Leninsky Prospect 33, Office 319, 119071 Moscow,
Russia. Voice: +7-495-952-80-19; fax: +7-495-952-80-19. Yablokov@ecopolicy.ru
†Deceased


ABSTRACT

Problems complicating a full assessment of the effects from Chernobyl included official secrecy and falsification of medical records by the USSR for the first 3.5 years after the catastrophe and the lack of reliable medical statistics in Ukraine, Belarus, and Russia. Official data concerning the thousands of cleanup workers (Chernobyl liquidators) who worked to control the emissions are especially difficult to reconstruct. Using criteria demanded by the International Atomic Energy Agency (IAEA), the World Health Organization (WHO), and the United Nations Scientific Committee on the Effects of Atomic Radiation (UNSCEAR) resulted in marked underestimates of the number of fatalities and the extent and degree of sickness among those exposed to radioactive fallout from Chernobyl. Data on exposures were absent or grossly inadequate, while mounting indications of adverse effects became more and more apparent. Using objective information collected by scientists in the affected areas—comparisons of morbidity and mortality in territories characterized by identical physiography, demography, and economy, which differed only in the levels and spectra of radioactive contamination—revealed significant abnormalities associated with irradiation, unrelated to age or sex (e.g., stable chromosomal aberrations), as well as other genetic and nongenetic pathologies.

In all cases when comparing the territories heavily contaminated by Chernobyl's radionuclides with less contaminated areas that are characterized by a similar economy, demography, and environment, there is a marked increase in general morbidity in the former.

Increased numbers of sick and weak newborns were found in the heavily contaminated territories in Belarus, Ukraine, and European Russia.

Accelerated aging is one of the well-known consequences of exposure to ionizing radiation. This phenomenon is apparent to a greater or lesser degree in all of the populations contaminated by the Chernobyl radionuclides.

This section describes the spectrum and the scale of the nonmalignant diseases that have been found among exposed populations.

Adverse effects as a result of Chernobyl irradiation have been found in every group that has been studied. Brain damage has been found in individuals directly exposed—liquidators and those living in the contaminated territories, as well as in their offspring. Premature cataracts; tooth and mouth abnormalities; and blood, lymphatic, heart, lung, gastrointestinal, urologic, bone, and skin diseases afflict and impair people, young and old alike. Endocrine dysfunction, particularly thyroid disease, is far more common than might be expected, with some 1,000 cases of thyroid dysfunction for every case of thyroid cancer, a marked increase after the catastrophe. There are genetic damage and birth defects especially in children of liquidators and in children born in areas with high levels of radioisotope contamination.

Immunological abnormalities and increases in viral, bacterial, and parasitic diseases are rife among individuals in the heavily contaminated areas. For more than 20 years, overall morbidity has remained high in those exposed to the irradiation released by Chernobyl. One cannot give credence to the explanation that these numbers are due solely to socioeconomic factors. The negative health consequences of the catastrophe are amply documented in this chapter and concern millions of people.

The most recent forecast by international agencies predicted there would be between 9,000 and 28,000 fatal cancers between 1986 and 2056, obviously underestimating the risk factors and the collective doses. On the basis of I-131 and Cs-137 radioisotope doses to which populations were exposed and a comparison of cancer mortality in the heavily and the less contaminated territories and pre- and post-Chernobyl cancer levels, a more realistic figure is 212,000 to 245,000 deaths in Europe and 19,000 in the rest of the world. High levels of Te-132, Ru-103, Ru-106, and Cs-134 persisted months after the Chernobyl catastrophe and the continuing radiation from Cs-137, Sr-90, Pu, and Am will generate new neoplasms for hundreds of years.

A detailed study reveals that 3.8–4.0% of all deaths in the contaminated territories of Ukraine and Russia from 1990 to 2004 were caused by the Chernobyl catastrophe. The lack of evidence of increased mortality in other affected countries is not proof of the absence of effects from the radioactive fallout. Since 1990, mortality among liquidators has exceeded the mortality rate in corresponding population groups.

From 112,000 to 125,000 liquidators died before 2005—that is, some 15% of the 830,000 members of the Chernobyl cleanup teams. The calculations suggest that the Chernobyl catastrophe has already killed several hundred thousand human beings in a population of several hundred million that was unfortunate enough to live in territories affected by the fallout. The number of Chernobyl victims will continue to grow over many future generations.

"My Strength of Materials prof would have flunked you if this was your answer to an essay question
http://www.democraticunderground.com/discuss/duboard.php?az=show_mesg&forum=115&topic_id=236498&mesg_id=236527

200psi is the strength of the vessel wall, no matter the size of the vessel."