GMOs: We all know stories of tobacco, asbestos, and DDT. Originally declared safe, they caused widespread death and disease. Although their impact was vast, most of the population was spared. The same cannot be said for sweeping changes in the food supply. Everyone eats; everyone is affected. The increase in several diseases in North America may be due to the profound changes in our diet. The most radical change occurred a little over a decade ago when genetically modified (GM) crops were introduced. Their influence on health has been largely ignored, but recent studies show serious problems. Genetically modified organisms (GMOs) have been linked to thousands of toxic or allergic-type reactions, thousands of sick, sterile, and dead livestock, and damage to virtually every organ and system studied in lab animals.1 Nearly every independent animal feeding safety study shows adverse or unexplained effects.
GM foods were made possible by a technology developed in the 1970s whereby genes from one species are forced into the DNA of other species. Genes produce proteins, which in turn can generate characteristics or traits. The promised traits associated with GMOs have been sky highβvegetables growing in the desert, vitamin fortified grains, and highly productive crops feeding the starving millions. None of these are available. In fact, the only two traits that are found in nearly all commericialized GM plants are herbicide tolerance and/or pesticide production.
Herbicide tolerant soy, corn, cotton, and canola plants are engineered with bacterial genes that allow them to survive otherwise deadly doses of herbicides. This gives farmers more flexibility in weeding and gives the GM seed company lots more profit. When farmers buy GM seeds, they sign a contract to buy only that seed producerβs brand of herbicide. Herbicide tolerant crops comprise about 80% of all GM plants. The other 20% are corn and cotton varieties that produce a pesticide in every cell. This is accomplished due to a gene from a soil bacterium called Bacillus thuringiensis or Bt, which produces a natural insect-killing poison called Bt- toxin. In addition to these two traits, there are also disease resistant GM Hawaiian papaya, zucchini and crook neck squash, which comprise well under 1% of GMO acreage.
Table of Contents
Such a lenient approach was largely the result of the influence of large agricultural corporations According to Henry Miller, who had a leading role in biotechnology issues at the FDA from 1979 to 1994, βIn this area, the US government agencies have done exactly what big agribusiness has asked them to do and told them to do.β2 The Ag biotech company with the greatest influence was clearly Monsanto. According to the New York Times, βWhat Monsanto wished for from Washington, Monsanto and, by extension, the biotechnology industry got. . . . When the company abruptly decided that it needed to throw off the regulations and speed its foods to market, the White House quickly ushered through an unusually generous policy of self-policing.β3
This policy was heralded by Vice President Dan Quayle on May 26, 1992. He chaired the Council on Competitiveness, which had identified GM crops as an industry that could boost US exports. To take advantage, Quayle announced βreformsβ to βspeed up and simplify the process of bringingβ GM products to market without βbeing hampered by unnecessary regulation.β4 Three days later, the FDA policy on non-regulation was unveiled.
The person who oversaw its development was the FDAβs Deputy Commissioner for Policy, Michael Taylor, whose position had been created especially for him in 1991. Prior to that, Taylor was an outside attorney for both Monsanto and the Food Biotechnology Council. After working at the FDA, he became Monsantoβs vice president. The Obama administration has put Talyor back into the FDA as the US Food Safety Czar.
FDA microbiologist Louis Pribyl, PhD, wrote about the policy, βWhat has happened to the scientific elements of this document? Without a sound scientific base to rest on, this becomes a broad, general, βWhat do I have to do to avoid troubleβ-type document. . . . It will look like and probably be just a political document. . . . It reads very pro-industry, especially in the area of unintended effects.β7
The scientistsβ concerns were not only ignored, their very existence was denied. The official FDA policy stated, βThe agency is not aware of any information showing that foods derived by these new methods differ from other foods in any meaningful or uniform way.β8 In sharp contrast, an internal FDA report stated, βThe processes of genetic engineering and traditional breeding are different and according to the technical experts in the agency, they lead to different risks.β9 The FDAβs deceptive notion of no difference was coined βsubstantial equivalenceβ and formed the basis of the US government position on GMOs.
Many scientists and organizations have criticized the US position. The National Academy of Sciences and even the pro-GM Royal Society of London10 describe the US system as inadequate and flawed. The editor of the prestigious journal Lancet said, βIt is astounding that the US Food and Drug Administration has not changed their stance on genetically modified food adopted in 1992. . . . The policy is that genetically modified crops will receive the same consideration for potential health risks as any other new crop plant. This stance is taken despite good reasons to believe that specific risks may exist. . . . Governments should never have allowed these products into the food chain without insisting on rigorous testing for effects on health.β11 The Royal Society of Canada described substantial equivalence as βscientifically unjustifiable and inconsistent with precautionary regulation of the technology.β 12
The Royal Society of Canada acknowledged that βthe default predictionβ for GM crops would include βa range of collateral changes in expression of other genes, changes in the pattern of proteins produced and/or changes in metabolic activities.β15 Although the FDA scientists evaluating GMOs in 1992 were unaware of the extent to which GM DNA is damaged or changed, they too described the potential consequences. They reported, βThe possibility of unexpected, accidental changes in genetically engineered plantsβ might produce βunexpected high concentrations of plant toxicants.β16 GM crops, they said, might have βincreased levels of known naturally occurring toxins,β and the βappearance of new, not previously identifiedβ toxins.17 The same mechanism can also produce allergens, carcinogens, or substances that inhibit assimilation of nutrients.
Most of these problems would pass unnoticed through safety assessments on GM foods, which are largely designed on the false premise that genes are like Legos that cleanly snap into place. But even if we disregard unexpected changes in the DNA for the moment, a proper functioning inserted gene still carries significant risk. Its newly created GM protein, such as the Bt-toxin, may be dangerous for human health (see below). Moreover, even if that protein is safe in its natural organism, once it is transferred into a new species it may be processed differently. A harmless protein may be transformed into a dangerous or deadly version. This happened with at least one GM food crop under development, GM peas, which were destroyed before being commercialized.
FDA scientists were also quite concerned about the possibility of inserted genes spontaneously transferring into the DNA of bacteria inside our digestive tract. They were particularly alarmed at the possibility of antibiotic resistant marker (ARM) genes transferring. ARM genes are employed during gene insertion to help scientists identify which cells successfully integrated the foreign gene. These ARM genes, however, remain in the cell and are cloned into the DNA of all the GM plants produced from that cell. One FDA report wrote in all capital letters that ARM genes would be βA SERIOUS HEALTH HAZARD,β due to the possibility of that they might transfer to bacteria and create super diseases, untreatable with antibiotics.
Although the biotech industry confidently asserted that gene transfer from GM foods was not possible, the only human feeding study on GM foods later proved that it does take place. The genetic material in soybeans that make them herbicide tolerant transferred into the DNA of human gut bacteria and continued to function18. That means that long after we stop eating a GM crop, its foreign GM proteins may be produced inside our intestines. It is also possible that the foreign genes might end up inside our own DNA, within the cells of our own organs and tissues.
Another worry expressed by FDA scientists was that GM plants might gather βtoxic substances from the environmentβ such as βpesticides or heavy metals,β19 or that toxic substances in GM animal feed might bioaccumulate into milk and meat products. While no studies have looked at the bioaccumulation issue, herbicide tolerant crops certainly have higher levels of herbicide residues. In fact, many countries had to increase their legally allowable levelsβby up to 50 timesβin order to accommodate the introduction of GM crops.
The overuse of the herbicides due to GM crops has resulted in the development of herbicide resistant weeds. USDA statistics showΒ that herbicide use is rapidly accelerating. Its use was up by 527 million pounds in the first 16 years of GM crops (1996-2011).Β Glyphosate use per acre on Roundup Ready soybeans was up by 227% while use on non-GMO soy acreage decreased by 20% overΒ the same time period. The rate of application is accelerating due in large part to the emergence of herbicide tolerant weeds, nowΒ found on millions of acres. According to a study by Charles Benbrook, the incremental increase per year was 1.5 million pounds inΒ 1999, 18 million in 2003, 79 million in 2009, and about 90 million in 2011. And as Roundup becomes less effective, farmers areΒ now using more toxic herbicides, such as 2-4D.
The pesticide-producing Bt crops do reduce the amount of sprayed on insecticides, but the total amount produced by the crops is farΒ greater than the amount of displaced spray. For example, Bt corn that kills the corn rootworm produces one to two pounds of BtΒ toxin per acre, but reduces sprayed insecticides by only about 0.19 pounds. SmartStax corn with eight genes produces 3.7 pounds ofΒ Bt toxin per acre, but displaces only 0.3 pounds of sprayed insecticides. 20
All of the above risks associated with GM foods are magnified for high-risk groups, such as pregnant women, children, the sick, and the elderly. The following section highlights some of the problems that have been identified.
According to Arpad Pusztai, PhD, one of the worldβs leading experts in GM food safety assessments, the type of stomach lesions linked to the tomatoes βcould lead to life-endangering hemorrhage, particularly in the elderly who use aspirin to prevent [blood clots].β24 Dr. Pusztai believes that the digestive tract, which is the first and largest point of contact with foods, can reveal various reactions to toxins and should be the first target of GM food risk assessment. He was alarmed, however, to discover that studies on the FlavrSavr never looked passed the stomach to the intestines. Other studies that did look found problems.
Mice fed potatoes engineered to produce the Bt-toxin developed abnormal and damaged cells, as well as proliferative cell growth in the lower part of their small intestines (ileum).25 Rats fed potatoes engineered to produce a different type of insecticide (GNA lectin from the snowdrop plant) also showed proliferative cell growth in both the stomach and intestinal walls (see photos).26 Although the guts of rats fed GM peas were not examined for cell growth, the intestines were mysteriously heavier; possibly as a result of such growth.27 Cell proliferation can be a precursor to cancer and is of special concern.
The state of the liverβa main detoxifier for the bodyβis another indicator of toxins.
In the FlavrSavr tomato study, a note in the appendix indicated that 7 of 40 rats died within two weeks and were replaced.35 In another study, chickens fed the herbicide tolerant βLiberty Linkβ corn died at twice the rate of those fed natural corn.36 But in these two industry-funded studies, the deaths were dismissed without adequate explanation or follow-up.
In addition, the cells in the pancreas of mice fed Roundup Ready soy had profound changes and produced significantly less digestive enzymes;37 in rats fed a GM potato, the pancreas was enlarged.38 In various analyses of kidneys, GM-fed animals showed lesions, toxicity, altered enzyme production or inflammation.39,40 Enzyme production in the hearts of rabbits was altered by GM soy.41 And GM potatoes caused slower growth in the brain of rats.42 A team of independent scientists re-analyzed the raw data in three Monsanto 90-day rat feeding studies and saw signs of toxicity in the liver and kidneys, as well as effects in the heart, adrenal glands, spleen, and blood.43 In one of the only long-term feeding studies, rats fed Roundup Ready corn for three years for 24 months (or even just low concentrations of Roundup in their drinking water) suffered significant damage to their kidneys, livers, and pituitary glands. They also died prematurely and had many massive tumorsβas large as 25% of their body weight.44
The testicles of both mice and rats fed Roundup Ready soybeans showed dramatic changes. In rats, the organs were dark blue instead of pink (see photos on next page).45 In mice, young sperm cells were altered.46 Embryos of GM soy-fed mice also showed temporary changes in their DNA function, compared to those whose parents were fed non-GM soy.47Β Female rats fed GM soy showed changes in their uterus, ovaries, and hormonal balance.48 By the third generation, most hamsters fed GM soy were unable to have babies. The infant mortality was 4-5 times greater than controls, and many of the GMO-fed third generation had hair growing in their mouths.49
An Austrian government study showed that mice fed GM corn (Bt and Roundup Ready) had fewer babies and smaller babies.50 More dramatic results were discovered by a leading scientist at the Russian National Academy of sciences. Female rats were fed GM soy, starting two weeks before they were mated.
When Indian shepherds let their sheep graze continuously on Bt cotton plants, within 5-7 days, one out of four sheep died. There was an estimated 10,000 sheep deaths in the region in 2006, with more reported in 2007. Post mortems on the sheep showed severe irritation and black patches in both intestines and liver (as well as enlarged bile ducts). Investigators said preliminary evidence βstrongly suggests that the sheep mortality was due to a toxin. . . . most probably Bt-toxin.β56 In a small feeding study, 100% of sheep fed Bt cotton died within 30 days. Those fed natural plants had no symptoms.
Buffalo that grazed on natural cotton plants for years without incident react to the Bt variety. In one village in Andhra Pradesh, for example, 13 buffalo grazed on Bt cotton plants for a single day. All died within 3 days.57 Investigators in the state of Haryana, India, report that most buffalo that ate GM cottonseed had reproductive complications such as premature deliveries, abortions, infertility, and prolapsed uteruses. Many young calves and adult buffaloes died.
It might be difficult to identify whether GM foods were triggering allergic responses in the population, since very few countries conduct regular studies or keep careful records. One country that does have an annual evaluation is the UK. Soon after GM soy was introduced into the British diet, researchers at the York Laboratory reported that allergies to soy had skyrocketed by 50% in a single year.61 Although no follow-up studies were conducted to see if GM soy was the cause, there is evidence showing several ways in which it might have contributed to the rising incidence of allergies:
It is interesting to note that in the five years immediately after GM soy was introduced, US peanut allergies doubled. It is known that a protein in natural soybeans cross-reacts with peanut allergies, i.e. soy may trigger reactions in some people who are allergic to peanuts.67 Given the startling increase in peanut allergies, scientists should investigate whether this cross-reactivity has been amplified in GM soy.
Roundup, tumors, etc.
Biotech companies claim that Bt-toxin has a history of safe use, is quickly destroyed in our stomach, and wouldnβt react with humans or mammals in any event. Studies verify, however, that natural Bt-toxin is not fully destroyed during digestion and does react with mammals. Mice fed Bt-toxin, for example, showed an immune response as potent as cholera toxin, 68, became immune sensitive to formerly harmless compounds,69 and had damaged and altered cells in their small intestines.70 A 2008 Italian government study found that Bt corn provoked immune responses in mice.71 Moreover, when natural Bt was sprayed over areas around Vancouver and Washington State to fight gypsy moths, about 500 people reported reactionsβmostly allergy or flu-like symptoms.72,73 Farm workers and others also report serious reactions7475767778 and authorities have long acknowledged that βpeople with compromised immune systems or preexisting allergies may be particularly susceptible to the effects of Bt.β79
The Bt-toxin produced in GM crops is βvastly different from the bacterial [Bt-toxins] used in organic and traditional farming and forestry.β80 The plant produced version is designed to be more toxic than natural varieties,81 and is about 3,000-5,000 times more concentrated than the spray form. And just like the GM soy protein, the Bt protein in GM corn varieties has a section of its amino acid sequence identical to a known allergen (egg yolk). The Bt protein also fails other allergen criteria recommended by the WHO, i.e. the protein is too resistant to break down during digestion and heat.
A 2011 study published in the Journal of Applied Toxicology showed that when Bt-toxin derived from Monsantoβs corn was exposed to human cells, the toxin disrupts the membrane in just 24 hours, causing certain fluid to leak through the cell walls. The authors specifically note, βThis may be due to pore formation like in insect cells.β In other words, the toxin may be creating small holes in human cells in the same manner that it kills insects. The researchers βdocumented that modified Bt toxins [from GM plants] are not inert on human cells, but can exert toxicity.β82 A 2011 Canadian study conducted at Sherbrooke Hospital discovered thatΒ 93% of the pregnant women they tested had Bt-toxin from Monsantoβs corn in their blood. And so did 80% of their unbornΒ fetuses. 83
If Bt-toxin causes allergies, then gene transfer carries serious ramifications. If Bt genes relocate to human gut bacteria, our intestinal flora may be converted into living pesticide factories, possibly producing Bt-toxin inside of us year after year. The UK Joint Food Safety and Standards Group also described gene transfer from a different route. They warned that genes from inhaled pollen might transfer into the DNA of bacteria in the respiratory system.84 Although no study has looked into that possibility, pollen from a Bt cornfield appears to have been responsible for allergic-type reactions.
In 2003, during the time when an adjacent Bt cornfield was pollinating, virtually an entire Filipino village of about 100 people was stricken by mysterious skin, respiratory, and intestinal reactions.85 The symptoms started with those living closest to the field and spread to those further away. Blood samples from 39 individuals showed antibodies in response to Bt-toxin, supportingβbut not provingβa link. When the same corn was planted in four other villages the following year, however, the symptoms returned in all four areasβonly during the time of pollination.86
Bt-toxin might also trigger reactions by skin contact. In 2005, a medical team reported that hundreds of agricultural workers in India are developing allergic symptoms when exposed to Bt cotton, but not when exposed to natural varieties.87 They say reactions come from picking the cotton, cleaning it in factories, loading it onto trucks, or even leaning against it. Their symptoms are virtually identical to those described by the 500 people in Vancouver and Washington who were sprayed with Bt.
A 2000 review of approved GM crops in Canada by professor E. Ann Clark, PhD, for example, reveals that 70% (28 of 40) βof the currently available GM crops . . . have not been subjected to any actual lab or animal toxicity testing, either as refined oils for direct human consumption or indirectly as feedstuffs for livestock. The same finding pertains to all three GM tomato decisions, the only GM flax, and to five GM corn crops.β In the remaining 30% (12) of the other crops tested, animals were not fed the whole GM feed. They were given just the isolated GM protein that the plant was engineered to produce. But even this protein was not extracted from the actual GM plant. Rather, it was manufactured in genetically engineered bacteria. This method of testing would never identify problems associated with collateral damage to GM plant DNA, unpredicted changes in the GM protein, transfer of genes to bacteria or human cells, excessive herbicide residues, or accumulation of toxins in the food chain, among others. Clark asks, βWhere are the trials showing lack of harm to fed livestock, or that meat and milk from livestock fed on GM feedstuffs are safe?β89
Epidemiologist and GM safety expert Judy Carman, PhD, MPH, shows that assessments by Food Safety Australia New Zealand (FSANZ) also overlook serious potential problems, including cancer, birth defects, or long-term effects of nutritional deficiencies. 90
βA review of twelve reports covering twenty-eight GM crops β four soy, three corn, ten potatoes, eight canola, one sugar beet and two cottonβrevealed no feeding trials on people. In addition, one of the GM corn varieties had gone untested on animals. Some seventeen foods involved testing with only a single oral gavage (a type of forced-feeding), with observation for seven to fourteen days, and only of the substance that had been genetically engineered to appear [the GM protein], not the whole food. Such testing assumes that the only new substance that will appear in the food is the one genetically engineered to appear, that the GM plant- produced substance will act in the same manner as the tested substance that was obtained from another source [GM bacteria], and that the substance will create disease within a few days. All are untested hypotheses and make a mockery of GM proponentsβ claims that the risk assessment of GM foods is based on sound science. Furthermore, where the whole food was given to animals to eat,Β sample sizes were often very lowβfor example, five to six cows per group for Roundup Ready soyβand they were fed for only four weeks.β91
Dr. Carman points out that GM βexperiments used some very unusual animal models for human health, such as chickens, cows, and trout. Some of the measurements taken from these animals are also unusual measures of human health, such as abdominal fat pad weight, total de-boned breast meat yield, and milk production.β In her examination of the full range of submittals to authorities in Australia and New Zealand, she says that there was no proper evaluation of βbiochemistry, immunology, tissue pathology, and gut, liver, and kidney function.β92 Writing on behalf of the Public Health Association of Australia, Dr. Carman says, βThe effects of feeding people high concentrations of the new protein over tens of years cannot be determined by feeding 20 mice a single oral gavage of a given high concentration of the protein and taking very basic data for 13-14 days.β93
βIf industry chooses to submit faulty, unpublishable studies, it does so without consequence. If it should respond to an agency request with deficient data, it does so without reprimand or follow-up. . . . If a company finds it disadvantageous to characterize its product, then its properties remain uncertain or unknown. If a corporation chooses to ignore scientifically sound testing standards . . . then faulty tests are conducted instead, and the results are considered legitimate. In the area of genetically engineered food regulation, the βcompetentβ agencies rarely if ever (know how to) conduct independent research to verify or supplement industry findings.β 95
At the end of the consultation, the FDA doesnβt actually approve the crops. Rather, they issue a letter that includes a statement such as the following:
βBased on the safety and nutritional assessment you have conducted, it is our understanding that Monsanto has concluded that corn products derived from this new variety are not materially different in composition, safety, and other relevant parameters from corn currently on the market, and that the genetically modified corn does not raise issues that would require premarket review or approval by FDA. . . . As you are aware, it is Monsantoβs responsibility to ensure that foods marketed by the firm are safe, wholesome and in compliance with all applicable legal and regulatory requirements.β96
βIn the judgment of the Expert Panel, the more regulatory agencies limit free access to the data upon which their decisions are based, the more compromised becomes the claim that the regulatory process is βscience based.β This is due to a simple but well- understood requirement of the scientific method itselfβthat it be an open, completely transparent enterprise in which any and all aspects of scientific research are open to full review by scientific peers. Peer review and independent corroboration of research findings are axioms of the scientific method, and part of the very meaning of the objectivity and neutrality of science.β97
Whenever private submissions are made public through lawsuits or Freedom of Information Act Requests, it becomes clear why companies benefit from secrecy. The quality of their research is often miserable, incompetent, and unacceptable for peer-review. In 2000, for example, after the potentially allergenic StarLink corn was found to have contaminated the food supply, the cornβs producer, Aventis CropScience, presented wholly inadequate safety data to the EPAβs scientific advisory panel. One frustrated panel member, Dean Metcalfe, MD,βthe governmentβs top allergistβsaid during a hearing, βMost of us review for a lot of journals. And if this were presented for publication in the journals that I review for, it would be sent back to the authors with all of these questions. It would be rejected.β98
Professor Clark, who analyzed submissions to Canadian regulators, concluded, βMost or all of the conclusions of food safety for individual GM crops are based on inferences and assumptions, rather than on actual testing.β For example, rather than actually testing to see if the amino acid sequence produced by their inserted gene is correct, βthe standard practice,β according to research analyst William Freese, βis to sequence just 5 to 25 amino acids,β99 even if the protein has more than 600 in total. If the short sample matches what is expected, they assume that the rest are also fine. If they are wrong, however, a rearranged protein could be quite dangerous.
Monsantoβs submission to Australian regulators on their high lysine GM corn provides an excellent example of overly optimistic assumptions used in place of science. The gene inserted into the corn produces a protein that is naturally found in soil. Monsanto claimed that since people consume small residues of soil on fruits and vegetables, the protein has a history of safe consumption. Based on the amount of GM corn protein an average US citizen would consume (if all their corn were Monsantoβs variety), they would eat up to 4 trillion times the amount normally consumed through soil. In other words, βfor equivalent exposureβ of the protein from soil βpeople would have to eat . . . nearly as much as 10,000kg [22,000 pounds, every] second 24 hours a day seven days a week.β100
When Monsanto learned that independent researchers were to publish a study in July 1999 showing that GM soy contains 12%-14% less cancer-fighting phytoestrogens, the company responded with its own study, concluding that soyβs phytoestrogen levels vary too much to even carry out a statistical analysis. Researchers failed to disclose, however, that they had instructed the laboratory to use an obsolete method of detectionβone that had been prone to highly variable results.101
When Aventis prepared samples to see if the potential allergen in StarLink corn remained intact after cooking, instead of using the standard 30-minute treatment, they heated corn for two hours.102
To show that pasteurization destroyed bovine growth hormone in milk from cows treated with rbGH, scientists pasteurized the milk 120 times longer than normal. Unable to destroy more than 19%, they then spiked the milk with a huge amount of the hormone and repeated the long pasteurization, destroying 90%.103 (The FDA reported that pasteurization destroys 90% of the hormone.104) To demonstrate that injections of rbGH did not interfere with cowβs fertility, Monsanto apparently added cows to the study that were pregnant prior to injection.105
And in order to prove that the protein from their GM crops breaks down quickly during simulated digestion, biotech companies used thousands of times the amount of digestive enzymes and a much stronger acid compared to that recommended by the World Health Organization.106
Other methods used to hide problems are varied and plentiful. For example, researchers:
In Pryme and Lembckeβs analysis, it came as no surprise that this Monsanto study, along with the other four peer-reviewed animal feeding studies that were βperformed more or less in collaboration with private companies,β reported no negative effects of the GM diet. βOn the other hand,β they wrote, βadverse effects were reported (but not explained) in [the five] independent studies.β They added, βIt is remarkable that these effects have all been observed after feeding for only 10β14 days.β112
Two GM foods whose commercialization was stopped because of negative test results give a chilling example of what may be getting through. Rats fed GM potatoes had potentially precancerous cell growth in the stomach and intestines, less developed brains, livers, and testicles, partial atrophy of the liver, and damaged immune systems.113 GM peas provoked an inflammatory response in mice, suggesting that the peas might trigger a deadly anaphylactic shock in allergic humans.114 Both of these dangerous crops, however, could easily have been approved. The problems were only discovered because the researchers used advanced tests that were never applied to GM crops already on the market. Both would have passed the normal tests that companies typically use to get their products approved.
Ironically, when Monsanto was asked to comment on the pea study, their spokesperson said it demonstrated that the regulatory system works. He failed to disclose that none of his companyβs GM crops had been put through such rigorous tests.
Industry-funded research that favors the funders is not new. Bias has been identified across several industries. In pharmaceuticals, for example, positive results are four times more likely if the drugβs manufacturer funds the study.115 When companies pay for the economic analyses of their own cancer drugs, the results are eight times more likely to be favorable.116 Compared to drug research, the potential for industry manipulation in GM crop studies is considerably higher. Unlike pharmaceutical testing, GM research has no standardized procedures dictated by regulators. GM studies are not usually published in peer-reviewed journals and are typically kept secret by companies and governments. There is little money available for rigorous independent research, so company evidence usually goes unchallenged and unverified. Most importantly, whereas drugs can show serious side-effects and still be approved, GM food cannot. There is no tolerance for adverse reactions; feeding trials must show no problems.
Thus, when industry studies show problems (in spite of their efforts to avoid them), serious adverse reactions and even deaths among GM-fed animals are ignored or dismissed as βnot biologically significantβ or due to βnatural variations.β In the critical arena of food safety research, the biotech industry is without accountability, standards, or peer-review. Theyβve got bad science down to a science.
While such self-serving behavior may be expected from corporations, how come government bodies let such blatant scientific contortions pass without comment? One reason is that several regulatory agencies are also charged with promoting the interests of biotechnology. This is the official position of the FDA and other US government bodies, for example. Suzanne Wuerthele, PhD, a US EPA toxicologist, says, βThis technology is being promoted, in the face of concerns by respectable scientists and in the face of data to the contrary, by the very agencies which are supposed to be protecting human health and the environment. The bottom line in my view is that we are confronted with the most powerful technology the world has ever known, and it is being rapidly deployed with almost no thought whatsoever to its consequences.β117
Canadian regulators are similarly conflicted. The Royal Society of Canada reported that, βIn meetings with senior managers from the various Canadian regulatory departments . . . their responses uniformly stressed the importance of maintaining a favorable climate for the biotechnology industry to develop new products and submit them for approval on the Canadian market. . . . The conflict of interest involved in both promoting and regulating an industry or technology . . . is also a factor in the issue of maintaining the transparency, and therefore the scientific integrity, of the regulatory process. In effect, the public interest in a regulatory system that is βscience basedβ. . . is significantly compromised when that openness is negotiated away by regulators in exchange for cordial and supportive relationships with the industries being regulated.β118
Many scientists on the European Food Safety Authority (EFSA) GMO Panel are personally aligned with biotech interests. According to Friends of the Earth (FOE), βOne member has direct financial links with the biotech industry and others have indirect links, such as close involvement with major conferences organized by the biotech industry. Two members have even appeared in promotional videos produced by the biotech industry. . . . Several members of the Panel, including the chair Professor Kuiper, have been involved with the EU-funded ENTRANSFOOD project. The aim of this project was to agree [to] safety assessment, risk management, and risk communication procedures that would βfacilitate market introduction of GMOs in Europe, and therefore bring the European industry in a competitive position.β Professor Kuiper, who coordinated the ENTRANSFOOD project, sat on a working group that also included staff from Monsanto, Bayer CropScience, and Syngenta.β In a statement reminiscent of the deceptive policy statement by the FDA, the FOE report concludes that EFSA is βbeing used to create a false impression of scientific agreement when the real situation is one of intense and continuing debate and uncertainty.β119
The pro-GM European Commission repeats the same ruse. According to leaked documents obtained by FOE, while they privately appreciate βthe uncertainties and gaps in knowledge that exist in relation to the safety of GM crops, . . . the Commission normally keeps this uncertainty concealed from the public whilst presenting its decisions about the safety of GM crops and foods as being certain and scientifically based.β For example, the Commission privately condemned the submission information for one crop as βmixed, scarce, delivered consecutively all over years, and not convincing.β They said there is βNo sufficient experimental evidence to assess the safety.β120
With an agenda to promote GM foods, regulators regularly violate their own laws. In Europe, the law requires that when EFSA and member states have different opinions, they βare obliged to co-operate with a view to either resolving the divergence or preparing a joint document clarifying the contentious scientific issues and identifying the relevant uncertainties in the data.β121 According to FOE, in the case of all GM crop reviews, none of these legal obligations were followed.122 The declaration of GRAS status by the FDA also deviated from the Food and Cosmetic Act and years of legal precedent. Some violations are more blatant. In India, one official tampered with the report on Bt cotton to increase the yield figures to favor Monsanto.123 In Mexico, a senior government official allegedly threatened a University of California professor, implying βWe know where your children go to school,β trying to get him not to publish incriminating evidence that would delay GM approvals.124 In Indonesia, Monsanto gave bribes and questionable payments to at least 140 officials, attempting to get their genetically modified (GM) cotton approved.125
Threatening letters from Monsantoβs attorneys have resulted in the cancellation of a five-part news series on their genetically engineered bovine growth hormone scheduled for a Fox TV station in Florida, as well as the cancellation of a book critical of Monsantoβs GMO products. A printer also shredded 14,000 copies of the Ecologist magazine issue entitled βThe Monsanto Files,β due to fear of a Monsanto lawsuit. (See the chapter βMuscling the Mediaβ in Seeds of Deception126 for more examples.)
The methods that biotech advocates use to manipulate public opinion research has become an art form. Consumer surveys by the International Food Information Council (IFIC), for example,whose supporters include the major biotech seed companies, offers conclusions such as βA growing majority of Americans support the benefits of food biotechnology as well as the US Food and Drug Administrationβs (FDA) labeling policy.β But communications professor James Beniger, who was past president of the American Association for Public Opinion Research, described the surveys as βso biased with leading questions favoring positive responses that any results are meaningless.β127 The 2003 survey, for example, included gems such as:
βAll things being equal, how likely would you be to buy a variety of produce, like tomatoes or potatoes, if it had been modified by biotechnology to taste better or fresher?β and
βBiotechnology has also been used to enhance plants that yield foods like cooking oils. If cooking oil with reduced saturated fat made from these new plants was available, what effect would the use of biotechnology have on your decision to buy this cooking oil?β128
A similar tactic was used at a December 11, 2007 focus group in Columbus, Ohio βdesignedβ to show that consumers wanted to make it illegal for dairies to label their milk as free from Monsantoβs genetically engineered bovine hormone rBST. The facilitator said, βAll milk contains hormones. There is no such thing as hormone-free milk. The composition of both types of milk is the same in all aspects. Now what do you think of a label that says βno added hormones?β Donβt you think it is deceiving and inappropriate to put βrBST-freeβ on labels?β Not only was the facilitator βleading the witness,β he presented false information. Milk from cows treated with rBST has substantially higher levels of Insulin-like Growth Factor-1,129 which has been linked to higher risk of cancer,130 and higher incidence of fraternal twins.131 It also has higher levels of bovine growth hormone, pus, and in some cases, antibiotics.
Another example of manipulated consumer opinion was found in a 2004 article in the British Food Journal, authored by four advocates of genetically modified (GM) foods.132 According to the peer-reviewed paper, when shoppers in a Canadian farm store were confronted with an informed and unbiased choice between GM corn and non-GM corn, most purchased the GM variety. This finding flew in the face of worldwide consumer resistance to GM foods, which had shut markets in Europe, Japan, and elsewhere. It also challenged studies that showed that the more information on genetically modified organisms (GMOs) consumers have, the less they trust them.133 The study, which was funded by the biotech-industry front group, Council for Biotechnology Information and the industryβs trade association, the Crop Protection Institute of Canada (now Croplife Canada), was given the Journalβs prestigious Award for Excellence for the Most Outstanding Paper of 2004 and has been cited often by biotech advocates.
Stuart Laidlaw, a reporter from Canadaβs Toronto Star, visited the farm store several times during the study and described the scenario in his book Secret Ingredients. Far from offering unbiased choices, key elements appeared rigged to favor GM corn purchases. The consumer education fact sheets were entirely pro-GMO, and Doug Powell, the lead researcher, enthusiastically demonstrated to Laidlaw how he could convince shoppers to buy the GM varieties. He confronted a farmer who had alreadyΒ purchased non-GM corn. After pitching his case for GMOs, Powell proudly had the farmer tell Laidlaw that he had changed his opinion and would buy GM corn in his next shopping trip.
Powellβs interference with shoppersβ βunbiasedβ choices was nothing compared to the effect of the signs placed over the corn bins. The sign above the non-GM corn read, βWould you eat wormy sweet corn?β It further listed the chemicals that were sprayed during the season. By contrast, the sign above the GM corn stated, βHereβs What Went into Producing Quality Sweet Corn.β It is no wonder that 60% of shoppers avoided the βwormy corn.β In fact, it may be a testament to peopleβs distrust of GMOs that 40% still went for the βwormyβ option.
Powell and his colleagues did not mention the controversial signage in their study. They claimed that the corn bins in the farm store were βfully labelledββeither βgenetically engineered Bt sweet cornβ or βRegular sweet corn.β When Laidlawβs book came out, however, Powellβs βwormyβ sign was featured in a photograph,134 exposing what was later described by Cambridge Universityβs Dr. Richard Jennings as βflagrant fraud.β Jennings, who is a leading researcher on scientific ethics, says, βIt was a sin of omission by failing to divulge information which quite clearly should have been disclosed.β135
In his defence, Powell claimed that his signs merely used the language of consumers and was βnot intended to manipulate consumer purchasing patterns.β He also claimed that the βwormyβ corn sign was only there for the first week of the trial and was then replaced by other educational messages. But eye witnesses and photographs demonstrate the presence of the sign long after Powellβs suggested date of replacement.136
Several scientists and outraged citizens say the paper should be withdrawn, but the Journal refused. In fact, the Journalβs editor has not even agreed to reconsider its Award for Excellence. A blatant propaganda exercise still stands validated as exemplary science.
After University of California Professor Ignacio Chapela, PhD, published evidence that GM corn contaminated Mexicoβs indigenous varieties, two fictitious internet characters created by Monsantoβs PR firm, the Bivings Group, initiated a brutal internet smear campaign, lying about Dr. Chapela and his research.
Irina Ermakova, PhD, a leading scientist at the Russian National Academy of Sciences, fed female rats GM soy and was stunned to discover that more than half their offspring died within three weeksβcompared to only 10% from mothers fed non-GM soy. Without funding to extend her analysis, she labeled her work βpreliminary,β published it in a Russian journal, and implored the scientific community to repeat the study. Two years later, no one has repeated it, but advocates use false or irrelevant arguments to divert attention from the shocking results and have tried to vilify Dr. Ermakova.
A New Zealand MP testified at the 2001 Royal Commission of Inquiry on Genetic Modification, βI have been contacted by telephone and e-mail by a number of scientists who have serious concerns . . . but who are convinced that if they express these fears publicly. . . or even if they asked the awkward and difficult questions, they will be eased out of their institution.β Indeed in 2007, after Professor Christian Velot, PhD, raised the difficult questions on GMOs at public conferences, his 2008 research funds were confiscated, his student assistants were re-assigned, and his position at the University of Paris-Sud faces early termination.
Regulators at Health Canada announced in 2002 that they would monitor Canadians for health problems from eating GM foods. A spokesperson said, βI think itβs just prudent and what the public expects, that we will keep a careful eye on the health of Canadians.β But according to CBC TV news, Health Canada βabandoned that research less than a year later saying it was βtoo difficult to put an effective surveillance system in place.ββ The news anchor added, βSo at this point, there is little research into the health effects of genetically modified food. So will we ever know for sure if itβs safe?β137
Not with the biotech companies in charge. Consider the following statement in a report submitted to county officials in California by pro-GM members of a task force. β[It is] generally agreed that long-term monitoring of the human health risks of GM food through epidemiological studies is not necessary because there is no scientific evidence suggesting any long-term harm from these foods.β138 Note the circular logic: Because no long-term epidemiological studies are in place, we have no evidence showing long- term harm. And since we donβt have any evidence of long-term harm, we donβt need studies to look for it.
What are these people thinking? Insight into the pro-GM mindset was provided by Dan Glickman, the US Secretary of Agriculture under President Clinton.
βWhat I saw generically on the pro-biotech side was the attitude that the technology was good, and that it was almost immoral to say that it wasnβt good, because it was going to solve the problems of the human race and feed the hungry and clothe the naked. . . . And there was a lot of money that had been invested in this, and if youβre against it, youβre Luddites, youβre stupid. That, frankly, was the side our government was on. Without thinking, we had basically taken this issue as a trade issue and they, whoever βtheyβ were, wanted to keep our product out of their market. And they were foolish, or stupid, and didnβt have an effective regulatory system. There was rhetoric like that even here in this department. You felt like you were almost an alien, disloyal, by trying to present an open-minded view on some of the issues being raised. So I pretty much spouted the rhetoric that everybody else around here spouted; it was written into my speeches.β139
Fortunately, not everyone feels that questioning GM foods is disloyal. On the contrary, millions of people around the world are unwilling to participate in this uncontrolled experiment. They refuse to eat GM foods. Manufacturers in Europe and Japan have committed to avoid using GM ingredients. And the US natural foods industry, not waiting for the government to test or label GMOs, is now engaged in removing all remaining GM ingredients from their sector using a third party verification system. The Campaign for Healthier Eating in America will circulate non-GMO shopping guides in stores nationwide so that consumers have clear, healthy non-GMO choices. With no governmental regulation of biotech corporations, it is left to consumers to protect ourselves.
For a guide to avoiding GMOs, go to www.NonGMOShoppingGuide.com.
International bestselling author and independent filmmaker Jeffrey M. Smith is the Executive Director of the Institute for Responsible Technology and a leading spokesperson on the health dangers of GMOs. His first book, Seeds of Deception, is the worldβs bestselling book on the subject. His second, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, identifies 65 risks of GMOs and demonstrates how superficial government approvals are not competent to find most of them. Mr. Smith has pioneered the Campaign for Healthier Eating in America, designed to create the tipping point of consumer rejection against GMOs. See www.ResponsibleTechnology.org, www.NonGMOShoppingGuide.com.
1 Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA USA 2007
2 Kurt Eichenwald, et al, New York Times, βBiotechnology Food: From the Lab to a Debacle,β January 25, 2001
www.nytimes.com/2001/01/25/business/25FOOD.html?pagewanted=all
3 Kurt Eichenwald, et al, New York Times, βBiotechnology Food: From the Lab to a Debacle,β January 25, 2001
www.nytimes.com/2001/01/25/business/25FOOD.html?pagewanted=all
4 Dan Quayle, βSpeech in the Indian Treaty Room of the Old Executive Office Building,β May 26, 1992.
5 For copies of FDA memos, see The Alliance for Bio-Integrity, www.biointegrity.org
6 Steven M. Druker, βHow the US Food and Drug Administration approved genetically engineered foods despite the deaths one had caused and
the warnings of its own scientists about their unique risks,β Alliance for Bio-Integrity, www.biointegrity.org/ext-summary.html
7 Louis J. Pribyl, βBiotechnology Draft Document, 2/27/92,β March 6, 1992, www.biointegrity.org
www.biointegrity.org/FDAdocs/04/view1.html
8 βStatement of Policy: Foods Derived from New Plant Varieties,β Federal Register 57, no. 104 (May 29, 1992): 22991.
9 Linda Kahl, Memo to James Maryanski about Federal Register Document βStatement of Policy: Foods from Genetically Modified Plants,β
Alliance for Bio-Integrity(January 8, 1992) www.responsibletechnology.org/fraud/fda-quotes
10 See for example, βGood Enough To Eat?β New Scientist (February 9, 2002), 7.
11 βHealth risks of genetically modified foods,β editorial, Lancet, 29 May 1999.
12 βElements of Precaution: Recommendations for the Regulation of Food Biotechnology in Canada; An Expert Panel Report on the Future of
Food Biotechnology prepared by The Royal Society of Canada at the request of Health Canada Canadian Food Inspection Agency and
Environment Canadaβ The Royal Society of Canada, January 2001.
13 J. R. Latham, et al., βThe Mutational Consequences of Plant Transformation,β The Journal of Biomedicine and Biotechnology 2006, Article ID
25376: 1-7; see also Allison Wilson, et. al., βTransformation-induced mutations in transgenic plants: Analysis and biosafety implications,β
Biotechnology and Genetic Engineering Reviews β Vol. 23, December 2006.
14 P. H. Bao, S. Granata, S. Castiglione, G. Wang, C. Giordani, E. Cuzzoni, G. Damiani, C. Bandi, S. K. Datta, K. Datta, I. Potrykus, A.
Callegarin and F. Sala, βEvidence for genomic changes in transgenic rice (Oryza sativa L.) recovered from protoplastsβ Transgen Res 5 (1996):
97-103.; M. Labra, C. Savini, M. Bracale, N. Pelucchi, L. Colombo, M. Bardini and F. Sala, βGenomic changes in transgenic rice (Oryza sativa L.)
plants produced by infecting calli with Agrobacterium tumefaciens,β Plant Cell Rep 20 (2001): 325-330.
15 βElements of Precaution: Recommendations for the Regulation of Food Biotechnology in Canada; An Expert Panel Report on the Future of
Food Biotechnology prepared by The Royal Society of Canada at the request of Health Canada Canadian Food Inspection Agency and
Environment Canadaβ The Royal Society of Canada, January 2001.
16 Edwin J. Mathews, Ph.D., in a memorandum to the Toxicology Section of the Biotechnology Working Group. Subject: Analysis of the Major
Plant Toxicants. Dated October 28, 1991
17 Division of Food Chemistry and Technology and Division of Contaminants Chemistry, βPoints to Consider for Safety Evaluation of
Genetically Modified Foods: Supplemental Information,β November 1, 1991, www.responsibletechnology.org/fraud/fda-quotes
18 Netherwood et al, βAssessing the survival of transgenic plant DNA in the human gastrointestinal tract,β Nature Biotechnology 22 (2004): 2.
19 Division of Food Chemistry and Technology and Division of Contaminants Chemistry, βPoints to Consider for Safety Evaluation of
Genetically Modified Foods: Supplemental Information,β November 1, 1991, www.biointegrity.org
20 Charles Benbrook, βImpacts of genetically engineered crops on pesticide use in the U.S. β the first sixteen years,β ENVIRONMENTAL SCIENCES
EUROPE, Vol. 24:24 doi:10.1186/2190-4715-24-24, 28 September 2012. www.enveurope.com/content/24/1/24/abstract.
21 Department of Veterinary Medicine, FDA, correspondence June 16, 1993. As quoted in Fred A. Hines, Memo to Dr. Linda Kahl. βFlavr Savr
Tomato: . . . Pathology Branchβs Evaluation of Rats with Stomach Lesions From Three Four-Week Oral (Gavage) Toxicity Studies . . . and an
Expert Panelβs Report,β Alliance for Bio-Integrity (June 16, 1993) www.biointegrity.org/FDAdocs/17/view1.html
22 Robert J. Scheuplein, Memo to the FDA Biotechnology Coordinator and others, βResponse to Calgene Amended Petition,β Alliance for BioIntegrity
(October 27, 1993) www.responsibletechnology.org/fraud/fda-quotes
23 Carl B. Johnson to Linda Kahl and others, βFlavr Savrβ’ Tomato: Significance of Pending DHEE Question,β Alliance for Bio-Integrity
(December 7, 1993) www.responsibletechnology.org/fraud/fda-quotes
24 Arpad Pusztai, βGenetically Modified Foods: Are They a Risk to Human/Animal Health?β June 2001 Action Bioscience
www.actionbioscience.org/biotech/pusztai.html
25 Nagui H. Fares, Adel K. El-Sayed, βFine Structural Changes in the Ileum of Mice Fed on Endotoxin Treated Potatoes and Transgenic
Potatoes,β Natural Toxins 6, no. 6 (1998): 219β233.
26 Stanley W. B. Ewen and Arpad Pusztai, βEffect of diets containing genetically modified potatoes expressing Galanthus nivalis lectin on rat
small intestine,β Lancet, 1999 Oct 16; 354 (9187): 1353-4.
27 Arpad Pusztai, βFacts Behind the GM Pea Controversy: Epigenetics, Transgenic Plants & Risk Assessment,β Proceedings of the Conference,
December 1st 2005 (Frankfurtam Main, Germany: Literaturhaus, 2005). www.oeko.de/oekodoc/277/2006-002-en.pdf
28 Arpad Pusztai, βCan science give us the tools for recognizing possible health risks of GM food,β Nutrition and Health, 2002, Vol 16 Pp 73-84.
29 John M. Burns, β13-Week Dietary Subchronic Comparison Study with MON 863 Corn in Rats Preceded by a 1-Week Baseline Food
Consumption Determination with PMI Certified Rodent Diet #5002,β December 17, 2002
www.monsanto.com/pdf/products/fullratstudy863.pdf
30 R. Tudisco, P. Lombardi, F. Bovera, D. dβAngelo, M. I. Cutrignelli, V. Mastellone, V. Terzi, L. Avallone, F. Infascelli, βGenetically Modified
Soya Bean in Rabbit Feeding: Detection of DNA Fragments and Evaluation of Metabolic Effects by Enzymatic Analysis,β Animal Science 82
(2006): 193β199.
31 Comments to ANZFA about Applications A346, A362 and A363 from the Food Legislation and Regulation Advisory Group (FLRAG) of the
Public Health Association of Australia (PHAA) on behalf of the PHAA, βFood produced from glyphosate-tolerant canola line GT73.β
32 M. Malatesta, C. Caporaloni, S. Gavaudan, M. B. Rocchi, S. Serafini, C. Tiberi, G. Gazzanelli, βUltrastructural Morphometrical and
Immunocytochemical Analyses of Hepatocyte Nuclei from Mice Fed on Genetically Modified Soybean,β Cell Struct Funct. 27 (2002): 173β180
33 Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA USA 2007
34 Irina Ermakova, βExperimental Evidence of GMO Hazards,β Presentation at Scientists for a GM Free Europe, EU Parliament, Brussels, June
12, 2007
35 Arpad Pusztai, βCan Science Give Us the Tools for Recognizing Possible Health Risks for GM Food?β Nutrition and Health 16 (2002): 73β84.
36 S. Leeson, βThe Effect of Glufosinate Resistant Corn on Growth of Male Broiler Chickens,β Department of Animal and Poultry Sciences,
University of Guelph, Report No. A56379, July 12, 1996.
37 Malatesta, et al, βUltrastructural Analysis of Pancreatic Acinar Cells from Mice Fed on Genetically modified Soybean,β J Anat. 2002
November; 201(5): 409β415; see also M. Malatesta, M. Biggiogera, E. Manuali, M. B. L. Rocchi, B. Baldelli, G. Gazzanelli, βFine Structural
Analyses of Pancreatic Acinar Cell Nuclei from Mice Fed on GM Soybean,β Eur J Histochem 47 (2003): 385β388.
38 Arpad Pusztai, βCan science give us the tools for recognizing possible health risks of GM food,β Nutrition and Health, 2002, Vol 16 Pp 73-84
39 R. Tudisco, P. Lombardi, F. Bovera, D. dβAngelo, M. I. Cutrignelli, V. Mastellone, V. Terzi, L. Avallone, F. Infascelli, βGenetically Modified
Soya Bean in Rabbit Feeding: Detection of DNA Fragments and Evaluation of Metabolic Effects by Enzymatic Analysis,β Animal Science 82
(2006): 193β199.
40 John M. Burns, β13-Week Dietary Subchronic Comparison Study with MON 863 Corn in Rats Preceded by a 1-Week Baseline Food
Consumption Determination with PMI Certified Rodent Diet #5002,β December 17, 2002
www.monsanto.com/pdf/products/fullratstudy863.pdf
41 R. Tudisco, P. Lombardi, F. Bovera, D. dβAngelo, M. I. Cutrignelli, V. Mastellone, V. Terzi, L. Avallone, F. Infascelli, βGenetically Modified
Soya Bean in Rabbit Feeding: Detection of DNA Fragments and Evaluation of Metabolic Effects by Enzymatic Analysis,β Animal Science 82
(2006): 193β199.
42 Arpad Pusztai, βCan science give us the tools for recognizing possible health risks of GM food,β Nutrition and Health, 2002, Vol 16 Pp 73-84
43 de VendΓ΄mois JS, Roullier F, Cellier D, SΓ©ralini GE. A Comparison of the Effects of Three GM Corn Varieties on Mammalian Health. Int J
Biol Sci 2009; 5:706-726. Available from www.biolsci.org/v05p0706.htm
44 SΓ©ralini, G.-E., et al. Long term toxicity of a Roundup herbicide and a Roundup-tolerant genetically modified maize. Food
Chem. Toxicol. (2012), dx.doi.org/10.1016/j.fct.2012.08.005
45 Irina Ermakova, βExperimental Evidence of GMO Hazards,β Presentation at Scientists for a GM Free Europe, EU Parliament, Brussels, June
12, 2007
46 L. Vecchio et al, βUltrastructural Analysis of Testes from Mice Fed on Genetically Modified Soybean,β European Journal of Histochemistry
48, no. 4 (OctβDec 2004):449β454.
47 Oliveri et al., βTemporary Depression of Transcription in Mouse Pre-implantion Embryos from Mice Fed on Genetically Modified Soybean,β
48th Symposium of the Society for Histochemistry, Lake Maggiore (Italy), September 7β10, 2006.
48 FlΓ‘via Bittencourt Brasil, et al, βThe Impact of Dietary Organic and Transgenic Soy on the Reproductive System of Female Adult Rat,β The
Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology Volume 292, Issue 4, pages 587-594, April 2009
onlinelibrary.wiley.com/doi/10.1002/ar.20878/abstract
49 Jeffrey M. Smith, βGenetically Modified Soy Linked to Sterility, Infant Mortality,β based on correspondence with study authors and press
reports, Institute for Responsible Technology www.responsibletechnology.org/article-gmo-soy-linked-to-sterility
50 Alberta Velimirov and Claudia Binter, βBiological effects of transgenic maize NK603xMON810 fed in long term reproduction studies in
mice,β Forschungsberichte der Sektion IV, Band 3/2008. Report-Federal Ministry of Health, Family and Youth. 2008.
www.biosicherheit.de/pdf/aktuell/zentek_studie_2008.pdf
51 I.V.Ermakova, βGenetically Modified Organisms and Biological Risks,β Proceedings of International Disaster Reduction Conference (IDRC)
Davos, Switzerland August 27th β September 1st, 2006: 168β172. eco-irina-ermakova.narod.ru/eng/art/art16.html
52 Irina Ermakova, βGenetically modified soy leads to the decrease of weight and high mortality of rat pups of the first generation. Preliminary
studies,β Ecosinform 1 (2006): 4β9.
53 Irina Ermakova, βExperimental Evidence of GMO Hazards,β Presentation at Scientists for a GM Free Europe, EU Parliament, Brussels, June
12, 2007
54 I.V.Ermakova βGMO: Life itself intervened into the experiments,β Letter, EcosInform N2 (2006): 3β4.
55 Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA USA 2007
56 βMortality in Sheep Flocks after Grazing on Bt Cotton FieldsβWarangal District, Andhra Pradeshβ Report of the Preliminary Assessment,
April 2006, gmwatch.org/latest-listing/1-news-items/6416-mortality-in-sheep-flocks-after-grazing-on-bt-cotton-fields-warangal-districtandhra-pradesh-2942006
57 Personal communication and visit by Jeffrey Smith with village members, near Warangal, Andhra Pradesh, January 2009.
58 John M. Burns, β13-Week Dietary Subchronic Comparison Study with MON 863 Corn in Rats Preceded by a 1-Week Baseline Food
Consumption Determination with PMI Certified Rodent Diet #5002,β December 17, 2002
www.monsanto.com/monsanto/content/sci_tech/prod_safety/fullratstudy.pdf, see also StΓ©phane Foucart, βControversy Surrounds a GMO,β
Le Monde, 14 December 2004; and Jeffrey M. Smith, βGenetically Modified Corn Study Reveals Health Damage and Cover-up,β Spilling the
Beans, June 2005, www.seedsofdeception.com/Public/Newsletter/June05GMCornHealthDangerExposed/index.cfm
59 Arpad Pusztai, βCan science give us the tools for recognizing possible health risks of GM food,β Nutrition and Health, 2002, Vol 16 Pp 73-84
60 V. E. Prescott, et al, βTransgenic Expression of Bean r-Amylase Inhibitor in Peas Results in Altered Structure and
Immunogenicity,β Journal of Agricultural Food Chemistry (2005): 53.
61 Yearly food sensitivity assessment of York Laboratory, as reported in Mark Townsend, βWhy soya is a hidden destroyer,β Daily Express,
March 12, 1999.
62 G. A. Kleter and A. A. C. M. Peijnenburg, βScreening of transgenic proteins expressed in transgenic food crops for the presence of short amino
acid sequences indentical to potential, IgE-binding linear epitopes of allergens,β BMC Structural Biology 2 (2002): 8β19.
63 Netherwood et al, βAssessing the survival of transgenic plant DNA in the human gastrointestinal tract,β Nature Biotechnology 22 (2004): 2.
64 Hye-Yung Yum, Soo-Young Lee, Kyung-Eun Lee, Myung-Hyun Sohn, Kyu-Earn Kim, βGenetically Modified and Wild Soybeans: An
immunologic comparison,β Allergy and Asthma Proceedings 26, no. 3 (MayβJune 2005): 210-216(7).
65 Stephen R. Padgette et al, βThe Composition of Glyphosate-Tolerant Soybean Seeds Is Equivalent to That of Conventional Soybeans,β The
Journal of Nutrition 126, no. 4, (April 1996); including data in the journal archives from the same study; see also A. Pusztai and S. Bardocz,
βGMO in animal nutrition: potential benefits and risks,β Chapter 17, Biology of Nutrition in Growing Animals (Elsevier, 2005).
66 Manuela Malatesta, et al, βUltrastructural Analysis of Pancreatic Acinar Cells from Mice Fed on Genetically modified Soybean,β Journal of
Anatomy 201, no. 5 (November 2002): 409; see also M. Malatesta, M. Biggiogera, E. Manuali, M. B. L. Rocchi, B. Baldelli, G. Gazzanelli, βFine
Structural Analyses of Pancreatic Acinar Cell Nuclei from Mice Fed on GM Soybean,β Eur J Histochem 47 (2003): 385β388.
67 See for example, Scott H. Sicherer et al., βPrevalence of peanut and tree nut allergy in the United States determined by means of a random digit
dial telephone survey: A 5-year follow-up study,β Journal of allergy and clinical immunology, March 2003, vol. 112, n 6, 1203-1207); and Ricki
Helm et al., βHypoallergenic FoodsβSoybeans and Peanuts,β Information Systems for Biotechnology News Report, October 1, 2002.
68 Vazquez et al, βIntragastric and intraperitoneal administration of Cry1Ac protoxin from Bacillus thuringiensis induces systemic and mucosal
antibody responses in mice,β Life Sciences, 64, no. 21 (1999): 1897β1912; Vazquez et al, βCharacterization of the mucosal and systemic immune
response induced by Cry1Ac protein from Bacillus thuringiensis HD 73 in mice,β Brazilian Journal of Medical and Biological Research 33 (2000):
147β155.
69 R. I. VΓ‘zquez, L. Moreno-Fierros, L. Neri-BazΓ‘n, et al., βBacillus thuringiensis Cry1Ac Protoxin Is a Potent Systemic and Mucosal Adjuvant,β
Scandinavian Journal of Immunology 49 (1999): 578β84. See also Vazquez-Padron, RI. Et al. (2000b) Characterization of the mucosal and
systemic immune response induced by Cry1Ac protein from Bacillus thuringiensis HD 73 in mice. Brazilian Journal of Medical and Biological
Research 33, 147-155.
70 Nagui H. Fares, Adel K. El-Sayed, βFine Structural Changes in the Ileum of Mice Fed on Endotoxin Treated Potatoes and Transgenic
Potatoes,β Natural Toxins 6, no. 6 (1998): 219β233.
71 Alberto Finamore, et al, βIntestinal and Peripheral Immune Response to MON810 Maize Ingestion in Weaning and Old Mice,β J. Agric. Food
Chem., 2008, 56 (23), pp 11533β11539, November 14, 2008
72 Washington State Department of Health, βReport of health surveillance activities: Asian gypsy moth control program,β (Olympia, WA:
Washington State Dept. of Health, 1993).
73 M. Green, et al., βPublic health implications of the microbial pesticide Bacillus thuringiensis: An epidemiological study, Oregon, 1985-86,β
Amer. J. Public Health 80, no. 7(1990): 848β852.
74 M.A. Noble, P.D. Riben, and G. J. Cook, βMicrobiological and epidemiological surveillance program to monitor the health effects of Foray
48B BTK sprayβ (Vancouver, B.C.: Ministry of Forests, Province of British Columbi, Sep. 30, 1992).
75 A. Edamura, MD, βAffidavit of the Federal Court of Canada, Trial Division. Dale Edwards and Citizens Against Aerial Spraying vs. Her
Majesty the Queen, Represented by the Minister of Agriculture,β (May 6, 1993); as reported in Carrie Swadener, βBacillus thuringiensis (B.t.),β
Journal of Pesticide Reform, 14, no, 3 (Fall 1994).
76 J. R. Samples, and H. Buettner, βOcular infection caused by a biological insecticide,β J. Infectious Dis. 148, no. 3 (1983): 614; as reported in
Carrie Swadener, βBacillus thuringiensis (B.t.)β, Journal of Pesticide Reform 14, no. 3 (Fall 1994)
77 M. Green, et al., βPublic health implications of the microbial pesticide Bacillus thuringiensis: An epidemiological study, Oregon, 1985-86,β
Amer. J. Public Health, 80, no. 7 (1990): 848β852.
78 A. Edamura, MD, βAffidavit of the Federal Court of Canada, Trial Division. Dale Edwards and Citizens Against Aerial Spraying vs. Her
Majesty the Queen, Represented by the Minister of Agriculture,β (May 6, 1993); as reported in Carrie Swadener, βBacillus thuringiensis (B.t.),β
Journal of Pesticide Reform, 14, no, 3 (Fall 1994).
79 Carrie Swadener, βBacillus thuringiensis (B.t.),β Journal of Pesticide Reform 14, no. 3 (Fall 1994).
80 Terje Traavik and Jack Heinemann, βGenetic Engineering and Omitted Health Research: Still No Answers to Ageing Questions, 2006. Cited in
their quote was: G. Stotzky, βRelease, persistence, and biological activity in soil of insecticidal proteins from Bacillus thuringiensis,β found in
Deborah K. Letourneau and Beth E. Burrows, Genetically Engineered Organisms. Assessing Environmental and Human Health Effects (cBoca
Raton, FL: CRC Press LLC, 2002), 187β222.
81 See for example, A. Dutton, H. Klein, J. Romeis, and F. Bigler, βUptake of Bt-toxin by herbivores feeding on transgenic maize and
consequences for the predator Chrysoperla carnea,β Ecological Entomology 27 (2002): 441β7; and J. Romeis, A. Dutton, and F. Bigler, βBacillus
thuringiensis toxin (Cry1Ab) has no direct effect on larvae of the green lacewing Chrysoperla carnea (Stephens) (Neuroptera: Chrysopidae),β
Journal of Insect Physiology 50, no. 2β3 (2004): 175β183.
82 Mesnage R, Clair E, Gress S, Then C, SzΓ©kΓ‘cs A, SΓ©ralini, GE. (2012). Cytotoxicity on human cells of Cry1Ab and Cry1Ac Bt insecticidal
toxins alone or with a glyphosate-based herbicide. J. Appl. Toxicol. doi: 10.1002/jat.2712
83 Aris A, Leblanc S. Maternal and fetal exposure to pesticides associated to genetically modified foods in Eastern Townships of Quebec, Canada.
Reprod Toxicol (2011), doi:10.1016/j.reprotox.2011.02.004 www.ncbi.nlm.nih.gov/pubmed/21338670
84 N. Tomlinson of UK MAFFβs Joint Food Safety and Standards Group 4, December 1998 letter to the U.S. FDA, commenting on its draft
document, βGuidance for Industry: Use of Antibiotic Resistance Marker Genes in Transgenic Plants.β
85 Jeffrey M. Smith, βBt-maize (corn) during pollination, may trigger disease in people living near the cornfield,β Press Release, February 2004,
www.responsibletechnology.org/gmo-dangers/health-risks/articles-about-risks-by-jeffrey-smith/Genetically-Engineered-Foods-May-CauseRising-Food-Allergies-Genetically-Engineered-Corn-June-2007;
and Allen V. Estabillo, βFarmerβs group urges ban on planting Bt corn; says it
could be cause of illnesses,β Mindanews, October 19, 2004 www.gmwatch.org/latest-listing/43-2004/5635-farmers-group-urges-ban-onplanting-bt-corn-20102004
86 Mae-Wan Ho, βGM Ban Long Overdue, Dozens Ill & Five Deaths in the Philippines,β ISIS Press Release, June 2, 2006. www.isis.org.uk/GMBanLongOverdue.php
87 Ashish Gupta et. al., βImpact of Bt Cotton on Farmersβ Health (in Barwani and Dhar District of Madhya Pradesh),β Investigation Report, Octβ
Dec 2005.
88 Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA USA 2007
89 E. Ann Clark, βFood Safety of GM Crops in Canada: toxicity and allergenicity,β GE Alert, 2000.
www.plant.uoguelph.ca/research/homepages/eclark/safety.htm
90 FLRAG of the PHAA of behalf of the PHAA, βComments to ANZFA about Applications A372, A375, A378 and A379.β
91 Judy Carman, βIs GM Food Safe to Eat?β in R. Hindmarsh, G. Lawrence, eds., Recoding Nature Critical Perspectives on Genetic Engineering
(Sydney: UNSW Press, 2004): 82β93.
92 Judy Carman, βIs GM Food Safe to Eat?β in R. Hindmarsh, G. Lawrence, eds., Recoding Nature Critical Perspectives on Genetic Engineering
(Sydney: UNSW Press, 2004): 82β93.
93 FLRAG, βComments to ANZFA about Applications A346, A362 and A363,β www.iher.org.au/
94 Doug Gurian-Sherman, βHoles in the Biotech Safety Net, FDA Policy Does Not Assure the Safety of Genetically Engineered Foods,β Center
for Science in the Public Interest, www.cspinet.org/new/pdf/fda_report__final.pdf
95 Bill Freese, βThe StarLink Affair, Submission by Friends of the Earth to the FIFRA Scientific Advisory Panel considering Assessment of
Additional Scientific Information Concerning StarLink Corn,β July 17β19, 2001.
96 FDA Letter, Letter from Alan M. Rulis, Office of Premarket Approval, Center for Food Safety and Applied Nutrition, FDA to Dr. Kent Croon,
Regulatory Affairs Manager, Monsanto Company, Sept 25, 1996. See Letter for BNF No. 34 at
www.fda.gov/Food/Biotechnology/Submissions/ucm161107.htm
97 βElements of Precaution: Recommendations for the Regulation of Food Biotechnology in Canada; An Expert Panel Report on the Future of
Food Biotechnology prepared by The Royal Society of Canada at the request of Health Canada Canadian Food Inspection Agency and
Environment Canadaβ The Royal Society of Canada, January 2001. www.canadians.org/food/documents/rsc_feb05.pdf
98 FIFRA Scientific Advisory Panel (SAP), Open Meeting, July 17, 2001. www.epa.gov/scipoly/sap/meetings/2001/july/julyfinal.pdf
99 Bill Freese, Crop testing, New Scientist, Letter to the Editor, issue 2530, December 17, 2005
100 M. Cretenet, J. Goven, J. A. Heinemann, B. Moore, and C. Rodriguez-Beltran, βSubmission on the DAR for application A549 Food Derived
from High-Lysine Corn LY038: to permit the use in food of high-lysine corn, 2006, www.inbi.canterbury.ac.nz
101 Marc LappΓ© and Britt Bailey, βASA Response,β June 25, 1999, www.environmentalcommons.org/cetos/articles/asaresponse.html
102 Bill Freese, βThe StarLink Affair, Submission by Friends of the Earth to the FIFRA Scientific Advisory Panel considering Assessment of
Additional Scientific Information Concerning StarLink Corn,β July 17-19, 2001
103 Paul P. Groenewegen, Brian W. McBride, John H. Burton, Theodore H. Elsasser. βBioactivity of Milk from bST-Treated Cows.β J. Nutrition
120, 1990, pp. 514-519
104 Judith C. Juskevich and C. Greg Guyer. βBovine Growth Hormone: Human Food Safety Evaluation.β Science, vol. 249. August 24, 1990, pp.
875-884
105 Pete Hardin, βrbGH: Appropriate Studies Havenβt Been Done,β The Milkweed, July 2000
106 See for example, Doug Gurian-Sherman, βHoles in the Biotech Safety Net, FDA Policy Does Not Assure the Safety of Genetically Engineered
Foods,β Center for Science in the Public Interest, www.cspinet.org/new/pdf/fda_report__final.pdf
107 S. R. Padgette, N. B.Taylor, D. L. Nida, M. R. Bailey, J. MacDonald, L. R. Holden, R. L. Fuchs, βThe composition of glyphosate-tolerant
soybean seeds is equivalent to that of conventional soybeans,β J. Nutr. 126 (1996):702β716.
108 B. G. Hammond, J. L. Vicini, G. F. Hartnell, M. W. Naylor, C. D. Knight, E. H. Robinson, R. L. Fuchs, and S. R. Padgette, βThe feeding
value of soybeans fed to rats, chickens, catfish, and dairy cattle is not altered by genetic incorporation of glyphosate tolerance,β J. Nutr. 126
(1996): 717β727.
109 A. Pusztai and S. Bardocz, βGMO in animal nutrition: potential benefits and risks,β Chapter 17, Biology of Nutrition in Growing Animals
(Elsevier, October 2005). earlier
110 Ian F. Pryme and Rolf Lembcke, βIn Vivo Studies on Possible Health Consequences of Genetically Modified Food and Feedβwith Particular
Regard to Ingredients Consisting of Genetically Modified Plan Materials,β Nutrition and Health 17(2003): 1β8.
111 Andreas Rang, et al, βDetection of RNA variants transcribed from the transgene in Roundup Ready soybean,β Eur Food
Res Technol 220 (2005): 438β443.
112 Ian F. Pryme and Rolf Lembcke, βIn Vivo Studies on Possible Health Consequences of Genetically Modified Food and Feedβwith Particular
Regard to Ingredients Consisting of Genetically Modified Plan Materials,β Nutrition and Health 17(2003): 1β8.
113 Arpad Pusztai, βCan science give us the tools for recognizing possible health risks of GM food,β Nutrition and Health, 2002, Vol 16 Pp 73-84;
Stanley W. B. Ewen and Arpad Pusztai, βEffect of diets containing genetically modified potatoes expressing Galanthus nivalis lectin on rat small
intestine,β Lancet, 1999 Oct 16; 354 (9187): 1353-4; Arpad Pusztai, βGenetically Modified Foods: Are They a Risk to Human/Animal Health?β
June 2001 Action Bioscience www.actionbioscience.org/biotech/pusztai.html; and A. Pusztai and S. Bardocz, βGMO in animal nutrition:
potential benefits and risks,β Chapter 17, Biology of Nutrition in Growing Animals, R. Mosenthin, J. Zentek and T. Zebrowska (Eds.) Elsevier,
October 2005
114 V. E. Prescott, et al, βTransgenic Expression of Bean r-Amylase Inhibitor in Peas Results in Altered Structure and Immunogenicity,β Journal
of Agricultural Food Chemistry (2005): 53.
115 J. Lexchin, L. A. Bero, B. Djulbegovic, and O. Clark, βPharmaceutical industry sponsorship and research outcome and quality: systematic
review,β BMJ 326 (2003):1167β1176.
116 Mark Friedberg, et al, βEvaluation of Conflict of Interest in Economic Analyses of New Drugs Used in Oncology,β JAMA 282 (1999):1453β
1457.
117 Suzanne Wuerthele quoted here: archive.sare.org/sanet-mg/archives/html-home/23-html/0195.html
118 βElements of Precaution,β The Royal Society of Canada, January 2001. www.canadians.org/food/documents/rsc_feb05.pdf
119 Friends of the Earth Europe, βThrowing Caution to the Wind: A review of the European Food Safety Authority and its work on genetically
modified foods and crops,β November 2004.
120 European Communities submission to World Trade Organization dispute panel, 28 January 2005, reported in Hidden uncertainties β risks of
GMOs, 23 April 2006, Friends of the Earth / Greenpeace www.non-gm-farmers.com/news_print.asp?ID=2731
121 EU Regulation 178/2002 (Article 30.4)
122 Friends of the Earth Europe, βThrowing Caution to the Wind: A review of the European Food Safety Authority and its work on genetically
modified foods and crops,β November 2004.
123 βGreenpeace exposes Government-Monsanto nexus to cheat Indian farmers: calls on GEAC to revoke BT cotton permission,β Press release,
March 3, 2005, www.greenpeace.org/india_en/news/details?item_id=771071
124 Jeffrey M. Smith, Seeds of Deception, (Iowa: Yes! Books, 2003), 224.
125 βMonsanto Bribery Charges in Indonesia by DoJ and USSEC,β Third World Network, Malaysia, Jan 27, 2005,
www.mindfully.org/GE/2005/Monsanto-Indonesia-Bribery27jan05.htm
126 Jeffrey M. Smith, Seeds of Deception, Yes! Books, Fairfield, Iowa 2003
127 Karen Charman, The Professor Who Can Read Your Mind, PR Watch Newsletter Fourth Quarter 1999, Volume 6, No. 4
128 www.gmwatch.org/latest-listing/41-2002/3068-support-for-food-biotechnology-holds-in-the-us-
129 Estimates of increased IGF-1 levels vary considerably. In Mepham et al, βSafety of milk from cows treated with bovine somatotropin,β The
Lancet 2 (1994):197, IGF-1 levels were up to 10 times higher. The methods used may also underestimate IGF-1 levels considerably. See Samuel
S. Epstein, βUnlabeled Milk From Cows Treated With Biosynthetic Growth Hormones: A Case of Regulatory Abdication,β International Journal
of Health Services 26(1996): 173β185; and Samuel S. Epstein, Whatβs In Your Milk? (Victoria, British Columbia, Canada:Trafford Publishing,
2006), 197β204.
130 For a review of literature linking elevated levels of IGF-1 with increased risks of breast, colon and prostate cancers, see Samuel S. Epstein,
Whatβs In Your Milk?, 197β204.
131 Gary Steinman, βMechanisms of Twinning VII. Effect of Diet and Heredity on the Human Twinning Rate,β Journal of Reproductive
Medicine, May 2006; S.E. Echternkamp et al, βOvarian Follicular Development in Cattle Selected for Twin Ovulations and Births,β Journal of
Animal Science 82 no. 2 (2004): 459β471; and S. E. Echternkamp et al, βConcentrations of insulin-like growth factor-I in blood and ovarian
follicular fluid of cattle selected for twins,β Biology of Reproduction, 43(1990): 8β14.
132 Powell D.A.; Blaine K.; Morris S.; Wilson J., Agronomic and consumer considerations for Bt and conventional sweet-corn, British Food
Journal, Volume: 105, Issue: 10, Page: 700-713 (Nov 2003)
133 GM Nation? The findings of the public debate, www.gmnation.org.uk/ut_09/ut_9_6.htm#summary
134 To see the Toronto Star photo in Laidlawβs book, go to www.gmwatch.org/p1temp.asp?pid=72&page=1 or
www.powerbase.info/index.php/Shane_Morris
135 Corn Fakes, Private Eye, No. 1194, 28 September-11 October 2007 www.gmwatch.org/latest-listing/46-2007/7525-award-winningpaper-qa-flagrant-fraudq-cambridge-expert-2692007
136 Tim Lambert, Would you eat wormy corn?, September 7 2007
scienceblogs.com/deltoid/2007/09/would_you_eat_wormy_sweet_corn.php
137 βGenetically modified foods, who knows how safe they are?β CBC News and Current Affairs, September 25, 2006.
138 Mike Zelina, et al., The Health Effects of Genetically Engineered Crops on San Luis Obispo County,β A Citizen Response to the SLO Health
Commission GMO Task Force Report, 2006.
139 Bill Lambrecht, Dinner at the New Gene CafΓ©, St. Martinβs Press, September 2001, pg 139
Photo credits
Stanley W. B. Ewen and Arpad Pusztai, βEffect of diets containing genetically modified potatoes expressing Galanthus nivalis lectin on rat small
intestine,β Lancet, 1999 Oct 16; 354 (9187): 1353-4.
M. Malatesta, C. Caporaloni, S. Gavaudan, M. B. Rocchi, S. Serafini, C. Tiberi, G. Gazzanelli, βUltrastructural Morphometrical and
Immunocytochemical Analyses of Hepatocyte Nuclei from Mice Fed on Genetically Modified Soybean,β Cell Struct Funct. 27 (2002): 173β180
Irina Ermakova, βExperimental Evidence of GMO Hazards,β Presentation at Scientists for a GM Free Europe, EU Parliament, Brussels, June 12,
2007
Irina Ermakova, βGenetically modified soy leads to the decrease of weight and high mortality of rat pups of the first generation. Preliminary
studies,β Ecosinform 1 (2006): 4β9.
Professional Scope of Practice *
The information herein on this entire blog site is not intended to replace a one-on-one relationship with a qualified healthcare professional or licensed physician and is not medical advice. We encourage you to make healthcare decisions based on your research and partnership with a qualified healthcare professional.
Blog Information & Scope Discussions
Our information scope is limited to Chiropractic, musculoskeletal, physical medicines, wellness, contributing etiological viscerosomatic disturbances within clinical presentations, associated somatovisceral reflex clinical dynamics, subluxation complexes, sensitive health issues, and/or functional medicine articles, topics, and discussions.
We provide and present clinical collaboration with specialists from various disciplines. Each specialist is governed by their professional scope of practice and their jurisdiction of licensure. We use functional health & wellness protocols to treat and support care for the injuries or disorders of the musculoskeletal system.
Our videos, posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate to and directly or indirectly support our clinical scope of practice.*
Our office has reasonably attempted to provide supportive citations and has identified the relevant research studies or studies supporting our posts. We provide copies of supporting research studies available to regulatory boards and the public upon request.
We understand that we cover matters that require an additional explanation of how they may assist in a particular care plan or treatment protocol; therefore, to discuss the subject matter above further, please feel free to ask Dr. Alex Jimenez, DC, or contact us at 915-850-0900.
We are here to help you and your family.
Blessings
Dr. Alex Jimenez DC, MSACP, RN*, CCST, IFMCP*, CIFM*, ATN*
email: coach@elpasofunctionalmedicine.com
Licensed as a Doctor of Chiropractic (DC) in Texas & New Mexico*
Texas DC License # TX5807, New Mexico DC License # NM-DC2182
Licensed as a Registered Nurse (RN*) in Florida
Florida License RN License # RN9617241 (Control No. 3558029)
Compact Status: Multi-State License: Authorized to Practice in 40 States*
Graduate with Honors: ICHS: MSN-FNP (Family Nurse Practitioner Program)
Degree Granted. Masters in Family Practice MSN Diploma (Cum Laude)
Dr. Alex Jimenez DC, MSACP, MSN-FNP, RN* CIFM*, IFMCP*, ATN*, CCST
My Digital Business Card
Β
Stress on the lower back during pregnancy often leads to back (upper, middle, lower), sciatica,… Read More
Can melatonin help many individuals dealing with sleep issues and help them stay asleep longer… Read More
For older individuals looking for a workout that can help improve overall fitness, can kettlebell… Read More
Can choosing the right pillow help many individuals with neck pain get a full night's… Read More
What is the recommended way to choose a mattress for individuals with back pain? … Read More
Can non-surgical treatments help individuals with piriformis syndrome reduce referred sciatica pain and help restore… Read More