Indian Children Blinded and Crippled By Fluoride In Water

Indian Children Blinded and Crippled By Fluoride In Water:

Of the 200-odd villagers in the Indian town of Gaudiyan, around 135 have bone deformities. A private doctor who conducts social work in the area termed it as a case of skeletal fluorosis -- the result of excess fluoride content in drinking water.

In another part of India, also partly as a result of fluoride poisoning, children are losing their vision. They have been diagnosed with Lamellar Congenital cataract -- a condition in which the eye lenses are damaged.

According to The Times of India:

"...high fluoride content in water and Vitamin A deficiencies is ruining the lives of children of this taluk."

Other examples of such harm include the village of Sogival where the groundwater contains 4.84 ppm of fluoride and two-thirds of the people suffer from skeletal deformities. And in Bihar, the prevalence of physical deformity is yet another testament to excessive fluoride exposure.

For even more stories from India detailing the harm caused by fluoride, please see this link.

Sources:

Express India June 23, 2010

Times of India June 20, 2010

Video Transcript

Hard News September 2009

FluorideAlert.org May 25, 2010

FluorideAlert.org February 17, 2010

FluorideAlert.org February 17, 2010

This is an important topic for a number of reasons and one of the most important is that it helps dispel the popular public health myth that fluoride in the water supply is normal and actually prevents dental caries.

Nothing could be further from the truth as fluoride is a toxin and a poison even when it occurs naturally in your water supply.

India is one of several countries known to have dangerously high levels of fluoride in their drinking water. This poison comes into contact with water supplies when rocks containing fluoride erode or volcanic activity spews fluoride-containing ash into the air, allowing the colorless, odorless substance to enter groundwater (of course in some areas, like the United States, fluoride is intentionally added to water supplies).

In areas where naturally occurring fluoride is high, serious health problems usually become apparent, and that is, unfortunately, what's happening now in India. But these events also have potential relevance to the US, as this summary on fluorosis in India explains.

As of 1999, 17 of India's 32 states and territories were known to have high concentrations of fluoride in water, according to the World Health Organization (WHO), with concentrations as high as 48 mg/liter reported. For comparison, WHO has capped the upper limit of fluoride in drinking water at 1.5 mg/liter.

Sadly, for many people in India there is no access to safer water supplies or reverse osmosis filters that could remove the fluoride from the water, and now generations of children are growing up with serious health problems as a result.

Blindness and Skeletal Fluorosis

In one Indian village, a disturbing trend of eye diseases in children has emerged. Previously healthy children are suffering from vision deterioration, lens damage, retina deterioration and blindness that cannot be reversed.

Health centers in the area are now launching a study of 29,800 children to determine the cause of the eye disorders, with their initial theory being high fluoride content in water, coupled with vitamin A deficiencies and marrying of close relatives.

In another village of about 200 people, about 135 of them suffer from bone deformities that are also thought to be the result of excess fluoride in drinking water. While children in the area appear normal at birth, they begin developing bone problems as they get older.

Skeletal fluorosis, a crippling bone disease, is well-documented and strongly associated with drinking water that contains high levels of fluoride. The disease is known to be endemic in several parts of the world, including India, China and many parts of Africa.

A Cumulative Poison

In order to understand the long-term dangers of fluoride, it's important to realize that fluoride is a cumulative poison.

Ninety-eight percent of the fluoride you ingest in water is absorbed into your blood through your gastrointestinal tract. From there, it enters your body's cellular tissues. On average, about 50 percent of the fluoride you ingest each day gets excreted through your kidneys. The remainder accumulates in your teeth and bones, pineal gland, and other tissues, such as the aorta.

The amount deposited into your bones and teeth varies depending on your age. In children, more than 50 percent of an ingested dose of fluoride is deposited in bone, but in adults only about 10 percent is stored there.

As with teeth, fluoride is deposited in bone by the ionic exchange with hydroxyl-apatite. It does dissolve from bone over time, but at a slower rate than it is deposited, so if your intake remains constant or high, the level of fluoride in your bones increases linearly with age.

Further, if your kidneys are damaged, fluoride accumulation will increase, and with it, the likelihood of harm.

Basically, if you ingest more fluoride than your body is capable of eliminating, various stages of fluorosis may ensue. Symptoms of early skeletal fluorosis include:

• Pains in your bones and joints
• Burning, prickling, and tingling in your limbs
• Muscle weakness
• Chronic fatigue
• Gastrointestinal disorders

There are numerous other health problems associated with the accumulation of fluoride in your body as well, such as:

• Hyperactivity and/or lethargy
• Arthritis
• Dental fluorosis (staining and pitting of teeth)
• Lowered thyroid function
• Lowered IQ, and dementia
• Disrupted immune system

For the people in India and other developing countries who are exposed to dangerously high levels of naturally occurring fluoride, the solution lies in securing safer water supplies or filters to remove the poison.

For those of you in the United States, you should know, too, that this toxin is being intentionally added to your drinking water supplies.

Fluoridated Drinking Water Pawned Off as "Healthy"

Given the well-known health risks of naturally occurring fluoride in drinking water, you may be wondering why the practice of adding fluoride to your tap water began back in 1945 and endorsed by the US Public Health Service in 1950 before any significant health studies of either naturally or artificially fluoridated communities had been published.

Amazingly, the United States is only one of eight countries in the entire developed world that fluoridates more than 50 percent of its water supply. (The other seven are: Australia, Colombia, Ireland, Israel, Malaysia, New Zealand and Singapore.) Canada has a little over 40 percent of its population drinking fluoridated water and that percentage is falling as more and more communities are halting the practice.

Most likely, your dentist – along with countless government and public health officials -- has praised and promoted the use of fluoride, both in toothpaste and drinking water, as one of your must-do regimens to promote strong and healthy teeth.

Unfortunately, they've all bought into the public deception of fluoridation's so-called "safety and effectiveness" and have unwittingly participated in and perpetuated perhaps one of the grandest public health frauds and toxic cover-ups in U.S. history.

As you may know, the theory behind the introduction of fluoride in your water supply initially seems beneficial – to reduce the incidence of dental caries in children.

However, the health dangers of fluoride are so numerous, they far outweigh any potential benefit to your teeth. Dr. Paul Connett, known throughout the world as a leader in the movement against water fluoridation, said in our recent interview:

"First of all, water fluoridation is very bad medicine because once you put it in the water, you can't control the dose. You can't control who gets it. There is no oversight. You're allowing a community to do to everyone what a doctor can do to no one, i.e. force a patient to take a particular medication."

Fluoride Has No Benefits When Ingested

Today, even promoters of fluoridation concede that the major benefit, as far as fighting tooth decay is concerned, is topical; fluoride works from the outside of the tooth, not from inside of your body, so why swallow it?

There is practically no difference in tooth decay between fluoridated and non-fluoridated countries, and no difference between states that have a high- or low percentage of their water fluoridated.

Yet in the United States, children are being exposed to concerning levels of fluoride daily. Dr. Connett says:

"We know that 32 percent of American children have been overexposed to fluoride because you have this telltale sign of dental fluorosis, which in its mildest form is little white specs. But when it gets more serious, it affects more of the surface of your teeth and it becomes colored; yellow, brown and orange mottling of the teeth."

Promoters of fluoridation scoff at these signs, saying that they're "just cosmetic."

But, since we already know that water fluoridation does NOT effectively reduce dental caries, this is an unnecessary cosmetic defect, and, worse yet, it is a worrisome indication that your body has been overexposed to fluoride.

If it's having a detrimental, visual effect on the surface of your teeth, you can be virtually guaranteed that it's also damaging something else inside your body, such as your bones, as is the case in India.

What to Do if You Want to Avoid Fluoridated Water

If you live in the United States and want to avoid drinking municipal tap water that is fluoridated, using a reverse osmosis system in your home will rid your water of fluoride. You are still going to get fluoride when you have meals and beverages downtown, at work, or at a friend's house. Or if you have an organic garden, do you really want to put this poison on your fruits and vegetables?

Also, remember there are many who simply don't have the resources or the know-how to protect themselves and their young children from this pervasive toxin.

This is why The Fluoride Action Network is working hard to pressure the U.S. government to halt the support it gives to fluoridation and also help communities end this outdated, unnecessary and dangerous practice.

If you and your friends and neighbors want to help get fluoride out of your community's water supply please contact the Fluoride Action Network at info@fluoridalert.org . Simply give them your name, state and email address and they will do their best to supply you with contacts in your area and provide you with other supporting material.

Promoters of fluoridation would like you to believe that there are no doctors, dentists, scientists or other professionals opposed to water fluoridation, but this is simply not true.

A statement calling for an end to fluoridation worldwide has been signed by over 3000 professionals.

We encourage all medical and science professionals to sign this statement.

Over a dozen of the professionals who have signed can be seen talking about this issue in the video "Professional Perspectives on Water Fluoridation" which is accessible online at www.FluorideAlert.org.

Dr. Connett has also co-authored a book with two other scientists dealing with the full scientific and ethical arguments against fluoridation that will be published in early October: The Case Against Fluoride: How Hazardous Waste Ended Up in Our Drinking Water and the Bad Science and Powerful Politics that Keep it There. (Chelsea Green publishers.) Advance orders can be placed on Amazon.com.

If you haven't already done so I would also encourage you to watch my recent video with Dr. Connett below on this topic where he expands on this information further and discusses some simple practical measures you can take.

If you want to speak with Dr. Connett in person simply email him at pconnett@fluoridealert.org and give him your phone number.

Related Links:

One of the Biggest Health Frauds EVER Perpetrated on the American People...

Warning: This Daily Habit is Damaging Your Bones, Brain, Kidneys, and Thyroid

What Your Dentist Isn’t Telling You About Fluoride

A Clear and Plastic Danger

A Clear and Plastic Danger: "A Clear and Plastic Danger
By Dr. David Blyweiss on 07/15/2010

I’ve been concerned about the health effects of plastics since I first learned about them back in the 1990s. Since then, research has shown that those handy plastic containers you put your food in contain dubious chemicals like bisphenol A (BPA) and polyvinyl chloride (PVC) that can leach into your food.

A 2008 study in the Journal of the American Medical Association found that people with the highest levels of BPA were twice as likely to suffer from heart disease and diabetes than those with the lowest levels. These substances can disrupt crucial antioxidant and DNA activity in the body, as well as the normal functioning of the endocrine system. But what worries me even more is that, once inside the body, BPA acts like the hormone estrogen. Based on this characteristic, new studies link BPA to reproductive damage in both men and women. It also boosts the risk of developing breast cancer.

Unfortunately, it’s hard to avoid BPA. Along with some food storage containers, you can also find this hormone-disrupting chemical in plastic water bottles and even in the cans that hold many of the foods you eat. The FDA says that this isn’t a threat, but a new Consumer Reports’ test of canned foods (including soups, juice, tuna, and green beans) found that almost all of the 19 name-brand foods tested contain some BPA.

The consumer group reports that a 165-pound adult eating one serving of canned green beans could ingest 80 times more BPA than the recommended upper daily limit. Children eating multiple servings of canned foods daily with BPA levels comparable to the ones they found in some of the tested products could get a dose of BPA approaching levels that have caused adverse effects in several animal studies.

Perhaps most telling is that in Japan major manufacturers voluntarily changed their can linings in 1997 to cut or eliminate the use of BPA because of concerns about health effects. A 2003 Japanese study found that the levels of the chemical in subjects’ urine dropped by 50 percent after the change in cans was made.

But BPA isn’t the only problem. The PVC used in many brands of plastic wrap is also problematic. This type of plastic contains phthlates—plasticizers, which have a similar estrogen-like effect in the human body. And like BPA, PVC has been associated with infertility problems and abnormalities of genital development.

Ideally, you should switch to glass, metal or ceramic containers to store your leftovers. But, I know that’s next to impossible. The next best option is to become well-versed in how to pick your plastics. The best way to tell if a plastic container contains BPA or phthalates is to look at the number on the bottom of the container. Containers marked with a 1, 3, or 7 contain phthalates or BPA, while ones labeled with 2, 4, or 5 are safer.

If plastic storage containers are used, never expose them to heat or use them in the microwave. This can cause even greater leaching. Remove cling wrap from any store-bought meats, cheeses and fish and repackage them in a safer container. It’s also important to throw away any container that is scratched or appears worn since bacteria can hide in these nooks and crannies.

While it’s difficult to completely avoid plastics, minimizing its use can reduce the overall amount of plasticizing chemicals that wind up in your body. And, even though it might seem like a bit more effort when storing your holiday leftovers, opting for safer alternatives to BPA- and PVC-laced containers can give you a big health payoff for years to come.

References:

Baccarelli A. Epigenetics and environmental chemicals. Current Opinions in Pediatrics. 2009;21:243-251.

Concern over canned foods. Consumer Reports. December 2009.

Munguía-López EM. Migration of bisphenol A (BPA) from can coatings into a fatty-food simulant and tuna fish. Food Additives and Contaminants. 2005;22:892-898.

Water Fluoridation May Be Harmful to Your Health

Water Fluoridation May Be Harmful to Your Health

Trained as a chemist, specializing in environmental chemistry, Dr. Paul Connett is known throughout the world as a leader in the movement against water fluoridation because of his knowledge base.

He is truly dedicated to the cause of ending water fluoridation, and heads up an organization called the Fluoride Action Network or www.fluoridealert.org that contains a wealth of information.

In addition, his book, The Case Against Fluoride, is scheduled for release in late September, but is available for pre-order.

In this timely and important book, Connett and his two co-authors, Beck and Micklem, take a new look at the science behind water fluoridation and argue that just because the medical establishment endorses a public health measure, that doesn't mean it's safe.

In the case of water fluoridation, the chemicals used to fluoridate the water that more than 180 million people drink each day are not pharmaceutical grade, but rather hazardous waste products of the phosphate fertilizer industry; it is illegal to dump these into rivers and lakes or release the parent gases into the atmosphere.

In addition, water fluoridation is a prime example of one of the worst medical practices possible—forced medication with no control over the dose or who gets it. Perhaps most shocking of all, it is not subject to any federal regulation.

At once painstakingly-documented and also highly-readable, The Case Against Fluoride brings new research to light, including links between fluoride and harm to your brain, bones, and kidneys, and shows that while there is possible value in topical applications like brushing your teeth with fluoride toothpaste, the evidence that swallowing fluoride reduces tooth decay is surprisingly weak.

In this interview, Dr. Connett shares important information about fluoride and water fluoridation that you may have not been aware of before, and offers practical advice for what you can do to help get fluoride removed from the water supply of the United States and in other fluoridating countries.

Sources:

Paul Connett Interview Transcript (PDF)

Dr. Mercola's Comments:

Amazingly, the United States is only one of eight countries in the entire developed world that fluoridates more than 50 percent of its water supply. (The other seven are: Australia, Colombia, Ireland, Israel, Malaysia, New Zealand and Singapore.)

In Europe, Ireland is the only country that fluoridates more than 50 percent of its drinking water, and England fluoridates 10 percent.

Most of mainland Europe is not fluoridated, and yet, according to World Health Organization data, their teeth are just as good, if not better than Americans'.

One of the central challenges in this debate is that the United States claim to have one of the most advanced scientific countries in the world, yet we're still engaging in a practice that is questionable at best, and extremely harmful at worst.

This interview is part of an ongoing effort to help provide you with the tools to take action in three primary areas, and help you understand that indeed you CAN make a real difference in this area .

Canada also fluoridates about 40 percent of its drinking water, and there, the efforts to eliminate fluoride seem quite optimistic. The fluoridation there is concentrated in Alberta and Ontario, so if Ontario stops water fluoridation, the entire country of Canada could conceivably get rid of it in short order.

In the US, the current focus is on two specific communities: San Diego, California, and Austin, Texas. These areas already have leadership backing this cause, along with favorable media support.

There may be other communities that we're not aware of, and if you're interested in starting a movement in your local community, please let us know you're interested by adding your remarks in the Vital Votes section below.

If you're not already registered, you can do so here. It only takes a moment. We can then help you to get the process rolling.

Is Water Fluoridation Really in the Best Interest of Public Health?

As you may know, the theory behind the introduction of fluoride in your water supply initially seems beneficial – to reduce the incidence of dental caries in children.

However, the health dangers of fluoride are so numerous; they far outweigh any potential benefit to your teeth.

"First of all, water fluoridation is very bad medicine," Dr. Connett says, "because once you put it in the water, you can't control the dose. You can't control who gets it. There is no oversight. You're allowing a community to do to everyone what a doctor can do to no one, i.e. force a patient to take a particular medication."

Secondly, it's both unnecessary and avoidable.

Today, even promoters of fluoridation concede that the major benefits are topical; fluoride works from the outside of the tooth, not from inside of your body, so why swallow it? Why put it in the drinking water when you could just brush your teeth with fluoridated toothpaste if you choose – in addition to drinking it!

Please note that I do NOT believe you should use fluoride in your toothpaste but I am just emphasizing the point that it might work topically but does not work at all when you swallow it. There are far better options for decreasing tooth decay than using a topical poison.

Third, water fluoridation is ineffective.

There is practically no difference in tooth decay between fluoridated and non-fluoridated countries, and no difference between states that have a high- or low percentage of their water fluoridated.

Meanwhile, fluoride can cause significant harm.

"We know that 32 percent of American children have been overexposed to fluoride," Connett says, "because you have this telltale sign of dental fluorosis, which in its mildest form is little white specs. But when it gets more serious, it affects more of the surface of your teeth and it becomes colored; yellow, brown and orange mottling of the teeth."

Promoters of fluoridation scoff at these signs, saying that they're "just cosmetic."

But, since we already know that water fluoridation does NOT effectively reduce dental caries, this is an unnecessary cosmetic defect, and, worse yet, it is a worrisome indication that your body has been overexposed to fluoride. If it's having a detrimental, visual effect on the surface of your teeth, you can be virtually guaranteed that it's also damaging something else inside your body, such as your bones.

"The teeth are the window to the bones," Connett says. "If you've seen the damage to the teeth, what damage can you not see?"

Bone is in fact living tissue that is constantly being replaced through cellular turnover. Bone building is a finely balanced, complicated process.

Fluoride has been known to disrupt this process ever since the 1930s. We have huge concerns about the potential of fluoride to damage the bone and cause symptoms like arthritis and making them more brittle and more prone to fracture.

Water Fluoridation is an Assault on Your Freedom of Choice!

"We now have 23 studies from four different countries; Mexico, Iran, India and China, which indicate that moderate exposure to fluoride is lowering IQ in children," Connett says.

"The lowest level at which they estimate this is happening is 1.9 parts per million of fluoride.

If you've got an effect at 1.9 parts per million with a few hundred children in the study, then there is not enough margin of safety to protect every child that's being exposed to fluoride."

You need a much larger margin of safety to protect children living in fluoridated communities.

Meanwhile, the US has not yet studied the impact of fluoride on IQ.

"The countries which are fluoridated are doing practically no health studies," Connett points out. "They are far more concerned about protecting this policy for some reason than protecting health."

In 2003, the National Research Council appointed one of the most balanced and objective panels of experts that have ever objectively investigated fluoride. They spent about three years studying it and determined that the current "safe" drinking water standard of 4 ppm (parts per million) set by the Environmental Protection Agency (EPA) for fluoride is too high and it should be lowered.

But in the four years since, the EPA has not completed a new health risk assessment and thus we still live with this outdated and unsafe standard, even though the NRC study was specifically requested by the EPA.

When evaluating the issue of water fluoridation it is also important to understand that fluoride is a drug. You can't get fluoride without a prescription! Yet it's being added to your water supply on a mandatory basis at various levels that may or may not be safe for various individuals, especially children, the sick, and the elderly.

Water fluoridation is a major assault on your freedom of choice – to be drugged or not.

Sodium fluoride, which is a far simpler toxin than the fluoride compounds used for most water fluoridation, has also been used for rat and cockroach poisons, so there is no question that it is highly toxic.

Have a Glass of Water, then Call Poison Control!?

"The sad irony here is that the FDA, which does not regulate fluoride in drinking water, does regulate toothpaste," Connett says, "and on the back of a tube of fluoridated toothpaste… it must state that "if your child swallows more than the recommended amount, contact a poison control center."

The amount that they're talking about, the recommended amount, which is a pea-sized amount, is equivalent to one glass of water.

The FDA is not putting a label on the tap saying don't drink more than one glass of water. If you do, contact a poison center. So you got this tweedledum and tweedledee…

There is no question that fluoride -- not an excessive amount -- can cause serious harm. There have been examples of children who swallowed the gel that is used for topical treatment and they died as a consequence. So fluoride is extremely toxic."

According to Dr. Connett, you also increase your child's risk for dental fluorosis if he brushes his teeth with fluoridated toothpaste twice a day compared to just once.

"We're not talking about killing people outright with drinking water," Connett says.

"What we're concerned about is the chronic exposure… It's poisonous."

Fluoride Breaks Down Your Bones and Damage Your Thyroid

Approximately fifty percent of the fluoride that you ingest each day ends up accumulating in your bones over a lifetime. So you're steadily increasing the fluoride levels in your bones over time.

Dr. Connett recounts the evidence gleaned from India and China, where some areas have high natural fluoride levels. There, the initial symptoms of fluoride poisoning are arthritis-like symptoms such as joint pains.

Despite these findings, no study has ever been conducted in the US to investigate whether there's an association between people living in fluoridated areas and increasing arthritis rates.

Fluoride also lowers thyroid function. It was used in medicine during the 1930s through 1950s in Europe to treat patients with overactive thyroid glands. This is a very real and significant concern, especially today as millions of people suffer with low thyroid function.

Women seem to be particularly sensitive to this. I've seen tens of thousands of patients, and low thyroid function is a very common problem.

If you exhibit symptoms of low thyroid function you'll want to get a TSH (thyroid stimulating hormone) test. If it's above 1.5 then you probably need to address your thyroid, at which point it becomes mandatory to avoid fluoride from all sources.

Common symptoms of decreased thyroid function include:

• Low body temperature
• Lack of energy
• Dry skin
• Tendency toward constipation
• Not sweating well

Your drinking water and fluoridated toothpaste are the two most obvious sources, but you may also be exposed to fluoride from certain drugs, if they are metabolized to free fluoride in the body. This may occur with some antidepressants and some antibiotics, especially the fluoroquinolones.

Another source is pesticides, so it also becomes more important to eat organic.

Where Does the Fluoride Come From?

It's important to make a distinction between the natural fluorides found in the environment versus the toxic chemicals used for fluoridating your water. Ninety percent of the chemicals used in fluoridation in the United States do not occur naturally.

"It's a substance called hexafluorosilicic acid or its sodium salt: silicon fluorides," Connett explains.

"These silicon fluorides are captured pollutants from the phosphate fertilizer industry. When you're making phosphate fertilizers… the process generates two very toxic gasses; hydrogen fluoride and silicon tetrafluoride.

For about a hundred years, these decimated the local area -- the vegetation; crippled cattle and so on. Eventually, they were required to capture these toxic gasses, using a spray of water. That spray of water produces silicon fluorides.

That scrubbing liquor cannot be dumped into the sea by international law. It can't be dumped locally because it's too concentrated. But if someone buys it, it's no longer a hazardous waste, it's a product.

… Who buys it?

The public water utilities buy this stuff and put it in our drinking water. It's absolutely absurd."

Dr. William Hirzy from the EPA has pointed out that if it goes into the air, it's a pollutant. If it goes into the local water, it's pollution. But if the public water utilities buy it and pour it in our drinking water, it's no longer a pollutant. All of a sudden like magic it's a beneficial public health measure.

"So not only are we doing something quite unique, using the public water supply to deliver medicine... we're using the public water supply to get rid of hazardous waste from the phosphate industry," Connett says.

It makes a lot of money for them [this way, because otherwise it would cost] a lot of money to get rid of it as hazardous waste."

Making matters worse, if that's even possible, is that in recent times the US has started purchasing these industrial fluoride products from China, as phosphate-producing industry in Florida has been reduced. However, some communities in the US have stopped using China-made fluoride because it was producing a white sludge that jammed up the delivery system.

"The Center for Disease Control engineer said, "We don't know what this sludge is but we know it's safe," Connett says. "But if you don't know what it is, how can you say it's safe?"

Since I've taken a personal interest in this, my team will try to obtain some of this fluoride from China and have it analyzed by a third-party, independent laboratory to see what's really in it… Once I have those results, I will share them with you in this newsletter.

The REAL Cause of Tooth Decay

As far as tooth decay is concerned, this is not caused by lack of fluoride.

Tooth decay is caused by acids in your mouth, typically created from sugar being metabolized by bacteria (Streptococcus mutans), and as you may already know, the number one source of calories in the United States is high fructose corn syrup.

The acid produced then attacks your enamel. Eventually the bacteria can get into the dentine, at which point tooth decay sets in.

You typically don't find dental caries in more primitive societies that do not consume these vast amounts of sugar.

"We need education, not fluoridation," Connett agrees. "That education would have a double dividend. By avoiding high fructose sugar, we'll not only score a huge benefit with dental decay but also with obesity and health."

A Special Note about Using Tap Water when Making Infant Formula

Most of the people who are educated about fluoride will avoid drinking municipal tap water that is fluoridated, and will use a reverse osmosis system in your home to rid your water of fluoride.

However, there are many who simply don't have the resources or the know-how to protect themselves and their young children.

In November of 2006, the American Dental Association (ADA) sent out an email to alert its members of their recommendation to parents to not use fluoridated tap water to make infant formula. A few days later, the CDC followed suit. But neither of them openly informed the public!

So there are millions of parents out there using tap water to make up formula, oblivious of the fact that the agencies that promote fluoridation in this country have issued a specific warning against using fluoridated water for this purpose.

Not only that, but by fluoridating the municipal water supply, you doom many low income families to fail to protect their young children from this dangerous drug, even if they have this information.

Help End Water Fluoridation in Canada and the United States

The Fluoride Action Network is an absolutely phenomenal resource for further education, and they're doing much to pressure the US government for change.

Their statement calling for an end to fluoridation worldwide now been signed by over 2,800 professionals.

We encourage all medical and science professionals to sign this statement.

In addition, I highly recommend getting a copy of Dr. Connett's new book, The Case Against Fluoride. It is scheduled for release in late September, but is available for pre-order.

Last but not least, stay tuned, as we will be working together to devise a complete game plan to tackle this issue head on. Once we reach the tipping point, which may be as little as five percent of the population, we will be able to reverse the policies of water fluoridation.

Our strategy will begin with addressing Canada, because 60 percent of Canada is already un-fluoridated. If we can get the rest of Canada to stop fluoridating their water, we believe the U.S. will be forced to follow.

If you live in Ontario, Canada, please join the ongoing effort by contacting Diane Sprules at diane.sprules@cogeco.ca.

The point-of-contact for Toronto is Aliss Terpstra. You may email her at aliss@nutrimom.ca.

We're also going to address the two US communities: Austin, Texas and San Diego, California.

If you live in Austin, Texas, you can join the effort by contacting Rae Nadler-Olenick at either: info@fluoridefreeaustin.com or fluoride.info@yahoo.com, or by regular mail or telephone:

POB 7486
Austin, Texas 78713
Phone: (512) 371-3786

If you're in San Diego, California, contact Patty Ducey-Brooks, publisher of the Presidio Sentinel at pbrooks936@aol.com .

You can always visit www.FluorideAlert.org for the most recent updates and progress.

In addition, we're willing to support any credible activist for this cause, who is scientifically based and grounded, regardless of where you live in the US. We can provide resources to help support you in your effort to eliminate fluoride from your local community – and it really needs to be a community battle.

We're not going to be able to pass a federal law against fluoridation. There is not going to be a Presidential mandate or even a State-wide elimination. This change will occur one community at a time.

"It's politics that is interfering with science in this issue,"Connett says . "It's a matter of political will, and you cannot change political will if you don't get the people. We must involve the people."

So please, get informed; stay involved.

Related Links:

One of the Biggest Health Frauds EVER Perpetrated on the American People...

Fluoride Damages Your Brain!

The Fluoride Controversy

PLoS Medicine: Medical Journals Are an Extension of the Marketing Arm of Pharmaceutical Companies

PLoS Medicine: Medical Journals Are an Extension of the Marketing Arm of Pharmaceutical Companies

Medical Journals Are an Extension of the Marketing Arm of Pharmaceutical Companies

Medical journals have become dependent on the pharmaceutical industry for their survival, which can have a corrupting influence on their content, argues Smith, the former editor of the BMJ.

Richard Smith

Citation: Smith R (2005) Medical Journals Are an Extension of the Marketing Arm of Pharmaceutical Companies. PLoS Med 2(5): e138. doi:10.1371/journal.pmed.0020138
Published: May 17, 2005
Copyright: © 2005 Richard Smith. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Competing interests: RS was an editor for the BMJ for 25 years. For the last 13 of those years, he was the editor and chief executive of the BMJ Publishing Group, responsible for the profits of not only the BMJ but of the whole group, which published some 25 other journals. He stepped down in July 2004. He is now a member of the board of the Public Library of Science, a position for which he is not paid.
Richard Smith is Chief Executive of UnitedHealth Europe, London, United Kingdom. E-mail: richardswsmith@yahoo.co.uk

“Journals have devolved into information laundering operations for the pharmaceutical industry”, wrote Richard Horton, editor of the Lancet, in March 2004 [1]. In the same year, Marcia Angell, former editor of the New England Journal of Medicine, lambasted the industry for becoming “primarily a marketing machine” and co-opting “every institution that might stand in its way” [2]. Medical journals were conspicuously absent from her list of co-opted institutions, but she and Horton are not the only editors who have become increasingly queasy about the power and influence of the industry. Jerry Kassirer, another former editor of the New England Journal of Medicine, argues that the industry has deflected the moral compasses of many physicians [3], and the editors of PLoS Medicine have declared that they will not become “part of the cycle of dependency…between journals and the pharmaceutical industry” [4]. Something is clearly up.

The Problem: Less to Do with Advertising, More to Do with Sponsored Trials

The most conspicuous example of medical journals' dependence on the pharmaceutical industry is the substantial income from advertising, but this is, I suggest, the least corrupting form of dependence. The advertisements may often be misleading [5,6] and the profits worth millions, but the advertisements are there for all to see and criticise. Doctors may not be as uninfluenced by the advertisements as they would like to believe, but in every sphere, the public is used to discounting the claims of advertisers.

The much bigger problem lies with the original studies, particularly the clinical trials, published by journals. Far from discounting these, readers see randomised controlled trials as one of the highest forms of evidence. A large trial published in a major journal has the journal's stamp of approval (unlike the advertising), will be distributed around the world, and may well receive global media coverage, particularly if promoted simultaneously by press releases from both the journal and the expensive public-relations firm hired by the pharmaceutical company that sponsored the trial. For a drug company, a favourable trial is worth thousands of pages of advertising, which is why a company will sometimes spend upwards of a million dollars on reprints of the trial for worldwide distribution. The doctors receiving the reprints may not read them, but they will be impressed by the name of the journal from which they come. The quality of the journal will bless the quality of the drug.

(Illustration: Margaret Shear, Public Library of Science)
doi:10.1371/journal.pmed.0020138.g001

Fortunately from the point of view of the companies funding these trials—but unfortunately for the credibility of the journals who publish them—these trials rarely produce results that are unfavourable to the companies' products [7,8]. Paula Rochon and others examined in 1994 all the trials funded by manufacturers of nonsteroidal anti-inflammatory drugs for arthritis that they could find [7]. They found 56 trials, and not one of the published trials presented results that were unfavourable to the company that sponsored the trial. Every trial showed the company's drug to be as good as or better than the comparison treatment.

By 2003 it was possible to do a systematic review of 30 studies comparing the outcomes of studies funded by the pharmaceutical industry with those of studies funded from other sources [8]. Some 16 of the studies looked at clinical trials or meta-analyses, and 13 had outcomes favourable to the sponsoring companies. Overall, studies funded by a company were four times more likely to have results favourable to the company than studies funded from other sources. In the case of the five studies that looked at economic evaluations, the results were favourable to the sponsoring company in every case.

The evidence is strong that companies are getting the results they want, and this is especially worrisome because between two-thirds and three-quarters of the trials published in the major journals—Annals of Internal Medicine, JAMA, Lancet, and New England Journal of Medicine—are funded by the industry [9]. For the BMJ, it's only one-third—partly, perhaps, because the journal has less influence than the others in North America, which is responsible for half of all the revenue of drug companies, and partly because the journal publishes more cluster-randomised trials (which are usually not drug trials) [9].

Why Do Pharmaceutical Companies Get the Results They Want?

Why are pharmaceutical companies getting the results they want? Why are the peer-review systems of journals not noticing what seem to be biased results? The systematic review of 2003 looked at the technical quality of the studies funded by the industry and found that it was as good—and often better—than that of studies funded by others [8]. This is not surprising as the companies have huge resources and are very familiar with conducting trials to the highest standards.

The companies seem to get the results they want not by fiddling the results, which would be far too crude and possibly detectable by peer review, but rather by asking the “right” questions—and there are many ways to do this [10]. Some of the methods for achieving favourable results are listed in the Sidebar, but there are many ways to hugely increase the chance of producing favourable results, and there are many hired guns who will think up new ways and stay one jump ahead of peer reviewers.

Then, various publishing strategies are available to ensure maximum exposure of positive results. Companies have resorted to trying to suppress negative studies [11,12], but this is a crude strategy—and one that should rarely be necessary if the company is asking the “right” questions. A much better strategy is to publish positive results more than once, often in supplements to journals, which are highly profitable to the publishers and shown to be of dubious quality [13,14]. Companies will usually conduct multicentre trials, and there is huge scope for publishing different results from different centres at different times in different journals. It's also possible to combine the results from different centres in multiple combinations.

These strategies have been exposed in the cases of risperidone [15] and odansetron [16], but it's a huge amount of work to discover how many trials are truly independent and how many are simply the same results being published more than once. And usually it's impossible to tell from the published studies: it's necessary to go back to the authors and get data on individual patients.

Peer Review Doesn't Solve the Problem

Journal editors are becoming increasingly aware of how they are being manipulated and are fighting back [17,18], but I must confess that it took me almost a quarter of a century editing for the BMJ to wake up to what was happening. Editors work by considering the studies submitted to them. They ask the authors to send them any related studies, but editors have no other mechanism to know what other unpublished studies exist. It's hard even to know about related studies that are published, and it may be impossible to tell that studies are describing results from some of the same patients. Editors may thus be peer reviewing one piece of a gigantic and clever marketing jigsaw—and the piece they have is likely to be of high technical quality. It will probably pass peer review, a process that research has anyway shown to be an ineffective lottery prone to bias and abuse [19].

Furthermore, the editors are likely to favour randomised trials. Many journals publish few such trials and would like to publish more: they are, as I've said, a superior form of evidence. The trials are also likely to be clinically interesting. Other reasons for publishing are less worthy. Publishers know that pharmaceutical companies will often purchase thousands of dollars' worth of reprints, and the profit margin on reprints is likely to be 70%. Editors, too, know that publishing such studies is highly profitable, and editors are increasingly responsible for the budgets of their journals and for producing a profit for the owners. Many owners—including academic societies—depend on profits from their journals. An editor may thus face a frighteningly stark conflict of interest: publish a trial that will bring US$100 000 of profit or meet the end-of-year budget by firing an editor.

Journals Should Critique Trials, Not Publish Them

How might we prevent journals from being an extension of the marketing arm of pharmaceutical companies in publishing trials that favour their products? Editors can review protocols, insist on trials being registered, demand that the role of sponsors be made transparent, and decline to publish trials unless researchers control the decision to publish [17,18]. I doubt, however, that these steps will make much difference. Something more fundamental is needed.

Firstly, we need more public funding of trials, particularly of large head-to-head trials of all the treatments available for treating a condition. Secondly, journals should perhaps stop publishing trials. Instead, the protocols and results should be made available on regulated Web sites. Only such a radical step, I think, will stop journals from being beholden to companies. Instead of publishing trials, journals could concentrate on critically describing them.

Examples of Methods for Pharmaceutical Companies to Get the Results They Want from Clinical Trials

• 
  
  Conduct a trial of your drug against a treatment known to be inferior.
• 
  
  Trial your drugs against too low a dose of a competitor drug.
• 
  
  Conduct a trial of your drug against too high a dose of a competitor drug (making your drug seem less toxic).
• 
  
  Conduct trials that are too small to show differences from competitor drugs.
• 
  
  Use multiple endpoints in the trial and select for publication those that give favourable results.
• 
  
  Do multicentre trials and select for publication results from centres that are favourable.
• 
  
  Conduct subgroup analyses and select for publication those that are favourable.
• 
  
  Present results that are most likely to impress—for example, reduction in relative rather than absolute risk.

Acknowledgments

This article is based on a talk that Richard Smith gave at the Medical Society of London in October 2004 when receiving the HealthWatch Award for 2004. The speech is reported in the January 2005 HealthWatch newsletter [20]. The article overlaps to a small extent with an article published in the BMJ [21].

References

1. Horton R (2004) The dawn of McScience. New York Rev Books 51(4): 7–9. Find this article online
2. Angell M (2005) The truth about drug companies: How they deceive us and what to do about it. New York: Random House. 336 p.
3. Kassirer JP (2004) On the take: How medicine's complicity with big business can endanger your health. New York: Oxford University Press. 251 p.
4. Barbour V, Butcher J, Cohen B, Yamey G (2004) Prescription for a healthy journal. PLoS Med 1: e22. doi: 10.1371/journal.pmed.0010022.
5. Wilkes MS, Doblin BH, Shapiro MF (1992) Pharmaceutical advertisements in leading medical journals: Experts' assessments. Ann Intern Med 116: 912–919. Find this article online
6. Villanueva P, Peiro S, Librero J, Pereiro I (2003) Accuracy of pharmaceutical advertisements in medical journals. Lancet 361: 27–32. Find this article online
7. Rochon PA, Gurwitz JH, Simms RW, Fortin PR, Felson DT, et al. (1994) A study of manufacturer-supported trials of nonsteroidal anti-inflammatory drugs in the treatment of arthritis. Arch Intern Med 154: 157–163. Find this article online
8. Lexchin J, Bero LA, Djulbegovic B, Clark O (2003) Pharmaceutical industry sponsorship and research outcome and quality. BMJ 326: 1167–1170. Find this article online
9. Egger M, Bartlett C, Juni P (2001) Are randomised controlled trials in the BMJ different? BMJ 323: 1253. Find this article online
10. Sackett DL, Oxman AD (2003) HARLOT plc: An amalgamation of the world's two oldest professions. BMJ 327: 1442–1445. Find this article online
11. Thompson J, Baird P, Downie J (2001) The complete text of the independent inquiry commissioned by the Canadian Association of University Teachers. The Olivieri report. Toronto: Lorimer. 584 p.
12. Rennie D (1997) Thyroid storm. JAMA 277: 1238–1243. Find this article online
13. Rochon PA, Gurwitz JH, Cheung M, Hayes JA, Chalmers TC (1994) Evaluating the quality of articles published in journal supplements compared with the quality of those published in the parent journal. JAMA 272: 108–113. Find this article online
14. Cho MK, Bero LA (1996) The quality of drug studies published in symposium proceedings. Ann Intern Med 124: 485–489. Find this article online
15. Huston P, Moher D (1996) Redundancy, disaggregation, and the integrity of medical research. Lancet 347: 1024–1026. Find this article online
16. Tramèr MR, Reynolds DJM, Moore RA, McQuay HJ (1997) Impact of covert duplicate publication on meta-analysis: A case study. BMJ 315: 635–640. Find this article online
17. Davidoff F, DeAngelis CD, Drazen JM, Hoey J, Hojgaard L, et al. (2001) Sponsorship, authorship, and accountability. Lancet 358: 854–856. Find this article online
18. De Angelis C, Drazen JM, Frizelle FA, Haug C, Hoey J, et al. (2004) Clinical trial registration: A statement from the International Committee of Medical Journal Editors. Lancet 364: 911–912. Find this article online
19. Godlee F, Jefferson T (2003) Peer review in health sciences, 2nd ed. London: BMJ Publishing Group. 367 p.
20. Garrow J (2005 January) HealthWatch Award winner. HealthWatch 56: 4–5. Find this article online
21. Smith R (2003) Medical journals and pharmaceutical companies: Uneasy bedfellows. BMJ 326: 1202–1205. Find this article online

PLoS Medicine: Ghostwriting at Elite Academic Medical Centers in the United States

Ghostwriting at Elite Academic Medical Centers in the United States

Jeffrey Lacasse and Jonathan Leo assess ghostwriting policies at 50 academic medical centers in the United States and find that only 10 explicitly prohibit ghostwriting.

Jeffrey R. Lacasse^1*, Jonathan Leo²

1 School of Social Work, College of Public Programs, Arizona State University, Phoenix, Arizona, United States of America, 2 Lincoln Memorial University - DeBusk College of Osteopathic Medicine, Harrogate, Tennessee, United States of America

Citation: Lacasse JR, Leo J (2010) Ghostwriting at Elite Academic Medical Centers in the United States. PLoS Med 7(2): e1000230. doi:10.1371/journal.pmed.1000230
Published: February 2, 2010
Copyright: © 2010 Lacasse, Leo. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: No specific funding was received to write this article.
Competing interests: The authors declare that they have no financial conflicts of interest. JL and JRL are members of Healthy Skepticism, an international nonprofit organization dedicated to reducing harm from misleading drug promotion. JRL serves on the management board of Healthy Skepticism.
* E-mail: jeffrey.lacasse@asu.edu
Provenance: Not commissioned; externally peer-reviewed.

Background 

Medical ghostwriting, the practice of pharmaceutical companies secretly authoring journal articles published under the byline of academic researchers, is a troubling phenomenon because it is dangerous to public health [1]. For example, ghostwritten articles on rofecoxib [2] probably contributed to “…lasting injury and even deaths as a result of prescribers and patients being misinformed about risks” [3]. Study 329, a randomized controlled trial of paroxetine in adolescents, was ghostwritten [4]–[7] to claim that paroxetine is “generally well tolerated and effective for major depression in adolescents” [8], although data made available through legal proceedings show that “Study 329 was negative for efficacy on all 8 protocol specified outcomes and positive for harm” [9]. Even beyond frank misrepresentation of data, commercially driven ghostwritten articles shape the medical literature in subtler but important ways, affecting how health conditions and treatments are perceived by clinicians. The ability of industry to exercise clandestine influence over the peer-reviewed medical literature is thus a serious threat to public health [1],[10].

In 2009, the Institute of Medicine recommended that US-based academic medical centers enact policies that prohibit ghostwriting by their faculties [11]. However, to date, there has been no systematic assessment of ghostwriting policies at academic medical centers. Since US-based academic medical centers generate biomedical research for a worldwide audience, we chose to conduct the first such investigation on elite US-based academic medical centers. Our methods are shown in Box 1. We sought to describe the current policy situation at US-based academic centers and then to propose an ideal ghostwriting policy.

Box 1. Methods

At the beginning of the 2009–2010 academic year, we evaluated the policies of the top-50 academic medical centers by research ranking according to the 2009 US News and World Report [29]. To avoid response bias, and given that faculty policies are commonly published on the World Wide Web, we searched for publicly available policy documents. We used a standardized search protocol in the Google search engine and key phrases used in policies regulating authorship, ghostwriting, and conflicts of interest. When we were unable to locate a published authorship policy, we contacted a reference librarian at the institution to verify that no policy was available. We also searched each Web site to see if any conflict-of-interest policies or faculty manuals were available on-line. We retrieved only policies that were publicly available and applicable to the entire academic medical center. Our retrieval method removed social desirability bias as a possible confounder but was time-intensive, leading us to examine only the top-50 schools, a trade-off we found reasonable given the influential nature of elite US-based medical schools in the worldwide biomedical research community and the exploratory nature of this research.

One rater (JRL) extracted data from the policies. If an academic medical center explicitly prohibited ghostwriting, this was coded as such, and the policy was transcribed. If ghostwriting was not mentioned, but there was an authorship policy, the policy was coded on whether it mandated (1) a substantive contribution to qualify for authorship and (2) that all individuals who make substantial contributions to the manuscript be listed as authors. Inclusion of both (1) and (2) was coded as prohibiting ghostwriting in practice.

To ensure reliability, two sets of data were blindly recoded by the second author (JL). First, a 50% random sample of those medical centers coded as lacking any authorship policies was recoded. There was disagreement on the existence of an authorship policy at one institution, which was resolved through discussion. Second, a 50% random sample of institutions with authorship policies were recoded on the two primary variables of interest, with perfect agreement between the two raters. All data are available as an Excel spreadsheet file, which includes hyperlinks to each institution's policies (Dataset S1), or as a PDF file (Dataset S2).

Findings of Our Survey 

Of the 50 academic medical centers that we examined (Box 1), ten (20%) explicitly prohibit ghostwriting. Of these ten, seven (14%) include some definition of ghostwriting in their policy, while three (6%) prohibit ghostwriting without defining the term. Many schools have an authorship policy that does not clearly ban all aspects of ghostwriting (n = 13, 26%); the most common reason is a failure to require that all qualified authors be listed. Three academic medical centers (6%) have stringent authorship policies that prohibit it in practice (by requiring both a substantive contribution to qualify for authorship and that all who qualify for authorship be listed) but do not mention ghostwriting by name (Table 1).

Table 1. Published policies of academic medical centers meeting specific criteria (n = 50).
doi:10.1371/journal.pmed.1000230.t001

By combining the ten schools that explicitly ban ghostwriting with the three schools that have authorship policies banning it in practice, we find that 13 of the top-50 academic medical centers (26%) have policies in place prohibiting medical ghostwriting. Six of the top-ten schools ban ghostwriting in practice, and all top-ten academic medical centers have published authorship policies. Although most schools (n = 45, 90%) had some policy documents posted online, the majority of academic medical centers (n = 26, 52%) had no published policies at all on either ghostwriting or authorship. The Web sites of two schools stated that they did have such policies, but the policies were not currently available online.

Implications of These Findings

A minority of top-50 US-based academic medical centers (n = 13, 26%) publicly prohibit their faculty from participating in ghostwriting. It is ironic that ghostwriting, a major threat to public health, is generally not prohibited within institutions that exist to train physicians and improve the public health. In this way, academic medical centers enable the pharmaceutical industry to covertly shape the medical literature in favor of commercial interests. When a pharmaceutical salesperson hands a clinician an article reprint, the name of the institution on the front page of the reprint serves as a stamp of approval. The article is not viewed as an advertisement, but as scientific research; the reprint is an effective marketing tool because peer-reviewed journal articles generated in academia are perceived to be the result of unbiased scientific inquiry. Deception regarding authorship prevents a discriminating audience from properly assessing the impact of bias in the published article [10]. Importantly, this deception is impossible without the cooperation of faculty employed by academic medical centers.

The practice of ghostwriting explicitly violates the usual norms of academia. We are not aware of any other academic fields where it is acceptable for professors to allow themselves to be listed as authors on research papers they did not write, or to purposefully conceal the contributions of industry coauthors in order to mislead readers. A recent New York Times article characterizes medical ghostwriting as “an academic crime akin to plagiarism” [12]. Anecdotally, we find many of our academic colleagues are stunned to hear about ghostwriting in medical schools, and some of our graduate students express dismay. (They have to write their own papers, and face disciplinary action and even expulsion if they submit term papers they did not write). In contrast, academic medical centers in the US and Europe employ professors who are publicly known to have participated in ghostwriting (e.g., [4]–[6],[13]). The culture of biomedical research apparently condones or at best takes a neutral position when it comes to ghostwriting. This suggests that ghostwriting will continue to be a problem until policy solutions are implemented. While our survey examined only published policies, the dearth of such policies is cause for concern.

Perhaps ghostwriting policies should be examined in the context of existing policies meant to regulate ethical research behavior. It is possible that some academic medical centers already prohibit ghostwriting under other rules of research integrity. For instance, ghostwriting may be characterized as a form of plagiarism [14], and to our knowledge, all academic institutions consider plagiarism to be a form of academic misconduct. Some academics have listed ghostwritten publications on their curricula vitae, meaning that they were considered for promotion and/or grants on the basis of fraudulent authorship, which would seem to be grounds for disciplinary action. It has been reported that academics receive payments from industry for participation in ghostwriting, and many institutions have rules requiring faculty to report outside income. Failure to report such income truthfully may violate existing policies. In theory, an administrator could penalize a violation of such policies by a faculty member who has participated in ghostwriting. If any of this has ever occurred, it is not publicly known.

A policy is only as useful as it is enforceable. A policy prohibiting ghostwriting that cannot be effectively enforced is unlikely to change practice. It is worth considering, then, whether existing policies of academic medical centers regulating authorship and ghostwriting clearly define “ghostwriting”? Is a policy useful if it forbids ghostwriting but never defines the term? Can we envision an academic being sanctioned for violating a policy that does not define its critical terms? Or does this lack of clarity provide “wiggle room” to evade sanctions? Our review of existing ghostwriting policies (see Datasets S1 and S2) indicates that the clarity of many policies could be improved substantially. For instance, the New York Times reported that Duke University has a policy which bans ghostwriting [15]. On closer examination, what Duke's policy prohibits is courtesy authorship—but it does not require that all contributors who qualify as authors be listed as such. The policy requires that a substantial contribution be made to qualify for authorship, but does not prohibit the concealment of corporate writers in the preparation of the manuscript. A professor could follow this policy to the letter and still participate in something most people would call “ghostwriting” [16] by failing to list a corporate coauthor in the author byline. Other existing ghostwriting policies have similar deficiencies and ambiguities.

An Unambiguous Policy Proposal

Ghostwriting was once the “dirty little secret” of the medical literature [3], but this no longer is the case. Pharmaceutical companies have used ghostwriting to market sertraline [17], olanzapine [18], gabapentin [19], estrogen replacement therapy [20], rofecoxib [2], paroxetine [4],[21], methylphenidate [22], milnaciprin [23], venlafaxine [24], and dexfenfluramine [25]. Ghostwriting is now known to be a major industry [26].

In the near future, we expect administrators of academic medical centers to enact policies that regulate medical ghostwriting. Such policies must be operationalized specifically enough to actually change practice. A problematic policy may be worse than no policy at all, as it may give the misleading impression that the ghostwriting problem has been solved. Therefore, we make the following policy proposal to academic medical centers worldwide.

The Proposal

First, deans of academic medical centers should immediately inform their faculties that a ban on medical ghostwriting will be enacted shortly. Following the suggestion by Barton Moffatt and Carl Elliot [1], the remaining months in the 2009–2010 academic year should be a period of amnesty. Faculty who have participated in ghostwriting will be allowed to come forward and describe their involvement. Known ghostwritten papers should be reevaluated by the academic medical community and considered for retraction.

Next, a policy that clearly defines participation in ghostwriting as a form of academic misconduct should be implemented at the beginning of the 2010–2011 academic year. By modifying several existing authorship policies to close any loopholes and be as specific as possible, we suggest the following wording:

“All listed authors on a publication must meet the authorship criteria set by the International Committee of Medical Journal Editors. Making minor revisions to a manuscript does not qualify as authorship. Participating in the creation of ghost-authored manuscripts is not permitted. A ghost author is defined as someone who makes substantial contributions to writing a publication but is not listed as an author. All individuals who have made a substantial contribution to the manuscript must be listed as authors. Accurately reporting authorship is essential for maintaining research integrity, and violating any of these rules is considered research misconduct akin to plagiarism or falsification of data.”

Implementation and Enforcement

Government funding agencies can play a primary role in encouraging the adoption of this policy. Francis Collins, Director of the US National Institutes of Health (NIH), recently remarked that “I was shocked by that revelation—that people would allow their names to be used on articles they did not write, that were written for them, particularly by companies that have something to gain by the way the data is presented…if we want to have the integrity of science preserved—that's not the way to do it” [27]. We agree, and suggest that, to encourage the adoption of this policy, NIH and similar funding agencies should refuse to disperse any public research funds to institutions that do not adopt a policy which bans ghostwriting, as we have suggested above. Academic medical centers are funded with public monies because they ostensibly serve the public good. Since ghostwriting harms public health and serves commercial rather than public interests, governments should not support institutions that permit ghostwriting.

At the institutional level, vigorous enforcement efforts should accompany the implementation of such policies. Administrators should carefully monitor the medical literature for clues of ghostwriting, such as an acknowledgment of a medical writer's assistance in a peer-reviewed journal article. When a medical writer is thanked, this will be taken to mean that they do not qualify for authorship, much in the way that a copyeditor does not receive a byline credit. At present, such acknowledgments are suspected to mean that the medical writer actually ghostwrote the paper (Figure 1) [28], but the implementation of a stringent ghostwriting policy will require strict accuracy on this issue. When there is doubt, aggressive investigative action should be taken. The empirical findings of medical literature are unlikely to change, but reports of authorship would thus be honest and transparent.

Figure 1. Acknowledging ghostwriters does not accurately reflect their authorship role.

Modified from [14]. Used under a Creative Commons license which permits the modification and re-use of intellectual content as long as it is properly acknowledged.

doi:10.1371/journal.pmed.1000230.g001

When it comes to light that an academic has violated this policy, rapid disciplinary action should result. Sanctions should be equivalent to those used in cases of plagiarism or falsification of data. When a behavior poses a significant public health risk, most governments punish such behavior vigorously. For instance, most governments heavily penalize people who drive an automobile while intoxicated; the goal is to protect the public by deterring the behavior. Similarly, it is hard to envision a policy that protects the public from ghostwriting without punishing the behavior.

Ultimately, this policy requires only that academic medical centers follow the norms of science, as exemplified by other departments of the university. Honest and transparent reporting of authorship has always been an essential element of scientific communication. We can think of no ethical or scientific reason why this proposal should not be adopted by every academic medical center.

Conclusion

Medical ghostwriting is a threat to public health which currently takes place only due to the cooperation of researchers employed at academic medical centers. Although there is growing awareness of the danger posed by medical ghostwriting, we find that few academic medical centers have public policies which prohibit this behavior, and many of the existing policies are ambiguous or ill-defined. We have proposed an unambiguous policy which defines participating in medical ghostwriting as academic misconduct akin to plagiarism or falsifying data. By adopting and enforcing this policy, academic medical centers would adhere to the norms of science followed across the rest of the University, and would no longer facilitate clandestine industry influence over the peer-reviewed scientific literature. By prohibiting medical ghostwriting, academic medical centers have a rare opportunity- to significantly reduce a major threat to public health with the stroke of a pen.

Supporting Information

Dataset S1.

Ghostwriting policies by academic medical center - Raw data file in Microsoft Excel format.

(0.07 MB XLS)

Dataset S2.

Ghostwriting policies by academic medical center - Raw data file in PDF format.

(0.09 MB PDF)

Acknowledgments

We thank Tomi Gomory for his helpful comments on a draft of this manuscript. We also acknowledge Michael J. Womack, MSW, and Kathryn Gerber, MSW, for research assistance.

Author Contributions

ICMJE criteria for authorship read and met: JRL JL. Wrote the first draft of the paper: JRL. Contributed to the writing of the paper: JRL JL.

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