Saturday, October 30, 2010

Lies, Damned Lies, and Medical Science

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MUCH OF WHAT MEDICAL RESEARCHERS CONCLUDE IN THEIR STUDIES IS MISLEADING, EXAGGERATED, OR FLAT-OUT WRONG. SO WHY ARE DOCTORS—TO A STRIKING EXTENT—STILL DRAWING UPON MISINFORMATION IN THEIR EVERYDAY PRACTICE? DR. JOHN IOANNIDIS HAS SPENT HIS CAREER CHALLENGING HIS PEERS BY EXPOSING THEIR BAD SCIENCE.

By David H. Freedman

IMAGE CREDIT: ROBYN TWOMEY/REDUX

IN 2001, RUMORS were circulating in Greek hospitals that surgery residents, eager to rack up scalpel time, were falsely diagnosing hapless Albanian immigrants with appendicitis. At the University of Ioannina medical school’s teaching hospital, a newly minted doctor named Athina Tatsioni was discussing the rumors with colleagues when a professor who had overheard asked her if she’d like to try to prove whether they were true—he seemed to be almost daring her. She accepted the challenge and, with the professor’s and other colleagues’ help, eventually produced a formal study showing that, for whatever reason, the appendices removed from patients with Albanian names in six Greek hospitals were more than three times as likely to be perfectly healthy as those removed from patients with Greek names. “It was hard to find a journal willing to publish it, but we did,” recalls Tatsioni. “I also discovered that I really liked research.” Good thing, because the study had actually been a sort of audition. The professor, it turned out, had been putting together a team of exceptionally brash and curious young clinicians and Ph.D.s to join him in tackling an unusual and controversial agenda.

Last spring, I sat in on one of the team’s weekly meetings on the medical school’s campus, which is plunked crazily across a series of sharp hills. The building in which we met, like most at the school, had the look of a barracks and was festooned with political graffiti. But the group convened in a spacious conference room that would have been at home at a Silicon Valley start-up. Sprawled around a large table were Tatsioni and eight other youngish Greek researchers and physicians who, in contrast to the pasty younger staff frequently seen in U.S. hospitals, looked like the casually glamorous cast of a television medical drama. The professor, a dapper and soft-spoken man named John Ioannidis, loosely presided.

One of the researchers, a biostatistician named Georgia Salanti, fired up a laptop and projector and started to take the group through a study she and a few colleagues were completing that asked this question: were drug companies manipulating published research to make their drugs look good? Salanti ticked off data that seemed to indicate they were, but the other team members almost immediately started interrupting. One noted that Salanti’s study didn’t address the fact that drug-company research wasn’t measuring critically important “hard” outcomes for patients, such as survival versus death, and instead tended to measure “softer” outcomes, such as self-reported symptoms (“my chest doesn’t hurt as much today”). Another pointed out that Salanti’s study ignored the fact that when drug-company data seemed to show patients’ health improving, the data often failed to show that the drug was responsible, or that the improvement was more than marginal.

Salanti remained poised, as if the grilling were par for the course, and gamely acknowledged that the suggestions were all good—but a single study can’t prove everything, she said. Just as I was getting the sense that the data in drug studies were endlessly malleable, Ioannidis, who had mostly been listening, delivered what felt like a coup de grĂ¢ce: wasn’t it possible, he asked, that drug companies were carefully selecting the topics of their studies—for example, comparing their new drugs against those already known to be inferior to others on the market—so that they were ahead of the game even before the data juggling began? “Maybe sometimes it’s the questions that are biased, not the answers,” he said, flashing a friendly smile. Everyone nodded. Though the results of drug studies often make newspaper headlines, you have to wonder whether they prove anything at all. Indeed, given the breadth of the potential problems raised at the meeting, can any medical-research studies be trusted?

That question has been central to Ioannidis’s career. He’s what’s known as a meta-researcher, and he’s become one of the world’s foremost experts on the credibility of medical research. He and his team have shown, again and again, and in many different ways, that much of what biomedical researchers conclude in published studies—conclusions that doctors keep in mind when they prescribe antibiotics or blood-pressure medication, or when they advise us to consume more fiber or less meat, or when they recommend surgery for heart disease or back pain—is misleading, exaggerated, and often flat-out wrong. He charges that as much as 90 percent of the published medical information that doctors rely on is flawed. His work has been widely accepted by the medical community; it has been published in the field’s top journals, where it is heavily cited; and he is a big draw at conferences. Given this exposure, and the fact that his work broadly targets everyone else’s work in medicine, as well as everything that physicians do and all the health advice we get, Ioannidis may be one of the most influential scientists alive. Yet for all his influence, he worries that the field of medical research is so pervasively flawed, and so riddled with conflicts of interest, that it might be chronically resistant to change—or even to publicly admitting that there’s a problem.

THE CITY OF IOANNINA is a big college town a short drive from the ruins of a 20,000-seat amphitheater and a Zeusian sanctuary built at the site of the Dodona oracle. The oracle was said to have issued pronouncements to priests through the rustling of a sacred oak tree. Today, a different oak tree at the site provides visitors with a chance to try their own hands at extracting a prophecy. “I take all the researchers who visit me here, and almost every single one of them asks the tree the same question,” Ioannidis tells me, as we contemplate the tree the day after the team’s meeting. “‘Will my research grant be approved?’” He chuckles, but Ioannidis (pronounced yo-NEE-dees) tends to laugh not so much in mirth as to soften the sting of his attack. And sure enough, he goes on to suggest that an obsession with winning funding has gone a long way toward weakening the reliability of medical research.

He first stumbled on the sorts of problems plaguing the field, he explains, as a young physician-researcher in the early 1990s at Harvard. At the time, he was interested in diagnosing rare diseases, for which a lack of case data can leave doctors with little to go on other than intuition and rules of thumb. But he noticed that doctors seemed to proceed in much the same manner even when it came to cancer, heart disease, and other common ailments. Where were the hard data that would back up their treatment decisions? There was plenty of published research, but much of it was remarkably unscientific, based largely on observations of a small number of cases. A new “evidence-based medicine” movement was just starting to gather force, and Ioannidis decided to throw himself into it, working first with prominent researchers at Tufts University and then taking positions at Johns Hopkins University and the National Institutes of Health. He was unusually well armed: he had been a math prodigy of near-celebrity status in high school in Greece, and had followed his parents, who were both physician-researchers, into medicine. Now he’d have a chance to combine math and medicine by applying rigorous statistical analysis to what seemed a surprisingly sloppy field. “I assumed that everything we physicians did was basically right, but now I was going to help verify it,” he says. “All we’d have to do was systematically review the evidence, trust what it told us, and then everything would be perfect.”

It didn’t turn out that way. In poring over medical journals, he was struck by how many findings of all types were refuted by later findings. Of course, medical-science “never minds” are hardly secret. And they sometimes make headlines, as when in recent years large studies or growing consensuses of researchers concluded that mammograms, colonoscopies, and PSA tests are far less useful cancer-detection tools than we had been told; or when widely prescribed antidepressants such as Prozac, Zoloft, and Paxil were revealed to be no more effective than a placebo for most cases of depression; or when we learned that staying out of the sun entirely can actually increase cancer risks; or when we were told that the advice to drink lots of water during intense exercise was potentially fatal; or when, last April, we were informed that taking fish oil, exercising, and doing puzzles doesn’t really help fend off Alzheimer’s disease, as long claimed. Peer-reviewed studies have come to opposite conclusions on whether using cell phones can cause brain cancer, whether sleeping more than eight hours a night is healthful or dangerous, whether taking aspirin every day is more likely to save your life or cut it short, and whether routine angioplasty works better than pills to unclog heart arteries.

But beyond the headlines, Ioannidis was shocked at the range and reach of the reversals he was seeing in everyday medical research. “Randomized controlled trials,” which compare how one group responds to a treatment against how an identical group fares without the treatment, had long been considered nearly unshakable evidence, but they, too, ended up being wrong some of the time. “I realized even our gold-standard research had a lot of problems,” he says. Baffled, he started looking for the specific ways in which studies were going wrong. And before long he discovered that the range of errors being committed was astonishing: from what questions researchers posed, to how they set up the studies, to which patients they recruited for the studies, to which measurements they took, to how they analyzed the data, to how they presented their results, to how particular studies came to be published in medical journals.

This array suggested a bigger, underlying dysfunction, and Ioannidis thought he knew what it was. “The studies were biased,” he says. “Sometimes they were overtly biased. Sometimes it was difficult to see the bias, but it was there.” Researchers headed into their studies wanting certain results—and, lo and behold, they were getting them. We think of the scientific process as being objective, rigorous, and even ruthless in separating out what is true from what we merely wish to be true, but in fact it’s easy to manipulate results, even unintentionally or unconsciously. “At every step in the process, there is room to distort results, a way to make a stronger claim or to select what is going to be concluded,” says Ioannidis. “There is an intellectual conflict of interest that pressures researchers to find whatever it is that is most likely to get them funded.”

Perhaps only a minority of researchers were succumbing to this bias, but their distorted findings were having an outsize effect on published research. To get funding and tenured positions, and often merely to stay afloat, researchers have to get their work published in well-regarded journals, where rejection rates can climb above 90 percent. Not surprisingly, the studies that tend to make the grade are those with eye-catching findings. But while coming up with eye-catching theories is relatively easy, getting reality to bear them out is another matter. The great majority collapse under the weight of contradictory data when studied rigorously. Imagine, though, that five different research teams test an interesting theory that’s making the rounds, and four of the groups correctly prove the idea false, while the one less cautious group incorrectly “proves” it true through some combination of error, fluke, and clever selection of data. Guess whose findings your doctor ends up reading about in the journal, and you end up hearing about on the evening news? Researchers can sometimes win attention by refuting a prominent finding, which can help to at least raise doubts about results, but in general it is far more rewarding to add a new insight or exciting-sounding twist to existing research than to retest its basic premises—after all, simply re-proving someone else’s results is unlikely to get you published, and attempting to undermine the work of respected colleagues can have ugly professional repercussions.

In the late 1990s, Ioannidis set up a base at the University of Ioannina. He pulled together his team, which remains largely intact today, and started chipping away at the problem in a series of papers that pointed out specific ways certain studies were getting misleading results. Other meta-researchers were also starting to spotlight disturbingly high rates of error in the medical literature. But Ioannidis wanted to get the big picture across, and to do so with solid data, clear reasoning, and good statistical analysis. The project dragged on, until finally he retreated to the tiny island of Sikinos in the Aegean Sea, where he drew inspiration from the relatively primitive surroundings and the intellectual traditions they recalled. “A pervasive theme of ancient Greek literature is that you need to pursue the truth, no matter what the truth might be,” he says. In 2005, he unleashed two papers that challenged the foundations of medical research.

He chose to publish one paper, fittingly, in the online journal PLoS Medicine, which is committed to running any methodologically sound article without regard to how “interesting” the results may be. In the paper, Ioannidis laid out a detailed mathematical proof that, assuming modest levels of researcher bias, typically imperfect research techniques, and the well-known tendency to focus on exciting rather than highly plausible theories, researchers will come up with wrong findings most of the time. Simply put, if you’re attracted to ideas that have a good chance of being wrong, and if you’re motivated to prove them right, and if you have a little wiggle room in how you assemble the evidence, you’ll probably succeed in proving wrong theories right. His model predicted, in different fields of medical research, rates of wrongness roughly corresponding to the observed rates at which findings were later convincingly refuted: 80 percent of non-randomized studies (by far the most common type) turn out to be wrong, as do 25 percent of supposedly gold-standard randomized trials, and as much as 10 percent of the platinum-standard large randomized trials. The article spelled out his belief that researchers were frequently manipulating data analyses, chasing career-advancing findings rather than good science, and even using the peer-review process—in which journals ask researchers to help decide which studies to publish—to suppress opposing views. “You can question some of the details of John’s calculations, but it’s hard to argue that the essential ideas aren’t absolutely correct,” says Doug Altman, an Oxford University researcher who directs the Centre for Statistics in Medicine.

Still, Ioannidis anticipated that the community might shrug off his findings: sure, a lot of dubious research makes it into journals, but we researchers and physicians know to ignore it and focus on the good stuff, so what’s the big deal? The other paper headed off that claim. He zoomed in on 49 of the most highly regarded research findings in medicine over the previous 13 years, as judged by the science community’s two standard measures: the papers had appeared in the journals most widely cited in research articles, and the 49 articles themselves were the most widely cited articles in these journals. These were articles that helped lead to the widespread popularity of treatments such as the use of hormone-replacement therapy for menopausal women, vitamin E to reduce the risk of heart disease, coronary stents to ward off heart attacks, and daily low-dose aspirin to control blood pressure and prevent heart attacks and strokes. Ioannidis was putting his contentions to the test not against run-of-the-mill research, or even merely well-accepted research, but against the absolute tip of the research pyramid. Of the 49 articles, 45 claimed to have uncovered effective interventions. Thirty-four of these claims had been retested, and 14 of these, or 41 percent, had been convincingly shown to be wrong or significantly exaggerated. If between a third and a half of the most acclaimed research in medicine was proving untrustworthy, the scope and impact of the problem were undeniable. That article was published in the Journal of the American Medical Association.

DRIVING ME BACK to campus in his smallish SUV—after insisting, as he apparently does with all his visitors, on showing me a nearby lake and the six monasteries situated on an islet within it—Ioannidis apologized profusely for running a yellow light, explaining with a laugh that he didn’t trust the truck behind him to stop. Considering his willingness, even eagerness, to slap the face of the medical-research community, Ioannidis comes off as thoughtful, upbeat, and deeply civil. He’s a careful listener, and his frequent grin and semi-apologetic chuckle can make the sharp prodding of his arguments seem almost good-natured. He is as quick, if not quicker, to question his own motives and competence as anyone else’s. A neat and compact 45-year-old with a trim mustache, he presents as a sort of dashing nerd—Giancarlo Giannini with a bit of Mr. Bean.

The humility and graciousness seem to serve him well in getting across a message that is not easy to digest or, for that matter, believe: that even highly regarded researchers at prestigious institutions sometimes churn out attention-grabbing findings rather than findings likely to be right. But Ioannidis points out that obviously questionable findings cram the pages of top medical journals, not to mention the morning headlines. Consider, he says, the endless stream of results from nutritional studies in which researchers follow thousands of people for some number of years, tracking what they eat and what supplements they take, and how their health changes over the course of the study. “Then the researchers start asking, ‘What did vitamin E do? What did vitamin C or D or A do? What changed with calorie intake, or protein or fat intake? What happened to cholesterol levels? Who got what type of cancer?’” he says. “They run everything through the mill, one at a time, and they start finding associations, and eventually conclude that vitamin X lowers the risk of cancer Y, or this food helps with the risk of that disease.” In a single week this fall, Google’s news page offered these headlines: “More Omega-3 Fats Didn’t Aid Heart Patients”; “Fruits, Vegetables Cut Cancer Risk for Smokers”; “Soy May Ease Sleep Problems in Older Women”; and dozens of similar stories.

When a five-year study of 10,000 people finds that those who take more vitamin X are less likely to get cancer Y, you’d think you have pretty good reason to take more vitamin X, and physicians routinely pass these recommendations on to patients. But these studies often sharply conflict with one another. Studies have gone back and forth on the cancer-preventing powers of vitamins A, D, and E; on the heart-health benefits of eating fat and carbs; and even on the question of whether being overweight is more likely to extend or shorten your life. How should we choose among these dueling, high-profile nutritional findings? Ioannidis suggests a simple approach: ignore them all.

For starters, he explains, the odds are that in any large database of many nutritional and health factors, there will be a few apparent connections that are in fact merely flukes, not real health effects—it’s a bit like combing through long, random strings of letters and claiming there’s an important message in any words that happen to turn up. But even if a study managed to highlight a genuine health connection to some nutrient, you’re unlikely to benefit much from taking more of it, because we consume thousands of nutrients that act together as a sort of network, and changing intake of just one of them is bound to cause ripples throughout the network that are far too complex for these studies to detect, and that may be as likely to harm you as help you. Even if changing that one factor does bring on the claimed improvement, there’s still a good chance that it won’t do you much good in the long run, because these studies rarely go on long enough to track the decades-long course of disease and ultimately death. Instead, they track easily measurable health “markers” such as cholesterol levels, blood pressure, and blood-sugar levels, and meta-experts have shown that changes in these markers often don’t correlate as well with long-term health as we have been led to believe.

On the relatively rare occasions when a study does go on long enough to track mortality, the findings frequently upend those of the shorter studies. (For example, though the vast majority of studies of overweight individuals link excess weight to ill health, the longest of them haven’t convincingly shown that overweight people are likely to die sooner, and a few of them have seemingly demonstrated that moderately overweight people are likely to live longer.) And these problems are aside from ubiquitous measurement errors (for example, people habitually misreport their diets in studies), routine misanalysis (researchers rely on complex software capable of juggling results in ways they don’t always understand), and the less common, but serious, problem of outright fraud (which has been revealed, in confidential surveys, to be much more widespread than scientists like to acknowledge).

If a study somehow avoids every one of these problems and finds a real connection to long-term changes in health, you’re still not guaranteed to benefit, because studies report average results that typically represent a vast range of individual outcomes. Should you be among the lucky minority that stands to benefit, don’t expect a noticeable improvement in your health, because studies usually detect only modest effects that merely tend to whittle your chances of succumbing to a particular disease from small to somewhat smaller. “The odds that anything useful will survive from any of these studies are poor,” says Ioannidis—dismissing in a breath a good chunk of the research into which we sink about $100 billion a year in the United States alone.

And so it goes for all medical studies, he says. Indeed, nutritional studies aren’t the worst. Drug studies have the added corruptive force of financial conflict of interest. The exciting links between genes and various diseases and traits that are relentlessly hyped in the press for heralding miraculous around-the-corner treatments for everything from colon cancer to schizophrenia have in the past proved so vulnerable to error and distortion, Ioannidis has found, that in some cases you’d have done about as well by throwing darts at a chart of the genome. (These studies seem to have improved somewhat in recent years, but whether they will hold up or be useful in treatment are still open questions.) Vioxx, Zelnorm, and Baycol were among the widely prescribed drugs found to be safe and effective in large randomized controlled trials before the drugs were yanked from the market as unsafe or not so effective, or both.

“Often the claims made by studies are so extravagant that you can immediately cross them out without needing to know much about the specific problems with the studies,” Ioannidis says. But of course it’s that very extravagance of claim (one large randomized controlled trial even proved that secret prayer by unknown parties can save the lives of heart-surgery patients, while another proved that secret prayer can harm them) that helps gets these findings into journals and then into our treatments and lifestyles, especially when the claim builds on impressive-sounding evidence. “Even when the evidence shows that a particular research idea is wrong, if you have thousands of scientists who have invested their careers in it, they’ll continue to publish papers on it,” he says. “It’s like an epidemic, in the sense that they’re infected with these wrong ideas, and they’re spreading it to other researchers through journals.”

THOUGH SCIENTISTS AND science journalists are constantly talking up the value of the peer-review process, researchers admit among themselves that biased, erroneous, and even blatantly fraudulent studies easily slip through it. Nature, the grande dame of science journals, stated in a 2006 editorial, “Scientists understand that peer review per se provides only a minimal assurance of quality, and that the public conception of peer review as a stamp of authentication is far from the truth.” What’s more, the peer-review process often pressures researchers to shy away from striking out in genuinely new directions, and instead to build on the findings of their colleagues (that is, their potential reviewers) in ways that only seem like breakthroughs—as with the exciting-sounding gene linkages (autism genes identified!) and nutritional findings (olive oil lowers blood pressure!) that are really just dubious and conflicting variations on a theme.

Most journal editors don’t even claim to protect against the problems that plague these studies. University and government research overseers rarely step in to directly enforce research quality, and when they do, the science community goes ballistic over the outside interference. The ultimate protection against research error and bias is supposed to come from the way scientists constantly retest each other’s results—except they don’t. Only the most prominent findings are likely to be put to the test, because there’s likely to be publication payoff in firming up the proof, or contradicting it.

But even for medicine’s most influential studies, the evidence sometimes remains surprisingly narrow. Of those 45 super-cited studies that Ioannidis focused on, 11 had never been retested. Perhaps worse, Ioannidis found that even when a research error is outed, it typically persists for years or even decades. He looked at three prominent health studies from the 1980s and 1990s that were each later soundly refuted, and discovered that researchers continued to cite the original results as correct more often than as flawed—in one case for at least 12 years after the results were discredited.

Doctors may notice that their patients don’t seem to fare as well with certain treatments as the literature would lead them to expect, but the field is appropriately conditioned to subjugate such anecdotal evidence to study findings. Yet much, perhaps even most, of what doctors do has never been formally put to the test in credible studies, given that the need to do so became obvious to the field only in the 1990s, leaving it playing catch-up with a century or more of non-evidence-based medicine, and contributing to Ioannidis’s shockingly high estimate of the degree to which medical knowledge is flawed. That we’re not routinely made seriously ill by this shortfall, he argues, is due largely to the fact that most medical interventions and advice don’t address life-and-death situations, but rather aim to leave us marginally healthier or less unhealthy, so we usually neither gain nor risk all that much.

Medical research is not especially plagued with wrongness. Other meta-research experts have confirmed that similar issues distort research in all fields of science, from physics to economics (where the highly regarded economists J. Bradford DeLong and Kevin Lang once showed how a remarkably consistent paucity of strong evidence in published economics studies made it unlikely that any of them were right). And needless to say, things only get worse when it comes to the pop expertise that endlessly spews at us from diet, relationship, investment, and parenting gurus and pundits. But we expect more of scientists, and especially of medical scientists, given that we believe we are staking our lives on their results. The public hardly recognizes how bad a bet this is. The medical community itself might still be largely oblivious to the scope of the problem, if Ioannidis hadn’t forced a confrontation when he published his studies in 2005.

Ioannidis initially thought the community might come out fighting. Instead, it seemed relieved, as if it had been guiltily waiting for someone to blow the whistle, and eager to hear more. David Gorski, a surgeon and researcher at Detroit’s Barbara Ann Karmanos Cancer Institute, noted in his prominent medical blog that when he presented Ioannidis’s paper on highly cited research at a professional meeting, “not a single one of my surgical colleagues was the least bit surprised or disturbed by its findings.” Ioannidis offers a theory for the relatively calm reception. “I think that people didn’t feel I was only trying to provoke them, because I showed that it was a community problem, instead of pointing fingers at individual examples of bad research,” he says. In a sense, he gave scientists an opportunity to cluck about the wrongness without having to acknowledge that they themselves succumb to it—it was something everyone else did.

To say that Ioannidis’s work has been embraced would be an understatement. His PLoS Medicinepaper is the most downloaded in the journal’s history, and it’s not even Ioannidis’s most-cited work—that would be a paper he published in Nature Genetics on the problems with gene-link studies. Other researchers are eager to work with him: he has published papers with 1,328 different co-authors at 538 institutions in 43 countries, he says. Last year he received, by his estimate, invitations to speak at 1,000 conferences and institutions around the world, and he was accepting an average of about five invitations a month until a case last year of excessive-travel-induced vertigo led him to cut back. Even so, in the weeks before I visited him he had addressed an AIDS conference in San Francisco, the European Society for Clinical Investigation, Harvard’s School of Public Health, and the medical schools at Stanford and Tufts.

The irony of his having achieved this sort of success by accusing the medical-research community of chasing after success is not lost on him, and he notes that it ought to raise the question of whether he himself might be pumping up his findings. “If I did a study and the results showed that in fact there wasn’t really much bias in research, would I be willing to publish it?” he asks. “That would create a real psychological conflict for me.” But his bigger worry, he says, is that while his fellow researchers seem to be getting the message, he hasn’t necessarily forced anyone to do a better job. He fears he won’t in the end have done much to improve anyone’s health. “There may not be fierce objections to what I’m saying,” he explains. “But it’s difficult to change the way that everyday doctors, patients, and healthy people think and behave.”

AS HELTER-SKELTER as the University of Ioannina Medical School campus looks, the hospital abutting it looks reassuringly stolid. Athina Tatsioni has offered to take me on a tour of the facility, but we make it only as far as the entrance when she is greeted—accosted, really—by a worried-looking older woman. Tatsioni, normally a bit reserved, is warm and animated with the woman, and the two have a brief but intense conversation before embracing and saying goodbye. Tatsioni explains to me that the woman and her husband were patients of hers years ago; now the husband has been admitted to the hospital with abdominal pains, and Tatsioni has promised she’ll stop by his room later to say hello. Recalling the appendicitis story, I prod a bit, and she confesses she plans to do her own exam. She needs to be circumspect, though, so she won’t appear to be second-guessing the other doctors.

Tatsioni doesn’t so much fear that someone will carve out the man’s healthy appendix. Rather, she’s concerned that, like many patients, he’ll end up with prescriptions for multiple drugs that will do little to help him, and may well harm him. “Usually what happens is that the doctor will ask for a suite of biochemical tests—liver fat, pancreas function, and so on,” she tells me. “The tests could turn up something, but they’re probably irrelevant. Just having a good talk with the patient and getting a close history is much more likely to tell me what’s wrong.” Of course, the doctors have all been trained to order these tests, she notes, and doing so is a lot quicker than a long bedside chat. They’re also trained to ply the patient with whatever drugs might help whack any errant test numbers back into line. What they’re not trained to do is to go back and look at the research papers that helped make these drugs the standard of care. “When you look the papers up, you often find the drugs didn’t even work better than a placebo. And no one tested how they worked in combination with the other drugs,” she says. “Just taking the patient off everything can improve their health right away.” But not only is checking out the research another time-consuming task, patients often don’t even like it when they’re taken off their drugs, she explains; they find their prescriptions reassuring.

Later, Ioannidis tells me he makes a point of having several clinicians on his team. “Researchers and physicians often don’t understand each other; they speak different languages,” he says. Knowing that some of his researchers are spending more than half their time seeing patients makes him feel the team is better positioned to bridge that gap; their experience informs the team’s research with firsthand knowledge, and helps the team shape its papers in a way more likely to hit home with physicians. It’s not that he envisions doctors making all their decisions based solely on solid evidence—there’s simply too much complexity in patient treatment to pin down every situation with a great study. “Doctors need to rely on instinct and judgment to make choices,” he says. “But these choices should be as informed as possible by the evidence. And if the evidence isn’t good, doctors should know that, too. And so should patients.”

In fact, the question of whether the problems with medical research should be broadcast to the public is a sticky one in the meta-research community. Already feeling that they’re fighting to keep patients from turning to alternative medical treatments such as homeopathy, or misdiagnosing themselves on the Internet, or simply neglecting medical treatment altogether, many researchers and physicians aren’t eager to provide even more reason to be skeptical of what doctors do—not to mention how public disenchantment with medicine could affect research funding. Ioannidis dismisses these concerns. “If we don’t tell the public about these problems, then we’re no better than nonscientists who falsely claim they can heal,” he says. “If the drugs don’t work and we’re not sure how to treat something, why should we claim differently? Some fear that there may be less funding because we stop claiming we can prove we have miraculous treatments. But if we can’t really provide those miracles, how long will we be able to fool the public anyway? The scientific enterprise is probably the most fantastic achievement in human history, but that doesn’t mean we have a right to overstate what we’re accomplishing.”

We could solve much of the wrongness problem, Ioannidis says, if the world simply stopped expecting scientists to be right. That’s because being wrong in science is fine, and even necessary—as long as scientists recognize that they blew it, report their mistake openly instead of disguising it as a success, and then move on to the next thing, until they come up with the very occasional genuine breakthrough. But as long as careers remain contingent on producing a stream of research that’s dressed up to seem more right than it is, scientists will keep delivering exactly that.

“Science is a noble endeavor, but it’s also a low-yield endeavor,” he says. “I’m not sure that more than a very small percentage of medical research is ever likely to lead to major improvements in clinical outcomes and quality of life. We should be very comfortable with that fact.”


David H. Freedman is the author of Wrong: Why Experts Keep Failing Us—And How to Know When Not to Trust Them. He has been an Atlantic contributor since 1998.

Sunday, October 24, 2010

Patients who had spinal fusion were less likely to return to work and needed more opiates, study says

Source

By Linda Carroll
msnbc.com contributor
updated 10/14/2010 8:55:44 AM ET

Just a month after back surgery, Nancy Scatena was once again in excruciating pain. The medications her doctor prescribed barely took the edge off the unrelenting back aches and searing jolts down her left leg. “The pain just kept intensifying,” says the 52-year-old Scottsdale, Ariz., woman who suffers from spinal stenosis, a narrowing of the chanel through which spinal nerves pass. “I was suicidal.”

Finally, Scatena made an appointment with another surgeon, one whom friends had called a “miracle worker.” The new doctor assured her that this second operation would fix everything, and in the pain-free weeks following an operation to fuse two of her vertebrae it seemed that he was right. But then the pain came roaring back.

Experts estimate that nearly 600,000 Americans opt for back operations each year. But for many like Scatena, surgery is just an empty promise, say pain management experts and some surgeons.

A new study in the journal Spine shows that in many cases surgery can even backfire, leaving patients in more pain.

Researchers reviewed records from 1,450 patients in the Ohio Bureau of Workers’ Compensation database who had diagnoses of disc degeneration, disc herniation or radiculopathy, a nerve condition that causes tingling and weakness of the limbs. Half of the patients had surgery to fuse two or more vertebrae in hopes of curing low back pain. The other half had no surgery, even though they had comparable diagnoses.

After two years, just 26 percent of those who had surgery returned to work. That’s compared to 67 percent of patients who didn’t have surgery. In what might be the most troubling study finding, researchers determined that there was a 41 percent increase in the use of painkillers, specifically opiates, in those who had surgery.

The study provides clear evidence that for many patients, fusion surgeries designed to alleviate pain from degenerating discs don’t work, says the study’s lead author Dr. Trang Nguyen, a researcher at the University of Cincinnati College of Medicine.

Unfortunately, for most patients with bad backs, there is no easy solution, no magic bullet. Pain management experts — and some surgeons — say that patients need to scale back their expectations. With the right treatments, pain can be eased, but a complete cure is unlikely.

In the wake of her operations, Scatena has turned to less invasive therapies. She’s learned to baby her back and to find ways to avoid irritating the nerves in her spine. She’s working to strengthen muscles in her lower back and abdomen so her spine will get better support. “I’ve been getting some relief from physical therapy,” she says. “And I hope that’s going to be permanent.”

27 million adults with back problems


A recent report by the Agency for Healthcare Research and Quality, a federal organization, found that in 2007, 27 million adults reported back problems with $30.3 billion spent on treatments to ease the pain. While some of that money is spent on physical therapy, pain management, chiropractor visits, and other non invasive therapies, a big chunk pays for spine surgeries.

Complicated spine surgeries that involve fusing two or more vertebrae are on the rise. In just 15 years, there was an eight-fold jump in this type of operation, according to a study published in Spine in July. That has some surgeons and public health experts concerned.

For some patients, there is a legitimate need for spine surgery and fusion, says Dr. Charles Burton, medical director for The Center for Restorative Spine Surgery in St. Paul, Minn. “But the concern is that it’s gotten way beyond what is reasonable or necessary. There are some areas of the country where the rate of spine surgery is three or four times the national average.”

Burton and others recommend that patients get a second opinion when back surgery is recommended for the treatment of back pain without neurological symptoms, such as sciatica, especially if other treatments haven’t been suggested first.

“We are very successful at improving leg symptoms," says Dr. William Welch, vice chairman of the department of neurosurgery at the University of Pennsylvania Medical Center and chief of neurosurgery at Pennsylvania Hospital. “We are less successful at treating back pain.”

Source of pain is often hard to pinpoint

The reason, Welch says, is that it’s often hard to pinpoint the exact cause of someone’s back pain. Even MRIs can be misleading because abnormalities, such as degenerating discs, can be seen on scans for virtually everyone over the age of 30 regardless of whether they have pain. Even when the surgery is a success, it rarely dispels 100 percent of back pain, Welch says.

And while many surgeons are careful about which patients they recommend for spine operations, some are not so discriminating, says Dr. Doris K. Cope, professor and vice chair for pain medicine at the University of Pittsburgh School of Medicine. “It’s a case of, if you have a hammer, everything looks like a nail,” she explains.

In general, the best results come about through a combination of approaches, Cope says. Each strategy may reduce pain by just 10 or 20 percent, but those percentages can add up so ultimately the patient’s pain is cut back by as much as 70 or 80 percent. Strategies can include exercise and weight loss, Cope says.

That advice resonates with Marilyn Seiger, a friend of Nancy Scatena in Scottsdale. Seiger opted to skip surgery, not wanting to follow her friend's painful path, even though her doctor recommended an operation to fuse two of her vertebrae.

She has gotten some relief from physical therapy, a back brace that reminds her to keep her back straight, and the occasional pain pill.

“I don’t know anyone who’s had surgery for back pain who had success,” says Seiger, 61. “I just figure this is part of growing older. We’re living longer than our bodies were meant to last and we’re just constantly shoring things up.”

© 2010 msnbc.com. Reprints

Wednesday, October 20, 2010

The more secular, the more superstitious

Look Who's Irrational Now


"You can't be a rational person six days of the week and put on a suit and make rational decisions and go to work and, on one day of the week, go to a building and think you're drinking the blood of a 2,000-year-old space god," comedian and atheist Bill Maher said earlier this year on "Late Night With Conan O'Brien."

On the "Saturday Night Live" season debut last week, homeschooling families were portrayed as fundamentalists with bad haircuts who fear biology. Actor Matt Damon recently disparaged Sarah Palin by referring to a transparently fake email that claimed she believed that dinosaurs were Satan's lizards. And according to prominent atheists like Richard Dawkins, traditional religious belief is "dangerously irrational." From Hollywood to the academy, nonbelievers are convinced that a decline in traditional religious belief would lead to a smarter, more scientifically literate and even more civilized populace.

The reality is that the New Atheist campaign, by discouraging religion, won't create a new group of intelligent, skeptical, enlightened beings. Far from it: It might actually encourage new levels of mass superstition. And that's not a conclusion to take on faith -- it's what the empirical data tell us.

"What Americans Really Believe," a comprehensive new study released by Baylor University yesterday, shows that traditional Christian religion greatly decreases belief in everything from the efficacy of palm readers to the usefulness of astrology. It also shows that the irreligious and the members of more liberal Protestant denominations, far from being resistant to superstition, tend to be much more likely to believe in the paranormal and in pseudoscience than evangelical Christians.

[Bigfoot]Corbis

The Gallup Organization, under contract to Baylor's Institute for Studies of Religion, asked American adults a series of questions to gauge credulity. Do dreams foretell the future? Did ancient advanced civilizations such as Atlantis exist? Can places be haunted? Is it possible to communicate with the dead? Will creatures like Bigfoot and the Loch Ness Monster someday be discovered by science?

The answers were added up to create an index of belief in occult and the paranormal. While 31% of people who never worship expressed strong belief in these things, only 8% of people who attend a house of worship more than once a week did.

Even among Christians, there were disparities. While 36% of those belonging to the United Church of Christ, Sen. Barack Obama's former denomination, expressed strong beliefs in the paranormal, only 14% of those belonging to the Assemblies of God, Sarah Palin's former denomination, did. In fact, the more traditional and evangelical the respondent, the less likely he was to believe in, for instance, the possibility of communicating with people who are dead.

This is not a new finding. In his 1983 book "The Whys of a Philosophical Scrivener," skeptic and science writer Martin Gardner cited the decline of traditional religious belief among the better educated as one of the causes for an increase in pseudoscience, cults and superstition. He referenced a 1980 study published in the magazine Skeptical Inquirer that showed irreligious college students to be by far the most likely to embrace paranormal beliefs, while born-again Christian college students were the least likely.

Surprisingly, while increased church attendance and membership in a conservative denomination has a powerful negative effect on paranormal beliefs, higher education doesn't. Two years ago two professors published another study in Skeptical Inquirer showing that, while less than one-quarter of college freshmen surveyed expressed a general belief in such superstitions as ghosts, psychic healing, haunted houses, demonic possession, clairvoyance and witches, the figure jumped to 31% of college seniors and 34% of graduate students.

We can't even count on self-described atheists to be strict rationalists. According to the Pew Forum on Religion & Public Life's monumental "U.S. Religious Landscape Survey" that was issued in June, 21% of self-proclaimed atheists believe in either a personal God or an impersonal force. Ten percent of atheists pray at least weekly and 12% believe in heaven.

On Oct. 3, Mr. Maher debuts "Religulous," his documentary that attacks religious belief. He talks to Hasidic scholars, Jews for Jesus, Muslims, polygamists, Satanists, creationists, and even Rael -- prophet of the Raelians -- before telling viewers: "The plain fact is religion must die for man to live."

But it turns out that the late-night comic is no icon of rationality himself. In fact, he is a fervent advocate of pseudoscience. The night before his performance on Conan O'Brien, Mr. Maher told David Letterman -- a quintuple bypass survivor -- to stop taking the pills that his doctor had prescribed for him. He proudly stated that he didn't accept Western medicine. On his HBO show in 2005, Mr. Maher said: "I don't believe in vaccination. . . . Another theory that I think is flawed, that we go by the Louis Pasteur [germ] theory." He has told CNN's Larry King that he won't take aspirin because he believes it is lethal and that he doesn't even believe the Salk vaccine eradicated polio.

Anti-religionists such as Mr. Maher bring to mind the assertion of G.K. Chesterton's Father Brown character that all atheists, secularists, humanists and rationalists are susceptible to superstition: "It's the first effect of not believing in God that you lose your common sense, and can't see things as they are."

Ms. Hemingway is a writer in Washington.

Monday, October 18, 2010

Massage doesn't remove lactic acid

Published: June 19, 2006

WHILE joggers, weightlifters, recreational softball players and other fitness enthusiasts will surely be delighted to hear that exercise science now sees lactic acid as a force of good and not evil, the fact remains that people are sore. What can be done about it?

Martin Kozlowski

While lactic acid can cause a burning sensation during hard exercise (because it is, as the name suggests, acidic) recent research has confirmed that the real culprits for the so-called delayed muscle soreness that comes one to three days after a big game or heavy workout are microscopic tears and trauma to the muscles and inflammation.

By the time delayed muscle soreness happens, "The lactic acid is pretty much back to normal levels," said Allan H. Goldfarb, a professor in the department of exercise and sport science at the University of North Carolina at Greensboro.

Lactic acid, which is produced by the breakdown of glucose in the body, was once seen as little more than a waste product. That view has changed, and lactic acid is now seen as an important fuel source for the body. "We're finding now that lactic acid is a major player in metabolism," said Thomas Fahey, an exercise physiologist at California State University, Chico.

The working muscles of the body, the heart, the diaphragm, even the brain, all "thrive" — as Dr. Fahey described it — on lactic acid as an important energy source. It may even help stimulate weight loss, he added.

The thinking about how to deal with the soreness has changed as well. In "The Complete Book of Running," published in 1977, the author and marathoner Jim Fixx said that soreness was "pretty much unavoidable," and recommended "a hot bath followed by a massage with some liniment." In the book, a best seller generally credited with helping to spark the running boom, the author, who died in 1984, went on to write that, "once you have sore muscles, there isn't much you can do about them except take a sauna and wait for the pain to go away."

Wait? In today's impatient culture, athletes and trainers take a more active approach to soreness. National Football League players, for example, may be some of the sorest athletes in the world. Every Sunday during their season, their muscles, to use the exercise physiologists term, suffer "insult" to a degree most of us could not withstand. "It takes these guys sometimes until Wednesday or Thursday to feel human again," said Todd Durkin, a licensed massage therapist and strength and conditioning coach in San Diego, who works with many N.F.L. players. "Recovery is a real important part of their training regimen."

Repairing these well-paid muscles is a high priority for both the team and their trainers. Typically, it starts with a postgame "ice plunge," five minutes immersed in a tub filled with ice. "The cold is one of the best things you can do to reduce inflammation," Mr. Durkin said. "Cold constricts the cells, basically closing them down, and gets rid of any toxicity or inflammation through trauma."

One of Mr. Durkin's clients is LaDanian Tomlinson, the San Diego Chargers' star running back, who gets tackled about 30 times a game. On Mondays during the season, Mr. Tomlinson spends much of the day with Mr. Durkin trying to minimize soreness, reduce inflammation and speed what Mr. Durkin calls "the regeneration process." To do so, more ice will be applied, and Mr. Tomlinson gets 60 minutes of deep massage and body work. But he also does light exercises — walking on a treadmill and weight-training movements — which may sound counterintuitive, but are basic to most treatments of sore bodies.

Although research has been unable to prove its value, "keep it moving" is a principle long prescribed by trainers and therapists. "The day after a race, you bike or swim or walk, something to just loosen yourself up," said David Balsley, a physical therapist in Manhattan who is also a competitive runner and triathlete. In the past, the reason for moving was often described as being to work the lactic acid out of muscles and reduce soreness. We know better now. Lactic acid isn't the problem, but soreness still is. Can the microtrauma and inflammation that are fingered as its causes be prevented? To some extent, the experts say yes.

"First off, try not to get damaged," Dr. Goldfarb said. "When you increase your workload, you should be doing it gradually." The rule of thumb is no more than 10 to 15 percent increases a week. For example, if you walk three miles this week, you should be doing no more than about three and a half next week.

Still, said Jeffrey A. Potteiger, a professor of exercise science at Miami University in Ohio, Mr. Fixx might have been partly correct when he wrote of the inevitability of mild soreness. "If you run a marathon, you're going to get sore, and there's not a whole lot you can do about it," Dr. Potteiger said. "If you do almost anything you're not accustomed to doing, you'll get some soreness. The good news is that if you continue to do that activity, the soreness will not be as prevalent and in some instances will go away. The body will adapt to that workload."

In the meantime, ice, stretch and perform light activity to help work the soreness from your muscles. Just be clear that it's not lactic acid you are working out. That soreness, Dr. Thomas Fahey of Chico said, "is completely due to muscle injury and inflammation." And yet, he added, "even today, massage therapists talk about getting rid of the lactic acid after a race or hard workout. This is just completely false.


Why the benefits of massage may be a myth

Athletes use post-exercise rubdowns to boost recovery but the gains could be all in the mind

To top athletes and anyone else who exercises a lot or has put him or herself through the rigours of a marathon or triathlon, a regular massage is considered almost as essential to keeping the body in condition as diet and training. After all, the kind of deep-tissue massage practised by registered sports massage therapists promises to increase blood flow to aching muscles and flush out metabolic waste products such as lactic acid after a hard workout.

Nothing could be better for your aching limbs. Or could it? In a study presented at the American College of Sports Medicine’s annual conference in Seattle this week, researchers claimed to have blown the myth that massage speeds up recovery from exercise. Professor Michael Tschavovsky of the health studies department at Queens University in Ontario, Canada, says that while most massage therapists believe that their work boosts circulation to the muscles and reduces fatigue, no study before his had tested the validity of this theory.

Tschavovsky asked 12 healthy male subjects to perform isometric hand-grip exercises for two minutes at a time while he and his team measured blood flow and lactic acid build-up every 30 seconds and for ten minutes after the exercise had finished. They also took the same measurements during rest, when the subjects had massage and during “active recovery” such as gentle jogging, walking or stretching. What they found was that massage did not increase — but decreased — blood flow to the muscles and hindered rather than improved the removal of lactic acid and other waste materials by as much as 25 per cent compared to “active recovery”.

“Anyone who believes that lactic acid symptoms are relieved by massage is wrong because the alleviation of discomfort is not due to waste products being flushed out after exercise,” Tschavovsky says. So does this mean that post-workout massage is a waste of time? Tschavovsky thinks not. He is a fan himself and admits to having massage to help his legs to recover after football tournaments. But he says that the benefits could all be in the mind. “It feels good, that’s the truth of it,” he says. “A lot of sports performance is psychologically based so if you feel you are in a better situation to train with massage then, yes, it probably does have the ability to improve your performance.”

What his study shows, Tschavovsky says, is not that massage is useless but that it isn’t helpful for the claimed reasons. If it does work, scientists have yet to prove how.

Massage therapists are taking the findings with a pinch of salt. “Any sort of physical activity produces a cocktail of waste products — not just lactic acid — that vary according to the activity, the intensity of the workout, your age and diet,” says Mel Cash, principal tutor of the London School of Sports Massage, where many of Britain’s Olympic sports masseurs have trained. “A qualified therapist will be able to reduce the swelling of tissues and aid minor soft tissue injuries so that you are ready for your next workout.” Bob Bramah, a spokesman for the Sports Massage Association, the governing body of sports massage in the UK, says that there is plenty of evidence that massage is helpful after exercise. “But I also know by personal experience that what I do works,” he says. “I know that my players feel better afterwards. I know that as a result of that their performance is enhanced.”

But is it? Experts who have reviewed other types of massage claim that not only are many approaches ineffective but that some hold potential risks. Professor Edzard Ernst, a researcher into complementary medicine and director of the Peninsular Medical School in Exeter, says that part of the problem is that the profession is unregulated. While studies do show that massage can help to relieve a range of ailments from stress, migraines and infertility to back pain, sickle cell anaemia and joint problems, many are inconclusive.

A study at Ohio State University last year, for example, showed aromatherapy treatment to be relaxing because of a placebo effect, while a study of hot stone treatment (heated stones placed on the body) found that while the warmth was comforting there was no scientific evidence of a reduction in ailments. In the case of Thai massage, which aims to realign the body by using pressure on acupressure points, after a five-week study by the Touch Research Institute in Florida, subjects reported reduced job stress and elevated moods.

“In most cases the evidence is highly contradictory and while some studies suggest an effect others don’t,” Ernst says. “There is reasonably good evidence that massage can be helpful for back pain, but rigorous investigations are difficult to carry out because a good placebo does not exist.”

Susan Findlay, a spokeswoman for the General Council for Massage Therapies, the UK’s governing body for all soft-tissue techniques, says: “The lack of reputable studies boils down to massage being very difficult to investigate because there are so many variables, including technique, perception of benefits and the standard of a practitioner.” There are groups of people — including those with low platelet counts or who are taking blood-thinning medications, pregnant women and people with cancer, osteoporosis or rheumatoid arthritis — who should be cautious about having a massage and should do so only on medical recommendation. For them — and others — massage could do more harm than good.

Research by Dr Robert Gotlin, a sports and orthopaedic rehabilitation specialist at the Beth Israel Medical Centre in New York, suggested that 15-20 per cent of people who have massage for injuries end up having corrective treatment afterwards: problems they attributed to muscular pain were more likely to be linked to spine or bone abnormalities. Massage could make the problem worse, injuring nerves, causing muscle spasms or inflammation. Gotlin suggests that thin people avoid deeptissue techniques such as shiatsu and Swedish massage. They are good for easing tight muscles, he says, but can lead to damaged muscle tissue, nerves or bones, particularly around the spinal area, in people without much body fat to act as protection.

Ernst says that serious problems linked to massage are rare. A review of evidence he conducted for the journal Rheumatology uncovered a few adverse effects; the majority were associated with “exotic” types of manual massage or techniques delivered by underqualified practitioners. “Massage is not risk-free, but significant adverse events are true rarities.”


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