Javier Benitez points us to this op-ed, “Massaging data to fit a theory is not the worst research sin,” where philosopher Martin Cohen writes:
The recent fall from grace of the Cornell University food marketing researcher Brian Wansink is very revealing of the state of play in modern research.
Wansink had for years embodied the ideal to which all academics aspire: innovative, highly cited and media-friendly.
I would just like to briefly interrupt that not all academics aspire to be media-friendly. I have that aspiration myself, and of course people who aspire to be media-friendly are overrepresented in the media—but I’ve met lots of academics who’d prefer to be left in peace and quite to do their work and communicate just with specialists and students.
But that’s not the key point here. So let me continue quoting Cohen:
[Wansink’s] research, now criticised as fatally flawed, included studies suggesting that people who go grocery shopping while hungry buy more calories, that pre-ordering lunch can help you choose healthier food, and that serving people out of large bowls leads them to eat larger portions.
Such studies have been cited more than 20,000 times and even led to an appearance on The Oprah Winfrey Show [and, more to the point, the spending of millions of dollars of government money! — ed.]. But Wansink was accused of manipulating his data to achieve more striking results. Underlying it all is a suspicion that he was in the habit of forming hypotheses and then searching for data to support them. Yet, from a more generous perspective, this is, after all, only scientific method.
Behind the criticism of Wansink is a much broader critique not only of his work but of a certain kind of study: one that, while it might have quantitative elements, is in essence ethnographic and qualitative, its chief value being in storytelling and interpretation. . . .
We forget too easily that the history of science is rich with errors. In a dash to claim glory before Watson and Crick, Linus Pauling published a fundamentally incoherent hypothesis that the structure of DNA was a triple helix. Lord Kelvin misestimated the age of the Earth by more than an order of magnitude. In the early days of genetics, Francis Galton introduced an erroneous mathematical expression for the contributions of different ancestors to individuals’ inherited traits. We forget because these errors were part of broader narratives that came with brilliant insights.
I accept that Wansink may have been guilty of shoehorning data into preconceived patterns – and in the process may have mixed up some of the figures too. But if the latter is unforgivable, the former is surely research as normal.
Let me pause again here. If all that happened is that Wansink “may have mixed up some of the figures,” that this is not “unforgivable” at all. We all “mix up some of the figures” from time to time (here’s an embarrassing example from my own published work), and nobody who does creative work is immune from “shoehorning data into preconceived patterns.”
For some reason, Cohen seems to be on a project to minimize Wansink’s offenses. So let me spell it out. No, the problem with the notorious food researcher is not that he “may have mixed up some of the figures.” First, he definitely—not “may have”—mixed up many—not “some”—of his figures. We know this because many of his figures contradicted each other, and others made no sense (see, for example, here for many examples). Second, Wansink bobbed and weaved, over the period of years denying problems that were pointed out to him from all sorts of different directions.
Cohen continues:
The critics are indulging themselves in a myth of neutral observers uncovering “facts”, which rests on a view of knowledge as pristine and eternal as anything Plato might have dreamed of.
It is thanks to Western philosophy that, for thousands of years, we have believed that our thinking should strive to eliminate ideas that are vague, contradictory or ambiguous. Today’s orthodoxy is that the world is governed by iron laws, the most important of which is if P then Q. Part and parcel of this is a belief that the main goal of science is to provide deterministic – cause and effect – rules for all phenomena. . . .
Here I think Cohen’s getting things backward! It’s Wansink’s critics who have repeatedly stated that the world is complicated and that we should be wary of taking misreported data from 97 people in a diner to make general statements about eating behavior, men’s and women’s behaviors, nutrition policy, etc.
Contrariwise, it was Wansink and his promoters who were making general statements, claiming to have uncovered facts about human nature, etc.
Cohen continues a few paragraphs later:
Plato attempted to avoid contradictions by isolating the object of inquiry from all other relationships. But, in doing so, he abstracted and divorced those objects from a reality that is multi-relational and multitemporal. This same artificiality dogs much research.
Exactly! Wansink, like all of us, is subject to the Armstrong Principle (“If you promise more than you can deliver, then you have an incentive to cheat.”). Most scholars, myself included, are scaredy-cats: in order to avoid putting ourselves in a Lance Armstrong situation, we’re careful to underpromise. Wansink, though, he overpromised, presenting his artificial research has yielding general truths.
In short, we, the critics of Wansink and other practitioners of cargo-cult science, are on Cohen’s side. We’re the ones who are trying to express scientific method in a way that respects the disconnect between experiment and real world.
Cohen concludes:
Even if the quantitative elements don’t convince and need revising, studies like Wansink’s can be of value if they offer new clarity in looking at phenomena, and stimulate ideas for future investigations. Such understanding should be the researcher’s Holy Grail.
After all, according to the tenets of our current approach to facts and figures, much scientific endeavour of the past amounted to wasted effort, in fields with absolutely no yield of true scientific information. And yet science has progressed.
I don’t get the logic here. “Much endeavour amounted to wasted effort . . . And yet science has progressed.” Couldn’t it be that, to a large extent, the wasted effort and the progress has been done in by different people, different places?
To use general scientific progress as a way of justifying scientific dead-end work . . . that’s kinda like saying that the Bills made a good choice to keep starting Nathan Peterman, because Patrick Mahomes has been doing so well.
Who cares?
So what? Why keep talking about this pizzagate? Because I think misconceptions here can get in the way of future learning.
Let me state the situation as plainly as possible, without any reference to this particular case:
Step 1. A researcher performs a study that gets published. The study makes big claims and gets lots of attention, both from the news media and from influential policymakers.
Step 2. Then it turns out that (a) the published work was seriously flawed, and the published claims are not supported by the data being offered in their support: the claims may be true, in some ways, but no good evidence has been given; (b) other published studies that appear to show confirmation of the original claim have their own problems; and (c) statistical analysis shows that it is possible that the entire literature is chasing noise.
Step 3. A call goes out to be open-minded: just because some of these studies did not follow ideal scientific practices, we should not then conclude that their scientific claims are false.
And I agree with Step 3. But I’ve said it before and I’ve said it again: We should be open-minded, but not selectively open-minded.
Suppose the original claim is X, but the study purporting to demonstrate X is flawed, and the follow-up studies don’t provide strong evidence for X either. Then, of course we should be open to the possibility that X remains true (after all, for just about any hypothesis X there is always some qualitative evidence and some theoretical arguments that can be found in favor of X), and we should also be open to the possibility that there is no effect (or, to put it more precisely, an effect that is in practice indistinguishable from zero). Fine. But let’s also be open to the possibility of “minus X”; that is, the possibility that the posited intervention is counterproductive. And, if we really want to get real, let’s be open to the possibility that the effect is positive for some people in some scenarios, and negative for other people in other scenarios, and that in the existing state of our knowledge, we can’t say much about where the effect is positive and where it is negative. Let’s show some humility about what we can claim.
Accepting uncertainty does not mean that we can’t make decisions. After all, we were busy making decisions about topic X, whatever it was, before we had any data at all—so we can keep making decisions on a case-by-case basis using whatever information and hunches we have.
Here are some practical implications. First, if we’re not sure the effect of an intervention, maybe we should think harder about costs, including opportunity costs. Second, it makes sense to gather information about what’s happening locally, to get a better sense of what the intervention is doing.
All the work that you haven’t heard of
The other thing I want to bring up is the selection bias involved in giving the benefit of the doubt to weak claims that happen to have received positive publicity. One big big problem here is that there are lots of claims in all sorts of directions that you haven’t heard about, because they haven’t appeared on Oprah, or NPR, or PNAS, or Freakonomics, or whatever. By the same logic as Cohen gives in the above-quoted piece, all those obscure claims also deserve our respect as “of value if they offer new clarity in looking at phenomena, and stimulate ideas for future investigations.” The problem is that we’re not seeing all that work.
As I’ve also said on various occasions, I have no problem when people combine anecdotes and theorizing to come up with ideas and policy proposals. My problem with Wansink is not that he had interesting ideas without strong empirical support: that happens all the time. Most of our new ideas don’t have strong empirical support, in part because ideas with strong empirical support tend to already exist so they won’t be new! No, my problem with Wansink is that he took weak evidence and presented it as if it were strong evidence. For this discussion, I don’t really care if he did this by accident or on purpose. Either way, now we know he had weak evidence, or no evidence at all. So I don’t see why his conjectures should be taken more seriously than any other evidence-free conjectures. Let a zillion flowers bloom.
