Freakonomics Radio - The Zero-Minute Workout (Rebroadcast)
Episode Date: January 2, 2020There is strong evidence that exercise is wildly beneficial. There is even stronger evidence that most people hate to exercise. So if a pill could mimic the effects of working out, why wouldn’t we w...ant to take it?
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Hey there, podcast listeners, and happy new year.
If you're like most people, you've made a New Year's resolution or two.
And if you're like most people, this resolution will fail.
Among the most popular resolutions we make and fail to keep, exercise.
This is the year I'm really, truly going to do a whole regular exercise thing.
If that's your resolution, you should find today's episode particularly compelling.
It was first published last June and has already been downloaded about 2.2 million times.
It is called The Zero Minute Workout. Pedal faster, Steven.
Hey, this is Steven Dubner.
I'm at the gym.
Your current heart rate is 110 beats per minute.
Your target rate is 130 beats per minute.
We all know that exercise is good for us.
We also know that most people don't get nearly enough. 34% of US adults are physically inactive,
another 20% are insufficiently active, and not surprisingly almost 40% of US
adults are classified as obese. To be reductive, many of us eat too much and exercise too little. Now, why don't we get more
exercise? Let's be honest. It is hard work. Stephen, I told you to pedal faster. The cost
of physical inactivity is massive, not just in illness and death, but in dollars too. Researchers
from the Centers for Disease Control and Emory University
say the U.S. spends about $117 billion a year on health care due to inadequate physical activity.
And those are just the direct costs from treating cardiovascular disease,
diabetes, and so on. It doesn't even include things like the loss of productivity.
There is a big hill coming up.
Stephen, are you ready?
It's strange if you think about it.
For thousands and thousands of years, our ancestors worried about not getting enough food to eat.
And their daily life required physical activity.
Today, food is everywhere and cheap and super fattening.
And a lot of us have lives that require very little physical activity, which is why I'm here on this stupid bike.
I am not going to take that personally.
A lot of smart people have spent a lot of time and effort
trying to get people to exercise more.
Mostly, they failed.
So what happens next?
Wouldn't it be amazing if, instead of exercise,
there was something like an exercise pill?
I do not like that idea. I do not like that idea one bit.
From Stitcher and Dubner Productions, this is Freakonomics Radio, the podcast that explores the hidden side of everything.
Here's your host, Stephen Dubner.
Okay, glad that's over. So, obesity started out as a problem in wealthier countries,
but now it's spread to middle and low-income countries.
The contributing factors are not in dispute.
We consume too many calories, especially low-quality calories,
and we don't burn off nearly enough calories with physical activity.
Now, to be fair, burning calories through exercise is a pretty inefficient process.
It takes a lot more exercise than you'd think to burn off one cheeseburger. In that regard,
it'd be better to just eat less. That said, exercise is also considered a very valuable
input for overall health. That's what we've been told, at least. But let's not take that for
granted. Let's see if we can find some real evidence for that claim
and understand why exercise is supposed to be so good for us.
We'll start with this man.
My name is Michael Joyner, and I'm a physician scientist at the Mayo Clinic.
A physician scientist meaning what?
I'm basically a physiologist who is also a clinical anesthesiologist.
So that sounds pretty impressive, a physician-scientist at the Mayo Clinic.
But just so you know, Michael Joyner was an unimpressive student growing up in Arizona.
You're correct. I was a sort of an indifferent student at Rincon High School.
And I started college in 1976 and went to several schools in one year.
I ended up in 1977 at the University of Arizona,
where I promptly almost flunked out. And in December of 1977, I'd actually signed up to take
the test to become a Tucson City fireman. And what happened is I was out running a race, a 10K race.
Joyner was a pretty good athlete.
I ran track and field at the University of Arizona,
where I ran the 5,000 and the 10,000. I also ran a 225 marathon in the late 70s. If you're not
familiar with marathon times, two hours and 25 minutes for more than 26 miles, that is a very
fast time. And then I continued to run until I was about 40. He still exercises about an hour a day. It varies between a relatively
easy day of aerobic exercise on the bike or maybe some swimming. And then on the opposite days, I do
something relatively intense, which includes a warm-up and then about 30 or 40 minutes of
circuit training. And because I'm 60 years old, I've done probably a little bit more strength
training the last 5, 10 years,
because as you get older, you really want to avoid frailty, muscle loss.
You don't want to slip on the ice, that sort of thing.
Back when Joyner was thinking about becoming a fireman, and he was running that 10K race,
a man named Eddie Coyle, who's a well-known exercise physiologist,
and he was a graduate student in the lab at Tucson at the time.
And he said, do you want to be a subject in a study on lactic acid?
I said, sounds good to me.
So I showed up and ran in the lab, and I said, man, this is unbelievable.
There's actually people who do this for a living.
Joyner was told he could work in the lab as a student assistant if he got his grades up.
And so then I had kind of a square wave experience with my grades and started
basically getting straight A's. And I saw that if you wanted to do studies in humans where you put
catheters in and do biopsies and that sort of thing, it would be facilitated if you were a
physician. So unlike a lot of physicians who get interested in research in medical school,
residency, or fellowship, I actually went to medical school with the express purpose of
becoming a research-based integrative physiologist. It did take Joyner a while to get into medical
school. Because I had to kind of do a little academic rehab to make up for those first bad
two years. And then I came to Mayo in 1987, and I've been here ever since. So you're a big deal
in the field of physiology, exercise physiology. Can you first,
just for total lay people, define physiology for us? If you think about anatomy, anatomy describes
the parts of the body. Physiology is really the engineering equivalent of that and says,
what do these different parts do alone and in combination? And so there are all sorts of
regulatory mechanisms that increase or decrease our breathing, increase or decrease our urine output.
And so what we do as physiologists is study these regulatory systems and try to understand how all living forms adapt to environmental challenges.
Okay, so open-ended question.
Tell us what we know in a nutshell.
We'll get into details as we go.
But tell us what we know about the benefits of physical exercise.
What we know in a nutshell is that people who are physically active, especially if they
get somewhere between 150 and 300 minutes per week of moderately vigorous physical activity,
have a large reduction in their all-cause mortality, typically about a 50% or maybe 40%
reduction in their all-cause mortality. And typically, they live somewhere, depending on
the study, between about four and seven years longer. Wow. Okay. Quickly, define for me all-cause
mortality. It just means you could die of anything. Could be cancer, heart disease,
infectious disease, and so forth. And that's one of the points people need
to remember. We typically think of exercise as being especially protective against death
and disability and diseases associated with the cardiovascular system, but it's also protective
against a number of forms of cancer and a number of things like diabetes and other diseases.
Okay, so you may be saying to yourself, Michael Joyner sounds credible and he's got great
credentials, but we also know he's a bit of an exercise fanatic himself. So how can we be sure
that it's exercise that's actually causing better health outcomes? What sort of baseline physiological
evidence is there for that claim? Well, a couple of things. You know, the best evidence comes from
various population cohorts. The most famous being the bus driver, bus conductor data from after
World War II in London, where they showed the sedentary bus drivers had much higher rates of
coronary artery disease and heart attack than the active conductors who were walking around
punching tickets going up and down the stairs all day. And they showed a similar thing when they compared clerical workers to postmen.
Again, all males, all members of the British civil servants.
And that's where that, you know, 40, 50 percent reduction in all-cause mortality
and cardiovascular mortality came from.
Okay, that is a neat story, the bus drivers.
But that was a long time ago.
Has the effect been shown more recently?
It's been shown over and over again in every sort of cohort study.
Then you come to some other things.
So if you start looking at people with risk factors, people with hypertension, high cholesterol, obesity, so forth and so on,
people with high levels of physical activity or cardiorespiratory fitness, their risk is markedly blunted. So I like to tell people that exercise and fitness
really absolve you of other sort of risk factor sins. All right, fine. But a couple of things
here. Cohort studies or population studies, those are not the randomized controlled trials that
scientists consider their gold standard. And how do we know that people with high levels of physical
activity, as Joyner's describing here, how do we know that people with high levels of physical activity, as Joyner is
describing here, how do we know that there aren't other reasons for their good health? Maybe the
kind of people who are more likely to exercise are the same people who are more likely to eat better
or sleep better. Maybe they're the same people who don't smoke or who face less stress in their
lives, stressors like poverty or difficult work or home environments.
How does Joyner know that exercise is such a strong causal mechanism of good health?
You get into studies in individual humans where you can take people and do very brief
periods of exercise training, improve their glucose tolerance, improve the function of
their blood vessels, and improve a whole lot of biomarkers,
which are associated with health.
And then you go one step further to animal studies,
and you can really take a deep dive into the mechanisms behind those positive changes.
Okay, what are those mechanisms?
A lot of Joyner's research is about how physical activity increases blood flow to skeletal muscles.
Your heart rate goes from 60 or 70 to
around 200. So you have about a threefold increase in heart rate. And then the amount of blood
pumped with each heartbeat also goes up. So think about that. So at rest, a tiny amount of that
blood flow, maybe 500 mLs, is going to all the muscle in your body. During maximum exercise, perhaps 16 or 17 liters is going to muscle.
Now, why is blood flow per se important or beneficial?
Well, the bottom line is if you're going to do prolonged exercise,
you've got to get oxygen from the lungs to the skeletal muscles,
so you have to have a big cardiac output.
And you've then got to get it to the muscles that are actually contracting. So it's just a supply-demand situation. Okay, so take me from
there, though. So you do vigorous exercise. It increases the blood flow a lot. What then are the
longer-term, I guess, physical and cognitive benefits of that increased blood flow? One is
that the blood vessels kind of grow. They become larger in diameter.
The lining of the blood vessels, the vascular endothelium, becomes more slippery and becomes
more prone to relax versus constrict, which makes your blood pressure lower.
And then the capillaries and small blood vessels around the skeletal muscles also grow.
So because there's this large increase in cardiac output, all of
the large blood vessels throughout the body become larger and the endothelial function increases.
They become more elastic, less stiff, which is also a good thing. The other thing to remember
is, and this is a really big finding in the last 20 years, is that there are hormone-like substances
secreted by the skeletal muscle which have
remote effects. They have effects on the liver to improve metabolism. They have effects on blood
vessels everywhere. And they also release something called BDNF, brain-derived neurotrophic factor,
which is good for brain growth. And people think that's at least one of the links between
physical activity and cognition and preservation of
cognition as you age. So it sounds like the benefits of exercise are massive and widespread,
and therefore we would all be idiots to not do a lot of exercise or at least enough exercise. So,
Dr. Joyner, what share of Americans do get what you'd consider to be enough exercise?
Oh, you see various numbers depending on whether it's survey research or tracking research. Dr. Joyner, what share of Americans do get what you'd consider to be enough exercise?
Oh, you see various numbers depending on whether it's survey research or tracking research.
But, you know, if it's 20%, that's a generous number.
So do you feel that you personally have been preaching the gospel of exercise for a long time and that people are not really buying? You know, I just try to point out the benefits and set a good example and be
as encouraging to people as I possibly can. People really need to understand that they need to do
something, do it regularly, and it's okay to take it in small bites. But until we have a wholesale
change in transportation and food policy and just the way things are, I don't see a whole
lot changing.
Most of the population's behavior aligns with various overt and covert incentives.
And I think we have a whole lot of incentives to be physically inactive and eat a lot.
I mean, there's a terrific study from Toronto showing that the walkability of whatever zip code equivalent you're in in Toronto, the walkability of that neighborhood
predicted who gained how much weight over, you know, 10 or 20 years. So I think we have a built
environment problem. I think we've got an incentive problem. I think that, you know, as much as I'd
like to tell everybody to go exercise, I think we've also got a transportation policy problem.
When you go to places like the Netherlands or Denmark that are very biking friendly, when whole cities are built to do that, you know, you see a lot of really fit people. The challenge is we're endlessly pitted against the technologic advances in civilization that tends to make us not move.
That's Ronald Evans.
I am the director of the Gene Expression Laboratory at the Salk Institute.
The Salk Institute for Biological Studies is one of the most important biomedical research institutes in the world.
And a lot of the work that we do studies the nature of genetic circuits that control metabolism.
Dr. Evans, like Dr. Joyner, is a big believer in the benefits of exercise.
Exercise is a beneficial factor that burns calories,
but it also activates many metabolic pathways that are pro-health.
But Evans is also a realist.
And this, given the human propensity to eat too much and exercise too little,
has turned Evans into a futurist.
He wonders whether we should accept the fact
that most people are never going to exercise enough
and instead think of a biomedical solution?
Very big question, and I think it deserves a lot of thought.
What sort of solution is Evans working on?
Exercise in a pill.
Details coming up right after this.
Fact one.
The typical modern human would do well to exercise more than they do.
Fact two.
Public health advocates and others have been urging us to exercise for many years. Fact three, their urging doesn't seem to work. Consider fact four, in the
U.S., more than 80% of large companies offer programs that encourage and often incentivize
exercise and weight control. A randomized study of one such company, BJ's Wholesale Club,
was recently published in the Journal of the American Medical Association.
It found that employees in the wellness program did self-report that they were more likely to
exercise and manage their weight. But the data revealed there were no significant differences
in actual health markers, including weight loss.
And as we heard on an earlier episode of Freakonomics Radio,
a world-class team of behavioral scientists recently did an experiment over 28 days
with 53 different interventions to try to increase the exercise activity
of people who were already members of a gym.
So after our 28-day program, pretty much we saw nothing in terms of behavior change.
That's Katie Milkman from the University of Pennsylvania.
All 53 versions of the program, pretty much nothing sticks.
And that was the ultimate goal.
So that was major failure.
With so much failure, you can understand why a lot of people look for exercise shortcuts.
The revolutionary new AbTrans transform system is the safe,
effective, and affordable way to change the way you work out and look forever. But maybe there's
another kind of shortcut, something a bit less hucksterish, a bit more grounded in science,
which brings us back to the biologist Ronald Evans from the Salk Institute. Evans is well
known in the field
for having discovered a family of hormone receptors that act as genetic switches.
And if you think of genes as instruments in an orchestra, you can have many different kinds of
sounds or many different ways to have them work together. And the conductor that makes the genes
come on at the right time and
orchestrate all that are regulatory factors that are called transcription factors that activate
the genes. So those are genetic switches. This is really the underpinning of a lot of
our body's physiology is while all cells have the same number and same set of genes,
individual cells activate different sets of genes and the
receptors and the hormones control gene networks. And so a lot of our physiology is about genetic
control. The discovery and understanding of this mechanism of genetic control has been incredibly
important. Once you have a mechanism, then you can think of how to actually develop therapies or
drugs that can control that mechanism. Everyone's familiar with hormone replacement for people.
Sometimes you lose a thyroid gland for various reasons, and you can replace that by finding or
making the hormone and then giving it back to the person. The steroid hormones are amongst the most widely prescribed drugs on the
planet. And perhaps the most famous steroid hormone therapy, the birth control pill. And that's all
about using these receptors. And in many ways, the impact of this family of receptors and
pharmaceuticals have changed society.
Ronald Evans may be on his way to creating a new pill,
which once again has the potential to change society.
Exercise in a pill.
His lab is developing a pill that would mimic the effects of exercise
in the absence of actual exercise.
Other labs around the world are working on similar exercise memetics,
as they're called, with various mechanisms. Evans' pill works by targeting one of two
key hormone receptors. There are two hormone receptors that we discovered that are very,
very close to each other, but play exactly opposite roles and complementary roles in body physiology as well as in disease.
And so one of the hormone receptors is called PPAR-gamma, and it is the master regulator of
adipose tissue. Adipose tissue is what most of us know as fat. You need this genetic regulator to activate the fat network. It's critical for
survival. You need to store energy in fat to survive. And then the partner for that,
it's called PPR Delta, which we discovered in 1995. That's the receptor that burns fat.
And most of the problem with disease is too much storage
and not enough burning so one of the ways that we have approached the problem is looking at drugs
that could be specifically built to target the fat burning receptor of ppa or. And that's led to a number of companies producing new kinds of molecules.
And one of the companies that I created a number of years ago developed a screening technology
that was licensed to Glaxo Welcome, and they built a drug called GW-1516.
Glaxo Welcome is now known as GlaxoSmithKline.
GW1516 originally had a different purpose.
It was made to change cholesterol levels and to try to increase something called HDL.
And this drug never made it into FDA approval.
It had problems.
Problems like causing tumors in the mice it was tested on.
Evans eventually began working with a less powerful version of the drug with the assumption it would be less toxic.
Another difference?
He wasn't looking at its effect on cholesterol.
So one of the surprising things that come out of studying the GW1516 compound
and it was a very dramatic result,
is when we gave it to sedentary mice or obese sedentary mice,
either one, for about 30 days. The GW drug progressively activated the genetic program
that is normally activated by exercise. I think we should hear that last bit again.
The GW drug progressively activated the genetic program that is normally activated by exercise.
In other words, their physiology seemed to indicate the mice had been exercising.
But these mice were not getting exercise. They were just getting the pill.
As you can imagine, this was a pretty exciting research result.
But how well did the pill do in terms of giving the benefits of exercise in a general sense?
You have to be careful when you say, does the pill give the benefits of exercise in the general sense?
Because exercise is a hundred things.
But I should say, in general exercise, no matter how you do it, focuses on a few things.
It increases energy expenditure.
It tends to increase burning of lipids and fats and sugars.
You get adult neurogenesis
and that enhances cognitive performance.
It also improves immune fitness, lowers inflammation.
So it has many benefits to the heart
and other parts of the body.
Now, if we go to this, what does PPR Delta drug do
in terms of metabolic fitness and let's
say the brain, it does exactly the same things.
It gives you this increased energy expenditure.
You burn more lipids, you burn more sugar, and you correct your insulin.
Your adipose depot starts to shrink, so you lose weight.
And the drug by itself gives you adult
neurogenesis. The drug also seemed to boost endurance, at least in the mice. After 30 days
of giving them the drug, Evans and his team put the sedentary mice on a treadmill. It's a mouse
treadmill. It's very cute. And we compared the mice that got the drug with ones that did not get the drug.
And the difference was striking.
The ones that got the drug could run approximately one hour longer,
continuous running, than the ones that didn't.
And what is the mechanism for this endurance effect?
What the actual drug does, it increases fat burning by the powerhouse of the muscle cell,
which is called the mitochondria. And the mitochondria can burn sugar or fat. But what the drug says is we want
the mitochondria to burn fat specifically and convert fat into the chemical form of energy
called ATP. But don't burn sugar. That's because the sugar or glucose is needed for brain energy.
And so the P-Pari Delta drug powers the brain
and powers the fat
by separating out the two energetic molecules in the body
for different purposes,
one for the muscle and one for the brain.
And by doing that,
you're able to sustain your running time
by an hour or an hour and a half if you're a mouse.
So this sounds pretty much like a miracle drug, doesn't it? Others thought so too. Right before
the 2008 Beijing Olympics, Evans reached out to the World Anti-Doping Agency, or WADA, about the potential for athlete abuse, and he eventually helped develop a test for it.
Soon after, WADA banned the drug, but in 2013, a bunch of pro cyclists were caught using it.
Fast forward to today, Ronald Evans and a pharmaceutical firm he co-founded, Mitobridge, are working on a new form of the drug that's meant to minimize side effects.
So the Mitobridge drug has been in what's called Phase I studies,
and it's now moving on to Phase II studies.
So the most critical is the Phase I to me because that's the safety.
They're now through that part.
So the next part is, does it work?
Then it works very well in the mouse models,
but we have to show that it works well in people.
We know it's safe in people,
but we have now to show that it works.
I would say two or three years
that we will have a pretty good idea
if it's working in human disease
in a way that could achieve FDA approval.
To get the drug through FDA approval,
MitoBridge is targeting patients with Duchenne muscular dystrophy.
That's a genetic disorder typically striking young boys who rarely survive into their 20s.
There is no real drug to treat it.
But our approach is to restore this balance of energy utilization in the muscle.
And we can stimulate that muscle to actually burn fat and become activated as if it was being exercised.
But Evans clearly sees a much wider potential use for this drug.
There is absolutely no way that the potential here is going to be limited to one
or two diseases. It will be very high from metabolic to neuro to vascular to aging. We can
think of the potential here in different ways. And maybe to the wider question, can it be used
preventatively in some cases just to maintain health as opposed to just treating
disease. And this is not an easy issue because taking healthy people and giving them a drug
is not common. Now, it does happen. A lot of people take adult aspirin for their entire life
because it's thought to be helpful to reduce inflammation and reduce
heart disease. Tens of millions of Americans also take statins every day to forestall heart disease.
Millions more take metformin to treat diabetes or even the onset of diabetes. We put fluoride
in our water supply to prevent tooth decay. And so could you transition this to a society
that is getting heavier
and running into the problem of obesity and diabetes
and the related complications?
The answer is yes,
but I think from a social and ethical component,
it raises a big question that should be addressed.
It's not unusual for scientific advances
to raise social issues and questions.
We have this all the time.
Indeed, just because a drug may soon exist
that could mimic the effects of exercise
does not necessarily mean we should immediately
spike our water supply with it.
So Evans' drug, if it does make it through FDA approval,
will surely have its philosophical and ethical skeptics.
But even now, it's got its physiological skeptics.
So an exercise memetic.
That, again, is Michael Joyner from the Mayo Clinic.
If you think about it, the main ones have been designed to try to increase the function of the mitochondria,
the little organelles in the skeletal muscle
that burn carbohydrate and fat and are critical to the metabolic benefits of exercise.
And certainly you can stimulate those with drugs.
But if you look at the broad class of things that exercise does, it goes way beyond just
affecting the mitochondria.
It affects, again, the blood
vessels, the remote effects of training, the effects on the brain, the effects on intermediate
metabolism, and all sorts of other things. So I think you can find a memetic for things that sort
of look like exercise, but I don't think you're going to find the big picture drug or compound
that can do the 10 or 15 main things that exercise
does for people. What would you think of, let's call it the exercise pharmaceutical that works
along the lines you're describing there on a mitochondrial level for those who can't exercise
due to, let's say, physical handicap or some other condition? Do you like that idea? Absolutely.
Absolutely. You know, you start thinking about exercise is good for your lipids, exercise is good
for diabetes, exercise is good for this and that.
And there's a terrific idea and a very interesting paper in the early 2000s, I believe in the
British Medical Journal, which said, you know, why don't we put everybody in low-dose statins,
low-dose antihypertensives, everybody over 50, low-dose anti-diabetic drugs, and see what it would do to their life expectancy and all-cause mortality.
So some people have argued that really this is closer to an exercise memetic than drugs that target the mitochondria, for example.
But you can imagine that if a so-called exercise pill does come to market, it might provide people the license to never exercise again. There's been research
showing that there can be licensing effects with diet behaviors. You remind me that I've
been dieting well, then I maybe eat more. Katie Milkman again from the University of Pennsylvania.
So if you give people a pill and say, you know, this has the effects of exercise,
well, they feel licensed not to exercise. It's a real risk.
I do not actually like to think of it that way
because we are designed to move.
And that, again, is Ronald Evans,
the man behind the exercise pill.
And so the social issue is not just
should we give the drug to everyone,
it's how do we manage the intrinsic advances
that are working against our health?
He may not intend for it to replace fitness, but will people take it and then feel that they're
licensed to skip workouts? And so whether that's the intent of the medication doesn't mean it won't
be a nasty side effect. Marcus Bauman, a physiologist at the University of Alabama, Birmingham,
is also not in favor of an exercise pill. Because there are thousands upon thousands of
molecular responses to exercise that cannot be recapitulated by one pill.
Bauman has another idea, a sort of hybrid idea, which he feels may be necessary given the
difficulty of turning an inactive person into an active one. Going from true sedentary status to
a regular exercise training habit or behavior, there are a lot of steps required to make that
happen. And one of those I think that would be very tangible for people is a prescription with good guidance. A prescription meaning an individualized
exercise regimen. It really doesn't do the patient a lot of good for a healthcare provider to just
say, well, your blood pressure is high, your glucose is high, and you need to lose some weight, so you should do more exercise. They don't know how frequent, what intensity, what dose,
is it resistance, is it endurance, is it a combination?
Bauman and his research team at UAB have been doing research for 15 years on this idea.
They started with older adults and now work specifically on patients with Parkinson's,
multiple sclerosis, and epilepsy.
But their idea is that everybody could benefit from an exercise prescription.
Let's just take the individual who comes to the clinic, 45 years old.
They've got a body mass index of 32.
For the record, that is a pretty high BMI,
the equivalent of a 5'10 person who weighs more than 220 pounds.
They've got some level of insulin resistance going on.
They've got stage 1 hypertension.
They've got some knee pain.
In a perfect world, or at least in Marcus Bauman's world,
a physician would have a lot of good data on exactly what forms of exercise,
at what intensity and duration, would be most useful.
If you can then point to that data and say to that person, the evidence is clear, this works,
and now I'm going to refer you to somebody who knows how to implement this evidence-based
prescription, I think that would have a major impact on whether or not somebody adopts the change. But the truth is, those data on ailment-specific exercise are fairly sparse.
In terms of which type of exercise is best for a given disease risk cluster,
the research is really void in many areas.
That may be starting to change.
The National Institutes of Health is starting an exercise trial as part of a program called the Molecular Transducers of Physical Activity Consortium.
And that study is really comparing resistance training to endurance training
and trying to understand the molecular mechanisms
by which each of those modes of exercise training induces potential health benefits.
You could also imagine that technology, especially smart technology,
has a larger role to play in helping us achieve our fitness goals,
like making exercise equipment and apps that, rather than beating us up,
Steven, I told you to pedal faster,
are a bit more encouraging.
Well, aren't you the little champion?
Five whole minutes on the bike without a break.
That's your new personal best.
In the meantime, coming up next week on Freakonomics Radio,
we all love to read about the latest breakthrough
in psychology research, don't we?
But the danger, I think, is quite right, which is that we can very easily push our wonder
buttons and push our interest buttons using pseudoscience rather than science.
What if I told you that a lot of the terms that psychologists use are all different kinds
of wrong?
Yes, inaccurate or misleading, frequently misused, ambiguous terms, oxymorons, and pleonasms.
For instance?
So, one that comes to mind is bystander apathy.
The biggest error is to assume that these personality traits are unitary, they only have one cause, and that they're inherited. One of the most important discoveries in neuroscience of the last few years has been that all that
hardwired stuff is completely wrong.
So what are psychologists good for anyway?
That's not a bad question, actually.
Misused and abused concepts from psychology and psychiatry.
That's next time on Freakonomics Radio.
Freakonomics Radio is produced by Stitcher and Dubner Productions.
This episode was produced by Morgan Levy with help from Daphne Chen.
Our staff also includes Allison Craiglow, Greg Rippin, Harry Huggins,
Zach Lipinski, Matt Hickey, and Corinne Wallace.
We had help this week from Nellie Osborne.
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