【英语语言学习】进化、健康与疾病
时间:2019-02-23 作者:英语课 分类:英语语言学习
英语课
This is FRESH AIR. I'm Terry Gross. Acid reflux, acne, anxiety, asthma 1, certain cancers, depression, type 2 diabetes 2, flat feet, high blood pressure, irritable 3 bowel 4 syndrome 5, lower back pain and osteoporosis - that's just a partial list of non-infectious diseases that might be caused because our bodies haven't sufficiently 6 adapted from the Paleolithic Era to modern life. This is what evolutionary 7 biologists like my guest Daniel Lieberman are proposing.
Lieberman is the author of the new book "The Story of the Human Body: Evolution, Health and Disease." He admits that if you're sick, you would not go to an evolutionary biologist to get treated. However, evolutionary biology can help you understand why you got sick, and it can help you be more aware of healthy and harmful behaviors. Lieberman is a professor of evolutionary biology at Harvard University.
Daniel Lieberman, welcome to FRESH AIR. I want you to explain the basic premise 8 of the book, about mismatch diseases.
DANIEL LIEBERMAN: Well, many people wonder how their bodies function today, and what's the relationship between how our bodies evolved and how we use them and how we get sick. And a key premise of the book is that many of the illnesses that we confront today are what evolutionary biologists call mismatch diseases. I didn't come up with the term. It's been around for a while.
But mismatch diseases are diseases that occur because our bodies are poorly or inadequately 10 adapted to environments in which we now live. So an example would be eating large amounts of sugar or being very physically 11 inactive leads to problems like diabetes or heart disease that then make us sick.
So mismatch diseases are really diseases that are modern, in the sense that they're more prevalent or even novel, or more severe because we don't live in the way in which our bodies are adapted.
GROSS: OK, let's look at diabetes 2, type 2 diabetes, which is, you know, in epidemic 12 proportions in the United States and now much of the world. So this is a good example of a mismatch disease. Why are bodies ill-equipped for the kind of foods and fats and sugars and the quantity of food that we're eating now?
LIEBERMAN: Yeah, well, this is an important topic, obviously. You know, in India and China, for example, rates of diabetes are going up by almost an order of magnitude over the last generation, and they're going up very rapidly in the U.S., too. And the reason we're - they're mismatch diseases is that diabetes, for example, is caused by, essentially 14, the body being unable to cope with sugar in the bloodstream.
So we evolved to crave 15 sugar, because sugar is an energy-rich food, but we didn't evolve to digest large amounts of it rapidly.
GROSS: So our bodies, the basic operating system of our bodies was designed for the hunter-gatherer era, right?
LIEBERMAN: To a large extent. I mean, until hunter-gatherers, and even before hunter-gatherers, chimpanzees, for example, eat plenty of foods that have carbohydrates 16. For example, chimpanzees eat almost all fruit. Right. You think, oh, if they eat all fruit, they must be getting a lot of sugar. But the sugar that they get is very different from the sugar that we get.
First of all, it's bound in cells. You have to digest it, and there's lots of fiber 17 in and around the sugar. So you don't get access to that sugar really fast. And there's much less sugar in those sorts of foods. So we evolved to crave sweet foods. Everybody loves sweet foods. But if you try to eat foods that hunter-gatherers eat or chimpanzees eat, you'll be surprised at how un-sweet they are. Most wild fruits are about as sweet as a carrot.
So we love sweetness, but until recently, pretty much the only food that we got that was very sweet was honey, and honey, of course, was a special treat. That was pretty much the only form of dessert in the Paleolithic. But now we have access to abundant quantities of sugar and to simple carbohydrates, which we evolved to love because they're full of energy, but we don't have the metabolism 18, we don't have the bodies that are able to cope with those kinds of levels of sugar. And the result is that we get sick.
So, type 2 diabetes used to be exceedingly rare. I mean, it did happen occasionally, but it was an extraordinarily 19 rare disease. And to my knowledge, there's not a single case of any hunter-gatherer ever diagnosed with the disease. And it was rare for our great-grandparents. But today, it's become very common because of the foods we eat for which we're not adapted. So, in that sense, it's a very classic mismatch disease.
GROSS: So, like our ancestors a zillion years ago, they didn't have sweets like we have sweets. The body needed - the body needs sugar, and it was designed to process sugar from foods like fruits, not designed to process sugar from foods like apple pie with icing on it or cinnamon rolls and stuff like that that are just, like, loaded with fat and sugar. Do I have that right?
LIEBERMAN: And all that good stuff. Yeah, exactly. So, sugar is good, right. Energy is good. Think about what natural selection's really all about.
GROSS: Right. Mr. Hunter-Gatherer needed that energy.
LIEBERMAN: Right. Well, the more energy you have, the more successful you'll be. Most hunter-gatherers, most animals live on the margin 20 of energy balance, right? They have just enough energy to do what they need to do, and any more energy is a good thing, right. It means that you can put more of that energy into growing a better body, or put more of that energy into reproducing and put some of that energy into coping with periods when food is scarce.
And one of the interesting things about humans is that we are specially 21 tuned 22 to energy, compared to other animals. We're actually a very fat species, compared to other primates 24 and most other mammals. The average primate 23, a chimpanzee or a monkey, has maybe about 5 or 6 percent body fat, whereas a thin human being, a very - you know, a supermodel has more, much more body fat than that.
You know, it's normal to have about 10 to 20 percent body fat for a normal, average, healthy human being. So we're already a very fatty species, in a way, and that's because we have a very - we evolved a very energy-intensive way of reproducing. And that part of our story is incredibly important to know, because we pulled off kind of a hat trick in the Paleolithic, right.
We figured out how to grow big bodies with really big brains. And brains are very expensive, and they always need lots of sugar all the time. And we also figured out a way to have babies about twice as fast as our ape ancestors. So a typical chimpanzee has a baby every three years, and she waits until that baby is pretty much fully 25 grown and able to feed on its own before it has another baby.
But humans are able to have - in the - you know, today, of course, we can have babies every year or so. But hunter-gatherers managed to have babies every three years, and that's well before a baby is able to eat on its own, forage 26 on its own. So mothers have to have lots of energy to grow babies in the womb. They have to have lots of energy to breastfeed them, and that costs a lot of energy to synthesize, to make breast milk. And they also have to have extra energy to feed those toddlers and young kids around who can't fully feed themselves.
That reproductive strategy that we evolved at some point during the Ice Age requires enormous quantities of energy, and it requires energy reserves. We have to be able to store it in our bodies. We have to have access to a lot of it, and so we're like gas guzzlers of the primate world.
GROSS: You know, in your book, "The Story of the Human Body," about evolutionary medicine, you write about how when farming evolved, then industrialization, the nature of what we were eating changed, and the nature of how we spent our time changed, too. You know, with farming, we started to eat more grains, more carbohydrates, and you write about how that can be very taxing on the body.
How come our bodies haven't evolved more effectively to deal with more modern life, to deal with the kind of foods we actually do eat now?
LIEBERMAN: That's a wonderful question. Well, to some extent, we have. But some populations have done it a little bit better than others. So going back to type 2 diabetes, for example, there are genes 27 that protect some people more than others from the disease. These are genes that probably evolved fairly recently that give some populations - it tends to be Europeans - better ability to cope with high-glycemic foods, and that means foods that cause more sugar in your bloodstream.
But some populations, for various reasons, probably chance, never evolved as many of those adaptations. So they tend to be more prone 28 to developing diabetes and obesity 29 from the same kinds of diets. So India and China are examples of countries where these epidemics 30 seem to be growing faster because of a lack of selection that somehow occurred, or just the genetic 31 variation that made it possible for evolution to give some protection.
So we did actually evolve, to some extent, to cope with some of these changes in our diet. Another factor is that a lot of these diseases don't occur until after people have reproduced. So most people who get diabetes, for example - I know we're harping 32 on this disease - but most people who get many of these diseases, heart disease, diabetes, hypertension, often get them after they've had their kids and after their kids are grown up.
And so the ill effects of these diseases don't have a very strong selective effect. So natural selection is not going to really operate that strongly.
GROSS: Oh. I see what you're saying. Because you've already reproduced, so any adaptation that you make as a result of the disease, it's too late to have an effect on reproduction.
LIEBERMAN: That's right. And, you know, it can have some effect. So we know, for example, that there's a strong selective benefit to being a good grandparent. Grandparents who do well - particularly among hunter-gatherers - their offspring do better. But with the origins of farming and industrialization, that role of grandparents in terms of providing food has declined in importance, and so those grandparenting-selective effects have probably also declined, as well.
(BREAK)
GROSS: Let me ask you about comfort food. Many of us, when we're stressed out, we crave carbohydrates or sweets, and you say there's actually an evolutionary reason for that.
LIEBERMAN: Yeah. So, the hormone 33 that gets elicited 35 when you get stressed is cortisol. That's the chief one. So when - if you jump out an airplane, or if something really bad happens, a loved one dies, our body goes into a flight-or-fright state. We're ready for danger. And cortisol plays an important role, because it releases sugar into the bloodstream. So you can run from that lion or deal with whatever that bad situation is. It makes you more alert.
But it also - cortisol also makes us want to bring in more energy to cope again with that - those energetic needs. So stress activates 37 basic primal 38 urges to eat calorie-rich food, which is, of course, useful to cope with those kinds of situations from an evolutionary perspective.
So people who have lives that contribute to higher basal levels of cortisol are more likely to suffer the ill consequences of that stress.
GROSS: So when we're stressed, we secrete 39 more cortisol, which gets us to crave fats and sweets. Another part of the problem here is that just because we're stressed doesn't mean that we're actually running from a beast that's chasing us. We're probably sitting in a chair or standing 40. So how does that affect how our bodies respond to both the cortisol, and also to the sweets and carbs that we're eating?
LIEBERMAN: Well, stress creates this sort of vicious cycle, this positive feedback loop, because when you're stressed, you crave unhealthy foods. But when you're stressed, you also have a harder time sleeping. And when you have a harder time sleeping, that elevates your levels of stress. It just sets off this chain reaction that keeps going on and on.
Now, normally when we're stressed, that's - the stimulus 41 that causes the stress should be a short-lived one. That's what evolution predicted, right. A lion chases you, that's a very stressful event, obviously. Hopefully you manage to run away from the lion. You climb into a tree. You calm down. You tell everybody the story. Life goes on.
But much of the stress that we create today results from social conditions. If you think about, you know, the most stressful things that we experience, they're often our lives. They're our jobs, our commutes 42, having - not having enough money, the list goes on. And those, of course, elicit 34 chronic 43 levels of stress.
And when stress becomes chronic, then it helps feed a variety of mismatch diseases that make us ill, that make us depressed 44, that make us anxious, that make us overweight, which then cause more stress, which then keep the cycle going.
GROSS: What are some of those mismatch diseases that arise from the stress response?
LIEBERMAN: Oh, gosh. Many of them are metabolic 45 diseases. So anything that has to do with high blood pressure, so hypertension, strokes. Stress certainly has effects on cardiovascular disease. Stress has effects on many mental health diseases and illnesses. In fact, the list is so long, I'm not sure it would be a good idea to list them all.
GROSS: Oh, OK. But - well, let's get to digestion 46, since we're talking about food and stress. You describe the gut 47 as a second brain, having more nerve endings than our spinal 48 cord or our peripheral 49 nervous system. What are all those nerve endings doing in our gut?
LIEBERMAN: Oh, gosh. Well, they're helping 50 move food around. They're - they help with just basic process of digestion, your - for example, when you eat a meal, you have to push all those - all that food through your digestive system, all the way out to the outside world. And so you have all these contractions 51 that your body is completely unaware 53 of that are squeezing the food along.
There are other nerve responses that sense what kind of enzymes 54 need to be added to the system. It's - digestion is a very complex phenomenon that has to be regulated, hence has a lot of neural 55 control.
GROSS: Why does our gut know when we're nervous?
LIEBERMAN: That's a good question. I don't actually know the answer to that. Certainly - well, I know partly the answer to that. Certainly, much of our digestive system is regulated by what's called the autonomic nervous system. It's the involuntary nervous system that you have. And the involuntary nervous system, of course, is heavily regulated by hormones 56. And among the chief hormones that regulate that system is cortisol.
So, when we get stressed, or when we get excited, hormones then affect pretty much every aspect of our body, including our digestive system. So sometimes we want to activate 36 energy. Sometimes we want to store it away for future use. So, you know, one of the things that one learns when studying and teaching human biology and physiology 57 is just how interconnected every system of the body is with other systems of the body.
It's - you can't change one thing without changing many things. And the hormonal 58 system is - its job, actually, is to help make all those systems work together.
GROSS: So while we're talking about digestion, you write about how irritable bowel disease and Crohn's disease, which lead to all kinds of intestinal 59 distress 60, are mismatch diseases. So put that into context for us.
LIEBERMAN: Well, many of the mismatch diseases that we think are going on - or actually, they're hypothesized, because we don't totally understand their origin. But Crohn's disease, for example, is a recent disease. It used to be extraordinarily rare, and today it's cropping up more and more as - and it's an autoimmune disease. It's a dysfunction of the digestive system that starts essentially attacking itself when - often in response to certain kinds of food.
And celiac disease would be another. And we think that - we're not quite sure, of course, what causes Crohn's disease. And we're not entirely 61 sure what causes the immune responses that lie behind celiac disease or irritable bowel syndrome. But the fact that these diseases are recent in origin, they're becoming more common, they're becoming more severe, particularly in developed countries, are all the hallmarks of mismatch diseases.
And there's enough evidence to suggest that the way in which we live today - and that can be anything from antibiotics 62 to our heavy reliance on cereals and grains - are promoting those diseases.
GROSS: How are they promoting them?
LIEBERMAN: Well, we don't know exactly. Allergies 63 are a fascinating example. I mean, the rate of allergies to gluten in wheat, or peanuts, or all kinds of proteins and substances that used to be very common and harmless raises a fascinating question, because there's no gene 13 sort of sweeping 64 through America causing peanut allergies. It's clearly an environmental cause.
And the immune system - if there's any system in the body that's very complex, it's the immune system. And we don't really know yet what it is that's causing our immune systems to react as they do in this abnormal fashion. But one hypothesis that's gaining a lot of traction 52 recently is the idea that somehow, we are knocking out our immune system or causing malfunctions 65 through a combination of overuse of antibiotics and also not using our immune systems in the ways for which they're evolved.
So this is often called the hygiene 66 hypothesis or the "old friends" hypothesis, that our immune systems evolved to be active. Just like our muscles and skeletons evolved to be used and stressed, our immune systems evolved to cope with all those germs in the outside world. And we've now created environments where - that are very sterile 67. They're extremely clean. We have very few pathogens that we have to deal with. And when we do get them, we nuke them with antibiotics.
But in so doing, we are now affecting how our immune system functions. It's still there, and it's primed and ready and waiting to attack all those nasty germs and worms that used to make us sick, but now those pathogens are absent. So it's - sometimes by chance, it finds the wrong targets.
And so that's a hypothesis for why so many allergies are on the rise and so many autoimmune diseases are on the rise, is that our immune systems are essentially not being used properly, and as a result, they go into overdrive. They attack ourselves through accident. And the result, of course, is very unfortunate. It's horrible.
GROSS: Daniel Lieberman will be back in the second half of the show. His new book is called "The Story of the Human Body: Evolution, Health and Disease." He's a professor of human evolutionary biology at Harvard. I'm Terry Gross, and this is FRESH AIR.
(BREAK)
GROSS: What would happen if we all read your book and thought, oh, mismatch diseases; we're eating the wrong foods and we're not doing what our bodies were designed to do, so let's go back to a Paleolithic diet?
LIEBERMAN: Ah, well, there are a bunch of people who are trying that experiment right now. It's...
GROSS: Oh, please don't recommend it.
(LAUGHTER)
LIEBERMAN: No, I'm not a...
GROSS: I really don't want to do that.
(LAUGHTER)
LIEBERMAN: I'm not a - I'm a bit of a skeptic 68 about the Paleo diet. One of the things that's interesting about the health movement today is that just as there is a lot of polarization in American in terms of politics and class, that's also happening with how we use our bodies. And it used to be that only rich people could afford to be unhealthy and overweight and inactive, and now it's, it's almost reversed and there are a lot of well-off, educated people who are now really interested in using their bodies better and they're exercising and they're running marathons and they're trying various kinds of diets.
And one of them that's become very popular recently, of course, is the Paleo diet. And I think that the Paleo diet has some germs of truth to it. It is true that an evolutionary perspective does help us understand that there are certain foods for which we're better adapted and there are other foods for which we're less adapted. But the Paleo diet also has a kind of simplistic approach to this question, almost creating a bunch of rules that don't necessarily make any sense from an evolutionary perspective. After all...
GROSS: So before you describe some of those rules, what's the diet?
LIEBERMAN: So, people who eat the Paleo tend to, they avoid all cereals and grains. They eat a lot of fat and meat because they have a, there's a notion that lots - our ancestors ate huge amounts of meat.
GROSS: And this is the pre-farming era, so there's no grains yet.
LIEBERMAN: That's right. Which is actually not true, because we know from various archaeological sites that hunter-gatherers, when they had grains available to them, did eat grains in probably very large quantities - although not, of course, as much as farmers.
They tend to avoid milk products because after all, we evolved to drink milk only when we're young and not to drink milk when we're older, after weaning. Many of them avoid legumes - things like peanuts, etcetera, which were not eaten by hunter-gatherers. At least so they think.
So it's a kind of diet by analogy. If hunter-gatherers ate it, it must be good; if we eat it - if it's more recent than hunter-gatherers, it must be bad. And you can, of course, quickly appreciate that some of that logic 69 is a little bit flawed because just because something is recent doesn't mean it's bad. And just because something is old doesn't mean it's good. And furthermore, hunter-gatherers didn't evolve necessarily to be healthy. They evolved to have lots of babies, and health was only selected for in so far as it helped people have more babies. That's after all, what natural selection's really about.
And hunter-gatherers, in fact, aren't always healthy. There's I think a kind of a little bit of romanticism applied 70 to hunter-gatherers. And there's also no one kind of hunter-gatherers. After all, our ancestors who are hunter-gatherers lived in environments as diverse as the African savanna 71 to in rainforests and in the Arctic and everywhere else, they managed to eke 72 out a living in all kinds of different habitats. And there was no one Paleo diet, there were many Paleo diets. And so it's a complex problem.
GROSS: And probably they didn't live to celebrate their 80th birthdays very often.
LIEBERMAN: Well, you know, actually you'd be surprised.
GROSS: Really?
LIEBERMAN: So hunter-gatherers have very high infant mortality rates. You know, it varies from population to population and the data aren't great, but maybe between 30 and 50 percent rates of infant mortality. But once they survived childhood, they actually tended to live reasonably long and healthy lives. And it was - actually the origins of farming that caused health to really decline in that respect. So farmers also have high infant mortality rates. But farmers also have high mortality rates in general and people started dying younger and becoming shorter. So farming really was initially 73 a very bad thing for the human body in terms of longevity 74 and nutrition and health. Of course, it was great for increasing the number of offspring people were able to have.
But to return to the Paleo diet, the thing about the Paleo diet is that there was also some truth to what some of the Paleo diet proposes. I mean, it is true that much of what we eat and do in our modern life we're poorly adapted for and the Paleo diet does go some of the way toward correcting that, but I'm not sure I agree with everything they say.
GROSS: Well, because it's going too far?
LIEBERMAN: In some respects. For example, there's a big debate going on about fats and what kinds of fats are healthy, and we've been hearing for years now that saturated 75 fats are evil and unsaturated fats are healthy. But some hunter-gatherers eat a lot of saturated fats. And so some Paleolithic diet proponents 76 believe that you should just have as much saturated fat as you want. And there are various arguments for and against that but that's an experiment that I, for example, am not willing to undergo, is to eat as much saturated fat as I'd like. There are still scientific arguments about what ratios of fats are the best and what's the right fat. And in fact, I think even asking what's the best is often problematic because again, what's the output parameter 77 you're interested in? You know, are you interested in living longest or being more vigorous or having more offspring? Remember that what natural selection cared about the most was how many offspring you had who then survived to then have offspring themselves. So just because hunter-gatherers may eat certain diets doesn't mean that they're going to - that that's the same kind of diet that's going to promote health in a modern context.
GROSS: You've said that no organism is primarily adapted to be healthy or to live long or to be happy or to achieve any other goals, except for the goal of reproducing. That evolution is all about evolving to the point where you can more effectively reproduce. I suppose in some ways that's a pretty obvious notion. But when you think about it, it's a really, really rich idea. And so just like, work off of that for us a little bit. What are the implications of that in terms of how we live our lives?
LIEBERMAN: Well, I think we have this idea that if we evolve to do something, it must be good for us. But, you know, we live in a world in which what we think is good for us, or what we value, may not be the same currency that evolution and natural selection values. And that's why I think we need to be thoughtful about how we apply evolution to our lives today.
GROSS: Well...
LIEBERMAN: I'll give you an interesting example...
GROSS: Sure. Yeah.
LIEBERMAN: ...from the public health literature. So often there are very well-meaning and well-intentioned efforts to try to alleviate 78 poor health that's caused by malnutrition 79 and undernutrition, people not having enough food. And a very famous example was in the Gambia. I think it was in the 1950s, I believe, when, you know, lots of women were giving birth to underweight babies and small - you know, babies who are very small when they're born have a much greater chance of a wide range of health problems as they mature, because they're, essentially their mothers haven't had enough energy to help the body grow properly in utero and so that sets up a body that's much more likely to succumb 80 to many diseases as it grows. So these mothers were - for the best of intentions - given nutritional 81 supplements.
What happened was that instead of giving birth to larger weight babies, what happened was that these mothers essentially started to more often just give birth to underweight babies but more often. They just shortened what we call their interbirth interval 82. So again, it goes to the point that they're doing exactly what their bodies evolved to do, which is that if you're in a energy-poor environment, what really matters is how many, you know, what really matters from an evolutionary perspective is reproduction. And so they're doing the evolutionarily rational thing to do. I mean they're not making decisions obviously; this is their bodies responding - which is to use that extra energy to improve their reproductive success. So it failed - the program failed because it didn't consider that evolutionary principle.
(BREAK)
GROSS: You know, if our bodies are primarily designed as reproduction machines, you know, the things that evolve so we could better reproduce, well, now we're living in an age where so many people use birth control and limit the number of children they have intentionally 83 or have no children at all, intentionally or unintentionally. It seems like we're really mismatched in terms of evolutionary development with the lives that we're leading.
LIEBERMAN: Yeah. Yeah. And, of course, an important example of that is breast cancer. So it's, you know, breast cancer was originally known as the nun's disease because it was very rare until recently and it was a, you know, medieval doctors noticed that it was more prevalent - or Renaissance 84 doctors noticed it was more prevalent in nuns 85 who didn't have offspring. And contraception has many benefits, of course. But everything has costs, right? There is no such thing as a pure benefit without a cost in your body. All things have trade-offs. Every time you do one thing, you don't do something else. And so contraception has enabled, you know, brought much good for women, giving them control over reproduction, but it does raise the risk of breast cancer because it means that women have more reproductive cycles where they're producing high amounts of estrogen and progesterone, hormones that are very important in that cycle, and those hormones are important for reproduction, but they also elevate the risk of breast cancer, because they are mitogens. They cause cells to reproduce, they cause cells to divide and proliferate 86, and the more cells that divide and proliferate, the more chances there are for mutations to arise that can turn into cancer. So that's another, that's a perfect example of a trade-off between reproductive strategies and the way we use our bodies today.
GROSS: Speaking of cancer, you describe cancer in a way as evolution gone wrong.
LIEBERMAN: It really is, because cancer is a kind of natural - it's almost a kind of selection that occurs in your body, because cancer cells are cells that have acquired a series of mutations, usually it's more than one mutation 87, that enable them to essentially outcompete other cells. So it's a kind of selection within the body and cancer cells essentially start taking over the cells and other organs, taking their nutrients 88, which is what causes us to die from cancers. And so in a sense we wouldn't have evolved cancer if we hadn't evolved multicellular life and if natural selection didn't occur.
GROSS: You write a little bit about exercise. Some people love to exercise, some people hate it. But one way or another it's important. And it relates to the fact with muscles it's a kind of use-it-or-lose-it condition, which is again an evolutionary issue. Would you explain that?
LIEBERMAN: Well, many systems of our bodies evolved to require some form of stress. And I don't mean stress in a bad way, like something that makes your cortisol levels go up. But stress in a good way; they evolve to have some, require some circumstances, some stimuli 89 in which capacity might not match demand. And our bodies respond to those stresses. So when you lift something very heavy, you know, your muscles get tired but that soreness in your muscle actually is partly related to the response of your muscle. That makes your muscle stronger. And so our bones, our muscles, our brains, many aspects of our body require stimuli to grow and develop properly. And some aspects of our body even require those stimuli to maintain those tissues because, for example, muscle is very expensive. If you're not using it, you want to get rid of it, because it's costly 90 just to maintain.
GROSS: By costly you mean it takes a lot of energy, a lot of...
LIEBERMAN: Calories.
GROSS: Calories. Right.
LIEBERMAN: Yeah.
GROSS: And in a calorie-poor environment, that's expensive.
LIEBERMAN: Yeah. About 40 percent of a typical person's body is spent just paying for your muscles, just to keep those muscles functioning. So if you're not using them and you're energy poor and you want to spend as much energy on reproduction, as opposed to sitting around, you're better off not having those extra muscles, which is why our muscles waste away when we don't use them.
The problem is that we live in a world for which we've kind of taken that to an extreme, right? So I think osteoporosis is really for me the most extreme example or the most, one of the most profound examples, which is that our skeletal system is designed to grow under conditions of stress. It never, we never evolved to hang around all day long and get rides to school and not exercise very much, and as a result, many people today are developing skeletons that just don't have that much mass, that's just, there's not that much bone. But our skeletons also evolve to lose mass as we age and that mass loss, that loss is exacerbated 91 by lack of exercise. So when astronauts, for example, go to space in microgravity environments, they lose bone at a really rapid rate.
And so what happens is that we tend to grow skeletons that don't have enough mass in the first place and then as we age, we accelerate that bone loss process. And the result is that more than 30 percent of women today have osteoporosis, and those rates are also climbing.
And that's preventable. It's preventable by having more physical activity when we're young and it's preventable by having more physical activity as we age to slow that rate of bone loss that inevitably 92 occurs. So yes, we do need to use our bodies in order to maintain health, and that use-it-or-lose-it phenomenon really has an evolutionary origin.
GROSS: You write that we often confuse comfort with well-being 93. Explain what you mean.
LIEBERMAN: Yeah. Well, we all love comfort. Comfort is, well, comfort. Right? I'm right now, for example, sitting in a very lovely, comfortable chair that's cushioned and it's just at the right height and angle. And we like that, right? And we like comfortable shoes and we like comfortable beds. But just because something is comfortable, it doesn't mean it's good for us.
And in fact, many things that are comfortable we actually know are bad for us. I mean there's increasing awareness 94 that chairs, for example, cause a host of problems if overused. For example, when I'm sitting in this chair now, I'm not using my back muscles to hold my upper body up, and that means that my back is not as strong as it could or should be.
My hips 95 are flexed 96 and, you know, just as you, you know, people who wear high-heeled shoes end up getting shorter calves 97 and Achilles tendons, that's causing my hip 9 flexors to be short and that can result in poor posture 98. So there are many costs to comfort that we don't perceive because those costs tend to be very small and incremental 99, in tiny doses, and they add up over decades. And we're unaware of those costs until it's too late.
GROSS: Have we stopped evolving?
LIEBERMAN: Definitely not. Evolution is just always churning along. Evolution, after all, is just change over time. And natural selection, which is the kind of evolution we tend to be thinking about the most, is caused by just a few phenomena 100 that are always there. So if you have variation, you know, if you go in a room of 10 people, they'll all look a little bit different. And if some of that variation is genetic, has a genetic basis, then - and if some of those individuals have more offspring than others, which of course is going to be the case, then those individuals who have genetic variations that are more likely to help them have more offspring or more likely to help them have fewer offspring or prevent them from having as many offspring, that will change the frequency of those genes from one population to the next.
So whether we like it or not, evolution is going on, but it's going on at a very slow pace. And really what's a more dominant 101 form of evolution today is cultural evolution. It's how we learn and use our bodies and interact with each other based on learned information. And that's also a kind of evolution. It's not Darwinian evolution. It's not biological evolution, but it affects our bodies. So we're evolving. We're evolving slowly through natural selection and rapidly through cultural evolution.
Lieberman is the author of the new book "The Story of the Human Body: Evolution, Health and Disease." He admits that if you're sick, you would not go to an evolutionary biologist to get treated. However, evolutionary biology can help you understand why you got sick, and it can help you be more aware of healthy and harmful behaviors. Lieberman is a professor of evolutionary biology at Harvard University.
Daniel Lieberman, welcome to FRESH AIR. I want you to explain the basic premise 8 of the book, about mismatch diseases.
DANIEL LIEBERMAN: Well, many people wonder how their bodies function today, and what's the relationship between how our bodies evolved and how we use them and how we get sick. And a key premise of the book is that many of the illnesses that we confront today are what evolutionary biologists call mismatch diseases. I didn't come up with the term. It's been around for a while.
But mismatch diseases are diseases that occur because our bodies are poorly or inadequately 10 adapted to environments in which we now live. So an example would be eating large amounts of sugar or being very physically 11 inactive leads to problems like diabetes or heart disease that then make us sick.
So mismatch diseases are really diseases that are modern, in the sense that they're more prevalent or even novel, or more severe because we don't live in the way in which our bodies are adapted.
GROSS: OK, let's look at diabetes 2, type 2 diabetes, which is, you know, in epidemic 12 proportions in the United States and now much of the world. So this is a good example of a mismatch disease. Why are bodies ill-equipped for the kind of foods and fats and sugars and the quantity of food that we're eating now?
LIEBERMAN: Yeah, well, this is an important topic, obviously. You know, in India and China, for example, rates of diabetes are going up by almost an order of magnitude over the last generation, and they're going up very rapidly in the U.S., too. And the reason we're - they're mismatch diseases is that diabetes, for example, is caused by, essentially 14, the body being unable to cope with sugar in the bloodstream.
So we evolved to crave 15 sugar, because sugar is an energy-rich food, but we didn't evolve to digest large amounts of it rapidly.
GROSS: So our bodies, the basic operating system of our bodies was designed for the hunter-gatherer era, right?
LIEBERMAN: To a large extent. I mean, until hunter-gatherers, and even before hunter-gatherers, chimpanzees, for example, eat plenty of foods that have carbohydrates 16. For example, chimpanzees eat almost all fruit. Right. You think, oh, if they eat all fruit, they must be getting a lot of sugar. But the sugar that they get is very different from the sugar that we get.
First of all, it's bound in cells. You have to digest it, and there's lots of fiber 17 in and around the sugar. So you don't get access to that sugar really fast. And there's much less sugar in those sorts of foods. So we evolved to crave sweet foods. Everybody loves sweet foods. But if you try to eat foods that hunter-gatherers eat or chimpanzees eat, you'll be surprised at how un-sweet they are. Most wild fruits are about as sweet as a carrot.
So we love sweetness, but until recently, pretty much the only food that we got that was very sweet was honey, and honey, of course, was a special treat. That was pretty much the only form of dessert in the Paleolithic. But now we have access to abundant quantities of sugar and to simple carbohydrates, which we evolved to love because they're full of energy, but we don't have the metabolism 18, we don't have the bodies that are able to cope with those kinds of levels of sugar. And the result is that we get sick.
So, type 2 diabetes used to be exceedingly rare. I mean, it did happen occasionally, but it was an extraordinarily 19 rare disease. And to my knowledge, there's not a single case of any hunter-gatherer ever diagnosed with the disease. And it was rare for our great-grandparents. But today, it's become very common because of the foods we eat for which we're not adapted. So, in that sense, it's a very classic mismatch disease.
GROSS: So, like our ancestors a zillion years ago, they didn't have sweets like we have sweets. The body needed - the body needs sugar, and it was designed to process sugar from foods like fruits, not designed to process sugar from foods like apple pie with icing on it or cinnamon rolls and stuff like that that are just, like, loaded with fat and sugar. Do I have that right?
LIEBERMAN: And all that good stuff. Yeah, exactly. So, sugar is good, right. Energy is good. Think about what natural selection's really all about.
GROSS: Right. Mr. Hunter-Gatherer needed that energy.
LIEBERMAN: Right. Well, the more energy you have, the more successful you'll be. Most hunter-gatherers, most animals live on the margin 20 of energy balance, right? They have just enough energy to do what they need to do, and any more energy is a good thing, right. It means that you can put more of that energy into growing a better body, or put more of that energy into reproducing and put some of that energy into coping with periods when food is scarce.
And one of the interesting things about humans is that we are specially 21 tuned 22 to energy, compared to other animals. We're actually a very fat species, compared to other primates 24 and most other mammals. The average primate 23, a chimpanzee or a monkey, has maybe about 5 or 6 percent body fat, whereas a thin human being, a very - you know, a supermodel has more, much more body fat than that.
You know, it's normal to have about 10 to 20 percent body fat for a normal, average, healthy human being. So we're already a very fatty species, in a way, and that's because we have a very - we evolved a very energy-intensive way of reproducing. And that part of our story is incredibly important to know, because we pulled off kind of a hat trick in the Paleolithic, right.
We figured out how to grow big bodies with really big brains. And brains are very expensive, and they always need lots of sugar all the time. And we also figured out a way to have babies about twice as fast as our ape ancestors. So a typical chimpanzee has a baby every three years, and she waits until that baby is pretty much fully 25 grown and able to feed on its own before it has another baby.
But humans are able to have - in the - you know, today, of course, we can have babies every year or so. But hunter-gatherers managed to have babies every three years, and that's well before a baby is able to eat on its own, forage 26 on its own. So mothers have to have lots of energy to grow babies in the womb. They have to have lots of energy to breastfeed them, and that costs a lot of energy to synthesize, to make breast milk. And they also have to have extra energy to feed those toddlers and young kids around who can't fully feed themselves.
That reproductive strategy that we evolved at some point during the Ice Age requires enormous quantities of energy, and it requires energy reserves. We have to be able to store it in our bodies. We have to have access to a lot of it, and so we're like gas guzzlers of the primate world.
GROSS: You know, in your book, "The Story of the Human Body," about evolutionary medicine, you write about how when farming evolved, then industrialization, the nature of what we were eating changed, and the nature of how we spent our time changed, too. You know, with farming, we started to eat more grains, more carbohydrates, and you write about how that can be very taxing on the body.
How come our bodies haven't evolved more effectively to deal with more modern life, to deal with the kind of foods we actually do eat now?
LIEBERMAN: That's a wonderful question. Well, to some extent, we have. But some populations have done it a little bit better than others. So going back to type 2 diabetes, for example, there are genes 27 that protect some people more than others from the disease. These are genes that probably evolved fairly recently that give some populations - it tends to be Europeans - better ability to cope with high-glycemic foods, and that means foods that cause more sugar in your bloodstream.
But some populations, for various reasons, probably chance, never evolved as many of those adaptations. So they tend to be more prone 28 to developing diabetes and obesity 29 from the same kinds of diets. So India and China are examples of countries where these epidemics 30 seem to be growing faster because of a lack of selection that somehow occurred, or just the genetic 31 variation that made it possible for evolution to give some protection.
So we did actually evolve, to some extent, to cope with some of these changes in our diet. Another factor is that a lot of these diseases don't occur until after people have reproduced. So most people who get diabetes, for example - I know we're harping 32 on this disease - but most people who get many of these diseases, heart disease, diabetes, hypertension, often get them after they've had their kids and after their kids are grown up.
And so the ill effects of these diseases don't have a very strong selective effect. So natural selection is not going to really operate that strongly.
GROSS: Oh. I see what you're saying. Because you've already reproduced, so any adaptation that you make as a result of the disease, it's too late to have an effect on reproduction.
LIEBERMAN: That's right. And, you know, it can have some effect. So we know, for example, that there's a strong selective benefit to being a good grandparent. Grandparents who do well - particularly among hunter-gatherers - their offspring do better. But with the origins of farming and industrialization, that role of grandparents in terms of providing food has declined in importance, and so those grandparenting-selective effects have probably also declined, as well.
(BREAK)
GROSS: Let me ask you about comfort food. Many of us, when we're stressed out, we crave carbohydrates or sweets, and you say there's actually an evolutionary reason for that.
LIEBERMAN: Yeah. So, the hormone 33 that gets elicited 35 when you get stressed is cortisol. That's the chief one. So when - if you jump out an airplane, or if something really bad happens, a loved one dies, our body goes into a flight-or-fright state. We're ready for danger. And cortisol plays an important role, because it releases sugar into the bloodstream. So you can run from that lion or deal with whatever that bad situation is. It makes you more alert.
But it also - cortisol also makes us want to bring in more energy to cope again with that - those energetic needs. So stress activates 37 basic primal 38 urges to eat calorie-rich food, which is, of course, useful to cope with those kinds of situations from an evolutionary perspective.
So people who have lives that contribute to higher basal levels of cortisol are more likely to suffer the ill consequences of that stress.
GROSS: So when we're stressed, we secrete 39 more cortisol, which gets us to crave fats and sweets. Another part of the problem here is that just because we're stressed doesn't mean that we're actually running from a beast that's chasing us. We're probably sitting in a chair or standing 40. So how does that affect how our bodies respond to both the cortisol, and also to the sweets and carbs that we're eating?
LIEBERMAN: Well, stress creates this sort of vicious cycle, this positive feedback loop, because when you're stressed, you crave unhealthy foods. But when you're stressed, you also have a harder time sleeping. And when you have a harder time sleeping, that elevates your levels of stress. It just sets off this chain reaction that keeps going on and on.
Now, normally when we're stressed, that's - the stimulus 41 that causes the stress should be a short-lived one. That's what evolution predicted, right. A lion chases you, that's a very stressful event, obviously. Hopefully you manage to run away from the lion. You climb into a tree. You calm down. You tell everybody the story. Life goes on.
But much of the stress that we create today results from social conditions. If you think about, you know, the most stressful things that we experience, they're often our lives. They're our jobs, our commutes 42, having - not having enough money, the list goes on. And those, of course, elicit 34 chronic 43 levels of stress.
And when stress becomes chronic, then it helps feed a variety of mismatch diseases that make us ill, that make us depressed 44, that make us anxious, that make us overweight, which then cause more stress, which then keep the cycle going.
GROSS: What are some of those mismatch diseases that arise from the stress response?
LIEBERMAN: Oh, gosh. Many of them are metabolic 45 diseases. So anything that has to do with high blood pressure, so hypertension, strokes. Stress certainly has effects on cardiovascular disease. Stress has effects on many mental health diseases and illnesses. In fact, the list is so long, I'm not sure it would be a good idea to list them all.
GROSS: Oh, OK. But - well, let's get to digestion 46, since we're talking about food and stress. You describe the gut 47 as a second brain, having more nerve endings than our spinal 48 cord or our peripheral 49 nervous system. What are all those nerve endings doing in our gut?
LIEBERMAN: Oh, gosh. Well, they're helping 50 move food around. They're - they help with just basic process of digestion, your - for example, when you eat a meal, you have to push all those - all that food through your digestive system, all the way out to the outside world. And so you have all these contractions 51 that your body is completely unaware 53 of that are squeezing the food along.
There are other nerve responses that sense what kind of enzymes 54 need to be added to the system. It's - digestion is a very complex phenomenon that has to be regulated, hence has a lot of neural 55 control.
GROSS: Why does our gut know when we're nervous?
LIEBERMAN: That's a good question. I don't actually know the answer to that. Certainly - well, I know partly the answer to that. Certainly, much of our digestive system is regulated by what's called the autonomic nervous system. It's the involuntary nervous system that you have. And the involuntary nervous system, of course, is heavily regulated by hormones 56. And among the chief hormones that regulate that system is cortisol.
So, when we get stressed, or when we get excited, hormones then affect pretty much every aspect of our body, including our digestive system. So sometimes we want to activate 36 energy. Sometimes we want to store it away for future use. So, you know, one of the things that one learns when studying and teaching human biology and physiology 57 is just how interconnected every system of the body is with other systems of the body.
It's - you can't change one thing without changing many things. And the hormonal 58 system is - its job, actually, is to help make all those systems work together.
GROSS: So while we're talking about digestion, you write about how irritable bowel disease and Crohn's disease, which lead to all kinds of intestinal 59 distress 60, are mismatch diseases. So put that into context for us.
LIEBERMAN: Well, many of the mismatch diseases that we think are going on - or actually, they're hypothesized, because we don't totally understand their origin. But Crohn's disease, for example, is a recent disease. It used to be extraordinarily rare, and today it's cropping up more and more as - and it's an autoimmune disease. It's a dysfunction of the digestive system that starts essentially attacking itself when - often in response to certain kinds of food.
And celiac disease would be another. And we think that - we're not quite sure, of course, what causes Crohn's disease. And we're not entirely 61 sure what causes the immune responses that lie behind celiac disease or irritable bowel syndrome. But the fact that these diseases are recent in origin, they're becoming more common, they're becoming more severe, particularly in developed countries, are all the hallmarks of mismatch diseases.
And there's enough evidence to suggest that the way in which we live today - and that can be anything from antibiotics 62 to our heavy reliance on cereals and grains - are promoting those diseases.
GROSS: How are they promoting them?
LIEBERMAN: Well, we don't know exactly. Allergies 63 are a fascinating example. I mean, the rate of allergies to gluten in wheat, or peanuts, or all kinds of proteins and substances that used to be very common and harmless raises a fascinating question, because there's no gene 13 sort of sweeping 64 through America causing peanut allergies. It's clearly an environmental cause.
And the immune system - if there's any system in the body that's very complex, it's the immune system. And we don't really know yet what it is that's causing our immune systems to react as they do in this abnormal fashion. But one hypothesis that's gaining a lot of traction 52 recently is the idea that somehow, we are knocking out our immune system or causing malfunctions 65 through a combination of overuse of antibiotics and also not using our immune systems in the ways for which they're evolved.
So this is often called the hygiene 66 hypothesis or the "old friends" hypothesis, that our immune systems evolved to be active. Just like our muscles and skeletons evolved to be used and stressed, our immune systems evolved to cope with all those germs in the outside world. And we've now created environments where - that are very sterile 67. They're extremely clean. We have very few pathogens that we have to deal with. And when we do get them, we nuke them with antibiotics.
But in so doing, we are now affecting how our immune system functions. It's still there, and it's primed and ready and waiting to attack all those nasty germs and worms that used to make us sick, but now those pathogens are absent. So it's - sometimes by chance, it finds the wrong targets.
And so that's a hypothesis for why so many allergies are on the rise and so many autoimmune diseases are on the rise, is that our immune systems are essentially not being used properly, and as a result, they go into overdrive. They attack ourselves through accident. And the result, of course, is very unfortunate. It's horrible.
GROSS: Daniel Lieberman will be back in the second half of the show. His new book is called "The Story of the Human Body: Evolution, Health and Disease." He's a professor of human evolutionary biology at Harvard. I'm Terry Gross, and this is FRESH AIR.
(BREAK)
GROSS: What would happen if we all read your book and thought, oh, mismatch diseases; we're eating the wrong foods and we're not doing what our bodies were designed to do, so let's go back to a Paleolithic diet?
LIEBERMAN: Ah, well, there are a bunch of people who are trying that experiment right now. It's...
GROSS: Oh, please don't recommend it.
(LAUGHTER)
LIEBERMAN: No, I'm not a...
GROSS: I really don't want to do that.
(LAUGHTER)
LIEBERMAN: I'm not a - I'm a bit of a skeptic 68 about the Paleo diet. One of the things that's interesting about the health movement today is that just as there is a lot of polarization in American in terms of politics and class, that's also happening with how we use our bodies. And it used to be that only rich people could afford to be unhealthy and overweight and inactive, and now it's, it's almost reversed and there are a lot of well-off, educated people who are now really interested in using their bodies better and they're exercising and they're running marathons and they're trying various kinds of diets.
And one of them that's become very popular recently, of course, is the Paleo diet. And I think that the Paleo diet has some germs of truth to it. It is true that an evolutionary perspective does help us understand that there are certain foods for which we're better adapted and there are other foods for which we're less adapted. But the Paleo diet also has a kind of simplistic approach to this question, almost creating a bunch of rules that don't necessarily make any sense from an evolutionary perspective. After all...
GROSS: So before you describe some of those rules, what's the diet?
LIEBERMAN: So, people who eat the Paleo tend to, they avoid all cereals and grains. They eat a lot of fat and meat because they have a, there's a notion that lots - our ancestors ate huge amounts of meat.
GROSS: And this is the pre-farming era, so there's no grains yet.
LIEBERMAN: That's right. Which is actually not true, because we know from various archaeological sites that hunter-gatherers, when they had grains available to them, did eat grains in probably very large quantities - although not, of course, as much as farmers.
They tend to avoid milk products because after all, we evolved to drink milk only when we're young and not to drink milk when we're older, after weaning. Many of them avoid legumes - things like peanuts, etcetera, which were not eaten by hunter-gatherers. At least so they think.
So it's a kind of diet by analogy. If hunter-gatherers ate it, it must be good; if we eat it - if it's more recent than hunter-gatherers, it must be bad. And you can, of course, quickly appreciate that some of that logic 69 is a little bit flawed because just because something is recent doesn't mean it's bad. And just because something is old doesn't mean it's good. And furthermore, hunter-gatherers didn't evolve necessarily to be healthy. They evolved to have lots of babies, and health was only selected for in so far as it helped people have more babies. That's after all, what natural selection's really about.
And hunter-gatherers, in fact, aren't always healthy. There's I think a kind of a little bit of romanticism applied 70 to hunter-gatherers. And there's also no one kind of hunter-gatherers. After all, our ancestors who are hunter-gatherers lived in environments as diverse as the African savanna 71 to in rainforests and in the Arctic and everywhere else, they managed to eke 72 out a living in all kinds of different habitats. And there was no one Paleo diet, there were many Paleo diets. And so it's a complex problem.
GROSS: And probably they didn't live to celebrate their 80th birthdays very often.
LIEBERMAN: Well, you know, actually you'd be surprised.
GROSS: Really?
LIEBERMAN: So hunter-gatherers have very high infant mortality rates. You know, it varies from population to population and the data aren't great, but maybe between 30 and 50 percent rates of infant mortality. But once they survived childhood, they actually tended to live reasonably long and healthy lives. And it was - actually the origins of farming that caused health to really decline in that respect. So farmers also have high infant mortality rates. But farmers also have high mortality rates in general and people started dying younger and becoming shorter. So farming really was initially 73 a very bad thing for the human body in terms of longevity 74 and nutrition and health. Of course, it was great for increasing the number of offspring people were able to have.
But to return to the Paleo diet, the thing about the Paleo diet is that there was also some truth to what some of the Paleo diet proposes. I mean, it is true that much of what we eat and do in our modern life we're poorly adapted for and the Paleo diet does go some of the way toward correcting that, but I'm not sure I agree with everything they say.
GROSS: Well, because it's going too far?
LIEBERMAN: In some respects. For example, there's a big debate going on about fats and what kinds of fats are healthy, and we've been hearing for years now that saturated 75 fats are evil and unsaturated fats are healthy. But some hunter-gatherers eat a lot of saturated fats. And so some Paleolithic diet proponents 76 believe that you should just have as much saturated fat as you want. And there are various arguments for and against that but that's an experiment that I, for example, am not willing to undergo, is to eat as much saturated fat as I'd like. There are still scientific arguments about what ratios of fats are the best and what's the right fat. And in fact, I think even asking what's the best is often problematic because again, what's the output parameter 77 you're interested in? You know, are you interested in living longest or being more vigorous or having more offspring? Remember that what natural selection cared about the most was how many offspring you had who then survived to then have offspring themselves. So just because hunter-gatherers may eat certain diets doesn't mean that they're going to - that that's the same kind of diet that's going to promote health in a modern context.
GROSS: You've said that no organism is primarily adapted to be healthy or to live long or to be happy or to achieve any other goals, except for the goal of reproducing. That evolution is all about evolving to the point where you can more effectively reproduce. I suppose in some ways that's a pretty obvious notion. But when you think about it, it's a really, really rich idea. And so just like, work off of that for us a little bit. What are the implications of that in terms of how we live our lives?
LIEBERMAN: Well, I think we have this idea that if we evolve to do something, it must be good for us. But, you know, we live in a world in which what we think is good for us, or what we value, may not be the same currency that evolution and natural selection values. And that's why I think we need to be thoughtful about how we apply evolution to our lives today.
GROSS: Well...
LIEBERMAN: I'll give you an interesting example...
GROSS: Sure. Yeah.
LIEBERMAN: ...from the public health literature. So often there are very well-meaning and well-intentioned efforts to try to alleviate 78 poor health that's caused by malnutrition 79 and undernutrition, people not having enough food. And a very famous example was in the Gambia. I think it was in the 1950s, I believe, when, you know, lots of women were giving birth to underweight babies and small - you know, babies who are very small when they're born have a much greater chance of a wide range of health problems as they mature, because they're, essentially their mothers haven't had enough energy to help the body grow properly in utero and so that sets up a body that's much more likely to succumb 80 to many diseases as it grows. So these mothers were - for the best of intentions - given nutritional 81 supplements.
What happened was that instead of giving birth to larger weight babies, what happened was that these mothers essentially started to more often just give birth to underweight babies but more often. They just shortened what we call their interbirth interval 82. So again, it goes to the point that they're doing exactly what their bodies evolved to do, which is that if you're in a energy-poor environment, what really matters is how many, you know, what really matters from an evolutionary perspective is reproduction. And so they're doing the evolutionarily rational thing to do. I mean they're not making decisions obviously; this is their bodies responding - which is to use that extra energy to improve their reproductive success. So it failed - the program failed because it didn't consider that evolutionary principle.
(BREAK)
GROSS: You know, if our bodies are primarily designed as reproduction machines, you know, the things that evolve so we could better reproduce, well, now we're living in an age where so many people use birth control and limit the number of children they have intentionally 83 or have no children at all, intentionally or unintentionally. It seems like we're really mismatched in terms of evolutionary development with the lives that we're leading.
LIEBERMAN: Yeah. Yeah. And, of course, an important example of that is breast cancer. So it's, you know, breast cancer was originally known as the nun's disease because it was very rare until recently and it was a, you know, medieval doctors noticed that it was more prevalent - or Renaissance 84 doctors noticed it was more prevalent in nuns 85 who didn't have offspring. And contraception has many benefits, of course. But everything has costs, right? There is no such thing as a pure benefit without a cost in your body. All things have trade-offs. Every time you do one thing, you don't do something else. And so contraception has enabled, you know, brought much good for women, giving them control over reproduction, but it does raise the risk of breast cancer because it means that women have more reproductive cycles where they're producing high amounts of estrogen and progesterone, hormones that are very important in that cycle, and those hormones are important for reproduction, but they also elevate the risk of breast cancer, because they are mitogens. They cause cells to reproduce, they cause cells to divide and proliferate 86, and the more cells that divide and proliferate, the more chances there are for mutations to arise that can turn into cancer. So that's another, that's a perfect example of a trade-off between reproductive strategies and the way we use our bodies today.
GROSS: Speaking of cancer, you describe cancer in a way as evolution gone wrong.
LIEBERMAN: It really is, because cancer is a kind of natural - it's almost a kind of selection that occurs in your body, because cancer cells are cells that have acquired a series of mutations, usually it's more than one mutation 87, that enable them to essentially outcompete other cells. So it's a kind of selection within the body and cancer cells essentially start taking over the cells and other organs, taking their nutrients 88, which is what causes us to die from cancers. And so in a sense we wouldn't have evolved cancer if we hadn't evolved multicellular life and if natural selection didn't occur.
GROSS: You write a little bit about exercise. Some people love to exercise, some people hate it. But one way or another it's important. And it relates to the fact with muscles it's a kind of use-it-or-lose-it condition, which is again an evolutionary issue. Would you explain that?
LIEBERMAN: Well, many systems of our bodies evolved to require some form of stress. And I don't mean stress in a bad way, like something that makes your cortisol levels go up. But stress in a good way; they evolve to have some, require some circumstances, some stimuli 89 in which capacity might not match demand. And our bodies respond to those stresses. So when you lift something very heavy, you know, your muscles get tired but that soreness in your muscle actually is partly related to the response of your muscle. That makes your muscle stronger. And so our bones, our muscles, our brains, many aspects of our body require stimuli to grow and develop properly. And some aspects of our body even require those stimuli to maintain those tissues because, for example, muscle is very expensive. If you're not using it, you want to get rid of it, because it's costly 90 just to maintain.
GROSS: By costly you mean it takes a lot of energy, a lot of...
LIEBERMAN: Calories.
GROSS: Calories. Right.
LIEBERMAN: Yeah.
GROSS: And in a calorie-poor environment, that's expensive.
LIEBERMAN: Yeah. About 40 percent of a typical person's body is spent just paying for your muscles, just to keep those muscles functioning. So if you're not using them and you're energy poor and you want to spend as much energy on reproduction, as opposed to sitting around, you're better off not having those extra muscles, which is why our muscles waste away when we don't use them.
The problem is that we live in a world for which we've kind of taken that to an extreme, right? So I think osteoporosis is really for me the most extreme example or the most, one of the most profound examples, which is that our skeletal system is designed to grow under conditions of stress. It never, we never evolved to hang around all day long and get rides to school and not exercise very much, and as a result, many people today are developing skeletons that just don't have that much mass, that's just, there's not that much bone. But our skeletons also evolve to lose mass as we age and that mass loss, that loss is exacerbated 91 by lack of exercise. So when astronauts, for example, go to space in microgravity environments, they lose bone at a really rapid rate.
And so what happens is that we tend to grow skeletons that don't have enough mass in the first place and then as we age, we accelerate that bone loss process. And the result is that more than 30 percent of women today have osteoporosis, and those rates are also climbing.
And that's preventable. It's preventable by having more physical activity when we're young and it's preventable by having more physical activity as we age to slow that rate of bone loss that inevitably 92 occurs. So yes, we do need to use our bodies in order to maintain health, and that use-it-or-lose-it phenomenon really has an evolutionary origin.
GROSS: You write that we often confuse comfort with well-being 93. Explain what you mean.
LIEBERMAN: Yeah. Well, we all love comfort. Comfort is, well, comfort. Right? I'm right now, for example, sitting in a very lovely, comfortable chair that's cushioned and it's just at the right height and angle. And we like that, right? And we like comfortable shoes and we like comfortable beds. But just because something is comfortable, it doesn't mean it's good for us.
And in fact, many things that are comfortable we actually know are bad for us. I mean there's increasing awareness 94 that chairs, for example, cause a host of problems if overused. For example, when I'm sitting in this chair now, I'm not using my back muscles to hold my upper body up, and that means that my back is not as strong as it could or should be.
My hips 95 are flexed 96 and, you know, just as you, you know, people who wear high-heeled shoes end up getting shorter calves 97 and Achilles tendons, that's causing my hip 9 flexors to be short and that can result in poor posture 98. So there are many costs to comfort that we don't perceive because those costs tend to be very small and incremental 99, in tiny doses, and they add up over decades. And we're unaware of those costs until it's too late.
GROSS: Have we stopped evolving?
LIEBERMAN: Definitely not. Evolution is just always churning along. Evolution, after all, is just change over time. And natural selection, which is the kind of evolution we tend to be thinking about the most, is caused by just a few phenomena 100 that are always there. So if you have variation, you know, if you go in a room of 10 people, they'll all look a little bit different. And if some of that variation is genetic, has a genetic basis, then - and if some of those individuals have more offspring than others, which of course is going to be the case, then those individuals who have genetic variations that are more likely to help them have more offspring or more likely to help them have fewer offspring or prevent them from having as many offspring, that will change the frequency of those genes from one population to the next.
So whether we like it or not, evolution is going on, but it's going on at a very slow pace. And really what's a more dominant 101 form of evolution today is cultural evolution. It's how we learn and use our bodies and interact with each other based on learned information. And that's also a kind of evolution. It's not Darwinian evolution. It's not biological evolution, but it affects our bodies. So we're evolving. We're evolving slowly through natural selection and rapidly through cultural evolution.
n.气喘病,哮喘病
- I think he's having an asthma attack.我想他现在是哮喘病发作了。
- Its presence in allergic asthma is well known.它在过敏性气喘中的存在是大家很熟悉的。
n.糖尿病
- In case of diabetes, physicians advise against the use of sugar.对于糖尿病患者,医生告诫他们不要吃糖。
- Diabetes is caused by a fault in the insulin production of the body.糖尿病是由体內胰岛素分泌失调引起的。
adj.急躁的;过敏的;易怒的
- He gets irritable when he's got toothache.他牙一疼就很容易发脾气。
- Our teacher is an irritable old lady.She gets angry easily.我们的老师是位脾气急躁的老太太。她很容易生气。
n.肠(尤指人肠);内部,深处
- Irritable bowel syndrome seems to affect more women than men.女性比男性更易患肠易激综合征。
- Have you had a bowel movement today?你今天有排便吗?
n.综合病症;并存特性
- The Institute says that an unidentified virus is to blame for the syndrome. 该研究所表示,引起这种综合症的是一种尚未确认的病毒。
- Results indicated that 11 fetuses had Down syndrome. 结果表明有11个胎儿患有唐氏综合征。
adv.足够地,充分地
- It turned out he had not insured the house sufficiently.原来他没有给房屋投足保险。
- The new policy was sufficiently elastic to accommodate both views.新政策充分灵活地适用两种观点。
adj.进化的;演化的,演变的;[生]进化论的
- Life has its own evolutionary process.生命有其自身的进化过程。
- These are fascinating questions to be resolved by the evolutionary studies of plants.这些十分吸引人的问题将在研究植物进化过程中得以解决。
n.前提;v.提论,预述
- Let me premise my argument with a bit of history.让我引述一些史实作为我立论的前提。
- We can deduce a conclusion from the premise.我们可以从这个前提推出结论。
n.臀部,髋;屋脊
- The thigh bone is connected to the hip bone.股骨连着髋骨。
- The new coats blouse gracefully above the hip line.新外套在臀围线上优美地打着褶皱。
ad.不够地;不够好地
- As one kind of building materials, wood is inadequately sturdy. 作为一种建筑材料,木材不够结实。
- Oneself is supported inadequately by the money that he earns. 他挣的钱不够养活自己。
adj.物质上,体格上,身体上,按自然规律
- He was out of sorts physically,as well as disordered mentally.他浑身不舒服,心绪也很乱。
- Every time I think about it I feel physically sick.一想起那件事我就感到极恶心。
n.流行病;盛行;adj.流行性的,流传极广的
- That kind of epidemic disease has long been stamped out.那种传染病早已绝迹。
- The authorities tried to localise the epidemic.当局试图把流行病限制在局部范围。
n.遗传因子,基因
- A single gene may have many effects.单一基因可能具有很多种效应。
- The targeting of gene therapy has been paid close attention.其中基因治疗的靶向性是值得密切关注的问题之一。
adv.本质上,实质上,基本上
- Really great men are essentially modest.真正的伟人大都很谦虚。
- She is an essentially selfish person.她本质上是个自私自利的人。
vt.渴望得到,迫切需要,恳求,请求
- Many young children crave attention.许多小孩子渴望得到关心。
- You may be craving for some fresh air.你可能很想呼吸呼吸新鲜空气。
n.碳水化合物,糖类( carbohydrate的名词复数 );淀粉质或糖类食物
- The plant uses the carbohydrates to make cellulose. 植物用碳水化合物制造纤维素。 来自《简明英汉词典》
- All carbohydrates originate from plants. 所有的碳水化合物均来自植物。 来自辞典例句
n.纤维,纤维质
- The basic structural unit of yarn is the fiber.纤维是纱的基本结构单元。
- The material must be free of fiber clumps.这种材料必须无纤维块。
n.新陈代谢
- After years of dieting,Carol's metabolism was completely out of whack.经过数年的节食,卡罗尔的新陈代谢完全紊乱了。
- All living matter undergoes a process of metabolism.生物都有新陈代谢。
adv.格外地;极端地
- She is an extraordinarily beautiful girl.她是个美丽非凡的姑娘。
- The sea was extraordinarily calm that morning.那天清晨,大海出奇地宁静。
n.页边空白;差额;余地,余裕;边,边缘
- We allowed a margin of 20 minutes in catching the train.我们有20分钟的余地赶火车。
- The village is situated at the margin of a forest.村子位于森林的边缘。
adv.特定地;特殊地;明确地
- They are specially packaged so that they stack easily.它们经过特别包装以便于堆放。
- The machine was designed specially for demolishing old buildings.这种机器是专为拆毁旧楼房而设计的。
adj.调谐的,已调谐的v.调音( tune的过去式和过去分词 );调整;(给收音机、电视等)调谐;使协调
- The resort is tuned in to the tastes of young and old alike. 这个度假胜地适合各种口味,老少皆宜。
- The instruments should be tuned up before each performance. 每次演出开始前都应将乐器调好音。 来自《简明英汉词典》
n.灵长类(目)动物,首席主教;adj.首要的
- 14 percent of primate species are highly endangered.14%的灵长类物种处于高度濒危状态。
- The woolly spider monkey is the largest primate in the Americas.绒毛蛛猴是美洲最大的灵长类动物。
primate的复数
- Primates are alert, inquisitive animals. 灵长目动物是机灵、好奇的动物。
- Consciousness or cerebration has been said to have emerged in the evolution of higher primates. 据说意识或思考在较高级灵长类的进化中已出现。
adv.完全地,全部地,彻底地;充分地
- The doctor asked me to breathe in,then to breathe out fully.医生让我先吸气,然后全部呼出。
- They soon became fully integrated into the local community.他们很快就完全融入了当地人的圈子。
n.(牛马的)饲料,粮草;v.搜寻,翻寻
- They were forced to forage for clothing and fuel.他们不得不去寻找衣服和燃料。
- Now the nutritive value of the forage is reduced.此时牧草的营养价值也下降了。
n.基因( gene的名词复数 )
- You have good genes from your parents, so you should live a long time. 你从父母那儿获得优良的基因,所以能够活得很长。 来自《简明英汉词典》
- Differences will help to reveal the functions of the genes. 它们间的差异将会帮助我们揭开基因多种功能。 来自英汉非文学 - 生命科学 - 生物技术的世纪
adj.(to)易于…的,很可能…的;俯卧的
- Some people are prone to jump to hasty conclusions.有些人往往作出轻率的结论。
- He is prone to lose his temper when people disagree with him.人家一不同意他的意见,他就发脾气。
n.肥胖,肥大
- One effect of overeating may be obesity.吃得过多能导致肥胖。
- Sugar and fat can more easily lead to obesity than some other foods.糖和脂肪比其他食物更容易导致肥胖。
n.流行病
- Reliance upon natural epidemics may be both time-consuming and misleading. 依靠天然的流行既浪费时间,又会引入歧途。
- The antibiotic epidemics usually start stop when the summer rainy season begins. 传染病通常会在夏天的雨季停止传播。
adj.遗传的,遗传学的
- It's very difficult to treat genetic diseases.遗传性疾病治疗起来很困难。
- Each daughter cell can receive a full complement of the genetic information.每个子细胞可以收到遗传信息的一个完全补偿物。
n.反复述说
- Don't keep harping on like that. 别那样唠叨个没完。
- You're always harping on the samestring. 你总是老调重弹。
n.荷尔蒙,激素,内分泌
- Hormone implants are used as growth boosters.激素植入物被用作生长辅助剂。
- This hormone interacts closely with other hormones in the body.这种荷尔蒙与体內其他荷尔蒙紧密地相互作用。
v.引出,抽出,引起
- It was designed to elicit the best thinking within the government. 机构的设置是为了在政府内部集思广益。
- Don't try to elicit business secrets from me. I won't tell you anything. 你休想从我这里套问出我们的商业机密, 我什么都不会告诉你的。
引出,探出( elicit的过去式和过去分词 )
- Threats to reinstate the tax elicited jeer from the Opposition. 恢复此项征税的威胁引起了反对党的嘲笑。
- The comedian's joke elicited applause and laughter from the audience. 那位滑稽演员的笑话博得观众的掌声和笑声。
vt.使活动起来,使开始起作用
- We must activate the youth to study.我们要激励青年去学习。
- These push buttons can activate the elevator.这些按钮能启动电梯。
使活动,起动,触发( activate的第三人称单数 )
- Activates the window and displays it in its current size and position. 激活窗口,保持当前的大小及位置不变。
- Pulling out the alarm switch activates alarm and pushing it deactivates it. 闹钟的开和关是通过拔出和按入闹铃开关实现的。
adj.原始的;最重要的
- Jealousy is a primal emotion.嫉妒是最原始的情感。
- Money was a primal necessity to them.对于他们,钱是主要的需要。
vt.分泌;隐匿,使隐秘
- The pores of your body secrete sweat.身上的毛孔分泌汗液。
- Squirrels secrete a supply of nuts for winter.松鼠为准备过冬而藏坚果。
n.持续,地位;adj.永久的,不动的,直立的,不流动的
- After the earthquake only a few houses were left standing.地震过后只有几幢房屋还立着。
- They're standing out against any change in the law.他们坚决反对对法律做任何修改。
n.刺激,刺激物,促进因素,引起兴奋的事物
- Regard each failure as a stimulus to further efforts.把每次失利看成对进一步努力的激励。
- Light is a stimulus to growth in plants.光是促进植物生长的一个因素。
上下班路程( commute的名词复数 )
- She commutes from Oxford to London every day. 她每天上下班往返于牛津与伦敦之间。
- Barbara lives in Oxford and commutes. 芭芭拉住在牛津,通勤往来。
adj.(疾病)长期未愈的,慢性的;极坏的
- Famine differs from chronic malnutrition.饥荒不同于慢性营养不良。
- Chronic poisoning may lead to death from inanition.慢性中毒也可能由虚弱导致死亡。
adj.沮丧的,抑郁的,不景气的,萧条的
- When he was depressed,he felt utterly divorced from reality.他心情沮丧时就感到完全脱离了现实。
- His mother was depressed by the sad news.这个坏消息使他的母亲意志消沉。
adj.新陈代谢的
- Impressive metabolic alternations have been undergone during embryogenesis.在胚胎发生期间经历了深刻的代谢变化。
- A number of intoxicants are associated with metabolic acidosis.许多毒性物质可引起代谢性酸中毒。
n.消化,吸收
- This kind of tea acts as an aid to digestion.这种茶可助消化。
- This food is easy of digestion.这食物容易消化。
n.[pl.]胆量;内脏;adj.本能的;vt.取出内脏
- It is not always necessary to gut the fish prior to freezing.冷冻鱼之前并不总是需要先把内脏掏空。
- My immediate gut feeling was to refuse.我本能的直接反应是拒绝。
adj.针的,尖刺的,尖刺状突起的;adj.脊骨的,脊髓的
- After three days in Japan,the spinal column becomes extraordinarily flexible.在日本三天,就已经使脊椎骨变得富有弹性了。
- Your spinal column is made up of 24 movable vertebrae.你的脊柱由24个活动的脊椎骨构成。
adj.周边的,外围的
- We dealt with the peripheral aspects of a cost reduction program.我们谈到了降低成本计划的一些外围问题。
- The hotel provides the clerk the service and the peripheral traveling consultation.旅舍提供票务服务和周边旅游咨询。
n.食物的一份&adj.帮助人的,辅助的
- The poor children regularly pony up for a second helping of my hamburger. 那些可怜的孩子们总是要求我把我的汉堡包再给他们一份。
- By doing this, they may at times be helping to restore competition. 这样一来, 他在某些时候,有助于竞争的加强。
n.收缩( contraction的名词复数 );缩减;缩略词;(分娩时)子宫收缩
- Contractions are much more common in speech than in writing. 缩略词在口语里比在书写中常见得多。 来自《简明英汉词典》
- Muscle contractions are powered by the chemical adenosine triphosphate(ATP ). 肌肉收缩是由化学物质三磷酸腺苷(ATP)提供动力的。 来自辞典例句
n.牵引;附着摩擦力
- I'll show you how the traction is applied.我会让你看如何做这种牵引。
- She's injured her back and is in traction for a month.她背部受伤,正在作一个月的牵引治疗。
a.不知道的,未意识到的
- They were unaware that war was near. 他们不知道战争即将爆发。
- I was unaware of the man's presence. 我没有察觉到那人在场。
n. 酶,酵素
- It was said that washing powders containing enzymes remove stains more efficiently. 据说加酶洗衣粉除污更有效。
- Among the enzymes which are particularly effective are pepsin, papain. 在酶当中特别有效的是胃朊酶、木瓜酶。
adj.神经的,神经系统的
- The neural network can preferably solve the non- linear problem.利用神经网络建模可以较好地解决非线性问题。
- The information transmission in neural system depends on neurotransmitters.信息传递的神经途径有赖于神经递质。
n.生理学,生理机能
- He bought a book about physiology.他买了一本生理学方面的书。
- He was awarded the Nobel Prize for achievements in physiology.他因生理学方面的建树而被授予诺贝尔奖。
adj.激素的
- Some viral diseases are more severe during pregnancy, probably tecause of hormonal changes. 有些病毒病在妊娠期间比较严重,可能是由于激素变化引起的。
- She underwent surgical intervention and a subsequent short period of hormonal therapy. 他接受外科手术及随后短暂荷尔蒙治疗。
adj.肠的;肠壁;肠道细菌
- A few other conditions are in high intestinal obstruction. 其它少数情况是高位肠梗阻。 来自辞典例句
- This complication has occasionally occurred following the use of intestinal antiseptics. 这种并发症偶而发生在使用肠道抗菌剂上。 来自辞典例句
n.苦恼,痛苦,不舒适;不幸;vt.使悲痛
- Nothing could alleviate his distress.什么都不能减轻他的痛苦。
- Please don't distress yourself.请你不要忧愁了。
ad.全部地,完整地;完全地,彻底地
- The fire was entirely caused by their neglect of duty. 那场火灾完全是由于他们失职而引起的。
- His life was entirely given up to the educational work. 他的一生统统献给了教育工作。
n.(用作复数)抗生素;(用作单数)抗生物质的研究;抗生素,抗菌素( antibiotic的名词复数 )
- the discovery of antibiotics in the 20th century 20世纪抗生素的发现
- The doctor gave me a prescription for antibiotics. 医生给我开了抗生素。
n.[医]过敏症;[口]厌恶,反感;(对食物、花粉、虫咬等的)过敏症( allergy的名词复数 );变态反应,变应性
- Food allergies can result in an enormous variety of different symptoms. 食物过敏会引发很多不同的症状。 来自辞典例句
- Let us, however, examine one of the most common allergies; hayfever. 现在让我们来看看最常见的变态反应的一种--枯草热。 来自辞典例句
adj.范围广大的,一扫无遗的
- The citizens voted for sweeping reforms.公民投票支持全面的改革。
- Can you hear the wind sweeping through the branches?你能听到风掠过树枝的声音吗?
n.故障,功能障碍(malfunction的复数形式)vi.失灵(malfunction的第三人称单数形式)
- The mood of defeat was as pervasive as the odor of malfunctions and decay. 失败的情绪就象损坏腐烂的臭味一样弥漫全艇。 来自辞典例句
- Possibility of engine malfunctions due to moisture, are lessened. 发动机故障的可能性,由于水分,也将减少。 来自互联网
n.健康法,卫生学 (a.hygienic)
- Their course of study includes elementary hygiene and medical theory.他们的课程包括基础卫生学和医疗知识。
- He's going to give us a lecture on public hygiene.他要给我们作关于公共卫生方面的报告。
adj.不毛的,不孕的,无菌的,枯燥的,贫瘠的
- This top fits over the bottle and keeps the teat sterile.这个盖子严实地盖在奶瓶上,保持奶嘴无菌。
- The farmers turned the sterile land into high fields.农民们把不毛之地变成了高产田。
n.怀疑者,怀疑论者,无神论者
- She is a skeptic about the dangers of global warming.她是全球变暖危险的怀疑论者。
- How am I going to convince this skeptic that she should attention to my research?我将如何使怀疑论者确信她应该关注我的研究呢?
n.逻辑(学);逻辑性
- What sort of logic is that?这是什么逻辑?
- I don't follow the logic of your argument.我不明白你的论点逻辑性何在。
adj.应用的;v.应用,适用
- She plans to take a course in applied linguistics.她打算学习应用语言学课程。
- This cream is best applied to the face at night.这种乳霜最好晚上擦脸用。
n.大草原
- The savanna is also the home of meat-eaters--the lion,leopard,and hyena who feed on the grasseaters.大草原也是食肉动物的家乡--狮子、豹、鬣狗--它们都是以草食动物维持生命的。
- They sped upon velvet wheels across an exhilarant savanna.他们的马车轻捷地穿过一片令人赏心悦目的大草原。
v.勉强度日,节约使用
- They had to eke out a livinga tiny income.他们不得不靠微薄收入勉强度日。
- We must try to eke out our water supply.我们必须尽量节约用水。
adv.最初,开始
- The ban was initially opposed by the US.这一禁令首先遭到美国的反对。
- Feathers initially developed from insect scales.羽毛最初由昆虫的翅瓣演化而来。
n.长命;长寿
- Good habits promote longevity.良好的习惯能增长寿命。
- Human longevity runs in families.人类的长寿具有家族遗传性。
a.饱和的,充满的
- The continuous rain had saturated the soil. 连绵不断的雨把土地淋了个透。
- a saturated solution of sodium chloride 氯化钠饱和溶液
n.(某事业、理论等的)支持者,拥护者( proponent的名词复数 )
- Reviewing courts were among the most active proponents of hybrid rulemaking procedures. 复审法院是最积极的混合型规则制定程序的建议者。 来自英汉非文学 - 行政法
- Proponents of such opinions were arrested as 'traitors. ' 提倡这种主张的人马上作为“卖国贼”逮捕起来。 来自辞典例句
n.参数,参量
- It is the parameter of distribution.这就是分布参数。
- One parameter which always comes into play is the national economy.国民经济是一个经常起作用的参量。
v.减轻,缓和,缓解(痛苦等)
- The doctor gave her an injection to alleviate the pain.医生给她注射以减轻疼痛。
- Nothing could alleviate his distress.什么都不能减轻他的痛苦。
n.营养不良
- In Africa, there are a lot of children suffering from severe malnutrition.在非洲有大批严重营养不良的孩子。
- It is a classic case of malnutrition. 这是营养不良的典型病例。
v.屈服,屈从;死
- They will never succumb to the enemies.他们决不向敌人屈服。
- Will business leaders succumb to these ideas?商业领袖们会被这些观点折服吗?
adj.营养的,滋养的
- A diet lacking in nutritional value will not keep a person healthy.缺乏营养价值的饮食不能维持人的健康。
- The labels on food products give a lot of information about their nutritional content.食品上的标签提供很多关于营养成分的信息。
n.间隔,间距;幕间休息,中场休息
- The interval between the two trees measures 40 feet.这两棵树的间隔是40英尺。
- There was a long interval before he anwsered the telephone.隔了好久他才回了电话。
ad.故意地,有意地
- I didn't say it intentionally. 我是无心说的。
- The local authority ruled that he had made himself intentionally homeless and was therefore not entitled to be rehoused. 当地政府裁定他是有意居无定所,因此没有资格再获得提供住房。
n.复活,复兴,文艺复兴
- The Renaissance was an epoch of unparalleled cultural achievement.文艺复兴是一个文化上取得空前成就的时代。
- The theme of the conference is renaissance Europe.大会的主题是文艺复兴时期的欧洲。
n.(通常指基督教的)修女, (佛教的)尼姑( nun的名词复数 )
- Ah Q had always had the greatest contempt for such people as little nuns. 小尼姑之流是阿Q本来视如草芥的。 来自《现代汉英综合大词典》
- Nuns are under vows of poverty, chastity and obedience. 修女须立誓保持清贫、贞洁、顺从。 来自辞典例句
vi.激增,(迅速)繁殖,增生
- We must not proliferate nuclear arms.我们决不能扩散核武器。
- Rabbits proliferate when they have plenty of food.兔子有充足的食物就会繁衍得很快。
n.变化,变异,转变
- People who have this mutation need less sleep than others.有这种突变的人需要的睡眠比其他人少。
- So far the discussion has centered entirely around mutation in the strict sense.到目前为止,严格来讲,讨论完全集中于围绕突变问题上。
n.(食品或化学品)营养物,营养品( nutrient的名词复数 )
- a lack of essential nutrients 基本营养的缺乏
- Nutrients are absorbed into the bloodstream. 营养素被吸收进血液。 来自《简明英汉词典》
n.刺激(物)
- It is necessary to curtail or alter normally coexisting stimuli.必需消除或改变正常时并存的刺激。
- My sweat glands also respond to emotional stimuli.我的汗腺对情绪刺激也能产生反应。
adj.昂贵的,价值高的,豪华的
- It must be very costly to keep up a house like this.维修这么一幢房子一定很昂贵。
- This dictionary is very useful,only it is a bit costly.这本词典很有用,左不过贵了些。
v.使恶化,使加重( exacerbate的过去式和过去分词 )
- The symptoms may be exacerbated by certain drugs. 这些症状可能会因为某些药物而加重。
- The drugs they gave her only exacerbated the pain. 他们给她吃的药只是加重了她的痛楚。 来自《简明英汉词典》
adv.不可避免地;必然发生地
- In the way you go on,you are inevitably coming apart.照你们这样下去,毫无疑问是会散伙的。
- Technological changes will inevitably lead to unemployment.技术变革必然会导致失业。
n.安康,安乐,幸福
- He always has the well-being of the masses at heart.他总是把群众的疾苦挂在心上。
- My concern for their well-being was misunderstood as interference.我关心他们的幸福,却被误解为多管闲事。
n.意识,觉悟,懂事,明智
- There is a general awareness that smoking is harmful.人们普遍认识到吸烟有害健康。
- Environmental awareness has increased over the years.这些年来人们的环境意识增强了。
abbr.high impact polystyrene 高冲击强度聚苯乙烯,耐冲性聚苯乙烯n.臀部( hip的名词复数 );[建筑学]屋脊;臀围(尺寸);臀部…的
- She stood with her hands on her hips. 她双手叉腰站着。
- They wiggled their hips to the sound of pop music. 他们随着流行音乐的声音摇晃着臀部。 来自《简明英汉词典》
adj.[医]曲折的,屈曲v.屈曲( flex的过去式和过去分词 );弯曲;(为准备大干而)显示实力;摩拳擦掌
- He stretched and flexed his knees to relax himself. 他伸屈膝关节使自己放松一下。 来自辞典例句
- He flexed his long stringy muscles manfully. 他孔武有力地弯起膀子,显露出细长条的肌肉。 来自辞典例句
n.(calf的复数)笨拙的男子,腓;腿肚子( calf的名词复数 );牛犊;腓;小腿肚v.生小牛( calve的第三人称单数 );(冰川)崩解;生(小牛等),产(犊);使(冰川)崩解
- a cow suckling her calves 给小牛吃奶的母牛
- The calves are grazed intensively during their first season. 小牛在生长的第一季里集中喂养。 来自《简明英汉词典》
n.姿势,姿态,心态,态度;v.作出某种姿势
- The government adopted an uncompromising posture on the issue of independence.政府在独立这一问题上采取了毫不妥协的态度。
- He tore off his coat and assumed a fighting posture.他脱掉上衣,摆出一副打架的架势。
adj.增加的
- For logic devices, the incremental current gain is very important. 对于逻辑器件来说,提高电流增益是非常重要的。 来自辞典例句
- By using an incremental approach, the problems involving material or geometric nonlinearity have been solved. 借应用一种增量方法,已经解决了包括材料的或几何的非线性问题。 来自辞典例句
n.现象
- Ade couldn't relate the phenomena with any theory he knew.艾德无法用他所知道的任何理论来解释这种现象。
- The object of these experiments was to find the connection,if any,between the two phenomena.这些实验的目的就是探索这两种现象之间的联系,如果存在着任何联系的话。