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  • In 490 BC a Greek messenger named Pheidippides ran from the Greek town of Marathon to the

  • capital Athens to deliver a message that the Greek army had

  • just beaten back the Persians, and the distance between those two towns is 26.2 miles, and

  • that’s the origin of the modern sporting event that we call the marathon. You might

  • know that story, but what they don’t always tell you is that when he got to Athens after

  • those 26.2 miles, Pheidippides died.

  • So why on Earth would anyone want to run one of those for fun? How are our bodies even

  • able to? I decided to find out, so I ran one. In the process, I

  • discovered a lot about what I’m made of, in more ways than one. You guys ready to run

  • the marathon? My training started millions of years before I ever got to the starting

  • line.

  • The first step to becoming a runner is, well, standing up, and bipedalism is only seen in

  • a handful of animals, except for a few species of birds walking on two legs is only uses

  • a temporary form of transportation. Our ancestors first stood up over three million years ago,

  • and well we were running probably not long after that, were made for

  • it. You could say that humans are built for long distance running but the truth is, long

  • distance running build us the most four on the floor quadrupeds could easily beat me

  • in a sprint, but humans are medal contenders in nature’s distance running events. Even

  • the cheetah, the most perfectly crafted running machine on Earth could only run for maybe

  • a mile and a half before it overheats. Today’s fastest Olympic marathoners, they would only

  • be beaten by a handful of Earth’s animals in that long

  • distance. One theory of human evolution says that our adaptations for distance running

  • work feast or hunting success like we talked about in my episodeWhy Do We Cook?”,

  • bigger, richer meals mean that we could evolve, well, bigger, richer brains. There’s a whole

  • list of ways that we are made to run. In large tubes in our skulls help us balance while

  • were running, reflexes in our eyes keep our heads steady as we move up and down. It’s

  • short arms and thin ankles that take us less effort to swing. Wide shoulders, a thin waist,

  • and a pretty narrow pelvis help us counter the rotation of our moving legs. We have sweat

  • glands, and less body hair, and tall thin bodies that let us disperse more heat. Better

  • blood flow away from the brain to keep it cool, your big gluteus maximus muscles to

  • stabilize our upper body, high surface area knee, ankle, and hip joints for shock absorption,

  • and most importantly, our lower legs are built like rubber bands.

  • This is by far our coolest running adaptation. Every time my body hits the ground, it delivers

  • up to 8 times the force of my body weight. That’s over 1400 pounds! In order to keep

  • that up for 26.2 miles, my foot expands and spreads like a shock absorber. This is the

  • most important part of a running human: the Achilles tendon. Though my foot hits the ground,

  • my calf muscles flexed, but even then the muscles and tendons are still a little bit

  • elastic, and then my ankle joint acts as a lever, which transfers as much as 50 percent

  • of that energy into the next step. By using stored kinetic energy, instead of chemical

  • energy, were able to go farther with less work.

  • You can’t run a marathon with just rubber bands though. You need power that humans are

  • run on gasoline your car ATP. This is an image of a striated muscle, the same type we have

  • in our arms, in our legs, and basically everywhere that we move. Each row of stripes contains

  • a string of proteins called actin, next to another string of proteins called myosin.

  • And the head of that myosin protein, well, it acts like a ratchet, pulling along the

  • string of actin, shortening our contracting the muscle. That myosin machine is powered

  • by ATP. The thing is, our bodies only have a couple seconds worth of ATP stored up at

  • any moment, so instead, were constantly replenishing it, thanks to our mitochondria

  • and their little ATP factories. Just picture me as a giant ship with trillions of mitochondria

  • at the oars. My body cycled through something like 75 kilograms of ATP during the marathon.

  • That’s almost my entire body weight! It just shows you how good our bodies are at

  • recycling energy. Now that’s 75 kilograms of ATP broken down release the same amount

  • of free energy as a kilogram of TNT. My body gets ATP in a couple of different ways. If

  • I was running full speed the entire time, my cells would be forced to use an inefficient

  • process called glycolysis, but by running slightly slower for the whole race, I let

  • my mitochondria use a much more efficient method called the Krebs cycle and the electron

  • transport chain. I can burn lots of fuel and make that ATP, like fat or protein, but my

  • muscles prefer glucose, which is stored in long chains like glycogen for quick access,

  • but even they don’t keep that much just lying around. So instead, I topped off my

  • glycogen tank before the race by doing something called carb loading.

  • Look at all these waffles I have to eat. But even eating all that before the race, my body

  • can’t hold all the glycogen it needs to get through a marathon, so I had to eat and

  • drink more during the race, or else I would hit the dreaded wall.

  • Hitting the wall is just a big scary name for fatigue. And there’s lots of reasons

  • why it can happen. If you run out of glycogen, then your muscles can run out of ATP, and

  • that protein ratchet will get stuck in the lock position. It’s actually why something,

  • well, gets kinda stiff when it dies. If your cells don’t have enough salt, then your

  • nerves and muscles won’t have the sodium, potassium, and calcium that they need to pass

  • electrical signals. The main reason that people hit the wall is because of this. See, your

  • brain is competing with your muscles for blood sugar, and if those levels dip too low, well,

  • youll feel dizzy and loopy.

  • “I think I’m gonna die. I’m gonna die. ”

  • Youll be okay.”

  • Your brain is actually preventing your muscles from firing goad for some emergency power

  • save mode. I’ve never run a marathon before and I discovered it’s not like any other

  • sporting event I’ve ever taken part in. Youre not battling an opponent; youre

  • only battling yourself. All those feelings of joy, and fatigue, and pain, they only exist

  • in your mind. That mind is connected to the physical muscles and chemical power plants

  • and proteins doing work. I’ve never understood more about my body, or my biology, and when

  • I push them to the limit, and in the process, I discovered that it wasn’t a limit after

  • all. That was the most fun I’d never want to have again. Like halfway through, it was

  • like the hardest thing I’ve ever done, and the entire second half

  • was just pure willpower, like a competition against yourself, and I-I won. I beat- I beat

  • my own mind. That was awesome. Thank you, everybody.

  • Were not the only social animals that sit down to eat together, but we are the only

  • ones who cook. Cultural anthropologist Claude Levi-Strauss is above all cooking establishes

  • the difference between animals and people, although I’d think he’d agree that pants

  • make a big difference, too.

[MUSIC]

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