Marathon Challenge

Fit to Go the Distance by Susan K. Lewis

When you watch an Olympic weightlifter hoist a 500-pound barbell over his head, or see a gymnast gracefully slide into a split, the physical attributes that allow these athletes to excel in their sports may seem obvious. But what is it—both physically and psychologically—that makes an elite marathoner able to run over 26 miles in little more than two hours? And can almost anyone—even someone who has been sedentary for years—become fit enough to run a marathon?

NOVA wanted to investigate these questions through the "Marathon Challenge," and with the help of a dozen enthusiastic recruits, we set out to see if "ordinary people" could transform themselves into marathoners in just a matter of months. The results were extraordinary.

A test of fitness

A range of physical traits and well-honed skills distinguishes elite distance runners from huffing joggers—lean yet muscular bodies, a linear and efficient stride, and a high threshold for pain and muscle fatigue among them. Yet exercise physiologists often focus on one measure of fitness, called VO2max, as the key to a person's aptitude for endurance sports. It's also a good gauge of overall cardiovascular health. And because it's quantifiable, it offered a way to assess how much progress NOVA's runners made from start to finish of their nine-month training for the Boston Marathon.

VO2max, theoretically, is the volume of oxygen a person can consume in one minute as he or she exercises at maximum exertion. In practice, it's measured by hooking up test subjects (in our case, NOVA runners) to a breathing apparatus and having them run as hard as they can. In endurance sports, you rely on oxygen to convert the fuel you get from food into energy for your muscles. VO2max is usually expressed in terms of body weight (milliliters of oxygen per kilogram of body weight), so merely losing weight can improve your score over time.

Nurturing what nature gave you

Elite endurance athletes, including distance runners and cyclists, consume vast amounts of oxygen when they compete; they can have VO2max scores twice as high as most of us mere mortals. Lance Armstrong once registered at 83.8 ml/kg/min; the average man his age would measure between 40 and 50. Even if Armstrong had never taken up cycling or any sport, he likely would have scored exceptionally high.

We are all born with a genetic predisposition for a certain VO2max range, and most of us, even if we work out daily, will never hit the marks of champions. Yet where we fall within our own ranges hinges on how often and how strenuously we exercise. More critically, this exercise, like a wonder drug, can boost our physical and emotional well-being.

So what innate physiological factors determined the NOVA runners' scores, how could training change them, and what impact could this have on their health? For the answers, it helps to trace how oxygen moves from the air you breathe all the way to the mitochondria of your muscle cells, where it is ultimately consumed.

Into the lungs

Given that VO2max is a measure of oxygen consumption, you might think that lung capacity—the volume of air a person can inhale—plays a major role in determining VO2max scores. Indeed, Lance Armstrong is renowned, among many more significant things, for having strikingly large lungs. However, lung size isn't a limiting factor; even people with smaller-than-average lung capacity breathe in far more oxygen than the rest of their bodies can process.

From the lungs, oxygen diffuses into the bloodstream. For most of us, the rate at which the oxygen moves at this point is also insignificant. Only elite athletes might have their VO2max scores hampered by the rate of diffusion, because their blood flows so rapidly that it might not have time to pick up all the oxygen it could carry. In any case, no amount of training will alter the lungs to make the oxygen flow from them any faster or make them healthier in general.

Red-blooded athletes

Exactly how much oxygen your blood can absorb and deliver to your muscles is critical to your VO2max and your performance in endurance sports. At the lungs, oxygen attaches to hemoglobin, a protein complex in red blood cells. Oxygen-enriched, the blood turns bright red and remains this vivid color until the oxygen is "dropped off" in all the various tissues of your body that need it—not just to power muscles, but to keep the heart, brain, and other vital organs functioning.

The sheer volume of blood in your body, the number of red blood cells it contains, and the quality of hemoglobin within these cells all affect the amount of oxygen your blood can shuttle to your muscles. If you are anemic and your hemoglobin lacks iron, for instance, it is less able to bond with oxygen. And cigarette smoking can dramatically compromise oxygen delivery, because tobacco smoke's carbon monoxide, rather than oxygen, holds onto hemoglobin.

With sweat and perseverance, all of us can strengthen our hearts.

"Born" runners may naturally generate high numbers of red blood cells that are particularly effective at transporting oxygen. World-class athletes also frequently train at high altitudes, where their bodies make more red blood cells in response to "thin" (low-oxygen) air. And all too often, competitive athletes temporarily boost blood oxygen levels through illicit means, including blood transfusions and doping with EPO (Erythropoietin), a hormone that triggers red blood cell production.

Team NOVA, of course, never turned to such underhanded tactics. Fortunately, legitimate training, even at sea level, could enhance the ability of their blood and vascular systems to carry more oxygen to hard-working muscles.

Regular and fairly intense training like the NOVA runners experienced spawns the growth of new capillaries, tiny blood vessels that supply oxygen and nutrients to skeletal muscles, the heart, the brain, and elsewhere. What's more, such exercise can make blood vessels throughout the body less stiff, improving blood flow and reducing risk of arteriosclerosis. And by improving cholesterol levels, exercise also helps keep the vascular system, including vital coronary arteries, free of clogs.

The heart of the matter

Perhaps the greatest determiner of VO2max scores is cardiac output, the amount of oxygen-rich blood your heart sends through your body in a single minute. Elite endurance athletes have extraordinarily powerful, and often unusually large, hearts. A typical jogger might pump over 15 quarts of blood per minute, while a frontrunner in the Boston Marathon is capable of pumping twice that.

Cardiac output is the product of heart rate (the number of beats per minute) times stroke volume (how much blood the heart ejects with each contraction). For champions and recreational runners alike, even the most arduous training won't increase maximal heart rate, and this rate inevitably drops as we get older.

On the other hand, with sweat and perseverance, all of us can strengthen our hearts and increase stroke volume. Elite marathoners rack up thousands of training miles each year to extend the muscles of the heart and increase stroke volume. Even Team NOVA's workouts—which eventually had the runners pounding pavement (and dirt) about 30 miles a week—could improve the efficiency of their hearts.

Muscle work

Elite distance runners may look almost waif-like, certainly not muscle-bound. Yet they have muscles that are exceptionally good at processing oxygen and propelling them through 26.2 miles—muscles that, despite maintaining nearly a five-minute-per-mile pace, don't seem to tire. How is it possible?

Part of the answer lies in the type of muscle fiber that predominates in their bodies. Physiologists call it "slow-twitch" fiber (as opposed to bulkier "fast-twitch" fiber that helps sprinters and weightlifters with quick bursts of power). Team NOVA's athletic muse, Uta Pippig, is likely graced with an abundance of slow-twitch fiber, while fast-twitch muscles probably contour NOVA runner Steve DeOssie, a former NFL linebacker.

It's possible that some of the positive change evident in Team NOVA's scores has little to do with red blood cells or mitochondria or any other physiological factor.

A person's tendency to develop either slow- or fast-twitch muscle is largely genetic, yet specific training techniques—long runs verses bench presses, for instance—practiced over many years may change the balance of fiber types slightly. Endurance training can also alter the physiology of either muscle type, in essence making fast-twitch muscles perform more like slow-twitch, and making slow-twitch muscles do better at what they already do well, namely use oxygen for energy production.

The key is mitochondria, tiny structures that act as power plants within all cells. Mitochondria combine oxygen with glucose or other food fuels to make ATP (adenosine triphosphate), the so-called "universal energy molecule" that powers cellular work. In muscle cells, ATP is essential for muscle contraction. Slow-twitch fiber inherently contains more mitochondria than fast-twitch. But endurance training increases the number of mitochondria in both types of muscle. It also can make mitochondria larger and more metabolically active.

No pain, no gain?

Bigger and more active mitochondria don't just produce extra energy to keep muscles moving, they also cut down on muscle fatigue. Tired, sore muscles during exercise are linked to a buildup of lactic acid, and mitochondria can sweep up and consume lactic acid as a fuel source. Once again, champion athletes may have an innate edge; their mitochondria might be particularly well suited for this cellular housekeeping. But anyone can condition his or her muscles to be less crippled by lactic acid.

The members of Team NOVA conditioned their muscles over nine months of rigorous training, and they were capable of runs at the end that would have been excruciating for them at the start. In the summer of 2006 some of them couldn't even make it through a single mile without cramping up and stopping. By the spring of 2007, they were aiming to take on the grueling 26.2-mile course of perhaps the world's most famous marathon, Heartbreak Hill and all.

"Winning" in the NOVA challenge

Shortly before they made their way to the starting line on the outskirts of Boston, the runners on Team NOVA stepped onto a treadmill to have their VO2max measured for the second time. Here are the results, comparing how well they did prior to their nine-month training adventure with how they did post-training:


Pre (ml/kg/min)

Post (ml/kg/min)

% improved

Larry Haydu

33.2 [Fair]

46.9 [Superior]


Mic Guaring

41.5 [Good]

54.3 [Superior]


Daniel Williams

42.8 [Good]

48.9 [Excellent]


Raymond Rassi

44.5 [Excellent]

48.4 [Superior]


Jonathan Bush

57.4 [Superior]

62.2 [Superior]


Steve DeOssie

not tested*

not tested*



Pre (ml/kg/min)

Post (ml/kg/min)

% improved

Betsey Powers-Sinclair

23.8 [Poor] **

50.1 [Superior]


Xenia Johnson

27.3 [Fair]

37.9 [Superior] ***


Jane Viener

22.0 [Poor]

28.6 [Good]


Carol Brayboy

26.7 [Fair]

34.2 [Excellent]


Vera Yanovsky

26.7 [Poor]

33.6 [Good]


Sama ElBannan

30.4 [Fair]

34.9 [Good]


* Steve DeOssie was unable to take the test due to a weak Achilles tendon, which the high-intensity treadmill run could have severely injured.

** Betsey Powers-Sinclair's initial score was likely slightly lower than her true VO2max. Her test was cut short when doctors picked up signals of possible heart distress.

*** Xenia Johnson had turned 40 by the time of her second test, putting her in a new category.

To understand these results, it helps to put them in the context of normal VO2max scores for men and women of various ages:



Very Poor








35.0 - 38.3

38.4 - 45.1

45.2 - 50.9

51.0 - 55.9




33.0 - 36.4

36.5 - 42.4

42.5 - 46.4

46.5 - 52.4




31.5 - 35.4

35.5 - 40.9

41.0 - 44.9

45.0 - 49.4




30.2 - 33.5

33.6 - 38.9

39.0 - 43.7

43.8 - 48.0




26.1 - 30.9

31.0 - 35.7

35.8 - 40.9

41.0 - 45.3




20.5 - 26.0

26.1 - 32.2

32.3 - 36.4

36.5 - 44.2




Very Poor








25.0 - 30.9

31.0 - 34.9

35.0 - 38.9

39.0 - 41.9




23.6 - 28.9

29.0 - 32.9

33.0 - 36.9

37.0 - 41.0




22.8 - 26.9

27.0 - 31.4

31.5 - 35.6

35.7 - 40.0




21.0 - 24.4

24.5 - 28.9

29.0 - 32.8

32.9 - 36.9




20.2 - 22.7

22.8 - 26.9

27.0 - 31.4

31.5 - 35.7




17.5 - 20.1

20.2 - 24.4

24.5 - 30.2

30.3 - 31.4


Clearly, some members of Team NOVA made tremendous advances in VO2max, others less so. Both Jonathan Bush and Ray Rassi started with relatively high scores and therefore had less room for improvement. But all the tested runners upped their scores, reflecting a positive change in their cardiovascular and respiratory fitness.

Betsey Powers-Sinclair's standout gain—more than doubling her VO2max—may be somewhat artificial, because her first test was stopped short due to concerns about her heart. But even had she scored slightly higher the first time, she still would have made a tremendous advance. By the time of her second test, she had dropped 45 pounds, largely due to changes she had made in her diet. Her final score is also a testament to her ability to rise nearly every morning at 5 a.m. to attend an exercise "boot camp," pushing herself far beyond even what Coach Megerle prescribed in his training regimen. Sama ElBannan also made a lifestyle change that may have boosted her VO2max and certainly changed the entire outlook for her future health—she gave up smoking.

The power of positive thinking

It's possible that some of the positive change evident in Team NOVA's scores has little to do with red blood cells or mitochondria or any other physiological factor. Perhaps some psychological "X Factor" contributed to the improvement. VO2max is, after all, oxygen consumption at "maximum" exertion, measured when people run on a treadmill as fast as they think they can. Did NOVA's runners, at the end of their adventure, have greater willpower and confidence to keep going on the treadmill at points where, nine months earlier, they might have felt they were too exhausted?

Whatever the answer, if the men and women of Team NOVA can retain some of the exercise practices and the mindset they gained through this experience, they likely will be not just fit to go the distance of future marathons, they will be better fit for life. A mountain of medical studies has shown that regular exercise decreases risk of heart disease, high blood pressure, and Type II diabetes, helps people maintain a healthy body weight, and can ward off mild depression and possibly even Alzheimer's.

Do you have to train for a marathon to see such health benefits? Not at all. For Team NOVA, taking on the challenge served as an impetus to get some of them off the proverbial couch. However, as Tufts University physiologist and Team NOVA advisor Roger Fielding notes, even brisk walking five or six days a week for 30 to 40 minutes at a time can impart many of the same health benefits. And that's something almost all of us can do.

(To learn more about how marathon training and other forms of exercise can impact your health—including the potential risks—see "Ask the Expert".)

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Uta Pippig makes it look easy. Like most elite marathoners, though, she has trained her naturally gifted body to perform at its peak.

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The NOVA runners had their oxygen consumption measured with an apparatus similar to this one. And like the model pictured here, they wore heart monitors to check for signs of dangerous overexertion.

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Regular aerobic exercise, whether it's marathon training or simply brisk walking, can dramatically enhance the health of your entire cardiovascular system.

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Red blood cells within a capillary, a tiny blood vessel that directly feeds oxygen and nutrients to muscle and other tissues of the body.

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While bodybuilders relish the bulky muscles brought on by resistance training, marathoners covet a different type of muscle adept at using oxygen.

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Betsey Powers-Sinclair transformed her body, and clearly her mindset as well, by taking on the NOVA challenge.

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Team NOVA's Daniel Williams, Ray Rassi, Jane Viener, and Steve DeOssie—all presented by a smiling Sama ElBannan.

Susan K. Lewis is editor of NOVA online.

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