The study, the
first to profile elite athletes habitually eating very low-carbohydrate diets,
involved 20 ultra-endurance runners age 21-45 who were top competitors in
running events of 50 kilometers (31 miles) or more.
"These
low-carb athletes were spectacular fat burners," said lead researcher Jeff
Volek, professor of human sciences at The Ohio State University. "Their
peak fat burning and the amount of fat burned while running for three hours on
a treadmill was dramatically higher than what the high-carb athletes were able
to burn.
"This
represents a real paradigm shift in sports nutrition, and I don't use that term
lightly," he said. "Maybe we've got it all backwards and we need to
re-examine everything we've been telling athletes for the last 40 years about
loading up on carbs. Clearly it's not as straightforward as we used to
think."
The 10 low-carb
athletes ate a diet consisting of 10 percent carbs, 19 percent protein and 70
percent fat. Ten high-carb athletes got more than half their calories from
carbs, with a ratio of 59 percent carbs, 14 percent protein and 25 percent fat.
In all other
respects, the athletes were similar: elite status, age, performance, training
history and maximum oxygen capacity. "They all had the same engine, so to
speak," Volek said.
Scientists
measured gas exchange repeatedly during a test determining the athletes'
maximum oxygen intake to gauge carb- and fat-burning rates. On average, the
low-carb runners' peak fat-burning rate was 2.3-fold higher than the rate for
high-carb athletes: 1.5 versus .67 grams per minute.
The research is
published online in the journal Metabolism: Clinical and Experimental.
Volek has been
studying the effects of low-carb eating -- and ketogenic diets specifically --
for years, particularly in the context of obesity and diabetes. But he has
always been interested in how such a diet might augment physical performance
and recovery. Ketogenic diets are those that reduce carbohydrates enough to
allow the body to access its fat stores as the primary source of fuel. Lowering
carbs and increasing fat intake leads to the conversion of fat into ketones,
molecules that can be used by cells throughout the body, especially the brain,
as an alternative to glucose.
It can take weeks
or longer for the human body to fully adjust to a ketogenic diet, so the
low-carb athletes in the study were eligible only if they had been restricting
carbs for at least six months. Their average time on a ketogenic diet was 20
months.
"The goal was
to characterize their metabolic response to a standardized exercise test,"
Volek said. "This is the first time we've had the opportunity to peek
under the hood at what a long-term low-carb, fat-adapted athlete looks
like."
Over two days,
researchers subjected the athletes to tests to determine peak fat burning
during a brief high-intensity workout and metabolic characteristics during
prolonged exercise.
On day one, the
athletes ran on a treadmill to determine their maximum oxygen consumption and
peak fat-burning rates. On day two, the athletes ran on a treadmill for three
hours at an intensity equal to 64 percent of their maximum oxygen capacity.
During this test, they drank water but took in no nutrition -- before the run,
athletes consumed either low- or high-carb nutrition shakes consisting of about
340 calories.
During the
endurance run, the two groups did not differ significantly in oxygen
consumption, ratings of perceived exertion or calorie expenditure. However,
fat-burning rates during prolonged exercise were again about twice as high in
the low-carb athletes, and the average contribution of fat during exercise in
the low-carb and high-carb groups was 88 percent and 56 percent, respectively.
"The low-carb
guys go beyond what you can achieve with good genetics and extensive
training," Volek said. "The high-carb runners were very healthy, and
were awesome fat burners by conventional standards -- yet their peak fat
burning is less than half that of endurance athletes eating low-carb diets.
This shows that we have far underestimated how much fat humans can burn. There
is a large reserve capacity that can only be tapped if carbs are restricted.
"So far, this
has been a grassroots movement. Athletes on their own have been going against
the grain, so to speak, and experiencing a lot of success. I think it's mainly
taken off in the ultra-endurance world because the self-perceived benefits are
so high there, but many other athletes competing in a variety of events and
various sports teams are experimenting with carb restricting," Volek said.
Another key
finding: Despite their low intake of carbs, these fat-burning athletes had
normal muscle glycogen levels -- the storage form of carbohydrates -- at rest.
They also broke down roughly the same level of glycogen as the high-carb
runners during the long run, and synthesized the same amount of glycogen in
their muscles during recovery as the high-carb athletes.
"This was
completely unexpected, but now that we have observed it we have some novel
ideas why this is the case. We can only speculate on the mechanism behind
it," Volek said.
Muscle glycogen
was discovered in the 1960s to be a critical energy source for athletes, which
led to decades of emphasis on high-carb diets to support energy needs during
intense exercise. But Volek said the body has an elegant system to support
glycogen levels even when carbohydrates are limited in the diet.
"The blue
print for becoming 'fat- or keto-adapted' is hard wired into our genetic code.
However, traditional 'healthy' diets with carbohydrates as the dominant
nutrient prevent this alternative metabolic operating system from ever booting
up.
"Restricting
carbs allows the program to reboot and enable many athletes to achieve improved
levels of health and performance" he said.
Story Source:
The above post is
reprinted from materials provided by Ohio State University. The original item was written
by Emily Caldwell. Note: Materials may be edited for content and
length.
Journal Reference:
Jeff
S. Volek, Daniel J. Freidenreich, Catherine Saenz, Laura J. Kunces, Brent C.
Creighton, Jenna M. Bartley, Patrick M. Davitt, Colleen X. Munoz, Jeffrey M.
Anderson, Carl M. Maresh, Elaine C. Lee, Mark D. Schuenke, Giselle Aerni,
William J. Kraemer, Stephen D. Phinney. Metabolic
characteristics of keto-adapted ultra-endurance runners. Metabolism,
2015; DOI:10.1016/j.metabol.2015.10.028
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