Try standing on one leg for any length of time and most of us would at least wobble. New research shows how flamingos bear all that weight for seemingly endless periods of time.
“Anytime I go to the zoo, I always hear a kid ask why or how they do that,” says Young-Hui Chang, a professor of biological sciences at Georgia Institute of Technology, who studies locomotion in animals from both a neurological and a biomechanical perspective. “It’s a natural question.”
Because science has yet to provide a definitive answer, Chang and Lena Ting, professor of biomedical engineering at Emory University and Georgia Tech who studies balance control in humans and mammals, decided to find out. They discovered the reason differs from most previous suggestions: it’s all about reducing muscular effort.
The findings could have potential applications for better robotics, orthopedic braces, artificial limbs, and more focused treatments for neurological or balance problems.
But the researchers argue that simply providing clarity to long-standing questions about long-standing flamingos has value as well.
“There’s something to be said for just scientific curiosity and learning how nature works,” Chang says. Flamingos aren’t the only birds that stand on one leg, but “the extreme example is the flamingo. It’s precisely from these extreme examples in nature where you can really gain a lot of insight.”
Previous research has suggested that flamingos engage in this behavior to avoid muscle fatigue or to conserve body heat.
For the new study, published in Biology Letters, the researchers studied live birds at the Zoo Atlanta flock, one of the largest breeding flocks of Chilean flamingos in the US. They also used two cadaver birds from the Birmingham Zoo and flamingo skeletons from the Museum of Paleontology at the University of California, Berkeley.
The findings show that a “passively engaged gravitational stay apparatus” helps the birds support their weight and maintain balance while on one reed-thin leg. The bird’s specialized anatomy, clever posture, and gravity combine to give the flamingo this ability, which does not involve bones locking into position. It’s more like a hammock or sling than a lock, but it does require the unique anatomy of flamingos.
“The biomechanics are such that when they stand on one leg, they become very stable and are able to maintain that posture without activating muscle,” Ting says. “If they deviate from that posture to two legs, that no longer holds. It’s very posture-specific, a one-legged posture that can support their body weight.”
“Here we have a non-living animal able to stand on one leg. Obviously, if it’s not alive, then the muscles are not activated.”
The “passively engaged” part of the flamingo’s gravitational stay apparatus is exactly as it sounds: It requires minuscule, if any, active muscular or nerve control, Chang adds.
Those who marvel at a large, fluffy pink lump of flamingo body held up by one slender leg may be surprised to learn that the “joint” in the middle of that leg is actually an ankle, not a knee. “Most people don’t realize that knee and hip joints are not actually in view in most birds,” Chang says. “They’re near the body, kind of behind the wing. The flamingo thigh is almost perfectly horizontal.”
All that contributes to biomechanics that might actually require greater muscular effort if not for the flamingo’s ability to “stay” in a pose, which flamingos can get out of easily in flight-or-fight situations.
A one-legged standing test, actually termed a “flamingo test,” is used to diagnose human balance disorders with the help of pressure plates, instruments that measure balance, force, and other data. Humans are usually more than willing to stand on pressure plates. But flamingos? They tend to squawk at things foreign in their environment.
“The zoo didn’t want us to interact with the adult flamingos because they don’t handle change in their environment very well,” Ting says. But zoo workers could handle juvenile flamingos and placed them near the plates after they were fed, hoping that post-meal sleepiness would yield measurable data.
The cadaver birds actually provided a eureka moment for Chang. After putting one into the one-legged pose, “I don’t know what made me do it, but I just kind of grabbed the leg and picked it up,” he says. The bird maintained its posture. “Here we have a non-living animal able to stand on one leg. Obviously, if it’s not alive, then the muscles are not activated.”
Can flamingo biomechanics help treat human movement and balance disorders?
“If we know how much is passive mechanics and how much the nervous system has to control, it puts researchers in a better position to treat people,” Chang says. Flamingo biomechanics can mean better wearable artificial limbs and longer battery life for stability supports.
Robots could also benefit. Getting robots to balance can be difficult; sensing the environment and making adjustments is how they currently do it.
“But if you design the biomechanics of a robot in the right way, not so much sensing but a sort of feedback control,” Ting says, “then they would have this passive ability, and they would be more robust in uncertain environments.”
This text is published here under a Creative Commons License.
Author: Renay San Miguel-Georgia Tech
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