From dragonflies to hummingbirds, hovering flight is among the most complex and captivating forms of animal movement -- a physiological feat of size, musculature and wing development.

 

For nectar-feeding bats that hover as they feed from flowers, this aerial maneuver also depends on extra-long whiskers unlike those of most other bat species, according to a Dartmouth College-led study in the journal Proceedings of the Royal Society B. The researchers used high-speed cameras to capture how the stiff hairs jutting forward from the face of nectar-eating bats provide enhanced spatial information that guides the animals as they swoop in to quickly feed -- within a second or less -- on succulent flowers without landing.

 

"The whiskers of nectar-feeding bats are critical sensory organs that provide high-quality input the brain works with to optimize hovering. It's a cool junction between sensory biology and bio-kinematics, between form and function," said lead author Eran Amichai, a postdoctoral researcher in biological sciences at Dartmouth who studies echolocation in bats. Co-authors are postdoctoral fellow David Boerma from the American Museum of Natural history, animal behavioralist Rachel Page at the Smithsonian Tropical Research Institute in Panama, Sharon Swartz, a professor of biology and engineering at Brown University, and Hannah ter Hofstede, a past assistant professor of biological sciences at Dartmouth now at the University of Windsor in Canada.

 

The researchers worked at the Smithsonian Tropical Research Institute recording Pallas's long-tongued bats -- a South and Central American bat that has the fastest metabolism of any mammal -- as they drank from hand-blown glass flowers designed for the study to replicate the plants the animals feed from. High-speed infrared cameras captured photos and video of the bats as they descended upon the glass flowers and navigated their muzzles and tongues into the "bloom" to eat the nectar. Feedings typically lasted between a half- to one second.

 

The researchers found that bats with clipped whiskers were less agile and accurate during feeding and flight than animals with untouched whiskers. The animals with clipped whiskers were held for a few days until the hairs regrew, then released back into the jungle. "Clipping the whiskers doesn't reduce the bats' ability to feed, they just do it a little less gracefully," Amichai said. "If it were gymnastics, they'd get an 8.5 instead of a 9.8."