This video says about itself:
18 July 2018
A feeding snipefish recorded at 2000 frames per second, playback at 30 frames per second. Powered by elastic recoil, the fish’s head pivots to bring the mouth close to the food item. (Sarah Longo, UC Davis).
From the University of California – Davis in the USA:
July 23, 2018
The snipefish, an ocean-dwelling relative of the seahorse, has a very long, skinny snout ending in a tiny mouth. A recent study by UC Davis graduate student Sarah Longo shows that snipefish feed with an elastic-boosted head flick at almost unprecedented speed.
“At as little as two milliseconds, it’s among the fastest feeding events ever recorded for fish”, said Longo, now a postdoctoral researcher at Duke University.
Snipefish, seahorses and pipefish all have long, skinny snouts and use “pivot feeding” to capture food, Longo said, meaning that they pivot their head rapidly to bring their mouth up close to the prey and suck it in.
“Not only do they pivot, but they pivot faster than their muscles should allow”, she said.
She first used high-speed video cameras to record snipefish feeding in the lab. Based on those videos, Longo was able to measure how fast the fish pivoted their heads and estimate the amount of energy involved.
Elastic recoil rapidly releases stored energy
The snipefish feeding strike took from two to 7.5 milliseconds from start to prey capture, with an instantaneous power requirement averaging 2800 Watts per kilogram of body weight. The power estimates ranged as high as 5500 Watts per kilogram.
Longo used micro computed tomography and digital X-ray imaging to examine the bones and tendons inside the snipefish’s head. She found that the fish use a latched elastic recoil mechanism — like a slingshot, or a compressed spring — to power their feeding strike.
“This mechanism behaves analogous to a slingshot, but instead of a rubber band, the fish stores energy in tendons”, Longo said. The mechanism involves a set of bones in the snipefish head and is latched in place by the specific arrangement of a small pair of hyoid bones located below the eye in the “cheek” region of the fish. With the hyoid latched, muscles behind the head put the tendon under tension. A small movement of the hyoid by a muscle releases the latch and unleashes the stored energy.
The discovery has implications for the evolution of this order of fishes, she said. Elastic recoil mechanisms are now known in three types of fish in two families in this group: seahorses, pipefish and now snipefish. That means that the mechanism may have evolved either very early in the history of the group, or evolved separately in the snipefish and the more closely related pipefish and seahorses.
Coauthors on the paper, published July 4 in the Proceedings of the Royal Society B, are Tyler Goodearly and Professor Peter Wainwright, Department of Evolution and Ecology, UC Davis College of Biological Sciences. The work was supported by graduate research fellowships from the National Science Foundation.