Rice-sized baby mantis shrimp throw a powerful punch

Tiny and transparent mantis shrimp larvae provide insights into the mechanisms behind ultra-fast movements. Researchers can see muscles contract to slightly deform the exoskeleton and lock the arm in striking position. (Credit: Jacob Harrison)

Even when they are smaller than a short grain of rice, larvae of the Philippine mantis shrimp display ultra-fast movements, according to a new study.

Their ultra-fast punching appendages measure less than 1 millimeter (0.039 inches), and develop right when the larva exhausts its yolk reserves, moves away from its nest, and out into the big wide sea. It immediately begins preying on organisms smaller than a grain of sand.

Although they accelerate their arms almost 100 times faster than a Formula One car, Philippine mantis shrimp (Gonodactylaceus falcatus) larvae are slower than larger adults, which goes against the theoretical expectation that smaller is always faster.

“They’re producing amazing speeds and impressive accelerations relative to their body size, but they’re not as fast as adults,” says lead author Jacob Harrison, a PhD candidate in biology at Duke University.

Mantis shrimps achieve their ultra-fast movements through a tiny spring-actuated mechanism hidden in their punching appendage. A muscle contracts, deforming a tiny segment of their exoskeleton—the rigid cuticle that covers their body. This contraction allows elastic energy to be stored in the locked joint. Once the latch releases, the exoskeleton springs back into its natural position, violently propelling the appendage forward with ultra-fast speeds.

Engineering and physics models predict that smaller organisms, who have a smaller mass to displace, will be faster than larger, heavier, organisms. Mantis shrimp larvae show that biology doesn’t always follow the theory.

“Theoretically, they should be producing the highest acceleration,” says Harrison, “but we don’t find that.”

This discrepancy may be due to multiple factors, Harrison says. The larvae muscles may be too small to effectively load a very stiff spring, or the water resistance at their small size may be too high for their punches to reach the speed that larger individuals reach, among other possibilities.

“There are limitations to these spring and latch structures that we don’t fully understand,” says Harrison. “But whenever biology moves away from theoretical models it highlights some pretty interesting areas for us to learn.”

Mantis shrimp larvae are an interesting system not only due to their small size, but also due to their color, or lack thereof.

Adult mantis shrimps have opaque exoskeletons, rendering the inner working of their spring-latch mechanisms impossible to observe in action. The exoskeleton of larvae, however, is much thinner and fully transparent, allowing researchers to see precisely how these animals manage to store so much elastic energy in their tiny appendages simply by watching them through a microscope.

“One of the trickiest parts of researching spring-actuated mechanisms is that a lot of those elements are working inside the animal. We can look outside of the animal and see the behavior, measure the kinematics, dissect the animal, and say the mechanism looks like it works like this, but there are always levels of assumption,” says Harrison.

“(Transparency) sets up larval mantis shrimps as systems where we can look at how each of these elements work in concert together,” says Harrison. “It removes assumptions and allows us to understand it on a finer scale.”

Larval mantis shrimps are therefore doubly interesting. They highlight discrepancies between physics and biology, and also offer a true window into a better understanding of the mechanism behind ultra-fast movements.

“When something doesn’t match your predictions, the first gut reaction is always to be incredibly frustrated, but this is actually what highlights new areas of research,” says Harrison.

The study appears in the Journal of Experimental Biology. The Company of Biologists Traveling Fellowship, the National Science Foundation, the Office of Naval Research, and the University of Hawai’i at Mānoa funded the work. This material is based upon work supported by, or in part by, the US Army Research Laboratory and the US Army Research Office.

Source: Marie Claire Chelini for Duke University