Nature’s first fiber optics could light the way to internet innovation

Clams called heart cockles use fiber optic–like structures to channel sunlight to symbiotic algae

A heart-shaped pink clamshell on a white background

Algae nestled within the heart cockle’s shell provides the clam with sugars and other important nutrients in exchange for fiber optic light filtration.

Ruiqi Li

In a discovery that blurs the line between biology and technology, scientists have found that heart-shaped clams use fiber optic–like structures to channel sunlight through their shells in much the same way that telecommunications company use fiber optics to deliver high-speed internet connectivity into homes.

This innovation, a first known example of bundled fiber optics in a living creature, helps to explain how heart cockles (Corculum cardissa) — a marine bivalve found in shallow waters across the Indian and Pacific Oceans — harness sunlight to nourish symbiotic algae living within, while protecting them from harmful ultraviolet rays. In return, the algae provide the clams with sugars and other essential nutrients.

The finding highlights an evolutionary adaptation that parallels human technological ingenuity, and offers potential insights for the development of bioinspired optical systems in the future, researchers report November 19 in Nature Communications.

Heart cockles are small, walnut-sized bivalves best known for their distinctive shell shape. But a close look reveals the shells are pockmarked with “windows” — minute, transparent structures that permit light to pass through.

This unique architecture is rooted in the special properties of aragonite, a crystalline form of calcium carbonate (SN:1/21/03). These aragonite crystals are arranged in micron-sized tubes that function like fiber-optic cables, guiding light with exceptional precision, while filtering out harmful ultraviolet radiation that could damage the clams’ symbiotic algae or their own delicate tissues.

A white shell with wavy transluscent patches is shown under a microscope's lens
The heart cockle’s translucent shell allows more than twice as much photosynthetically useful light to penetrate inside as it does harmful, DNA-damaging ultraviolet light.Dakota McCoy

Evolutionary biophysicist Dakota McCoy, of the University of Chicago, and her colleagues performed microscope experiments demonstrating that the sun-facing side of the shell allows more than twice as much photosynthetically useful light to penetrate inside as it does harmful, DNA-damaging ultraviolet light.

According to McCoy, this light-filtering capacity likely helps reduce the risk of bleaching, a deadly phenomenon affecting both corals and clams alike that is currently being exacerbated by climate change (SN: 8/7/24).

Computer simulations further demonstrated that the arrangement of the fiber optic–like structures represents an evolutionary trade-off, finely tuned to balance the shell’s mechanical strength with its ability to efficiently transmit light.

“Finally, somebody has actually worked this out,” says Jingchun Li, an evolutionary biologist at the University of Colorado, Boulder, who studies the symbiotic relationship between heart cockles and their algae.

The heart cockles aren’t alone in channeling sunlight to symbiotic algae. Other marine creatures, such as giant clams, do this too (SN: 6/22/18). But whereas these massive, ridged bivalves rely on specialized cells to draw in beneficial sunlight, heart cockles, with their shells shut tight, take advantage of their unique aragonite architecture.

“They’re using minerals in their shells to do this and not biological structures,” says Sarah Lemer, an evolutionary geneticist at the Leibniz Institute for the Analysis of Biodiversity Change in Hamburg, Germany, who was not involved in the study. “It’s really neat.”

McCoy and others now envision leveraging the properties of aragonite or its intricate lattice structures to create new materials with superior optical performance — potentially revolutionizing wireless communication technologies and advanced measurement tools.

One quality they hope to replicate is aragonite’s ability to channel light without reflective coatings. Such coatings are needed on telecommunications cables to confine light signals, but aragonite naturally possesses its own optical containment features.

“By mimicking the bundled fiber structures found in heart cockles, we could develop systems that offer enhanced light collection,” says Boon Ooi, a photonics researcher at the King Abdullah University of Science and Technology in Saudi Arabia.

“Billions of years of product design have gone into this,” McCoy points out. Tapping into the heart cockles’ shell design, she says, could lead to unmatched light-transmission capabilities — leaving the human end-users of these technologies as happy as clams.