Ancient worm fossil shows early preference for right turns

A 555-million-year-old worm-like creature displayed a bias toward turning right, according to a new analysis of fossils from South Australia. The finding offers the earliest known evidence of handedness in animals.

Researchers examined 100 specimens of Spriggina floundersi, a small flatworm that lived on the seafloor during the Ediacaran Period. Scott Evans of the American Museum of Natural History led the study, which found that twice as many fossils were bent in a way indicating the animals turned right rather than left.

Evans noted that the pattern is statistically significant and aligns with observations of handedness in modern animals. Some specimens showed bends in both directions, suggesting the creatures could move freely without circling.

The discovery indicates that aspects of advanced nervous systems, such as favouring one side of the body, emerged before the Cambrian Period. Russell Bicknell of Flinders University said the presence of such functional asymmetry deep in the fossil record provides key insights into the evolution of these behaviours.

Related Articles

Photorealistic illustration of invasive flatworms including the Asian hammerhead worm discovered in Sweden.
Image generated by AI

Two invasive flatworms discovered in Sweden

Reported by AI Image generated by AI

Two new species of invasive flatworms have been discovered in Sweden, according to the Swedish Museum of Natural History. One is the Asian hammerhead worm that can grow up to 40 centimeters long.

Researchers at the University of Oxford have found that upright walking and larger brains likely drove the strong right-hand preference seen in modern humans. The findings come from an analysis of primate species and extinct hominins.

Reported by AI

Newly examined fossils indicate that the earliest four-limbed vertebrates developed directly into adults without a larval phase featuring external gills.

Researchers at Dartmouth have shown that octopuses can learn to use mirrors to find food they cannot see directly. The study, published in Current Biology, marks the first time this ability has been documented in invertebrates.

Reported by AI

A new evolutionary analysis has shown that skin bones in reptiles developed independently across multiple lizard lineages rather than from a single ancestor. Researchers traced the trait over 320 million years using fossils and computational methods. Australian goannas stand out for losing the armor and then regaining it millions of years later.

This website uses cookies

We use cookies for analytics to improve our site. Read our privacy policy for more information.
Decline