Octopus arms decoded: New research unveils neural secrets

The latest research, led by a team led by Robyn Crook from San Francisco State University, sheds new light on the structure of octopus arms, which some consider to be the Earth's closest alien-like form of life.

The results of this research, published as two separate scientific papers, provide a fuller understanding of how octopuses control their movements and respond to stimuli.

- The fact that both studies appeared at the same time means the amount of knowledge we can gain from a single experiment has increased astronomically. These publications truly open up new possibilities for discovery, - emphasizes Crook.

Watching a hunting octopus is like watching flowing ink moving with a clear intent. The muscles of the octopus's arms, lacking bone support, are capable of complex movements: twisting, stretching, and precise grabbing. This combination of strength and dexterity distinguishes octopuses from other marine creatures.

Previous research revealed how oblique and longitudinal muscles collaborate and how millions of neurons organized in clusters, known as ganglia, allow each arm to operate almost independently – like a specialized military unit capable of individual problem-solving while remaining loyal to a common goal.

Crook and her team decided to take a closer look at the nervous system of octopuses, focusing on a detailed analysis of the arms of the dwarf octopus Bock (Octopus bocki). The research focused on the classification and distribution of nerves running the entire arm length, from the tip to the base.

The first study, led by neurobiologist Gabrielle C. Winters-Bostwick, used DNA technology to label and identify different types of nerve cells. Using an advanced microscope, the team created high-resolution images that allowed them to create a three-dimensional map of the distribution of specific types of nerve cells in the arms.

The study revealed a diversity of nerve cell populations in different parts of the arm, opening up new possibilities for understanding their function.

- This allows us to start formulating hypotheses and asking new questions about how cells communicate with each other, - says Winters-Bostwick.

Crook and her team's research findings could significantly contribute to the development of knowledge about the complexity of the octopus nervous system. The development of research methods, such as three-dimensional imaging, allows for a better understanding of how these incredibly complex and intelligent animals move and respond to their environment. As science delves deeper into the mysteries of octopuses, we gain not only insight into their remarkable biology but also new tools for neurobiological analysis, which can benefit other fields as well.

Innovative discoveries, such as those made in Crook’s laboratory, point to the enormous potential of further research on cephalopods, opening new perspectives not only in marine biology but also in neuroscience.