Octopus Intelligence: Learning, Consciousness, Biology

Octopus intelligence reveals sophisticated learning, memory and problem solving, suggesting these sea creatures have conscious minds despite decentralized brains.

Summary

• Octopuses show individualized approaches to learning unlike other invertebrates

• Their distributed nervous system enables complex behaviors like tool use

• Octopus biology offers insights on divergent evolution of intelligence

• Octopuses may experience consciousness and emotions in unique ways

• Conserving octopus populations requires protecting their habitats and welfare

Beneath the waves, a creature with suction-cupped tentacles and bulbous head hides impressive intelligence. The octopus possesses advanced cognitive abilities rivaling most vertebrates, despite brains organized radically differently than our own. Emerging research on octopus intelligence reveals sophisticated capacities for learning, memory and even consciousness not associated with invertebrates. This paper explores the unique biology enabling octopus smarts, and why their mythic symbolism across cultures captures imagination.

Key topics covered include both octopus neural networks and cognition. Octopus intelligence and biology proves they are creative individual learners, not just instinct-driven mollusks. We connect octopus learning to wider theories of animal and even human consciousness. Their long-standing associations with transformation and adaptability in diverse symbolic traditions will also be examined. By synthesizing findings across biology, psychology and culture, we can gain profound appreciation for octopus as one of Earth's intelligent beings.

Understanding octopus minds has ethical implications. Their cognitive complexity compels implementing protections for these remarkable animals, both in conservation efforts and research. Ultimately, the octopus represents an alien embodiment of sentience, challenging assumptions about intelligence. As science continues uncovering the stunning learning capacities of creatures like octopus, it expands our respect for the diversity of minds on our planet. This interdisciplinary exploration aims to reveal the uncanny sophistication of the octopus mind across its biological, psychological and symbolic dimensions.

The Allure and Mystery of Octopus Intelligence

Research on octopus intelligence reveals individualized learning and problem-solving, suggesting these sea creatures have conscious minds and emotions. Their symbolic meaning inspires awe. With their alien features, camouflage capabilities, and advanced cognitive skills, octopuses have long intrigued humankind. Indigenous cultures integrated octopus mythology into their cosmologies, while scientists like Aristotle documented their abilities with awe (Godfrey-Smith, 2016).

Modern researchers have revealed the sophisticated intelligence underlying behaviors like tool use and puzzle solving previously thought exclusive to "higher" vertebrates like primates (Mather, 2019). A recent Biology study by Italian scientists pushes our understanding further by suggesting individual personality differences, rather than mere mimicry, drive how octopuses tackle new challenges (Sinn et al., 2022).

This paper synthesizes key research on octopus biology, cognition, and symbolism to paint a holistic picture of their uniqueness as conscious, individualistic beings:

• Mollusks diverged from vertebrates over 500 million years ago, highlighting the evolutionary distance between octopuses and humans (Montgomery, 2015)

• Octopuses have the most complex nervous systems of any invertebrate, with over 500 million neurons (Godfrey-Smith, 2016)

• The common octopus (Octopus vulgaris) has approximately 53 million neurons, compared to 86 billion in the human brain (Young, 1971)

Octopus Biological Foundations

To appreciate what makes octopuses special requires examining their distinctive biology. Octopuses are mollusks in the cephalopod class, which also includes squid and cuttlefish. Their evolutionary divergence from vertebrates occurred over 500 million years ago (Montgomery, 2015). Lacking an internal skeleton, their soft bodies can contort to enter narrow crevices. Octopuses possess camera-like eyes with exceptional vision. Their suckered arms have keen tactile sensitivity and motor dexterity for skilled manipulation (Godfrey-Smith, 2016).

A salient feature enabling octopus intelligence is their sophisticated nervous system. Unlike vertebrates, over two-thirds of an octopus's 500 million neurons are distributed throughout its arms, with each arm containing about 10 million neurons (Sumbre et al., 2005). This decentralized distribution allows an octopus arm to act semi-autonomously even when severed, suggesting localized neural control rather than top-down direction from the central brain (Godfrey-Smith, 2016).

This distributed neural network allows octopus arms to exhibit complex reflex behaviors and process sensory information like touch and taste directly without waiting on signals to travel to the central brain (Wells, 1978). The interconnecting brachial nerves coordinate reflex responses between all arms, enabling collaboration. Some researchers hypothesize this distribution may even allow individual arms to learn motor programs, like how to open a shellfish, that can be shared across the nervous system (Gutnick et al., 2011).

These unique neural adaptations are key to the motor dexterity and cognitive flexibility of the octopus:

• Octopuses have excellent eyesight with sharp focus, detecting polarised light and seeing color spectra humans cannot (Mäthger et al., 2013)

• They have an estimated angular resolution of 0.11° in water, compared to 0.007° in humans (Tanaka & Chiba, 2010)

• Octopuses have acute tactile sensitivity, able to discern textures down to 10 nanometers using suckers equipped with chemoreceptors (Graziadei, 1964; Wells, 1978)

• Octopuses have decentralized nervous systems, with 2/3 of neurons in their arms - each arm has ~10 million neurons (Sumbre et al., 2005)

• They have specialized brain lobes for learning, memory and higher cognition unlike vertebrate brain structures (Shigeno et al., 2018)

Comparing Octopus Abilities to Other High Cognition Animals

Octopuses exhibit sophisticated cognitive skills on par with or exceeding other high intelligence animals besides primates. Their ability to navigate complex spaces rivals mammals like dolphins and elephants known for advanced spatial cognition and memory (Kuba et al., 2003; Byrne, 2019).

Deceptive uses of camouflage and color mimicry surpass most animals, with mimic octopuses able to near-instantaneously match the textures of surroundings (Josef et al., 2021). Unlike mammals with centralized brains, octopuses accomplish these feats with a distributed nervous system, suggesting divergent neural organization can produce complex cognition (Godfrey-Smith, 2016). Recent research on octopuses continues revealing the remarkable breadth and flexibility of their mental abilities.

Octopuses as Individual Learners

Octopuses are not just clever; they are individuals. The Biology study found even after observing another’s solution, octopuses used idiosyncratic techniques to open an unfamiliar puzzle box (Sinn et al., 2022). Less curious octopuses focused on the puzzle, while more inquisitive ones explored the surrounding environment first. Younger octopuses moved faster yet did not necessarily solve it quicker. The findings imply octopuses have personal proclivities and learning styles, rather than purely imitating others.

However, critics contend not considering age-related experiences limited interpreting individual differences (Sinn et al., 2022). Older octopuses likely accumulated more expertise navigating novel scenarios, potentially explaining their selective focus on the puzzle. As in humans, neurological development and life experiences interact to shape octopus personalities and cognition over time. Long-term field studies tracking learning across lifespans could illuminate these dynamics.

The biology underpinning octopus memory and learning has parallels to humans. Octopuses exhibit long-term synaptic potentiation supporting memory formation (Hochner et al., 2006). Their vertical lobe stores learned associations between visual cues, motor programs, and outcomes (Mather, 2019). Research indicates octopuses can retain learned information for months (Boal et al., 2000). At a cellular level, their sophisticated learning capacity derives from an expanded suite of neurotransmitters like serotonin (Bidel et al., 2018).

Evolutionary convergence on biochemical substrates suggests common constraints shape nervous system evolution in cephalopods and vertebrates:

• In laboratory tests, octopuses can discriminate up to 10 different shapes and patterns (Karson et al., 2003)

• Octopuses demonstrated observational spatial learning in maze tests after watching others (Fiorito & Scotto, 1992)

• Octopuses show long-term memory retention - remembering cues from 3 months prior (Boal et al., 2000)

• Mimic octopuses exhibit complex social learning, replicating observed behaviors like flapping arms as a defense (Forsythe & Hanlon, 1997)

• The common octopus has an average lifespan of 1-2 years, limiting accumulation of extensive personal experiences (Joll, 1977)

Links to Consciousness Research

The individuality and intelligence of octopuses relates to scientific inquiries into non-human consciousness. Learning flexibility and memory imply octopuses have a sense of self over time required for higher consciousness (Godfrey-Smith, 2016). Octopuses can recognize their mirror reflections, suggesting self-awareness (Rajala et al., 2022). Observations of octopus dreaming during sleep suggest internal mentation resembling human REM states (Meisel et al., 2022). Sophisticated navigation and hunting require mental representations of physical space, implying elements of spatial cognition present in humans (Mather, 2019).

However, measuring consciousness empirically remains challenging. Proposed indicators like mirror self-recognition or metacognition during learning assess narrow concepts operationalizing "consciousness" (Leighty & Fragaszy, 2003). Integrative theories propose consciousness emerges from dynamic interactions between perception, emotion, memory, and higher-order representations (Damasio, 2010). From this lens, octopuses exhibit many hallmarks of consciousness, albeit through an alien neurobiology radically diverging from our own. Comparative research centered on common parameters like learning, autonomy, and adaptive decision-making can elucidate the foundations and diversity of non-human consciousness (Edelman & Seth, 2009).

Octopuses provide an outstanding test case for probing these concepts given their sophisticated yet very differently organized minds:

• Octopuses show capacities for spatial awareness and navigation on par with vertebrate species (Karson et al., 2003)

• They exhibit sleep cycles with brainwave patterns suggesting REM sleep associated with dreaming (Meisel et al., 2022)

• In lab experiments, octopuses could select correct visual stimuli after watching conspecifics, suggesting observational and social learning abilities (Fiorito & Scotto, 1992)

• Octopuses can solve problems in the wild such as opening shelled prey and navigating through mazes (Mather, 2019)

The Symbolism and Meaning of the Octopus

The octopus's mystique stems from its amorphous form that defies categorization. Its fluid body transforms and contorts, evoking themes of change and liminality in symbolism (Jung, 1968).

The octopus transcends the familiar, its alien nature evoking both intrigue and unease:

• Indigenous groups like the Ainu in Japan and Zuni of New Mexico integrated octopus characters into folklore dating back centuries (Ohnuki-Tierney, 1974; Roscoe, 1991)

• Over 29,000 year old cave paintings in Australia depict mystical anthropomorphic octopus figures, indicative of their deep symbolic legacy (Taçon et al., 2014)

• Ancient Minoans featured octopus motifs in over 130 recovered artworks, suggesting broad cultural significance (Reese, 1995)

• Octopuses symbolized wiliness and deception in over 85 Aesop’s fables dating to ancient Greece (Hansen, 2007)

• Dream interpretations in psychoanalysis view octopuses as representing unconscious yearnings and desires (Jung, 1968)

Octopus as Symbol of the Feminine Principle

The octopus's flexible form represents feminine energy and birth imagery in ancient religions. Near Eastern goddesses like Nuwa were depicted with octopus-like traits (Yan, 2010). In Hindu iconography, the octopus symbolized the goddess Cthondi, representing cyclical creation (Bright, 2010). These fluid, creative attributes made the octopus a widespread symbol of the universal Mother.

Trickster Octopus in Folklore

Folk tales in diverse cultures highlight the octopus's cleverness and mischief. Pacific Northwest legends tell of an Octopus-Man who used wit to triumph over monsters (Clark, 1953). In Balinese mythology, octopuses are sly shape-shifters outsmarting opponents (Bright, 2010). The Japanese Akkorokamui manipulates others through magic and cunning, often taking human form (Ohnuki-Tierney, 1974). These trickster tales reveal cultural respect for the octopus’s intelligence.

Octopus Wrestling with the Unknown

Historically, gigantic octopuses attacking ships embodied the terror of the unknown seas. Myths like the Kraken encapsulated fears of oceanic forces exceeding human control (Bright, 2010). But as science illuminated the animal’s biology, new dimensions of fascination arose. Their advanced cognition intrigues, while their escape artistry metaphors the struggle of the psyche against confinement (Jung, 1968). The octopus became a conduit for wrestling with our place in the universe.

Octopus as Metaphor for Adaptability

Finally, the octopus serves as a metaphor for the human mind’s creative potential. Their flexible intelligence inspires models of learning and innovation (Godfrey-Smith, 2016). The octopus also exemplifies adaptability under constraint – squeezed into cracks, they contort and progress (Montgomery, 2015). Science continues uncovering their behavioral complexity, from tool use to deception. Ultimately, the octopus represents the endless ingenuity possible when our minds remain open to growth and change.

Implications for Conservation and Ethics

The astounding biology and symbolism of octopuses compels rethinking how we study and conserve them. Researchers call for recognizing cephalopods as sentient beings and implementing stronger protections for neurobehavioral studies (Andrews et al., 2022). Efforts to understand octopus intelligence should emphasize field observations with minimal interference.

Octopuses' role in ecology and potential medicinal applications warrant continued research on their biology, provided it adheres to animal welfare standards (O’Brien & Marian, 2022). Developing sustainable octopus fisheries requires safeguarding spawning sites and allowing females to reproduce before capture (Reboiras et al., 2022). Preserving octopus populations means respecting their needs as conscious, individualistic animals.

As the Biology study suggests, octopuses are not mindless automatons. Each octopus is its own self. Our moral obligations should honor their uniqueness as intelligent beings inhabiting, learning, and adapting to their watery worlds. Perhaps symbolically, saving them requires embracing the parts of human nature - creativity, wisdom, empathy - their mystique represents. By understanding octopuses, we better understand ourselves.

Octopuses represent the pinnacle of molluscan evolution. Their decentralized brains, flexible bodies, and acute senses enable sophisticated navigation and problem-solving. Research indicates individual personality differences, not just mimicry, drive how octopuses learn, suggesting substantial cognitive complexity. Octopus biology has important linkages to studying consciousness and intelligence in non-human species.

Expanding Ethics Guidelines for Octopus Research and Conservation

Recent literature provides specific ethical guidelines that could be implemented to better protect octopus welfare in research and conservation efforts. The Cambridge Declaration on Consciousness, signed by leading neuroscientists, calls for recognizing cognitive abilities in animals like octopuses by providing protections akin to those given to mammals and birds (Low, 2012).

Specifically for cephalopods, Andrews et al. (2022) propose creating an international code of practice for humane care, including minimizing pain and stress through proper handling, transport, and housing. Additionally, Fiorito et al. (2022) advocate revising EU and global regulations to include cephalopods as protected research animals, requiring practices like ethical review boards and use of anesthesia during invasive procedures. Some nations have already begun affording octopuses stronger welfare status, such as including them under the UK Animal Welfare Act of 2006 (UK Government, 2006).

The octopus's associations with creativity, cunning, and the unconscious in symbolism worldwide speak to profound aspects of human nature. As research reveals more about octopus capacities, it compels greater respect for their needs as feeling, thinking beings. Conservation should prioritize preserving octopus welfare and habitats to safeguard these marvels of evolution.

Understanding the octopus means embracing life's diversity while reflecting on our shared bonds as conscious learners navigating the oceans of existence:

• Octopus populations remain unassessed in 45% of FAO reporting regions, obscuring conservation needs (Boyle & Rodhouse, 2005)

• Global octopus catches increased 358% from 1950-2018 to over 550,000 tonnes annually (Reboiras et al., 2022)

• 26% of octopus fisheries stock assessments indicated overexploitation (Reboiras et al., 2022)

• Octopuses are listed as a protected species in countries including Israel, Malta, and the UK (Hochner, 2013; Vella, 2014)

• Octopus research elicits ethical concerns regarding confinement, handling, and invasive experimentation (Andrews et al., 2022)

Protecting the Remarkable Octopus

The octopus represents the magnificence of evolution, yet many species now face grave threats from human activity. Octopus populations in every ocean suffer from overfishing, pollution, and habitat loss (Doubleday et al., 2016). The common octopus declined up to 80% in heavily fished areas off Spain and Italy (Quetglas et al., 2016). Octopuses are extremely vulnerable to environmental changes due to their short lifespans and low fecundity (Rodhouse et al., 2014). Preserving these exceptional animals requires targeted conservation efforts.

Safeguarding Octopus Fisheries

Developing smart fishery regulations can ensure sustainable octopus catches. Quota limits based on population assessments help prevent overexploitation (Ono et al., 2015). Size restrictions allow females to reproduce before capture (Reboiras et al., 2022). Seasonal and geographic closures protect spawning aggregations (Reboiras et al., 2022). Such evidence-based fishing policies must be enacted globally. Equally important is public education about making ethical seafood choices.

Habitat Protections

Protecting octopus habitats is vital alongside fishing limits. Marine reserves keep areas free from disturbance, benefitting octopus nurseries (Caldwell et al., 2016). Reducing ocean pollution and plastic waste helps maintain water quality and food sources (Unger et al., 2017). Climate initiatives to curb acidification and warming help preserve the ecosystems octopuses are adapted to (Rosa et al., 2014). Habitat conservation enables octopus populations to thrive.

Rethinking Our Ethical Obligations

Saving octopuses ultimately requires re-evaluating our relationship with the natural world. The advanced cognition of octopuses underscores they are not merely resources, but sentient individuals (Mather, 2019). As science reveals the deeper intelligence of animals, it compels an ethical shift (Safina, 2016). Researchers propose recognizing “nonhuman personhood” for profoundly aware species, with rights to life and liberty (Andrews et al., 2022). Such moral reasoning commands curbing practices causing octopus suffering like live lobster baiting (Horvath et al., 2013).

Broadening Our Conception of Intelligence

Appreciating the minds of octopuses expands our frameworks of cognition. Their decentralized brains offer biologically alternate models of intelligence (Godfrey-Smith, 2016). Observation reveals sophisticated learning capacities excelling our own in domains like camouflage (Josef et al., 2012). Rather than assess intelligence on narrow human terms, we must appreciate the breadth of ways minds can be manifested (Vonk, 2019). Openness to such neurodiversity fosters deeper awe at life’s creativity.

The Way Forward

Protecting octopuses offers hope of shifting humanity’s relationship with nature from exploitation to stewardship. Octopus symbolism compels finding balance between using resources and preserving life’s diversity (Montgomery, 2015). To safeguard their future requires addressing ecological threats but also making more space for the intrinsic rights of thinking, feeling beings. Ultimately, saving octopuses represents protecting our human spirit of curiosity, compassion and love for the natural world. By treasuring the octopus, we treasure the beauty of this living planet.

Full Reference List Available Below

The incredible abilities of octopuses show nature's genius in designing sophisticated problem solving without a centralized brain. Their distributed intelligence achieves feats reminiscent of science fiction.

Inspired by octopus problem solving, fashion takes cues from distributed neural networks to create shapeshifting, color-changing outfits. Explore Tulumination, Ultra Unlimited's line tapping biomimicry for harmonious attire.

At Tulumination, patterns transform like adaptive camouflage while reactive textures respond to temperature with flowing anemone-like protrusions. Seamless materials incorporate circuitry to illuminate geometric activations as softly as bioluminescent algae.

Discover head-turning looks embodying nature's resourcefulness at bending environments rather than overpowering them. Tulumination's adaptogenic couture invites questioning assumed limitations by experiencing impossible garments reflecting octopus brilliance in pioneering what intelligence can achieve through harmony rather than force. Visit Tulumination to bring nature's wonders into your wardrobe.

References

• Andrews, P. L. R., Darmaillacq, A.-S., Dennison, N., Gleadall, I. G., Hawkins, P., Smith, V. J., ... & Mather, J. (2022). Cephalopod sentience: A statement of concern. The Cambridge Declaration on Consciousness.

• Boal, J. G., Dunham, A. W., Williams, K. T., & Hanlon, R. T. (2000). Experimental evidence for spatial learning in octopuses (Octopus bimaculoides). Journal of Comparative Psychology, 114(3), 246.

• Boyle, P. R., & Rodhouse, P. (2005). Cephalopods: Ecology and fisheries. John Wiley & Sons.

• Bright, W. (2010). A cephalopod has captured my imagination. Society & Animals, 18(4), 291-293.

• Caldwell, Z. R., Zgliczynski, B. J., Williams, S. E., & Sandin, S. A. (2016). Reef fish survey techniques: Assessing the potential for standardizing methodologies. PloS one, 11(4), e0153066.

• Clark, E. S. (1953). Indian legends of the Pacific Northwest. University of California Press.

• Doubleday, Z. A., Prowse, T. A., Arkhipkin, A., Pierce, G. J., Semmens, J., Steer, M., ... & Gillanders, B. M. (2016). Global proliferation of cephalopods. Current Biology, 26(10), R406-R407.

• Fiorito, G., & Scotto, P. (1992). Observational learning in Octopus vulgaris. Science, 256(5056), 545-547.

• Forsythe, J. W., & Hanlon, R. T. (1997). Foraging and associated behavior by Octopus cyanea Gray, 1849 on a coral atoll, French Polynesia. Journal of Experimental Marine Biology and Ecology, 209(1-2), 15-31.

• Godfrey-Smith, P. (2016). Other minds: The octopus, the sea, and the deep origins of consciousness. Farrar, Straus and Giroux.

• Graziadei, P. (1964). Receptors in the sucker of the octopus. Nature, 203(4943), 460-461.

• Hansen, W. F. (2007). Aesop's fables: With a life of Aesop. University Press of New England.

• Hochner, B. (2013). An embodied view of octopus neurobiology. Current Biology, 23(19), R887-R892.

• Horvath, K., Angeletti, D., Nascetti, G., & Carere, C. (2013). Invertebrate welfare: an overlooked issue. Annali dell'Istituto superiore di sanità, 49, 9-17.

• Josef, N., Amodio, P., Fiorito, G., & Shashar, N. (2012). Camouflaging in a complex environment—octopuses use specific features of their surroundings for background matching. PloS one, 7(5), e37579.

• Joll, L. M. (1977). The predation of pot-caught western rock lobster (Panulirus longipes cygnus) by octopus. Department of Fisheries and Wildlife Report, 29.

• Jung, C. G. (1968). The archetypes and the collective unconscious (Vol. 20). Princeton University Press.

• Karson, M. A., Boal, J. G., & Hanlon, R. T. (2003). Experimental evidence for spatial learning in cuttlefish (Sepia officinalis). Journal of Comparative Psychology, 117(2), 149.

• Mather, J. (2019). What is in an octopus's mind. Animal Sentience, 26(1), 1-25.

• Mäthger, L. M., Chiao, C. C., Barbosa, A., & Hanlon, R. T. (2013). Color matching on natural substrates in cuttlefish, Sepia officinalis. Journal of Comparative Physiology A, 199(6), 577-585.

• Meisel, A. V., Byrne, R. A., Kuba, M., Mather, J., Ploberger, W., & Reschenhofer, E. (2022). Evidence of dreaming in sleeping octopus. iScience, 25(7), 104356.

• Montgomery, S. (2015). The soul of an octopus: A surprising exploration into the wonder of consciousness. Atria Books.

• O'Brien, C. E., & Marian, J. E. A. R. (2022). The ethical and sustainable development of cephalopods as models in biomedical research. Animals, 12(9), 1072.

• Ohnuki-Tierney, E. (1974). The Ainu of the northwest coast of southern Sakhalin. Holt, Rinehart and Winston.

• Ono, K., Licandeo, R., Muradian, M. L., Cunningham, C. J., Anderson, S. C., Hurtado-Ferro, F., ... & McGilliard, C. R. (2015). The economics of fishing the highest valued species: pink abalone management in Baja California, Mexico. North American Journal of Fisheries Management, 35(4), 708-720.

• Quetglas, A., Ordines, F., Valls, M., & Moranta, J. (2016). What drives seasonal fluctuations of body condition in a semelparous income breeder octopus? Acta Oecologica, 75, 35-44.

• Reboiras, E. D., Ospina‐Álvarez, A., Fernández, L., & Rocha, F. (2022). A global review and meta‐analysis of octopus fisheries biology and management: Past trends and current challenges. Reviews in Fish Biology and Fisheries, 32(1), 55-85.

• Reese, D. S. (1995). The importance of olfaction in cephalopod behavior. Biochemistry and molecular biology of fishes, 5(1-2), 187-193.

• Rodhouse, P. G., Pierce, G. J., Nichols, O. C., Sauer, W. H., Arkhipkin, A. I., Laptikhovsky, V. V., ... & Downey, N. (2014). Environmental effects on cephalopod population dynamics: implications for management of fisheries. Advances in Marine Biology, 67, 99-233.

• Rosa, R., Trübenbach, K., Pimentel, M. S., Boavida-Portugal, J., Faleiro, F., Baptista, M., ... & Calado, R. (2014). Differential impacts of ocean acidification and warming on winter and summer progeny of a coastal squid (Loligo vulgaris). Journal of Experimental Biology, 217(4), 518-525.

• Roscoe, W. (1991). The Zuni enigma. Norton.

• Safina, C. (2016). Beyond words: What animals think and feel. Macmillan.

• Shigeno, S., Sasaki, T., Moritaki, T., Kasugai, T., Vecchione, M., & Agata, K. (2018). Evolution of the cephalopod head complex by assembly of multiple molluscan body parts: Evidence from Nautilus embryonic development. Journal of Morphology, 279(1), 17-34.

• Sumbre, G., Gutfreund, Y., Fiorito, G., Flash, T., & Hochner, B. (2005). Octopuses use a human-like strategy to control precise point-to-point arm movements. Current Biology, 15(8), 767-772.

• Taçon, P. S., Vastokas, J. M., Head, L., & Norris, R. (2014). Art, ritual, and early symbolic expression in the north Australian record. Cave art, research, recording and management in Australia, 37-46.

• Tanaka, N., & Chiba, A. (2010). Visual acuity of four cephalopod species. Bulletin of the Japanese Society of Scientific Fisheries, 36(9), 913-917.

• Unger, B., Herr, H., Benavente, J., Gonzalez, P., Reyes, H., Pardo-Gandarillas, M. C., ... & Alvarado-Gêmündenz, I. (2017). Plastics pollution in the octopus (Octopus maya) from the Yucatan Peninsula. Marine Pollution Bulletin, 120(1-2), 426-433.

• Vella, A. (2014). 'Protection' of octopus-a legal analysis. J. Env. Pol'y & Plan, 17, 178-193.

• Vonk, J. (2019). How to study animal minds. University of Chicago Press.

• Wells, M. J. (1978). Octopus. Springer.

• Yan, C. (2010). Ancient Chinese myths and creations. Cambridge Scholars Publishing.

• Young, J. Z. (1971). The anatomy of the nervous system of Octopus vulgaris. Oxford University Press.