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Octopodidae

Octopodidae is a family of mollusks within the order and suborder Incirrina, encompassing the majority of known —approximately 175 to 200 in total across 23 genera and 5 subfamilies. These benthic are distinguished by their eight flexible arms equipped with one or two rows of suckers lacking chitinous rings, a soft, muscular to gelatinous body without an internal shell, and a prominent head housing large eyes and a powerful beak. Members of Octopodidae inhabit diverse marine environments worldwide, primarily coastal and continental shelf waters from the to depths exceeding 200 meters, favoring rocky, sandy, or muddy substrates where they construct dens for shelter. Their bodies feature advanced chromatophores and papillae in the skin, enabling remarkable and rapid color changes for predation and evasion, while their consists mainly of crustaceans, fishes, and other mollusks captured using and arm dexterity. Notable for high relative to other , including problem-solving abilities and complex learning, octopodids exhibit semelparous , with females guarding eggs until hatching before dying, and lifespans typically ranging from 6 months to 5 years depending on and conditions. The family holds significant ecological and economic importance, serving as both predators and prey in marine food webs, and supporting global fisheries with annual landings around 378,000 tonnes as of 2020. Taxonomic challenges persist due to morphological similarities and cryptic species, but molecular studies continue to refine classifications, highlighting the family's evolutionary since the period of the .

Taxonomy and classification

Etymology and history

The name Octopodidae derives from the oktṓpous (ὀκτώπους), meaning "eight-footed," in reference to the eight arms characteristic of its member species. The family was formally established by French naturalist Alcide d'Orbigny in 1839, with Octopus vulgaris designated as the , marking the initial taxonomic recognition of this group within the order Octopoda. In the 19th century, early classifications encompassed incirrate octopods—lacking cirri on their arms—under broader cephalopod groupings, with Octopodidae serving as a foundational category for benthic forms like the common octopus. Throughout the 20th century, significant revisions refined this framework, notably separating the pelagic Argonautidae (including paper nautiluses) from Octopodidae based on morphological distinctions such as shell secretion and habitat adaptations, as detailed in cladistic analyses that highlighted their distinct evolutionary trajectories. Post-2020 genomic advancements have provided new insights into the family's phylogenetic status; for instance, a 2023 genome skimming study using mitochondrial and markers suggested that Octopodidae may not be strictly monophyletic within , with conflicting placements of Argonautoidea as either its (mitochondrial data) or sister to all other incirrates ( data), resolving prior uncertainties about its boundaries with related superfamilies like Argonautoidea. Key contributions include the comprehensive 2014 taxonomic review by , , and Hochberg, which synthesized morphological and distributional data for over 200 species, and the 2024 description of Bolcaoctopus pesciaraensis, the earliest fossil assigned to Octopodidae, integrating paleontological evidence to extend the family's record into the Eocene.

Phylogenetic position

Octopodidae is classified hierarchically within the kingdom Animalia, phylum Mollusca, class Cephalopoda, order Octopoda, suborder Incirrina, superfamily Octopodoidea, and family Octopodidae. The temporal range of the family spans from the Cenomanian stage of the Late Cretaceous period, approximately 100 million years ago, to the present day. Recent phylogenetic analyses using genome skimming of mitochondrial and nuclear genes have clarified relationships within Octopoda, positioning Octopodidae as part of the diverse incirrate octopods, primarily benthic forms. These studies indicate that Octopodidae may not be strictly monophyletic, with mitochondrial data recovering Argonautoidea as its sister group (bootstrap support 97, posterior probability 1), potentially rendering the family paraphyletic, while nuclear rRNA analyses place Argonautoidea as sister to all other incirrates (bootstrap support 100, posterior probability 1). Within Octopodoidea, Octopodidae clusters with families such as Amphitretidae, Megaleledonidae, and Bathypolypodidae in a well-supported clade based on nuclear data. Major divergences within Octopoda, including lineages leading to Octopodidae, occurred during the Mesozoic era, with significant radiations around the Cretaceous-Paleogene boundary. The fossil record integrates with molecular evidence to support the evolutionary history of Octopodidae, with early representatives known from Lagerstätten. For instance, the genus Styletoctopus, including the species S. annae, is documented from Upper deposits in , preserving soft-tissue features like arms and an that confirm its placement within Octopodidae. The first recognized octopod, Bolcaoctopus pesciaraensis, from lower Eocene (Ypresian) strata in Italy's Monte Bolca locality, exhibits elongated arms and body wrinkles diagnostic of the family, indicating post-Cretaceous-Paleogene extinction radiation and diversification among incirrate octopods.

Genera and species

The Octopodidae family comprises approximately 175 species distributed across 23 genera, representing the majority of known octopus diversity worldwide. This tally includes several commercially significant species, such as , which supports major fisheries in temperate and tropical waters. The family exhibits substantial taxonomic complexity, with ongoing revisions reflecting molecular and morphological studies. Among the recognized genera, is the largest, encompassing over 100 of common octopuses noted for their adaptability and widespread distribution. Amphioctopus includes about 11 , such as the shortarm octopus (A. marginatus), characterized by their small size and proficiency in camouflage within sandy substrates. Tremoctopus, with four like the (T. violaceus), displays extreme , where females develop expansive dorsal and lateral webs for prey capture and defense, while dwarf males lack these structures and measure mere centimeters in length. Hapalochlaena consists of four highly venomous , including the (H. lunulata), distinguished by their iridescent blue rings that signal toxicity. Several undescribed species within Octopodidae have been documented, particularly in the , where at least 50 such forms are recognized based on morphological and genetic evidence. Notable examples include the white V octopus (Abdopus sp.), a long-armed form observed in and Philippine waters, potentially allied with Thaumoctopus but awaiting formal description. Ongoing discoveries in this region highlight the family's underestimated diversity, driven by deep-sea and reef explorations. Recent additions include three new species in the genus Callistoctopus described in 2024 from the : C. paucilamellus, C. sparsus, and C. gracilis.

Physical characteristics

Morphology

Octopodidae are soft-bodied, bilaterally symmetrical cephalopods lacking an external or fins, with a prominent head region and a muscular that encloses the visceral mass and forms the mantle cavity for and . The body is supported by eight flexible that operate as muscular hydrostats, devoid of a rigid and controlled by intricate patterns of longitudinal, transverse, and oblique muscles, allowing for versatile and . These bear one or two rows of suckers along their entire , with up to several hundred suckers per arm in representative , each functioning as a sensory and organ. The skin surface features specialized cells including chromatophores, which enable dynamic through expansion and contraction. Internally, Octopodidae possess a highly developed , including a that is the largest and most complex among , comprising approximately 500 million neurons distributed across a central and peripheral ganglia. The includes three hearts: two branchial hearts that pump deoxygenated blood to the gills for oxygenation and a single systemic heart that circulates oxygenated blood throughout the body. An , connected to the mantle cavity, produces and stores ink for defensive ejection, though it is absent in some deep-sea genera. The mouth is equipped with a hard, chitinous for biting and tearing prey, complemented by a in some species. As diagnostic traits of the incirrate suborder, Octopodidae exhibit the absence of sessile cirri on the arms and lack fins entirely, setting them apart from cirrate octopods. The , a muscular tube arising from the mantle, directs water flow for and aids in by drawing water over the gills. These features collectively define the family's to benthic and pelagic environments through flexible, hydrostatic-based mobility.

Size and coloration

Octopodids display considerable variation in body size across the family, with mantle lengths typically ranging from 1 cm in the smallest species to about 90 cm in the largest. Arm spans can extend from 5 cm to 4.3 m, while body weights vary from less than 1 g to over 50 kg in mature individuals. For instance, the (Octopus vulgaris) commonly attains a mantle length of 15–25 cm and an average weight of 1–3 kg, though maximum weights can reach 10 kg. Notable size extremes within Octopodidae include diminutive species such as the blue-ringed octopuses (Hapalochlaena spp.), which measure 10–20 cm in total length, and larger forms like the (Enteroctopus dofleini), which can achieve arm spans up to 4.3 m and weights up to 50 kg, establishing the upper limits of the family's size spectrum. These variations reflect the diverse morphologies adapted within the family, though the arm structure itself—characterized by eight flexible appendages—remains consistent across sizes. Sexual dimorphism in size is pronounced in certain genera, such as Tremoctopus, where females grow to total lengths of up to 2 m and weights substantially larger, while males remain tiny at approximately 2.4 cm in length, representing one of the most extreme examples of size disparity in the animal kingdom. Coloration in Octopodidae arises from specialized skin cells that facilitate dynamic pigmentation and structural effects. Chromatophores, elastic sacs filled with pigments, expand or contract via muscular control to display colors like and , enabling rapid shifts in hue. Iridophores contribute iridescent reflections through platelet arrangements that scatter , producing , greens, and silvers, while papillae are muscular protrusions that alter skin texture for enhanced . These mechanisms collectively allow for instantaneous changes in appearance.

Distribution and habitat

Geographic range

The Octopodidae family exhibits a across all major oceans, including , Indian, Pacific, , and Southern Oceans, spanning tropical, subtropical, temperate, and polar waters but absent from freshwater habitats. Members of this family are benthic or nektobenthic, occurring from intertidal zones to abyssal depths exceeding 5,000 meters, with some species like Vulcanoctopus hydrothermalis recorded at 2,600–2,832 meters along hydrothermal vents in the . This broad latitudinal and bathymetric range reflects their adaptability to diverse marine conditions, from shallow coastal shelves to deep-sea slopes and seamounts. The Indo-West Pacific region represents a major hotspot of diversity within Octopodidae, with over 100 described species and numerous undescribed forms concentrated in areas such as the Indo-Malayan Archipelago, the , , and ; genera like Amphioctopus, Callistoctopus, and Hapalochlaena contribute significantly to this richness. In contrast, the and eastern Atlantic host prominent populations of Octopus vulgaris, which is abundant from the to and extends into the . Southern Ocean species, such as Megaleledone setebos and various Pareledone taxa, underscore the family's presence in polar environments, often at depths of 32–850 meters around . Dispersal in Octopodidae is facilitated primarily by the planktonic paralarval stage, which allows larvae to spread widely across ocean basins and contribute to the family's global reach; for instance, the hatchlings of Octopus vulgaris undergo an extended planktonic phase enabling colonization of distant coastal areas. Human-mediated range expansions have also occurred, such as the of Amphioctopus kagoshimensis from the into the Mediterranean via the .

Ecological niches

Octopodidae species predominantly occupy benthic habitats across a wide , from intertidal zones to abyssal depths exceeding 4,000 meters. Most are bottom-dwellers adapted to coastal and environments, with common species like Octopus vulgaris favoring shallow subtidal areas up to 100 meters where they construct dens in rocky crevices or amid solid substrates such as shells and boulders for protection. Deeper-water taxa, including Eledone cirrhosa (up to ~770 meters on upper slopes) and certain Benthoctopus species, extend into slope and abyssal regions, with records of incirrate octopods observed at depths of 4,290 meters on manganese-encrusted seamounts, where low oxygen and characterize their niches. While primarily benthic, some juveniles exhibit extended paralarval phases in the before settling, though adults remain substrate-associated rather than fully pelagic. These octopods inhabit diverse substrate types, including coral reefs, meadows, kelp forests, and soft sandy or muddy bottoms, often selecting sites that provide and shelter. For instance, Octopus vulgaris thrives in structured environments like Mediterranean beds and rocky reefs, where it excavates burrows or repurposes natural crevices, while Eledone moschata prefers unstructured soft sediments along coastal plains, avoiding exposed rocky areas except during spawning. In deeper habitats, species associate with biogenic structures such as deep-sea corals or sediment mounds in submarine canyons, demonstrating preferences for fine-grained substrates that facilitate burrowing and ambush predation. Such habitat versatility allows Octopodidae to exploit varied benthic niches, from tropical reef systems to cold-temperate mudflats. Within marine ecosystems, Octopodidae serve as key predators, exerting top-down control on populations of crustaceans, bivalves, and smaller mollusks through active and shell-drilling behaviors, thereby influencing benthic community structure and preventing overgrazing of or infauna. Species like Octopus vulgaris and Eledone cirrhosa consume a broad spectrum of prey, including crabs and polychaetes, which helps maintain in reef and soft-bottom assemblages. Conversely, they function as important prey items for a range of predators, including demersal fish such as hakes, , and larger cetaceans, linking benthic and pelagic food webs. Their sensitivity to environmental stressors positions Octopodidae as effective bioindicators of health; for example, Octopus vulgaris accumulates heavy metals like , mercury, and lead in digestive glands at levels reflecting coastal gradients, signaling habitat degradation from or runoff.

Biology and ecology

Feeding and diet

Members of the Octopodidae family are predominantly carnivorous predators, with diets consisting mainly of crustaceans such as and , mollusks including bivalves and gastropods, and various species. Some species display opportunistic omnivory, incorporating polychaetes and other small when available. Prey is processed using the family's characteristic hard, chitinous , which crushes shells and tears flesh, often aided by the for manipulation. Foraging typically occurs at night, with octopuses emerging as active hunters from their dens to pursue prey across benthic habitats. They employ arm probing from den entrances to detect and capture nearby organisms, leveraging the flexible, sucker-lined arms for precise handling. Notable adaptations include tool use in species like the veiled octopus (), which transports shell halves for temporary shelter during foraging excursions. Certain genera, such as Hapalochlaena, utilize paralytic toxins delivered via salivary glands to immobilize and fish prey rapidly. As mid-to-upper carnivores, octopodids maintain high metabolic demands, with daily food consumption ranging from 5% to 20% of their body weight depending on , , and conditions, to support and activity. Dietary preferences vary by ; for instance, the (Octopus vulgaris) favors , which form a significant portion of its intake and optimize . Their suckered facilitate secure capture of mobile prey during these hunts.

Reproduction and life cycle

Members of the Octopodidae family exhibit through the transfer of spermatophores by males using a specialized known as the . This , typically the third right , delivers packets of sperm directly to the female's mantle cavity or during mating. is pronounced in some genera, such as Tremoctopus, where dwarf males are significantly smaller than females, reaching only a fraction of their size to facilitate mate location and transfer. Females lay eggs in large clusters, often numbering over 100,000 per clutch in species like Octopus vulgaris, with individual eggs measuring 1-2 mm in diameter and attached to substrates within sheltered dens. Following oviposition, females engage in extensive brooding, guarding the eggs, cleaning them of debris, and ventilating them with water currents for periods ranging from 1 to 8 months, depending on species and environmental conditions. During this phase, brooding females cease feeding, relying on stored energy reserves, which culminates in semelparity: post-hatching death due to and physiological . The of Octopodidae includes distinct stages beginning with planktonic paralarvae that hatch at 1-2 mm length and disperse in the for 30-90 days, feeding on before settling to the as juveniles. Juveniles transition to a benthic lifestyle, growing rapidly and reaching maturity within 1-2 years, with overall lifespans typically spanning 1-5 years, influenced by habitat depth and temperature. Reproductive timing varies across Octopodidae, with temperate species like exhibiting annual breeding cycles synchronized to seasonal cues, featuring maturation peaks in spring or autumn. In contrast, tropical and subtropical populations often display continuous or year-round reproduction, allowing multiple spawning events without strict seasonality.

Behavior and intelligence

Octopuses in the family Octopodidae exhibit remarkable intelligence, characterized by advanced problem-solving abilities, such as navigating multi-step puzzles to access food rewards. In experiments with Octopus vulgaris, individuals successfully learned to manipulate a five-level puzzle box by pulling or pushing levers in sequence, demonstrating flexible decision-making and adaptation to novel challenges over multiple trials. Tool use has also been observed, where octopuses employ objects like coconut shells for shelter or stones to block den entrances, indicating purposeful environmental manipulation. Their cognitive prowess is supported by a large brain-to-body mass ratio, the highest among invertebrates, with approximately 500 million neurons distributed across a centralized brain and distributed neural networks in the arms. Learning occurs through observation, as demonstrated in laboratory settings where octopuses acquired foraging techniques by watching conspecifics solve tasks, bypassing trial-and-error. Both short-term and long-term memory are evident; for instance, O. vulgaris retains spatial maps of maze configurations for weeks, aiding navigation and resource location. Interindividual differences in these abilities highlight personality variations, with some octopuses approaching and solving puzzle boxes more efficiently than others. Daily behaviors of Octopodidae members are predominantly solitary and nocturnal, with individuals at night and retreating to dens during the day to avoid predators. Den fidelity is common, as octopuses maintain and return to specific shelters, often remodeling them with for security. via rapid skin texture and color changes enables blending with substrates, while ink ejection creates visual distractions during escapes, and —voluntary arm detachment—serves as a last-resort defense against threats. In captivity, play-like actions emerge, such as manipulating non-food objects like bottles or toys, suggesting exploratory behaviors akin to those in vertebrates. Communication in Octopodidae relies on dynamic patterns rather than vocalizations, with chromatophore-mediated displays signaling threats or readiness through uniform darkening, pulsing, or mottled appearances. Lacking complex social structures, these cephalopods nonetheless demonstrate individual recognition in controlled settings, distinguishing familiar humans based on visual and tactile cues over repeated interactions. An for benthic Octopodidae outlines over 50 distinct behaviors, including arm like extension for probing or coiling for , and displays ranging from uniform pale for relaxation to dark hoods for . Variations include advanced in species like , which impersonates venomous animals through and pattern combinations to deter predators. Recent studies as of 2025 continue to explore octopus cognition, highlighting interindividual differences in problem-solving efficiency and advocating an agnostic approach to interpreting their due to challenges in cross-species comparisons.

Human interactions

Fisheries and economic importance

Octopodidae, particularly species like Octopus vulgaris, support significant global fisheries, with annual catches approximating 380,000 metric tons in 2020. These fisheries are concentrated in key regions including the Mediterranean, (notably and ), and (such as ), where octopuses contribute substantially to coastal economies and livelihoods. Common fishing methods involve traps and pots, which exploit the octopuses' natural tendency to seek shelter in enclosed spaces, allowing for targeted capture while minimizing in artisanal operations. Aquaculture of Octopodidae remains emerging, with pilot and research efforts in and parts of , including , aimed at supplementing wild stocks. However, challenges such as high rates of among juveniles and difficulties in paralarval rearing have hindered large-scale commercialization, alongside ethical debates concerning in . The global economic value of octopus fisheries and trade is estimated at around $2 billion annually, driven primarily by export markets for fresh, frozen, and processed products. Beyond commercial exploitation, Octopodidae hold cultural significance as a traditional food source, often prepared as calamari in Mediterranean cuisines, where they have been integral to diets since and times. Additionally, octopuses serve as important models in research due to their distributed nervous systems and complex behaviors, providing insights into and neural plasticity.

Conservation status

Octopodidae species face several threats that impact their populations and habitats. represents a primary concern, with many fisheries experiencing declines due to intense exploitation and inadequate management, particularly in regions like the Mediterranean and Atlantic where (Octopus vulgaris) stocks have been overfished. in trawl fisheries further exacerbates mortality rates for non-target Octopodidae species. Habitat loss from and degradation of benthic environments also poses risks, as these octopuses rely on complex seafloor structures for shelter and . Climate change compounds these pressures, with ocean warming projected to reduce suitability for such as Octopus vulgaris and Octopus maya, leading to potential range contractions in tropical and subtropical waters by 2100. specifically affects early life stages, impairing the development and survival of paralarvae in cephalopods, including octopuses, by disrupting and metabolic processes essential for their planktonic phase. Regarding conservation statuses, most assessed Octopodidae are classified as Least Concern by the , including the widespread Octopus vulgaris and the blue-ringed octopuses of the genus Hapalochlaena, which maintain low but stable population numbers despite their toxicity limiting human harvest. No family-wide endangered designation exists, though data deficiencies for many deep-sea and remote hinder comprehensive assessments. Hapalochlaena , while Least Concern, are vulnerable to localized declines due to their restricted distributions and sensitivity to perturbations. Conservation efforts include national quotas and management plans in the , where octopus fisheries are excluded from common quotas but subject to reforms like those in emphasizing seasonal closures and size limits to promote sustainable yields. protected areas (MPAs) in waters, covering about 13.7% of areas as of 2023, provide refuge for Octopodidae by restricting activities, though only a fraction enforce strict protections beneficial to octopus habitats. Ongoing research focuses on sustainable harvest models and , with recent studies highlighting adaptive strategies for warming oceans to mitigate paralarval vulnerabilities. Significant gaps remain in , particularly for undescribed Octopodidae , which face elevated risks due to unknown distributions and heightened susceptibility to emerging threats like deep-sea mining. Global monitoring programs are urgently needed to address these uncertainties and enable targeted protections across the family's diverse taxa.

References

  1. [1]
    https://www.itis.gov/servlet/SingleRpt/SingleRpt?search_topic=TSN&search_value=82590
  2. [2]
    Family OCTOPODIDAE d'Orbigny, 1839 - Australian Faunal Directory
    Octopodids are eight-armed cephalopods with muscular to gelatinous bodies. The arms are equipped with one or two rows of suckers without chitinous sucker rings.
  3. [3]
    Octopodidae - an overview | ScienceDirect Topics
    vulgaris (coastal distribution from northern Europe around Africa, including Mediterranean and Red Sea, and Asia east to Japan, also western Atlantic from USA ...
  4. [4]
    octopus - Wiktionary, the free dictionary
    Etymology. From Latin octōpūs, from Ancient Greek ὀκτώπους (oktṓpous), from ... From Ancient Greek ὀκτώπους (oktṓpous), from ὀκτώ (oktṓ, “eight”) + πούς ...
  5. [5]
    World Register of Marine Species - Octopodidae A. d'Orbigny, 1839
    Biota · Animalia (Kingdom) · Mollusca (Phylum) · Cephalopoda (Class) · Coleoidea (Subclass) · Octopodiformes (Superorder) · Octopoda (Order) · Incirrata (Suborder) ...
  6. [6]
    http://www.marinespecies.org/aphia.php?p=taxdetails&id=11782
  7. [7]
    Genome skimming elucidates the evolutionary history of Octopoda
    Here we present a phylogeny for the Octopodiformes using whole mitochondrial genomes. Mitochondrial genomes followed the typical Octopodiformes gene order.
  8. [8]
    https://www.sciencedirect.com/science/article/pii/S1055790323000295
  9. [9]
    https://doi.org/10.1016/j.ympev.2023.107729
  10. [10]
    https://doi.org/10.54103/2039-4942/23207
  11. [11]
    https://www.marinespecies.org/aphia.php?p=taxdetails&id=141829
  12. [12]
    The first record of Tremoctopus violaceussensu stricto Delle Chiaje ...
    ... sexual size dimorphism, with small or dwarf males and larger females, some of which reach 2 m long (Naef 1923; Norman 2000). Such extreme dimorphism is not ...
  13. [13]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC7854555/
  14. [14]
    [PDF] Molluscan Research: Wunderpus photogenicus n. gen. and sp.
    At least 50 undescribed species have been recognized by the ... et sp.), a new octopus from the tropical Indo-west Pacific (Cephalopoda: Octopodidae).
  15. [15]
    White-V Octopus - Abdopus sp. - Florent's Guide
    White-V Octopus. Category: Octopuses. Scientific Name: Abdopus sp. Size: Arms up to 6 in. (15 cm). Distribution: Indonesia, Philippines.
  16. [16]
    [PDF] Cephalopods of the World. An Annotated and Illustrated Catalogue ...
    This publication is the third of three volumes of the second edition of the original FAO Catalogue of Cephalopods of the. World (Roper et al., 1984), and it ...
  17. [17]
    Full article: Octopus Suckers Identification Code (OSIC)
    The octopus has eight arms, each of which is equipped with one or two rows of suckers (Hochberg et al. Citation1992). There are several hundred suckers per arm, ...
  18. [18]
    Where Is It Like to Be an Octopus? - PMC - PubMed Central - NIH
    Mar 14, 2022 · Anatomy and Functions. With its 500 million neurons—a number more typical of vertebrates such as dogs—octopuses have the largest nervous systems ...
  19. [19]
    Common Octopus (Octopus vulgaris) Dimensions & Drawings
    Jun 15, 2022 · The Common Octopus has an arm length between 29.9”-39.4” (76-100 cm), mantle length of 5.9”-9.8” (15-25 cm), and weight of 6.6-22 lb (3-10 kg).
  20. [20]
    Octopus vulgaris, Common octopus : fisheries - SeaLifeBase
    Inhabits rocky, sandy and muddy bottoms of the coastline to the edge of the continental shelf (Ref. 2133). Found in intertidal and subtidal areas (Ref. 83938).Missing: characteristics | Show results with:characteristics
  21. [21]
    Common Octopus - OctoNation - The Largest Octopus Fan Club!
    Considered to be a medium-large size octopus with adults commonly weighing 3-5 Kg (6-11 lbs). Mantle length to 250 mm (10 in); total length to around 1.3 m (4 ...
  22. [22]
    Blue ringed octopus | AIMS
    Size differs between species, but they range from four to six centimetres long, with arms reaching lengths of seven to 10 centimetres. The group is named for ...
  23. [23]
    Giant Pacific Octopus | Akron Zoo
    Classification · Order: Octopoda · Family: Octopodidae · Genus: Enteroctopus · Species: dofleini ...
  24. [24]
    Photos of octopuses - Family Octopodidae - Dr Paddy Ryan
    The family Octopodidae contains 146 species in 23 genera. · Octopuses are, as the name implies, characterized by their possession of eight arms. · Many species, ...
  25. [25]
    First encounter with a live male blanket octopus: The world's most ...
    Aug 10, 2025 · The first encounter with a live male blanket octopus, Tremoctopus violaceus Chiaie, 1830, illustrates the most extreme example of sexual size‐dimorphism in a ...
  26. [26]
    Cephalopod Camouflage: Cells and Organs of the Skin - Nature
    Many cephalopods rely on sophisticated tissues - the chromatophores, iridophores, leucophores and papillae - to blend in with their surroundings and disrupt ...
  27. [27]
    How Octopuses and Squids Change Color | Smithsonian Ocean
    The center of each chromatophore contains an elastic sac full of pigment, rather like a tiny balloon, which may be colored black, brown, orange, red or yellow.
  28. [28]
    None
    Below is a merged summary of the habitat, depth range, and ecological roles for Octopodidae species (e.g., *Octopus vulgaris*, *Eledone cirrhosa*, *Eledone moschata*, and other incirrate octopods) based on the provided segments. To retain all detailed information in a dense and organized manner, I will use tables in CSV format where applicable, followed by a narrative summary for additional context and details not easily tabularized. The response includes all unique data points across the segments, with sources and useful URLs consolidated at the end.
  29. [29]
    Association of deep-sea incirrate octopods with manganese crusts ...
    Dec 19, 2016 · Here, we report that the depth range of incirrate octopods can now be extended to at least 4,290 m. Octopods (twenty-nine individuals from ...
  30. [30]
    First in situ observation of Cephalopoda at hadal depths (Octopoda
    May 26, 2020 · Generally, the Cephalopoda are restricted to abyssal depths or shallower (ca. < 5000 m). The deepest sighting of an incirrate octopod, the ' ...Missing: Octopodidae | Show results with:Octopodidae
  31. [31]
    Octopodidae) to Artificial Nests Placed in Different Habitats at Urla ...
    Aug 7, 2025 · For those from artificial nests, octopuses preferred Neptune grass habitats (66.33%) and only 33.33% of individuals gave a preference to sandy ...
  32. [32]
    Deep octopod habitat in the western North Atlantic characterized by ...
    Dec 13, 2023 · This study uses observations from in situ videos recorded by remotely operated vehicles (ROVs) deployed from the NOAA Ship Okeanos Explorer.
  33. [33]
    Fatty acids and elemental composition as biomarkers of Octopus ...
    The present study describes the novel use of fatty acids (FAs) and element profiles of Octopus vulgaris inhabiting three coastal areas in the W-Mediterranean ...
  34. [34]
    Biomarkers of physiological responses of Octopus vulgaris to ...
    Analyzing the digestive glands, octopuses from human-altered coastal areas showed higher activity of superoxide dismutase (SOD), catalase (CAT) and glutathione ...
  35. [35]
    Diet Composition and Variability of Wild Octopus vulgaris ... - Frontiers
    Juvenile and sub-adult cephalopods are mainly fed with live prey, including crustaceans, fishes, and mollusks (Domingues et al., 2004; García García and Cerezo ...Missing: Octopodidae | Show results with:Octopodidae
  36. [36]
    Feeding intensity and molecular prey identification of the common ...
    Jan 27, 2020 · Few studies have focused on the ecology of O. minor, whose diet is roughly known to include crustaceans, molluscs, polychaetes and fish [25, 26] ...
  37. [37]
    (PDF) Diet and Feeding Habits of Octopus hubbsorum Berry, 1953 ...
    The diet comprised 53 types in seven phyla; crustaceans, mollusks, and fishes were the main groups. In general, the crustaceans were dominant; in particular ...
  38. [38]
    Prey Capture, Ingestion, and Digestion Dynamics of Octopus ...
    Aug 17, 2017 · Food ingestion was assisted by buccal mass movements, the beak and the radula. Food passed through the esophagus into the upper digestive tract, ...Missing: crushing | Show results with:crushing
  39. [39]
    Cephalopods as Predators: A Short Journey among Behavioral ...
    Aug 17, 2017 · Defensive tool use in a coconut-carrying octopus. Curr. Biol. 19 ... Chemical tools of Octopus maya during crab predation are also active on ...Missing: probing | Show results with:probing
  40. [40]
    How octopuses use and recruit additional arms to find and ...
    We discovered that octopuses used all eight arms with similar frequency and most often engaged three, four, or five arms simultaneously. These findings further ...
  41. [41]
    Defensive tool use in a coconut-carrying octopus - ScienceDirect.com
    Dec 15, 2009 · We repeatedly observed soft-sediment dwelling octopuses carrying around coconut shell halves, assembling them as a shelter only when needed.
  42. [42]
    Toxicity and toxins of the greater blue-ringed octopus - SciTechnol
    Attempts were made to identify the paralytic toxins in the octopus. Paralytic toxins were partially purified by extraction with 0.1% AcOH and Sep-Pak C18 ...Missing: diet | Show results with:diet
  43. [43]
    Changes in body weight and intake of food by Octopus vulgaris
    The food intake was estimated and compared with the changes in body weight of the octopuses; 25 to 55% of the total intake of food appeared to be incorporated.Missing: percentage | Show results with:percentage
  44. [44]
    [PDF] Productive performance of the common octopus (Octopus vulgaris C ...
    The superiority of crab seems to depend mainly on the fact that the octopus prefers it; the food intake, in fact, is higher (P < 0.01) than for tattler and ...
  45. [45]
    Sexual Selection and the Evolution of Male Reproductive Traits in ...
    Oct 9, 2019 · In all cases, male octopuses pack their sperm into spermatophores and transfer them to females by using a modified arm called hectocotylus.
  46. [46]
    Cephalopod ontogeny and life cycle patterns - Frontiers
    This review provides explicit definitions and explanations of the steps in a cephalopod life cycle, from fertilization to death.
  47. [47]
    A practical staging atlas to study embryonic development of Octopus ...
    Apr 16, 2020 · 1a) [4, 5]. Octopuses that lay eggs that hatch out as planktonic paralarvae generally produce thousands of small eggs, reaching 500,000 in O. ...
  48. [48]
    Reproductive development versus estimated age and size in a wild ...
    Mar 28, 2012 · A lifecycle of about one year appears to be confirmed by the seasonality of the octopus catches in Sardinian waters, with important yields ...
  49. [49]
    Reproductive and growth parameter estimation utilizing length ...
    Males had a mantle length range from 3.1 to 7.5 cm (mean: 5.2 ± 0.7 cm) and a weight range of 5.99–94.00 g (mean: 35.34 ± 11.24 g), while females had a mantle ...Missing: sources | Show results with:sources
  50. [50]
    Pull or Push? Octopuses Solve a Puzzle Problem - PMC
    Mar 22, 2016 · Here we present data from a five-level learning and problem-solving experiment. Seven octopuses (Octopus vulgaris) were first trained to open an ...
  51. [51]
    Review Grow Smart and Die Young: Why Did Cephalopods Evolve ...
    Like tool use in corvids [33], learning can play a key role in octopus problem solving by allowing the fine tuning of innate predispositions. Critically, ...
  52. [52]
    How intelligent is a cephalopod? Lessons from comparative cognition
    Sep 6, 2020 · The soft-bodied cephalopods including octopus, cuttlefish, and squid are broadly considered to be the most cognitively advanced group of invertebrates.
  53. [53]
    Observational and Other Types of Learning in Octopus - ScienceDirect
    This chapter briefly reviews the most recent knowledge on octopus learning capabilities, focusing on its capability to learn by observation of conspecifics.
  54. [54]
    [PDF] Learning and memory in Octopus vulgaris: a case of biological ...
    Various forms of learning have been demonstrated in cephalopods, from simple sensitization, to associative learning and problem solving, to more complex forms.<|control11|><|separator|>
  55. [55]
    Octopus vulgaris Exhibits Interindividual Differences in Behavioural ...
    Dec 4, 2023 · Here, we investigated how Octopus vulgaris approached and solved a problem required for obtaining food from a puzzle box.
  56. [56]
    Evidence of play behavior in captive California Two-Spot Octopuses ...
    Aug 26, 2024 · Here, we characterized play behavior in wild-caught, laboratory-housed California Two-Spot Octopuses, Octopus bimaculoides, a species with growing relevance as ...Missing: solitary nocturnal fidelity ink autotomy
  57. [57]
    Octopus body language: body patterns of Abdopus capricornicus ...
    Jan 31, 2025 · This is the first study aimed at disentangling the body patterns used for camouflage from those used for communication.
  58. [58]
    [PDF] Octopuses (Enteroctopus dofleini) Recognize Individual Humans
    A final measure of “response to disturbance” is changes in skin patterns and color. During such situations in testing, Packard & Sanders (1971) reported ...Missing: communication | Show results with:communication
  59. [59]
    An ethogram for Benthic Octopods (Cephalopoda: Octopodidae)
    The present paper constructs a general ethogram for the actions of the flexible body as well as the skin displays of octopuses in the family Octopodidae.Missing: 2013 Amphioctopus mimicry
  60. [60]
    Assessing the quality of octopus: From sea to table
    Mar 27, 2023 · According to data from the European Market Observatory for Fisheries and Aquaculture Products, world catches of octopus totaled 405,773 t in ...
  61. [61]
    6. how to make various types of traps and pots
    Octopus traps. Unglazed earthenware pots are used in traditional octopus fishing in the Mediterranean and southeast Asia. The pots are placed on the sea bed ...Missing: Octopodidae | Show results with:Octopodidae<|control11|><|separator|>
  62. [62]
    Octopus aquaculture: Welfare practices and challenges - PMC - NIH
    Octopus aquaculture itself is not without difficulty. The biggest challenges that exist are cannibalism, trauma, sourcing feed, and raising paralarval stages.Missing: Japan | Show results with:Japan
  63. [63]
    Octopus etiquette - ScienceDirect.com
    Oct 23, 2023 · Ancient Greeks and Romans already served them as delicacies, and today coastal cultures such as Galicia in northwest Spain, as well as Greece ...<|control11|><|separator|>
  64. [64]
    An Octopus Could Be the Next Model Organism | Scientific American
    Mar 1, 2021 · Big-brained cephalopods could shine light on the evolution and neurobiology of intelligence, complexity, and more—and inspire medical and ...