Octopus vulgaris is considered cosmopolitan. A global species, its range in the eastern Atlantic extends from the Mediterranean Sea and the southern coast of England to at least Senegal in Africa. It also occurs off the Azores, Canary Islands, and Cape Verde Islands. The species is also common in the Western Atlantic.
Octopus vulgaris grows to 25 cm in mantle length with arms up to 1 m long. O. vulgaris is caught by bottom trawls on a huge scale off the northwestern coast of Africa. More than 20,000 tonnes are harvested annually.
The common octopus hunts at dusk. Crabs, crayfish, and bivalve mollusks (two-shelled molluscs such as cockles) are preferred, although the octopus will eat almost anything it can catch. It is able to change colour to blend in with its surroundings, and is able to jump upon any unwary prey that strays across its path. Using its beak, it is able to break into the shells of shelled mollusks. It also possesses venom to subdue its prey.
Training experiments have shown the common octopus can distinguish the brightness, size, shape, and horizontal or vertical orientation of objects. They are intelligent enough to learn how to unscrew a jar and are known to raid lobster traps. O. vulgaris was the first invertebrate animal protected by the Animals (Scientific Procedures) Act 1986 in the UK; it was included because of its high intelligence.
Habitat and demands
The common octopus is typically found in tropical waters throughout the world, such as the Mediterranean Sea and East Atlantic. They prefer the floor of relatively shallow, rocky, coastal waters, often no deeper than 200 meters. Although they prefer around 36 grams per liter, salinity throughout their global habitat is found to be between roughly 30 and 45 grams of salt per liter of water. They are exposed to a wide variety of temperatures in their environments, however their preferred temperature ranges from about 15 °C to 16 °C. In especially warm seasons, the octopus can often be found deeper than usual in order to escape the warmer layers of water. In moving vertically throughout the water, the octopus is subjected to various pressures and temperatures which affect the concentration of oxygen available in the water. This can be understood through Henry's Law, which states that the concentration of a gas in a substance is proportional to pressure and solubility, which is influenced by temperature. These various discrepancies in oxygen availability introduce a requirement for regulation methods.
Primarily, the octopus situates itself in a shelter where a minimal amount of its body is presented to the external water, which would pose a problem for an organism which breathes solely through its skin. When it does move, most of the time it is along the ocean or sea floor, in which case the underside of the octopus is still obscured. This crawling increases metabolic demands greatly, requiring they increase their oxygen intake by approximately 2.4 times the amount that is required for a resting octopus. This increased demand is met by an increase in the stroke volume of the octopus' heart.
The octopus does sometimes swim throughout the water, exposing itself completely. In doing so, the octopus uses a jet mechanism that involves creating a much higher pressure in their mantle cavity that allows them to propel themselves through the water. As the common octopus' heart and gills are located within their mantle, this high pressure also constricts and puts constraints on the various vessels that are returning blood to the heart. Ultimately, this creates circulation issues and is not a sustainable form of transportation, as the octopus cannot attain an oxygen intake that can balance the metabolic demands of maximum exertion.
The octopus uses gills as its respiratory surface. The gill is composed of branchial ganglia and a series of folded lamellae. Primary lamellae extend out to form demibranches and are further folded to form the secondary free folded lamellae, which are only attached at their tops and bottoms. The tertiary lamellae are formed by folding the secondary lamellae in a fan-like shape. Water moves slowly in one direction over the gills and lamellae, into the mantle cavity and out of the octopus' funnel.
The structure of the octopus' gills allows for a high amount of oxygen uptake; up to 65% in water at 20⁰C. The thin skin of the octopus accounts for a large portion of in-vitro oxygen uptake; estimates suggest around 41% of all oxygen absorption is through the skin when at rest. This number is affected by the activity of the animal – the oxygen uptake increases when the octopus is exercising due to its entire body being constantly exposed to water, but the total amount of oxygen absorption through skin is actually decreased to 33% as a result of the metabolic cost of swimming. When the animal is curled up after eating, its absorption through its skin can drop to 3% of its total oxygen uptake. The octopus' respiratory pigment, hemocyanin, also assists in increasing oxygen uptake. Octopuses can maintain a constant oxygen uptake even when oxygen concentrations in the water decrease to around 3.5 kPa or 31.6% saturation (standard deviation 8.3%). If oxygen saturation in sea water drops to about 1–10% it can be fatal for Octopus vulgaris depending on the weight of the animal and the water temperature. Ventilation may increase to pump more water carrying oxygen across the gills but due to receptors found on the gills the energy use and oxygen uptake remains at a stable rate. The high percent of oxygen extraction allows for energy saving and benefits for living in an area of low oxygen concentration.
Water is pumped into the mantle cavity of the octopus where it comes into contact with the internal gills. The water has a high concentration of oxygen compared to the blood returning from the veins, therefore oxygen diffuses into the blood. The tissues and muscles of the octopus use oxygen and release carbon dioxide when breaking down glucose in the Krebs cycle. The carbon dioxide then dissolves into the blood or combines with water to form carbonic acid which decreases blood pH. The Bohr Effect explains why oxygen concentrations are lower in venous blood than arterial blood and why oxygen diffuses into the blood stream. The rate of diffusion is affected by the distance the oxygen has to travel from the water to the blood stream as indicated by Fick's laws of diffusion. Fick's laws explain why the gills of the octopus contain many small folds that are highly vascularised. They increase surface area and thus also increase the rate of diffusion. The capillaries that line the folds of the gill epithelium have a very thin tissue barrier (10 µm) which allows for fast, easy diffusion of the oxygen into the blood. In situations where the partial pressure of oxygen in the water is low, diffusion of oxygen into the blood is reduced, Henry's Law can explain this phenomenon. The law states that at equilibrium the partial pressure of oxygen in water will be equal to that in air; however the concentrations will differ due to the differing solubility. This law explains why Octopus vulgaris has to alter the amount of water cycled through its mantle cavity as the oxygen concentration in water changes.
The gills are in direct contact with water – carrying more oxygen than the blood – that has been brought into the mantle cavity of the octopus. Gill capillaries are quite small and abundant which creates an increased surface area that water can come into contact with, thus resulting in enhanced diffusion of oxygen into the blood. There is evidence that lamellae and vessels within the lamellae on the gills contract to aid in propelling blood through the capillaries.
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The blood of the octopus is composed of copper-rich hemocyanin which is less efficient than the iron-rich hemoglobin of vertebrates and thus does not increase oxygen affinity to the same degree. Oxygenated hemocyanin in the arteries binds to CO2, which is then released when the blood in the veins is deoxygenated. The release of CO2 into the blood causes it to acidify by forming carbonic acid. The Bohr effect explains that carbon dioxide concentrations affect the blood pH and the release or intake of oxygen. The Krebs cycle uses the oxygen from the blood to break down glucose in active tissues or muscles and releases carbon dioxide as a waste product, which leads to more oxygen being released. Oxygen released into the tissues or muscles creates deoxygenated blood which returns to the gills in veins. The two brachial hearts of the octopus pump blood from the veins through the gill capillaries. The newly oxygenated blood drains from the gill capillaries into the systemic heart where it is then pumped back throughout the body.
The octopus has three hearts, one main two-chambered heart charged with sending oxygenated blood to the body and two smaller branchial hearts, one next to each set of gills. The circulatory circuit sends oxygenated blood from the gills to the atrium of the systemic heart, then to its ventricle which pumps this blood to the rest of the body. Deoxygenated blood from the body goes to the branchial hearts which pumps the blood across the gills to oxygenate it, and then the blood flows back to the systemic atrium for the process to begin again. Three aortae leave the systemic heart, two minor ones (the abdominal aorta and the gonadal aorta) and one major one, the dorsal aorta which services most of the body. The octopus also has large blood sinuses around its gut and behind its eyes that function as reserves in times of physiologic stress.
The octopus' heart rate does not change significantly with exercise, though temporary cardiac arrest of the systemic heart can be induced by oxygen debt, almost any sudden stimulus, or mantle pressure during jet propulsion. Its only compensation for exertion is through an increase in stroke volume of up to three times by the systemic heart, which means it suffers an oxygen debt with almost any rapid movement. The octopus is, however, able to control how much oxygen it pulls out of the water with each breath using receptors on its gills, allowing it to keep its oxygen uptake constant over a range of oxygen pressures in the surrounding water.
Octopuses use hemocyanin as their respiratory pigment, which binds oxygen through copper rather than the iron used by our own hemoglobin. Blood volume in the octopus' body is about 3.5% of its body weight but the blood's oxygen carrying capacity is only about 4 volume percent. This contributes to their susceptibility to the oxygen debt mentioned before. Shadwick and Nilsson concluded that the octopus circulatory system is "fundamentally unsuitable for high physiologic performance".
Like those of vertebrates, octopus blood vessels are very elastic with a resilience of 70% at physiologic pressures. They are primarily made of an elastic fibre called octopus arterial elastomer, with stiffer collagen fibres recruited at high pressure to help the vessel maintain its shape without over-stretching. Shadwick and Nilsson theorized that all octopus blood vessels may use smooth muscle contractions to help move blood through the body, which would make sense in the context of them living under water with the attendant pressure.
The elasticity and contractile nature of the octopus aorta serves to smooth out the pulsing nature of blood flow from the heart as the pulses travel the length of the vessel, while the vena cava serves in an energy storage capacity. Stroke volume of the systemic heart changes inversely with the difference between the input blood pressure through the vena cava and the output back pressure through the aorta.
The blood composition of the species Octopus vulgaris differs from humans in two main ways: the binding agent is not iron that is found in hemoglobin, but copper found in hemocyanin which is not found within the blood cells as hemoglobin is, but within the blood's plasma. Since the binding agent is found within the plasma and not the blood cells there is a limit to the oxygen up take that the octopus can experience. If it were to increase the hemocyanin within its blood stream, the fluid would become too viscous for the myogenic hearts to pump. Poiseuille's Law explains the rate of flow of the bulk fluid throughout the entire circulatory system through the differences of blood pressure and vascular resistance. The three hearts are also temperature and oxygen depended and the beat rhythm of the three hearts are generally in phase with the two branchial hearts beating together followed by the systemic heart. The Frank-Starling Law also contributes to overall heart function, through contractility and stroke volume, since the total volume of blood vessels must be maintained, and must be kept relatively constant within the system for the heart to function properly.
The hemolymph, pericardial fluid and urine of cephalopods, including the common octopus are all isosmotic with each other, as well as with the surrounding sea water. It has been suggested that cephalopods do not osmoregulate, which would indicate that they are conformers. This means that they adapt to match the osmotic pressure of their environment, and because there is no osmotic gradient, there is no net movement of water from the organism to the seawater, or from the seawater into the organism. It has been shown that octopuses have an average minimum salinity requirement of 27g/L, and that any disturbance introducing significant amounts of fresh water into their environment can prove fatal.
In terms of ions, however, there does seem to be a discrepancy between ionic concentrations found in the seawater and those found within cephalopods. In general, it seems as though they maintain hypoionic concentrations of sodium, calcium and chloride in contrast to the saltwater. Sulfate and potassium exist in a hypoionic state as well, with the exception of the excretory systems of cephalopods where the urine is hyperionic. These ions are free to diffuse, and because they exist in hypoionic concentrations within the organism, they would be moving into the organism from the seawater. The fact that the organism can maintain hypoionic concentrations suggests not only that a form of ionic regulation exists within cephalopods, but that they also actively excrete certain ions such as potassium and sulfate in order to maintain homeostasis.
Octopus vulgaris has a mollusc-style kidney system, which is very different from our own. The system is built around an appendage of each branchial heart, which is essentially an extension of its pericardium. These long, ciliated ducts filter the blood into a pair of kidney sacs while actively reabsorbing glucose and amino acids into the bloodstream. The renal sacs actively adjust the ionic concentrations of the urine, and actively add nitrogenous compounds and other metabolic waste products to the urine. Once filtration and reabsorption are complete, the urine is emptied into Octopus vulgaris' mantle cavity via a pair of renal papillae, one from each renal sac.
Temperature and body size directly affect the oxygen consumption of Octopus vulgaris which will alter the rate of metabolism. Katsanevakis et al. found that when oxygen consumption decreases the amount of ammonia excretion also decreases due to the slowed metabolic rate. Octopus vulgaris has four different fluids found within its body: blood, pericardial fluid, urine and renal fluid. The urine and renal fluid have high concentrations of potassium and sulphate, but low concentrations of chlorine. The urine has low calcium concentrations which suggests it has been actively removed. The renal fluid has similar calcium concentrations to the blood. Chlorine concentrations are high in the blood, while sodium varies. The pericardial fluid has concentrations of sodium, potassium, chlorine and calcium similar to that of the salt water supporting the idea that Octopus vulgaris does not osmoregulate, but conforms. However, it has lower sulphate concentrations. The pericardial duct contains an ultrafiltrate of the blood known as the pericardial fluid and the rate of filtration is partly controlled by the muscle and nerve rich brachial hearts. The renal appendages move nitrogenous and other waste products from the blood to the renal sacs, but do not add volume. The renal fluid has a higher concentration of ammonia than the urine or the blood thus the renal sacs are kept acidic in order to help draw the ammonia from the renal appendages. The ammonia will diffuse down its concentration gradient into the urine or into the blood where it gets pumped through the brachial hearts and diffuses out the gills. The excretion of ammonia by Octopus vulgaris makes them ammonotelic organisms. Aside from ammonia, there are a few other nitrogenous waste products that have been found to be excreted by Octopus vulgaris such as urea, uric acid, purines and some free amino acids but in smaller amounts.
Within the renal sacs, there are two recognized and specific cells that are responsible for the regulation of ions. The two kinds of cells are the lacuna forming cells and the epithelial cells that are typical to kidney tubules. The epithelia cells are ciliated, cylindrical, and polarized with three distinct regions. These three regions are apical, middle cytoplasmic and basal lamina. The middle cytoplasmic region is the most active of the three due to the concentration of multiple organelles within, such as mitochondria, smooth and rough endoplasmic reticulum, among others. The increase of activity is due to the interlocking labyrinth of the basal lamina creating a crosscurrent activity similar to the mitochondrial rich cells found in teleost marine fish. The lacuna forming cells are characterized by contact to the basal lamina, but not reaching the apical rim of the associated epithelial cells and are located in the branchial heart epithelium. The shape varies widely and are occasionally more electron dense than the epithelial cells, seen as a "diffused kidney" regulating ion concentrations.
One adaptation that Octopus vulgaris has is some direct control over its kidneys. It is able to switch at will between the right or left kidney doing the bulk of the filtration, and can also regulate the filtration rate so that the rate does not increase when the animal's blood pressure goes up due to stress or exercise. Some species of Octopus, including O. vulgaris, also have a duct that runs from the gonadal space into the branchial pericardium. Wells theorized that this duct, which is highly vascularized and innervated, may enable the reabsorption of important metabolites from the ovisac fluid of pregnant females by directing this fluid into the renal appendages.
As an oceanic organism, Octopus vulgaris experiences a temperature variance due to many factors, such as season, geographical location and depth. For example, octopuses living around Naples may experience a temperature of 25 °C in the summer months, and 15 °C in the winter months. These changes would occur quite gradually, however, and thus would not require any extreme regulation.
The common octopus is a poikilothermic, eurythermic ectotherm, meaning that it conforms to the ambient temperature. This implies that there is no real temperature gradient between the organism and its environment, the two are quickly equalized. If the octopus swims to a warmer locale, it will gain heat from the surrounding water, and if it swims to colder surroundings it will lose heat in a similar fashion.
Octopus vulgaris can apply behavioral changes in order to manage wide varieties of environmental temperatures. Respiration rate in octopods is temperature sensitive – respiration increases with temperature. The oxygen consumption of Octopus vulgaris increases when in water temperatures between 16–28 °C, reaches a maximum at 28 °C, and then begins to drop at 32 °C. The optimum temperature for metabolism and oxygen consumption is between 18–24 °C. Variations in temperature can also induce a change in hemolymph protein levels along oxygen consumption. As temperature increases, protein concentrations increase in order to accommodate the temperature. Also the cooperativity of hemocyanin increases but the affinity decreases. Conversely, a decrease in temperature results in a decrease in respiratory pigment cooperativity and increase in affinity. The slight rise in P50 that occurs with temperature change allows oxygen pressure to remain high in the capillaries, allowing for elevated diffusion of oxygen into the mitochondria during periods of high oxygen consumption. The increase in temperature results in higher enzyme activity yet the decrease in hemocyanin affinity allows enzyme activity to remain constant and maintain homeostasis. The highest hemolymph protein concentrations are seen at 32 °C and then drop at temperatures above this. Oxygen affinity in the blood decreases by 0.20 kPa/°C at a pH of 7.4. The octopod's thermal tolerance is limited by its ability to consume oxygen, and when it fails to provide enough oxygen to circulate at extreme temperatures the effects can be fatal. Octopus vulgaris have a pH-independent venous reserve that represents the amount of oxygen that remains bound to the respiratory pigment at constant pressure of oxygen. This reserve allows the octopus to tolerate a wide range of pH related to temperature.
As a temperature conformer, Octopus vulgaris does not have any specific organ or structure dedicated to heat production or heat exchange. Like all animals they produce heat as a result of ordinary metabolic processes such as digestion of food, but take no special means to keep their body temperature within a certain range. Their preferred temperature directly reflects the temperature they are acclimated to. They have an acceptable ambient temperature range of 13–28 °C, with their optimum for maximum metabolic efficiency being about 20 °C.
As ectothermal animals, Octopus vulgaris are highly influenced by changes in temperature. All species have a thermal preference where they can function at their basal metabolic rate. The low metabolic rate allows for rapid growth and thus, these cephalopods mate as the water becomes closest to the preferential zone. Research has shown that increasing temperatures cause an increase in oxygen consumption by Octopus vulgaris. Increased oxygen consumption can be directly related to the metabolic rate, because the breakdown of molecules such as glucose requires an input of oxygen, as explained by the Krebs cycle. The amount of ammonia excreted conversely decreases with increasing temperature. The decrease in ammonia being excreted is also related to the metabolism of the octopus due to its need to spend more energy as the temperature increases. Octopus vulgaris will reduce the amount of ammonia excreted in order to use the excess solutes that it would have otherwise excreted due to the increased metabolic rate. Octopuses do not regulate their internal temperatures until it reaches a threshold where they must begin to regulate in order to prevent death. The increase in metabolic rate shown with increasing temperatures is thus, likely due to the octopus swimming to shallower or deeper depths in order to stay within its preferential temperature zone.
- Quigley, D.T.G. and Flannery, K. 2014. The Common Octopus (Octopus vulgaris Cuvier) in Irish waters. The Irish Naturalists' Journal 33(2): 124–127. JSTOR 24393605.
- Norman, M.D. 2000. Cephalopods: A World Guide. ConchBooks.
- Species Fact Sheets: Octopus vulgaris (Lamarck, 1798). FAO Fisheries & Aquaculture.
- "The Animals (Scientific Procedures) Act(Amendment) Order 1993". August 23, 1993. Retrieved February 22, 2013.
- Belcari, P., Cuccu, D., González, M., Srairi, A. & Vidoris, P. (2002) Distribution and abundance of Octopus vulgaris Cuvier 1797, (Cephalopoda: Octopoda) in the Mediterranean Sea. Scientia Marina, 66(S2): 157–166. doi:10.3989/scimar.2002.66s2157.
- Moreno, A., Lourenço, S., Pereira, J., Gaspar, M.B., Cabral, H.N., Pierce, G.J., et al. (2013). Essential habits for pre-recruit Octopus vulgaris along the Portuguese coast. Fisheries Research, 152: 74–85. doi:10.1016/j.fishres.2013.08.005.
- Katsanevakis, S. & Verriopoulos, G. (2004). Abundance of Octopus vulgaris on soft sediment. Scientia Marina, 68, 553–560. doi:10.3989/scimar.2004.68n4553.
- Valverde, Jesús C. & García, Benjamin. (2005). Suitable dissolved oxygen levels for common octopus (Octopus vulgaris cuvier, 1797) at different weights and temperature: analysis of respiratory behavior. Aquaculture. 244: 303–314. doi:10.1016/j.aquaculture.2004.09.036.
- Madan, J.J. & Wells, M.J. (1996). Cutaneous respiration in Octopus vulgaris. The Journal of Experimental Biology, 199: 2477–2483
- Katsanevakis, S., Stephanopoulou, S., Miliou, H., Moraitou-Apostolopoulou, M. & Verriopoulos, G. (2005). Oxygen consumption and ammonia excretion of Octopus vulgaris (Cephalopoda) in relation to body mass and temperature. Marine Biology, 146, 725–732. doi:10.1007/s00227-004-1473-9.
- Wells, M.J., Duthie, G.G., Houlihan, D.F., Smith, P.J.S. & Wells, J. (1987). Blood flow and pressure changes in exercising octopuses (Octopus vulgaris). The Journal of Experimental Biology, 131, 175–187
- Young, Richard E. & Vecchione, Michael. (2002). Evolution of the gills in the octopodiformes. Bulletin of marine science. 71(2): 1003–1017
- Wells, M.J., & Wells, J. (1995). The control of ventilatory and cardiac responses to changes in ambient oxygen tension and oxygen demand in Octopus. The Journal of Experimental Biology, 198, 1717–1727
- Eno, N.C. (August 1994). The morphometrics of cephalopod gills. Journal of the Marine Biological Association of the United Kingdom, 74(3), 687–706
- Melzner, F., Block, C. & Pörtner, H.O. (2006). Temperature-dependent oxygen extraction from the ventilatory current and the costs of ventilation in the cephalopod Sepia officinalis. Journal of Comparative Physiology B, 176, 607–621
- Wells, M.J., & Smith, P.J.S. (1987). The performance of the octopus circulatory system: A triumph of engineering over design. Experientia, 43, 487–499
- "Octopus Fact Sheet" (PDF). World Animal Foundation.
- Pörtner, H.O. (1994). Coordination of metabolism, acid-base regulation and haemocyanin function in cephalopods. Marine and Freshwater Behaviour and Physiology, 25(1–3), 131–148. doi:10.1080/10236249409378913.
- Wells, M.J. (1980). Nervous control of the heartbeat in Octopus. The Journal of Experimental Biology, 85, 111–128. PMID 7373208.
- Smith, P.J.S. (1981). The role of venous pressure in regulation of output from the heart of the octopus, Eledone cirrhosa (Lam.). The Journal of Experimental Biology, 93, 243–255
- O'Dor, R.K., & Wells, M.J. (1984). Circulation time, blood reserves and extracellular space in a cephalopod. The Journal of Experimental Biology, 113, 461–464. hdl:10222/29342.
- Wells, M.J. (1979). The heartbeat of Octopus vulgaris. The Journal of Experimental Biology, 78, 87–104
- Shadwick, R.E., & Nilsson E.K.. (1990). The importance of vascular elasticity in the circulatory system of the cephalopod Octopus vulgaris. The Journal of Experimental Biology, 152, 471–484
- Shadwick, Robert E. & Gosline, John M. (1985). Mechanical properties of the octopus aorta. The Journal of Experimental Biology, 114, 259–284
- Hill, Richard W., Gordon A. Wyse, and Margaret Anderson. Animal Physiology. 3rd ed. Sunderland, MA: (635–636, 654–657, 671–672) Sinauer Associates, 2012. Print
- Excitation-contraction coupling
- Wells, M.J. (1978). Octopus: Physiology and behaviour of an advanced invertebrate. Cambridge: University Printing House.
- Vaz-Pires, P., Seixas, P. & Barbosa, A. 2004. Aquaculture potential of the common octopus (Octopus vulgaris Cuvier, 1797): a review. Aquaculture, 238, 221–238. doi:10.1016/j.aquaculture.2004.05.018.
- Witmer, A. (1975). The fine structure of the renopericardial cavity of the cephalopod ocotopus dofleine martini. Journal of Ultrastructure Research, (53), 29–36.
- Hill, R.W., Wyse, G.A., & Anderson, M. (2012). Animal Physiology. Sunderland: SinauerAssociates pp. 164–165.
- Katsanevakis, S., Protopapas, N., Miliou, H. & Verriopoulos, G. (2005). Effect of temperature on specific dynamic action in the common octopus, Octopus vulgaris (Cephalopoda). Marine Biology, 146, 733–738.
- Yin F., et al. 2013. The respiration, excretion and biochemical response of the juvenile common Chinese cuttlefish, Sepiella maindroni at different temperatures. Aquaculture. 402–403: 127–132. doi:10.1016/j.aquaculture.2013.03.018.
- Zeilinski S., et al. 2001. Temperature effects on hemocyanin oxygen binding in an antarctic cephalopod. The Biological Bulletin. 200(1): 67–76. doi:10.2307/1543086. PMID 11249213.
- Noyola, J., Caamal-Monsreal, C., Díaz, F., Re, D., Sánchez, A., & Rosas, C. (2013). Thermopreference, tolerance and metabolic rate of early stages juvenile Octopus maya acclimated to different temperatures. Journal of Thermal Biology, 38, 14–19.
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- Javier Quinteiro, Tarik Baibai, Laila Oukhattar, Abdelaziz Soukri, Pablo Seixas, & Manuel Rey-Méndez, Multiple paternity in the common octopus Octopus vulgaris (Cuvier, 1797), as revealed by microsatellite DNA analysis; Molluscan Research 31(1): 15–20 ; ISSN 1323-5818
- "CephBase: Common octopus". Archived from the original on 2005.