This article is about the empirical or physical senses of living organisms (sight, hearing, etc.). For other uses, see Sense (disambiguation).
"Five senses" redirects here. For other uses, see Five senses (disambiguation).
Five senses and the respective sensory organs inherent among Homo sapiens
An allegory of five senses. Still Life by Pieter Claesz, 1623. The painting illustrates the senses through musical instruments, a compass, a book, food and drink, a mirror, incense and an open perfume bottle. The tortoise may be an illustration of touch or an allusion to the opposite (the tortoise isolating in its shell).

A sense is a physiological capacity of organisms that provides data for perception. The senses and their operation, classification, and theory are overlapping topics studied by a variety of fields, most notably neuroscience, cognitive psychology (or cognitive science), and philosophy of perception. The nervous system has a specific sensory system or organ, dedicated to each sense.

Humans have a multitude of senses. Sight (vision), hearing (audition), taste (gustation), smell (olfaction), and touch (somatosensation) are the five traditionally recognized senses. The ability to detect other stimuli beyond those governed by these most broadly recognized senses also exists, and these sensory modalities include temperature (thermoception), kinesthetic sense (proprioception), pain (nociception), balance (equilibrioception), vibration (mechanoreception), and various internal stimuli (e.g. the different chemoreceptors for detecting salt and carbon dioxide concentrations in the blood). However, what constitutes a sense is a matter of some debate, leading to difficulties in defining what exactly a distinct sense is, and where the borders between responses to related stimuli lay.

Other animals also have receptors to sense the world around them, with degrees of capability varying greatly between species. Humans have a comparatively weak sense of smell and a stronger sense of sight relative to many other mammals while some animals may lack one or more of the traditional five senses. Some animals may also intake and interpret sensory stimuli in very different ways. Some species of animals are able to sense the world in a way that humans cannot, with some species able to sense electrical and magnetic fields, and detect water pressure and currents.


Detail of The Senses of Hearing, Touch and Taste, Jan Brueghel the Elder, 1618

A broadly acceptable definition of a sense would be "A system that consists of a group of sensory cell types that responds to a specific physical phenomenon, and that corresponds to a particular group of regions within the brain where the signals are received and interpreted." There is no firm agreement as to the number of senses because of differing definitions of what constitutes a sense.

The senses are frequently divided into exteroceptive and interoceptive:

Non-human animals may possess senses that are absent in humans, such as electroreception and detection of polarized light.

In Buddhist philosophy, Ayatana or "sense-base" includes the mind as a sense organ, in addition to the traditional five. This addition to the commonly acknowledged senses may arise from the psychological orientation involved in Buddhist thought and practice. The mind considered by itself is seen as the principal gateway to a different spectrum of phenomena that differ from the physical sense data. This way of viewing the human sense system indicates the importance of internal sources of sensation and perception that complements our experience of the external world.

Traditional senses


In this painting by Pietro Paolini, each individual represents one of the five senses.[2]

Sight or vision (adjectival form: visual/optical) is the capability of the eye(s) to focus and detect images of visible light on photoreceptors in the retina of each eye that generates electrical nerve impulses for varying colors, hues, and brightness. There are two types of photoreceptors: rods and cones. Rods are very sensitive to light, but do not distinguish colors. Cones distinguish colors, but are less sensitive to dim light. There is some disagreement as to whether this constitutes one, two or three senses. Neuroanatomists generally regard it as two senses, given that different receptors are responsible for the perception of color and brightness. Some argue that stereopsis, the perception of depth using both eyes, also constitutes a sense, but it is generally regarded as a cognitive (that is, post-sensory) function of the visual cortex of the brain where patterns and objects in images are recognized and interpreted based on previously learned information. This is called visual memory.

The inability to see is called blindness. Blindness may result from damage to the eyeball, especially to the retina, damage to the optic nerve that connects each eye to the brain, and/or from stroke (infarcts in the brain). Temporary or permanent blindness can be caused by poisons or medications.

People who are blind from degradation or damage to the visual cortex, but still have functional eyes, are actually capable of some level of vision and reaction to visual stimuli but not a conscious perception; this is known as blindsight. People with blindsight are usually not aware that they are reacting to visual sources, and instead just unconsciously adapt their behaviour to the stimulus.

On February 14, 2013 researchers developed a neural implant that gives rats the ability to sense infrared light which for the first time provides living creatures with new abilities, instead of simply replacing or augmenting existing abilities.[3]


Hearing or audition (adjectival form: auditory) is the sense of sound perception. Hearing is all about vibration. Mechanoreceptors turn motion into electrical nerve pulses, which are located in the inner ear. Since sound is vibration, propagating through a medium such as air, the detection of these vibrations, that is the sense of the hearing, is a mechanical sense because these vibrations are mechanically conducted from the eardrum through a series of tiny bones to hair-like fibers in the inner ear, which detect mechanical motion of the fibers within a range of about 20 to 20,000 hertz,[4] with substantial variation between individuals. Hearing at high frequencies declines with an increase in age. Inability to hear is called deafness or hearing impairment. Sound can also be detected as vibrations conducted through the body by tactition. Lower frequencies that can be heard are detected this way. Some deaf people are able to determine direction and location of vibrations picked up through the feet.[5]


Taste or gustation (adjectival form: gustatory) is one of the traditional five senses. It refers to the capability to detect the taste of substances such as food, certain minerals, and poisons, etc. The sense of taste is often confused with the "sense" of flavor, which is a combination of taste and smell perception. Flavor depends on odor, texture, and temperature as well as on taste. Humans receive tastes through sensory organs called taste buds, or gustatory calyculi, concentrated on the upper surface of the tongue. There are five basic tastes: sweet, bitter, sour, salty and umami. Other tastes such as calcium[6][7] and free fatty acids[8] may also be basic tastes but have yet to receive widespread acceptance. The inability to taste is called ageusia.


Smell or olfaction (adjectival form: olfactory) is the other "chemical" sense. Unlike taste, there are hundreds of olfactory receptors (388 according to one source[9]), each binding to a particular molecular feature. Odor molecules possess a variety of features and, thus, excite specific receptors more or less strongly. This combination of excitatory signals from different receptors makes up what we perceive as the molecule's smell. In the brain, olfaction is processed by the olfactory system. Olfactory receptor neurons in the nose differ from most other neurons in that they die and regenerate on a regular basis. The inability to smell is called anosmia. Some neurons in the nose are specialized to detect pheromones.[10]


Touch or somatosensation (adjectival form: somatic), also called tactition (adjectival form: tactile) or mechanoreception, is a perception resulting from activation of neural receptors, generally in the skin including hair follicles, but also in the tongue, throat, and mucosa. A variety of pressure receptors respond to variations in pressure (firm, brushing, sustained, etc.). The touch sense of itching caused by insect bites or allergies involves special itch-specific neurons in the skin and spinal cord.[11] The loss or impairment of the ability to feel anything touched is called tactile anesthesia. Paresthesia is a sensation of tingling, pricking, or numbness of the skin that may result from nerve damage and may be permanent or temporary.

Non-traditional senses

Balance and acceleration

Main article: Vestibular system

Balance, equilibrioception, or vestibular sense is the sense that allows an organism to sense body movement, direction, and acceleration, and to attain and maintain postural equilibrium and balance. The organ of equilibrioception is the vestibular labyrinthine system found in both of the inner ears. In technical terms, this organ is responsible for two senses of angular momentum acceleration and linear acceleration (which also senses gravity), but they are known together as equilibrioception.

The vestibular nerve conducts information from sensory receptors in three ampulla that sense motion of fluid in three semicircular canals caused by three-dimensional rotation of the head. The vestibular nerve also conducts information from the utricle and the saccule, which contain hair-like sensory receptors that bend under the weight of otoliths (which are small crystals of calcium carbonate) that provide the inertia needed to detect head rotation, linear acceleration, and the direction of gravitational force.


Thermoception is the sense of heat and the absence of heat (cold) by the skin and internal skin passages, or, rather, the heat flux (the rate of heat flow) in these areas. There are specialized receptors for cold (declining temperature) and for heat (increasing temperature). The cold receptors play an important part in the animal's sense of smell, telling wind direction. The heat receptors are sensitive to infrared radiation and can occur in specialized organs, for instance in pit vipers. The thermoceptors in the skin are quite different from the homeostatic thermoceptors in the brain (hypothalamus), which provide feedback on internal body temperature.


Proprioception, the kinesthetic sense, provides the parietal cortex of the brain with information on the movement and relative positions of the parts of the body. Neurologists test this sense by telling patients to close their eyes and touch their own nose with the tip of a finger. Assuming proper proprioceptive function, at no time will the person lose awareness of where the hand actually is, even though it is not being detected by any of the other senses. Proprioception and touch are related in subtle ways, and their impairment results in surprising and deep deficits in perception and action.[12]


Nociception (physiological pain) signals nerve-damage or damage to tissue. The three types of pain receptors are cutaneous (skin), somatic (joints and bones), and visceral (body organs). It was previously believed that pain was simply the overloading of pressure receptors, but research in the first half of the 20th century indicated that pain is a distinct phenomenon that intertwines with all of the other senses, including touch. Pain was once considered an entirely subjective experience, but recent studies show that pain is registered in the anterior cingulate gyrus of the brain.[13] The main function of pain is to attract our attention to dangers and motivate us to avoid them. For example, humans avoid touching a sharp needle, or hot object, or extending an arm beyond a safe limit because it is dangerous, and thus hurts. Without pain, people could do many dangerous things without being aware of the dangers.

Other internal senses

An internal sense also known as interoception[14] is "any sense that is normally stimulated from within the body".[15] These involve numerous sensory receptors in internal organs, such as stretch receptors that are neurologically linked to the brain. Interoception is thought to be atypical in clinical conditions such as alexithymia.[16] Some examples of specific receptors are:

Perception not based on a specific sensory organ


Chronoception refers to how the passage of time is perceived and experienced. Although the sense of time is not associated with a specific sensory system, the work of psychologists and neuroscientists indicates that human brains do have a system governing the perception of time,[19][20] composed of a highly distributed system involving the cerebral cortex, cerebellum and basal ganglia. One particular component, the suprachiasmatic nucleus, is responsible for the circadian (or daily) rhythm, while other cell clusters appear to be capable of shorter-range (ultradian) timekeeping.

One or more dopaminergic pathways in the central nervous system appear to have a strong modulatory influence on mental chronometry, particularly interval timing.[21]

Non-human senses

Analogous to human senses

Other living organisms have receptors to sense the world around them, including many of the senses listed above for humans. However, the mechanisms and capabilities vary widely.


Most non-human mammals have a much keener sense of smell than humans, although the mechanism is similar. An example of smell in non-mammals is that of sharks, which combine their keen sense of smell with timing to determine the direction of a smell. They follow the nostril that first detected the smell.[22] Insects have olfactory receptors on their antennae.

Vomeronasal organ

Many animals (salamanders, reptiles, mammals) have a vomeronasal organ[23] that is connected with the mouth cavity. In mammals it is mainly used to detect pheromones of marked territory, trails, and sexual state. Reptiles like snakes and monitor lizards make extensive use of it as a smelling organ by transferring scent molecules to the vomeronasal organ with the tips of the forked tongue. In reptiles the vomeronasal organ is commonly referred to as Jacobsons organ. In mammals, it is often associated with a special behavior called flehmen characterized by uplifting of the lips. The organ is vestigial in humans, because associated neurons have not been found that give any sensory input in humans.[24]


Flies and butterflies have taste organs on their feet, allowing them to taste anything they land on. Catfish have taste organs across their entire bodies, and can taste anything they touch, including chemicals in the water.[25]


Cats have the ability to see in low light, which is due to muscles surrounding their irides–which contract and expand their pupils–as well as to the tapetum lucidum, a reflective membrane that optimizes the image. Pit vipers, pythons and some boas have organs that allow them to detect infrared light, such that these snakes are able to sense the body heat of their prey. The common vampire bat may also have an infrared sensor on its nose.[26] It has been found that birds and some other animals are tetrachromats and have the ability to see in the ultraviolet down to 300 nanometers. Bees and dragonflies[27] are also able to see in the ultraviolet. Mantis shrimps can perceive both polarized light and multispectral images and have twelve distinct kinds of color receptors, unlike humans which have three kinds and most mammals which have two kinds.[28]


Many invertebrates have a statocyst, which is a sensor for acceleration and orientation that works very differently from the mammalian's semi-circular canals.

Sensing gravity

Some plants (such as mustard) have genes that are necessary for the plant to sense the direction of gravity. If these genes are disabled by a mutation, a plant cannot grow upright.[29]

Not analogous to human senses

In addition, some animals have senses that humans do not, including the following:


Main article: Animal echolocation

Certain animals, including bats and cetaceans, have the ability to determine orientation to other objects through interpretation of reflected sound (like sonar). They most often use this to navigate through poor lighting conditions or to identify and track prey. There is currently an uncertainty whether this is simply an extremely developed post-sensory interpretation of auditory perceptions or it actually constitutes a separate sense. Resolution of the issue will require brain scans of animals while they actually perform echolocation, a task that has proven difficult in practice.

Blind people report they are able to navigate and in some cases identify an object by interpreting reflected sounds (especially their own footsteps), a phenomenon known as human echolocation.


Electroreception (or electroception) is the ability to detect electric fields. Several species of fish, sharks, and rays have the capacity to sense changes in electric fields in their immediate vicinity. For cartilaginous fish this occurs through a specialized organ called the Ampullae of Lorenzini. Some fish passively sense changing nearby electric fields; some generate their own weak electric fields, and sense the pattern of field potentials over their body surface; and some use these electric field generating and sensing capacities for social communication. The mechanisms by which electroceptive fish construct a spatial representation from very small differences in field potentials involve comparisons of spike latencies from different parts of the fish's body.

The only orders of mammals that are known to demonstrate electroception are the dolphin and monotreme orders. Among these mammals, the platypus[30] has the most acute sense of electroception.

A dolphin can detect electric fields in water using electroreceptors in vibrissal crypts arrayed in pairs on its snout and which evolved from whisker motion sensors.[31] These electroreceptors can detect electric fields as weak as 4.6 microvolts per centimeter, such as those generated by contracting muscles and pumping gills of potential prey. This permits the dolphin to locate prey from the seafloor where sediment limits visibility and echolocation.

Body modification enthusiasts have experimented with magnetic implants to attempt to replicate this sense.[32] However, in general humans (and it is presumed other mammals) can detect electric fields only indirectly by detecting the effect they have on hairs. An electrically charged balloon, for instance, will exert a force on human arm hairs, which can be felt through tactition and identified as coming from a static charge (and not from wind or the like). This is not electroreception, as it is a post-sensory cognitive action.


Magnetoception (or magnetoreception) is the ability to detect the direction one is facing based on the Earth's magnetic field. Directional awareness is most commonly observed in birds, which rely on their magnetic sense to navigate during migration.[33][33][34][35][36] It has also been observed in insects such as bees. Cattle make use of magnetoception to align themselves in a north-south direction.[37] Magnetotactic bacteria build miniature magnets inside themselves and use them to determine their orientation relative to the Earth's magnetic field.[38][39]


Hygroreception is the ability to detect changes in the moisture content of the environment.[40][41]

Infrared sensing

The ability to sense infrared thermal radiation evolved independently in various families of snakes. Essentially, it allows these reptiles to "see" radiant heat at wavelengths between 5 and 30 μm to a degree of accuracy such that a blind rattlesnake can target vulnerable body parts of the prey at which it strikes.[42] It was previously thought that the organs evolved primarily as prey detectors, but it is now believed that it may also be used in thermoregulatory decision making.[43] The facial pit underwent parallel evolution in pitvipers and some boas and pythons, having evolved once in pitvipers and multiple times in boas and pythons.[44] The electrophysiology of the structure is similar between the two lineages, but they differ in gross structural anatomy. Most superficially, pitvipers possess one large pit organ on either side of the head, between the eye and the nostril (Loreal pit), while boas and pythons have three or more comparatively smaller pits lining the upper and sometimes the lower lip, in or between the scales. Those of the pitvipers are the more advanced, having a suspended sensory membrane as opposed to a simple pit structure. Within the family Viperidae, the pit organ is seen only in the subfamily Crotalinae: the pitvipers. The organ is used extensively to detect and target endothermic prey such as rodents and birds, and it was previously assumed that the organ evolved specifically for that purpose. However, recent evidence shows that the pit organ may also be used for thermoregulation. According to Krochmal et al., pitvipers can use their pits for thermoregulatory decision making while true vipers (vipers who do not contain heat-sensing pits) cannot.

In spite of its detection of IR light, the pits' IR detection mechanism is not similar to photoreceptors – while photoreceptors detect light via photochemical reactions, the protein in the pits of snakes is in fact a temperature sensitive ion channel. It senses infrared signals through a mechanism involving warming of the pit organ, rather than chemical reaction to light.[45] This is consistent with the thin pit membrane, which allows incoming IR radiation to quickly and precisely warm a given ion channel and trigger a nerve impulse, as well as vascularize the pit membrane in order to rapidly cool the ion channel back to its original "resting" or "inactive" temperature.[45]


Plant senses

By using a variety of sense receptors, plants sense light, gravity, temperature, humidity, chemical substances, chemical gradients, reorientation, magnetic fields, infections, tissue damage and mechanical pressure. The absence of a nervous system notwithstanding, plants interpret and respond to these stimuli by a variety of hormonal and cell-to-cell communication pathways that result in movement, morphological changes and physiological state alterations at the organism level, that is, result in plant behavior. Such physiological and cognitive functions are generally not believed to give rise to mental phenomena or qualia, however, as these are typically considered the product of nervous system activity. The emergence of mental phenomena from the activity of systems functionally or computationally analogous to that of nervous systems is, however, a hypothetical possibility explored by some schools of thought in the philosophy of mind field, such as functionalism and computationalism.


Further information: Five wits, Ṣaḍāyatana, Ayatana, and Indriya
Lairesse's Allegory of the Five Senses

In the time of William Shakespeare, there were commonly reckoned to be five wits or five senses.[46] At that time, the words "sense" and "wit" were synonyms,[46] so the senses were known as the five outward wits.[47][48] This traditional concept of five senses is common today.

The traditional five senses are enumerated as the "five material faculties" (pañcannaṃ indriyānaṃ avakanti) in Hindu literature. They appear in allegorical representation as early as in the Katha Upanishad (roughly 6th century BC), as five horses drawing the "chariot" of the body, guided by the mind as "chariot driver".

Depictions of the five traditional senses as allegory became a popular subject for seventeenth-century artists, especially among Dutch and Flemish Baroque painters. A typical example is Gérard de Lairesse's Allegory of the Five Senses (1668), in which each of the figures in the main group alludes to a sense: Sight is the reclining boy with a convex mirror, hearing is the cupid-like boy with a triangle, smell is represented by the girl with flowers, taste is represented by the woman with the fruit, and touch is represented by the woman holding the bird.

See also


  1. Voustianiouk A, Kaufmann H (November 2000). "Magnetic fields and the central nervous system". Clin Neurophysiol. 111 (11): 1934–5. doi:10.1016/S1388-2457(00)00487-9. PMID 11068225.
  2. "Allegory of the Five Senses". The Walters Art Museum.
  3. "Implant gives rats sixth sense for infrared light". Wired UK. 14 February 2013. Retrieved 14 February 2013.
  4. "Frequency Range of Human Hearing, Physics Factbook by Glenn Elert (ed)". Retrieved 2014-04-05.
  5. "Deaf Culture and Communication: A Basic Guide" (PDF). Victorian Deaf Society. 2010.
  6. Tordoff MG (August 2008). "Gene discovery and the genetic basis of calcium consumption". Physiol. Behav. 94 (5): 649–59. doi:10.1016/j.physbeh.2008.04.004. PMC 2574908Freely accessible. PMID 18499198.
  7. "That Tastes ... Sweet? Sour? No, It's Definitely Calcium!". Sciencedaily.
  8. Mattes RD (2009). "Is there a fatty acid taste?". Annu. Rev. Nutr. 29: 305–27. doi:10.1146/annurev-nutr-080508-141108. PMC 2843518Freely accessible. PMID 19400700.
  9. "A Sense of Smell: Olfactory Receptors". Sandwalk.
  10. "The Surprising Impact of Taste and Smell". LiveScience.
  11. Sun YG, Zhao ZQ, Meng XL, Yin J, Liu XY, Chen ZF (September 2009). "Cellular basis of itch sensation". Science. 325 (5947): 1531–4. doi:10.1126/science.1174868. PMC 2786498Freely accessible. PMID 19661382.
  12. "The Importance of the Sense of Touch in Virtual and Real Environments" (PDF). International Society for Haptics.
  13. Fulbright RK, Troche CJ, Skudlarski P, Gore JC, Wexler BE (November 2001). "Functional MR imaging of regional brain activation associated with the affective experience of pain". AJR Am J Roentgenol. 177 (5): 1205–10. doi:10.2214/ajr.177.5.1771205. PMID 11641204.
  14. Craig AD (August 2003). "Interoception: the sense of the physiological condition of the body". Curr. Opin. Neurobiol. 13 (4): 500–5. doi:10.1016/S0959-4388(03)00090-4. PMID 12965300.
  15. Dunn BD, Galton HC, Morgan R, et al. (December 2010). "Listening to your heart. How interoception shapes emotion experience and intuitive decision making". Psychol Sci. 21 (12): 1835–44. doi:10.1177/0956797610389191. PMID 21106893.
  16. Shah, Punit; Hall, Richard; Catmur, Caroline; Bird, Geoffrey (2016-08-01). "Alexithymia, not autism, is associated with impaired interoception". Cortex. 81: 215–220. doi:10.1016/j.cortex.2016.03.021. PMC 4962768Freely accessible. PMID 27253723.
  17. Farr OM, Li CS, Mantzoros CS (May 2016). "Central nervous system regulation of eating: Insights from human brain imaging". Metab. Clin. Exp. 65 (5): 699–713. doi:10.1016/j.metabol.2016.02.002. PMID 27085777.
  18. "How Your Lungs Work". HowStuffWorks.
  19. Rao SM, Mayer AR, Harrington DL (March 2001). "The evolution of brain activation during temporal processing". Nat. Neurosci. 4 (3): 317–23. doi:10.1038/85191. PMID 11224550.
  20. "Brain Areas Critical To Human Time Sense Identified". UniSci – Daily University Science News. 2001-02-27.
  21. Parker KL, Lamichhane D, Caetano MS, Narayanan NS (October 2013). "Executive dysfunction in Parkinson's disease and timing deficits". Front. Integr. Neurosci. 7: 75. doi:10.3389/fnint.2013.00075. PMC 3813949Freely accessible. PMID 24198770. Manipulations of dopaminergic signaling profoundly influence interval timing, leading to the hypothesis that dopamine influences internal pacemaker, or “clock,” activity. For instance, amphetamine, which increases concentrations of dopamine at the synaptic cleft advances the start of responding during interval timing, whereas antagonists of D2 type dopamine receptors typically slow timing;... Depletion of dopamine in healthy volunteers impairs timing, while amphetamine releases synaptic dopamine and speeds up timing.
  22. Gardiner, Jayne M.; Atema, Jelle (2010). "The Function of Bilateral Odor Arrival Time Differences in Olfactory Orientation of Sharks". Current Biology. 20 (13): 1187–1191. doi:10.1016/j.cub.2010.04.053. ISSN 0960-9822. PMID 20541411.
  23. Takami S (August 2002). "Recent progress in the neurobiology of the vomeronasal organ". Microsc. Res. Tech. 58 (3): 228–50. doi:10.1002/jemt.10094. PMID 12203701.
  24. Frasnelli J, Lundström JN, Boyle JA, Katsarkas A, Jones-Gotman M (March 2011). "The vomeronasal organ is not involved in the perception of endogenous odors". Hum Brain Mapp. 32 (3): 450–60. doi:10.1002/hbm.21035. PMC 3607301Freely accessible. PMID 20578170.
  25. Atema, Jelle (1980) "Chemical senses, chemical signals, and feeding behavior in fishes" p. 57–101. In: Bardach, JE Fish behavior and its use in the capture and culture of fishes', The WorldFish Center, ISBN 978-971-02-0003-0.
  26. "The illustrated story of the Vampire bat". Retrieved 2007-05-25.
  27. van Kleef, J.; Berry, R.; Stange, G. (2008). "Directional Selectivity in the Simple Eye of an Insect". Journal of Neuroscience. 28 (11): 2845–2855. doi:10.1523/JNEUROSCI.5556-07.2008. ISSN 0270-6474. PMID 18337415.
  28. Justin Marshall; Johannes Oberwinkler (1999). "Ultraviolet vision: the colourful world of the mantis shrimp". Nature. 401 (6756): 873–874. Bibcode:1999Natur.401..873M. doi:10.1038/44751. PMID 10553902.
  29. Carl Zimmer, "The Search for Genes Leads to Unexpected Places", New York Times, April 27, 2010, page D1, New York edition Plants sensing gravity
  30. "Electroreceptive Mechanisms in the Platypus". Archived from the original on 1999-02-09.
  31. Drake, Nadia (2011). "Life: Dolphin can sense electric fields: Ability may help species track prey in murky waters". Science News. 180 (5): 12–12. doi:10.1002/scin.5591800512. ISSN 0036-8423.
  32. "Implant gives man the sense of "magnetic vision"". Retrieved 2011-04-23.
  33. 1 2 "The Magnetic Sense of Animals". Theoretical and Computational Biophysics Group.
  34. "Built-in GPS in birds in tune with Earth's magnetic field". Baylor College of Medicine.
  35. Wu, L.-Q.; Dickman, J. D. (2012). "Neural Correlates of a Magnetic Sense". Science. 336 (6084): 1054–1057. doi:10.1126/science.1216567. ISSN 0036-8075.
  36. Cressey, Daniel (2012). "Pigeons may 'hear' magnetic fields". Nature. doi:10.1038/nature.2012.10540. ISSN 1744-7933.
  37. "Cattle shown to align north-south". BBC NEWS - Science/Nature.
  38. Blakemore R (October 1975). "Magnetotactic bacteria". Science. 190 (4212): 377–9. doi:10.1126/science.170679. PMID 170679.
  39. Urban JE (November 2000). "Adverse effects of microgravity on the magnetotactic bacterium Magnetospirillum magnetotacticum". Acta Astronautica. 47 (10): 775–80. doi:10.1016/S0094-5765(00)00120-X. PMID 11543576.
  40. Enjin, Anders; Zaharieva, Emanuela E.; Frank, Dominic D.; Mansourian, Suzan; Suh, Greg S. B.; Gallio, Marco; Stensmyr, Marcus C. "Humidity Sensing in Drosophila". Current Biology. doi:10.1016/j.cub.2016.03.049.
  41. Tichy, Harald; Kallina, Wolfgang (2013-01-16). "The Evaporative Function of Cockroach Hygroreceptors". PLOS ONE. 8 (1): e53998. doi:10.1371/journal.pone.0053998. ISSN 1932-6203. PMC 3546976Freely accessible. PMID 23342058.
  42. (Kardong & Mackessy 1991)
  43. (Krochmal et al. 2004)
  44. (Pough et al. 1992)
  45. 1 2 (Gracheva et al. 2010)
  46. 1 2 Horace Howard Furness (1880). "King Lear". Shakespeare. 5 (7th ed.). Philadelphia: J.B. Lippincott Co. p. 187. OCLC 1932507.
  47. "wit". The Merriam-Webster new book of word histories. Merriam-Webster. 1991. p. 508. ISBN 0-87779-603-3. OCLC 24246335.
  48. Clive Staples Lewis (1990). "Sense". Studies in Words (2nd (republished) ed.). Cambridge University Press. p. 147. ISBN 0-521-39831-2. OCLC 489987083.
Wikiquote has quotations related to: Senses
Wikiversity has learning materials about What is the sixth sense
Wikimedia Commons has media related to Senses.
This article is issued from Wikipedia - version of the 11/27/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.