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Eye - Cytology | | Eye - Cytology: Encyclopedia II - Eye - Cytology | | The retina contains two forms of photosensitive cells - rods and cones. Though structurally and metabolically similar, their function is quite different, though they are equally important to vision. Rod cells are highly sensitive to light allowing them to respond in dim light and dark conditions. These are the cells which allow humans and other animals to see by moonlight, or with very little available light (as in a dark room). However, they do not distinguish between colours, and have low visual acuity (a measure of detail). This is why th ...
See also:Eye, Eye - Varieties of eyes, Eye - Evolution of eyes, Eye - Anatomy, Eye - Cytology, Eye - Acuity, Eye - Dynamic range, Eye - Adnexa and related parts, Eye - The orbit, Eye - Eyebrows, Eye - Eyelids, Eye - Eyelashes, Eye - Eye movement, Eye - Rapid eye movement, Eye - Saccades, Eye - Microsaccades, Eye - Vestibulo-ocular reflex, Eye - Smooth pursuit movement, Eye - Optokinetic reflex, Eye - Vergence movement, Eye - Accommodation, Eye - Diseases disorders and age-related changes | | | Eye, Eye - Accommodation, Eye - Acuity, Eye - Adnexa and related parts, Eye - Anatomy, Eye - Cytology, Eye - Diseases disorders and age-related changes, Eye - Dynamic range, Eye - Evolution of eyes, Eye - Eye movement, Eye - Eyebrows, Eye - Eyelashes, Eye - Eyelids, Eye - Microsaccades, Eye - Optokinetic reflex, Eye - Rapid eye movement, Eye - Saccades, Eye - Smooth pursuit movement, Eye - The orbit, Eye - Varieties of eyes, Eye - Vergence movement, Eye - Vestibulo-ocular reflex, WikiSaurus:eye — the WikiSaurus list of synonyms and slang words for eyes in many languages, Adaptation, Binocular vision, Corrective lens, Crystallin, Evil eye, Eye color, Eye contact, Eye tracking, Eyeglass prescription, Macropsia, Micropsia, Nictitating membrane, Ocular tremor, Ophthalmology, Optician, Optometry, Persistence of vision, Phosphenes, Snellen chart, Staring contest, Tears, Visual perception | | |
| | | Eye: Encyclopedia II - Eye - Cytology
Eye - Cytology
The retina contains two forms of photosensitive cells - rods and cones. Though structurally and metabolically similar, their function is quite different, though they are equally important to vision. Rod cells are highly sensitive to light allowing them to respond in dim light and dark conditions. These are the cells which allow humans and other animals to see by moonlight, or with very little available light (as in a dark room). However, they do not distinguish between colours, and have low visual acuity (a measure of detail). This is why the darker conditions become, the less colour objects seem to have. Cone cells, conversely, need high light intensities to respond and have high visual acuity. Different cone cells respond to different colours (wavelengths) of light, which allows an organism to see colour.
The differences are useful; apart from enabling sight in both dim and light conditions, humans have given them further application. The fovea, directly behind the lens, consists of mostly densely-packed cone cells. This gives humans a highly detailed central vision, allowing reading, bird watching, or any other task which primarily requires looking at things. Its requirement for high intensity light does cause problems for astronomers, as they cannot see dim stars, or other objects, using central vision because the light from these is not enough to stimulate cone cells. Because cone cells are all that exist directly in the fovea, astronomers have to look at stars through the "corner of their eyes" (averted vision) where rods also exist, and where the light is sufficient to stimulate cells, allowing the individual to observe distant stars.
Rods and cones are both photosensitive, but respond differently to different frequencies of light. They both contain different pigmented photoreceptor proteins. Rod cells contain the protein rhodopsin and cone cells contain different proteins for each colour-range. The process through which these proteins go is quite similar - upon being subjected to electromagnetic radiation of a particular wavelength and intensity (ie. a colour visible light) the protein breaks down into two constituent products. Rhodopsin, of rods, breaks down into opsin and retinal; iodopsin of cones breaks down into photopsin and retinal. The opsin in both opens ion channels on the cell membrane which leads to the generation of an action potential (an impulse which will eventually get to the visual cortex in the brain).
This is the reason why cones and rods enable organisms to see in dark and light conditions - each of the photoreceptor proteins requires a different light intensity to break down into the constituent products. Further, synaptic convergence means that several rod cells are connected to a single bipolar cell, which then connects to a single ganglion cell and information is relayed to the visual cortex. Whereas, a single cone cell is connected to a single bipolar cell. Thus, action potentials from rods share neurons, where those from cones are given their own. This results in the high visual acuity, or the high ability to distinguish between detail, of cone cells and not rods. If a ray of light were to reach just one rod cell this may not be enough to stimulate an action potential. Because several "converge" onto a bipolar cell, enough transmitter molecules reach the synapse of the bipolar cell to attain the threshold level to generate an action potential.
Furthermore, colour is distinguishable when breaking down the iodopsin of cone cells because there are three forms of this protein. One form is broken down by the particular EM wavelength that is red light, another green light, and lastly blue light. In simple terms, this allows human beings to see red, green and blue light. If all three forms of cones are stimulated equally, then white is seen. If none are stimulated, black is seen. Most of the time however, the three forms are stimulated to different extents - resulting in different colours being seen. If, for example, the red and green cones are stimulated to the same extent, and no blue cones are stimulated, yellow is seen. For this reason red, green and blue are called primary colours and the products of mixing two secondary colours. The secondary colours can be further complimented with primary colours to see tertiary colours.
Other related archivesAccommodation (eye), Adaptation, Anterior chamber, Aqueous humour, Binocular vision, Blind spot, Blinking, Choroid, Ciliary body, Ciliary muscle, Compound eyes, Conjunctiva, Cornea, Corrective lens, Crystallin, Crystalline Lens, David Berlinski, Evil eye, Extraocular muscles, Eye color, Eye contact, Eye movements, Eye tracking, Eyeglass prescription, Fossilization, Fovea, Iris, Lens, List of eye diseases and disorders, Macropsia, Macula, Micropsia, Microsaccade, Nautilus, Nictitating membrane, Ocular manifestations of systemic disease, Ocular tremor, Ophthalmology, Optic disc, Optic nerve, Optician, Optometry, Ora serrata, Origin of Species, Persistence of vision, Phosphenes, Pinhole Camera, Pupil, Purkinje effect, Rapid eye movement, Retina, Saccade, Schlemm's canal, Sclera, Snellen chart, Staring contest, Strepsiptera, Suspensory ligament, Tapetum lucidum, Tears, Trabecular meshwork, Trilobites, Vestibulo-ocular reflex, Visual acuity, Visual perception, Vitreous humour, WikiSaurus, Zonule of Zinn, action potential, amphibians, angular resolution, aqueous humour, arthropods, astigmatism, astronomers, bacterial infection, binocular vision, bipolar cell, birds, birds of prey, blind spot, blood vessels, brain, camera, cell membrane, cephalopods, chameleons, chemical, choroid, chromatic aberration, ciliary body, ciliary muscles, colour vision, cone cells, cones, connective tissue, contrast ratio, converge, convergence, convex, cornea, corneal endothelium, crystallins, degree, diopter, diurnal, divergence, ears, edema, electromagnetic radiation, evolution, eyebrows, eyelashes, eyelids, f-number, feedback, fibrin, fish, focus, fovea, ganglion cell, hertz, humans, hyperopia, immune system, inferior oblique, inferior rectus, intelligent design, invertebrates, ion channels, iris, lateral rectus, lens, light, mammals, medial rectus, mollusks, monophyletic, moulting, myopia, nerve impulses, ocelli, opsin, optic nerve, orbits, organ, organisms, osmotic, oxygen, parallel evolution, photopsin, photoreceptor, photosensitive, presbyopia, primary colours, proteins, pupil, rabbits, reading, red, green and blue, refraction errors, refractive index, reptiles, respiration, retina, retinal, rhodopsin, rod, rods, sclera, secondary colours, sense, sleep, snails, snakes, squids, stemmata, stops, superior oblique, superior rectus, suspensory ligaments, synapse, tapetum lucidum, three-dimensional, transmitter molecules, transparent, ultraviolet, vertebrates, vision, visual acuity, visual cortex, vitreous humour, wavelengths, yellow
 Adapted from the Wikipedia article "Cytology", under the G.N U Free Docmentation License. Please also see http://en.wikipedia.org/wiki |
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