Table of contents :

• somatic senses : senses other than the special senses
• protopathic sensibility : sensibility to crude stimulations that reach thalamus such as pain, temperature, and some forms of touch, which acts as a defensive agency against pathologic changes in the tissues
• epicritic sensibility : the sensibility of the skin to precise stimulations which furnishes the means for making fine discriminations of touch and temperature in the cerebral cortex
• paleosensation : the sensation of severe pain and marked variations of temperature, as compared with phylogenetically newer sensations such as those of light touch and moderate variations of temperature and the epicritic sensations
• superficial sensibilities cross in spinal cord
• exteroception : pain, tactile, thermal, and pressure senses
• exteroceptive nervous system : that portion of the afferent elements of the somatic nervous system which is sensitive to stimuli originating outside the body.
• interoception : stimuli from receptors in vessels and viscera
• interoceptive nervous system : that system which transmits afferent impulses from viscera by fibers which run centrally either in autonomic or somatic nerves
• subjective sensations
• pain sense / algesia / agesthesia / nociception : the ability to feel pain, caused by stimulation of a nociceptor => Ad fibers and C fibers => contralateral spinothalamic tract => posterior nucleus of thalamus => primary somatosensory area
• gate hypothesis or theory / gate-control theory : neural impulses generated by noxious painful stimuli and transmitted to the spinal cord by small-diameter C fibers and Ad fibers are blocked at their synapses in the dorsal horn by the simultaneous stimulation of large-diameter myelinated Ab fibers, thus inhibiting pain by preventing pain impulses from reaching higher levels of the CNS
• convergence-projection theory : a theory advanced as an explanation for reference of pain, according to which some visceral afferent nerve fibers converge with cutaneous pain afferents to end upon the same neuron at some point in the sensory pathway.
Men are less sensitive than women to pain : the male hormone testosterone leads to an increase in levels of the natural painkillers enkephalins, and such tolerance effects may help men to maintain their stamina in fights, when testosterone levels are high. Testosterone implants to male sparrows allowed the birds to tolerate discomfort caused by dangling one of their legs in a beaker of water at 52°C for longer periods. A drug that blocks the effect of testosterone causes the birds became more than twice as sensitive to water at 48 ºC, a temperature at which they normally showed little discomfort^ref. There could be a case for administering replacement testosterone to men with chronic pain. These men often take drugs that lower normal testosterone levels, interfering with the natural alleviation of their suffering.
Women have long been known to experience more pain than men. And the idea that sex hormones are to blame has just been bolstered by a study into pain thresholds in a unique study group: people undergoing sex-change operations. Men taking female hormones often start to experience chronic pain. In a study of 54 men taking oestrogen and anti-androgens as treatment to become women, 30% reported developing pains, primarily chronic headaches, during their treatment. In another study of women taking testosterone to become men, > 50% found their aches and pains improved. They seemed to feel better generally. The results back up previous research on sex differences in pain. Although no one knows exactly how sex hormones affect pain tolerance, researchers think testosterone dulls pain by muting the excitatory pain pathways in the central nervous system, while oestrogen heightens pain by blocking the inhibitory mechanisms that damp pain sensing. The evidence for this is piling up. But the story about oestrogen is more confusing than it first seemed. On the one hand, pain typically arises during the menstrual cycle when oestrogen is at its lowest ebb, as during menstruation. On the other, girls report more pain than boys from the onset of puberty when oestrogen starts to surge. It seems to be sudden changes in hormone levels that are the problem, rather than the levels themselves. It is the withdrawal or fluctuation of oestradiol that is associated with pain. To check this theory, LeResche is starting to study women who choose to take the contraceptive pill all the way through their cycle, so that they never menstruate. LeResche will investigate whether keeping their oestrogen levels up affects their experience of pain. Clinicians should measure levels of sex hormones in patients. An imbalance could be exacerbating their problems. And hormone replacement therapy could be used in some chronic-pain patients : one trial has been started that bolsters testosterone in male patients with low levels of the hormone. This idea could also be applied to women, although she adds that giving testosterone to women is more complicated than giving it to men.
Associations : International Association for the Study of Pain (IASP)
• objective sensations
• touch / tactile sense / taction / pselaphesia
• topesthesia : the power of localizing a tactile sensation.
Cell types :
• touch-specialized primary sensory neurons
• corpusculum tactus / tactile corpuscle or cell / touch cell or corpuscle / Meissner's corpuscle : a type of medium-sized encapsulated nerve ending found in the skin, most commonly in the palms and soles


• axile or axis corpuscle : the central part of a tactile corpuscle
• corpusculum lamellosum / lamellar or lamellated corpuscle / Pacini's, pacinian, Vater's, and Vater-Pacini corpuscle : a type of large encapsulated nerve ending sensitive to pressure and vibration; the most complicated of the nerve endings, it is found throughout the body



• articular corpuscle : a type of lamellated corpuscle found within joints.
• genital corpuscle : a type of lamellated corpuscle found in the genital mucous membranes and in the skin around the nipples
• paciniform corpuscles or receptors
• Golgi-Mazzoni corpuscles : tactile corpuscles found in the subcutaneous tissue of the fingertips, resembling pacinian corpuscles, but possessing fewer lamellae and a relatively larger cone, and having the contained nerve fibers more extensively branched
• Ruffini's corpuscle, cylinder or ending :  a type of lamellated corpuscle in the dermis that is a slowly-adapting receptor for sensations of continuous pressure
• Timofeew's corpuscle : a specialized form of lamellated corpuscle found in the submucosa of the membranous and prostatic portions of the urethra.
• Merkel cell (Merkel F. Tastzellen und Tastkorperchen bei den Haustieren und beim Menschen. Ark. Mikroskop. Anat. 11:636-652 (1875)) : a specialized cell at or near the DEJ, characterized by numerous membrane-bound granules with dense cores, some desmosomes, cytoplasmic microfilaments, intranuclear filaments bundled in parallel to form rodlets, and spikelike processes that interdigitate with keratinocytes. They are believed to act as touch receptors by association with meniscus tactus / tactile disk or meniscus (one of the small, cup-shaped, tactile nerve endings within the skin; many of them are formed by branches of a single nerve fiber, and each one is in contact with a single, modified epithelial cell (Merkel cell); they are found in the deep epidermis, in hair follicles, and in the hard palate, and function as touch receptors)
• tactile hair disk
• hederiform ending of Merkel-Ranvier found in glabrous skin, nose, lip, palate, and genitalia
• Merkel touch spots (Tastscheiben) found on the palpebral margin of the eyelid
Of Aristotle's 5 senses, we know that sight, smell and much of taste are initiated by ligands binding to GPCRs; however, the mechanical sensations of touch and hearing remain without a clear understanding of their molecular basis. Recently, the relevant force-transducing molecules—the mechanosensitive ion channels—have been identified. Such channel proteins purified from bacteria sense forces from the lipid bilayer in the absence of other proteins. Recent evidence has shown that lipids are also intimately involved in opening and closing the mechanosensitive channels of fungal, plant and animal species^ref.
• temperature sense / thermesthesia / thermoesthesia : the faculty by which differences in temperature are distinguished by the thermoreceptors
• temperature-specialized primary sensory neurons
• rhigosis : the ability to feel cold, dependent on cold-sensitive primary sensory neurons
• corpusculum bulboideum / bulboid corpuscle / bulb of Krause / Krause's corpuscle or end bulb : a type of small encapsulated nerve ending found in the skin, mucous membranes, and conjunctiva, at varying levels; thought to function either as thermoreceptors for cold or as rapidly adapting receptors


• warm-sensitive primary sensory neurons
• deep sensibilities travel in fasciculi gracilis and cuneatus of spinal cord and cross at a suprabulbar level
• proprioceptive sense / proprioception : perception mediated by proprioceptors or proprioceptive tissues.
• proprioceptive nervous system : that portion of the afferent elements of the somatic nervous system which is sensitive to stimuli originating inside the body (from muscles, bones, joints, and ligaments).
• pallesthesia / vibration sense / palmesthesia / bone sensibility : the ability to feel mechanical vibrations on or near the body, such as when a vibrating tuning fork is placed over a bony prominence
• pressure sense / barognosis / piesesthesia / piezesthesia / baresthesia : the faculty by which pressure upon the surface of the body is perceived
• tickling / gargalesthesia : the perception of tickling
• bathyesthesia / deep sensibility / mesoblastic sensibility : sensibility to stimuli such as pain, movement, and pressure that activate receptors below the body surface but not in the viscera. It includes joint sensibility (arthresthesia) and muscle sense (myesthesia).
• joint sense / arthresthesia : joint sensibility; the perception of joint motions.
• posture or position sense : the awareness of the position of the body or its parts in space, a combination of
• sense of  equilibrium / static, labyrinthine or vestibular sense : the sense of maintenance of or divergence from an upright position, controlled by receptors in the vestibule of the ear
• kinesthetic, motion, movement or muscle sense / myesthesia / kinesthesia : the awareness of motion by the head or body, based on input from muscle and joint receptors and hair cells.
• somatognosis / body or sixth sense / cenesthesia / somatesthesia / somesthesia / common sensibility : the general feeling of the existence of one's body and of the functioning of the organs
• stereognosis  / stereocognosy / stereognostic sense : the sense by which form and solidity are perceived
• trichesthesia / trichoesthesia / hair sensibility : the perception that one of the hairs of the skin has been touched, caused by stimulation of a hair follicl receptor.
• graphesthesia : the sense by which figures or numbers are recognized when written on the skin with a dull-pointed object.
• internal, seventh or visceral sense / splanchnesthesia : the awareness of sensations that arise from the viscera and stimulate the interoceptors; sensations include pain, pressure or fullness, and organ movement
Pathways : the primary sensory neuron has soma in the spinal ganglia and is T-shaped : the distal branch reaches periphery together with the motor fibers, while the central branch enters the spinal cord with the posterior root
• epicritic tactile stimuli and deep sensitivity (deep pain, baresthesia, muscular, tendineal and articular proprioception) travels via long fibers of Goll and Burdach fasciculi in posterior cords of psinal cord till to Goll and Burdach nuclei in bulb. The second sensory neuron crosses in the bulb and continue in the medial lemniscus (median Reil's band), which ends in VP_m and VP_l nuclei. The third sensory neuron starts from thalamus in the thalamocortical tract, travels in the the posterior limb of internal capsule, and ends in the primary somatosensory area
• superficial sensitivity (thermal and pain) fibers synapse with second sensory neuron at their enter in spinal cord neuromere : the latter crosses and travel in the spinothalamic tract near the medial lemniscus

• special senses : the senses of seeing, hearing, taste, and smell. Touch is now usually considered a somatic sense, and sense of equilibrium is sometimes considered a special sense.
• organa sensoria or sensuum / sense organs / organs of special sense : organs that receive stimuli that give rise to sensations, i.e., organs that translate certain forms of energy into nerve impulses that are perceived as special sensations; they are characterized by highly specialized neuroreceptors and relationships, and include the visual, vestibulocochlear, olfactory, and gustatory organs
• chemical sense : the senses of smell (olfaction) and taste.
• tongue and taste / gustation (see also diseases of taste, physiology of tongue, and diseases of tongue)
• organum gustatorium / gustatory organ / organum gustus : the organ of taste, comprising the taste buds, most of which are found within the epithelial covering of the tongue
• papillae linguales / lingual papillae : the filiform, fungiform, vallate, foliate, and conical papillae of the tongue.
• papillae filiformes / filiform papillae : threadlike elevations that cover most of the tongue surface.
• papillae conicae / conical papillae : sparsely scattered large elevations on the tongue surface, often considered a modified type of filiform papillae.

• papillae foliatae / foliate papillae : parallel mucosal folds on the margins of the tongue at the junction of its body and root.


• papillae fungiformes / fungiform papillae : knoblike projections on the tongue, scattered singly among the filiform papillae.


• papillae vallatae / circumvallate or vallate papillae: the largest papillae of the tongue, 8 to 12 in number, arranged in the form of a V anterior to the sulcus terminalis of the tongue.


• caliculus gustatorius / taste or gustatory bud / Schwalbe's corpuscle / gemma gustatoria : one of the minute, barrel-shaped terminal organs of the gustatory nerve, situated around the bases of the vallate, fungiform, and foliate papillae of the tongue. It contains several types of cells, including basal cells, taste cells, supporting cells, and some that are both supporting and taste cells
• gustatory papillae type I / supporting or sustentacular cells : cells that serve to provide support and protection and perhaps contribute to the nutrition of principal cells taste buds
• gustatory papillae type II / taste or gustatory cells : the cells in a taste bud that have gustatory receptors and are thus directly involved in taste; they undergo degeneration and replacement every few days
• lingual corpuscle : an encapsulated terminal sensory nerve ending in a lingual papilla.
• taste sensations provide animals with valuable information about the nature and quality of food. Much of what people refer as taste is really smell, in that the mouth serves as a route for some odors to reach receptors in the nasal cavity.
• sweet : an analysis of cat genes shows that they lack functioning taste receptors for sugar. Throw a dog a bone or a bonbon and he'll enjoy either. Humans too have a taste for sugar because, on most mammalian tongues, specialized taste bud receptors pick up on sweet tastes and send a pleasant signal to the brain. The receptors contain a pair of proteins called T1R2 and T1R3, which are hooked together. When sugar binds to these receptors, they set off a cascade of events within the cell that ultimately signal a sweet sensation. Scientists first documented cats' behavioural distaste for sugar in the 1970s^ref. But no one could explain why domestic cats (Felis silvestris catus) couldn't care less about candy. Sequencing of the regions of the domestic cat's DNA that code for the T1R2 and T1R3 proteins showed that the gene for T1R3 lacks 247 base pairs of DNA, which means it cannot produce a working protein. This shortened feline version of T1R3 represents a pseudogene. Genes that are not important for a species' survival tend to accumulate more mutations over time. Many olfactory genes in humans have met this fate: there was no pressure to keep them intact. As a result, we possess a much weaker sense of smell than other animals. As cats are strict carnivores, they may have had no use for tasting sugars. The same genetic deletion was found in close relatives of the domestic cat, including the tiger and cheetah. They hope to find out whether more distant relatives, such as the hyena share the same flaw in their T1R3 gene^ref.
• salty
• bitter taste detection functions as an important sensory input to warn against the ingestion of toxic and noxious substances. T2Rs are a family of approximately 30 highly divergent G-protein-coupled receptors (GPCRs) that are selectively expressed in the tongue and palate epithelium and are implicated in bitter taste sensing. T2R receptors are necessary and sufficient for the detection and perception of bitter compounds, and differences in T2Rs between species (human and mouse) can determine the selectivity of bitter taste responses. In addition, mice engineered to express a bitter taste receptor in 'sweet cells' become strongly attracted to its cognate bitter tastants, whereas expression of the same receptor (or even a novel GPCR) in T2R-expressing cells resulted in mice that are averse to the respective compounds. Together these results illustrate the fundamental principle of bitter taste coding at the periphery: dedicated cells act as broadly tuned bitter sensors that are wired to mediate behavioural aversion^ref
• sour
• savoury or umami
• nose and olfaction / smell / osmesthesia / osphresis (rhinology) (see also diseases of olfaction, physiology of nose, and diseases of nose)
• organum olfactorium / olfactory organ / organ olfactus : the specialized structures subserving the function of the sense of smell, including the olfactory region of the nasal mucosa containing the bipolar cells of origin of the olfactory nerves, together with the olfactory glands
• olfactory mucosa or membrane : the olfactory portion of the mucous membrane lining the nasal fossa.
• Brunn's membrane : the epithelium of the olfactory region of the nose
• Schultze's olfactory receptor cells : a set of specialized, fusiform nerve cells with large nuclei, embedded among the epithelial cells in the mucous membrane of the nose; they carry impulses from the olfactory receptors to the glomeruli in the olfactory bulb
• basal olfactive neuron stem cell
• granule cells : diminutive stellate cells
• olfactory glomerulus : one of the small globular masses of dense neuropil in the olfactory bulb; it contains the first synapse in the olfactory pathway and the axons of olfactory cells synapse here with dendrites primarily of mitral cells and tufted cells.
• supporting or sustentacular cells : cells that serve to provide support and protection and perhaps contribute to the nutrition of principal or other cells of olfactory epithelium
• zone of oval nuclei : a narrow band of sustentacular cells with oval nuclei in the olfactory mucosa.
• zone of round nuclei : a broad band of olfactory cells with round nuclei in the olfactory mucosa.
• glandulae olfactoriae / Bowman's olfactory glands : small mucous glands in the olfactory mucosa
• olfactory bulb
Phylogenesis : most modern fish have 4 external nostrils, whereas land vertebrates have choanae. Some experts suggested that choanae evolved through the gradual repositioning of external nostrils, but sceptics countered that this would involve the nostrils migrating through the line of the teeth, a feature not seen in any fossil until a 395-million-year-old fish precursor of land vertebrates, Kenichthys campbelli, which has nostrils in the middle of its upper teeth, a halfway point in the evolutionary reshuffling of the external nostrils back through the teeth and palate. This theory is also bolstered by the fact that no known animal has both choanae and a double pair of external nostrils^ref.
Odorous substances : humans can recognize, and form memories of, around 10,000 different odours. Human genome contains 347 olfactory genes - fully 1%  of the total - while there are only 4, for example, for vision. At least half of those genes are polymorphous, meaning that they have a great potential of variation among themselves. Teeth provide the brain nearly half of the information it receives related to taste, and the nose collects most of the rest - via the mouth. The tongue is rather useless. That's one reason that older people are less sensitive to odours
• pure odoriferous substances (used to test olfaction) :
• coffee
• phenylethylic alcohol
• lavanda oil
• betulla catram
• cinnamom
• olfacto-trigeminal substances :
• benzaldehyde
• mentol
• trementine
• petroil
• piperite menta
• camphore
• alcohol
• formalin
• acetic acid
• citric acid
• ammonium
• olfacto-gustatory substances
• vanilla
• olfacto-gustatory-trigeminal substances
• chloroform
• pyridine
Each olfactory sensory neuron (OSN) in the nasal olfactory epithelium expresses a single functional odorant receptor gene^ref, and OSNs with the same odorant receptor are randomly dispersed within one olfactory epithelial zone^{ref1, ref2}. Consistent with their ability to detect and discriminate diverse odorants, mammals have as many as 1,000 different odorant receptors that vary in protein sequence^{ref1, ref2, ref3} and are used combinatorially to detect different odorants and encode their unique identities^ref. These features of the odorant receptor family would seem to account easily for the odorant recognition abilities of mammals. However, a small percentage of OSNs lack G_olf^ref, the G protein through which odorant receptors signal^ref, suggesting that they might express another class of chemosensory receptor. In addition, small peptides that bind major histocompatibility complex (MHC) proteins can stimulate some OSNs^ref, suggesting that those OSNs might express a class of receptor that detects peptides rather than small volatile odorants. Finally, although many pheromones are detected in the vomeronasal organ—an olfactory structure with receptors that differ from odorant receptors^{ref1, ref2}—responses to some mouse pheromones involve the olfactory epithelium^{ref1, ref2, ref3}, raising the possibility that the olfactory epithelium also contains a dedicated class of pheromone receptors. Certain chemicals in mouse urine can alter the social or sexual behaviour of other mice. These chemicals work partly by binding to receptors in a particular structure in the mouse nose, known as the vomeronasal organ. In humans, however, this organ is thought to be defunct and the role of pheromones is hotly debated. Finding such receptors in the lining of the nose, rather the vomeronasal organ, is a more direct parallel with humans^ref. A second family of receptors in the mouse olfactory epithelium was discovered in 2006. Like odorant receptors, individual mouse trace amine-associated receptors (TAARs) are expressed in unique subsets of neurons dispersed in the epithelium. It is highly unlikely that TAARs are coexpressed with odorant receptors. In mutant mice that express the odorant receptor MOR28 (Olfr1507) in 50–90% of OSNs^ref, only 0.8% (2 in 250), rather than 50–90%, of neurons that hybridized to Taar6 or Taar7f probes were co-labelled by a MOR28 probe. It is difficult to completely exclude coexpression of odorant receptors and TAARs in non-transgenic olfactory epithelium, because each odorant receptor gene is typically expressed in only 1 in 1,000 OSNs, or 1 in 250 in the odorant receptor's expression zone^{ref1, ref2}. Notably, at least three murine TAARs detect compounds found in mouse urine, an important source of social cues^{ref1, ref2}. One detects a chemical (b-phenylethylamine) that is elevated in urine in response to stress, whereas two others detect chemicals (isoamylamine and trimethylamine) that are elevated in male versus female mouse urine. Moreover, one of these compounds (isoamylamine) is reported to act as a male-derived pheromone that accelerates puberty onset in female mice^ref. In addition, the mouse TAAR that recognizes trimethylamine is activated by extremely dilute mouse urine from sexually mature males, but not females or prepubescent males. Together, these findings suggest that at least some murine TAARs detect social cues that may elicit innate behaviours or physiological responses. This idea is consistent with observations that the olfactory epithelium is involved in some pheromone responses^{ref1, ref2, ref3, ref4}, and that certain pheromone responses may involve dual signals from the olfactory epithelium and vomeronasal organ^ref. In this regard, it is interesting that one amine reported to accelerate puberty (isoamylamine) is detected by a TAAR whereas another (isobutylamine) is detected by receptors in the vomeronasal organ^ref. Future studies should provide information on the ligands of additional TAAR family members and illuminate the functional roles played by individual TAARs. Researchers have not yet carried out a key test to show that activating or eliminating the receptors alters a mouse's behaviour. But they might be pheromone receptors. So far, most evidence for human pheromones has come from behavioural research. Women's menstrual cycles changed in length after they sniffed the sweat on pads previously worn in the armpits of another woman^ref. Newborn babies move towards a pad carrying the smell of their mother's breast rather than a clean pad^ref. Human behaviour is influenced by so many conscious and unconscious factors that it's hard to measure the subtle changes in behaviour caused by a putative pheromone. Work on human pheromones seems always to capture both public interest and scientific scepticism. If the receptors discovered in mice are indeed pheromone receptors, this could allow researchers to ask concrete questions about human pheromones. Scientists could, for instance, study people with mutant versions of the receptors to see if they behave differently when exposed to candidate pheromones. he latest study makes it harder for the sceptics. Hopefully, this will catalyse a lot of research by high-powered scientists. Neuroscientists already know that genes in neurons in the lining of the nose make > 1,000 different olfactory receptors for identifying chemical odours. The discovery of this gene family won Buck and Richard Axel the 2004 Nobel Prize in Physiology or Medicine. To look for other classes of receptor, Liberles and Buck isolated neurons from mouse noses and searched for genes that were active only in those cells and were similar to olfactory receptors. There are 6 genes that code for TAARs in humans. The researchers next searched through a set of other chemicals to find those that activated the TAAR receptors. 3 of the chemicals they found are present in mouse urine, which is known to affect the animals' social behaviour. One in particular earns the label of a pheromone because it is produced in the urine of male mice and accelerates the onset of puberty in females. There may be other as yet undiscovered sensory receptors involved in detecting mammalian pheromones, perhaps including human ones. A paper in 2000 showed that a gene for one mouse pheromone receptor in the vomeronasal organ is also active in the human nose^ref. There might be other unidentified ones out there. Liberles and Buck are now testing whether there are molecules in human urine, sweat and vaginal fluid that can trigger the receptors and that mig ht be human pheromones. They also want to examine whether the neurons manufacturing the newfound receptors are wired up in the brain in a different way from regular, smell-detecting neurons. If so, they might connect to centres that control our behaviour or emotions
Web resources :
• Olfactory Receptor Database (ORDB) at SenseLab, Yale University
• Chemoreception in olfaction
• eyeball / globe and vision / sight (oculistics) (see also diseases of eyes and vision and geometric optics)



• visual system : the series of structures by which visual sensations are received from the environment and conveyed as signals to the CNS; it consists of the photoreceptors in the retina and the afferent fibers in the optic nerve, chiasm, and tract.
The acquisition of the upright walking causes folds in neural tube to maintain horizontal visual axes.
• caliculus ophthalmicus / ophthalmic, ocular or optic cup : an indentation of the distal wall of the optic vesicle, brought about by rapid marginal growth and producing a double-layered cup, attached to the diencephalon by a tubular stalk
• choroid or optic fissure : in the embryo, a ventral fissure formed by invagination of the optic vesicle and its stalk, permitting the ingrowth of the mesoblast
Average sizes :
• anteroposterior diameter : 23.3 mm
• vertical diameter : 23 mm
Tissues (tunicae) :
• tunica fibrosa
• sclera (posterior 5/6) : connective tissue with randomly arrayed collagen fibers
• lamina cribrosa : sieve-like structure in the sclera through which exit the eyeball
• short ciliary nerves
• long ciliary nerves
• short posterior ciliary vessels
• long posterior ciliary vessels
• 4 holes for venae vorticosae / vortex veins
• insertion of extrinsic ocular muscles
• limbus : circular zone where the cornea joins the sclera and where corneal epithelial stem cells are located
• cornea (anterior 1/6) : corneal avascularity—the absence of blood vessels in the cornea—is required for optical clarity and optimal vision, and has led to the cornea being widely used for validating pro- and anti-angiogenic therapeutic strategies for many disorders. But the molecular underpinnings of the avascular phenotype have until now remained obscure and are all the more remarkable given the presence in the cornea of VEGF-A, a potent stimulator of angiogenesis, and the proximity of the cornea to vascularized tissues. The cornea expresses soluble VEGFR1 and suppression of this endogenous VEGF-A trap by neutralizing antibodies, RNA interference or Cre-lox-mediated gene disruption abolishes corneal avascularity in mice. The spontaneously vascularized corneas of corn1 and Pax6^+/- mice and Pax6^+/- patients with aniridia are deficient in sflt-1, and recombinant sflt-1 administration restores corneal avascularity in corn1 and Pax6^+/- mice. Manatees, the only known creatures uniformly to have vascularized corneas, do not express sflt-1, whereas the avascular corneas of dugongs, also members of the order Sirenia, elephants, the closest extant terrestrial phylogenetic relatives of manatees, and other marine mammals (dolphins and whales) contain sflt-1, indicating that it has a crucial, evolutionarily conserved role. The recognition that sflt-1 is essential for preserving the avascular ambit of the cornea can rationally guide its use as a platform for angiogenic modulators, supports its use in treating neovascular diseases, and might provide insight into the immunological privilege of the cornea^ref
• corneal squamous multilayered epithelium (50-100 mm)
• surface cell in squamous epithelia
• wing cells : cells in the corneal epithelium with convex anterior surfaces and concave posterior surfaces.
• basal layer of cells
• basement membrane
• Bowman's membrane / anterior limiting lamina of stroma (12 mm)
• corneal stroma (500 mm) : about 200 layers of collagen fibers arranged into fibrous bundles. X-ray scattering has shown that most bundles at the cornea's centre are arranged either vertically (pointing from eyebrow to cheek) or horizontally (from nose to ear). And at the edge of the cornea, most of the bundles are arranged so as to form a ring around the eye : this arrangement strengthens the region where the cornea joins the sclera
• fibroblast
• keratan sulfate proteoglycans (KSPGs)
• keratocan
• lumican
• mimecan
• Descemet's membrane / posterior limiting lamina of stroma (4-10mm)
• corneal endothelium (5 mm) : the single layer of nonkeratinized squamous cells that covers the inner surface of the cornea and maintains proper fluid balance within the cornea; not renawable cells. It has irregular surface to maintain tears.
• corneal "endothelial" cell (3,200 cells/mm², decreasing with age)
• Hudson-Stähli pigment line / pigmented or superficial line of the cornea : a linear horizontal brown mark located at about the junction of the middle and lower thirds of the cornea but not reaching the limbus, seen in the normal corneas of 16% of aged individuals
• corneal stem cells
Sizes :
• posterior face diameter : 13 mm
• posterior curvature radius : 6.8 mm
• anterior face diameter :
• horizontal anterior diameter : 12 mm
• vertical anterior diameter : 11 mm
• anterior curvature radius : 7.8 mm
• thickness :
• 1.1 mm in periphery
• 0.8 mm at center

• tunica vasculosa / uvea / uveal tract
• anterior uvea / iris
• epithelium
• stroma
• flattened fibroblasts
• melanocytes
• iris myoepithelial cell : sphincter muscle of the iris : stimulated by parasympathetic nerve fibers from Edinger-Westphal nucleus in oculomotor nerve (III) in increased light conditions, causing miosis
• clump cells : round, thick, pigmented cells seen in the sphincter muscle of the iris
• dilator muscle of the iris : contractile projections of the external retinal layer into stroma; stimulated by orthosympathetic nerve fibers from Budge's ciliospinal center via short and long ciliary nerves in stressful or reduced light conditions, causing mydriasis
• endothelium
• blood vessels consist of coaxial tubes that can be extended or retracted coherently with muscular movement
Color of iris ranges from black to green depending on concentration of melanin and lipofuchsin and blood into vessels (small arterial circle of iris)
• the anterior surface of the iris is divided by the collarette into
• ciliary zone (outer)
• pupillary zone (inner)
• pupil : the opening in the center of the iris that enlarges up to 4 mm (admitting more light) or reduces down to 1 mm (admitting less light)
Vascularization : anterior ciliary arteries
• ciliary body
• pars plana / ciliary orbiculum is the portion closest to choroid, containing orbicular folds
• ciliary crown
• pars plicata contains 70-80 ciliary processes (2 mm-long and 0.5 mm-large extensions that secrete aqueous humor into posterior chamber) separated by valleculae.
• zonule of Zinn / lens suspensory ligament holds the lens in place
• Hannover canal
• spatia zonularia / zonular spaces / Petit's canal : the lymph-filled interstices between the fibers of the zonula ciliaris, communicating with the posterior chamber of the eye
• accessory fibers / auxiliary fibers : those fibers of the zonule of Zinn running perpendicularly to the chief fibers and not reaching the lens of the eye; supporting the fibers running from the ciliary body to the chief fibers and bracing them, including the interciliary fibers and the orbiculociliary fibers
• chief, main or principal fibers : those fibers of the zonule of Zinn which run from the ciliary body to the lens, including the ...
• orbiculoanterocapsular fibers : those chief fibers which have the most posterior and internal position, lying in close relation to the anterior boundary of the vitreous
• orbiculoposterocapsular fibers : those chief fibers which spring from the prolongation of the hyaloid membrane investing the ciliary ring.
• cilioposterocapsular fibers : the most numerous of the chief zonular fibers, arising from the tips and sides of the ciliary processes, passing posteriorly and crossing the anteriorly directed fibers, to insert into the posterior capsule anterior to the insertion of the orbiculoposterocapsular fibers.
• cilioequatorial fibers : those chief fibers which pass from the summits of the ciliary processes to the equator of the lens.
• stroma
• reticular plate : a form of nerve ending in the ciliary body consisting of very fine reticulations of granular nerve fiber
• ciliary muscle
• Brucke muscle (meridian)
• Müller muscle (circular or annular)
• irideal muscle (radial)
Vascularization : short posterior ciliary arteries
• posterior uvea / choroid : the layer in the eye filled with blood vessels that nourishes the outer retina
• suprachoroid layer / lamina suprachoroidea or fusca (the most pigmented layer)
• vascular lamina
• large vessels Haller's layer
• medium sized vessels Sattler's layer
• choriocapillaris / lamina choriocapillaris or choroidocapillaris / choriocapillary layer : the inner layer of the choroid, composed of a single-layered network of small capillaries
• Ruysch's or ruyschian membrane / membrana ruyschiana, tunica ruyschiana, and Ruysch's tunic : the capillary layer of the choroid in addition to the pigmented layer of the retina and Bruch's membrane (the basal complex of the choroid)
• Bruch membrane / lamina vitrea / membrana vitrea or hyaloidea / hyaline or hyaloid membrane / lamina basalis choroidea / lamina limitans posterior corneae
• basal membrane of capillaries
• interposed connective tissue
• basal lamina of retinal pigment epithelium (RPE)
Vascularization from ophthalmic artery : long posterior ciliary arteries
• medial
• lateral
• retina (thickness : 0.4 mm)
• external layer : retinal pigment epithelial (RPE) cells (not pigmented in albinism) are nourished by diffusion from choriocapillaris, absorb light and prevents scattering.
• internal layer
• blind retina (cubic epithelium)
• ciliary body blind retina (filtering humor aqueous)
• irideal blind retina (pigmented)
• ora serrata retinae : the irregular anterior margin of the pars optica of the retina, lying internal to the junction of the choroid and the ciliary body.
• Blessig's groove : a trace in the eye of the developing embryo corresponding in position with the future ora serrata retinae
• pars optica of the retina / neurosensory retina (covering choroid) : the miniscule marine worm Platynereis dumerilii (Dumeril's clam worm), whose crude light perception seems to have stood it in good stead for millennia, has a few light-sensing cells that come in two types: one is of a type seen almost exclusively in vertebrates, and one is seen in insects. Insect eyes are known to consist of an array of compound lenses, whereas vertebrate eyes contain a single lens. But they are also made of different types of cells: insects' eyes are built up with cells called rhabdomeric photoreceptors; vertebrates use ciliary photoreceptors. The most obvious difference between these cells is in the way the cells increase their surface area to accommodate large numbers of light sensors. Rhabdomeric cells are covered in little finger-like protrusions. Ciliary cells sport hair-like cilia that extend outwards and branch out like tiny umbrellas. Platynereis has rhabdomeric receptors in its tiny eyes, and ciliary cells in its equally tiny brain. The ciliary cells perhaps regulate circadian rhythms by sensing light : there is a direct connection to the area used for locomotion. So if this worm has both kinds of photoreceptor, does that mean that the 2 types of eyes, insect and vertebrate, both originated in an ancestor of this species? If the animal had 2 copies of the genes needed to make one kind of photoreceptor, then the extra set would have been free to evolve into the other photoreceptor. Different animals would subsequently evolve to use the 2 options in different ways^ref.
• layer of rods and cones
• external segment (turnover)
• external fiber (kinocilium)
• internal segment
• ellipsoid
• myoid
• photoreceptor cells / visual cells are nourished by diffusion from choriocapillaris
• rod cells / retinal rods => light sense : the faculty by which different degrees of brilliancy are distinguished via rhodopsin pigment
• cone cells / retinal cones => color sense : the faculty by which various colors are perceived and distinguished.
• blue-sensitive cone cells
• green-sensitive cone cells
• red-sensitive cone cells
• Hering's opponent colors theory : the doctrine that color sensation depends on decomposition and restitution of the visual substance: disassimilation producing red, yellow, and white, and restitution producing blue, green, and black
• Ladd-Franklin theory : a theory of the evolution of color vision: first, light stimulates a substance in the visual cells, producing a sensation of white light; next, molecular changes from the first reaction produce two reactive products, one for each end of the spectrum, for blue and yellow; finally, the reactive product from the yellow becomes two products for red and green. Dichromasies and anomalous trichromasies are considered to be incomplete recapitulations of the evolutionary development.
• Young-Helmholtz theory : the doctrine that color vision depends on 3 sets of retinal fibers, corresponding to the colors red, green, and violet
• cone pedicle : the thick triangular or club-shaped ending of a retinal cone cell, which synapses with the bipolar and horizontal cells in the outer plexiform layer.
• triad of retinal cone : the tip of 2 horizontal cell dendrites and one midget cell dendrite, enclosed in a synaptic invagination of a retinal cone pedicle.
Color vision in Drosophila relies on the comparison between 2 color-sensitive photoreceptors, R7 and R8. 2 types of ommatidia in which R7 and R8 contain different rhodopsins are distributed stochastically in the retina and appear to discriminate short (p-subset) or long wavelengths (y-subset). The choice between p and y fates is made in R7, which then instructs R8 to follow the corresponding fate, thus leading to a tight coupling between rhodopsins expressed in R7 and R8. Warts, encoding large tumor suppressor (Lats) and melted, encoding a PH-domain protein, play opposite roles in defining the yR8 or pR8 fates. By interacting antagonistically at the transcriptional level, they form a bistable loop that insures a robust commitment of R8 to a single fate, without allowing ambiguity. This represents an unexpected postmitotic role for genes controlling cell proliferation (warts and its partner hippo and salvador) and cell growth (melted)^ref.
• a small number of ganglion cells uses melanopsin to tell night from day, but apparently the visual parts of the brain do not use this information. Instead, these cells communicate with the neurons at the base of the brain that set the daily body cycle (for example, mice without working rods or cones cannot see images). But researchers showed that they can still use a small set of melanopsin-containing cells in the retina to adjust their biological clocks : melanopsin is a light-sensitive pigment, as proved by activating the gene for it inside non-vision cells (embryonic mouse neurons, frog eggs or human embryonic kidney cells), and converting them into photoreceptors^{ref1, ref2, ref3}. Very few light-sensitive proteins still work in the cells of different species. Melanopsin resembles pigments in invertebrates' eyes, in that light makes the cells containing it more active. Pigments in vertebrates' rods and cones have the opposite effect, inhibiting their cells. This may help biologists understand the evolution of the circadian rhythm system in humans. The results also underline the possibility of conferring visual powers on unlikely cells. If you could put the melanopsin gene into cells then you could make the normally non-sensitive ones become light-sensitive. It's quite important, because there are some forms of blindness where the rods and cones are lost. In the future, converting other cells in these people's eyes with melanopsin could help them to form images.
• retinal stem cells
Each rod or cone has an inner, axonal, process synapsing with one or more horizontal or bipolar retinal cells, has a soma in the outer nuclear layer, and has a photosensitive outer dendritic process that extends toward the pigment epithelium.
• membrana limitans externa / external limiting membrane : a thin fenestrated layer of the pars nervosa retinae adjacent to the outer nuclear layer and through which extend the visual rods and cones
• outer nuclear layer
• outer plexiform layer
• inner nuclear layer
• horizontal or H cell of retina : retinal neurons for local integration; there are 2 types, and their functions are unclear. Each cell has a multipolar soma in the internal nuclear layer and 1 long neurite and several short ones. All the neurites serve as both axons and dendrites, extending along and ramifying within the internal nuclear layer. The long neurites synapse in the outer plexiform layer with both pedicles and spherules; the short neurites synapse either with pedicles or with spherules.
• inner plexiform layer
• bipolar retinal cells : various types of bipolar neurons that are the second, intermediate, neurons in the vertical linkage of the retina and are analogous to the spinal ganglia
• monosynaptic
• multisynaptic
• ganglionic layer
• multipolar ganglion cells : any of those retinal cells that are the third, last, neurons in the vertical linkage of the retina and are analogous to the relays in the spinal cord and brain stem. At least 6 types of ganglion cells have been classified according to their dendritic patterns. Their axons form the optic nerve
• Müller's fibers / sustentacular fibers / cells of Müller / radial cells of Müller / retinal gliocytes : elongated neuroglial cells traversing all the layers of the retina and forming its most important supporting element
• stratum opticum
• membrana limitans interna
The space between the limiting membranes is nourished by the central retinal artery.
Fundus (oculi) is a collective term for ...
• retina
• optic disk or papilla / optic nerve head / papilla nervi optici / discus opticus / discus nervi optici : the location where the central retinal artery enters and the central retinal vein, as well as the nerve fibers, exits. As this area is photoreceptor-free, it causes physiological blind spot / physiological scotoma
• excavatio disci or papillae nervi optici / excavation of optic disk / optic or physiologic cup : a white depression in the center of the optic disk
• Mariotte's experiment : an experiment to demonstrate the blind spot of the eye: the eye is fixed on the center of a cross marked on a card on which is also marked a large spot; the card is moved to or from the face, and at a certain distance the image of the spot will disappear.
• macula lutea / macula flava retinae : the small, avascular, sensitive area of the central retina, providing vision for fine work and reading (no neurons are present between the limiting membranes).
• fovea (centralis) : a depression in the macula that contains only cones (not rods), providing acute eyesight in many primates, birds and fish
• foveola
• capillary-free zone
• umbo
• papillomacular bundles : an oval shaped arrangement of ganglion cell axons extending from the macula lutea to the optic disk, then entering the optic nerve as discrete bundles.

Vascularization : central retinal vein (blood vessel that collects retinal venous blood drainage) (see also blood-retina barrier)
• chambers of the eye
• anterior chamber of eye / camera anterior bulbi : that portion of the aqueous-containing space which is bounded in front by the cornea and part of the sclera, and behind by the iris, part of the ciliary body, and that part of the lens which presents through the pupil. Normal deepness = 3.1 mm.
• aqueous humor / humor aquosus / hydatoid is a clear fluid ultrafiltrated from blood vessels (20%) and secreted by the ciliary processes of pars plicata in ciliary body (80%) with a circadian rhtythm into posterior chamber, then flows into anterior chamber (where nourishes the crystalline lens and the cornea), and diffusing out of the eye into the blood; regarded as the lymph of the eye, its composition varies from that of lymph in the body generally
• secondary (alternative) aqueous outflow pathway : unconventional or uveoscleral aqueous outflow system (5-15%) refers to aqueous exiting the eye through the anterior face of the ciliary body and percolating through the ciliary muscles to the suprachoroidal space (ie, between the choroid and sclera), where it eventually exits the eye via scleral channels.
• primary (conventional) outflow system : anterior chamber angle / filtration angle (83-96%) (the junction of the cornea and the iris, from which aqueous humor leaves the eye) =>
• sclerocorneal trabecular meshwork and Fontana's spaces : the sponge-like structure that filters the aqueous humor from the anterior chamber and controls its rate of flow out of the eye
• Schlemm’s canal / sinus venosus sclerae : a branching, circumferential vessel lying in the internal scleral sulcus (limbus) that drains the aqueous humor from the anterior chamber after it has flowed through the trabecular meshwork
• aqueous veins : microscopic, blood vessel–like pathways on the surface of the eye, containing aqueous humor or diluted blood
• episcleral veins / venae episclerales : the veins that ring the cornea
• venae vorticosae / vortex veins / posterior ciliary veins / venae choroideae oculi : 4 veins that pierce the sclera and carry blood from the choroid to the superior ophthalmic vein
• conjunctival veins : small veins that drain blood from the conjunctiva to the superior ophthalmic vein
• ophthalmic veins
• vena ophthalmica inferior / inferior ophthalmic vein : a vein formed by confluence of muscular and ciliary branches, and running backward either to join the superior ophthalmic vein or to open directly into the cavernous sinus; it sends a communicating branch through the inferior orbital fissure to join the pterygoid venous plexus.
• vena ophthalmica superior / superior ophthalmic vein : the vein that begins at the medial angle of the eyelid, where it communicates with the frontal, supraorbital, and angular veins; it follows the distribution of the ophthalmic artery, and may be joined by the inferior ophthalmic vein at the superior orbital fissure before opening into the cavernous sinus.
‡ superior orbitary fissure
• cavernous sinus
It undergoes complete turnover every 100'. Normal intraocular pressure (IOP) = 15.2 ± 2.5 mmHg (increasing with age, expecially in females).
• posterior chamber of eye / camera posterior bulbi : that portion of the aqueous-containing space which is bounded in front by the iris, and behind by the lens and ciliary zonule
• (crystalline) lens (thickness = 3.6 mm; refractive power : 13 D in vivo; 22 D ex vivo)
• capsule / crystalloid
• anterior crystalloid (curvature radius = 10 => 6 mm)
• pericapsular membrane and zonular lamella at equator
• posterior crystalloid (curvature radius = - 6 => - 5.5 mm)
• Berger-Wieger hyaloid-capsular ligament
• vortex lentis / nuclear arc or zone : a spiral figure on the surface of the lens of the eye produced by the concentric arrangement of the fibers composing it
• subcapsular epithelium (simple cuboid epithelium)
• anterior lens epithelial cell (LEC)
• susbstantia propria / parenchyma
• lens fiber : lens central fiber cells lose their nuclei during development. The crystallins synthetised are retained throughout life, making them extremely stable proteins. 7 protein regions exist in crystallins: 4 homologous motifs, a connecting peptide, and N- and C-terminal extensions.
• ubiquitous crystallins
• a crystallins are  heterogeneous aggregates consisting of 30-40 subunits coded by 2 gene products
• a_A (for acidic; expression restricted to the lens)
• a_B (for basic; expressed widely in many tissues and organs)
 in a 3:1 ratio. Alpha crystallins can be induced by heat shock and are members of the small heat shock protein (sHSP / HSP20) family. They act as molecular chaperones although they do not renature proteins due to post-translational modification and release them in the fashion of a true chaperone; instead they hold them in large soluble aggregates. 2 additional functions of alpha crystallins are an autokinase activity and participation in the intracellular architecture
• b crystallins form aggregates of different sizes and are able to self-associate to form homodimers or to form heterodimers with other beta-crystallins
• b_A (for acidic; no C-terminal extension)
• b_A1 & b_A3 (alternate translation initiation site)
• b_A2
• b_A4
• b_B (for basic; C-terminal extension)
• b_B1
• b_B2
• b_B3
• g crystallins are a homogeneous group of highly symmetrical, monomeric proteins typically lacking connecting peptides and terminal extensions. They are differentially regulated after early development.
• g_A
• g_B
• g_C
• g_D
• y_{g E}
• y_{g F}
• y_{g G}
• g_N
• g_S
• l 1
• taxon-specific or phylogenetically-restricted crystallins
• m binds thyroid hormone
• z has low expression
• vitreous (body) chamber is the space between the back of the lens and the front face of the retina. Normal deepness = 16.6 mm.
• membrana vitrea / vitreous membrane / membrana hyaloidea / hyaloid membrane : a delicate boundary layer investing the vitreous body of the eye
• hyalocyte
• vitreous humor / humor vitreus : the transparent, colorless, watery mass of gel, resembling aqueous humor, contained within the interstices of the stroma in the vitreous body, lying behind the lens and in front of the retina. It contains :
• collagen, type II, alpha 1 (COL2A1)
• tenascin C (hexabrachion)
• Cloquet's hyaloid canal : space where primary vitreous was; passes through the middle of the vitreous from the optic disk to the lens
It has 3 attachments in the eye :
• annular zone of adhesion straddling the ora serrata retinae
• adhesion between gel and posterior lens capsule
• adhesion to the retina via the inner limiting membrane
Light route : cornea => aqueous humor (in anterior chamber => pupil => aqueous humor in posterior chamber) => lens => vitreous body => membrana limitans interna => ... => membrana limitans externa => photoreceptors (inverted retina in Vertebrata)
Axes : a 23° angle exists between
• axis opticus / optic axis : a line connecting the center of the anterior curvature of the cornea (anterior pole) with that of the posterior curvature of the sclera (posterior pole)
• visual axis : the line between the fovea centralis retinae and the point of fixation, intersecting the optic axis as it passes through the nodal point; it is sometimes defined as the line extending from the fovea to the nodal point and then continuing anteriorly through the cornea.
Protective adnexa / appendages of the eye :
• palpebrum / eyelid
• palpebral fissure : the space between the upper and lower eyelids when the eyes are open
• canthus : the angle formed by the meeting of the upper and lower eyelids
• lateral or temporal canthus
• medial or nasal canthus
• epicanthus / epicanthal or palpebronasal fold / plica palpebronasalis : a vertical fold of skin on either side of the nose, sometimes covering the inner canthus. It is present as a normal characteristic in persons of certain races and sometimes occurs as a congenital anomaly in others
• tarsus / tarsal plate : the dense, plate-like framework within the middle layer of each eyelid that gives the eyelids their firmness and shape
• cilia / eyelash : 150 in upper eyelid, 70 in lower eyelid
• caruncle : small fleshy elevation of epithelium
• orbital septum / septum orbitale / tarsal membrane : a fibrous membrane anchored to the periorbita along the entire margin of the orbit, extending to the levator palpebrae superioris muscle in the upper lid and to the tarsal plate in the lower lid
• muscles
• Müller’s eyelid smooth muscle (innervated by orthosympathetic fibers in cervical plexus)
• levator palpebrae superioris muscle (innervated by oculomotor (III) nerve)
• orbicular muscle (innervated by facial (VII) nerve) => blinking
• spontaneous blinking : 15-20 times per minute (consciousless as lasting less than image latency time)
• voluntary blinking
• reflexed blinking starting from cranial nerve I, V or VII
The world doesn't go dark when we blink because a critical part of the brain switches off and fails to detect the blackness behind closed eyes. An optical fibre was inserted into the mouths of people wearing black-out goggles : the fibre illuminated the back of the subjects' retinas, so that they saw a light at all times, even when they blinked. This allowed^{refBristow D, 1296-1300} to distinguish between the effects of the act of blinking and the darkness that it causes. Using fMRI brains scans, it was shown that activity in V3 area was suppressed in subjects when they blinked. It's not that the visual gap is filled in. It's that you're not aware of it. Similar inactivation is known to allow us to see a smooth image even when our eyes jump between two parts of a scene. But working out what happens in the brain during blinking has proven very difficult. Blinks normally cause an abrupt change in the amount of light reaching the retina, which in turn causes a massive change in brain activity in the visual region. Seeing any effect in the V3 area has been obscured by this in the past. Blinking is not the only process that causes areas of the brain to be suppressed. fMRI scans have shown that tactile areas of the brain are suppressed when we tickle ourselves, but not when someone else does it^ref. How do we distinguish between what is caused by you and what is caused by the outside world? It's more important, for all animals, to pay attention to outside causes. Blinking is a way of studying how they do so.
• lacrimal apparatus / apparatus lacrimalis : the system concerned with the secretion and circulation of the tears and the normal fluid of the conjunctival sac; it consists of the lacrimal gland and ducts, and associated structures
• Rosenmüller's gland : pars palpebralis glandulae lacrimalis
• ductuli excretorii glandulae lacrimalis / excretory ductules of lacrimal gland : numerous ductules that traverse the palpebral part of the lacrimal gland and open into the superior fornix of the conjunctiva.
Tear production : 0.6-20 mL / min. pH = 6.5-7.6, refractive index = 1.3369
Cell types :
• lacrimal gland cell (tear-secreting)
Tear film (4-8 mm) :
• lipid or outer layer (0.5 mm) retards the evaporation of the watery layer and allow eyelid slipping. It is produced by accessory lacrimal glands :
• muciparous goblet cells in conjunctiva
• Henle's glands : tubular glands in the conjunctiva of the eyelids
• Manz glands
• glands of Zeis / sebaceous glands of conjunctiva or of eyelids / glandulae sebaceae palpebrarum : modified rudimentary sebaceous glands attached directly to the follicles of the eyelashes. They produce sebum palpebrale / lema
• watery or serous intermediate layer (6-10 mm) contains O₂ (P = 140 mmHg), lactoferrin, lysozyme, and contributes to clearance of eyeball surface. It is produced by ...
• principal lacrimal gland / meibomian glands / glandulae tarsales : a pair of glands, one at the upper outer angle of each orbit, small almond-shaped structure that produce (95%) of the tear film; divided into orbitary and palpebral portions by the orbital fascia. 12 secretory ducts drain tears in upper tarsal border.
• accessory lacrimal glands / glandulae lacrimales accessoriae / Ciaccio's glands : portions of the lacrimal gland sometimes found near the superior fornix of the conjunctiva.
• Wolfring glands : small tubuloalveolar glands in the subconjunctival tissue above the upper border of the tarsal plate, their ducts opening on the conjunctival surface.
• Krause glands / glandulae conjunctivales / conjunctival glands : accessory lacrimal glands situated deep in the subconjunctival connective tissue, mainly in the upper fornix
• mucous or inner layer (0.3 mm) lies over corneal and bulbar conjunctival epithelial cells, allowing the watery layer to lies on the otherwise hydrophobic eyeball surface. It is produced by ...
• principal lacrimal gland / meibomian gland
• accessory lacrimal glands
• Moll's gland / glandulae ciliares conjunctivales : ciliary glands of conjunctiva: sweat glands that have become arrested in their development, situated obliquely in contact with and parallel to the bulbs of the eyelashes
• eyelid Moll gland cell (specialized sweat-gland)

Lacrimation / lachrymation : the physiological secretion and discharge of tear following some reflexes
Lacrimal ways :
• punctum lacrimale / lacrimal point : the opening on the lacrimal papilla of an eyelid, near the medial angle of the eye, into which tears from the lacrimal lake drain to enter the lacrimal canaliculi.
• Bochdalek's valve : a fold within the lacrimal duct near the punctum lacrimale
• upper punctum => ampulla => upper canaliculus
• lower punctum => ampulla => lower canaliculus
• Foltz's valve : a fold of membrane at the lacrimal canaliculus
• saccus lacrimalis / lacrimal sac : the dilated upper end of the nasolacrimal duct (10 mm)
• sinus of Maier / Arlt's sinus : a slight diverticulum from the upper part of the lacrimal sac, into which the lacrimal canaliculi open, either together or separately
• Béraud's or Krause's valve : a fold of mucous membrane sometimes found at the junction of the lacrimal sac and the nasolacrimal duct
• nasolacrimal duct (NLD) (12 mm)
• Taillefer's valve : a fold of the mucous membrane of the nasolacrimal duct near the middle of its course
• Hasner's valves / plica lacrimalis / plica lacrimalis [Hasneri] / lacrimal fold : a fold of mucous membrane at the lower opening of the nasolacrimal duct
• Verga's lacrimal groove : a groove running downward from the lower orifice of the nasal duct.
• meatus nasi inferior
Tears : the watery secretion of the lacrimal glands which serves to moisten the conjunctiva; the secretion is slightly alkaline and saline and contains :
• lysozyme
• SIgA
• conjunctiva : 5 layers of cubic / cylindric epithelium
• palpebral conjunctiva (adhesed to tarsus)
• saccus conjunctivalis / conjunctival sac : the potential space, lined by conjunctiva, between the eyelids and the eyeball
• fornix / cul-de-sac conjunctiva : the junction of the palpebral and bulbar conjunctivas (scarce adhesion to allow eyeball movements)
• fornix conjunctivae inferior / inferior conjunctival fornix : the inferior line of reflection of the conjunctiva from the eyelid to the eyeball
• fornix conjunctivae superior / superior conjunctival fornix : the superior line of reflection of the conjunctiva from the eyelid to the eyeball; it receives the openings of the lacrimal duct.
• bulbar conjunctiva (over sclera, adhesed only at limbus)
Cell types :
• muciparous goblet cells producing the mucous layer of tear film
• lymphocytes draining in preauricular and submandibular lymph nodes
• orbitary cavity
• orbit fat body
• vagina bulbi / sheath of eyeball / bulbar fascia / capsula bulbi / fascia bulbi [Tenoni] / bulbar sheath / Bonnet's, ocular, or Tenon's capsule : connective tissue that forms the capsule enclosing the posterior part of the eyeball, extending anteriorly to the conjunctival fornix, and continuous with the muscular fascia of the eye. It arises from meninges that surround optic nerve (the tunica fibrosa arise from the bulbar region)
• spatium episclerale / episcleral space / spatium intervaginale / intervaginal space /  spatium interfasciale [Tenoni] / Tenon's space : the space between the bulbar fascia and the eyeball
• orbit : the bony cavity in the skull
• maxillary bone
• frontal bone
• lacrimal bone
• zygomatic bone
• lamina papyracea /  lamina orbitalis ossis ethmoidalis
• orbitary process of palatine bones
Communications :
• optic hole for optic (II) nerve and ophthalmic artery
• infraorbitary canals for maxillary division of trigeminal nerve
• extrinsic muscles / external ocular (extraocular) muscles (their nerves pass through upper orbitary fissure)
• oblique muscles (posterolateral insertions)
• superior or larger oblique muscle (extends downward lateral visual field) (innervated by pathetic or trochlear (IV) nerve)
• inferior or smaller oblique muscle (extends upward lateral visual field) (innervated by oculomotor (III) nerve)
• recti muscles / musculi recti bulbi (anterior insertions)
• superior rectus muscle / musculus rectus superius bulbi (innervated by oculomotor (III) nerve) : rising and adduction
• inferior rectus muscle / musculus rectus inferius bulbi / deprimens oculi (innervated by oculomotor (III) nerve) : lowering and adduction
• external or lateral rectus muscle / musculus rectus lateralis bulbi (innervated by abducens (VI) nerve) : abduction
• internal or medial rectus muscle / musculus rectus medialis bulbi (innervated by oculomotor (III) nerve) : adduction
Synergias :
• eyelid elevation is associated with inward and upward rotation of the eyeball
• upward or lateral eyeball rotation is associated with forced eyelid closure to allow eye rest
• pupillary contraction (miosis) is associated with convergence and accommodation
Conjugate movements depend on posterior longitudinal fasciculus :
• conjugate horizontal or lateral movement center is in midbrain
• conjugate vertical or upward movement center is in pons

Scheme of optic ways : as all sensitive ways, even optic ways is completely crossed. Refractive media of the eye allow crossing on temporal retinas (that then will have direct ways) but not on nasal retinas (that then will cross in optic chiasm).
Glossary :
• ocular anterior segment : the anterior portion of the globe (cornea, iris and anterior sclera)
• ocular posterior segment : that portion of the eye posterior to the iris
• OD : abbreviation for right eye (oculus dexter, Latin)
• OS : abbreviation for left eye (oculus sinister, Latin)
• OU : abbreviation for both eyes or each eye (oculus uterque, Latin)
• focus / focal point : the point at which light rays through a lens form an image
• focal length : the distance between the focal point and the lens
• intraocular pressure (IOP) : pressure inside the eye = 10-21 mmHg
• (inter)pupillary distance (IPD / PD) : the distance between one's pupils, measured center-to-center, ranging between 54 mm to 77 mm (average = 64 mm)
• after-image : the eye's ability to still see an image during eye blinks and even after the viewed object is no longer present. The most common example is seeing light after the flash of a camera
• bi-lateral integration / gross motor coordination : visual guidance of body movements and the coordination between both sides of the body
• physiological astigmatism : the slight astigmatism possessed by nearly all eyes and causing the twinkling sensation when distant points of light are viewed.
• visual field : area of vision the eye can see while its attention is directed straight ahead
• central vision : finely detailed vision needed for reading and other detailed tasks
• peripheral vision : side vision or what an eye can see to the side while looking straight ahead
• isopter : a line depicting the area in the field of vision in which the visual acuity is the same.
• horopter : the sum of all the spatial points whose images at a given distance fall on corresponding points of the retina. If the point of fixation is 2 meters, the horopter is a straight line across the observer's front (the apparent frontoparallel plane horopter); if the point of fixation is < 2 m, the horopter is a curve concave to the observer (concave horopter); and if the point of fixation is < 2 m, the horopter is a curve convex to the observer (convex horopter).
• Vieth-Müller horopter or circle : a circle which joins the fixation point with the nodal points of the 2 eyes
• Hering-Hellebrand deviation : the amount of deviation between any point on the Vieth-Müller horopter and the frontoparallel plane passing through the point of fixation.
• Panum's area / fusion area : the area on the retina of one eye over which a point-sized image can range and still provide a stereoscopic image with a specific point of stimulus on the retina of the other eye
• dark adaptation : the adjustment of the retina and iris (pupil) to decreased illumination
• McCollough effect : an aftersensation of color; following exposure to vertical and horizontal lines of differing colors, a grid of vertical and horizontal black lines may be seen as edged with the previously seen colors
• dominant eye : the eye that "leads" its mate during eye movements.
• depth perception / stereopsis : the ability to judge the distance and/or spatial relationship of objects of varying distances => form sense : the ability of the eye to recognize objects as solid
• binocular stereopsis: the ability to use both eyes as a team and to be able to fuse 2 visual images into 1 3D image. The break point is the point at which a person can no longer fuse 2 images into one. A blur point will occur before this point.
• bifoveal or binocular fixation : training both eyes on the same object as in ordinary vision.
• convergence : simultaneous turning in of both eyes to keep objects in sight as they approach the eyes
• divergence : simultaneous turning out of both eyes to keep sight of an object as it moves farther from the eyes
• monocular steropsis (in blindness or amblyopia) :
• parallax : an apparent displacement of an object due to a change in the observer's position.
• binocular parallax / stereoscopic parallax : the seeming difference in position of an object as seen separately by one eye and then by the other, the head remaining stationary. Types include
• crossed parallax / heteronymous parallax : binocular parallax occurring in exophoria; when one eye is covered, the object viewed seems to move away from the open eye and toward the covered eye.
• direct parallax / uncrossed parallax / homonymous parallax : binocular parallax occurring in esophoria; when one eye is covered, the object viewed seems to move toward the open eye and away from the covered eye.
• vertical parallax : binocular parallax occurring in vertical diplopia or heterophoria; the object seen seems to move vertically when each eye is closed in turn.
• relative sizes
• refractive media : the transparent parts of the eye (assimilated to a biconvex convergent lens) having refractive power for a total of 58.9 D
• cornea : 40-43 D
• air / anterior corneal surface interface : + 48.8 D
• posterior corneal surface / aqueous humor interface : - 5.9 D
• lens : 20 D in vivo; 22 D ex vivo
• aqueous humor / anterior lens surface interface : + 7.4 D
• posterior lens surface / vitreous humor interface : + 13.3 D
• resolution : as the minimal distance between 2 cones is 0.01 mm, when pupil is 2 mm, at the near point the minimal resolvable distance between 2 objects is 0.1 mm.
• refractive aberrations :
• chromatic aberrations inversely relates with light wavelength (in foveola no blue-sensitive cones are found and pigment absorb blue wavelengths, hence the name macula lutea)
• spheric aberrations at borders
They can be compensated with miosis, but this increases diffraction (numeric opening = n ^. sen(q/2), where q is the angle between 2 rays that passes for diametrically opposed points of pupil).
• accommodation : the ability of the eye to change its focus from distant object to objects closer than optical infinity (< 9 m). The eye achieves this by altering the shape of the crystalline lens with the ciliary muscles. The reflex, normally associated with convergence, is examinated by recalling the look of the patient from a distant object to an object placed 15 cm in front of the root of the nose, in a high position to prevent eyelid lowering (which would prevent examination of reflexed bilateral symmetric miosis)
• Scheiner's experiment : an experiment in accommodation: one looks at an object through two pinholes closer together than pupil diameter in a card. If the object is in focus, only one image is observed; if it is not, two or more images are seen.
• far point : the point at which an object must be placed to have a sharp image on the retina of the unaccommodated eye, generally considered to be infinite
• near point / amplitude of accommodation (AA) : the point at which an object must be placed to have a sharp image on the retina of a fully accommodated eye. It denotes distance used in conventional reading, generally considered 14 inches (25 cm), but it actually increases with age :
• 7 cm at age 10
• 14 cm at age 35
• 30 cm at age 40
• 1 m at age 60
• ....
• accommodative convergence / accommodative (AC/A) ratio (measured in prism diopters/diopters). The convergence response of an individual (amount the eyes turn inward) in relation to the amount of stimulus of accommodation (eye focusing). The normal ratio is 4:1.
• accommodation phosphene : the streak of light surrounding the visual field seen in the dark after accommodation.
• Schön's theory : the theory (of ocular accommodation) that the ciliary muscle exerts on the lens the same effect as is produced on a rubber ball held in both hands and compressed by the fingers.
• physiological reflexes :
• cochlear reflexes
• cochleo-orbicular reflex / cochleopalpebral reflex : contraction of the orbicularis palpebrarum muscle when a sharp, sudden noise is made close to the ear; does not occur in total deafness from labyrinthine disease.
• cochleopupillary reflex : a reaction of the iris (contraction of the pupil followed by dilatation) to a loud sound
• oculoauricular reflex : slight flattening of the pinna of one ear against the skull when the eyes deviate strongly to the opposite side. Absence on one side indicates facial nerve palsy at or proximal to the stylomastoid foramen.
• oculocardiac reflex / Aschner's reflex or phenomenon : a slowing of the rhythm of the heart following compression of the eyes. A slowing of from 5 to 13 beats per minute is normal; one of from 13 to 50 or more is exaggerated; one of from 1 to 5 is diminished. If ocular compression produces acceleration of the heart, the reflex is called inverted
• oculocephalogyric reflex : the reflex by which the movements of the eye, the head, and the body are directed in the interest of visual attention.
• oculopharyngeal reflex : rapid deglutition together with spontaneous closing of the eyes in response to irritation of the conjunctiva.
• oculopupillary, oculosensory or trigeminus reflex : stimulation of the cornea or of the eyelid results in dilation and then contraction of both pupils
• oculovagal reflex : pressure on the eyeball induces ectopic atrioventricular beats or rhythm.
• opticofacial winking reflex : closure of the lids when an object is brought suddenly into the field of vision.
• orbicularis oculi reflex : normal contraction of the orbicularis oculi muscle, with resultant closing of the eye, on percussion at the outer aspect of the supraorbital ridge, over the glabella, or around the margin of the orbit.
• supraorbital reflex / McCarthy's reflex : contraction of the orbicularis oculi muscle on tapping the supraorbital nerve
• Ruggeri's reflex : acceleration of the pulse following strong convergence of the eyeballs toward something very close to the eyes; it indicates sympathetic excitability.
• consensual reflexes of eyeballs (even if one of the 2 eyeballs is not stimulated)
• maintainance of horizontal meridian of retina parallel to horizont : eyeball contrarotation reflex at lateral inclination of head (vestibular afferences)
• foveation (focusing on foveola objects projected on other retinal regions)
• moving head and object at constant distance
• vestibuloocular or vestibulooculomotor reflex for fast movements (n_max = 20 Hz) (vestibular afferences) : when the fixed object goes out of visual field, the slow phase is followed by a fast phase of vestibular nystagmus (a saccad in the rotation sense), then by a new fast phase => ... When the head stops, a post-rotatory nystagmus (reverse : a slow phase in the rotation sense followed by a fast phase in the contrarotatory sense) occurs for some times.
• optokinetic reflex (retinal afferences) for slow movements during which the vestibuloocular reflex undergoes adaptation  => optokinetic nystagmus
• immobile head
• immobile object : voluntary or reflexed correction saccades / saccadic movements (the series of involuntary, abrupt, rapid (700°/s), small movements or jerks of both eyes simultaneously in changing the point of fixation on a visualized object, such as the series of jumps the eyes make in scanning a line of print) and microsaccades
• mobile object :
• constant distance
• variable distance
• protection reflexes :
• light, photomotor or pupillary reflex : bilateral contraction of the iris sphincter muscle on exposure of one retina to a distant light source (to avoid the miotic effect associated with accommodation and convergence) in a dark environment. Each eye is studied separately by placing a hand parallel to the nose
• Gifford-Galassi or Westphal-Piltz orbicularis pupillary reflex or phenomenon : unilateral contraction of the pupil, followed by dilatation after closure or attempted closure of eyelids that are forcibly held apart
• retrobulbar pupillary reflex : slight dilation of the pupil, which contracts under light stimulation and then dilates while the light stimulation is still present.
• reversed pupillary reflex / paradoxical pupillary reflex or phenomenon : any abnormal pupillary reflex opposite to that which occurs normally; e.g., stimulation of the retina by light dilates the pupil
• corneal or trigeminofacial reflex
As people grow older, their vision can actually get better in some way : neurological changes could help the elderly to spot small motions in otherwise uniform scenes. Part of visual processing in the human brain involves cells that suppress each other's activity. This allows the mind to focus on a scene's important features while ignoring trivial regions. But as people age, these inhibitory interactions seem to weaken. As the number of vertical black-and-white stripes shown on a computer screen increases, young people become much worse at identifying their movement. Scientists think that the stripes' large, stark borders activate the brains inhibitory mechanisms. The mind starts disregarding these monotonous forms. Older people don't show the same drop in performance : with a large part of the screen filled with the high-contrast stripes, younger people required 100 ms to work out the direction of movement, and took twice as long for a small patch, but the performance of older people stayed constant at around 70 ms. Reduced brain inhibition might make older observers more sensitive to visual input that is normally suppressed^ref. It is the high contrast between black and white stripes that produces this effect, and not the expanding area on the screen showing the stripes. Both young and older people are faster at identifying the movement of low-contrast grey stripes when they can see more of them. In the real world older people might find it easier to follow action in sweeping scenes, such as a sporting event.
Web resources :
• Vision, Aging and Age-Related Diseases
• Functions of Visual Motion Perception
• ear and hearing / audition (otology) (see also diseases of ear and hearing)


• external or outer ear / auris externa : the portion of the auditory organ comprising the auricle and the external acoustic meatus.


• external auditory canal or acoustic meatus
• Meyer's sinus / sinus Meyeri : a small depression in the floor of the external auditory canal just in front of the tympanic membrane.
• foveola suprameatica / suprameatal pit / foveola suprameatalis / mastoid or supramastoid fossa / Macewen's triangle / suprameatal triangle : a small triangular depression at the junction of the posterior and superior borders of the external acoustic meatus, posterior to the suprameatal spine
• sulcus posterior auriculae / posterior sulcus of auricle / sulcus auriculae or auricularis posterior : the slight depression on the pinna that separates the anthelix from the antitragus
• helix : the superior and posterior free margin of the pinna of the ear
• cauda helicis / tail of helix : the termination of the posterior margin of the cartilage of the helix.
• crus helicis / crus of helix / crista helicis : the anterior termination of the helix of the external ear located above the entrance to the external acoustic meatus
• sulcus cruris helicis / sulcus of crus of helix : a transverse sulcus on the medial surface of the pinna, corresponding to the crus helicis on the lateral surface.
• fossa triangularis auriculae / triangular fossa of auricle : the cavity just above the concha of the ear between the crura of the anthelix.
• fossa antihelica / antihelical fossa / fossa anthelicis / fossa of antihelix : the depression on the medial surface of the auricle of the ear that corresponds to the antihelix on the lateral surface
• scapha / scaphoid fossa / fossa helicis : the long curved depression that separates the helix from the anthelix
• eminentia scaphae / eminence of scapha : the prominence on the medial side of the auricle of the external ear that corresponds to the scapha on the lateral side
• antihelix / anthelix : the prominent semicircular ridge seen on the lateral aspect of the auricle of the external ear, anteroinferior to the helix
• sulcus anthelicis transversus / transverse sulcus of anthelix : the depression on the medial surface of the pinna corresponding to the lower crus of the anthelix.
• crura anthelicis / crura of anthelix / limbs of anthelix : the 2 ridges on the external ear marking the superior termination of the anthelix and bounding the triangular fossa
• tragus : the cartilaginous projection anterior to the external opening of the ear
• concha auriculae / concha auricularis / concha of auricle : the hollow of the auricle of the external ear, bounded anteriorly by the tragus and posteriorly by the anthelix.
• cymba conchae auriculae : the upper part of the concha of the auricle
• antitragus : a projection opposite the tragus, bounding the cavitas conchae posteroinferiorly and continuous above with the anthelix
• fissura antitragohelicina / antitragohelicine fissure / posterior fissure of auricle : a fissure in the auricular cartilage between the cauda helicis and the antitragus
• ear ceruminos gland cell (wax-secreting)

• tympanum / tympanic membrane / membrana tympani or tympanica / myrinx / myringa / eardrum
• pars tensa membrane tympanicae / membrana tensa or vibrans : the larger portion of the tympanic membrane; it is tense and firm.
• pars flaccida membrane tympanicae / Rivinus-Shrapnell's membrane : the small portion of the tympanic membrane, between the anterior and posterior mallear folds; it is lax and thin.(no intermediate fibrous layer between mucous and skin layers)
• umbo membranae tympani or tympanicae / umbo of tympanic membrane / spatula mallei : the slight projection at the center of the outer surface of the tympanic membrane, corresponding to the point of attachment of the tip of the manubrium of the malleus
• promontorium tympani / promontory of tympanic cavity : the prominence on the medial wall of the tympanic cavity, formed by the first turn of the cochlea
• stria mallearis or malleolaris membranae tympani or tympanicae / mallear stria of tympanic membrane : a nearly vertical radial band seen on the outer surface of the tympanic membrane; it extends from the umbo upward to the prominentia mallearis and is caused by the manubrium mallei.
• eustachian tuber : an eminence on the medial wall of the tympanum, below the vestibular window
• Tröltsch's corpuscles : connective tissue spaces lined with flattened endothelial cells, and appearing like corpuscular bodies among the radial fibers of the membrana tympani
• Huguier's sinus : a depression in the tympanum between the fenestra ovalis and the fenestra rotunda.
• middle ear / auris media
• 4 pouches in the fetal middle ear
• saccus anticus, later developing into the anterior recess of the tympanic membrane.
• saccus medius, later subdividing to form the epitympanum and the region of the petrous part of the temporal bone.
• saccus posticus, later developing into the round window, oval window, and sinus tympani.
• saccus superior, later developing into the posterior recess of the tympanic membrane, part of the mastoid process, and the space below the incus
• tubotympanum
• cavitas tympani
• eminentia pyramidalis / pyramidal eminence : an elevation in the posterior wall of the middle ear, which contains the stapedius muscle
• ossicula auditus or auditoria / auditory ossicles / ossicular chain (6) : the small bones of the middle ear, which transmit vibrations from the tympanic membrane to the oval window
• malleus / hammer (2) attaches at 3 points to the interior surface of the tympanum
• incus (2) attaches the malleus to the stapes
• crus breve incudis / short crus of incus / short limb or short process of incus : the backward-projecting process on the incus that is connected to the posterior wall of the tympanic cavity by the posterior incudal ligament
• crus longum incudis / long crus of incus / long limb or long process of incus : a process on the incus directed downward and inward, parallel with the manubrium of the malleus
• stapes / stirrup (2) is seated within the oval window : an oval opening in the inner ear, which is closed by the base of the stapes
• crus anterius stapedis / anterior crus of stapes / anterior limb of stapes : the anterior of the 2 bony limbs that connect the footplate and capitulum of the stapes
• crus posterius stapedis / posterior crus of stapes / posterior limb of stapes : the posterior of the 2 bony limbs that connect the footplate and capitulum of the stapes
• muscles
• tensor tympani
• septum canalis musculotubarii / septum of musculotubal canal : the thin lamella of bone that divides the musculotubal canal into the semicanals for the tensor tympani muscle and the auditory tube.
• stapedius
• stapedial reflex : afferences via vestibulocochlear (VIII) nerve and efferences via facial (VII) nerve
• tuba auditiva / tuba acustica / tuba auditoria / otosalpinx / otopharyngeal tube / pharyngotympanic tube / eustachian canal or tube : functions in equalizing the pressure between the atmosphere (rhynopharynx) and the middle ear space, as well as for mucociliary clearance of the middle ear.
• pars ossea : located in the temporal bone, usually open
• pars cartilaginea : the pharyngeal end is cartilaginous, slit-like, and closed, acting like a one-way flutter valve. Opening of the Eustachian tube occurs with the contraction of the levator and tensor veli palatini muscles during acts of chewing, swallowing, or yawning.
• adnexa mastoidea : the structures in the mastoid (posterior) wall of the middle ear, including the mastoid antrum and its aditus and the mastoid air cells.
• inner or internal ear / auris interna : the cavity situated medial to the middle ear entirely within the petrous portion of the temporal bone comprising the cavitas tympani, adnexa mastoidea, and tuba auditiva. It is composed of dense, compact bone 2-3 mm thick, forming the osseous labyrinth / bony labyrinth. Within the bony labyrinth is a membranous labyrinth. The supporting fluid outside of the membranous labyrinth is perilymph, somewhat similar to CSF and high in Na⁺ content. The fluid inside the membranous labyrinth, endolymph, has a high K⁺ content.


• apertura externa canaliculi cochleae / external aperture of canaliculus of cochlea : the external opening of the cochlear canaliculus on the margin of the jugular foramen in the temporal bone
• perilymphatic space

Cell types :
• squamous cell
• starred cell
• endolymphatic space
• ductus reuniens / canalis reuniens / Hensen's canal or duct / Reichert's canal : a small canal leading from the saccule to the cochlear duct
• ductus utriculosaccularis / utriculosaccular duct / sacculoutricular duct or canal / utriculosaccular canal : a tiny Y-shaped duct in the membranous labyrinth with one branch to the utricle, one branch to the saccule, and one branch to the ductus endolymphaticus
• ductus endolymphaticus / endolymphatic duct : the membranous tube connecting the utriculosaccular duct with the endolymphatic sac, located within the bony vestibular aqueduct
• saccus endolymphaticus / endolymphatic sac / Böttcher's space : the blind, flattened cerebral end of the endolymphatic duct
• apertura externa aqueductus vestibuli / external aperture of aqueduct of vestibule / fissure of aqueduct of vestibule : the external opening for the aqueduct of the vestibule, located on the posterior surface of the petrous part of the temporal bone, lateral to the opening for the internal acoustic meatus
Cell types :
• squamous cell
• columnar cell of endolymphatic sac
• with microvilli
• without microvilli
• dark cells
• vestibular membrane cell
• zona denticulata / denticulate zone : the inner zone of the lamina basilaris ductus cochlearis with the limbus of the osseous spiral lamina.
• zona perforata : the inner portion of the lamina basilaris ductus cochlearis.
• zona pectinata / pectinate zone : the outer part of the lamina basilaris ductus cochlearis running from the rods of Corti to the spiral ligament.
• stria vascularis ductus cochlearis / vascular stria of cochlear duct : a layer of vascular tissue consisting of epithelial cells, mesothelial cells, and probably some neuroectoderm; it covers the outer wall of the cochlear duct and is thought to secrete the endolymph.
• basal cell of vascular streak
This is divided into :
• auditory apparatus (audiology) : the cochlea is a 2 and a half-turn coil about a central core called the modiolus, with the apex pointing anteriorly and laterally.


• sulcus spiralis externus / external spiral sulcus : a concavity within the cochlear duct immediately above the basilar crest
• sulcus spiralis internus / internal spiral sulcus : the C -shaped concavity within the cochlear duct formed by the limbus laminae spiralis and its tympanic and vestibular labia along the edge of the osseous spiral lamina.
The spirally arranged membranous labyrinth within the bony canal of the cochlea constitutes the scala media of Löwenberg / cochlear canal or duct / ductus cochlearis / membranous cochlea :
• caecum cupulare ductus cochlearis / cupular caecum of cochlear duct : the closed blind apical end of the cochlear duct.
• caecum vestibulare ductus cochlearis / vestibular caecum of cochlear duct : a small blind outpouching at the vestibular end of the cochlear duct.
The scala media is limited on 3 sides :
• vestibular membrane / Reissner's membrane
• basilar membrane
• lateral membrane
It contains :
• organ of Corti, which rests on the basilar membrane and contains about 24,000 acoustic hair cells / auditory cells / bristle cells / cells of Corti arranged throughout the cochlea as
• a single row of inner hairy cells (IHC)
• 3-5 rows of contractile outer hairy cells (OHC)
• Hensen's body : a rounded modified Golgi net under the cuticle of an OHC of the organum spirale
• body of Retzius : protoplasmic mass containing pigment granules at the lower end of a hair cell of the organum spirale
Between them, they form a somewhat triangular tunnel of Corti that has its own slightly different fluid, Cortilymph. Both IHC and OHC carry stereocilia (but no kinocilia, on the contrary of crossed by a tip link. It is known that high frequency sounds stimulate the hair cells near the vestibule, and low frequency sounds stimulate those near the apex. The area of the promontory or basilar turn of the cochlea is stimulated by frequencies in the range of 3000 to 5000 Hz; it appears to be the most vulnerable to acoustic trauma, probably from the shearing force in the fluid so near the stapes footplate and the beginning curve in the scala. Other cell types :
• interdental epithelial cells : found in the spiral limbus between the dentes acustici, which secrete the tectorial membrane of the cochlear duct.
• supporter cells
• pillar cells / Corti's rods : elongated supporting cells in a double row in the organ of Corti, having their heads joined and their bases resting on the basilar membrane widely separated so as to form a tunnel (inner tunnel or canal of Corti) that extends the length of the cochlea
• inner pillar cell
• outer pillar cell
• arches of Corti : a series of arches in the organ of Corti formed by inner and outer pillar cells.
• phalangeal cells : elongated supporting cells of the organ of Corti with bases that rest on the basilar membrane adjacent to the pillar cells
• inner phalangeal cell are arranged in a row on the inner surface of the inner pillar cells and surround the inner hair cells
• outer phalangeal cells / Deiters' cells support the outer hair cells.
• border cell
• Hensen cell : tall supporting cells arranged in rows adjacent to the last row of outer phalangeal cells, constituting the outer border of the organ of Corti.
• inner ear stem cells



Cytoneural junctions :

• type 1 (less granulated or small nerve endings) are afferent nerve endings
• type 2 (much granulated or large nerve endings) are efferent nerve endings
• Claudius' cells : cuboidal cells found in the floor of the external spiral sulcus, external to the organ of Corti
• Boettcher or Böttcher's cell : small groups of polyhedral cells interposed between Claudius' cells and the basilar membrane of the cochlea.
The scala media is separated by the body labyrinth by ...
• scala vestibuli (associated with the fenestra vestibuli / fenestra or window of vestibule / fenestra ovalis / oval or vestibular window : an oval opening in the inner ear, which is closed by the base of the stapes)
• scala tympani (associated with the fenestra cochleae / fenestra or window of cochlea / fenestra rotunda / cochlear or round window : a round opening in the inner wall of the middle ear inferior to and a little posterior to the fenestra vestibuli; it is covered by the secondary tympanic membrane)
..., which contain perilymph and are joined at the apex of the cochlea through the helicotrema
Acoustics provides a basis for understanding hearing and communications. Sound can be described as a wave-like pressure fluctuation in air, fluid or solid media that conveys energy from the source outward in all directions. The basic physical characteristics of sound are :
• frequency, measured in hertz (Hz) or cycles per second (cps) is the number of positive or negative pressure fluctuations of a sound wave each second. Frequency largely determines pitch, although it is not quite a one-to-one relationship. The subjective term pitch comes from the musical vocabulary and is the relative lowness or highness of that attribute of sound relating to the frequencies of the musical scale. The gross frequency range of human hearing for young, healthy, and undiseased ears is from below 20 to over 20,000 Hz, but is specialized for the range 2 to 5 kHz.
• high frequency : acute tones
• low frequency : low tones
• intensity is the amplitude component of a sound wave.
• sound intensity or pressure level (SPL) = 10 log (I/I₀) = 20 log(P/P₀) dB, where P represents the measured sound pressure in pascals (Pa), and P₀ is the reference pressure = 20 mPa (or 20 N/m²) for acousticians, i.e. the minimal SPL which can be listened of a sound with frequency = 1 kHz. As humans can hear 20 mPa < SPL < 20 Pa, working with a logarytmic scale is easier : so humans can hear from 0 dB to a pain threshold 130 dB.
• loudness is loosely related to intensity, depending somewhat upon frequency (Fletcher-Munson curve, 1933) and spectrum. Sound level meters contain a set of frequency-weighting networks which correspond to different loudness levels :
• A-weighted level, LA, corresponds to an equal loudness contour near threshold
• B-weighted level, LB, to a moderate loudness level (55 to 88 dB)
• C-weighted level, LC, is nearly "flat" or unweighted and corresponds to a loudness sensation above 85 dB
The useful amplitude range of human hearing is from 0 to 105 dB.
• > 105 dB : many individuals find that they can no longer tolerate the noise and will try to get away from it or seek hearing protection
• > 120 dB : many people describe sensations of pain or tickle in their ear canals.
• 160 dB : tissue damage has been observed in deaf subjects, viz., a bruising of the capillaries of the tympanic membrane particularly around its periphery and near the manubrium of the malleus
Absolute threshold of hearing is the minimum level of sound that evokes a response in at least 50% of the trials.
Hearing sensitivity is the general term denoting the absolute hearing threshold of an individual.
Hearing acuity is the just-noticeable-difference in a controlled change of frequency, intensity, or spectrum.
celerity = velocity of transmission, inversely related to density of the medium
• in air : 300 m/s

in water : 1,500 m/s
Otoacoustic emissions (OAE) : subtle sounds produced by amplifying processes in the cochlea during normal hearing and transmitted through the middle ear to the external auditory canal.
cochlear microphonic or potentials / Wever-Bray phenomenon :  the electrical potential generated in the hair cells of the organ of Corti in response to acoustic stimulation
Pure tone is a discrete frequency stimulus
Complex sounds are complex mixtures of various frequencies and intensities (sound spectrum) :
• narrow band noise
• broad-band or wide-band noise
Noise having all frequencies with equal energy is called white noise, and noise with a gradual decrease in amplitude of the higher frequencies is called pink noise. Musical sounds, when analyzed, produce line spectra since they are composed of fundamental frequencies and overtones or harmonic frequencies which are arithmetically related to the fundamental.
The minimum audible field (MAF) curve is the absolute threshold of hearing versus frequency
• < 18-20 Hz : we feel rather than hear the vibrations in the infrasonic range
• 80/100 - 10,000 Hz : the speech area (40-80 dB SPL)
• 300 to 3000 Hz : trasmitted by telephone and aircraft radio systems
• 3000 - 4000 Hz : ear is less sensitive
• > 20,000 Hz, we sense a sort of pressure for sound in the ultrasonic range
Rutherford's frequency theory : an early theory of hearing, which postulated that the pattern of excitation of auditory nerve fibers was more important in perception of pitch than was the excitation of any of the fibers in any particular area of the cochlear basilar membrane
place theory : an early theory of pitch perception which postulated that excitation of specific areas of the basilar membrane of the cochlea determined the pitch perceived
Helmholtz place or resonance theory : an early theory of sound perception, now disproved; it held that each basilar fiber responded sympathetically to a definite tone and stimulated the hair cells of Corti's organ, causing nerve impulses that were then carried to the brain
A team of US researchers has made an inventive attempt to discover how much an unborn baby can hear in the womb — by making recordings from the inner ear of a fetal sheep (sheep is generally the animal of choice for pregnancy research and the acoustics of human and sheep wombs are roughly the same) : low frequencies (i.e. vowel sounds, e.g. the 'melody' of speech) reach the womb with ease, whereas higher-pitched sounds (consonants) are more muffled. The researchers made the recordings by removing a sheep fetus from the womb and inserting tiny electrodes that picked up the electrical signals generated in the ear in response to sound into its inner ear : the fetus was then returned to the womb and human speech was played through a loudspeaker next to its mother's body. When the researchers asked human volunteers to listen to sounds recorded in the womb, the listeners correctly identified only about 40% of the words The fact that the womb's walls soak up sound from outside will be a relief to those concerned about the effect of outside noise on unborn babies. Health experts had worried that expectant mothers who work in loud factories or attend rock concerts might be putting their children's hearing at risk. This study suggests that some of the sound is being filtered out. It also suggests that mothers who play music to their unborn children should chose something with a lot of bass if they want their babies to hear the notes^ref.
• vestibular apparatus (vestibulogy) : the structures in the inner ear concerned with reception and transduction of stimuli of equilibrium; they include the semicircular canals, the utricle, and the saccule.
• semicircular canals / ductus semicirculares (the long ducts of the membranous labyrinth of the ear, corresponding to the semicircular canals of the bony labyrinth and designated anterior, posterior, and lateral, according to the canal they occupy. Their diameter is only 25% that of the bony canals containing them, and each is affixed by one wall to the endosteal lining of the canal. They give information about angular acceleration and deceleration and consists of simple arm and ampulla (ampullar crest with cupule / anist membrane (no otoliths) sense angular accelerations (a = w/t))
• lateral or "horizontal" semicircular duct / ductus semicircularis lateralis : the semicircular duct occupying the lateral semicircular canal
• Donaldson's line : an imaginary line drawn longitudinally through the lateral semicircular canal and bisecting the perpendicular dimension of the posterior canal; in most individuals it will pass just above the endolymphatic sac.
• anterior semicircular duct / ductus semicircularis anterior / ductus semicircularis superior / superior semicircular duct : the semicircular duct occupying the anterior semicircular canal
• posterior semicircular duct / ductus semicircularis lateralis : the semicircular duct occupying the lateral semicircular canal
Evald laws :
• I : ampullipetal / utriculipetal current is excitatory for lateral semircular canals and inhibitory for anterior and posterior semicircular canals
• II : semicircular canals can be excited more than how they can be inhibited
Goltz's theory : the theory that the function of the semicircular canals is to transmit sensations of position, and thus materially aid in the sense of equilibrium.
Depolarization rate depends on angular accelerations (a) :
• when a = 0°/s², 80-90 spikes per second
• when a = - 15°/s², 0 spikes per second
• when a = + oo, 400 spikes per second (limit due to refractory period).
• vestibule from otic vesicle : acoustic maculae / membrana statoconiorum macularum (from macula communis) with gelatinous statoconic or otolithic membrane and otoconia / otoconites / statoconia / otoliths / otolites / ear crystals (minute calciferous granules containing calcite crystals) sense linear accelerations (a = v/t)
• saccule (with macula sacculi) senses laterolateral linear accelerations
• utricule (with macula utriculi) senses anteroposterior linear accelerations
• commissura bulborum vestibuli / commissure of bulbs of vestibule / pars intermedia bulborum vestibuli : a narrow median band spanning the vaginal orifice to unite the bulbs of the vestibule
Cell types :
• acceleration and gravity receptors
• type I ciliated or hair cell / cylindric cells : 1 kinocilium and 40-60 stereocilia.
• type II ciliated or hair cell / flat cells
• semilunar floor epithelial cell (proteoglycan-secreting)
• supporter cell
Physiological phenomena :
• end-position nystagmus / pseudonystagmus : nystagmus occurring in normal individuals at extremes of gaze (> 45°)
• fixation nystagmus : nystagmus which appears only on gazing fixedly at an object.
• opticokinetic, optokinetic or railroad nystagmus : the normal nystagmus occurring from optokinetic reflex when looking at objects passing across the field of vision, as in viewing from a moving railroad car or automobile. It can be induced for testing purposes to check ocular and vestibular functioning
Hearing and vestibular ways.
• central tract of auditory nerve : a group of fibers that passes from the cochlear nuclei to the superior olive, to the lateral lemniscus on the same and the opposite side and then up through the brachium of the inferior colliculus into the medial geniculate body and from there to the cortex of the transverse temporal gyri.
• vestibulocerebellar tract : a group of fibers of the pars vestibularis nervi octavi that extends to the cortex of the cerebellum via the inferior cerebellar peduncles.
• tracti vestibulospinaes / vestibulospinal tracts
• tractus vestibulospinalis lateralis / lateral vestibulospinal tract : a group of nerve fibers arising from the lateral vestibular nucleus and descending first ipsilaterally in the periphery of the anterolateral funiculus and then through the medial part of the anterior funiculus at lower levels of the spinal cord, ending ipsilaterally in the medial part of the anterior gray column.
• tractus vestibulospinalis medialis / medial vestibulospinal tract : a group of nerve fibers arising mainly from the medial vestibular nucleus and descending via the medial longitudinal fasciculus into the anterior funiculus of the spinal cord, close to the midline; it contains both crossed and uncrossed fibers and projects mainly to the cervical cord segments, ending at the midthoracic cord level.
• apertura tympanica canaliculi chordae tympani / tympanic aperture of canaliculus of chorda tympani / iter chordae posterius : the opening in the posterior part of the middle ear through which the chorda tympani nerve enters the tympanic cavity
• apertura superior canaliculi tympanici / superior aperture of tympanic canaliculus / internal aperture of tympanic canaliculus : the upper opening of the tympanic canaliculus in the temporal bone, leading to the tympanum
• apertura inferior canaliculi tympanici / inferior aperture of tympanic canaliculus / external aperture of tympanic canaliculus : the lower opening of the tympanic canaliculus on the inferior surface of the petrous portion of the temporal bone
Web resources :
• The Virtual Library - Acoustics and Vibrations
• Acoustical Society of America : meeting
• space sense : that combination of the senses (chiefly of sight and touch) which gives information as to the relative positions and relations of objects in space.
• time sense : the ability to distinguish time intervals

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