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Pineal gland

October 14, 2023

"Conarium" redirects here. For the video game, see Conarium (video game).

The pineal gland (also known as the pineal body,[1] conarium, or epiphysis cerebri) is a small endocrine gland in the brain of most vertebrates. The pineal gland produces melatonin, a serotonin-derived hormone which modulates sleep patterns in both circadian and seasonal cycles. The shape of the gland resembles a pine cone, which gives it its name.[2] The pineal gland is located in the epithalamus, near the center of the brain, between the two hemispheres, tucked in a groove where the two halves of the thalamus join.[3][4] It is one of the neuroendocrine secretory circumventricular organs in which capillaries are mostly permeable to solutes in the blood.[5]

Pineal gland
Pineal gland or epiphysis (in red)
Diagram of pituitary and pineal glands in the human brain
Details
PrecursorNeural ectoderm, roof of diencephalon
ArteryPosterior cerebral artery
Identifiers
LatinGlandula pinealis
MeSHD010870
NeuroNames297
NeuroLex IDbirnlex_1184
TA98A11.2.00.001
TA23862
FMA62033
Anatomical terms of neuroanatomy
[edit on Wikidata]

The pineal gland is present in almost all vertebrates, but is absent in protochordates in which there is a simple pineal homologue. The hagfish, considered as a primitive vertebrate, has a rudimentary structure regarded as the "pineal equivalent" in the dorsal diencephalon.[6] In some species of amphibians and reptiles, the gland is linked to a light-sensing organ, variously called the parietal eye, the pineal eye or the third eye.[7] Reconstruction of the biological evolution pattern suggests that the pineal gland was originally a kind of atrophied photoreceptor that developed into a neuroendocrine organ.

Ancient Greeks were the first to notice the pineal gland and believed it to be a valve, a guardian for the flow of pneuma. Galen in the 2nd century C.E. could not find any functional role and regarded the gland as a structural support for the brain tissue. He gave the name konario, meaning cone or pinecone, which during Renaissance was translated to Latin as pinealis. In the 17th century, René Descartes revived the mystical purpose and described the gland as the "principal seat of the soul". In the mid-20th century, the real biological role as a neuroendocrine organ was established.[8]

Etymology Edit

The word pineal, from Latin pinea (pine-cone), was first used in the late 17th century to refer to the cone shape of the brain gland.[2]

Structure Edit

The pineal gland is a pine cone-shaped (hence the name), unpaired midline brain structure.[2][9] It is reddish-gray in colour and about the size of a grain of rice (5–8 mm) in humans. It forms part of the epithalamus.[1] It is attached to the rest of the brain by a pineal stalk.[10]

Location Edit

It normally lies in a depression between the two superior colliculi.[10] It is situated between the laterally positioned thalamic bodies, and posterior to the habenular commissure. It is located in the quadrigeminal cistern.[1] It is located posterior to the third ventricle and encloses the small, cerebrospinal fluid-filled pineal recess of the third ventricle which projects into the stalk of the gland.[11]

The ventral lamina of the pituitary stalk is continuous with the posterior commissure, and its dorsal lamina with the habenular commissure.[10]

Blood supply Edit

Unlike most of the mammalian brain, the pineal gland is not isolated from the body by the blood–brain barrier system;[12] it has profuse blood flow, second only to the kidney,[13] supplied from the choroidal branches of the posterior cerebral artery.

Afferents Edit

The pineal gland receives sympathetic afferents from the superior cervical ganglion,[14] and parasympathetic afferents from the pterygopalatine ganglia and otic ganglia.[14][15] According to research on animals, neurons of the trigeminal ganglion that are involved in pituitary adenylate cyclase-activating peptide neuropeptide signaling project the gland.[16][15]

Neural pathway for melatonin production Edit

The canonical neural pathway regulating pineal melatonin production begins in the eye with the intrinsically photosensitive ganglion cells of the retina which project inhibitory GABAergic efferents to the paraventricular nucleus of hypothalamus via the retinohypothalamic tract. The paraventricular nucleus in turn projects to the superior cervical ganglia, which finally projects to the pineal gland. Darkness thus leads to disinhibition of the paraventricular nucleus, leading it to activate pineal gland melatonin production by way of the superior cervical ganglia.[17]

Microanatomy Edit

 
Pineal gland parenchyma with calcifications
 
Micrograph of a normal pineal gland – very high magnification
 
Micrograph of a normal pineal gland – intermediate magnification

The pineal body in humans consists of a lobular parenchyma of pinealocytes surrounded by connective tissue spaces. The gland's surface is covered by a pial capsule.

The pineal gland consists mainly of pinealocytes, but four other cell types have been identified. As it is quite cellular (in relation to the cortex and white matter), it may be mistaken for a neoplasm.[18]

Cell type Description
Pinealocytes The pinealocytes consist of a cell body with 4–6 processes emerging. They produce and secrete melatonin. The pinealocytes can be stained by special silver impregnation methods. Their cytoplasm is lightly basophilic. With special stains, pinealocytes exhibit lengthy, branched cytoplasmic processes that extend to the connective septa and its blood vessels.
Interstitial cells Interstitial cells are located between the pinealocytes. They have elongated nuclei and a cytoplasm that is stained darker than that of the pinealocytes.
Perivascular phagocyte Many capillaries are present in the gland, and perivascular phagocytes are located close to these blood vessels. The perivascular phagocytes are antigen presenting cells.
Pineal neurons In higher vertebrates neurons are usually located in the pineal gland. However, this is not the case in rodents.
Peptidergic neuron-like cells In some species, neuronal-like peptidergic cells are present. These cells might have a paracrine regulatory function.

Development Edit

The human pineal gland grows in size until about 1–2 years of age, remaining stable thereafter,[19][20] although its weight increases gradually from puberty onwards.[21][22] The abundant melatonin levels in children are believed to inhibit sexual development, and pineal tumors have been linked with precocious puberty. When puberty arrives, melatonin production is reduced.[23]

Symmetry Edit

In the zebrafish the pineal gland does not straddle the midline, but shows a left-sided bias. In humans, functional cerebral dominance is accompanied by subtle anatomical asymmetry.[24][25][26]

Function Edit

One function of the pineal gland is to produce melatonin. Melatonin has various functions in the central nervous system, the most important of which is to help modulate sleep patterns. Melatonin production is stimulated by darkness and inhibited by light.[27][28] Light sensitive nerve cells in the retina detect light and send this signal to the suprachiasmatic nucleus (SCN), synchronizing the SCN to the day-night cycle. Nerve fibers then relay the daylight information from the SCN to the paraventricular nuclei (PVN), then to the spinal cord and via the sympathetic system to superior cervical ganglia (SCG), and from there into the pineal gland.

The compound pinoline is also claimed to be produced in the pineal gland; it is one of the beta-carbolines.[29] This claim is subject to some controversy.[citation needed]

Regulation of the pituitary gland Edit

Studies on rodents suggest that the pineal gland influences the pituitary gland's secretion of the sex hormones, follicle-stimulating hormone (FSH), and luteinizing hormone (LH). Pinealectomy performed on rodents produced no change in pituitary weight, but caused an increase in the concentration of FSH and LH within the gland.[30] Administration of melatonin did not return the concentrations of FSH to normal levels, suggesting that the pineal gland influences pituitary gland secretion of FSH and LH through an undescribed transmitting molecule.[30]

The pineal gland contains receptors for the regulatory neuropeptide, endothelin-1,[31] which, when injected in picomolar quantities into the lateral cerebral ventricle, causes a calcium-mediated increase in pineal glucose metabolism.[32]

Regulation of bone metabolism Edit

Studies in mice suggest that the pineal-derived melatonin regulates new bone deposition. Pineal-derived melatonin mediates its action on the bone cells through MT2 receptors. This pathway could be a potential new target for osteoporosis treatment as the study shows the curative effect of oral melatonin treatment in a postmenopausal osteoporosis mouse model.[33]

Clinical significance Edit

Calcification Edit

Calcification of the pineal gland is typical in young adults, and has been observed in children as young as two years of age.[34] The internal secretions of the pineal gland are known to inhibit the development of the reproductive glands because when it is severely damaged in children, development of the sexual organs and the skeleton are accelerated.[35] Pineal gland calcification is detrimental to its ability to synthesize melatonin[36][37] and scientific literature presents inconclusive findings on whether it causes sleep problems.[38][39]

The calcified gland is often seen in skull X-rays.[34] Calcification rates vary widely by country and correlate with an increase in age, with calcification occurring in an estimated 40% of Americans by age seventeen.[34] Calcification of the pineal gland is associated with corpora arenacea, also known as "brain sand".

Tumors Edit

Tumors of the pineal gland are called pinealomas. These tumors are rare and 50% to 70% are germinomas that arise from sequestered embryonic germ cells. Histologically they are similar to testicular seminomas and ovarian dysgerminomas.[40]

A pineal tumor can compress the superior colliculi and pretectal area of the dorsal midbrain, producing Parinaud's syndrome. Pineal tumors also can cause compression of the cerebral aqueduct, resulting in a noncommunicating hydrocephalus. Other manifestations are the consequence of their pressure effects and consist of visual disturbances, headache, mental deterioration, and sometimes dementia-like behaviour.[41]

These neoplasms are divided into three categories: pineoblastomas, pineocytomas, and mixed tumors, based on their level of differentiation, which, in turn, correlates with their neoplastic aggressiveness.[42] The clinical course of patients with pineocytomas is prolonged, averaging up to several years.[43] The position of these tumors makes them difficult to remove surgically.

Other conditions Edit

The morphology of the pineal gland differs markedly in different pathological conditions. For instance, it is known that its volume is reduced both in obese patients as well as patients with primary insomnia.[44]

Other animals Edit

Nearly all vertebrate species possess a pineal gland. The most important exception is a primitive vertebrate, the hagfish. Even in the hagfish, however, there may be a "pineal equivalent" structure in the dorsal diencephalon.[6] A few more complex vertebrates have lost pineal glands over the course of their evolution.[45] The lamprey (another primitive vertebrate), however, does possess one.[46] The lancelet Branchiostoma lanceolatum, an early chordate which is a close relative to vertebrates, also lacks a recognizable pineal gland.[46] Protochordates in general do not have the distinct structure as an organ, but they have a mass of photoreceptor cells called lamellar body, which is regarded as a pineal homologue.[47][48]

The results of various scientific research in evolutionary biology, comparative neuroanatomy and neurophysiology have explained the evolutionary history (phylogeny) of the pineal gland in different vertebrate species. From the point of view of biological evolution, the pineal gland is a kind of atrophied photoreceptor. In the epithalamus of some species of amphibians and reptiles, it is linked to a light-sensing organ, known as the parietal eye, which is also called the pineal eye or third eye.[7] It is likely that the common ancestor of all vertebrates had a pair of photosensory organs on the top of its head, similar to the arrangement in modern lampreys.[49] In many lower vertebrates (such as species of fish, amphibians and lizards), the pineal gland is associated with parietal or pineal eye. In these animals, the parietal eye acts as a photoreceptor, and hence are also known as the third eye, and they can be seen on top of the head in some species.[50] Some extinct Devonian fishes have two parietal foramina in their skulls,[51][52] suggesting an ancestral bilaterality of parietal eyes. The parietal eye and the pineal gland of living tetrapods are probably the descendants of the left and right parts of this organ, respectively.[53]

During embryonic development, the parietal eye and the pineal organ of modern lizards[54] and tuataras[55] form together from a pocket formed in the brain ectoderm. The loss of parietal eyes in many living tetrapods is supported by developmental formation of a paired structure that subsequently fuses into a single pineal gland in developing embryos of turtles, snakes, birds, and mammals.[56]

The pineal organs of mammals fall into one of three categories based on shape. Rodents have more structurally complex pineal glands than other mammals.[57]

Crocodilians and some tropical lineages of mammals (some xenarthrans (sloths), pangolins, sirenians (manatees and dugongs), and some marsupials (sugar gliders)) have lost both their parietal eye and their pineal organ.[58][59][57] Polar mammals, such as walruses and some seals, possess unusually large pineal glands.[58]

All amphibians have a pineal organ, but some frogs and toads also have what is called a "frontal organ", which is essentially a parietal eye.[60]

Pinealocytes in many non-mammalian vertebrates have a strong resemblance to the photoreceptor cells of the eye. Evidence from morphology and developmental biology suggests that pineal cells possess a common evolutionary ancestor with retinal cells.[61]

Pineal cytostructure seems to have evolutionary similarities to the retinal cells of the lateral eyes.[61] Modern birds and reptiles express the phototransducing pigment melanopsin in the pineal gland. Avian pineal glands are thought to act like the suprachiasmatic nucleus in mammals.[62] The structure of the pineal eye in modern lizards and tuatara is analogous to the cornea, lens, and retina of the lateral eyes of vertebrates.[56]

In most vertebrates, exposure to light sets off a chain reaction of enzymatic events within the pineal gland that regulates circadian rhythms.[63] In humans and other mammals, the light signals necessary to set circadian rhythms are sent from the eye through the retinohypothalamic system to the suprachiasmatic nuclei (SCN) and the pineal gland.

The fossilized skulls of many extinct vertebrates have a pineal foramen (opening), which in some cases is larger than that of any living vertebrate.[64] Although fossils seldom preserve deep-brain soft anatomy, the brain of the Russian fossil bird Cerebavis cenomanica from Melovatka, about 90 million years old, shows a relatively large parietal eye and pineal gland.[65]

History Edit

 
Diagram of the operation of the pineal gland for Descartes in the Treatise of Man (figure published in the edition of 1664)

The secretory activity of the pineal gland is only partially understood. Its location deep in the brain suggested to philosophers throughout history that it possesses particular importance. This combination led to its being regarded as a "mystery" gland with mystical, metaphysical, and occult theories surrounding its perceived functions. The earliest recorded description of the pineal gland is from the Greek physician Galen in the 2nd century C.E.[66] According to Galen, Herophilus (325–280 B.C.E.) had already considered the structure as a kind of valve that partitioned the brain chambers, particularly for the flow of vital spirits (pneuma).[67] Specifically, the ancient Greeks believed that the structure maintains the movement vital spirits from the middle (now identified to the third) ventricle to the one in the parencephalis (fourth ventricle).[68][69]

Galen described the pineal gland in De usu partium corporis humani, libri VII (On the Usefulness of Parts of the Body, Part 8) and De anatomicis administrationibus, libri IX (On Anatomical Procedures, Part 9).[70] He introduced the name κωνάριο (konario, often Latinised as conarium) that means cone, as in pinecone,[71] in De usu partium corporis humani. He correctly located the gland as directly lying behind the third ventricle. He argued against the prevailing concept as a valve for two basic reasons: it is located outside of the brain tissue and it does not move on its own.[66]

Galen instead identified the valve as a worm-like structure in the cerebellum (later called vermiform epiphysis, known today as the vermis cerebelli or cerebellar vermis).[72] From his study on the blood vessels surrounding the pineal gland he discovered the great vein of the cerebellum, later called the vein of Galen.[71][73] He could not establish any functional role of the pineal gland and regarded it as a structural support for the cerebral veins.[74]

Seventeenth-century philosopher and scientist René Descartes discussed the pineal gland both in his first book, the Treatise of Man (written before 1637, but only published posthumously 1662/1664), and in his last book, The Passions of the Soul (1649) and he regarded it as "the principal seat of the soul and the place in which all our thoughts are formed".[75] In the Treatise of Man, he described conceptual models of man, namely creatures created by God, which consist of two ingredients, a body and a soul.[75][76] In the Passions, he split man up into a body and a soul and emphasized that the soul is joined to the whole body by "a certain very small gland situated in the middle of the brain's substance and suspended above the passage through which the spirits in the brain's anterior cavities communicate with those in its posterior cavities". Descartes gave importance to the structure as it was the only unpaired component of the brain.[75]

The Latin name pinealis became popular in the 17th century. For example, English physician Thomas Willis described glandula pinealis book, Cerebri anatome cui accessit nervorum descriptio et usus (1664). Willis criticised Descartes' concept, remarking: "we can scarce[ly] believe this to be the seat of the Soul, or its chief Faculties to arise from it; because Animals, which seem to be almost quite destitute of Imagination, Memory, and other superior Powers of the Soul, have this Glandula or Kernel large and fair enough."[74]

Walter Baldwin Spencer at the University of Oxford gave the first description of the pineal gland in lizards. In 1886, he described an eye-like structure, which he called the pineal eye or parietal eye, that were associated with the parietal foramen and the pineal stalk.[77] The main pineal body was already discovered by German zoologist Franz Leydig in 1872 from European lizards. Leydig called them frontal organ (German stirnorgan).[78][79] In 1918, Swedish zoologist Nils Holmgren described the parietal eye in frogs and dogfish.[80] He discovered that the parietal eyes were made up of sensory cells similar to the cone cells of the retina,[74] and suggested that it was a primitive light-sensor organ (photoreceptor).[80]

The pineal gland was originally believed to be a "vestigial remnant" of a larger organ. In 1917, it was known that extract of cow pineals lightened frog skin. Dermatology professor Aaron B. Lerner and colleagues at Yale University, hoping that a substance from the pineal might be useful in treating skin diseases, isolated and named the hormone melatonin in 1958.[81] The substance did not prove to be helpful as intended, but its discovery helped solve several mysteries such as why removing the rat's pineal accelerated ovary growth, why keeping rats in constant light decreased the weight of their pineals, and why pinealectomy and constant light affect ovary growth to an equal extent; this knowledge gave a boost to the then new field of chronobiology.[82] Of the endocrine organs, the function of the pineal gland was the last discovered.[83]

Society and culture Edit

The notion of a "pineal-eye" is central to the philosophy of the French writer Georges Bataille, which is analyzed at length by literary scholar Denis Hollier in his study Against Architecture. In this work Hollier discusses how Bataille uses the concept of a "pineal-eye" as a reference to a blind-spot in Western rationality, and an organ of excess and delirium.[84] This conceptual device is explicit in his surrealist texts, The Jesuve and The Pineal Eye.[85]

In the late 19th century Madame Blavatsky, founder of theosophy, identified the pineal gland with the Hindu concept of the third eye, or the Ajna chakra. This association is still popular today.[75] The pineal gland has also featured in other religious contexts, such as in the Principia Discordia, which claims it can be used to contact the goddess of discord Eris.[86]

In the short story "From Beyond" by H. P. Lovecraft, a scientist creates an electronic device that emits a resonance wave, which stimulates an affected person's pineal gland, thereby allowing them to perceive planes of existence outside the scope of accepted reality, a translucent, alien environment that overlaps our own recognized reality. It was adapted as a film of the same name in 1986. The 2013 horror film Banshee Chapter is heavily influenced by this short story.

Additional images Edit

The pineal body is labeled in these images.

  •  

    Mesal aspect of a brain sectioned in the median sagittal plane

  •  

    Dissection showing the ventricles of the brain

  •  

    Hind- and mid-brains; antero-lateral view

  •  

    Median sagittal section of brain

  •  

    Pineal gland

  •  

    Brainstem; posterior view

See also Edit

References Edit

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October 14, 2023
pineal, gland, conarium, redirects, here, video, game, conarium, video, game, pineal, gland, also, known, pineal, body, conarium, epiphysis, cerebri, small, endocrine, gland, brain, most, vertebrates, pineal, gland, produces, melatonin, serotonin, derived, hor. Conarium redirects here For the video game see Conarium video game The pineal gland also known as the pineal body 1 conarium or epiphysis cerebri is a small endocrine gland in the brain of most vertebrates The pineal gland produces melatonin a serotonin derived hormone which modulates sleep patterns in both circadian and seasonal cycles The shape of the gland resembles a pine cone which gives it its name 2 The pineal gland is located in the epithalamus near the center of the brain between the two hemispheres tucked in a groove where the two halves of the thalamus join 3 4 It is one of the neuroendocrine secretory circumventricular organs in which capillaries are mostly permeable to solutes in the blood 5 Pineal glandPineal gland or epiphysis in red Diagram of pituitary and pineal glands in the human brainDetailsPrecursorNeural ectoderm roof of diencephalonArteryPosterior cerebral arteryIdentifiersLatinGlandula pinealisMeSHD010870NeuroNames297NeuroLex IDbirnlex 1184TA98A11 2 00 001TA23862FMA62033Anatomical terms of neuroanatomy edit on Wikidata The pineal gland is present in almost all vertebrates but is absent in protochordates in which there is a simple pineal homologue The hagfish considered as a primitive vertebrate has a rudimentary structure regarded as the pineal equivalent in the dorsal diencephalon 6 In some species of amphibians and reptiles the gland is linked to a light sensing organ variously called the parietal eye the pineal eye or the third eye 7 Reconstruction of the biological evolution pattern suggests that the pineal gland was originally a kind of atrophied photoreceptor that developed into a neuroendocrine organ Ancient Greeks were the first to notice the pineal gland and believed it to be a valve a guardian for the flow of pneuma Galen in the 2nd century C E could not find any functional role and regarded the gland as a structural support for the brain tissue He gave the name konario meaning cone or pinecone which during Renaissance was translated to Latin as pinealis In the 17th century Rene Descartes revived the mystical purpose and described the gland as the principal seat of the soul In the mid 20th century the real biological role as a neuroendocrine organ was established 8 Contents 1 Etymology 2 Structure 2 1 Location 2 2 Blood supply 2 3 Afferents 2 4 Neural pathway for melatonin production 2 5 Microanatomy 2 6 Development 2 7 Symmetry 3 Function 3 1 Regulation of the pituitary gland 3 2 Regulation of bone metabolism 4 Clinical significance 4 1 Calcification 4 2 Tumors 4 3 Other conditions 5 Other animals 6 History 7 Society and culture 8 Additional images 9 See also 10 References 11 External linksEtymology EditThe word pineal from Latin pinea pine cone was first used in the late 17th century to refer to the cone shape of the brain gland 2 Structure EditThe pineal gland is a pine cone shaped hence the name unpaired midline brain structure 2 9 It is reddish gray in colour and about the size of a grain of rice 5 8 mm in humans It forms part of the epithalamus 1 It is attached to the rest of the brain by a pineal stalk 10 Location Edit It normally lies in a depression between the two superior colliculi 10 It is situated between the laterally positioned thalamic bodies and posterior to the habenular commissure It is located in the quadrigeminal cistern 1 It is located posterior to the third ventricle and encloses the small cerebrospinal fluid filled pineal recess of the third ventricle which projects into the stalk of the gland 11 The ventral lamina of the pituitary stalk is continuous with the posterior commissure and its dorsal lamina with the habenular commissure 10 Blood supply Edit Unlike most of the mammalian brain the pineal gland is not isolated from the body by the blood brain barrier system 12 it has profuse blood flow second only to the kidney 13 supplied from the choroidal branches of the posterior cerebral artery Afferents Edit The pineal gland receives sympathetic afferents from the superior cervical ganglion 14 and parasympathetic afferents from the pterygopalatine ganglia and otic ganglia 14 15 According to research on animals neurons of the trigeminal ganglion that are involved in pituitary adenylate cyclase activating peptide neuropeptide signaling project the gland 16 15 Neural pathway for melatonin production Edit The canonical neural pathway regulating pineal melatonin production begins in the eye with the intrinsically photosensitive ganglion cells of the retina which project inhibitory GABAergic efferents to the paraventricular nucleus of hypothalamus via the retinohypothalamic tract The paraventricular nucleus in turn projects to the superior cervical ganglia which finally projects to the pineal gland Darkness thus leads to disinhibition of the paraventricular nucleus leading it to activate pineal gland melatonin production by way of the superior cervical ganglia 17 Microanatomy Edit nbsp Pineal gland parenchyma with calcifications nbsp Micrograph of a normal pineal gland very high magnification nbsp Micrograph of a normal pineal gland intermediate magnificationThe pineal body in humans consists of a lobular parenchyma of pinealocytes surrounded by connective tissue spaces The gland s surface is covered by a pial capsule The pineal gland consists mainly of pinealocytes but four other cell types have been identified As it is quite cellular in relation to the cortex and white matter it may be mistaken for a neoplasm 18 Cell type DescriptionPinealocytes The pinealocytes consist of a cell body with 4 6 processes emerging They produce and secrete melatonin The pinealocytes can be stained by special silver impregnation methods Their cytoplasm is lightly basophilic With special stains pinealocytes exhibit lengthy branched cytoplasmic processes that extend to the connective septa and its blood vessels Interstitial cells Interstitial cells are located between the pinealocytes They have elongated nuclei and a cytoplasm that is stained darker than that of the pinealocytes Perivascular phagocyte Many capillaries are present in the gland and perivascular phagocytes are located close to these blood vessels The perivascular phagocytes are antigen presenting cells Pineal neurons In higher vertebrates neurons are usually located in the pineal gland However this is not the case in rodents Peptidergic neuron like cells In some species neuronal like peptidergic cells are present These cells might have a paracrine regulatory function Development Edit The human pineal gland grows in size until about 1 2 years of age remaining stable thereafter 19 20 although its weight increases gradually from puberty onwards 21 22 The abundant melatonin levels in children are believed to inhibit sexual development and pineal tumors have been linked with precocious puberty When puberty arrives melatonin production is reduced 23 Symmetry Edit In the zebrafish the pineal gland does not straddle the midline but shows a left sided bias In humans functional cerebral dominance is accompanied by subtle anatomical asymmetry 24 25 26 Function EditOne function of the pineal gland is to produce melatonin Melatonin has various functions in the central nervous system the most important of which is to help modulate sleep patterns Melatonin production is stimulated by darkness and inhibited by light 27 28 Light sensitive nerve cells in the retina detect light and send this signal to the suprachiasmatic nucleus SCN synchronizing the SCN to the day night cycle Nerve fibers then relay the daylight information from the SCN to the paraventricular nuclei PVN then to the spinal cord and via the sympathetic system to superior cervical ganglia SCG and from there into the pineal gland The compound pinoline is also claimed to be produced in the pineal gland it is one of the beta carbolines 29 This claim is subject to some controversy citation needed Regulation of the pituitary gland Edit Studies on rodents suggest that the pineal gland influences the pituitary gland s secretion of the sex hormones follicle stimulating hormone FSH and luteinizing hormone LH Pinealectomy performed on rodents produced no change in pituitary weight but caused an increase in the concentration of FSH and LH within the gland 30 Administration of melatonin did not return the concentrations of FSH to normal levels suggesting that the pineal gland influences pituitary gland secretion of FSH and LH through an undescribed transmitting molecule 30 The pineal gland contains receptors for the regulatory neuropeptide endothelin 1 31 which when injected in picomolar quantities into the lateral cerebral ventricle causes a calcium mediated increase in pineal glucose metabolism 32 Regulation of bone metabolism Edit Studies in mice suggest that the pineal derived melatonin regulates new bone deposition Pineal derived melatonin mediates its action on the bone cells through MT2 receptors This pathway could be a potential new target for osteoporosis treatment as the study shows the curative effect of oral melatonin treatment in a postmenopausal osteoporosis mouse model 33 Clinical significance EditCalcification Edit Calcification of the pineal gland is typical in young adults and has been observed in children as young as two years of age 34 The internal secretions of the pineal gland are known to inhibit the development of the reproductive glands because when it is severely damaged in children development of the sexual organs and the skeleton are accelerated 35 Pineal gland calcification is detrimental to its ability to synthesize melatonin 36 37 and scientific literature presents inconclusive findings on whether it causes sleep problems 38 39 The calcified gland is often seen in skull X rays 34 Calcification rates vary widely by country and correlate with an increase in age with calcification occurring in an estimated 40 of Americans by age seventeen 34 Calcification of the pineal gland is associated with corpora arenacea also known as brain sand Tumors Edit Tumors of the pineal gland are called pinealomas These tumors are rare and 50 to 70 are germinomas that arise from sequestered embryonic germ cells Histologically they are similar to testicular seminomas and ovarian dysgerminomas 40 A pineal tumor can compress the superior colliculi and pretectal area of the dorsal midbrain producing Parinaud s syndrome Pineal tumors also can cause compression of the cerebral aqueduct resulting in a noncommunicating hydrocephalus Other manifestations are the consequence of their pressure effects and consist of visual disturbances headache mental deterioration and sometimes dementia like behaviour 41 These neoplasms are divided into three categories pineoblastomas pineocytomas and mixed tumors based on their level of differentiation which in turn correlates with their neoplastic aggressiveness 42 The clinical course of patients with pineocytomas is prolonged averaging up to several years 43 The position of these tumors makes them difficult to remove surgically Other conditions Edit The morphology of the pineal gland differs markedly in different pathological conditions For instance it is known that its volume is reduced both in obese patients as well as patients with primary insomnia 44 Other animals EditNearly all vertebrate species possess a pineal gland The most important exception is a primitive vertebrate the hagfish Even in the hagfish however there may be a pineal equivalent structure in the dorsal diencephalon 6 A few more complex vertebrates have lost pineal glands over the course of their evolution 45 The lamprey another primitive vertebrate however does possess one 46 The lancelet Branchiostoma lanceolatum an early chordate which is a close relative to vertebrates also lacks a recognizable pineal gland 46 Protochordates in general do not have the distinct structure as an organ but they have a mass of photoreceptor cells called lamellar body which is regarded as a pineal homologue 47 48 The results of various scientific research in evolutionary biology comparative neuroanatomy and neurophysiology have explained the evolutionary history phylogeny of the pineal gland in different vertebrate species From the point of view of biological evolution the pineal gland is a kind of atrophied photoreceptor In the epithalamus of some species of amphibians and reptiles it is linked to a light sensing organ known as the parietal eye which is also called the pineal eye or third eye 7 It is likely that the common ancestor of all vertebrates had a pair of photosensory organs on the top of its head similar to the arrangement in modern lampreys 49 In many lower vertebrates such as species of fish amphibians and lizards the pineal gland is associated with parietal or pineal eye In these animals the parietal eye acts as a photoreceptor and hence are also known as the third eye and they can be seen on top of the head in some species 50 Some extinct Devonian fishes have two parietal foramina in their skulls 51 52 suggesting an ancestral bilaterality of parietal eyes The parietal eye and the pineal gland of living tetrapods are probably the descendants of the left and right parts of this organ respectively 53 During embryonic development the parietal eye and the pineal organ of modern lizards 54 and tuataras 55 form together from a pocket formed in the brain ectoderm The loss of parietal eyes in many living tetrapods is supported by developmental formation of a paired structure that subsequently fuses into a single pineal gland in developing embryos of turtles snakes birds and mammals 56 The pineal organs of mammals fall into one of three categories based on shape Rodents have more structurally complex pineal glands than other mammals 57 Crocodilians and some tropical lineages of mammals some xenarthrans sloths pangolins sirenians manatees and dugongs and some marsupials sugar gliders have lost both their parietal eye and their pineal organ 58 59 57 Polar mammals such as walruses and some seals possess unusually large pineal glands 58 All amphibians have a pineal organ but some frogs and toads also have what is called a frontal organ which is essentially a parietal eye 60 Pinealocytes in many non mammalian vertebrates have a strong resemblance to the photoreceptor cells of the eye Evidence from morphology and developmental biology suggests that pineal cells possess a common evolutionary ancestor with retinal cells 61 Pineal cytostructure seems to have evolutionary similarities to the retinal cells of the lateral eyes 61 Modern birds and reptiles express the phototransducing pigment melanopsin in the pineal gland Avian pineal glands are thought to act like the suprachiasmatic nucleus in mammals 62 The structure of the pineal eye in modern lizards and tuatara is analogous to the cornea lens and retina of the lateral eyes of vertebrates 56 In most vertebrates exposure to light sets off a chain reaction of enzymatic events within the pineal gland that regulates circadian rhythms 63 In humans and other mammals the light signals necessary to set circadian rhythms are sent from the eye through the retinohypothalamic system to the suprachiasmatic nuclei SCN and the pineal gland The fossilized skulls of many extinct vertebrates have a pineal foramen opening which in some cases is larger than that of any living vertebrate 64 Although fossils seldom preserve deep brain soft anatomy the brain of the Russian fossil bird Cerebavis cenomanica from Melovatka about 90 million years old shows a relatively large parietal eye and pineal gland 65 History Edit nbsp Diagram of the operation of the pineal gland for Descartes in the Treatise of Man figure published in the edition of 1664 The secretory activity of the pineal gland is only partially understood Its location deep in the brain suggested to philosophers throughout history that it possesses particular importance This combination led to its being regarded as a mystery gland with mystical metaphysical and occult theories surrounding its perceived functions The earliest recorded description of the pineal gland is from the Greek physician Galen in the 2nd century C E 66 According to Galen Herophilus 325 280 B C E had already considered the structure as a kind of valve that partitioned the brain chambers particularly for the flow of vital spirits pneuma 67 Specifically the ancient Greeks believed that the structure maintains the movement vital spirits from the middle now identified to the third ventricle to the one in the parencephalis fourth ventricle 68 69 Galen described the pineal gland in De usu partium corporis humani libri VII On the Usefulness of Parts of the Body Part 8 and De anatomicis administrationibus libri IX On Anatomical Procedures Part 9 70 He introduced the name kwnario konario often Latinised as conarium that means cone as in pinecone 71 in De usu partium corporis humani He correctly located the gland as directly lying behind the third ventricle He argued against the prevailing concept as a valve for two basic reasons it is located outside of the brain tissue and it does not move on its own 66 Galen instead identified the valve as a worm like structure in the cerebellum later called vermiform epiphysis known today as the vermis cerebelli or cerebellar vermis 72 From his study on the blood vessels surrounding the pineal gland he discovered the great vein of the cerebellum later called the vein of Galen 71 73 He could not establish any functional role of the pineal gland and regarded it as a structural support for the cerebral veins 74 Seventeenth century philosopher and scientist Rene Descartes discussed the pineal gland both in his first book the Treatise of Man written before 1637 but only published posthumously 1662 1664 and in his last book The Passions of the Soul 1649 and he regarded it as the principal seat of the soul and the place in which all our thoughts are formed 75 In the Treatise of Man he described conceptual models of man namely creatures created by God which consist of two ingredients a body and a soul 75 76 In the Passions he split man up into a body and a soul and emphasized that the soul is joined to the whole body by a certain very small gland situated in the middle of the brain s substance and suspended above the passage through which the spirits in the brain s anterior cavities communicate with those in its posterior cavities Descartes gave importance to the structure as it was the only unpaired component of the brain 75 The Latin name pinealis became popular in the 17th century For example English physician Thomas Willis described glandula pinealis book Cerebri anatome cui accessit nervorum descriptio et usus 1664 Willis criticised Descartes concept remarking we can scarce ly believe this to be the seat of the Soul or its chief Faculties to arise from it because Animals which seem to be almost quite destitute of Imagination Memory and other superior Powers of the Soul have this Glandula or Kernel large and fair enough 74 Walter Baldwin Spencer at the University of Oxford gave the first description of the pineal gland in lizards In 1886 he described an eye like structure which he called the pineal eye or parietal eye that were associated with the parietal foramen and the pineal stalk 77 The main pineal body was already discovered by German zoologist Franz Leydig in 1872 from European lizards Leydig called them frontal organ German stirnorgan 78 79 In 1918 Swedish zoologist Nils Holmgren described the parietal eye in frogs and dogfish 80 He discovered that the parietal eyes were made up of sensory cells similar to the cone cells of the retina 74 and suggested that it was a primitive light sensor organ photoreceptor 80 The pineal gland was originally believed to be a vestigial remnant of a larger organ In 1917 it was known that extract of cow pineals lightened frog skin Dermatology professor Aaron B Lerner and colleagues at Yale University hoping that a substance from the pineal might be useful in treating skin diseases isolated and named the hormone melatonin in 1958 81 The substance did not prove to be helpful as intended but its discovery helped solve several mysteries such as why removing the rat s pineal accelerated ovary growth why keeping rats in constant light decreased the weight of their pineals and why pinealectomy and constant light affect ovary growth to an equal extent this knowledge gave a boost to the then new field of chronobiology 82 Of the endocrine organs the function of the pineal gland was the last discovered 83 Society and culture EditThe notion of a pineal eye is central to the philosophy of the French writer Georges Bataille which is analyzed at length by literary scholar Denis Hollier in his study Against Architecture In this work Hollier discusses how Bataille uses the concept of a pineal eye as a reference to a blind spot in Western rationality and an organ of excess and delirium 84 This conceptual device is explicit in his surrealist texts The Jesuve and The Pineal Eye 85 In the late 19th century Madame Blavatsky founder of theosophy identified the pineal gland with the Hindu concept of the third eye or the Ajna chakra This association is still popular today 75 The pineal gland has also featured in other religious contexts such as in the Principia Discordia which claims it can be used to contact the goddess of discord Eris 86 In the short story From Beyond by H P Lovecraft a scientist creates an electronic device that emits a resonance wave which stimulates an affected person s pineal gland thereby allowing them to perceive planes of existence outside the scope of accepted reality a translucent alien environment that overlaps our own recognized reality It was adapted as a film of the same name in 1986 The 2013 horror film Banshee Chapter is heavily influenced by this short story Additional images EditThe pineal body is labeled in these images nbsp Mesal aspect of a brain sectioned in the median sagittal plane nbsp Dissection showing the ventricles of the brain nbsp Hind and mid brains antero lateral view nbsp Median sagittal section of brain nbsp Pineal gland nbsp Brainstem posterior viewSee also EditPineal gland cystReferences Edit a b c Chen CY Chen FH Lee CC Lee KW Hsiao HS October 1998 Sonographic characteristics of the cavum velum interpositum PDF AJNR American Journal of Neuroradiology 19 9 1631 1635 PMC 8337493 PMID 9802483 a b c Pineal as an adjective Online Etymology Dictionary Douglas Harper 2018 Retrieved 27 October 2018 Macchi MM Bruce JN 2004 Human pineal physiology and functional significance of melatonin Frontiers in Neuroendocrinology 25 3 4 177 195 doi 10 1016 j yfrne 2004 08 001 PMID 15589268 S2CID 26142713 Arendt J Skene DJ February 2005 Melatonin as a chronobiotic Sleep Medicine Reviews 9 1 25 39 doi 10 1016 j smrv 2004 05 002 PMID 15649736 Exogenous melatonin has acute sleepiness inducing and temperature lowering effects during biological daytime and when suitably timed it is most 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Vie en Noir Cham Springer International Publishing pp 9 21 doi 10 1007 978 3 319 41679 3 2 ISBN 978 3 319 41678 6 Lopez Munoz F Marin F Alamo C 2016 History of Pineal Gland as Neuroendocrine Organ and the Discovery of Melatonin In Lopez Munoz F Srinivasan V de Berardis D Alamo C eds Melatonin Neuroprotective Agents and Antidepressant Therapy New Delhi Springer India pp 1 23 doi 10 1007 978 81 322 2803 5 1 ISBN 978 81 322 2801 1 Retrieved 28 March 2023 a b Laios K July 2017 The Pineal Gland and its earliest physiological description Hormones 16 3 328 330 doi 10 14310 horm 2002 1751 PMID 29278521 Steinsiepe KF January 2023 The worm in our brain An anatomical historical and philological study on the vermis cerebelli Journal of the History of the Neurosciences 32 3 265 300 doi 10 1080 0964704X 2022 2146515 PMID 36599122 S2CID 255470624 Ustun C September 2004 Galen and his anatomic eponym vein of Galen Clinical Anatomy 17 6 454 457 doi 10 1002 ca 20013 PMID 15300863 a b c Pearce JM 2022 The pineal seat of the soul Hektoen International ISSN 2155 3017 Retrieved 28 March 2023 a b c d Lokhorst GJ 2015 Descartes and the Pineal Gland Stanford The Stanford Encyclopedia of Philosophy Descartes R 2002 The Passions of the Soul In Chalmers D ed Philosophy of the Mind New York Oxford University Press Inc ISBN 978 0 19 514581 6 Spencer B 1885 On the Presence and Structure of the Pineal Eye in Lacertilia Quarterly Journal of Microscopy London pp 1 76 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Flemming AF 1991 A third eye Culna 40 26 27 via Sabinet Eakin RM 1973 3 Structure The Third Eye University of California Press pp 32 84 doi 10 1525 9780520326323 004 ISBN 978 0 520 32632 3 a b Wurtman RJ Axelrod J July 1965 The Pineal Gland Scientific American 213 1 50 60 Bibcode 1965SciAm 213a 50W doi 10 1038 scientificamerican0765 50 PMID 14298722 Lerner AB Case JD Takahashi Y July 1960 Isolation of melatonin and 5 methoxyindole 3 acetic acid from bovine pineal glands The Journal of Biological Chemistry 235 7 1992 1997 doi 10 1016 S0021 9258 18 69351 2 PMID 14415935 Coates PM Blackman MR Cragg GM Levine M Moss J White JD 2005 Encyclopedia of Dietary Supplements CRC Press p 457 ISBN 978 0 8247 5504 1 Retrieved 31 March 2009 Sahai A Sahai RJ December 2013 Pineal gland A structural and functional enigma Journal of the Anatomical Society of India 62 2 170 177 doi 10 1016 j jasi 2014 01 001 Hollier D 1989 Against Architecture The Writings of Georges Bataille Translated by Wing B MIT Bataille G 1985 Visions of excess Selected writings 1927 1939 Manchester University Press Principia Discordia Page 15 principiadiscordia com Retrieved 22 September 2023 External links Edit nbsp Wikimedia Commons has media related to Pineal gland nbsp Look up pineal gland in Wiktionary the free dictionary Retrieved from https en wikipedia org w index php title Pineal gland amp oldid 1178598054, wikipedia, wiki, book, books, library,

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