565) Anteater

Anteater, (suborder Vermilingua), any of four species of toothless, insect-eating mammals found in tropical savannas and forests from southern Mexico to Paraguay and northern Argentina. They are long-tailed animals with elongated skulls and tubular muzzles. The mouth opening of the muzzle is small, but the salivary glands are large and secrete sticky saliva onto a wormlike tongue, which can be as long as 60 cm (24 inches) in the giant anteater. Anteaters live alone or in pairs (usually mother and offspring) and feed mainly on ants and termites. They capture their prey by inserting their tongues into insect nests that they have torn open with the long, sharp, curved claws of their front feet; the claws are also used for defense. Giant anteaters and the smaller tamanduas use their hind legs and tail as a tripod when threatened, which thus frees the front limbs to slash at attackers.

The Giant Anteater

The giant anteater (Myrmecophaga tridactyla), sometimes called the ant bear, is the largest member of the anteater family and is best known in the tropical grasslands (Llanos) of Venezuela, where it is still common. It was once found in the lowland forests of Central America and still lives in the Amazon basin southward to the grasslands of Paraguay and Argentina. Gray with a diagonal white-bordered black stripe on each shoulder, the giant anteater attains a length of about 1.8 metres (6 feet), including the long bushy tail, and weighs up to 40 kg (88 pounds). This ground dweller is mainly diurnal, but in areas near human settlement it is most active at night.

Using its keen sense of smell to track ants, the giant anteater walks with a shuffle, bearing its weight on the sides and knuckles of its forefeet. When harried, it is capable of a clumsy gallop. The giant anteater is also a good swimmer. It does not seem to use dens or other resting places on a permanent basis but chooses instead a secluded spot where it can curl up to rest, with its huge tail covering both its head and its body. Females bear a single offspring after a gestation period of about 190 days. A young anteater looks identical, except in size, to an adult, and, from two or three weeks following birth until it is about a year old, it rides on its mother’s back as she travels. The home ranges of individual anteaters living in the Llanos overlap and can cover more than 2,500 hectares (6,000 acres). The giant anteater is the longest-lived anteater; one in captivity reportedly survived 25 years.

The Tamandua

Unlike the giant anteater, the lesser anteater, or tamandua (genus Tamandua), is arboreal as well as terrestrial. The two tamandua species are similar in size—about 1.2 metres (4 feet) long, including the almost-hairless prehensile tail, which is used for climbing. They are often tan with a blackish “vest” around the shoulders and on the body, but some are entirely tan or entirely black. Tamanduas have shorter fur and proportionately shorter muzzles than giant anteaters.

The tamandua, meaning “catcher of ants” in the Tupí language of eastern Brazil, eats both termites and ants and often uses the same pathway day after day in search of food. Although many species of ants are eaten by tamanduas, they are selective, eating relatively few ants of any given colony and avoiding those with painful stings or bites, such as army ants (genus Eciton). Tamandua dens can be found in hollow trees and logs or in the ground, and individual home ranges cover about 75 hectares (185 acres). The northern tamandua (T. mexicana) is found from eastern Mexico to northwestern South America; the southern tamandua (T. tetradactyla) is found from the island of Trinidad southward to northern Argentina.

The Silky Anteater

Also known as the two-toed, pygmy, or dwarf anteater, the silky anteater (Cyclopes didactylus) is the smallest and least-known member of the family. The silky anteater is found from southern Mexico southward to Bolivia and Brazil. It is not rare but is difficult to spot because it is nocturnal and lives high in the trees. It is also exquisitely camouflaged, its silky yellowish coat matching both the colour and the texture of fibrous seed masses produced by the silk-cotton tree. During the day the silky anteater rests amid clumps of tropical vines.

Silky anteaters seldom exceed 300 grams (11 ounces). The animal’s maximum overall length is about 44 cm (17 inches). About one-half of that length is the furred prehensile tail. There are two clawed toes on each forefoot. (The forefoot of the tamandua has four clawed toes, whereas that of the giant anteater has three prominent clawed toes flanked by two small toes.) The silky anteater has large eyes that allow foraging at night. The feet are equipped with heel pads that can be opposed against the claws, enabling the animal to grip small branches as it travels the forest canopy along lianas and other vines. Males live in territories of 5–10 hectares (12–25 acres) that overlap with those of several females.

Classification

The giant anteater and tamanduas constitute the family Myrmecophagidae, which means “ant-eating” in Latin, whereas the silky anteater is classified in a family of its own, Cyclopedidae. Together the two families make up the anteater suborder, Vermilingua (literally “worm-tongue” in Latin). Anteaters, along with sloths, are placed within the mammalian order Pilosa of the magnorder Xenarthra. A number of animals unrelated to the myrmecophagids are also called anteaters. The banded anteater, for example, is a marsupial. The scaly anteater was formerly grouped with xenarthrans in an order called Edentata, but it has since been assigned to its own separate order. The short-beaked echidna is often called a spiny anteater, but this animal is even more distantly related. The African aardvark also belongs to a different mammalian order, yet, like the anteater, it has a tubular muzzle for eating ants and is sometimes called an antbear.

Hi,

#4771. Ralph obtained 36, 25, 34, and 25 marks in history, geography, biology, and physics. What are his average marks?

Hi,

#3551. What does the noun endorsement mean?

#3552. What does the noun endoskeleton (Zoology) mean?

562) Pituitary gland

Pituitary gland, also called hypophysis, ductless gland of the endocrine system that secretes hormones directly into the bloodstream. The term hypophysis (from the Greek for “lying under”)—another name for the pituitary—refers to the gland’s position on the underside of the brain. The pituitary gland is called the “master gland” because its hormones regulate other important endocrine glands—including the adrenal, thyroid, and reproductive glands — and in some cases have direct regulatory effects in major tissues, such as those of the musculoskeletal system.

Anatomy Of The Pituitary Gland

The pituitary gland lies at the middle of the base of the skull and is housed within a bony structure called the sella turcica, which is behind the nose and immediately beneath the hypothalamus. The pituitary gland is attached to the hypothalamus by a stalk composed of neuronal axons and the so-called hypophyseal-portal veins. Its weight in normal adult humans ranges from about 500 to 900 mg (0.02 to 0.03 ounce).

In most species the pituitary gland is divided into three lobes: the anterior lobe, the intermediate lobe, and the posterior lobe (also called the neurohypophysis or pars nervosa). In humans the intermediate lobe does not exist as a distinct anatomic structure but rather remains only as cells dispersed within the anterior lobe. Nonetheless, the anterior and posterior lobes of the pituitary are functionally, anatomically, and embryologically distinct. Whereas the anterior pituitary contains abundant hormone-secreting epithelial cells, the posterior pituitary is composed largely of unmyelinated (lacking a sheath of fatty insulation) secretory neurons.

The Anterior Pituitary

The cells of the anterior pituitary are embryologically derived from an outpouching of the roof of the pharynx, known as Rathke’s pouch. Although the cells appear to be relatively homogeneous under a light microscope, there are in fact at least five different types of cells, each of which secretes a different hormone or hormones. The thyrotrophs synthesize and secrete thyrotropin (thyroid-stimulating hormone; TSH); the gonadotrophs, both luteinizing hormone (LH) and follicle-stimulating hormone (FSH); the corticotrophs, adrenocorticotropic hormone (ACTH; corticotropin); the somatotrophs, growth hormone (GH; somatotropin); and the lactotrophs, prolactin.

Somatotrophs are plentiful in the anterior pituitary gland, constituting about 40 percent of the tissue. They are located predominantly in the anterior and the lateral regions of the gland and secrete between one and two milligrams of GH each day.

Structure and function of anterior pituitary hormones

The hormones of the anterior pituitary are proteins that consist of one or two long polypeptide chains. TSH, LH, and FSH are called glycoproteins because they contain complex carbohydrates known as glycosides. Each of those hormones is composed of two glycopeptide chains, one of which, the alpha chain, is identical in all three hormones. The other chain, the beta chain, differs in structure for each hormone, thereby explaining the different actions of TSH, LH, and FSH. As is the case for all protein hormones, the hormones of the anterior pituitary are synthesized in the cytoplasm of the cells as large inactive molecules called prohormones. Those prohormones are stored in granules, within which they are cleaved into active hormones and are secreted into the circulation.

Each pituitary hormone plays a vital role in endocrine function. Thyrotropin stimulates the production of thyroid hormone. ACTH stimulates the production of cortisol and androgenic hormones by the adrenal cortex. FSH stimulates the production of estrogens and the growth of egg cells (oocytes) in the women and male gamete cells in men. LH stimulates the production of estrogens and progesterone by the ovaries in women and the production of testosterone by the testes in men. GH stimulates linear growth in children and helps to maintain bone and other tissues in adults. Prolactin stimulates milk production.

Regulation of anterior pituitary hormones

The production and secretion of each of the major anterior pituitary hormones are regulated by peptides that are released from the median eminence neurons of the hypothalamus into the hypophyseal-portal veins, which traverse a short distance to the pituitary microvasculature. Among those peptides are thyrotropin-releasing hormone (TRH), corticotropin-releasing hormone, gonadotropin-releasing hormone, and growth-hormone-releasing hormone. The hypothalamus also produces dopamine and somatostatin, which are potent inhibitors of prolactin and GH, respectively.

Feedback loops involving the pituitary hormones and their target glands play an important role in pituitary-hormone signaling. TRH secretion, for example, is inhibited by thyroid hormone, which also inhibits the effect of TRH on thyrotrophs. Such negative feedback loops help to maintain a stable balance between the secretion of pituitary hormones and the secretion of hormones produced by pituitary target glands. Physiological perturbations, such as the effects of stress on the pituitary-adrenal axis and neuroendocrine rhythms, can override that balance.

Posterior Pituitary Hormones

The posterior lobe of the pituitary gland consists largely of extensions of processes (axons) from two pairs of large clusters of nerve cell bodies (nuclei) in the hypothalamus. One of those nuclei, known as the supraoptic nuclei, lies immediately above the optic tract, while the other nuclei, known as the paraventricular nuclei, lies on each side of the third ventricle of the brain. Those nuclei, the axons of the cell bodies of nerves that form the nuclei, and the nerve endings in the posterior pituitary gland form the neurohypophyseal system. There are neural connections that run from those nuclei to other regions of the brain, including to regions that sense osmolality (solute concentrations) and regulate thirst.

The major neurohypophyseal hormones are vasopressin (antidiuretic hormone) and oxytocin, which are synthesized and incorporated into neurosecretory granules in the cell bodies of the nuclei. Those hormones are synthesized as part of a precursor protein that includes one of the hormones and a protein called neurophysin. After synthesis and incorporation into neurosecretory granules, the precursor protein is cleaved, forming separate hormone and neurophysin molecules, which remain loosely attached to one another. Those granules are carried through the axons and are stored in the posterior lobe of the pituitary gland. Upon stimulation of the nerve cells by internal or external events (e.g., milk suckling in the case of oxytocin-secreting neurons), the granules fuse with the cell wall of the nerve endings, the hormone and neurophysin dissociate from one another, and both the hormone and the neurophysin are released into the bloodstream. The hormones are released into the circulation in response to nerve signals that originate in the hypothalamus and are transmitted to the posterior pituitary lobe.

Oxytocin stimulates contraction of the uterus, an important aspect of labour and parturition and of milk ejection during breast-feeding. Vasopressin regulates blood pressure and increases reabsorption of water from the kidneys, thus conserving body water and defending against dehydration. Vasopressin secretion is stimulated by increased serum osmolality, which is an indication of dehydration.

Diseases Of The Anterior And Posterior Pituitary

Decreased secretion of anterior and posterior pituitary hormones is known as panhypopituitarism, a serious and sometimes fatal disorder. The term panhypopituitarism is also commonly used when only anterior pituitary hormones are deficient. Patients with panhypopituitarism usually have features of adrenal insufficiency, hypothyroidism, and gonadal failure, along with poor responses to stress. Pituitary vascular insufficiency, autoimmunity, infections, and neoplasms can cause panhypopituitarism. If central diabetes insipidus is present, the lesion generally involves the posterior as well as the anterior pituitary. Isolated deficiencies of one or two pituitary hormones also may occur, often on a heritable basis. Those conditions are rare. Some patients may present with infertility due to LH and FSH deficiency. Proportionate congenital growth failure due to GH deficiency is a predominant type of isolated deficiency.

Tumours that secrete individual anterior pituitary hormones are recognized. Acromegaly due to GH-secreting tumours and Cushing syndrome due to ACTH-producing tumours are among the most-common disorders produced by functional pituitary tumours, though even those conditions are rare. Autonomous hypersecretion of prolactin is a common feature of pituitary tumours, since such growths tend to interfere (via tissue compression) with prolactin-suppressing signals from the hypothalamus. Excess prolactin typically is associated with varying degrees of gonadal failure and in some cases with spontaneous breast-milk secretion (galactorrhea) in men and women. Posterior pituitary tumours that secrete excess vasopressin or oxytocin do not occur; however, functional states of excess vasopressin (inappropriate vasopressin secretion) and transient vasopressin deficiency have been described.

697) Jules Bordet

Jules Bordet, in full Jules-Jean-Baptiste-Vincent Bordet, (born June 13, 1870, Soignies, Belg.—died April 6, 1961, Brussels), Belgian physician, bacteriologist, and immunologist who received the Nobel Prize for Physiology or Medicine in 1919 for his discovery of factors in blood serum that destroy bacteria; this work was vital to the diagnosis and treatment of many dangerous contagious diseases.

Bordet’s research on the destruction of bacteria and red corpuscles in blood serum, conducted at the Pasteur Institute, Paris (1894–1901), contributed significantly to the foundation of serology, the study of immune reactions in body fluids. In 1895 he found that two components of blood serum are responsible for the rupture of bacterial cell walls (bacteriolysis): one is a heat-stable antibody found only in animals already immune to the bacterium; the other is a heat-sensitive substance found in all animals that was named alexin (it is now called complement). Three years later Bordet discovered that red blood cells from one animal species that are injected into another species are destroyed through a process (hemolysis) analogous to bacteriolysis.

In Brussels, where Bordet founded and directed (1901–40) what is now the Pasteur Institute of Brussels, he continued his immunity research with Octave Gengou, his brother-in-law. Their work led to the development of the complement-fixation test, a diagnostic technique that was used to detect the presence of infectious agents in the blood, including those that cause typhoid, tuberculosis, and, most notably, syphilis (the Wassermann test). After discovering (with Gengou in 1906) the bacterium, now known as Bordetella pertussis, that is responsible for whooping cough, Bordet became professor of bacteriology at the Free University of Brussels (1907–35).

Hi,

#1464. What is 'Dengue fever'?

560) Heron

Heron, any of about 60 species of long-legged wading birds, classified in the family Ardeidae (order Ciconiiformes) and generally including several species usually called egrets. The Ardeidae also include the bitterns (subfamily Botaurinae). Herons are widely distributed over the world but are most common in the tropics. They usually feed while wading quietly in the shallow waters of pools, marshes, and swamps, catching frogs, fishes, and other aquatic animals. They nest in rough platforms of sticks constructed in bushes or trees near water; the nests usually are grouped in colonies called heronries.

Herons commonly stand with the neck bent in an S shape. They fly with the legs trailing loosely and the head held back against the body, instead of stretching the neck out in front as most birds do. They have broad wings, long straight sharp-pointed bills, and powder downs; the latter are areas of feathers that continually disintegrate to a fine powder which is used for preening (absorbing and removing fish oil, scum, and slime from the plumage).

Herons are subdivided into typical herons, night herons, and tiger herons. Typical herons feed during the day. In breeding season some develop showy plumes on the back and participate in elaborate mutual-courtship posturing. Best known of the typical herons are the very large, long-legged and long-necked, plain-hued, crested members of the genus Ardea—especially the 130-cm (50-inch) great blue heron (A. herodias) of North America, with a wingspan of 1.8 metres (6 feet) or more, and the similar but slightly smaller gray, or common, heron (A. cinerea), widespread in the Old World. Largest of all is the goliath heron (A. goliath) of Africa, a 150-cm (59-inch) bird with a reddish head and neck. The purple heron (A. purpurea) is a darker and smaller Old World form.

The typical herons also include the black heron, Hydranassa (or Melanophoyx) ardesiaca, of Africa, and several species of the genus Egretta (egrets), such as the tricoloured heron (E. tricolor), of the southeastern United States and Central and South America, and the little blue heron (E. caerulea). The green heron (Butorides virescens), a small green and brown bird widespread in North America, is notable for its habit of dropping bait on the surface of the water in order to attract fish.

Night herons have thicker bills and shorter legs and are more active in the twilight hours and at night. The black-crowned night heron (Nycticorax nycticorax) ranges over the Americas, Europe, Africa, and Asia; the Nankeen night heron (N. caledonicus) in Australia, New Caledonia, and the Philippines; and the yellow-crowned night heron (Nyctanassa violacea) from the eastern and central United States to southern Brazil. Another night heron is the boat-billed heron, or boatbill (Cochlearius cochlearius), of Central and South America, placed by some authorities in its own family (Cochleariidae).

The most primitive herons are the six species of tiger herons (formerly called tiger bitterns), shy, solitary birds with cryptic, often barred, plumage. The lined, or banded, tiger heron (Tigrisoma lineatum), 75 cm (30 inches) long, of central and northern South America, is a well-known example. Another is the Mexican, or bare-throated, tiger heron (T. mexicanum) of Mexico and Central America.

559) Sparrow

Sparrow, any of a number of small, chiefly seed-eating birds having conical bills. The name sparrow is most firmly attached to birds of the Old World family Passeridae (order Passeriformes), particularly to the house sparrow (Passer domesticus) that is so common in temperate North America and Europe, but also to many New World members of the Emberizidae.

Most members of the New World family Emberizidae are called sparrows. Examples breeding in North America are the chipping sparrow (Spizella passerina) and the tree sparrow (S. arborea), trim-looking little birds with reddish-brown caps; the savanna sparrow (Passerculus sandwichensis) and the vesper sparrow (Pooecetes gramineus), finely streaked birds of grassy fields; the song sparrow (Melospiza melodia) and the fox sparrow (Passerella iliaca), heavily streaked skulkers in woodlands; and the white-crowned sparrow (Zonotrichia leucophrys) and the white-throated sparrow (Z. albicollis), larger species with black-and-white crown stripes. The rufous-collared sparrow (Z. capensis) has an exceptionally wide breeding distribution: from Mexico and Caribbean islands to Tierra del Fuego. A great many emberizid sparrows are native to Central and South America.

558) Kingfisher

Kingfisher, any of about 90 species of birds in three families (Alcedinidae, Halcyonidae, and Cerylidae), noted for their spectacular dives into water. They are worldwide in distribution but are chiefly tropical. Kingfishers, ranging in length from 10 to 42 cm (4 to 16.5 inches), have a large head, a long and massive bill, and a compact body. Their feet are small, and, with a few exceptions, the tail is short or medium-length. Most species have vivid plumage in bold patterns, and many are crested.

These vocal, colourful birds are renowned for their dramatic hunting techniques. Typically, the bird sits still, watching for movement from a favourite perch. Having sighted its quarry, it plunges into the water and catches the fish usually no deeper than 25 cm (10 inches) below the surface in its dagger-shaped bill. With a swift downstroke of the wings, it bobs to the surface. It then takes the prey back to the perch and stuns the fish by beating it against the perch before swallowing it. Many species also eat crustaceans, amphibians, and reptiles.

The typical kingfishers (subfamily Alcedininae) are river dwellers, like the belted kingfisher (Megaceryle alcyon), the only widespread North American species. This handsome crested bird flies off over the water when disturbed, uttering a loud rattling call. It is about 30 cm (12 inches) long and is bluish gray above and across the breast and white below. Only the females sport the brownish red band or “belt” across the lower breast. The male in its courtship ritual offers fish to the female as she perches. After copulation the pair circle high overhead and chase each other while crying shrilly.

Stretching 43 cm (17 inches) long and weighing 465 grams (16 ounces), the largest of all kingfishers is the kookaburra, known throughout Australia for its laughing call. The kookaburra’s white head has a brown eye stripe, the back and wings are dark brown, and the underparts are white. Often found in urban and suburban areas, it can become quite tame and may be fed by hand. A member of the subfamily Daceloninae, the forest kingfishers, it captures insects, snails, frogs, reptiles, and small birds on the ground. It lives in family groups that roost together at night.

The IUCN Red List of Threatened Species classifies most kingfishers as species of least concern. Many species, such as the common kingfisher (Alcedo atthis), have large populations and vast geographic ranges. However, ecologists have observed that the populations of some species endemic to specialized habitats in Southeast Asia and the islands of the tropical Pacific Ocean are in decline. Aggressive logging activities resulting in the deforestation of large areas of Indonesia, Malaysia, and the Philippines have been associated with dramatic population decreases in several species, including the blue-banded kingfisher (A. euryzona), the Sulawesi kingfisher (Ceyx fallax), the brown-winged kingfisher (Pelargopsis amauropterus), and some of the paradise kingfishers (Tanysiptera) of New Guinea.

The Marquesan kingfisher (Todiramphus godeffroyi), one of the most endangered kingfishers, faces a different suite of threats. Once found on a handful of islands in the Marquesas chain, the species is now limited to only one, Tahuata. The bird’s decline has been attributed to habitat degradation caused by feral livestock coupled with predation by introduced species such as the great horned owl (Bubo virginianus), common mynah (Acridotheres tristis), and house rat (Rattus rattus).

557) Melanoma

Overview

Melanoma, the most serious type of skin cancer, develops in the cells (melanocytes) that produce melanin — the pigment that gives your skin its color. Melanoma can also form in your eyes and, rarely, inside your body, such as in your nose or throat.

The exact cause of all melanomas isn't clear, but exposure to ultraviolet (UV) radiation from sunlight or tanning lamps and beds increases your risk of developing melanoma. Limiting your exposure to UV radiation can help reduce your risk of melanoma.

The risk of melanoma seems to be increasing in people under 40, especially women. Knowing the warning signs of skin cancer can help ensure that cancerous changes are detected and treated before the cancer has spread. Melanoma can be treated successfully if it is detected early.

Symptoms

Melanomas can develop anywhere on your body. They most often develop in areas that have had exposure to the sun, such as your back, legs, arms and face.
Melanomas can also occur in areas that don't receive much sun exposure, such as the soles of your feet, palms of your hands and fingernail beds. These hidden melanomas are more common in people with darker skin.
The first melanoma signs and symptoms often are:
•    A change in an existing mole
•    The development of a new pigmented or unusual-looking growth on your skin

Melanoma doesn't always begin as a mole. It can also occur on otherwise normal-appearing skin.

Normal moles

Normal moles are generally a uniform color — such as tan, brown or black — with a distinct border separating the mole from your surrounding skin. They're oval or round and usually smaller than 1/4 inch (about 6 millimeters) in diameter — the size of a pencil eraser.

Most moles begin appearing in childhood and new moles may form until about age 40. By the time they are adults, most people have between 10 and 40 moles. Moles may change in appearance over time and some may even disappear with age.

Unusual moles that may indicate melanoma

To help you identify characteristics of unusual moles that may indicate melanomas or other skin cancers, think of the letters ABCDE:
•    A is for asymmetrical shape. Look for moles with irregular shapes, such as two very different-looking halves.
•    B is for irregular border. Look for moles with irregular, notched or scalloped borders — characteristics of melanomas.
•    C is for changes in color. Look for growths that have many colors or an uneven distribution of color.
•    D is for diameter. Look for new growth in a mole larger than 1/4 inch (about 6 millimeters).
•    E is for evolving. Look for changes over time, such as a mole that grows in size or that changes color or shape. Moles may also evolve to develop new signs and symptoms, such as new itchiness or bleeding.

Cancerous (malignant) moles vary greatly in appearance. Some may show all of the changes listed above, while others may have only one or two unusual characteristics.
Hidden melanomas

Melanomas can also develop in areas of your body that have little or no exposure to the sun, such as the spaces between your toes and on your palms, soles, scalp or genitals. These are sometimes referred to as hidden melanomas because they occur in places most people wouldn't think to check. When melanoma occurs in people with darker skin, it's more likely to occur in a hidden area.

Hidden melanomas include:
•    Melanoma under a nail. Acral-lentiginous melanoma is a rare form of melanoma that can occur under a fingernail or toenail. It can also be found on the palms of the hands or the soles of the feet. It's more common in people of Asian descent, black people and in others with dark skin pigment.
•    Melanoma in the mouth, digestive tract, urinary tract or math. Mucosal melanoma develops in the mucous membrane that lines the nose, mouth, esophagus, math, urinary tract and math. Mucosal melanomas are especially difficult to detect because they can easily be mistaken for other far more common conditions.
•    Melanoma in the eye. Eye melanoma, also called ocular melanoma, most often occurs in the uvea — the layer beneath the white of the eye (sclera). An eye melanoma may cause vision changes and may be diagnosed during an eye exam.

When to see a doctor

Make an appointment with your doctor if you notice any skin changes that seem unusual.

Causes

Melanoma occurs when something goes wrong in the melanin-producing cells (melanocytes) that give color to your skin.

Normally, skin cells develop in a controlled and orderly way — healthy new cells push older cells toward your skin's surface, where they die and eventually fall off. But when some cells develop DNA damage, new cells may begin to grow out of control and can eventually form a mass of cancerous cells.

Just what damages DNA in skin cells and how this leads to melanoma isn't clear. It's likely that a combination of factors, including environmental and genetic factors, causes melanoma. Still, doctors believe exposure to ultraviolet (UV) radiation from the sun and from tanning lamps and beds is the leading cause of melanoma.
UV light doesn't cause all melanomas, especially those that occur in places on your body that don't receive exposure to sunlight. This indicates that other factors may contribute to your risk of melanoma.

Risk factors

Factors that may increase your risk of melanoma include:
•    Fair skin. Having less pigment (melanin) in your skin means you have less protection from damaging UV radiation. If you have blond or red hair, light-colored eyes, and freckle or sunburn easily, you're more likely to develop melanoma than is someone with a darker complexion. But melanoma can develop in people with darker complexions, including Hispanic people and black people.
•    A history of sunburn. One or more severe, blistering sunburns can increase your risk of melanoma.
•    Excessive ultraviolet (UV) light exposure. Exposure to UV radiation, which comes from the sun and from tanning lights and beds, can increase the risk of skin cancer, including melanoma.
•    Living closer to the equator or at a higher elevation. People living closer to the earth's equator, where the sun's rays are more direct, experience higher amounts of UV radiation than do those living farther north or south. In addition, if you live at a high elevation, you're exposed to more UV radiation.
•    Having many moles or unusual moles. Having more than 50 ordinary moles on your body indicates an increased risk of melanoma. Also, having an unusual type of mole increases the risk of melanoma. Known medically as dysplastic nevi, these tend to be larger than normal moles and have irregular borders and a mixture of colors.
•    A family history of melanoma. If a close relative — such as a parent, child or sibling — has had melanoma, you have a greater chance of developing a melanoma, too.
•    Weakened immune system. People with weakened immune systems have an increased risk of melanoma and other skin cancers. Your immune system may be impaired if you take medicine to suppress the immune system, such as after an organ transplant, or if you have a disease that impairs the immune system, such as AIDS.

Prevention

You can reduce your risk of melanoma and other types of skin cancer if you:

•    Avoid the sun during the middle of the day. For many people in North America, the sun's rays are strongest between about 10 a.m. and 4 p.m. Schedule outdoor activities for other times of the day, even in winter or when the sky is cloudy.

You absorb UV radiation year-round, and clouds offer little protection from damaging rays. Avoiding the sun at its strongest helps you avoid the sunburns and suntans that cause skin damage and increase your risk of developing skin cancer. Sun exposure accumulated over time also may cause skin cancer.
•    Wear sunscreen year-round. Use a broad-spectrum sunscreen with an SPF of at least 30, even on cloudy days. Apply sunscreen generously, and reapply every two hours — or more often if you're swimming or perspiring.
•    Wear protective clothing. Cover your skin with dark, tightly woven clothing that covers your arms and legs, and a broad-brimmed hat, which provides more protection than does a baseball cap or visor.

Some companies also sell protective clothing. A dermatologist can recommend an appropriate brand. Don't forget sunglasses. Look for those that block both types of UV radiation — UVA and UVB rays.
•    Avoid tanning lamps and beds. Tanning lamps and beds emit UV rays and can increase your risk of skin cancer.
•    Become familiar with your skin so that you'll notice changes. Examine your skin often for new skin growths or changes in existing moles, freckles, bumps and birthmarks. With the help of mirrors, check your face, neck, ears and scalp.
Examine your chest and trunk and the tops and undersides of your arms and hands. Examine both the front and back of your legs and your feet, including the soles and the spaces between your toes.

Hi,

#7760. When

556) Meteorite crater

Meteorite crater, depression that results from the impact of a natural object from interplanetary space with Earth or with other comparatively large solid bodies such as the Moon, other planets and their satellites, or larger asteroids and comets. For this discussion, the term meteorite crater is considered to be synonymous with impact crater. As such, the colliding objects are not restricted by size to meteorites as they are found on Earth, where the largest known meteorite is a nickel-iron object less than 3 metres (10 feet) across. Rather, they include chunks of solid material of the same nature as comets or asteroids and in a wide range of sizes—from small meteoroids up to comets and asteroids themselves.

Meteorite crater formation is arguably the most important geologic process in the solar system, as meteorite craters cover most solid-surface bodies, Earth being a notable exception. Meteorite craters can be found not only on rocky surfaces like that of the Moon but also on the surfaces of comets and ice-covered moons of the outer planets. Formation of the solar system left countless pieces of debris in the form of asteroids and comets and their fragments. Gravitational interactions with other objects routinely send this debris on a collision course with planets and their moons. The resulting impact from a piece of debris produces a surface depression many times larger than the original object. Although all meteorite craters are grossly similar, their appearance varies substantially with both size and the body on which they occur. If no other geologic processes have occurred on a planet or moon, its entire surface is covered with craters as a result of the impacts sustained over the past 4.6 billion years since the major bodies of the solar system formed. On the other hand, the absence or sparseness of craters on a body’s surface, as is the case for Earth’s surface, is an indicator of some other geologic process (e.g., erosion or surface melting) occurring during the body’s history that is eliminating the craters.

The Impact-Cratering Process

When an asteroidal or cometary object strikes a planetary surface, it is traveling typically at several tens of kilometres per second—many times the speed of sound. A collision at such extreme speeds is called a hypervelocity impact. Although the resulting depression may bear some resemblance to the hole that results from throwing a pebble into a sandbox, the physical process that occurs is actually much closer to that of an atomic bomb explosion. A large meteorite impact releases an enormous amount of kinetic energy in a small area over a short time. Planetary scientists’ knowledge of the crater-formation process is derived from field studies of nuclear and chemical explosions and of rocket missile impacts, from laboratory simulations of impacts using gun-impelled high-velocity projectiles, from computer models of the sequence of crater formation, and from observations of meteorite craters themselves.

Immediately after a meteorite strikes the surface of the planet, shock waves are imparted both to the surface material and to the meteorite itself. As the shock waves expand into the planet and the meteorite, they dissipate energy and form zones of vaporized, melted, and crushed material outward from a point below the planet’s surface that is roughly as deep as the meteorite’s diameter. The meteorite is usually vaporized completely by the released energy. Within the planet, the expanding shock wave is closely followed by a second wave, called a rarefaction, or release, wave, generated by the reflection of the original wave from the free surface of the planet. The dissipation of these two waves sets up large pressure gradients within the planet. The pressure gradients generate a subsurface flow that projects material upward and outward from the point of impact. The material being excavated resembles an outward-slanted curtain moving away from the point of impact.

The depression that is produced has the form of an upward-facing parabolic bowl about four times as wide as it is deep. The diameter of the crater relative to that of the meteorite depends on several factors, but it is thought for most craters to be about 10 to 1. Excavated material surrounds the crater, causing its rim to be elevated above the surrounding terrain. The height of the rim accounts for about 5 percent of the total crater depth. The excavated material outside the crater is called the ejecta blanket. The elevation of the ejecta blanket is highest at the rim and falls off rapidly with distance.

When the crater is relatively small, its formation ends when excavation stops. The resulting landform is called a simple crater. The smallest craters require no more than a few seconds to form completely, whereas craters that are tens of kilometres wide probably form in a few minutes.

As meteorite craters become larger, however, the formation process does not cease with excavation. For such craters the parabolic hole is apparently too large to support itself, and it collapses in a process that generates a variety of features. This collapse process is called the modification stage, and the final depression is known as a complex crater. The modification stage of complex crater formation is poorly understood because the process is mostly beyond current technological capability to model or simulate and because explosion craters on Earth are too small to produce true complex crater landforms. Although conceptually the modification stage is considered to occur after excavation, it may be that collapse begins before excavation is complete. The current state of knowledge of complex crater formation relies primarily on inferences drawn from field observations of Earth’s impact structures and spacecraft imagery of impact craters on other solid bodies in the solar system.

Features associated with complex craters are generally attributed to material moving back toward the point of impact. Smaller complex craters have a flat floor caused by a rebound of material below the crater after excavation. This same rebound causes large complex craters to have a central peak; even-larger craters have a raised circular ring within the crater. Analogues to the central peak and ring are the back splash and outward ripple that are seen briefly when a pebble is dropped into water. Also associated with the modification stage is downward faulting, which forms terraces of large blocks of material along the inner rim of the initial cavity. In the case of very large craters, discrete, inward-facing, widely spaced faults called megaterraces form well outside the initial excavation cavity. Craters with megaterraces are called impact basins.

Variations In Craters Across The Solar System

Although impact craters on all the solid bodies of the solar system are grossly similar, their appearances from body to body can vary dramatically. The most-notable differences are a result of variations among the bodies in surface gravity and crustal properties. A higher surface gravitational acceleration creates a greater pressure difference between the floor of the crater and the surface surrounding the crater. That pressure difference is thought to play a large role in driving the collapse process that forms complex craters, the effect being that the smallest complex craters seen on higher-gravity bodies are smaller than those on lower-gravity bodies. For example, the diameters of the smallest craters with central peaks on the Moon, Mercury, and Venus decrease in inverse proportion to the bodies’ surface gravities; Mercury’s surface gravity is more than twice that of the Moon, whereas Venus’s gravity is more than five times that of the Moon.

The inherent strength of the impacted surface has an effect similar to that of surface gravity in that it is easier for craters to collapse on bodies with weaker near-surface materials. For example, the presence of water in the near-surface materials of Mars, a condition thought to be likely, would help explain why the smallest complex craters there are smaller than on Mercury, which has a similar surface gravity. Layering in a body’s near-surface material in which weak material overlies stronger strata is thought to modify the excavation process and contribute to the presence of craters with flat floors that contain a central pit. Such craters are particularly prominent on Ganymede, the largest moon of Jupiter.

Observations of the solid planets show clearly that the presence of an atmosphere changes the appearance of impact craters, but details of how the cratering process is altered are poorly understood. Comparison of craters on planets with and without an atmosphere shows no obvious evidence that an atmosphere does more than minimally affect the excavation of the cavity and any subsequent collapse. It does show, however, that an atmosphere strongly affects emplacement of the ejecta blanket. On an airless body the particles of excavated material follow ballistic trajectories.

In the presence of an atmosphere most of this material mixes with the atmosphere and creates a surface-hugging fluid flow away from the crater that is analogous to volcanic pyroclastic flow on Earth. On an airless body an ejecta blanket shows a steady decrease in thickness away from the crater, but on a planet with an atmosphere the fluid flow of excavated material lays down a blanket that is relatively constant in thickness away from the crater and that ends abruptly at the outer edge of the flow. The well-preserved ejecta blankets around Venusian craters show this flow emplacement, and field observations of Earth’s impact structures indicate that much of their ejecta were emplaced as flows. On Mars most of the ejecta blankets also appear to have been emplaced as flows, but many of these are probably mudflows caused by abundant water near the Martian surface.

Meteorite Craters As Measures Of Geologic Activity

A common misconception is that Earth has very few impact craters on its surface because its atmosphere is an effective shield against meteoroids. Earth’s atmosphere certainly slows and prevents typical asteroidal fragments up to a few tens of metres across from reaching the surface and forming a true hypervelocity impact crater, but kilometre-scale objects of the kind that created the smallest telescopically visible craters on the Moon are not significantly slowed by Earth’s atmosphere (see meteor and meteoroid: Meteorites—meteoroids that survive atmospheric entry). The Moon and Earth certainly experienced similar numbers of these larger impact events, but on Earth subsequent geologic processes (e.g., volcanism and plate tectonic processes) completely eliminated or severely degraded the craters. The dominant role of erosion as a geologic process that destroys craters is unique to Earth among the solid bodies that have been well-studied. Erosional processes may be important in eliminating craters on Titan, Saturn’s largest moon, if methane proves to play the role there that water does in Earth’s hydrologic cycle. Elsewhere only volcanic and tectonic processes are capable of eliminating large meteorite craters.

An absence or sparseness of craters in a given region of a large solid body indicates that relatively recent geologic activity has resurfaced it or otherwise greatly altered its surface appearance. For example, on the Moon the dark mare regions are much less heavily cratered than the light highland areas because the mare were flooded by basaltic volcanic flows about one billion years after formation of the highland areas. From simple counts of the craters larger than a given size per unit area for different regions of a body, it is possible to determine relative surface ages of different regions in order to gain insight into a body’s geologic history. For the Moon absolute ages can be assigned to regions with different numbers of craters per unit area because surface samples from several regions were collected during Apollo lunar landing missions and dated in laboratories on Earth. For other large bodies, assigning absolute ages to given regions based on the number of craters is based on estimates of asteroidal and cometary impact rates, the size range of those objects, and the size of the crater that forms from a given impacting object. Very little data exist as a basis for these estimates, particularly for impact rates. Absolute ages determined for planetary surfaces other than the Moon consequently have large uncertainties relative to the age of the solar system.