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       Frog Chandelier

"Frog Chandelier" and Frog light fixtures 
 Frog light fixture chandelier: Go to www.sisalnet.com for more items.

 

We custom design and make and hand finish Frog and other whimsical chandeliers in New York, USA.

One of our popular frog chandeliers is for your pool table in your billiard room.

They are hand painted and had finished to order for fine homes and designers through out the US and Canada, the Carribean.

Please enjoy the frog information below reprinted from Wikipedia. We also have dogs, fox, cats owls and other whisical lighting themes.

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The artist sculptor is
Bill Huebbe , of Huebbe Designs, who is a very unique and original artist. Please visit
 website if you would like more information about the man who sculpted these pieces.
Thanks for looking !!!

Frogs in popular culture

Moche Frog 200 A.D. Larco Museum Collection Lima, Peru.

Moche Frog 200 A.D. Larco Museum Collection Lima, Peru.

For more details on this topic, see Frogs in popular culture.

Frogs feature prominently in folklore, fairy tales and popular culture. They tend to be portrayed as benign, ugly, clumsy, but with hidden talents. Examples include Michigan J. Frog, The Frog Prince, and Kermit the Frog. Michigan J. Frog, featured in a Warner Brothers cartoon, only performs his singing and dancing routine for his owner. Once another person looks at him, he will return to a frog-like pose. "The Frog Prince" is a fairy tale of a frog who turns into a handsome prince once kissed. Kermit the Frog, on the other hand, is a conscientious and disciplined character of Sesame Street and The Muppet Show; while openly friendly and greatly talented, he is often portrayed as cringing at the fanciful behaviour of more flamboyant characters.

The Moche people of ancient Peru worshipped animals and often depicted frogs in their art. [32]

 

For more details on this topic, see List of Anuran families.

The order Anura contains 5,250 species in 33 families, of which the Leptodactylidae (1100 spp.), Hylidae (800 spp.) and Ranidae (750 spp.) are the richest in species. About 88% of amphibian species are frogs.

The use of the common names "frog" and "toad" has no taxonomic justification. From a taxonomic perspective, all members of the order Anura are frogs, but only members of the family Bufonidae are considered "true toads". The use of the term "frog" in common names usually refers to species that are aquatic or semi-aquatic with smooth and/or moist skins, and the term "toad" generally refers to species that tend to be terrestrial with dry, warty skin. An exception is the fire-bellied toad (Bombina bombina): while its skin is slightly warty, it prefers a watery habitat.

Frogs and toads are broadly classified into three suborders: Archaeobatrachia, which includes four families of primitive frogs; Mesobatrachia, which includes five families of more evolutionary intermediate frogs; and Neobatrachia, by far the largest group, which contains the remaining 24 families of "modern" frogs, including most common species throughout the world. Neobatrachia is further divided into the Hyloidea and Ranoidea.[3] This classification is based on such morphological features as the number of vertebrae, the structure of the pectoral girdle, and the morphology of tadpoles. While this classification is largely accepted, relationships among families of frogs are still debated. Future studies of molecular genetics should soon provide further insights to the evolutionary relationships among frog families.[4]

Some species of anurans hybridise readily. For instance, the edible frog (Rana esculenta) is a hybrid of the pool frog (R. lessonae) and the marsh frog (R. ridibunda). Bombina bombina and Bombina variegata similarly form hybrids, although these are less fertile, giving rise to a hybrid zone.

The structure of the feet and legs varies greatly among frog species, depending in part on whether they live primarily on the ground, in water, in trees, or in burrows. Frogs must be able to move quickly through their environment to catch prey and escape predators, and numerous adaptations help them do so.

Many frogs, especially those that live in water, have webbed toes. The degree to which the toes are webbed is directly proportional to the amount of time the species lives in the water. For example, the completely aquatic African dwarf frog (Hymenochirus sp.) has fully webbed toes, whereas the toes of White's tree frog (Litoria caerulea), an arboreal species, are only a half or a quarter webbed.

Arboreal frogs have "toe pads" to help grip vertical surfaces. These pads, located on the ends of the toes, do not work by suction. Rather, the surface of the pad consists of interlocking cells, with a small gap between adjacent cells. When the frog applies pressure to the toe pads, the interlocking cells grip irregularities on the substrate. The small gaps between the cells drain away all but a thin layer of moisture on the pad, and maintain a grip through capillarity. This allows the frog to grip smooth surfaces, and does not function when the pads are excessively wet.[5]

In many arboreal frogs, a small "intercalary structure" in each toe increases the surface area touching the substrate. Furthermore, since hopping through trees can be dangerous, many arboreal frogs have hip joints that allow both hopping and walking. Some frogs that live high in trees even possess an elaborate degree of webbing between their toes, as do aquatic frogs. In these arboreal frogs, the webs allow the frogs to "parachute" or control their glide from one position in the canopy to another.[6]

Ground-dwelling frogs generally lack the adaptations of aquatic and arboreal frogs. Most have smaller toe pads, if any, and little webbing. Some burrowing frogs have a toe extension—a metatarsal tubercle—that helps them to burrow. The hind legs of ground dwellers are more muscular than those of aqueous and tree-dwelling frogs.

Many frogs are able to absorb water directly through the skin, especially around the pelvic area. However, the permeability of a frog's skin can also result in water loss. Some tree frogs reduce water loss with a waterproof layer of skin. Others have adapted behaviours to conserve water, including engaging in nocturnal activity and resting in a water-conserving position. This position involves the frog lying with its toes and fingers tucked under its body and chin, respectively, with no gap between the body and substrate. Some frog species will also rest in large groups, touching the skin of the neighbouring frog. This reduces the amount of skin exposed to the air or a dry surface, and thus reduces water loss. These adaptations only reduce water loss enough for a predominantly arboreal existence, and are not suitable for arid conditions.

Camouflage is a common defensive mechanism in frogs. Most camouflaged frogs are nocturnal, which adds to their ability to hide. Nocturnal frogs usually find the ideal camouflaged position during the day to sleep. Some frogs have the ability to change colour, but this is usually restricted to shades of one or two colours. For example, White's tree frog varies in shades of green and brown. Features such as warts and skin folds are usually found on ground-dwelling frogs, where a smooth skin would not disguise them effectively. Arboreal frogs usually have smooth skin, enabling them to disguise themselves as leaves.

Certain frogs change colour between night and day, as light and moisture stimulate the pigment cells and cause them to expand or contract.

Many frogs contain mild toxins that make them distasteful to potential predators. For example, all toads have large poison glands—the parotid glands—located behind the eyes on the top of the head. Some frogs, such as some poison dart frogs, are especially toxic. The chemical makeup of toxins in frogs varies from irritants to hallucinogens, convulsants, nerve poisons, and vasoconstrictors. Many predators of frogs have adapted to tolerate high levels of these poisons. Others, including humans, may be severely affected.

Some frogs obtain poisons from the ants and other arthropods they eat;[7] others, such as the Australian Corroboree Frogs (Pseudophryne corroboree and Pseudophryne pengilleyi), can manufacture an alkaloid not derived from their diet.[8] Some native people of South America extract poison from the poison dart frogs and apply it to their darts for hunting,[9] although few species are toxic enough to be used for this purpose. It was previously a misconception the poison was placed on arrows rather than darts. The common name of these frogs was thus changed from "poison arrow frog" to "poison dart frog" in the early 1980s. Poisonous frogs tend to advertise their toxicity with bright colours, an adaptive strategy known as aposematism. There are at least two non-poisonous species of frogs in tropical America (Eleutherodactylus gaigei and Lithodytes lineatus) that mimic the colouration of dart poison frogs' coloration for self-protection (Batesian mimicry).[10][11]

Because frog toxins are extraordinarily diverse, they have raised the interest of biochemists as a "natural pharmacy". The alkaloid epibatidine, a painkiller 200 times more potent than morphine, is found in some species of poison dart frogs. Other chemicals isolated from the skin of frogs may offer resistance to HIV infection.[12] Arrow and dart poisons are under active investigation for their potential as therapeutic drugs.[13]

The skin secretions of some toads, such as the Colorado River toad and cane toad, contain bufotoxins, some of which, such as bufotenin, are psychoactive, and have therefore been used as recreational drugs. Typically, the skin secretions are dried and smoked. Skin licking is especially dangerous, and appears to constitute an urban myth. See psychoactive toad.

The skin of a frog is permeable to oxygen and carbon dioxide, as well as to water. There are a number of blood vessels near the surface of the skin. When a frog is underwater, oxygen is transmitted through the skin directly into the bloodstream. On land, adult frogs use their lungs to breathe. Their lungs are similar to those of humans, but the chest muscles are not involved in respiration, and there are no ribs or diaphragm to support breathing. Frogs breathe by taking air in through the nostrils (causing the throat to puff out), and compressing the floor of the mouth, which forces the air into the lungs.

Frogs are known for their three-chambered heart, which they share with all tetrapods except birds and mammals. In the three-chambered heart, oxygenated blood from the lungs and de-oxygenated blood from the respiring tissues enter by separate atria, and are directed via a spiral valve to the appropriate vessel—aorta for oxygenated blood and pulmonary vein for deoxygenated blood. This special structure is essential to keeping the mixing of the two types of blood to a minimum, which enables frogs to have higher metabolic rates, and to be more active than otherwise.

Once at the breeding ground, male frogs call to attract a mate, collectively becoming a chorus of frogs. The call is unique to the species, and will attract females of that species. Some species have satellite males who do not call, but intercept females that are approaching a calling male.

The male and female frogs then undergo amplexus. This involves the male mounting the female and gripping her tightly. Fertilization is external: the egg and sperm meet outside of the body. The female releases her eggs, which the male frog covers with a sperm solution. The eggs then swell and develop a protective coating. The eggs are typically brown or black, with a clear, gelatin-like covering.

Most temperate species of frogs reproduce between late autumn and early spring. In the UK, most common frog populations produce frogspawn in February, although there is wide variation in timing. Water temperatures at this time of year are relatively low, typically between four and 10 degrees Celsius. Reproducing in these conditions helps the developing tadpoles because dissolved oxygen concentrations in the water are highest at cold temperatures. More importantly, reproducing early in the season ensures that appropriate food is available to the developing frogs at the right time.

Frog Call

Some frog calls are so loud, they can be heard up to a mile away.[18]The call of a frog is unique to its species. Frogs call by passing air through the larynx in the throat. In most calling frogs, the sound is amplified by one or more vocal sacs, membranes of skin under the throat or on the corner of the mouth that distend during the amplification of the call. The field of neuroethology studies the neurocircuitry that underlies frog audition.

Some frogs lack vocal sacs, such as those from the genera Heleioporus and Neobatrachus, but these species can still produce a loud call. Their buccal cavity is enlarged and dome-shaped, acting as a resonance chamber that amplifies their call. Species of frog without vocal sacs and that do not have a loud call tend to inhabit areas close to flowing water. The noise of flowing water overpowers any call, so they must communicate by other means.

The main reason for calling is to allow males to attract a mate. Males call either individually or in a group called a chorus. Females of many frog species, for example Polypedates leucomystax, produce calls reciprocal to the males', which act as the catalyst for the enhancement of reproductive activity in a breeding colony.[19] A male frog emits a release call when mounted by another male. Tropical species also have a rain call that they make on the basis of humidity cues prior to a rain shower. Many species also have a territorial call that is used to chase away other males. All of these calls are emitted with the mouth of the frog closed.

A distress call, emitted by some frogs when they are in danger, is produced with the mouth open, resulting in a higher-pitched call. The effectiveness of the call is unknown; however, it is suspected the call intrigues the predator until another animal is attracted, distracting them enough for its escape.

Many species of frog have deep calls, or croaks. The onomatopoeic spelling is "ribbit". The croak of the American bullfrog (Rana catesbiana) is sometimes spelt "jug o' rum". Other examples are Ancient Greek brekekekex koax koax for probably Rana ridibunda, and the description in Rigveda 7:103.6 gómāyur éko ajámāyur ékaħ = "one [has] a voice like a cow's, one [has] a voice like a goat's".

 

 

The frog is an amphibian in the order Anura (meaning "tail-less", from Greek an-, without + oura, tail), formerly referred to as Salientia (Latin saltare, to jump). The name frog derives from Old English frogga,[1] (compare Old Norse frauki, German Frosch, older Dutch spelling kikvorsch), cognate with Sanskrit plava (frog), probably deriving from Proto-Indo-European praw = "to jump".[2]

Adult frogs are characterised by long hind legs, a short body, webbed digits, protruding eyes and the absence of a tail. Most frogs have a semi-aquatic lifestyle, but move easily on land by jumping or climbing. They typically lay their eggs in puddles, ponds or lakes, and their larvae, called tadpoles, have gills and develop in water. Adult frogs follow a carnivorous diet, mostly of arthropods, annelids and gastropods. Frogs are most noticeable by their call, which can be widely heard during the night or day, mainly in their mating season.

The distribution of frogs ranges from tropic to subarctic regions, but most species are found in tropical rainforests. Consisting of more than 5,000 species described, they are among the most diverse groups of vertebrates. However, populations of certain frog species are significantly declining.

A distinction is often made between frogs and toads on the basis of their appearance, caused by the convergent adaptation among so-called toads to dry environments; however, this distinction has no taxonomic basis. The only family exclusively given the common name "toad" is Bufonidae, but many species from other families are also called "toads," and the species within the toad genus Atelopus are referred to as "harlequin frogs."

General references

Cited references

  1. ^ http://en.wiktionary.org/wiki/frog
  2. ^ Indo-European etymology database
  3. ^ Ford, L.S.; D.C. Cannatella (1993). "The major clades of frogs". Herpetological Monographs 7: 94–117. 
  4. ^ Faivovich, J.; C.F.B. Haddad, P.C.A. Garcia, D.R. Frost, J.A. Campbell, and W.C. Wheeler. "Systematic review of the frog family Hylidae, with special reference to Hylinae: Phylogenetic analysis and taxonomic revision". Bulletin of the American Museum of Natural History 294: 1–240. 
  5. ^ Emerson, S.B.; Diehl, D. (1980). "Toe pad morphology and mechanisms of sticking in frogs". Biol. J. Linn. Soc. 13 (3): 199–216. 
  6. ^ Harvey, M. B; A. J. Pemberton, and E. N. Smith (2002). "New and poorly known parachuting frogs (Rhacophoridae : Rhacophorus) from Sumatra and Java". Herpetological Monographs 16: 46–92. 
  7. ^ Saporito, R.A.; H.M. Garraffo, M.A. Donnelly, A.L. Edwards, J.T. Longino, and J.W. Daly (2004). "Formicine ants: An arthropod source for the pumiliotoxin alkaloids of dendrobatid poison frogs". Proceedings of the National Academy of Science 101: 8045–8050. 
  8. ^ Smith, B. P.; Tyler M. J., Kaneko T., Garraffo H. M., Spande T. F., Daly J. W. (2002). "Evidence for biosynthesis of pseudophrynamine alkaloids by an Australian myobatrachid frog (pseudophryne) and for sequestration of dietary pumiliotoxins". J Nat Prod 65 (4): 439–47. 
  9. ^ Myers, C.W.; J.W. Daly (1983). "Dart-poison frogs". Scientific American 248: 120–133. 
  10. ^ Savage, J. M. (2002). The Amphibians and Reptiles of Costa Rica. University of Chicago Press, Chicago. 
  11. ^ Duellman, W. E. (1978). "The Biology of an Equatorial Herpetofauna in Amazonian Ecuador". University of Kansas Museum of Natural History Miscellaneous Publication 65: 1–352. 
  12. ^ VanCompernolle, S. E.; R. J. Taylor, K. Oswald-Richter, J. Jiang, B. E. Youree, J. H. Bowie, M. J. Tyler, M. Conlon, D. Wade, C. Aiken, and T. S. Dermody (2005). "Antimicrobial peptides from amphibian skin potently inhibit Human Immunodeficiency Virus infection and transfer of virus from dendritic cells to T cells". Journal of Virology 79: 11598–11606. 
  13. ^ Phillipe, G.; Angenot L. (2005). "Recent developments in the field of arrow and dart poisons". J Ethnopharmacol 100(1–2): 85–91. 
  14. ^ Warkentin, K.M. (1995). "Adaptive plasticity in hatching age: a response to predation risk trade-offs". Proceedings of the National Academy of Sciences 92: 3507–3510. 
  15. ^ Silva, H. R.; Britto-Pereira M. C., & Caramaschi U. (1989). "Frugivory and Seed Dispersal by Hyla truncata, a Neotropical Treefrog". Copeia 1989(3): 781–783. 
  16. ^ Frogs Found in the U.K.. Retrieved 18 July 2007.
  17. ^ Crump, M.L. (1996). "Parental care among the Amphibia". Advances in the Study of Behavior 25: 109–144. 
  18. ^ See, for instance, Ohio's Toads and Frogs by the Ohio Department of Natural Resources. Retrieved 18 July 2007.
  19. ^ Roy, Debjani (1997). "Communication signals and sexual selection in amphibians". Current Science 72: 923–927. 
  20. ^ "Freaky Frogs," at National Geographic Explorer. Retrieved 18 July 2007.
  21. ^ Evolution Encyclopedia, Volume 3: Geographical Distribution. Retrieved 18 July 2007.
  22. ^ Stuart, S.N.; J.S. Chanson, N.A. Cox, B.E. Young, A.S.L. Rodrigues, D.L. Fischman, and R.W. Waller (2004). "Status and trends of amphibian declines and extinctions worldwide". Science 306: 1783–1786. 
  23. ^ Phillips, Kathryn (1994). Tracking the Vanishing Frogs. New York: Penguin Books. ISBN 0-14-024646-0. 
  24. ^ New Scientist (July 7, 2006). "Frog population decrease mostly due to traffic". New Scientist. 
  25. ^ http://www.nationalparks.nsw.gov.au/npws.nsf/Content/dec_media_070109_01
  26. ^ http://news.bbc.co.uk/1/hi/sci/tech/4298050.stm
  27. ^ http://www.environment.gov.au/biodiversity/threatened/publications/recovery/p-corroboree/part4.html
  28. ^ http://www.physorg.com/news99134333.html
  29. ^ Robert W. Briggs Biographical Memoir. Retrieved on 2006-04-22.
  30. ^ Developing the potential of Xenopus tropicalis as a genetic model. Retrieved on 2006-03-09.
  31. ^ Joint Genome Institute - Xenopus tropicalis Home. Retrieved on 2006-03-03.
  32. ^ Berrin, Katherine & Larco Museum. The Spirit of Ancient Peru:Treasures from the Museo Arqueológico Rafael Larco Herrera. New York: Thames and Hudson, 1997.

 

 

 

 

 

 

 

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