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Original Brass Retro Keychain Handmade Snake Key Ring Creative Pendant Gift ASnake (englisch für Schlange) ist ein Computerspielklassiker, bei dem eine sich gerade oder rechtwinklig bewegende Schlange durch ein Spielfeld gesteuert. Buy Original Snake Mountain Gym Herren T-Shirt and other T-Shirts at Amazon.com. Our wide selection is elegible for free shipping and free returns. Original Brass Retro Keychain Handmade Snake Key Ring Creative Pendant Gift ABastel- & Künstlerbedarf, Schmuckherstellung, Perlen, Schmucksteine.
Snake Original Select which mode you would like to play in. VideoWorld's Longest Snakes! EP. 424 : SnakeBytesTV : AnimalBytesTV By clicking sign up, I agree that I would like information, tips, and offers about Microsoft Store and other Microsoft Acapulco Guerrero and services. Thank you! Solitaire Mahjong Pac-man Tetris. Approximate size Report this product Report this game Biggest Slot Machine Microsoft Thanks for reporting your concern.
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Get more out of your Kongregate experience. Snake Game v 1. Game Play You the player control a virtual "snake" which roams around its little world eating food pellets and trying to avoid its demise by running into itself or the edges of the world.
Instructions Simple! Please select a name for your snake! Many nocturnal snakes have slit pupils while diurnal snakes have round pupils.
Most species possess three visual pigments and are probably able to see two primary colors in daylight. It's concluded that the last common ancestors of all snakes had UV-sensitive vision, but that most snakes that depends on their eyesight to hunt in daylight have evolved lenses that act as sunglasses which filters out UV-light, and probably also sharpens their vision by improving the contrasts.
The skin of a snake is covered in scales. Contrary to the popular notion of snakes being slimy because of possible confusion of snakes with worms , snakeskin has a smooth, dry texture.
Most snakes use specialized belly scales to travel, gripping surfaces. The body scales may be smooth, keeled , or granular.
The eyelids of a snake are transparent "spectacle" scales, which remain permanently closed, also known as brille. The shedding of scales is called ecdysis or in normal usage, molting or sloughing.
In the case of snakes, the complete outer layer of skin is shed in one layer. Snakes have a wide diversity of skin coloration patterns.
These patterns are often related to behavior, such as a tendency to have to flee from predators. Snakes that are plain or have longitudinal stripes often have to escape from predators, with the pattern or lack thereof not providing reference points to predators, thus allowing the snake to escape without being notice.
Plain snakes usually adopt active hunting strategies, as their pattern allows them to send little information to prey about motion.
Blotched snakes, on the other hand, usually use ambush-based strategies, likely because it helps them blend into an environment with irregularly shaped objects, like sticks or rocks.
Spotted patterning can similarly help snakes to blend into their environment. The shape and number of scales on the head, back, and belly are often characteristic and used for taxonomic purposes.
Scales are named mainly according to their positions on the body. In "advanced" Caenophidian snakes, the broad belly scales and rows of dorsal scales correspond to the vertebrae , allowing scientists to count the vertebrae without dissection.
Molting , or ecdysis , serves a number of functions. Firstly, the old and worn skin is replaced; secondly, it helps get rid of parasites such as mites and ticks.
Renewal of the skin by molting is supposed to allow growth in some animals such as insects; however, this has been disputed in the case of snakes.
Molting occurs periodically throughout the snake's life. Before a molt, the snake stops eating and often hides or moves to a safe place.
Just before shedding, the skin becomes dull and dry looking and the eyes become cloudy or blue-colored. The inner surface of the old skin liquefies.
This causes the old skin to separate from the new skin beneath it. After a few days, the eyes clear and the snake "crawls" out of its old skin.
The old skin breaks near the mouth and the snake wriggles out, aided by rubbing against rough surfaces. In many cases, the cast skin peels backward over the body from head to tail in one piece, like pulling a sock off inside-out.
A new, larger, brighter layer of skin has formed underneath. An older snake may shed its skin only once or twice a year.
But a younger snake, still growing, may shed up to four times a year. Scale counts can sometimes be used to tell the sex of a snake when the species is not distinctly sexually dimorphic.
A probe is inserted into the cloaca until it can go no further. The probe is marked at the point where it stops, removed, and compared to the subcaudal depth by laying it alongside the scales.
The skeleton of most snakes consists solely of the skull, hyoid, vertebral column, and ribs, though henophidian snakes retain vestiges of the pelvis and rear limbs.
The skull of the snake consists of a solid and complete neurocranium , to which many of the other bones are only loosely attached, particularly the highly mobile jaw bones, which facilitate manipulation and ingestion of large prey items.
The left and right sides of the lower jaw are joined only by a flexible ligament at the anterior tips, allowing them to separate widely, while the posterior end of the lower jaw bones articulate with a quadrate bone, allowing further mobility.
The bones of the mandible and quadrate bones can also pick up ground borne vibrations. The jaw-quadrate-stapes pathway is capable of detecting vibrations on the angstrom scale, despite the absence of an outer ear and the ossicle mechanism of impedance matching used in other vertebrates to receive vibrations from the air.
The hyoid is a small bone located posterior and ventral to the skull, in the 'neck' region, which serves as an attachment for muscles of the snake's tongue, as it does in all other tetrapods.
The vertebral column consists of anywhere between and or more vertebrae. The vertebrae have projections that allow for strong muscle attachment enabling locomotion without limbs.
Autotomy of the tail, a feature found in some lizards is absent in most snakes. In some snakes, most notably boas and pythons , there are vestiges of the hindlimbs in the form of a pair of pelvic spurs.
These small, claw-like protrusions on each side of the cloaca are the external portion of the vestigial hindlimb skeleton, which includes the remains of an ilium and femur.
Snakes are polyphyodonts with teeth that are continuously replaced. Snake's and other reptiles have a three-chambered heart that controls the circulatory system via the left and right atrium, and one ventricle.
Located beneath the cavum venosum is the cavum pulmonale, which pumps blood to the pulmonary trunk. The snake's heart is encased in a sac, called the pericardium , located at the bifurcation of the bronchi.
The heart is able to move around, however, owing to the lack of a diaphragm. This adjustment protects the heart from potential damage when large ingested prey is passed through the esophagus.
The spleen is attached to the gall bladder and pancreas and filters the blood. The thymus is located in fatty tissue above the heart and is responsible for the generation of immune cells in the blood.
The cardiovascular system of snakes is also unique for the presence of a renal portal system in which the blood from the snake's tail passes through the kidneys before returning to the heart.
The vestigial left lung is often small or sometimes even absent, as snakes' tubular bodies require all of their organs to be long and thin. This lung contains a vascularized anterior portion and a posterior portion that does not function in gas exchange.
Snakes have no lymph nodes. Cobras, vipers, and closely related species use venom to immobilize, injure or kill their prey. The venom is modified saliva , delivered through fangs.
Snake venoms are often prey specific—their role in self-defense is secondary. Venom, like all salivary secretions, is a predigestant that initiates the breakdown of food into soluble compounds, facilitating proper digestion.
Even nonvenomous snake bites like any animal bite will cause tissue damage. Certain birds, mammals, and other snakes such as kingsnakes that prey on venomous snakes have developed resistance and even immunity to certain venoms.
The colloquial term "poisonous snake" is generally an incorrect label for snakes. A poison is inhaled or ingested, whereas venom produced by snakes is injected into its victim via fangs.
Snake venoms are complex mixtures of proteins , and are stored in venom glands at the back of the head.
Venomous snakes that use hemotoxins usually have fangs in the front of their mouths, making it easier for them to inject the venom into their victims.
They must actually bite the victim. It has recently been suggested that all snakes may be venomous to a certain degree, with harmless snakes having weak venom and no fangs.
This theory postulates that snakes may have evolved from a common lizard ancestor that was venomous—and that venomous lizards like the gila monster , beaded lizard , monitor lizards , and the now-extinct mosasaurs may also have derived from it.
They share this venom clade with various other saurian species. Venomous snakes are classified in two taxonomic families :. There is a third family containing the opistoglyphous rear-fanged snakes as well as the majority of other snake species :.
Although a wide range of reproductive modes are used by snakes, all snakes employ internal fertilization. This is accomplished by means of paired, forked hemipenes , which are stored, inverted, in the male's tail.
Most species of snakes lay eggs which they abandon shortly after laying. However, a few species such as the king cobra actually construct nests and stay in the vicinity of the hatchlings after incubation.
She will even "shiver" to generate heat to incubate the eggs. Some species of snake are ovoviviparous and retain the eggs within their bodies until they are almost ready to hatch.
Sexual selection in snakes is demonstrated by the 3, species that each use different tactics in acquiring mates. It is common for neck biting to occur while the snakes are entwined.
Parthenogenesis is a natural form of reproduction in which growth and development of embryos occur without fertilization.
Agkistrodon contortrix copperhead and Agkistrodon piscivorus cotton mouth can reproduce by facultative parthenogenesis. That is, they are capable of switching from a sexual mode of reproduction to an asexual mode.
This process leads to genome wide homozygosity , expression of deleterious recessive alleles and often to developmental abnormalities.
Both captive-born and wild-born A. Reproduction in squamate reptiles is almost exclusively sexual. Males ordinarily have a ZZ pair of sex determining chromosomes, and females a ZW pair.
However, the Colombian Rainbow boa Epicrates maurus can also reproduce by facultative parthenogenesis resulting in production of WW female progeny.
In regions where winters are colder than snakes can tolerate while remaining active, local species will brumate. Unlike hibernation, in which mammals are actually asleep, brumating reptiles are awake but inactive.
Individual snakes may brumate in burrows, under rock piles, or inside fallen trees, or snakes may aggregate in large numbers at hibernacula. All snakes are strictly carnivorous , eating small animals including lizards, frogs, other snakes, small mammals, birds, eggs , fish, snails, worms or insects.
The body size of a snake has a major influence on its eating habits. Smaller snakes eat smaller prey. Juvenile pythons might start out feeding on lizards or mice and graduate to small deer or antelope as an adult, for example.
The snake's jaw is a complex structure. Contrary to the popular belief that snakes can dislocate their jaws, snakes have a very flexible lower jaw , the two halves of which are not rigidly attached, and numerous other joints in their skull see snake skull , allowing them to open their mouths wide enough to swallow their prey whole, even if it is larger in diameter than the snake itself.
While the majority of snakes eat a variety of prey animals, there is some specialization by some species. King cobras and the Australian bandy-bandy consume other snakes.
Snakes of the family Pareidae have more teeth on the right side of their mouths than on the left, as the shells of their prey usually spiral clockwise.
Some snakes have a venomous bite, which they use to kill their prey before eating it. After eating, snakes become dormant while the process of digestion takes place.
In species that feed only sporadically, the entire intestine enters a reduced state between meals to conserve energy.
Being ectothermic "cold-blooded" , the surrounding temperature plays a large role in snake digestion. So much metabolic energy is involved in a snake's digestion that in the South American rattlesnake Crotalus durissus , surface body temperature increases by as much as 1.
When undisturbed, the digestive process is highly efficient, with the snake's digestive enzymes dissolving and absorbing everything but the prey's hair or feathers and claws , which are excreted along with waste.
The lack of limbs does not impede the movement of snakes. They have developed several different modes of locomotion to deal with particular environments.
Unlike the gaits of limbed animals, which form a continuum, each mode of snake locomotion is discrete and distinct from the others; transitions between modes are abrupt.
Lateral undulation is the sole mode of aquatic locomotion, and the most common mode of terrestrial locomotion.
Terrestrial lateral undulation is the most common mode of terrestrial locomotion for most snake species. When swimming, the waves become larger as they move down the snake's body, and the wave travels backwards faster than the snake moves forwards.
In spite of overall similarities, studies show that the pattern of muscle activation is different in aquatic versus terrestrial lateral undulation, which justifies calling them separate modes.
Most often employed by colubroid snakes colubrids , elapids , and vipers when the snake must move in an environment that lacks irregularities to push against rendering lateral undulation impossible , such as a slick mud flat, or a sand dune, sidewinding is a modified form of lateral undulation in which all of the body segments oriented in one direction remain in contact with the ground, while the other segments are lifted up, resulting in a peculiar "rolling" motion.
When push-points are absent, but there is not enough space to use sidewinding because of lateral constraints, such as in tunnels, snakes rely on concertina locomotion.
This mode of locomotion is slow and very demanding, up to seven times the cost of laterally undulating over the same distance.
The movement of snakes in arboreal habitats has only recently been studied. Gliding snakes Chrysopelea of Southeast Asia launch themselves from branch tips, spreading their ribs and laterally undulating as they glide between trees.
The slowest mode of snake locomotion is rectilinear locomotion, which is also the only one where the snake does not need to bend its body laterally, though it may do so when turning.
Waves of movement and stasis pass posteriorly, resulting in a series of ripples in the skin. Snakes do not ordinarily prey on humans.
Unless startled or injured, most snakes prefer to avoid contact and will not attack humans. With the exception of large constrictors, nonvenomous snakes are not a threat to humans.
The bite of a nonvenomous snake is usually harmless; their teeth are not adapted for tearing or inflicting a deep puncture wound, but rather grabbing and holding.
Although the possibility of infection and tissue damage is present in the bite of a nonvenomous snake, venomous snakes present far greater hazard to humans.
Documented deaths resulting from snake bites are uncommon. Nonfatal bites from venomous snakes may result in the need for amputation of a limb or part thereof.
Of the roughly species of venomous snakes worldwide, only are able to kill a human with one bite. Australia averages only one fatal snake bite per year.
In India , , snakebites are recorded in a single year, with as many as 50, recorded initial deaths. The treatment for a snakebite is as variable as the bite itself.
The most common and effective method is through antivenom or antivenin , a serum made from the venom of the snake. Some antivenom is species-specific monovalent while some is made for use with multiple species in mind polyvalent.
In the United States for example, all species of venomous snakes are pit vipers , with the exception of the coral snake. To produce antivenom, a mixture of the venoms of the different species of rattlesnakes , copperheads, and cottonmouths is injected into the body of a horse in ever-increasing dosages until the horse is immunized.
Blood is then extracted from the immunized horse. The serum is separated and further purified and freeze-dried. It is reconstituted with sterile water and becomes antivenom.
For this reason, people who are allergic to horses are more likely to suffer an allergic reaction to antivenom.
In some parts of the world, especially in India, snake charming is a roadside show performed by a charmer.
In such a show, the snake charmer carries a basket that contains a snake that he seemingly charms by playing tunes from his flutelike musical instrument, to which the snake responds.
The Wildlife Protection Act of in India technically proscribes snake charming on grounds of reducing animal cruelty. Other snake charmers also have a snake and mongoose show, where both the animals have a mock fight; however, this is not very common, as the snakes, as well as the mongooses, may be seriously injured or killed.
Snake charming as a profession is dying out in India because of competition from modern forms of entertainment and environment laws proscribing the practice.
Many Indians have never seen snake charming and it is becoming a folktale of the past. The Irulas tribe of Andhra Pradesh and Tamil Nadu in India have been hunter-gatherers in the hot, dry plains forests, and have practiced the art of snake catching for generations.
They have a vast knowledge of snakes in the field. They generally catch the snakes with the help of a simple stick. Earlier, the Irulas caught thousands of snakes for the snake-skin industry.
After the complete ban of the snake-skin industry in India and protection of all snakes under the Indian Wildlife Protection Act , they formed the Irula Snake Catcher's Cooperative and switched to catching snakes for removal of venom, releasing them in the wild after four extractions.
The venom so collected is used for producing life-saving antivenom, biomedical research and for other medicinal products.
Despite the existence of snake charmers, there have also been professional snake catchers or wranglers. Modern-day snake trapping involves a herpetologist using a long stick with a V- shaped end.