Sensory organs Like all pit vipers, rattlesnakes have two organs that can sense
radiation; their eyes and a set of heat-sensing "pits" on their faces that enable them to locate prey and move towards it, based on the prey's
thermal radiation signature. These pits have a relatively short effective range of about but give the rattlesnake a distinct advantage in hunting for warm-blooded creatures at night. located in blue circle on a rattlesnake specimen: Location of the pit is the same in all
Viperidae.
Heat-sensing pits Aside from their eyes, rattlesnakes are able to detect thermal radiation emitted by
warm-blooded organisms in their environment. Functioning optically like a pinhole camera eye, thermal radiation in the form of infrared light passes through the opening of the pit and strikes the pit membrane located in the back wall, warming this part of the organ. Due to the high density of heat-sensitive receptors innervating this membrane, the rattlesnake can detect temperature changes of 0.003 °C or less in its immediate surroundings. Due to the small sizes of the pit openings, typically these thermal images are low in resolution and contrast. Nevertheless, rattlesnakes superimpose visual images created from information from the eyes with these thermal images from the pit organs to more accurately visualize their surroundings in low levels of light.
Smell Rattlesnakes have an exceptionally keen sense of
smell. They can sense olfactory stimuli both through their
nostrils and by flicking their
tongues, which carry scent-bearing particles to the
Jacobson's organs in the roof of their mouths. Rattlesnakes are born with fully functioning fangs and venom, and are capable of killing prey at birth. Adult rattlesnakes shed their fangs every 6–10 weeks. At least three pairs of replacement fangs lie behind the functional pair.
Venom Rattlesnake venom is hemotoxic, destroying tissue, causing
necrosis and
coagulopathy (disrupted blood clotting). In the U.S., the
tiger rattlesnake (
C. tigris) and some varieties of the
Mojave rattlesnake (
C. scutulatus) also have a
presynaptic neurotoxic venom component known as Mojave type A toxin, which can cause severe
paralysis. Although it has a comparatively low venom yield, the venom toxicity of
C. tigris is considered to be among the highest of all rattlesnake venoms, and among the highest of all snakes in the Western Hemisphere based on studies conducted on laboratory mice.
C. scutulatus is also widely regarded as producing one of the most toxic snake venoms in the Americas, based on studies in
laboratory mice. Rattlesnake venom is a mixture of five to fifteen
enzymes, various
metal ions,
biogenic amines,
lipids,
free amino acids,
proteins, and
polypeptides. More specifically, there are three main families of toxins in rattlesnakes:
phospholipases A2 (PLA2s), snake venom metalloproteinases (SVMPs), and snake venom serine proteinases (SVSPs). It contains components meant to immobilize and disable the prey, as well as digestive enzymes, which break down tissue to prepare for later
ingestion. However, recently,
balancing selection has been indicated to better explain the maintenance of adaptive genetic diversity in venom-related genes, potentially allowing for the rattlesnakes to better keep up in the
evolutionary arms race with their prey. Older snakes possess more potent venom, and larger snakes are frequently capable of storing larger volumes of it.
Rattle The rattle serves as a warning for predators of the rattlesnake. The rattle is composed of a series of hollow, interlocked segments made of
keratin, which are created by modifying the scales that cover the tip of the tail. The contraction of special "shaker" muscles in the tail causes these segments to vibrate against one another, thus making the rattling noise (which is amplified because the segments are hollow) in a behavior known as
tail vibration. In 2016, Allf et al. published a paper proposing
behavioral plasticity as the mechanism by which the rattling system evolved in rattlesnakes. In the case of rattlesnakes, Allf et al. proposed that tail vibration in response to predator threat could be the precursor for the rattling system in rattlesnakes, an example of behavioral plasticity. At birth, a "prebutton" is present at the tip of the snake's tail; it is replaced by the "button" several days later when the first skin is shed. However, no sound can be made by the rattle until a second segment is added when the skin is shed again. A new rattle segment is added each time the snake sheds its skin, and the snake may shed its skin several times a year, depending on food supply and growth rate. Rattlesnakes travel with their rattles held up to protect them from damage, but in spite of this precaution, their day-to-day activities in the wild still cause them to regularly break off end segments. Because of this, the number of rattles on its tail is not related to the age of a rattlesnake. The right atrium receives deoxygenated
blood from
veins coming from the systemic circuit. The left atrium receives oxygenated
blood from the lungs in the pulmonary circuit and pumps it to the ventricle and through the systemic circuit via
capillaries and
arteries. Rattlesnake skin has a set of overlapping scales that cover the entire body, providing protection from a variety of threats, including dehydration and physical trauma. The typical rattlesnake, genus
Crotalus, has the top of its head covered with small scales, except, with a few species, a few crowded plates directly over the snout. The skin of snakes is highly sensitive to contact, tension, and pressure; they are capable of feeling pain. An important function of the skin is the sensation of changes in air temperature, which can guide the snakes towards warm basking/shelter locations. Rattlesnakes do not generally have bright or showy colors (reds, yellows, blues, etc.), instead relying on subtle earth tones that resemble the surrounding environment. Creases in the epidermal tissue connect the scales of rattlesnakes. When ingesting large prey, these creases can unfold, allowing the skin to expand to envelop a much greater volume. The skin appears to tightly stretch to accommodate the meal, but in reality, the skin is simply smoothing out from its creased state and is not under very high tension. == Reproduction ==