Tag: veterinarian

  • What is UVB light and why does my pet reptile need it?

    What is UVB Light?

    UV light or Ultraviolet light is high energy light than violet but lower energy than X-rays on the electromagnetic spectrum. Ten percent of the light energy produced by the sun is UV light. UV light is invisible to most humans. Small birds, on the other hand, have a forth color receptor in their retinas that gives them “true” UV vision.

    UV light is further broken up into UV-A, UV-B, and UV-C.

    UV-A is low wave UV. It easily penetrates the ozone layer. This is the light we find in black lights and is known as “soft” UV. Reptiles utilize this light to help regulate behaviors (a.k.a. their circadian rhythm) such as feeding, daytime movement, mating, and similar activities.

    UV-B is medium-wave UV or “intermediate” UV and most of this light frequency is absorbed by our ozone layer. Biologically, it is utilized by non-fish vertebrates like reptiles, amphibians, birds, mammals, and even humans for vitamin D synthesis.

    UV-C is short-wave UV or “hard” UV. It is ionizing radiation and used in germicidal UV sterilizers. Luckily, the UV-C produced by our sun is completely absorbed by the ozone layer and our atmosphere.

    Why do reptiles need UVB light?

    Reptiles, like many vertebrates, utilize UV-B light in the synthesis of vitamin D. When UV-B light interacts with the skin it interacts with 7-dihydrocholesterol activating it into cholecalciferol, or vitamin D3. From there it undergoes further transformation within the liver and kidneys to become 1,25-dihydroxyvitamin D3 used for maintenance of calcium balanced within the body. So without UV-B light that first step in producing this vital chemical regulator within the body never happens. 1,25-dihydroxyvitamin D3 is important as it increases absorption of calcium from the diet, decreases loss of calcium in the urine from the kidneys, prevents overproduction of parathyroid hormone, and modulates the activity if the cells of the skeletal system.

    Do all reptiles need UVB light?

    Diurnal reptiles, such as iguanas, bearded dragons, turtles, tortoises, water dragons, day geckos, etc. all require UV-B for production of active vitamin D3. Crepuscular reptiles, those active at dawn and dusk, have been found to also be able to utilize UV-B to activate vitamin D3. However, they can also utilize dietary vitamin D3 and have been raised in captivity for generations without UVB lighting. Studies in nocturnal reptiles (i.e. pythons, boas) have shown they cannot utilize UV-B for vitamin D3 activation. However, there may be additional benefits that UV-B lighting provides that have yet to be discovered.

    What sources of UVB lighting are available to pet owners?

    UV-B light for your reptile can be naturally provided from the sun or artificially by using specially designed light bulbs that produce UV-B. Natural sun can only be used by reptiles housed outside. This is because UV-B cannot penetrate glass so placing your pet near a window will not work. UV-B is only able to penetrate the glass of UV-B bulbs because the glass has been specially treated to allow UV-B to penetrate the glass. This coating wears off over 6-12 months of use causing these bulbs to stop producing UV-B light long before they burn out. This is why manufacturers recommend replacing these bulbs regularly. Artificial UV-B is available in 4 different types of reptile bulbs: fluorescent, mercury vapor, metal halide, and LED.

    The first is fluorescent which produces light using a low-pressure mercury-vapor gas-exchange lamp that fluoresces to produce visible light. These bulbs produce minimal heat and come in 3 types. The first are the T8 bulbs, this is a second generation fluorescent straight tube bulb (first generation being T12 bulbs and are no longer produced as UV-B bulbs). The second are the compact fluorescent bulbs where the fluorescent tube is formed into a coil or loop and then set into a normal light bulb socket. Both T8 and compact fluorescent bulbs produce similar amounts UV-B. The third and newest type are the T5 or third generation straight tube fluorescent bulbs. These emit stronger light and have more UV-B production than both T8 and compact fluorescent bulbs.

    Most UV-B fluorescent bulbs are sold in various strengths, which vary in their labeling depending on the manufacturer. For example, Zoo Med sells them as 2.0, 5.0, and 10.0 bulbs corresponding to 2%, 5% and 10% UV-B production respectively. While Arcadia sells 2%, 7%, 10%, 12% and 14% bulbs. Exo-Terra takes a completely different aproach utilizing a more complex system to help keepers choose the correct bulb based on species and basking distance with bulbs labeled as 100, 150, or 200.

    The second type of UV-B bulb available to reptile owners are Mercury Vapor bulbs. A mercury-vapor lamp is a gas-discharge lamp that uses an electric arc through vaporized mercury to produce light. They procude both head and UV-B light. These bulbs are ballasted, when they turn off they need to cool down before they will turn back on, so they cannot be regulated with a thermostat like standard heat lamps. They have a higher UV penetration and UV index than fluorescent bulbs making them ideal for larger enclosures (40 gallons or larger).

    Metal Halide bulbs are the third type available on the market. A metal-halide lamp is an electrical lamp that produces light by an electric arc through a gaseous mixture of vaporized mercury and metal halides. This bubl also produces both heat and light, but less heat at a lower wattage than mercury vapor bulbs. These high intensity UV-B bulbs also work well for larger habitats. It should be noted that special fixures are required for these and standard heat domes will not work.

    The final type available are LED or light-emitting diode lamps. These are a semiconductor light source that emits light when current flows through it. Relatively new to the market, more research is needed to really gauge how they compare to other bulbs on the market. While expensive, these bulbs are energy efficient and produce little to no heat.

    What is UV penetration and why is understanding this important to choosing the right lighting for your pet?

    UV penetration is the concept that the farther you get from the UV-B source, the lower the UV-B index is. Different bulbs are going to give you different depths of penetration into the cage. It is important to take this into account when choosing the lighting for your pet. In general, mercury vapor and metal halide bulbs have the highest (or deepest) penetration while fluorescents the penetration is lower. Below are some examples of UV penetration diagrams for a variety of different UV-B bulbs.

    What is UV index?

    The last area that needs to be touched on is UV index. UV index is an international standard measurement of the strength of sunburn-producing ultraviolet radiation at a particular place and time. It’s an open-ended linear scale, directly proportional to the intensity of UV radiation that causes sunburn on human skin. It was invented to help people effectively protect themselves from UV radiation, which has health benefits in moderation but in excess causes negative effects. We borrow this in reptiles just as a measure of the amount of UVB reaching our pets.

    Summary

    UV-B lighting is essential for the health of many pet reptiles. Most reptiles require UVB lighting to properly absorb and utilize dietary calcium. Without UVB many reptiles will develop Nutritional Secondary Hyperparathyroidism a.k.a. “Metabolic Bone Disease.” It is important to understand that artificial UVB lights need to be changed every 6-12 months as they will stop giving off UVB light. Both species and cage setup should be considered when choosing the right UVB source.

    For more information on UV-B light – click here.

    For more inforamtion on Nutritional Secondary Hyperparathyroidism – click here.

  • Introduction to Reptiles: Taxonomy and Anatomy

    Introduction

    Reptiles are often referred to being “cold-blooded”, which can be misleading.  More appropriately they should be considered poikilothermic or ectothermic, which means that unlike mammals and birds reptiles are unable to regulate their body temperatures internally and change their body temperature in adaptation to their environmental temperature.  Because reptiles do not need to expend as much energy heating their bodies, they have a much lower metabolic rate than that of mammals.  Each reptile species has what is referred to as its preferred optimal temperature zone which is a narrow temperature range at which they are active and undergo typical functions such as feeding, digestion and reproduction.  Outside of this range these functions may be hindered or cease altogether.  Some species will hibernate during colder months and during this time their metabolic rate will decrease. 

    Reptiles belong to the Class Reptilia, which can be broken further down into 4 Orders: Squamata, Chelonia, Crocodilia, and Tuatara.

    Tuatara

    The Tuatara is an ancient type of reptile only found in New Zealand and is a protected species only rarely seen in captivity in zoos or very special private collections.

    Crocodilia

    Crocodilians include crocodiles, alligators, and caiman.  Members of Crocodilia are illegal to own as pets in Arizona.

    Squamata

    The order squamata can be broken down into 2 suborders: Serpentes (snakes) and Sauria (lizards). 

    There are over 2,700 species of snakes worldwide and snakes can be found on every continent besides Antarctica
    .  While the obvious answer to how snakes differ from lizards might appear to be that they lack limbs, it gets confusing when you consider legless lizards.  Thus, to be more precise, snakes differ from lizards by lacking external ears and lacking remnants of forelimbs.  That said, some snakes do have vestigial hind limbs, which can be seen externally as a pair of spurs on either side of their cloaca.  Snakes also lack eyelids.  Instead their eyes are protected by a clear scale known as a spectacle, which is shed at the same time as the snake sheds its skin. 

    All snakes are carnivorous, most feed on rodents, lizards, birds, and even eggs.  Since snakes are unable to chew or take bites of their meals, they must swallow their food whole.  To do this they have a very flexible skull and jawbones.  Snakes can easily consume an animal as big as they are wide. The majority of snakes are non-venomous and kill their prey by constriction.  Those that are venomous produce venom in glands located behind the eyes and inject it via fangs by biting.  Venomous snakes should be discouraged as pets due to the risk of injury to humans. 

    Most snakes lay eggs (oviparous), with the exceptions of nearly all boas and some vipers such as rattlesnakes who give live birth (viviparous).  Snake eggs are oval shaped and have flexible, leathery shells. 

    Snakes are largely non-social and live solitary lives, rarely seeking out company outside of the breeding season. 

    Lizards far outnumber snakes with nearly 5,000 different species worldwide.  And like snakes, lizards can be found on every continent except Antarctica.  Lizards have well developed color vision and communicate via body language and pheromones.  Most lizards are solitary animals and keep a loose territory.  Most lay eggs (oviparous) but some do give live birth (viviparous).  There are two species of venomous lizard, the Gila monster and the beaded lizard. 

    Some lizards have unusual adaptations.  Many species of gecko have adhesive lamina on their toes to enable them to climb on sheer surfaces.  Many geckos also lack eyelids and, similar to snakes, have a spectacle

    Many species of lizard have the ability to drop their tails, an adaptation referred to as autonomy.  Most lizards will regrow their tails with the exception of Rhacodactylus geckos.  Lizards that do not practice autonomy will not regrow a lost tail, however.

    Both snakes and lizards shed their skin as they grow.  Snakes shed their skin in one large piece, while lizards often do so in multiple smaller pieces.  Proper shedding is very important to their health.

    Chelonians

    This suborder includes turtles, terrapins and tortoises.  Turtles most accurately should be used to describe sea turtles, which are not kept as pets due to their size and care requirements.  Terrapins are the freshwater and land dwelling species that are what we commonly refer to as turtles.  Terrapins are omnivorous to carnivorous.  Tortoises are strictly land dwelling and predominantly herbivorous.  Often, the confusion arises when trying to distinguish a box turtle from a tortoise.  While they are primarily land animals, box turtles are terrapins. They are omnivores and have limbs more similar to that of a terrapin.  

    All Chelonians have a protective shell, however some may be more protective than others.  Soft shelled  turtles, for instance, have a shell covered with leathery skin that does very little for protection.  Other than soft shells, a chelonian’s shell is comprised of living bone covered with plates of keratin, similar to scales, called scutes.  It is normal for terrapins to shed their scutes as they grow, but not for tortoises. 

    One of the most well known characteristics of chelonians is that they are very long lived; even the shortest-lived aquatic terrapins routinely live 20-30 years.  Tortoises can live 60-100 years, depending on species.  Chelonians are very social animals and establish loose territories.  Males can be very territorial and will fight over resources and females.  All chelonians lay eggs (oviparous); they produce eggs with a hard shell similar to a bird’s egg and are usually spherical.

    Basic Anatomy

    Most reptiles have a 3-chambered heart as well as a renal portal system where blood passes through the kidneys both as it leaves the heart and as it returns to the heart after traveling through the back end of the body.

    Reptile lungs are simple and sac-like and often have a vascular epithelium towards the front and non-respiratory epithelium towards the back. They do not have aleoli like mammals, but instead their pulmonary functional unit is called faveoli, small air spaces in the lungs that resemble honeycomb cells.

    Reptile gonads are internal and the right and left gonads are located at different levels of the snake between the pancreas and the kidneys. Male snakes and lizards have paired copulatory organs called hemipenes while male chelonians and crocodilians have a single phallus. These are not associated with the urination and only function for mating, thus if diseased these may be amputated.

    Snakes

    Snakes possess very elastic to allow for ingestion of prey. Periodically shed whole, usually between 2 to 4 times per year depending on growth rate. They also are very delicately built compared to other reptiles. They have two rows of teeth on the top (maxillary and pterygoids) and one on the bottom (mandibular). Their teeth are recurved and are periodically shed throughout life. Their tongue is long, deeply forked and lies in sheath under the glottis and is used in olfaction (smell) together with the Jacobson’s organ found on the palate. They have no external ears and no tympanic membrane or middle ear, yet they are able to hear low frequency sound using the inner ear. Their vision geared for movement and they have no eyelids, instead their eyes are covered with a spectacle. Heat-pits are present on the heads of boas, pythons, and pit vipers allowing them to find prey in complete darkness.

    The right lung is larger than the left in snakes, with the left lung completely non-functional (vestigial) in colubrids like corn snakes and kingsnakes. Like all reptiles, snakes lack of diaphragm.

    Venom glands in snakes are modified salivary glands and located behind the eyes on the head.

    Like all reptiles, the snake ureter empties into part of the cloaca called the urodeum. Snakes lack a urinary bladder. Male snakes have a sexual portion of the kidney that enlarges during the breeding season and produces seminal fluid. 

    Lizards

    Unlike snakes, most lizards shed their skin in pieces. Their skin is usually fairly thick and scaled, with the exception of geckos who possess very thin skin. Many practice tail autonomy, meaning they can drop their tails as a defence mechanism. While most species will regrow their tails, not all can do this, i.e. crested geckos. Bearded dragons do not drop their tails and their tails cannot regenerate if lost.

    Their ear drum, or tympanic membrane, is visible and there is no external or ear lobe.

    Most lizards have eyelids, with the exception of some species of geckos, and have well developed color vision. Many also possess a degenerate 3rd eye or parietal eye located on the top of the head. It contains a retina and lens and is used to stimulate hormone production as well as moderate behavior associated with thermoregulation and basking times.

    The heart is 3-chambered and located between the shoulders in most lizards, with the exception of monitor lizards where it is located low in the chest.

    Lizard tongue morphology varies based on function.

    Chelonians

    Probably the most promanent part of chelonian anatomy is their shell witha dorsal carapace and ventral plastron. Their pectoral and pelvic girdles are uniquely located within their rib cage. Comprised of living bone covered with protectie keratin, their shells are well innervated and can feel touch and pain.

    Their eyes are similar to birds and they possess scleral ossicles, small circular bones embedded in the whites of the eyes.

    The chelonian ear is hidden behind a large scale or several smaller scales that overlies their tympanic membrane (ear drum).

    Chelonians have large lungs that extend the length of the shell. Like all reptiles, they lack a diaphragm. Their shell prevents movement of the rib cage so respiration requires movement of the head and forelimbs.

    While chelonians have a relatively simple stomach, the large intestines of many tortoises is extensive and used for microbial digestion of fiber.