- Common names: Russell's viper, chain viper, Indian Russell's viper, (more).
is a monotypic genus
created for a venomous viper species
, D. russelii
, which is found in Asia
throughout the Indian subcontinent
, much of Southeast Asia
, southern China
. Within much of its range, this species is easily the most dangerous viperid
snake and a major cause of snakebite injury and mortality. It is a member of the big four
venomous snakes in India
, which are together responsible for nearly all Indian snakebite fatalities. The species was named in honor of Dr. Patrick Russell
(1726 - 1805), who had earlier described this animal, and the genus after the Hindi
name for it, which means "that lies hid"
, or "the lurker."
are currently recognized, including the nominate subspecies described here.
This snake grows to a maximum length of 166 cm (5.5 ft). The average length is about 120 cm (4 ft) on the mainland, although island populations do not attain this size. It is more slenderly built than most other vipers. Ditmars
(1937) reported the following dimensions for a "fair sized adult specimen":
||4 ft., 1 inch
|Length of tail
|Width of head
|Length of head
The head is flattened, triangular and distinct from the neck. The snout is blunt, rounded and raised. The nostrils are large, in the middle of a large, single nasal scale
. The lower edge of the nasal touches the nasorostral
. The supranasal has a strong crescent shape and separates the nasal from the nasorostral anteriorly. The rostral
is as broad as it is high.
The crown of the head is covered with irregular, strongly fragmented scales. The supraocular scales are narrow, single, and separated by 6-9 scales across the head. The eyes are large, flecked with yellow or gold, and each is surrounded by 10-15 circumorbital scales. There are 10-12 supralabials, the 4th and 5th of which are significantly larger. The eye is separated from the supralabials by 3-4 rows of suboculars. There are two pairs of chin shields, the front pair of which are notably enlarged. The two maxillary bones support at least two and at the most five or six pairs of fangs at a time: the first are active and the rest replacements. The fangs attain a length of 16 mm in the average specimen.
The body is stout, the cross-section of which is rounded to cylindrical. The dorsal scales are strongly keeled; only the lower row is smooth. Mid-body, the dorsal scales number 27-33. The ventral scales number 153-180. The anal plate is not divided. The tail is short -- about 14% of the total body length -- with the paired subcaudals numbering 41-68.
The color pattern consists of a deep yellow, tan or brown ground color, with three series of dark brown spots that run the length of its body. Each of these spots has a black ring around it, the outer border of which is intensified with a rim of white or yellow. The dorsal spots, which usually number 23-30, may grow together, while the side spots may break apart. The head has a pair of distinct dark patches, one on each temple, together with a pinkish, salmon or brownish V or X pattern that forms an apex towards the snout. Behind the eye, there is a dark streak, outlined in white, pink or buff. The venter is white, whitish, yellowish or pinkish, often with an irregular scattering of dark spots.
- English - Russell's viper, chain viper, Indian Russell's viper, common Russell's viper, seven pacer, chain snake, scissors snake. Previously, another common name was used to described a subspecies that is now part of the synonymy of this form: Sri Lankan Russell's viper for D. r. pulchella.
- Hindi - daboia.
- Kashmiri - gunas.
- Sindhi - koraile.
- Bengali - bora, chandra bora, uloo bora.
- Gujarati - chitalo, khadchitalo.
- Marathi - ghonas.
- Telugu - ketuka rekula poda.
- Kannada - mandaladha haavu or mandalata havu, kolakumandala.
- Tamil - retha aunali, kannadi virian or kannadi viriyan.
- Malayalam - mandali, ruthamandali.
- Sinhala - tic polonga.
- Burmese - mwe lewe.
- Tulu - kandhodi
- Oriya - Chandra Boda
Found in Pakistan
, Sri Lanka
, east Java
Islands). The type locality
is listed as "India". More specifically, this would be the Coromandel Coast
, by inference of Russell (1796).
Brown (1973) mentions that it can also found in Vietnam, Laos and on the Indonesian island of Sumatra. Ditmars (1937) reportedly received a specimen from Sumatra as well. However, the distribution of this species in the Indonesian archipelago is still being elucidated.
Within its range it can be very common in some areas, but scarce in others. In India, is abundant in Punjab, very common along the West Coast and its hills, in southern India and up to Bengal. It is uncommon to rare in the Ganga valley, northern Bengal and Assam. It is prevalent in Myanmar.
It is not restricted to any particular habitat, but does tend to avoid dense forests. The snake is mostly found in open, grassy or bushy areas, but may also be found in second growth forests (scrub jungles), on forested plantations and farmland. They are most common in plains, coastal lowlands and hills of suitable habitat. Generally not found at altitude, but has been reported as far up as 2300-3000 m. Humid environments, such as marshes, swamps and rain forests, are avoided.
This species is often found in highly urbanized areas and settlements in the countryside, the attraction being the rodents commensal with man.
As a result, those working outside in these areas are most at risk of being bitten. It should be noted, however, that D. russelii does not associate as closely with human habitation as Naja and Bungarus (cobras and kraits).
and active primarily as a nocturnal
forager. However, during cool weather it will alter its behavior and become more active during the day.
Adults are reported to be persistently slow and sluggish unless pushed beyond a certain limit, after which they becomes fierce and aggressive. Juveniles, on the other hand, are generally more active and will bite with minimal provocation.
When threatened they form a series of S-loops, raise the first third of the body and produce a hiss that is supposedly louder than that of any other snake. When striking from this position, they can exert so much force that even a large individual can lift most of its body off the ground in the process. These are difficult snakes to handle: they are strong and agile and react violently to being picked up. The bite may be a snap, or, they may hang on for many seconds.
Although this genus does not have the heat-sensitive pit organs common to the Crotalinae, it is one of a number of viperines that are apparently able to react to thermal cues, further supporting the notion that they too possess a heat-sensitive organ. The identity of this sensor is not certain, but the nerve endings in the supranasal sac of these snakes resemble those found in other heat-sensitive organs.
It feeds primarily on rodents, especially murid
species. However, they will eat just about anything, including rats, mice shrews, squirrels, domestic cats, land crabs, scorpions and other arthropods
. Juveniles are crepuscular
, feeding on lizards and foraging actively. As they grow and become adults, they begin to specialize in rodents. Indeed, the presence of rodents is the main reason they are attracted to human habitation.
Juveniles are known to be cannibalistic.
This species is ovoviviparous
. Mating generally occurs early in the year, although gravid females may be found at any time. The gestation period is more than six months. Young are produced from May to November, but mostly in June and July. It is a prolific breeder. Litters of 20-40 are common, although there may be fewer offspring and as little as one. The reported maximum is 65 in a single litter. At birth, juveniles are 215-260 mm in length. The minimum length for a gravid female is about 100 cm. It seems that sexual maturity is achieved in 2-3 years. In one case, it took a specimen nearly 4.5 hours to produce 11 young.
These snakes do extremely well in captivity, requiring only a water dish and a hide box. Juveniles feed readily on pinky mice, while the adults will take rats, mice and birds. However, many adults do not feed, with one having refused all food for five months. Breeding is not a problem either. On the other hand, they do make quite dangerous captives. When handled, specimens have been known to use their long, curved fangs to bite right through their lower jaw and into the thumb of the person holding them.
The amount of venom produced by individual specimens is considerable. Reported venom yields for adult specimens range from 130-250 mg to 150-250 mg to 21-268 mg. For 13 juveniles with an average length of 79 cm, the average venom yield was 8-79 mg (mean 45 mg).
The LD50 in mice, which is used as a general indicator of snake venom toxicity, is as follows: 0.08-0.31 μg/g intravenous, 0.40 μg/kg intraperitoneal, 4.75 mg/kg subcutaneous. For most humans a lethal dose is 40-70 mg. In general, the toxicity depends on a combination of five different venom fractions, each of which is less toxic when tested separately. Venom toxicity also varies within populations and over time.
Envenomation symptoms begin with pain at the site of the bite, immediately followed by swelling of the affected extremity. Bleeding is a common symptom, especially from the gums, and sputum may show signs of blood within 20 minutes post-bite. There is a drop in blood pressure and the heart rate falls. Blistering occurs at the site of the bite, developing along the affected limb in severe cases. Necrosis is usually superficial and limited to the muscles near the bite, but may be severe in extreme cases. Vomiting and facial swelling occurs in about one-third of all cases.
Severe pain may last for 2-4 weeks. Locally, it may persist depending on the level of tissue damage. Often, local swelling peaks within 48-72 hours, involving both the affected limb and the trunk. If swelling up to the trunk occurs within 1-2 hours, massive envenomation is likely. Discoloration may occur throughout the swollen area as red blood cells and plasma leak into muscle tissue. Death from septicaemia, respiratory or cardiac failure may occur 1 to 14 days post-bite or even later.
Because this venom is so effective at inducing thrombosis, it has been incorporated into an in vitro diagnostic test for blood clotting that is widely used in hospital laboratories. This test is often referred to as Dilute Russell's viper venom time (dRVVT). The coagulant in the venom directly activates factor X, which turns prothrombin into thrombin in the presence of factor V and phospholipid. The venom is diluted to give a clotting time of 23 to 27 seconds and the phospholipid is reduced to make the test extremely sensitive to phospholipid. The dRVVT test is more sensitive than the aPTT test for the detection of lupus anticoagulant (an autoimmune disorder), because it is not influenced by deficiencies in clotting factors VIII, IX or XI.
In India, the Haffkine Institute prepares a polyvalent antivenin that is used to treat bites from this species.
A number of other subspecies may be encountered in literature, including:
- D. r. formosensis, Maki 1931 - found in Taiwan (considered a synonym of D. r. siamensis).
- D. r. limitis, Mertens 1927 - found in Indonesia (considered a synonym of D. r. siamensis).
- D. r. pulchella, Gray 1842 - found in Sri Lanka (considered a synonym of D. r. russelii).
- D. r. nordicus, Deraniyagala 1945 - found in northern India (considered a synonym of D. r. russelii).
The correct spelling of the species, D. russelii has been, and still is, a matter of debate. Shaw & Nodder (1797), in their account of the species Coluber russelii, named it after Dr. Patrick Russell, but apparently misspelled his name, using only one "L" instead of two. Russell (1727-1805) was the author of An Account of Indian Serpents (1796) and A Continuation of an Account of Indian Serpents (1801). McDiarmid et al. (1999) are among those who favor the original misspelled spelling, citing Article 32c (ii) of the International Code of Zoological Nomenclature. Others, such as Zhao and Adler (1993) favor russellii.
In the future, more species may be added to Daboia. Obst (1983) reviewed the genus and suggested that it be extended to include Macrovipera lebetina, Vipera palaestinae and V. xanthina. Groombridge (1980, 1986) united V. palaestinae and Daboia as a clade based on a number of shared apomorphies, including snout shape and head color pattern. Lenk et al. (2001) found support for this idea based on molecular evidence, suggesting that Daboia not only include V. palaestinae, but also M. mauritanica and M. deserti.
believe that, because D. russelii
is so successful as a species and has such a fearful reputation within its natural environment, another snake has even come to mimic its appearance. Superficially, the rough-scaled sand boa, Gongylophis conicus
, has a color pattern that often looks a lot like that of D. russelii
, even though it is completely harmless.
- Adler K, Smith HM, Prince SH, David P, Chiszar D. 2000. Russell's Viper: Daboia russelii not Daboia russellii, due to Classical Latin rules. Hamadryad, 25(2): 83-85.
- Breidenbach CH. 1990. Thermal cues influence strikes in pitless vipers. Journal of Herpetology, Society for the Study of Reptiles and Amphibians, Vol. 24(4):448-450.
- Cox M. 1991. The Snakes of Thailand and Their Husbandry. Krieger Publishing Company, Malabar, Florida. 526 pp. ISBN 0-89464-437-8.
- Daniels, J.C. Book of Indian Reptiles and Amphibians. (2002). BNHS. Oxford University Press. Mumbai. viii+238pp.
- Dimitrov G, Kankokar R. 1968. Fractionation of Vipera russelli venom by gel filtration I. Venom composition and relative fraction function. Toxicon (Great Britain) 5:213-21.
- Dowling HG. 1993. The name of Russel's viper. Amphibia-Reptilia 14: 320.
- Gharpurey K. 1962. Snakes of India and Pakistan. Bombay, India: Popular Prakishan. 79 pp.
- Groombridge B. 1980. A phyletic analysis of viperine snakes. Ph-D thesis. City of London: Polytechnic College. 250 pp.
- Groombridge B. 1986. Phyletic relationships among viperine snakes. In: Proceedings of the third European herpetological meeting; 1985 July 5-11; Charles University, Prague. pp 11-17.
- Jena I, Sarangi A. 1993. Snakes of Medical Importance and Snake-bite Treatment. New Delhi: SB Nangia, Ashish Publishing House. 293 pp.
- Lenk P, Kalyabina S, Wink M, Joger U. 2001. Evolutionary relationships among the true vipers (Reptilia: Viperidae) inferred from mitochondrial DNA sequences. Molecular Phylogenics and Evolution 19(1):94-104.
- Mahendra BC. 1984. Handbook of the snakes of India, Ceylon, Burma, Bangladesh and Pakistan. Annals of Zoology. Agra, India, 22.
- Master RWP, Rao SS. 1961. Identification of enzymes and toxins in venoms of Indian cobra and Russell's viper after starch gel electrophoresis. The Journal of Biological Chemistry 236:1986-90.
- Minton SA Jr. 1974. Venom Diseases. CC Thomas Publishing, Springfield, Illinois. 386 pp.
- Naulleau G, van den Brule B. 1980. Captive reproduction of Vipera russelli. Herpetological Review. Society for the Study of Amphibians and Reptiles. 11:110-2.
- Obst F. 1983. Zur Kenntnis der Schlangengattung Vipera. Zoologische Abhandlungen. Staatliches Museums für Tierkunde in Dresden. 38:229-35.
- Reid HA. 1968. Symptomatology, pathology, and treatment of land snake bite in India and southeast Asia. In: Bucherl W, Buckley E, Deulofeu V, editors. Venomous Animals and Their Venoms. Vol. 1. New York: Academic Press. pp 611-42.
- Shaw G, Nodder FP. 1797. The Naturalist's Miscellany. Volume 8. London: Nodder and Co. 65 pp.
- Shortt. 1863. A short account of the viper Daboia elegans (Vipera Russellii). Annals and Magazine of Natural History, London. (3) 11: 384-385.
- de Silva A. 1990. Colour Guide to the Snakes of Sri Lanka. Avon (Eng): R&A Publishing Ltd. 88 pp. ISBN 1-872688-00-4.
- Sitprija V, Benyajati C, Boonpucknoaviq V. 1974. Further observations of renal insufficiency in snakebite. Nephron 13:396-403.
- Thiagarajan P, Pengo V, Shapiro SS. 1986. The Use of Dilute Russell Viper Venom Time for the Diagnosis of Lupus Anticoagulants. Grune & Stratton Inc. Blood, Vol.68(4):869-74. PDF at blood Accessed 27 September 2006.
- Thwin M, Mee-Mee K, Kyin M, Than T. 1985. Kinetics of envenomation with Russell's viper venom and of the antivenin use in mice. Toxicon (Great Britain) 26:373-8.
- Thwin M, Than T, Hla-Pe U. 1985. Relationship of administered dose to blood venom levels in mice following experimental envenomation by Russell's viper venom. Toxicon (Great Britain) 23:43-52.
- Tweedie MWF. 1983. The Snakes of Malaya. Singapore: Singapore National Printers Ltd., 105 pp. ASIN B0007B41IO.
- Vit Z. The Russell's Viper. 1977. Prezgl. Zool. 21:185-8
- Wall F. 1906. The breeding of Russell's viper. Journal of the Bombay Natural History Society 16:292-312.
- Whitaker R. 1978. Common Indian Snakes. New Delhi (India): MacMillan. 85 pp.
- Wüster W. 1992. Cobras and other herps in south-east Asia. British Herpetological Society Bulletin 39:19-24.
- Wüster W, Otsuka S, Malhotra A, Thorpe RS. 1992. Population Systematics of Russell's Viper: A Multivariate Study. Biological Journal of the Linnean Society 47 (1):97-113.
- Zhao EM, Adler K. 1993. Herpetology of China. Society for the Study of Amphibians & Reptiles. 522 pp. ISBN 0-916984-28-1.