Snakes have well-formed biting apparatuses coupled with toxic venoms produced by poison glands. Their fangs are long, pointed, and hollow, allowing venom to be injected. The biting mechanism involves opening the mouth through muscle contraction, rotating the maxilla bone to erect the fangs, and then closing the mouth to inject venom. Snake venoms contain complex chemical mixtures including enzymes and proteins that can be neurotoxic, causing paralysis, or haemotoxic, resulting in tissue damage and hemorrhaging. The first aid treatment for a snake bite involves remaining calm, immobilizing the bitten area, seeking medical help, and avoiding actions like cutting the wound or sucking out venom.

1. Biting Mechanism of Poisonous
Snake s and Venom
presented by : Gaurav kumar

2. SNAKES
INTRODUCTION
The most innocent animal of the world.
Has the largest number of enemy.
Goddess in some religion.
Study of snakes is called as. Serpentology.
Snakes can also digest hairs, feathers &
horns.
Largest serpentorium in India is situated in
Chennai(Madras).

3.  ectothermic reptiles
 belong to the suborder Serpentes
 bears well formed biting apparatus coupled
with toxic venoms, products by the poison
gland
 less than 300 species may be harmful to
human

9.  King Cobras are the largest
venomous snakes and they reach
lengths between 3 and 5.5 m
(9.8 - 18 ft). Their colour can
vary depending on their location
but they are usually olive, brown
or black.
 Seen through out India,
Burma, Srilanka
 Well marked hood
 Single (monocellate) or double
spectacle mark
 Cobra’s venom is heamotoxic.
Common Cobra / Indian Nag

11. Common Krait Description
Male kraits have longer tails as
compared to females.
The common krait has small eyes and
flat head.
It has 15 – 17 rows of scales on its
body.
The krait does not go far away from a
water source.
Common kraits make homes in
termite mounds or rat holes
Common krait or Indian krait

12. The saw-scaled viper is
highly venomous and listed
as one of south Asia's most
dangerous snakes. It is quite
a common snake, lives in
proximity to people and is
quick to bite when it feels
threatened. These vipers are
mostly nocturnal and
sometimes bury themselves
in sand. Saw-scaled vipers
give birth to live young and
those that live in colder
climates hibernate in winter.
Saw scaled viper

13. Russell’s Viper
Distribution:
Russell's vipers are widely found in
India, Sri Lanka, Thailand, Indo-
China and Indo-Australian
archipelago.
Habitat:
They normally live in plains
Characteristics:
•Body of Russell's viper is covered
with keeled scales.
•Russell's viper can reach 3.3 to 5.5
feet in length.
•Venom type is haemotoxic.

14. Black Mamba most dangerous snake
of the world

15.  Poison glands - modified superior labial or
parotid glands.
 situated on the either side of the upper jaw
 Sac-like structure
 thickly encapsulated with fibrous tissue
 narrow duct from the anterior end of the poison
sacs and passes forward along the side of the
upper jaw and loops over itself just in front of
the fang.
 capsule supports vascular fibrous septa that
separate the glandular substances into secretory
pockets.
POISON APPARATUS IN SNAKES

17.  Fangs- Snakes eject venoms by their two
hollow maxillary teeth called fangs
 Fangs are long sharply pointed and hook like,
being extremely hard and calcified with a
superficial enamel layer

18. According to the position,
the poison fang may be
According to the structural
differences poison fangs
 Opisthoglyphodont :
◦ fangs lie at the back of
the maxilla and are of
open category.
 Proteroglypodont :
◦ fangs are situated at the
front end of the maxilla
and are at closed
category.
 Open type :
◦ furrowed by a groove for
the conduction of the
venom.
 Closed type :
◦ Fang becomes almost or
totally tubular,
hypodermic syringe like
structure due to
approximation of the
groove tips.

19.  Muscles - Digastric muscle;
sphenoterygoid; anterior and
posterior temporalis

20.  Opening of mouth by contraction of digastric
muscle
 Rotation of maxilla bone
 Fangs become erect and press the victim
 Mouth closes by the action o temporalis
muscles
 Injection of poison is completed
Mechanism of snake bite

21. The mechanism also entails the same story in case of Indian
poisonous snakes, specially the cobra and viper groups. The
mechanism of biting is a complicated process and the sequences
of biting may be discussed in three observable steps.
(a) Opening of the mouth:
Just before striking the digastrics muscle contracts, as a result the
mouth opens
(b) Rotation of maxilla:
As the mouth opens, the lower jaw moves forward and a rotation of
the squamosal, quadrate and mandible in relation to each other
occurs. Now the sphenopterygoid muscles contract. This
contraction results in the forward movement of pterygoid and up-
pushing of the ectopterygoid.
The upward movement of the ectopterygoid brings about a rotation
of the maxilla on its own axis round the lacrimal and as the end
result the fang is raised and comes to its striking position. The
fang is nearly horizontal in position when the mouth remains
closed. But during opening of the mouth to bite, the fang assumes
almost vertical position.

22. Boltt and Ewer (1964) have suggested that the quadrate is
loosely attached to the posterior part of the pterygoid and
the weak force which is generated by the rotation of the
lower end of quadrate, could not help in the forward
movement of pterygoid and ectopterygoid.
They suggest that the movement of the pterygoid and
ectopterygoid is effected by the contraction of their own
muscles the protractor and levator pterygoidei (Fig. 8.33)
which jointly act to push the pterygoid and ectopterygoid
directly forward.
As a result the maxilla rotates in its own axes. Boltt and Ewer
also believe that the erection of fangs is not related to the
opening and closing of the mouth. The fangs can be erected
independently.

24. (c) Closing of mouth:
This is brought about by the contraction of the
temporalis muscles and sphenopterygoid muscles. The
point of the fang is directed backward while the mouth
is closed. It takes a longer time to open the mouth than
to close it.

27.  Highly complex chemical mixtures
that “may contain many proteins,
mainly particular enzymes, and
strongly basic polypeptides
 The chemical compositions of venoms
are known to vary intra-specifically for
a number of reasons
Snake venom

28.  The geographic variation in venom - closely
related to diet and thus reasoned that natural
selection had directed venom composition to
make the venoms most effective against the
specific prey types that snakes in separate
areas would encounter
 As a general rule, venoms seem to be either
highly toxic (to bring about rapid prey death)
or highly proteolytic (presumably to help with
chemical digestion)

29. Neurotoxic … Haemotoxic …
 produce paralysis and
death by respiratory
shock
 rich in basic amino acids
 act at the molecular level
by disrupting
neuromuscular junctions
and hence limit muscle
activity
 Low molecular weight –
fast diffusion process
 have hemorrhagic effects
 often cause tissue
destruction in other body
systems - attributed to
proteins and digestive
enzymes such as
phospholipase A2
 Higher molecular weight
– slow diffusion process

34.  Call medical help immediately if
possible.
 Remain calm, remember most
snake bites are not fatal.
 Minimise movement if possible. If
you are hiking alone you may
have to hike out for help.
First aid for snake bite

35.  If you are bitten on the arm or finger
remove any rings, bracelets or watches.
Loosen any tight clothing in case
swelling occurs.
 Apply a pressure bandage to the bitten
limb. If the bite is to the trunk, head or
neck, apply firm pressure to the bitten
area. Do not restrict chest movement as
breathing will be affected by this.

36.  Splint or use a sling on the bitten limb to restrict
movement.
 If there is no bandage or equivalent to apply a
pressure bandage make note of any inflammation
by tracing the edge of the swelling with a pen or
the like near/around the bite and mark the time
clearly next to it. If it progresses make a new
tracing noting the time of each new mark beside
that new tracing. This will give valuable
information to medical help as to the
development of the swelling.

37.  If possible, lie down and keep the bitten
extremity at body level. Raising it can
cause venom to travel through the body
quicker. Holding it down, can increase
swelling.
 When possible arrange for transport to
the nearest hospital emergency room,
where anti-venom for snakes common to
the area will often be available and given
if required.

38.  NO aspirin or other pain relievers.
 NO tourniquets. This cuts blood flow completely and may
result in loss of the affected limb.
 DO NOT try to suck the venom out of the wound or cut
into the bite with a knife. Such measures have not been
proven useful and may cause further injury (see below
explanation).
 DO NOT apply a cold compress or ice on the bite. Research
has shown this to be potentially harmful.
 DO NOT raise the wound above the heart. Raising it can
cause venom to travel into the body. Holding it down, can
increase swelling.

39.  DO NOT use electric shock or a stun gun on the bite area.
This method is under study and has yet to be proven
effective. It could harm the victim.
 DO NOT wash the snake bite area - Australian
recommendations for snake bite treatment strongly
recommend against cleaning the wound. Traces of venom
left on the skin/bandages from the strike can be used in
combination with a snake bite identification kit to identify
the species of snake. This speeds determination of which
anti-venom to administer in the emergency room.
 DO NOT try and capture the snake. If it's safe you can try
to take a photo with a camera or with your phone. This is
the best way in aiding snake identification.

40. Thank You