Transcript long tail

FLIGHT ADAPTATIONS
IN BIRDS
Dr.Jagdish Kaur
P.G.G.C.,Sector 11
Chandigarh
FLIGHT ADAPTATION IN BIRDS
only vertebrates specialized to aerial mode of life.
The super order ratitae or palaeognatheae includes the
flightless terrestrial birds e.g. Ostrich, Kiwi etc.
Super order impennae or spenisciformes includes marine
and flightless birds and occur in antarctic region e.g. Penguin.
The super order neognatheae includes the flying or modern
birds.
Flying birds are heavier than air machines and show a
number of morphological, anatomical & physiological
modifications to suit their aerial mode of life.
These are called volant adaptation.
MORPHOLOGICAL ADAPTATIONS
1. Body Shape
 Generally spindle shaped or streamlined
 Lack the extra lateral projection to minimize the resistance in air
during flight.
2. Feathery Exoskeleton
Feathers are special integumentary derivatives and are one of the
diagnostic features of birds, and perform following functions:

Contour feathers make the body streamlined.

Form an insulating coat to prevent the loss of body heat.

Wing quill feather, called remiges provide a large and broad
surface area for the air movement.
3. Flight Organs
The fore limbs are modified into powerful flight organs, called
wings.
4. MOBILE NECK & BEAK
Transformation of forelimbs into wings is dully compensated by
the development of extreme mobility of the long and flexible neck
for reaching food.
•The mouth is bounded by a horny beak which help in ingestion,
nest building etc.
5.EQUILIBRIUM
• Shifting of light organs towards upper part of body &
heavy organ towards lower.
• That shifts the centre of gravity to the posterior part of
body
This low centre of gravity prevent the turning of the
body of a bird in the air.
6. STEERING APPARATUS
Short tail bearing a tuff of long tail quill
feather (retrices), that assist in steering,
lifting and counter balancing during flying.
ANATOMICAL ADAPTATIONS
1. FLIGHT MUSCLES
 Muscles of back are greatly reduced but the flight muscles are
greatly developed and highly vascular.

These have long and straited muscle fibses so that they do not
undergo fatigue even after prolonged activity.
2. LIGHTNESS AND RIGIDITY OF ENDOSKELETON
 light and rigid endoskeleton
 Their endoskeleton is built on hollow girder principle.
 Rigidity is
required to resist the pressure of air current during
flight.
 Lightness achieved through following adaptation:
 Skull bones are thin and papery.
 Pneumacity: most of long bones are filled with air spaces to make
them light such bones are called Pneumatic bones, which also
decreases the specific gravity of the bird.
In pigeon there are three types of flight muscle.
Pectoralis depressor major :- These are largest size flight
muscle. Their contraction cause powerful downstroke of
wings, arise from the ventral side of sternal keel.
Pectoralis elevator muscle :- these arise from anterior part of
the sternum . Their contraction cause upstroke of the wings.
Accessory muscles :- these supplement the pectoralis muscles
to elevate or depress the wings. These are:1. coraco – brachialis longus or coraco – brachialis brevis.
2. Biceps and triceps
3. Extensor carpiradialis and extensor carpiulnaris.
• Presence of Air Sacs
•
In birds there is tendency towards reduction in
the number of bones.
• Lightness is also achieved by the loss of certain
organs
e.g. teeth, gall bladder, urinary bladder and
right ovary
and oviduct in the female.
3. RIGIDITY IS ACHIEVED THROUGH FOLLOWING ADAPTATIONS:
 Complete fusion of skull bones so that even the
sutures are absent or indistinct between them.
 Caudal vertebrae are fused to form a small and
triangular pygostyle to provide stability in the air.
PHYSIOLOGICAL ADAPTATION
Digestive system: Birds have following adaptation in their
digestive system:
 Beaks are variously modified to intake large amount of
food in the mininum period.
 A masticatory gizzard with a thick cuticular lining is
developed to compensate the absence of teeth.
 Rate of digestion is very high due to immediate
utilizations of digestive juices due to presence of two
bile ducts and three pencreatic ducts.
2. Respiratory system:
 In birds, the rate of respiration is very high.
It is about 25-29 times per minute.
 To compensate small sized and inelastic
lungs, the birds show double respiration in
which the lung alveoli receive fresh air
during both inspiration and expiration.
 Air sacs are thin and distensible sacs
associated with the lungs.
CIRCULATORY SYSTEM
 Avian heart is larger in size, more powerful and
more efficient.
 Their heart is four chambered with double
circulation.
 Rate of heart beat is faster in birds which
increase cardiac output and blood supply to
various organs of body.
 RBCS of birds have large amount of
haemoglobin.
 Homeothermy: birds are warm blooded or
homeothermal vertebrates.
5. EXCRETORY SYSTEM:
 Loop of henle is long sized.
 Urinary bladder is absent so that nitrogenous
wastes are immediately expelled out of the
body.
 Brain and sense organs: Birds have to depend
more on the sense of sight to locate their food so
that optic lobe of midbrain and eyes are well
developed.
 Brain is large sized and well developed to coordinate the complex movements of wings and
the feathers during flight.
These adaptation reveals that
flight in birds is a technical wonder
which enables them to explore new
habitats for food and shelter and to
escape from the unfavourable
climatic condition and enemies.