Gaseous Exchange in Animal PDF

Summary

This document provides a comprehensive overview of gaseous exchange in animals, with specifics on the human respiratory system, invertebrate respiration, and various respiratory problems. The content introduces different types of respiratory systems and mechanisms. It includes learning objectives, diagrams and explanations of processes. Included are discussions on diseases and conditions.

Full Transcript

GASEOUS EXCHANGE IN ANIMAL
Norfarahin Norwen | [email protected]

Aquila Watercolour Illustrator

Finch Fight Illustrator
Mother Daughter Illustrator
LEARNING OBJECTIVES

To explain the
gaseous exchange in human

To explain the
gaseous exchange in
invertebrate and vertebrate
 Human
respiratory
structure
 Breathing mechanism of human
Exhalation Inhalation
External intercostals External intercostals
muscles relax, internal muscles contract,
intercostals muscle internal intercostals
contract. –rib cage muscle relax. –rib
moved lowered and cage moved up
move inwards toward the front

Diaphragm muscles Diaphragm muscles
relaxes and curves up contract and flatten

Volume of the Volume of the
thoracic cavity thoracic cavity
decreases increases

Higher pressure in Higher atmospheric
thoracic cavity pushes pressure pushes air
air out of the lungs into the lungs
Human respiratory structure

Main organ; lung

Trachea branches into two main
bronchus/bronchi. Further into
smaller tubes; bronchioles. Each
ends in a cluster of microscopic air
sacs; alveolus/alveoli

respiratory structure where the gas
exchange between the blood and air
occurs by simple diffusion
Alveolus: Site for Gaseous Exchange

Structural adaptations:

Small size and high number present
–for larger surface area

Moist wall
–allows respiratory gases to dissolve easily

Thin wall
–for quick and easy diffusion of gases

Rich supplied with blood capillaries
–to increase the rate of diffusion and
the rate of the transportation of gases
 Exchange of O₂ and CO₂
-alveoli and blood capillary

During inhalation, partial
pressure of O₂ is higher in
alveoli than blood capillary.
O₂ diffuses into blood capillary

PCO₂ is higher in blood
capillary than alveoli. So, CO₂
moves into alveoli in opposite
direction and gets exhaled out
 Exchange of O₂ and CO₂
-blood capillary and tissues

Partial pressure of O₂ is higher in
blood capillary than tissues. O₂
gets release into tissues

PCO₂ is higher in tissue than in
blood capillary. So, CO₂
diffused in opposite direction
into blood
 Transport of Oxygen in Human

98% O2 in blood
transported by
haemoglobin (Hb) in the
form of oxyhaemoglobin
(HBO₂)

Another 2% dissolved in
plasma, transported by it
Transport of Carbon dioxide in Human
7% of the CO₂ dissolved in the
plasma

23% of the CO₂ combines with
haemoglobin (Hb) forming
carbaminohaemoglobin
(HbCO₂). It then breaks down,
releasing CO₂ into the alveoli

70% of excess CO₂ diffuses into
red blood cells reacting with
water (H₂O) becoming carbonic
acid (H₂CO₃). It then moving into
the plasma while dissolved CO₂
diffuses into the alveolar air
space
The Respiratory Control System

Respiratory controls centers:
Medulla Oblongata –controls respiration to
cause breathing to occur by sending signals
to the muscles of respiratory structure

Also controls the reflexes for
nonrespiratory air movements

Pons –controls the rate or speed of breathing
Regulation of Breathing is a form of negative feedback. The goal is to keep
pH blood within normal range.

Chemoreceptor detect changes in chemical
composition of blood and send information to the
brain.

An increase of CO2 concentration leads to a
decrease in the blood pH, due to the production of
H+ ions from carbonic acid.

In response, the respiratory center in the medulla
sends nervous impulses → external intercostal
muscles and the diaphragm, to allow respiratory
muscles contract and relax faster.

Breathing and ventilation rate increase causing
more O2 to be inhaled and the O2 concentrations
returns to normal.

As excess CO2 is eliminated from the body, the CO2
concentration and blood pH return to normal level.
Respiratory Problems
1. Pneumonia

lung(s) infection from bacteria / viruses / fungi,
causes alveoli fill up with fluid or pus

Symptom:
mild to serious cough with/without mucus
fever, shaking chills
Trouble/rapid in breathing, rapid pulse

Treatment: can be prevented by vaccines.
Can be treat by antibiotic, viral, or fungal
medicines, If get worse? Antibiotics given
through intravenous line and oxygen therapy
Respiratory Problems
2. COPD: Emphysema
long-term exposure to airbone irritants
damaging air sacs, inner walls become
weaken and rupture. It then affect amount of
O₂ → bloodstream

Symptom:
long-termed coughing
shortness of breath
coughing with mucus
wheezing, ongoing fatigue, trouble sleeping
chest tightness

Treatment: stop smoking, avoid secondhand
smoke and air pollutant, wear protection from
chemical fumes, varnish, paint or dust
Respiratory Problems
3. COPD: Chronic Bronchitis
exposure to cigarette smoking, air pollution of
dust or toxic gases inflamed the lung airways,
destroy cilia; bronchi cause sticky mucus to
build up in it

Symptom:
shortness of breath
Coughs for at least 3 months
wheezing
chest pain
tiredness

Treatment: lifestyle changes and medication
such bronchodilators to relax air passages,
steroids to lessen the swelling. Oxygen therapy,
specialized rehab programme, lung transplant
Respiratory Problems
4. Asthma
Major noncommunicable disease (NCD) that
makes airways narrow, swell, and blocked due
to producing of extra mucus

Symptom:
breathing difficulty
shortness of breath
coughing
whistling, wheezing
trouble sleeping

Treatment: inhaled medication, avoid asthma
triggers such airborne substances, air-
conditions cold and dry
Respiratory Problems
5. Tuberculosis
contagious infection of Mycobacterium
tuberculosis that attacks lungs, can also
spread to other part of human body. Start with
Primary, Latent, Active to Active outside lungs

Symptom:
breathing difficulty, chest pain
fever, chills
cough last more than 3 weeks
coughing up blood
Night sweats
Loss appetite, weigh loss

Treatment: most cured by antibiotics,
medications for at least 6 to 9 months
 Invertebrate Circulatory System

Roundworm

Phylum Porifera Phylum Cnidaria Phylum Nematoda
 The blood flows This system has
freely through vessels that
cavities since there conduct blood
are NO vessels to throughout the
conduct the blood body *annelids &
*mollucs & arthropods vertebrates
Gaseous Exchange in INVERTEBRATE respiration
Skin-breathing
Movement of O2 and CO2 across moist
respiratory surfaces takes place entirely
by diffusion

Survive for extended periods only in
damp or aquatic habitat
 Tracheal systems
Air enters the spiracles; small holes located
at the thorax and abdomen

Air is distributed through the body of the
organisms via trachea and tracheoles
that come into close contact with the
organisms' cells
 Vertebrate Circulatory System
All vertebrates have a
closed cardiovascular system

Vertebrate heart
Two different circulatory pathways in vertebrates;
Atrial chamber(s) of heart receive Single-loop
blood from general circulation heart only pumps blood to gills

Ventricle chamber(s) of heart pump Two-circuits
blood out through blood vessels Pulmonary circuit - heart pumps blood to the
lungs
Vertebrate vessels
Arteries carry blood away from heart Systemic circuit - heart pumps blood to all parts
Arterioles lead to capillaries
of the body except for the lungs
Capillaries exchange materials with tissue fluid
Venules lead to veins
Veins return blood to heart
Fishes single loop Amphibians, Reptiles double loop
Heart with single atrium and Two atria and single ventricle pumps
a single ventricle blood in the pulmonary circuit to the
lungs
enriched blood with
oxygen when it leaves gills Also pumps blood in the systemic
circuit to the rest of the body
O2 -rich and O2 -poor blood enter the
single ventricle, it is kept separated
O2-poor blood is pumped firstly out of
the ventricle into the lungs before O2-
rich blood enters and is pumped into
the systemic circuit

Birds and Mammals
Two atria and two ventricles in the heart
and there’s complete separation of the
pulmonary and systemic circuits
Right ventricle pumps blood under
pressure to the lungs, and the larger left
ventricle pumps blood under pressure to
the rest of the body
Gaseous Exchange in VERTEBRATE respiration
A fish simply open its mouth and let
water flow past its gills

Each gill arch has two rows of gills
filaments, composed of flattened
plates called lamellae

Blood flowing through capillaries
within the lamellae, picks up oxygen
from the water

Counter current exchanges
mechanisms; water flow over the
gills in one direction while blood
flows in opposite direction through
capillaries
Mouth
By vascular bucco-pharyngeal.
Occur while the frog is not submerged in water

Skin
Thin, permeable to water and kept moist as it
covered by mucous lining.
Entirely dependent on respiration through the
skin when they are underwater.

Lungs
Consist of a pair of thin-walled sacs connected to the
mouth through an opening called glottis.
The membranes of the lungs are thin, moist and covered
by a network of capillaries.
Use their throats, nostrils and mouths together to bring in
and expel gases.
Bird’s respiratory system consists of paired
lungs with connected to two air sacs.

Passage of air through the entire system
requires two cycles of inhalation and
exhalation cycle, before it is fully used
and exhaled out of the body.
1st inhalation: Fresh air travels through trachea,
which splits into left and right primary bronchi. Some
air enters the lungs where gas exchange occurs
while the remaining air fills the posterior air sacs

1st exhalation: Posterior air sacs contract, pushing air
into lungs and undergoes gas exchange.
*The spent air in the lungs is displaced by the incoming air
and flows out the body through the trachea
2nd inhalation: *Fresh air again enters both the posterior
sacs and the lungs. Spent air in the lungs is again
displaced by incoming air but it cannot exit through
trachea because fresh air is flowing inward. Instead,
spent air passes through lungs and fills anterior air sacs

2nd exhalation: Anterior air sacs contract, air in the
lungs flows out through the trachea, and fresh air in
the posterior sacs enters the lungs for gas exchange