Gaseous Exchange.pptx.pdf

Full Transcript

GASEOUS
EXCHANG
E
 GASEOUS EXCHANGE

Breathing / ventilation:
mechanical process that moves
air in and out of the respiratory
organs.
Gaseous exchange: exchange of
gases; oxygen and carbon
dioxide
Cellular respiration: release of
energy from glucose
 WHY IS GASEOUS EXCHANGE NECESSARY?

Supplies the body with oxygen
Removal of CO2
Failure to remove causes carbonic
acid to be formed
Lowers pH
REQUIREMENTS OF EFFICIENT GAS EXCHANGE ORGANS

Large: maximise gas exchange
Thin and permeable: easy and quick diffusion
Moist: gases can dissolve
Well-ventilated: brining fresh air to gas exchange
surface
Well-protected: prevent desiccation and injury
Transport system: blood supply close to gas
exchange surface
GASEOUS EXCHANGE IN VARIOUS ORGANISMS
INSECTS
BONY FISH
MAMMALS
SURFACE AREA AND VOLUME OF ORGANISM

As organism size increase; surface area to volume
decreases
Surface area – amount of oxygen can be absorbed
Volume indicates amount of oxygen the organism
requires.
Unicellular organisms: large surface area compared to
volume; rely on diffusion
Large multicellular organism: small surface area
compared to volume; lungs or gills
COMPONENTS OF BREATHING SYSTEM

Air passages
Two lungs
Respiratory muscles
(intercostal and diaphragm)
Respiratory centre in the brain
 AIR PASSAGES: NASAL PASSAGES
Function
Anatomy Warms and moistens air
Increase surface area
Mucous membrane
containing rich supply Cilia involved in movement and
of blood vessels trapping of dust
Turbinate bones:
division by 3 bony
plates
Ciliated epithelium
with goblet cells
 PHARYNX (THROAT)

Anatomy
Connects nasal cavity with
larynx

Function
Food and air passage
 LARYNX (VOICE BOX)
Anatomy
Vocal cords
Epiglottis

Function
Sound production
Prevents food from entering
larynx (closes glottis)
TRACHEA (WINDPIPE)
Anatomy
C-shaped cartilaginous rings
Lined with cilia
Lined with goblet cells
Function

Takes air to and from lungs
Keeps trachea open
Movement of mucus
Produces mucous for moisture
and trapping foreign particles
 BRONCHI
Anatomy
Two branches – left and right
O-shaped cartilaginous rings
Lined with cilia and goblet cells

Function
Movement of air to and from
lungs
 BRONCHIOLE (SMALL BRONCHI)
Anatomy
Narrow branches
Lined with cilia and goblet
cells

Function
Take air to and from alveoli
 LUNGS

Protection by rib cage
Two membranes - Pleural
membranes
Contains pleural fluid
Lungs are divided into lobes
Right: three
Left; two
Consist of sac-like structures:
infundibulum 🡪 smaller air sacs:
alveoli
 LUNGS ARE SUITED FOR THEIR FUNCTION
Alveoli increase surface area
Alveoli only 1 cell layer thick
Moisture in alveoli
Capillaries surround alveoli
Surrounded by a double membrane

Blood supply:
Pulmonary artery 🡪 deoxygenated blood
Pulmonary veins 🡪 oxygenated blood
 VENTILATION – INHALATION / INSPIRATION
Active process
Diaphragm contracts
Top to bottom increases
External intercostal muscles
contract
Ribs move outwards
Thoracic cavity enlarges
Pressure in lungs decrease and
become lower than atmospheric
pressure
Air flows into the lungs
 EXHALATION / EXPIRATION

Passive process
Diaphragm relaxes and moves
upwards
External intercostal muscles
relaxes and moves inward
Pressure in lungs increase and
become higher than
atmospheric pressure
Air flows out of the lungs
EXTERNAL GASEOUS EXCHANGE

▪ Higher concentration of
O2 in the alveolus than in
the capillary
▪ O2 dissolves in the
moisture and diffuses
through alveolus wall and
wall of capillary into the
blood
EXTERNAL GASEOUS EXCHANGE

▪ Higher concentration of
CO2 in the capillary than
in the alveolus
▪ CO2 diffuses through the
wall of capillary and
alveolus wall into the
alveolus
INTERNAL GASEOUS EXCHANGE In tissues

▪ Cellular respiration:
needs O2 and produces
CO2
▪ Levels of O2 decreases
and levels of CO2
increases
▪ O2: capillary → cell
▪ CO2: cell → capillary
 TRANSPORT OF OXYGEN AROUND THE BODY

98% of oxygen binds to haemoglobin
2% dissolved in blood plasma
 CARBON DIOXIDE TRANSPORT

7% dissolved in water and transported by blood plasma
23% combines with haemoglobin to form carbaminohaemoglobin
Carbonic anhydrase splits CO2 at the lung surface
70% combines with water to form carbonic acid 🡪 transported as bicarbonate
ions (HCO3)
H atoms lower blood pH🡪 more O2 dissociate
H ions attach to globin and acts as a buffer
Carbonic anhydrase dissociates CO2 at lungs
 Oxyhaemoglobin is split to release oxygen to cells
Carbonic acid is present in blood and aids in dissociation of oxygen from
haemoglobin.
The amount of oxygen required at a site depends on the amount of carbonic acid
present.
Bӧhr effect
 LUNG CAPACITY

Amount of air that enters of leaves
the lungs
Spirometer
Total volume = 5 L
Tidal volume = 0.5 L normally
inhaled/exhaled
Vital capacity = exhaled with force;
3.5 L
Residual volume = air remaining in
lungs after forced exhalation; 1.5 L
GASINHOUD/ GAS CONTENT
 RESPIRATORY CENTRE Diagram page 2.39

Respiratory centre in Medulla oblongata
of the brain
Detects CO2 levels in blood and controls
rate and depth of breathing.
Nerve impulses is sent to breathing
muscles to increase rate and depth.
Coordination of
all voluntary
activity in body

Autonomic Muscle tone,
control; heart, balance
respiratory,
salivation,
swallowing
 EFFECTS OF ALTITUDE ON GASEOUS EXCHANGE

Increase in altitude 🡪 less oxygen
Hypoxia
Nausea, headaches, dizzy
Body needs to acclimatise

Initial 🡪 🡪

Secondary: production of erythropoietin
(hormone) 🡪 stiumulate red bone
marrow to make more red blood cells
EFFECTS OF SMOKING

Cigarettes contains over 4000
harmful or poisonous substances.
Nicotine
Stimulates adrenalin
Nicotine travels in blood
Arteries narrow
Increased heart rate and blood
pressure; fatty acid
addictive
 Tar
Carcinogenic
Cancer – lung, mouth, trachea
Damage to cilia
Excess mucus production 🡪 infections
Damage to alveoli
Inflammation to air passages 🡪
chronic bronchitis
 Carbon monoxide
Colourless, poisonous
Combines with haemoglobin
Increased risk of heart attack
Passive smoking
SMOKING LEGISLATION IN SA
RESPIRATORY DISEASES

▪Tuberculosis (TB)
▪Asthma
▪Hay fever
▪Bronchitis
▪Emphysema
▪Lung cancer
 TUBERCULOSIS (TB)
▪ Mycobacterium tuberculosis (bacteria) –
deadly
▪ Causes inflammation in the lungs
▪ infected person that coughs or sneeze can
spread bacteria in droplets of saliva
SYMPTOMS MANAGING
Cough regularly
▪ Antibiotics for 6 months
Coughing blood
▪ Side-effects – nausea and liver
Chest pain
damage
Headache
Fever
Fatigue
Weight loss
ASTHMA
▪ Get asthma attacks and
struggle to breathe
▪ Smooth muscles of the
lining of bronchi or
bronchioles contract
▪ Airways become narrow
▪ Caused by dust, pollen or
polluted air
▪ Inhaler is required
▪ Relax smooth muscles –
dilate airways
 HAY FEVER

▪ Allergic reaction in the
nasal passages
▪ Caused by dust or pollen
▪ Symptoms – watery
eyes, runny nose and
sneezing
 BRONCHITIS

▪ Inflammation in the lining of
bronchi
▪ Swelling of muscle and
excessive release of mucus
▪ Caused by infection, polluted
air or smoke
▪ Symptoms – cough regularly,
shortness of breath and chest
pains
 EMPHYSEMA

▪ Alveoli walls are
damaged
▪ Reduce gas exchange
surface
▪ Caused by smoke
▪ Symptoms – coughing and
shortness of breath
▪ Incurable
LUNG CANCER

▪ Uncontrolled division of cancer
cells (tumor) in the lung tissue
▪ Caused by smoke or other toxins
in the air
▪ Symptoms – cough regularly,
coughing up blood, shortness of
breath and chest pains
▪ Treatment – physical removal,
chemotherapy or radiotherapy