Physiology Of The Respiratory System PDF

Summary

This document is a study guide on the physiology of the respiratory system. It details the functions and structure of the respiratory system, including external and internal respiration. The mechanisms of breathing, intra-pleural pressure, gas transport, and factors affecting gas diffusion are also discussed.

Full Transcript

PHYSIOLOGY OF THE
RESPIRATORY SYSTEM

By
Doaa Samy
Professor of Physiology
 1- FUNCTION, STRUCTURE OF
RESPIRATORY SYSTEM

* a- Function
* supplies the cells of the body with O2
* removes CO2 produced by cellular activities.

* b- Structure
* it consists of respiratory passages which are the nose,
pharynx, larynx, trachea, bronchi, bronchioles , and area
of gas exchange which contains alveoli.
b- Types of respiration:
* 1- External respiration

* 2- Internal respiration
External respiration

inhalation of O2
and removal of
CO2
 Internal respiration
utilization of O2
and production of
CO2 by cells
(cellular respiration)
6
 External respiration is divided into:

1- Pulmonary ventilation
2- Pulmonary perfusion
3- Diffusion of gases
4- Gas transport
 EXTERNAL RESPIRATION

1-Ventilation 2-Diffusion 3-Perfusion
The inflow and Exchange of (O2 Distribution of
outflow of air and CO2) between blood through
air in alveoli and the lungs
blood
 1- Pulmonary ventilation

inflow and outflow of air between the
atmosphere and the lung alveoli &
distribution of air within the lung
It occurs through breathing movements
Regulated by respiratory centers in the brain
stem
 The Respiratory Airways

Conducting zone

Respiratory zone

The airways consist of a series of branching tubes,
which become narrower, shorter, and more numerous
as they penetrate deeper into the lung
 Functionally, the respiratory system consists
of two zones:

* a- The conducting zone
includes all other respiratory
passageways down to terminal
bronchioles, which conduct air to
reach the gas exchange sites

* b- The respiratory zone.
the actual site of gas exchange
comprises the respiratory
bronchioles, alveolar ducts,
alveolar sacs and alveoli.
 2- FUNCTIONS OF RESPIRATORY PASSAGES 1-
1- FUNCTIONS OF THE CONDUCTING ZONE
* 1- Air conduction.
* 2- Air conditioning
(When the inspired air reaches the respiratory zone, its
temperature is 37° C
(body temperature)
* 3- Humidification of air.
(to protect delicate lung
tissue from damage).
* 4- Immunity
(Secretion of Immunoglobulins)
 2- FUNCTIONS OF RESPIRATORY PASSAGES
FUNCTIONS OF THE CONDUCTING ZONE

* 5- Filtration and cleaning of air.
(Mucus secreted by cells of the conducting zone trap
small particles in the inspired air ).

* 6- Protective reflexes.(cough, sneezing)

* 7- Phonation (sound protection).
(The larynx produces sound When air passes
across it, the vocal cords vibrate à producing
sounds
2- Respiratory zone
Respiratory bronchioles ➔alveolar ducts ➔
alveolar sacs ➔ alveoli
Gas exchange occurs in this part.
Mechanism of breathing
 3- MECHANICS OF Breathing
* a- Inspiration is an active process
* 1- Downward movement
of the diaphragm

* 2- Elevation of the ribs
by contraction of the
external intercostal muscles

* Expansion of the chest cavity ➔ rush of 500
ml (tidal volume) of air into the lungs.
 3- MECHANICS OF BREATHING
* b- Expiration: is a passive processRelaxation of inspiratory muscles

* The thoracic cavity decreases in all dimensions,
and elastic lungs recoil passively, causing 500 ml
of air to flow out of the lungs.

* N.B.
* Forced expiration, as in muscular exercise, is an
active process caused by the contraction of
expiratory muscles, such as abdominal and
internal intercostal muscles.
3- MECHANICS OF BREATHING
 3- MECHANICS OF BREATHING

Expansion of the chest cavity ➔ rush of 500 ml of air into the lungs
Recoil of the lungs ➔ The 500 ml of air rush out of the lungs
 Intra-pleural
Pressure
It is the pressure in the
“potential space” between
the lungs and chest wall
(pleural space). It is a
negative pressure
(sub-atmospheric)
Intra-pleural Pressure

ØCauses of negative IPP:
1. Lack of air in the pleural cavity.
2. Elastic recoil of the lung which tends to collapse the lung. This
is due to: Tendency of lung to collapse
a- the Elastic fibers of the lung tissue, which are continuously
stretched and have recoil tendency.
b-Surface tension of the fluid lining the alveoli.
3. Elastic properties of the chest wall, which tend to expand the
thoracic cage, thus it pulls the parietal pleura outwards.
 Intra-pleural Pressure
ØImportance of negative IPP:
1. It helps the expansion of the lungs. And prevent its collapse expecially in
expiration

2. It is responsible for the negative intrathoracic pressure,
which also helps the venous return to the heart.
Ø In quiet breathing, a healthy
man inspires about 500ml
air/breath (tidal volume)
Ø only 350ml of this volume
reaches and ventilates normal
alveoli.
Ø The remainder 150ml fills the
conducting air passage from the
nose to respiratory bronchioles.
Ø This volume does not take part
in gas exchange with blood.
 Minute Respiratory Volume

Minute Ventilation at rest=
Tidal volume X breathing rate
= 500 ml X 12 b/min
= 6000 ml/min
= 6 L/min

N.B. respiratory rate in adults = 12-20 b/min
It is higher in children
 SURFACTANT
* a- Definition: It is a surface tension-lowering agent,
which decreases the surface tension of the alveolar
fluid.

* b- Site of release: Type II alveolar epithelial cells

* c-Structure: it is composed of phospholipids, proteins
and calcium ions.
Each phospholipid
molecule has a
hydrophilic head and a
hydrophobic tail.

The hydrophilic head
dissolves in water
lining the alveoli, while
the hydrophobic tail is
facing the alveolar air
and doesn't dissolve in
the fluid
 d- Functions of surfactant
* 1- It lowers the surface tension of alveolar fluid.
* 2- It prevents lung collapse during expiration.
* 3- It decreases the work of breathing.
* 4- It keeps the alveoli dry.
Factors affecting the formation of surfactant
Factors that stimulate its formation
-Thyroid hormones.
-Glucocorticoid hormones.

Factors that decrease its formation
-Smoking.
-Insulin.
-Long term inhalation of pure O2.
-Stoppage of the Pulmonary circulation for a long time.
 Effect of surfactant deficiency

* i- In adults, this results in
“increased work of breathing”.

* ii- In preterm infants, this results in
“respiratory distress syndrome”
Infant respiratory distress syndrome
Absence of surfactantà difficult lung expansion at birth

The surface tension is
high with areas of
atelectasis (collapsed
alveoli), the alveoli are
filled with fluid.
 EXTERNAL RESPIRATION

1-Ventilation 2-Diffusion 3-Perfusion
The inflow and Exchange of (O2 Distribution of
outflow of air and CO2) between blood through
air in alveoli and the lungs
blood
 2- Perfusion of the lung

: Distribution of blood
through the lungs.
The normal volume of
blood perusing the
lungs is 5 L/min. =
cardiac output of the
right ventricle.
 3- DIFFUSION OF GASES
(gas transfer at lung)
* a- Definition:
* it is the exchange of O2 and
CO2 between air in the
alveoli and blood in the
pulmonary capillaries
* it is a passive process as it
occurs according to
pressure gradient of gases
across alveolo-capillary
(respiratory) membrane.
b- Factors affecting rate of gas
diffusion across respiratory
membrane:
* 1- Thickness of respiratory membrane.
inversely proportional
* 2- Surface area of the
respiratory membrane.
directly proportional
* 3- Pressure gradient of gases across the
respiratory membrane.
directly proportional
* 4- Solubility of gases in the respiratory
membrane
directly proportional
* 5-Molecular weight (MW) of
gases.
inversely proportional
 4- GAS transport

q blood transports O2 from the lungs to the
tissues and CO2 from the tissues to the
lungs.
q Gas can move from one point to another
by diffusion from high-pressure to low-
pressure
 GAS TRANSPORT
A- O2 transport
* O2 is transported in 2 forms:
1- Dissolved O2: (3%)
Physically dissolved in plasma
It is responsible for O2 tension in the blood
In arterial blood: It causes PO2 = 100 mm Hg.
In venous blood: It causes PO2 = 40 mm Hg.

in arterial blood. in venous blood.
PO2 =100mmHg. PO2 = 40mmHg.
 GAS TRANSPORT
A- O2 transport
* 2- Chemically combined with hemoglobin
(Hb) 97% 100 ml of blood has 15 g of Hemoglobin

i- It is the main form of transport; each molecule of
hemoglobin carries 4 molecules of O2.
II- Each 100 ml arterial blood carries about 20 ml of
O2, but the tissues take only 5 ml O2/min at rest.

20ml/100ml in 15ml/100ml in
arterial blood. venous blood.
O2 Transport from the blood to the cells
capillary

RBC
HB-O2
Cell

Dissolved
O2

Dissolved O2 diffuses to the cells è
decreased PaO2 è release of O2 from HB
Release of O2 from Hb to blood

5 ml O2 then to the cell

Cells
Gas Exchange in Lungs & Tissues
 GAS TRANSPORT
B- CO2 transport
* CO2 is transported in 2 forms:
1- Dissolved CO2: (5%)
Physically dissolved in plasma
It is responsible for CO2 tension in the blood
In arterial blood: It causes PCO2 = 40 mm Hg.
In venous blood: PCO2 = 46 mm Hg.

in arterial blood. in venous blood.
PCO2 = 40 PCO2 = 46
mmHg. mmHg.
 GAS TRANSPORT
B- CO2 transport
2. Chemically combined CO2: (95%)

a. Carbamino compounds: (5%)
It is formed by the combination of CO2 and Hb.

b. Bicarbonate: (90%)
It is the major form by which CO2 is transported
in the blood.
KHCO3 (in the RBCs) & NaHCO3 (in the plasma)
 Tidal CO2
It is the volume of CO2 that is added to each 100
ml of arterial blood during its flow through the
tissues at rest. = 4ml CO2 /100 ml

4 ml CO2
Hypoxia
O2 deficiency at tissue level

Hypoxemia
O2 deficiency in the blood
According to the cause
of hypoxia
 Types of hypoxia

1- Hypoxic hypoxia (decreased arterial
pressure of O2 (PO2). that is caused by:
i- Decreased PO2 in the inspired air as in
high attitude.
iii- Pulmonary diseases (hypoventilation,
defective diffusion & depression of
respiration)
2- Anemic hypoxia (decreased O2 carrying
capacity of Hb).
As in cases of:
i- anemia: with reduced total Hb concentration.

ii- carbon-monoxide (CO) poisoning:
CO has 200 times more affinity to Hb than O2
decreasing the available amount of Hb that can
carry O2.
Carbon-monoxide Hb (Hb-CO is cherry red in
color).
3- Stagnant hypoxia (decreased O2 supply to
the tissue due to slow circulation)
as in cases of heart failure.

4- Histotoxic (cytotoxic) hypoxia (decreased
O2 uptake and utilization by tissues)
as in cyanide poisoning that inhibits cytochrome
oxidase enzyme which is necessary for O2
utilization.
 Cyanosis
Definition:-
bluish discoloration of the skin and mucous membrane
due to an abnormal increase in the amount of
reduced Hb in the blood more than 5 gm/100ml.

Hypoxia with Cyanosis: in hypoxic & stagnant types.
Hypoxia without Cyanosis : in anemic & histotoxic
types.