Respiratory System Lecture Notes PDF

Summary

This document is a lecture on the respiratory system, discussing topics such as the structure and function of the lungs, including bronchi, bronchioles, and alveoli. It also explains the processes of breathing, gas exchange between the lungs and blood, and the transportation of gases throughout the body.

Full Transcript

 Lecture in PHYSIOLOGY
The Respiratory System (B)
By
Prof. Dr. Mohamed Fathy Farag Bayomy
 In the lungs, each bronchus branches into
smaller and smaller tubes termed bronchioles
that end in clusters of small grape-like structures
called alveoli which represent the functional
respiratory units in which gaseous exchange
takes place. The alveoli are lined with a layer
of flat epithelial cells and are surrounded
by a network of blood capillaries.
Alveoli are surrounded by a network of

thin-walled capillaries. Only about 0.2

μm separate the alveoli from the

capillaries due to the extremely thin

walls of both structures.
The walls of the chest region contain the ribs and
the intercostal muscles. Below, the chest region is
separated from the abdominal cavity by the muscular
diaphragm.
Above the diaphragm there are 3 closed cavities;
these are 2 lateral pleural cavities surrounding the
lungs, and the median pericardial cavity that
contains the heart.

Breathing:
The functional parts of the lung for gaseous
exchange, the alveoli, are connected with the
outside air at all times. That is, the nares, the nasal
chambers, pharynx, glottis, larynx, trachea, bronchi,
and bronchioles form a continuous system with the
outside.
 In the trachea, there are horseshoe-shaped cartilages in its wall
which keep it always open. In the bronchi and larger bronchioles,
rings of cartilages function in the same way. So, in such a system,
when cavities surrounding the lungs are enlarged, air rush in.
Because of the pressure of the outside air and the elastic nature of
the lungs: lungs will expand to fill the pleural cavities. That is, the
human breathing mechanism is essentially a suction pump
mechanism. During inspiration, the muscle of the diaphragm
contract, changing it from a dome-like structure to a more flattened
straight sheet that press down on the viscera.
During expiration, the muscles relax, and the diaphragm resumes
its dome-shaped position. Moreover, contraction of the intercostal
muscles and the rise of the ribs during inspiration increases the
diameters of the pleural cavities. In expiration, the ribs return to
their former position, decreasing these diameters of the cavities and
allowing the lungs to force the air out.
External respiration
Oxygen taken in during inhalation diffuses from the
alveoli into the blood, and CO2 in the blood diffuses into
the alveoli, to be given off in exhalation. This process is
purely diffusion. The concentration of O2 in the alveoli is
greater than the concentration of O2 in the blood. The
thin membranes separating the alveoli and the blood are
permeable. Oxygen goes into solution on the moist lining
the alveoli, and diffuses from a region of higher to a
region of lower concentration. The reverse is true for
CO2, and each gas behaves independently.
Transport of O2 and CO2 by the blood
When O2 diffuses into the blood in external
respiration, most of it enters the red blood cells
(erythrocytes), and units with hemoglobin (Hb) in
these cells, forming a compound called
oxyhemoglobin (HbO2). The great affinity of Hb for
O2 enables the blood to carry about 50 times more
O2 than the plasma alone can carry. Therefore,
as the blood passes through the alveolar
capillaries, the Hb becomes saturated with O2.
The reaction may be represented by the following
equation: Hb + O2 HbO2
Hemoglobin Oxygen Oxyhemoglobin
 Oxyhemoglobin (HbO2) is very unstable compound, and when
the blood reaches the capillaries in the tissues where the
tension is low, HbO2 compound breaks down into Hb and O2
and O2 diffuses into the cells.
The difference in color between oxygenated and non-
oxygenated blood is due to HbO2 which is bright scarlet
color whereas Hb (without O2) is dull purple. The property of
Hb to combine reversibly with O2 may be represented by the
oxygen dissociation curve (ODC) which indicates that Hb is
almost completely saturated at an O2 pressure of 100 mmHg.
When the O2 pressure falls below 60 mmHg, the O2
saturation of Hb falls rapidly. Thus, at low O2 pressure,
HbO2 releases its O2 very rapidly. Carbon dioxide affects
the ability of Hb to combine with O2: as CO2 increases the curve
shifts to the right hand side, i.e. % HbO2 decreases.
Figure indicates: The shift of the O2 dissociation curve (ODC) by PCO2.
Effect of pH on O2 transport:
It was found that, HbO2 dissociates more readily in a
more acidic media. Thus, the affinity of O2 for Hb
decreases when the pH is lowered (see the Fig.). This
effect helps in providing more O2 to tissues when CO2
output is increased.
Effect of Temperature (T):
At constant pH values and different T, the affinity of Hb for O2
decreases by a rise in temperature. An increase in T weakens the
bond between Hb and O2, and the HbO2 dissociation curve is shifted
to the right, thus, at higher T, more O2 is delivered to the tissues as
in case of muscles that are warmed during exercise.
CO2 Transport:
Most of the CO2 is transported in the plasma in the form
of bicarbonates, whereas some of it is carried in the red
blood cells in combination with amino groups of the Hb
molecules as carbaminohemoglobin.
In the alveolar capillaries, due to the low CO2 tension
in the alveoli, the bicarbonates and carbaminohemoglobin
liberate CO2. Hemoglobin combines with gases other than
O2 and CO2.
Hydrogen sulphide is a poison as a result of its affinity
for Hb. Carbon monoxide (CO) formed by incomplete
combustion of carbon, combines with Hb to give a stable
compound called carboxyhemoglobin. It diminishes the
amount of O2 that can be carried by the blood, and
therefore, victims of CO poisoning suffer from a lack of O2.
Internal respiration
This process takes place throughout the body.
It is the exchange of gases between the blood
and the cells, with O2 passing from the blood into
cells and CO2 going from the cells into the blood.
This is again a process of diffusion, with each gas
diffusing from a region of its higher concentration
into a region of lower concentration. Actually, O2
does not diffuse directly into the cells, and also
CO2 does not diffuse directly into the blood. The
cells are separated from the capillaries by a film
of lymph, and the gases diffuse through this fluid.
Cellular respiration
As it has been discussed, before, that this is a complex
process including many steps. The energy stored in the
glucose molecule, for example, is released in the step-by-
step process, and this energy is trapped in the formation
of high energy molecules called adenosine triphosphates
(ATP). The ATP is then available for the various requiring
processes in the cell.
 Diseases of the respiratory system
The condition of the airways and the pressure differences between
the lungs and atmosphere are important factors in the flow of air in
and out of lungs.

Many diseases affect the condition of these airways, among these
are:

Asthma: It narrows the airways by causing an allergy-induced
spasms of the surrounding muscles or by clogging the airways with
mucus.

Bronchitis: Is an inflammatory response that reduces airflow and is
caused by long-term exposure to irritants such as cigarette smoke
and air pollutants.

Cystic fibrosis: Is a genetic defect that causes excessive mucus
production that clogs the airways.