Respiratory Physiology PDF

Summary

This document covers the principles of respiratory physiology, with a focus on the respiratory system, outlining its organization, mechanisms, and functions. The document explores ventilation, gas exchange, and the transport of oxygen and carbon dioxide in the body.

Full Transcript

SYSTEMS
PHYSIOLOGY
Respiratory
 Outlines
Organization of the Respiratory System
Ventilation and Lung Mechanics
Exchange of Gases in Alveoli and Tissues
Transport of Oxygen in Blood
Transport of Carbon Dioxide in Blood
Transport of Hydrogen Ion Between Tissues and Lungs
Control of Respiration
Hypoxia
Nonrespiratory Functions of the Lungs
Organization of the Respiratory System
The Airways and Blood Vessels.
 Organization of the Respiratory System
The Airways and Blood Vessels.

Functions of the Conducting Zone of the Airways
Provides a low-resistance pathway for airflow.
Resistance is physiologically regulated by changes in
contraction of bronchiolar smooth muscle and by
physical forces acting upon the airways.
Defends against microbes, toxic chemicals, and other
foreign matter. Cilia, mucus, and macrophages
perform this function.
Warms and moistens the air.
Phonates (vocal cords).
 Organization of the Respiratory System
Site of Gas Exchange: The Alveoli

What consequences would result if
inflammation caused a
buildup of fluid in the alveoli and
interstitial spaces?

Relation of the Lungs to the Thoracic (Chest)
Wall
 Ventilation and Lung Mechanics
Understanding the forces that control the inflation
and deflation of the lung and the flow of air
between the lung and the environment requires
some knowledge of several fundamental physical
laws.

Ventilation is defined as the exchange of air
between the atmosphere and alveoli.
– Like blood, air moves by bulk flow from a
region of high pressure to one of low pressure.
– Bulk flow can be described by the equation:
F=ΔP/R
 Ventilation and Lung Mechanics
A very important point must be made here:
– All pressures in the respiratory system, as in the cardiovascular system, are
given relative to atmospheric pressure, which is 760 mmHg at sea level but
which decreases in proportion to an increase in altitude.

– During ventilation, air moves into and out of the lungs because the alveolar
pressure is alternately less than and greater than atmospheric pressure
(Figure).
 Ventilation and Lung Mechanics
To understand how a change in lung dimensions causes a change in alveolar pressure,
you need to learn one more basic physical principle described by Boyle’s law, which is
represented by the equation P 1 V 1 = P 2 V 2.
 Ventilation and Lung Mechanics
There are no muscles attached to the lung surface to pull the lungs
open or push them shut.
Rather, the lungs are passive elastic structures—like balloons—and
their volume, therefore, depends on other factors.
– The first of these is the difference in pressure between the
inside and outside of the lung, termed the transpulmonary
pressure ( P tp ).
– The second is how stretchable the lungs are, which determines
how much they expand for a given change in P tp.
The pressure inside the lungs is the air pressure inside the alveoli ( P
alv ), and the pressure outside the lungs is the pressure of the
intrapleural fluid surrounding the lungs ( P ip ).
Thus, Transpulmonary pressure
– Ptp= Palv-Pip
 Ventilation and Lung Mechanics
How Is a Stable Balance Achieved Between Breaths?
The transmural pressures of the respiratory system at
rest—that is, at the end of an unforced expiration when
the respiratory muscles are relaxed and there is no
airflow.

At rest, when there is no airflow and P alv = 0, P ip must
be negative, providing the force that keeps the lungs open
and the chest wall in. What are the forces that cause P ip
to be negative?

At rest, all of these transmural pressures balance each other out. It is clear that the subatmospheric. (negative) intrapleural pressure ( P ip ) is the essential factor keeping the lungs partially expanded
between breaths.
An extremely important question is, “What is the reason for a subatmospheric (‘negative’) P ip ?”
 Ventilation and Lung Mechanics
How Is a Stable Balance Achieved Between
Breaths?
The importance of the transpulmonary pressure
in achieving this stable balance can be seen
when, during surgery or trauma, the chest wall is
pierced without damaging the lung.
– Atmospheric air enters the intrapleural
space through the wound, a phenomenon
called pneumothorax, and the intrapleural
pressure increases from -4 mmHg to 0
mmHg. How can a collapsed lung be re-expanded in
a patient with a pneumothorax?
– That is, P ip increases from 4 mmHg lower ( Hint: What changes in P ip and P tp would be
than P atm to a P ip value equal to P atm. needed to re-expand the lung?)
– The transpulmonary pressure acting to hold
the lung open is thus eliminated, and the
lung collapses.
 Ventilation and Lung Mechanics
Inspiration/Expiration
 Ventilation and Lung Mechanics
Inspiration
Inspiration is initiated by the neurally induced
contraction of the diaphragm and the external
intercostal muscles located between the ribs.  The
diaphragm is the most important inspiratory muscle
that acts during normal quiet breathing.
The crucial point is that contraction of the inspiratory
muscles, by actively increasing the size of the thorax,
upsets the stability set up by purely elastic forces
between breaths.
When contraction of the inspiratory muscles actively
increases the thoracic dimensions, the lungs are
passively forced to enlarge.  The enlargement of
the lungs causes an increase in the sizes of the
alveoli throughout the lungs.
 Ventilation and Lung Mechanics
Expiration
At the end of inspiration, the motor neurons to the
diaphragm and inspiratory intercostal muscles
decrease their firing and so these muscles relax.

As the lungs become smaller, air in the alveoli becomes
temporarily compressed so that, by Boyle’s law, alveolar
pressure exceeds atmospheric pressure.

Under certain conditions, such as during exercise, expiration of
larger volumes is achieved by contraction of a different set of
intercostal muscles and the abdominal muscles, which actively
decrease thoracic dimensions.
 Ventilation and Lung Mechanics
Inspiration/Expiration
 Ventilation and Lung Mechanics
Lung Compliance
To repeat, the degree of lung expansion at any instant is
proportional to the transpulmonary pressure, P alv - P ip.
But just how much any given change in transpulmonary pressure
expands the lungs depends upon the stretchability, or
compliance, of the lungs.
– Lung compliance ( C L ) is defined as the magnitude of the
change in lung volume (Δ V L ) produced by a given change
in the transpulmonary pressure:
– CL = ΔVL/ΔPtp
– Thus, the greater the lung compliance, the easier it is to Premature infants with inadequate
expand the lungs at any given change in transpulmonary surfactant have decreased lung
pressure. compliance (respiratory distress syndrome
of the newborn).
If surfactant is not available to administer
Compliance can be considered the inverse of stiffness. for therapy, what can be done to inflate
the lung?
 Ventilation and Lung Mechanics
Lung Compliance
Determinants of Lung Compliance. There are two major determinants of lung compliance.
– One is the stretchability of the lung tissues, particularly their elastic connective tissues.
Thus, a thickening of the lung tissues decreases lung compliance.
– Two the presence of the Surfactant which is a mixture of both lipids and proteins,
Some Important Facts About Pulmonary Surfactant
– Pulmonary surfactant is a mixture of phospholipids and protein.
– It is secreted by type II alveolar cells.
– It lowers the surface tension of the water layer at the alveolar surface, which increases lung
compliance, thereby making it easier for the lungs to expand.
– Its effect is greater in smaller alveoli, thus reducing the surface tension of small alveoli below that
of larger alveoli. This stabilizes the alveoli.
– A deep breath increases its secretion by stretching the type II cells. Its concentration decreases
when breaths are small.
– Production in the fetal lung occurs in late gestation and is stimulated by the increase in cortisol
(glucocorticoid) secretion that occurs then.
 Ventilation and Lung Mechanics
Airway Resistance
The volume of air that flows into or out of the alveoli per unit time is directly proportional to the
pressure difference between the atmosphere and alveoli and is inversely proportional to the resistance
to flow of the airways.
The factors that determine airway resistance are analogous to those determining vascular resistance in
the circulatory system.
Physical, neural, and chemical factors affect airway radii and therefore resistance.
– One important physical factor is the transpulmonary pressure, which exerts a distending force on
the airways, just as on the alveoli.
– A second physical factor holding the airways open is the elastic connective-tissue fibers that link
the outside of the airways to the surrounding alveolar tissue.
Why are we concerned with all the physical and chemical factors that can influence airway resistance
when airway resistance is normally so low that it poses no impediment to airflow?
 Ventilation and
Lung Mechanics
Lung Volumes and Capacities
 Ventilation and Lung Mechanics
Alveolar Ventilation
The total ventilation per minute—( V˙E )—is equal to the tidal volume
multiplied by the respiratory rate: Minute ventilation (mL/min)= Tidal
volume(mL/breath)*Respiratory rate(breaths/min)
– VE=Vt* f

Dead Space

The total volume of fresh air entering the alveoli per minute is called
the alveolar ventilation ( V˙ A ):
Alveolar ventilation (mL/min) = Tidal volume (mL/breath) – Dead space
(mL/breath) * Respiratory rate (breaths/min) What would be the effect of breathing
through a plastic tube with a length of 20
VA = (Vt - VD) * f
cm and diameter of 4 cm?
Alveolar ventilation, rather than minute ventilation, is the more ( Hint: Use the formula for the volume of
important factor in the effectiveness of gas exchange. a perfect cylinder.)
 Ventilation and Lung Mechanics
Alveolar Ventilation
Dead Space
This generalization is demonstrated readily by the data in Table 13.4. In this experiment, subject A breathes
rapidly and shallowly, B normally, and C slowly and deeply.
Each subject has exactly the same minute ventilation; that is, each is moving the same amount of air in and out of
the lungs per minute.
Yet, when we subtract the anatomical-dead-space ventilation from the minute ventilation, we find marked
differences in alveolar ventilation.
Subject A has no alveolar ventilation and would become unconscious in several minutes, whereas C has a
considerably greater alveolar ventilation than B, who is breathing normally.
 Ventilation and Lung Mechanics
Alveolar Ventilation
Dead Space
The anatomical dead space is not the only type of dead space.
Some fresh inspired air is not used for gas exchange with the blood even though it reaches the alveoli
because some alveoli may, for various reasons, have little or no blood supply.
This volume of air is known as alveolar dead space.
It is quite small in healthy persons but may be very large in persons with several kinds of lung disease.
As we shall see, local mechanisms that match air and blood flows minimize the alveolar dead space.
The sum of the anatomical and alveolar dead spaces is known as the physiological dead space.
This is also known as wasted ventilation because it is air that is inspired but does not participate in gas
exchange with blood flowing through the lungs.
 Exchange of Gases in Alveoli and Tissues
Oxygen must move across the alveolar
membranes into the pulmonary capillaries,
be transported by the blood to the tissues,
leave the tissue capillaries and enter the
extracellular fluid, and finally cross plasma
membranes to gain entry into cells.
Carbon dioxide must follow a similar path,
but in reverse.

The balance depends primarily upon which
nutrients are used for energy, because the
enzymatic pathways for metabolizing
carbohydrates, fats, and proteins generate
different amounts of CO 2.
– The ratio of CO 2 produced to O 2
consumed is known as the respiratory
quotient ( RQ )
 Exchange of Gases in Alveoli and Tissues
Partial Pressures of Gases
Gas molecules undergo continuous random motion.
As Dalton’s law states, in a mixture of gases, the pressure each gas
exerts is independent of the pressure the others exert.

The sum of the partial pressures of all these gases is called
atmospheric pressure, or barometric pressure.

Diffusion of Gases in Liquids
– When a liquid is exposed to air containing a particular gas,
molecules of the gas will enter the liquid and dissolve in it.
– Another physical law, called Henry’s law, states that the
amount of gas dissolved will be directly proportional to the
partial pressure of the gas with which the liquid is in
equilibrium.
– A corollary is that, at equilibrium, the partial pressures of the
gas molecules in the liquid and gaseous phases must be
identical.
 Exchange of Gases in Alveoli and Tissues
Alveolar Gas Pressures
Typical alveolar gas pressures are PO2 = 105 mmHg and PCO2 5 40 mmHg.
Alveolar PCO2 is higher than atmospheric PCO2 because carbon dioxide enters the alveoli from the
pulmonary capillaries. The factors that determine the precise value of alveolar PO2 are
– (1) the PO2 of atmospheric air,
– (2) the rate of alveolar ventilation, and
– (3) the rate of total-body oxygen consumption.
 Exchange of Gases in Alveoli and Tissues
Alveolar Gas Pressures
Hypoventilation exists when there is an
increase in the ratio of carbon dioxide
production to alveolar ventilation. In other
words, a person is hypoventilating if the alveolar
ventilation cannot keep pace with the carbon dioxide
production. The result is that alveolar PCO2 increases
above the normal value.
Hyperventilation exists when there is a
decrease in the ratio of carbon dioxide
production to alveolar ventilation, that is,
when alveolar ventilation is actually too great
for the amount of carbon dioxide being
produced. The result is that alveolar PCO2
decreases below the normal value.
 Exchange of Gases in Alveoli and Tissues
Gas Exchange Between Alveoli and Blood
The blood that enters the pulmonary capillaries is systemic venous blood pumped
to the lungs through the pulmonary arteries.
The differences in the partial pressures of oxygen and carbon dioxide on the two
sides of the alveolar-capillary membrane result in the net diffusion of oxygen from
alveoli to blood and of carbon dioxide from blood to alveoli.

The net diffusion of these gases ceases when the capillary partial pressures become
equal to those in the alveoli.
 Exchange of Gases in Alveoli and Tissues
Gas Exchange Between Alveoli and Blood
In a healthy person, the rates at which oxygen and carbon dioxide
diffuse are high enough and the blood flow through the capillaries
slow enough that complete equilibrium is reached well before the
blood reaches the end of the capillaries.

Many of the pulmonary capillaries at the apex (top) of each lung
are normally closed at rest.
During exercise, these capillaries open and receive blood, thereby
enhancing gas exchange.
What is the effect of
The mechanism by which this occurs is a simple physical one; exercise on PO2 at the end of
– the pulmonary circulation at rest is at such a low blood a capillary in a normal
pressure that the pressure in these apical capillaries is region of the lung?
inadequate to keep them open, In a region of the lung with
diffusion limitation due to
– but the increased cardiac output of exercise increases
disease?
pulmonary vascular pressures, which opens these capillaries.
 Exchange of Gases in Alveoli and Tissues
Matching of Ventilation and Blood Flow in Alveoli
The major disease-induced cause of inadequate oxygen movement between alveoli
and pulmonary capillary blood is not a problem with diffusion but, instead, is due
to the mismatching of the air supply and blood supply in individual alveoli.

The lungs are composed of approximately 300 million alveoli, each capable of
receiving carbon dioxide from, and supplying oxygen to, the pulmonary capillary
blood. To be most efficient, the correct proportion of alveolar airflow (ventilation)
and capillary blood flow (perfusion) should be available to each alveolus. Any
mismatching is termed ventilation–perfusion inequality.

– The major effect of ventilation–perfusion inequality is to decrease the PO2 of
systemic arterial blood.
 Exchange of Gases in Alveoli and Tissues
Matching of Ventilation and Blood Flow in Alveoli
There are several local homeostatic responses within the
lungs that minimize the mismatching of ventilation and
blood flow and thereby maximize the efficiency of gas
exchange.

The net adaptive effects of vasoconstriction and
bronchoconstriction are to
– (1) supply less blood flow to poorly ventilated areas, thus
diverting blood flow to well-ventilated areas; and
– (2) redirect air away from diseased or damaged alveoli
and toward healthy alveoli.
– These factors greatly improve the efficiency of pulmonary
gas exchange, but they are not perfect even in the healthy
lung.
– There is always a small mismatch of ventilation and
perfusion, which, as just described, leads to the normal
alveolar-arterial O2 gradient of about 5 mmHg.
 Transport of Oxygen in Blood
Each liter normally contains the number of oxygen molecules
equivalent to 200 mL of pure gaseous oxygen at atmospheric
pressure. The oxygen is present in two forms:
– (1) dissolved in the plasma and erythrocyte cytosol and
– (2) reversibly combined with hemoglobin molecules in the
erythrocytes.

As predicted by Henry’s law, the amount of oxygen dissolved in blood is
directly proportional to the PO2 of the blood.

hemoglobin can exist in one of two forms—deoxyhemoglobin ( Hb ) and
oxyhemoglobin ( HbO 2 ). In a blood sample containing many
hemoglobin molecules, the fraction of all the hemoglobin in the form of
oxyhemoglobin is expressed as the percent hemoglobin saturation.

The denominator in this equation is also termed the oxygen-carrying
capacity of the blood.
 Transport of Oxygen in Blood
What factors determine the percent hemoglobin saturation?
By far the most important is the blood PO2.
However, it must be stressed that the total amount of oxygen carried by hemoglobin in the blood depends not only
on the percent saturation of hemoglobin but also on how much hemoglobin is in each liter of blood.
– A significant decrease in hemoglobin in the blood is called anemia.

What Is the Effect of PO2 on Hemoglobin
Saturation?
It is evident that increasing the blood PO2
should increase the combination of oxygen
with hemoglobin.
The quantitative relationship between these
variables is called an oxygen–hemoglobin
dissociation curve.
 Transport of Oxygen in Blood
What Is the Effect of PO2 on Hemoglobin Saturation?
We now retrace our steps and reconsider the movement of oxygen across the various membranes, this
time including hemoglobin in our analysis.
 Transport of Oxygen in Blood
What Is the Effect of PO2 on Hemoglobin Saturation?
Let us now apply this analysis to capillaries of the lungs and tissues.
 Transport of Oxygen in Blood
What Is the Effect of PO2 on Hemoglobin Saturation?
Effect of Carbon Monoxide on Oxygen Binding to Hemoglobin Carbon monoxide is a colorless,
odorless gas that is a product of the incomplete combustion of hydrocarbons, such as gasoline.
– It is one of the more common causes of sickness and death due to poisoning, both intentional
and accidental.
– Its most striking pathophysiological characteristic is its extremely high affinity—210 times that
of oxygen—for the oxygen-binding sites in hemoglobin.
– For this reason, it reduces the amount of oxygen that combines with hemoglobin in pulmonary
capillaries by competing for these sites.
– It also exerts a second deleterious effect: It alters the hemoglobin molecule so as to shift the
oxygen–hemoglobin dissociation curve to the left, thus decreasing the unloading of oxygen from
hemoglobin in the tissues.
– The situation is worsened by the fact that persons suffering from carbon monoxide poisoning do
not show any reflex increase in their ventilation.
 Transport of Oxygen in Blood
Effects of CO 2 and Other Factors in the Blood and Different Isoforms on Hemoglobin Saturation

Researchers are developing
blood substitutes to meet
the demand for emergency
transfusions. What would
be the effect of artificial
blood in which binding of O 2
is not altered by acidity?
 Transport of Carbon Dioxide in Blood
Remember that CO 2 is a waste product that has toxicity in part because it generates H+.
 Transport of Hydrogen Ion Between Tissues and Lungs
As blood flows through the tissues, a fraction
of oxyhemoglobin loses its oxygen to become
deoxyhemoglobin, while simultaneously a
large quantity of carbon dioxide enters the
blood and undergoes the reactions that
generate HCO3- and H+. What happens to this
H1?
Deoxyhemoglobin has a much greater affinity
for H+ than does oxyhemoglobin, so it binds
(buffers) most of the H+. When
deoxyhemoglobin binds H, it is abbreviated
HbH.
 Control of Respiration
The control of breathing at rest, altitude, and during and after exercise has intrigued physiologists for centuries.
It is a wonderful example of several general principles of physiology, including how homeostasis is essential for
health and survival, and how physiological functions are controlled by multiple regulatory systems, often working
in opposition.
Neural Generation of Rhythmic Breathing
The diaphragm and intercostal muscles are skeletal muscles and therefore do not contract unless motor neurons
stimulate them to do so.
Thus, breathing depends entirely upon cyclical respiratory muscle excitation of the diaphragm and the intercostal
muscles by their motor neurons.
Destruction of these neurons or a disconnection between their origin in the brain stem and the respiratory
muscles results in paralysis of the respiratory muscles and death, unless some form of artificial respiration can be
instituted.
Inspiration is initiated by a burst of action potentials in the spinal motor neurons to inspiratory muscles like the
diaphragm.
Then the action potentials cease, the inspiratory muscles relax, and expiration occurs as the elastic lungs recoil.
In situations such as exercise when the contraction of expiratory muscles facilitates expiration, the neurons to
these muscles, which were not active during inspiration, begin firing during expiration.
 Control of Respiration
Neural Generation of Rhythmic Breathing
By what mechanism are impulses in the neurons
innervating the respiratory muscles alternately increased
and decreased?
– The respiratory rhythm generator is located in the pre-
Bötzinger complex of neurons in the upper part of the
VRG
– The medullary inspiratory neurons receive a rich
synaptic input from neurons in various areas of the
pons, the part of the brainstem just above the medulla.
– Another cutoff signal for inspiration comes from pulmonary
stretch receptors, which lie in the airway smooth muscle
layer and are activated by a large lung inflation. This is called
the Hering–Breuer reflex.
– The arterial chemoreceptors also have important input to the
respiratory control centers.
– A final point about the medullary inspiratory neurons is that
they are quite sensitive to inhibition by drugs such as
barbiturates and morphine.
 Control of Respiration
Control of Ventilation by PO2, PCO2 , and H+ Concentration

Several decades ago, removal of the carotid
bodies was tried as a treatment for asthma. It
was thought that it would reduce shortness of
breath and airway hyperreactivity. What would
be the effect of bilateral carotid body removal on
someone taking a trip to the top of a mountain
(an altitude of 3000 meters)?
 Control of Respiration
Control of Ventilation by PO2, PCO2 , and H+ Concentration
Control by PO2
 Control of Respiration
Control of Ventilation by PO2, PCO2 , and H+ Concentration
Control by PCO2
 Control of Respiration
Control of Ventilation by PO2, PCO2 , and H+ Concentration
Control by Changes in Arterial H+ Concentration That Are Not Due to
Changes in Carbon Dioxide
 Control of Respiration
Control of Ventilation by PO2, PCO2
, and H+ Concentration
 Control of Respiration

Control of Ventilation During Exercise
During exercise, the alveolar ventilation may increase
as much as 20-fold.
On the basis of our three variables— PO2, PCO2, and
H+ concentration—it may seem easy to explain the
mechanism that induces this increased ventilation.
This is not the case, however, and the major stimuli to
ventilation during exercise, at least moderate exercise,
remain unclear.
 Control of Respiration
Control of Ventilation During Exercise
Other Factors
A variety of other factors play some role in stimulating ventilation
during exercise. These include:
(1) reflex input from mechanoreceptors in joints and muscles,
(2) an increase in body temperature,
(3) inputs to the respiratory neurons via branches from axons
descending from the brain to motor neurons supplying the
exercising muscles (central command),
(4) an increase in the plasma epinephrine concentration,
(5) an increase in the plasma potassium concentration due to
movement of potassium out of the exercising muscles, and
(6) a conditioned (learned) response mediated by neural input to
the respiratory centers.
 Control of Respiration
Control of Ventilation During Exercise

The existence of
chemoreceptors in the
pulmonary artery has been
suggested. Hypothesize a
function for peripheral
chemoreceptors located on and
sensing the PO2 and PCO2 of the
blood in the pulmonary artery.
 Hypoxia
Hypoxia is defined as a deficiency of oxygen at the tissue level.
There are many potential causes of hypoxia, but they can be
classified into four general categories:
– (1) hypoxic hypoxia (also termed hypoxemia ), in which the
arterial PO2 is reduced;

– (2) anemic hypoxia or carbon monoxide hypoxia, in which
the arterial PO2 is normal but the total oxygen content of the
blood is reduced because of inadequate numbers of
erythrocytes, deficient or abnormal hemoglobin, or
competition for the hemoglobin molecule by carbon
monoxide;

– (3) ischemic hypoxia (also called hypoperfusion hypoxia ), in
which blood flow to the tissues is too low;

– (4) histotoxic hypoxia, in which the quantity of oxygen
reaching the tissues is normal but the cell is unable to utilize
the oxygen because a toxic agent— cyanide, for example—
has interfered with the cell’s metabolic machinery.
 Hypoxia
Why Do Ventilation–Perfusion Abnormalities Affect O 2 More Than CO 2 ?
Ventilation–perfusion inequalities often cause hypoxemia without associated
increases in PCO2.
The explanation for this resides in the fundamental difference between the transport
of O 2 and the transport of CO 2 in the blood.
An increase in PO2 above 100 mmHg does not add much oxygen to hemoglobin that
is already almost 100% saturated.
The situation for CO 2 , however, is very different. The CO 2 content curve is
relatively linear because CO 2 is transported in the blood mainly as highly soluble
HCO3- , which does not reach saturating levels at physiological concentrations.
The net result, as blood mixes in the pulmonary vein in this case, is essentially
normal arterial CO 2 content and PCO2.
Thus, clinically significant ventilation–perfusion mismatching can lead to low arterial
PO2 with normal PCO2.
 Hypoxia
Emphysema
The pathophysiology of emphysema, a major cause of hypoxia, offers an instructive review of many
basic principles of respiratory physiology.
Emphysema is characterized by a loss of elastic tissue and the destruction of the alveolar walls
leading to an increase in compliance.

Acclimatization to High Altitude
Atmospheric pressure progressively decreases as altitude increases.
– Therefore, the alveolar and arterial PO2 must decrease as persons ascend unless they breathe
pure oxygen.
The effects of oxygen deprivation vary from one individual to another, but most people who ascend
rapidly to altitudes above 10,000 ft experience some degree of mountain sickness (altitude sickness).
Over the course of several days, the symptoms of mountain sickness usually disappear, although
maximal physical capacity remains reduced.
Acclimatization to high altitude is achieved by the compensatory mechanisms.
 Non-respiratory Functions of the Lungs
The lungs perform a variety of functions in addition to their roles in gas exchange
and regulation of H+ concentration.

Most notable are the influences they have on the arterial concentrations of a large
number of biologically active substances.

In contrast, the lungs may also produce new substances and add them to the blood.

Finally, the lungs also act as a sieve that traps small blood clots generated in the
systemic circulation, thereby preventing them from reaching the systemic arterial
blood where they could occlude blood vessels in other organs.
 Functions of the Respiratory System
Conclusion
– Provides oxygen
– Eliminates carbon dioxide
– Regulates the blood’s hydrogen ion concentration (pH) in
coordination with the kidneys
– Forms speech sounds (phonation)
– Defends against microbes
– Influences arterial concentrations of chemical messengers by
removing some from pulmonary capillary blood and producing and
adding others to this blood
– Traps and dissolves blood clots arising from systemic veins such as
those in the legs