Respiratory System Notes PDF

Summary

These notes provide a detailed overview of the human respiratory system. Topics covered include the structures and functions of the conducting zone, such as the nose and its adjacent structures, the pharynx, larynx, and trachea. The notes also discuss the role of the respiratory system in gas exchange and the mechanisms of breathing.

Full Transcript

Structures that make up the Respiratory System

Functionally, the respiratory system can be divided into a conducting zone and a
respiratory zone. The conducting zone of the respiratory system includes the organs and
structures not directly involved in gas exchange. The gas exchange occurs in the
respiratory zone.

Conducting Zone
The major functions of the conducting zone are to provide a route for incoming and
outgoing air, remove debris and pathogens from the incoming air, and warm and humidify
the incoming air. Several structures within the conducting zone perform other functions as
well. The epithelium of the nasal passages, for example, is essential to sensing odors, and
the bronchial epithelium that lines the lungs can metabolize some airborne carcinogens.

The Nose and its Adjacent Structures

The major entrance and exit for the respiratory system is through the nose. When
discussing the nose, it is helpful to divide it into two major sections: the external nose, and
the nasal cavity or internal nose.

The external nose consists of the surface and skeletal structures that result in the outward
appearance of the nose and contribute to its numerous functions. The root is the region of
the nose located between the eyebrows. The bridge is the part of the nose that connects
the root to the rest of the nose. The dorsum nasi is the length of the nose. The apex is the
tip of the nose. On either side of the apex, the nostrils are formed by the alae (singular =
ala). An ala is a cartilaginous structure that forms the lateral side of each naris (plural =
nares), or nostril opening. The philtrum is the concave surface that connects the apex of
the nose to the upper lip.

The conchae, meatuses, and paranasal sinuses are lined by respiratory epithelium
composed of pseudostratified ciliated columnar epithelium. The epithelium contains
goblet cells, one of the specialized, columnar epithelial cells that produce mucus to trap
debris. The cilia of the respiratory epithelium help remove the mucus and debris from the
nasal cavity with a constant beating motion, sweeping materials towards the throat to be
swallowed. Interestingly, cold air slows the movement of the cilia, resulting in
accumulation of mucus that may in turn lead to a runny nose during cold weather. This
moist epithelium functions to warm and humidify incoming air. Capillaries located just
beneath the nasal epithelium warm the air by convection. Serous and mucus-producing
cells also secrete the lysozyme enzyme and proteins called defensins, which have
antibacterial properties. Immune cells that patrol the connective tissue deep to the
respiratory epithelium provide additional protection.

Pharynx

The pharynx is a tube formed by skeletal muscle and lined by mucous membrane that is
continuous with that of the nasal cavities. The pharynx is divided into three major regions:
the nasopharynx, the oropharynx, and the laryngopharynx.

Larynx

The larynx is a cartilaginous structure inferior to the laryngopharynx that connects the
pharynx to the trachea and helps regulate the volume of air that enters and leaves the
lungs.

The structure of the larynx is formed by several pieces of cartilage. Three large cartilage
pieces—the thyroid cartilage (anterior), epiglottis (superior), and cricoid cartilage
(inferior)—form the major structure of the larynx. The thyroid cartilage is the largest piece
of cartilage that makes up the larynx.

The thyroid cartilage consists of the laryngeal prominence, or “Adam’s apple,” which tends
to be more prominent in males. The thick cricoid cartilage forms a ring, with a wide
posterior region and a thinner anterior region. Three smaller, paired cartilages—the
arytenoids, corniculates, and cuneiforms—attach to the epiglottis and the vocal cords and
muscle that help move the vocal cords to produce speech.

The epiglottis, attached to the thyroid cartilage, is a very flexible piece of elastic cartilage
that covers the opening of the trachea. When in the “closed” position, the unattached end
of the epiglottis rests on the glottis. The glottis is composed of the vestibular folds, the true
vocal cords, and the space between these folds. A vestibular fold, or false vocal cord, is
one of a pair of folded sections of mucous membrane.

A true vocal cord is one of the white, membranous folds attached by muscle to the
thyroid and arytenoid cartilages of the larynx on their outer edges. The inner edges of the
true vocal cords are free, allowing oscillation to produce sound.
Trachea

The trachea (windpipe) extends from the larynx toward the lungs. The trachea is formed by
16 to 20 stacked, C-shaped pieces of hyaline cartilage that are connected by dense
connective tissue. The trachealis muscle and elastic connective tissue together form the
fibroelastic membrane, a flexible membrane that closes the posterior surface of the
trachea, connecting the C-shaped cartilages.

The fibroelastic membrane allows the trachea to stretch and expand slightly during
inhalation and exhalation, whereas the rings of cartilage provide structural support and
prevent the trachea from collapsing. In addition, the trachealis muscle can be contracted
to force air through the trachea during exhalation. The trachea is lined with
pseudostratified ciliated columnar epithelium, which is continuous with the larynx. The
esophagus borders the trachea posteriorly.

Bronchial Tree

The trachea branches into the right and left primary bronchi at the carina. These bronchi
are also lined by pseudostratified ciliated columnar epithelium containing mucus-
producing goblet cells.

The carina is a raised structure that contains specialized nervous tissue that induces
violent coughing if a foreign body, such as food, is present.

The main function of the bronchi, like other conducting zone structures, is to provide a
passageway for air to move into and out of each lung. In addition, the mucous membrane
traps debris and pathogens.

A bronchiole branches from the tertiary bronchi. Bronchioles, which are about 1 mm in
diameter, further branch until they become the tiny terminal bronchioles, which lead to the
structures of gas exchange. There are more than 1000 terminal bronchioles in each lung.
The muscular walls of the bronchioles do not contain cartilage like those of the bronchi.
This muscular wall can change the size of the tubing to increase or decrease airflow
through the tube.

Respiratory Zone

In contrast to the conducting zone, the respiratory zone includes structures that are
directly involved in gas exchange. The respiratory zone begins where the terminal
bronchioles join a respiratory bronchiole, the smallest type of bronchiole, which then leads
to an alveolar duct, opening into a cluster of alveoli.

Alveoli

An alveolar duct is a tube composed of smooth muscle and connective tissue, which
opens into a cluster of alveoli. An alveolus is one of the many small, grape-like sacs that
are attached to the alveolar ducts.

An alveolar sac is a cluster of many individual alveoli that are responsible for gas
exchange. An alveolus is approximately 200 mm in diameter with elastic walls that allow
the alveolus to stretch during air intake, which greatly increases the surface area available
for gas exchange. Alveoli are connected to their neighbors by alveolar pores, which help
maintain equal air pressure throughout the alveoli and lung.

The alveolar wall consists of three major cell types: type I alveolar cells, type II alveolar
cells, and alveolar macrophages.

A type I alveolar cell is a squamous epithelial cell of the alveoli, which constitute up to 97
percent of the alveolar surface area. These cells are about 25 nm thick and are highly
permeable to gases.

A type II alveolar cell is interspersed among the type I cells and secretes pulmonary
surfactant, a substance composed of phospholipids and proteins that reduces the surface
tension of the alveoli. Roaming around the alveolar wall is the alveolar macrophage, a
phagocytic cell of the immune system that removes debris and pathogens that have
reached the alveoli.

Asthma is common condition that affects the lungs in both adults and children.

Asthma is a chronic disease characterized by inflammation and edema of the airway, and
bronchospasms (that is, constriction of the bronchioles), which can inhibit air from
entering the lungs. In addition, excessive mucus secretion can occur, which further
contributes to airway occlusion. Cells of the

immune system, such as eosinophils and mononuclear cells, may also be involved in
infiltrating the walls of the bronchi and bronchioles.
Bronchospasms occur periodically and lead to an “asthma attack.” An attack may be
triggered by environmental factors such as dust, pollen, pet hair, or dander, changes in the
weather, mold, tobacco smoke, and respiratory infections, or by exercise and stress.

Symptoms of an asthma attack involve coughing, shortness of breath, wheezing, and
tightness of the chest. Symptoms of a severe asthma attack that requires immediate
medical attention would include difficulty breathing that results in blue (cyanotic) lips or
face, confusion, drowsiness, a rapid pulse, sweating, and severe anxiety. The severity of
the condition, frequency of attacks, and identified triggers influence the type of medication
that an individual may require. Longer-term treatments are used for those with more
severe asthma. Short-term, fast-acting drugs that are used to treat an asthma attack are
typically administered via an inhaler. For young children or individuals who have difficulty
using an inhaler, asthma medications can be administered via a nebulizer.

In many cases, the underlying cause of the condition is unknown. However, recent
research has demonstrated that certain viruses, such as human rhinovirus C (HRVC), and
the bacteria Mycoplasma pneumoniae and Chlamydia pneumoniae that are contracted in
infancy or early childhood, may contribute to the development of many cases of asthma.

he Lungs

The lungs are pyramid-shaped, paired organs that are connected to the trachea by the right
and left bronchi; on the inferior surface, the lungs are bordered by the diaphragm. The
diaphragm is the flat, dome-shaped muscle located at the base of the lungs and thoracic
cavity. The lungs are enclosed by the pleurae, which are attached to the mediastinum. The
right lung is shorter and wider than the left lung, and the left lung occupies a smaller
volume than the right. The cardiac notch is an indentation on the surface of the left lung,
and it allows space for the heart (Figure 1). The apex of the lung is the superior region,
whereas the base is the opposite region near the diaphragm. The costal surface of the lung
borders the ribs. The mediastinal surface faces the midline.

Each lung is composed of smaller units called lobes. Fissures separate these lobes from
each other. The right lung consists of three lobes: the superior, middle, and inferior lobes.
The left lung consists of two lobes: the superior and inferior lobes. A bronchopulmonary
segment is a division of a lobe, and each lobe houses multiple bronchopulmonary
segments. Each segment receives air from its own tertiary bronchus and is supplied with
blood by its own artery.
Some diseases of the lungs typically affect one or more bronchopulmonary segments, and
in some cases, the diseased segments can be surgically removed with little influence on
neighboring segments. A pulmonary lobule is a subdivision formed as the bronchi branch
into bronchioles. Each lobule receives its own large bronchiole that has multiple branches.
An interlobular septum is a wall, composed of connective tissue, which separates lobules
from one another.

Blood Supply

The major function of the lungs is to perform gas exchange, which requires blood from the
pulmonary circulation. This blood supply contains deoxygenated blood and travels to the
lungs where erythrocytes, also known as red blood cells, pick up oxygen to be transported
to tissues throughout the body. The pulmonary artery is an artery that arises from the
pulmonary trunk and carries deoxygenated, arterial blood to the alveoli. The pulmonary
artery branches multiple times as it follows the bronchi, and each branch becomes
progressively smaller in diameter. One arteriole and an accompanying venule supply and
drain one pulmonary lobule. As they near the alveoli, the pulmonary arteries become the
pulmonary capillary network. The pulmonary capillary network consists of tiny vessels with
very thin walls that lack smooth muscle fibers. The capillaries branch and follow the
bronchioles and structure of the alveoli. It is at this point that the capillary wall meets the
alveolar wall, creating the respiratory membrane. Once the blood is oxygenated, it drains
from the alveoli by way of multiple pulmonary veins, which exit the lungs through the
hilum.
Nervous Innervation

Dilation and constriction of the airway are achieved through nervous control by the
parasympathetic and sympathetic nervous systems. The parasympathetic system causes
bronchoconstriction, whereas the sympathetic nervous system stimulates
bronchodilation.

Reflexes such as coughing, and the ability of the lungs to regulate oxygen and carbon
dioxide levels, also result from this autonomic nervous system control. Sensory nerve
fibers arise from the vagus nerve, and from the second to fifth thoracic ganglia. The
pulmonary plexus is a region on the lung root formed by the entrance of the nerves at the
hilum. The nerves then follow the bronchi in the lungs and branch to innervate muscle
fibers, glands, and blood vessels.
Pleura of the Lungs

Each lung is enclosed within a cavity that is surrounded by the pleura. The pleura (plural =
pleurae) is a serous membrane that surrounds the lung. The right and left pleurae, which
enclose the right and left lungs, respectively, are separated by the mediastinum. The
pleurae consist of two layers. The visceral pleura is the layer that is superficial to the
lungs, and extends into and lines the lung fissures (Figure 2). In contrast, the parietal
pleura is the outer layer that connects to the thoracic wall, the mediastinum, and the
diaphragm. The visceral and parietal pleurae connect to each other at the hilum. The
pleural cavity is the space between the visceral and parietal layers.

The pleurae perform two major functions: They produce pleural fluid and create cavities
that separate the major organs. Pleural fluid is secreted by mesothelial cells from both
pleural layers and acts to lubricate their surfaces. This lubrication reduces friction
between the two layers to prevent trauma during breathing, and creates surface tension
that helps maintain the position of the lungs against the thoracic wall. This adhesive
characteristic of the pleural fluid causes the lungs to enlarge when the thoracic wall
expands during ventilation, allowing the lungs to fill with air. The pleurae also create a
division between major organs that prevents interference due to the movement of the
organs, while preventing the spread of infection.

The Process of Breathing
Pulmonary ventilation is the act of breathing, which can be described as the movement of
air into and out of the lungs. The major mechanisms that drive pulmonary ventilation are
atmospheric pressure (Patm); the air pressure within the alveoli, called alveolar pressure
(Palv); and the pressure within the pleural cavity, called intrapleural pressure (Pip).

· Mechanisms of Breathing

Pressure Relationships

Inspiration (or inhalation) and expiration (or exhalation) are dependent on the differences
in pressure between the atmosphere and the lungs.

In a gas, pressure is a force created by the movement of gas molecules that are confined.
For example, a certain number of gas molecules in a two-liter container has more room
than the same number of gas molecules in a one-liter container. In this case, the force
exerted by the movement of the gas molecules against the walls of the two-liter container
is lower than the force exerted by the gas molecules in the one-liter container. Therefore,
the pressure is lower in the two-liter container and higher in the one-liter container. At a
constant temperature, changing the volume occupied by the gas changes the pressure, as
does changing the number of gas molecules.

Boyle’s law describes the relationship between volume and pressure in a gas at a
constant temperature. Boyle discovered that the pressure of a gas is inversely proportional
to its volume: If volume increases, pressure decreases. Likewise, if volume decreases,
pressure increases. Pressure and volume are inversely related
Therefore, the pressure in the one-liter container (one-half the volume of the two-liter
container) would be twice the pressure in the two-liter container. Boyle’s law is expressed
by the following formula:

P 1V 1 = P 2V 2

Atmospheric pressure is the amount of force that is exerted by gases in the air
surrounding any given surface, such as the body. Atmospheric pressure can be expressed
in terms of the unit atmosphere, abbreviated atm, or in millimeters of mercury (mm Hg).
One atm is equal to 760 mm Hg, which is the atmospheric pressure at sea level.

Intra-alveolar pressure is the pressure of the air within the alveoli, which changes during
the different phases of breathing (Figure 2). Because the alveoli are connected to the
atmosphere via the tubing of the airways (similar to the two- and one-liter containers in the
example above), the interpulmonary pressure of the alveoli always equalizes with the
atmospheric pressure.

Intrapleural pressure is the pressure of the air within the pleural cavity, between the
visceral and parietal pleurae. Similar to intra-alveolar pressure, intrapleural pressure also
changes during the different phases of breathing. However, due to certain characteristics
of the lungs, the intrapleural pressure is always lower than, or negative to, the intra-
alveolar pressure (and therefore also to atmospheric pressure). Although it fluctuates
during inspiration and expiration, intrapleural pressure remains approximately –4 mm Hg
throughout the breathing cycle.

Transpulmonary pressure is the difference between the intrapleural and intra-alveolar
pressures, and it determines the size of the lungs. A higher transpulmonary pressure
corresponds to a larger lung.
Pulmonary Ventilation

The difference in pressures drives pulmonary ventilation because air flows down a
pressure gradient, that is, air flows from an area of higher pressure to an area of lower
pressure. Air flows into the lungs largely due to a difference in pressure; atmospheric
pressure is greater than intra-alveolar pressure, and intra-alveolar pressure is greater than
intrapleural pressure. Air flows out of the lungs during expiration based on the same
principle; pressure within the lungs becomes greater than the atmospheric pressure.

Pulmonary ventilation comprises two major steps: inspiration and expiration. Inspiration
is the process that causes air to enter the lungs, and expiration is the process that causes
air to leave the lungs (Figure 3). A respiratory cycle is one sequence of inspiration and
expiration.

Respiratory Volumes and Capacities

Respiratory volume is the term used for various volumes of air moved by or associated
with the lungs at a given point in the respiratory cycle. There are four major types of
respiratory volumes: tidal, residual, inspiratory reserve, and expiratory reserve (Figure 4).

Tidal volume (TV) is the amount of air that normally enters the lungs during quiet
breathing, which is about 500 milliliters. Expiratory reserve volume (ERV) is the amount of
air you can forcefully exhale past a normal tidal expiration, up to 1200 milliliters for men.
Inspiratory reserve volume (IRV) is produced by a deep inhalation, past a tidal
inspiration. This is the extra volume that can be brought into the lungs during a forced
inspiration. Residual volume (RV) is the air left in the lungs if you exhale as much air as
possible. The residual volume makes breathing easier by preventing the alveoli from
collapsing. Respiratory volume is dependent on a variety of factors, and measuring the
different types of respiratory volumes can provide important clues about a person’s
respiratory health (see Table 1).
Respiratory Rate and Control of Ventilation

Breathing usually occurs without thought, although at times you can consciously control it,
such as when you swim under water, sing a song, or blow bubbles. The respiratory rate is
the total number of breaths, or respiratory cycles, that occur each minute. Respiratory rate
can be an important indicator of disease, as the rate may increase or decrease during an
illness or in a disease condition. The respiratory rate is controlled by the respiratory center
located within the medulla oblongata in the brain, which responds primarily to changes in
carbon dioxide, oxygen, and pH levels in the blood.

The normal respiratory rate of a child decreases from birth to adolescence. A child under 1
year of age has a normal respiratory rate between 30 and 60 breaths per minute, but by the
time a child is about 10 years old, the normal rate is closer to 18 to 30. By adolescence, the
normal respiratory rate is similar to that of adults, 12 to 18 breaths per minute.
· Ventilation Control Centers

The control of ventilation is a complex interplay of multiple regions in the brain that signal
the muscles used in pulmonary ventilation to contract (Table 2). The result is typically a
rhythmic, consistent ventilation rate that provides the body with sufficient amounts of
oxygen, while adequately removing carbon dioxide.

Factors That Affect the Rate and Depth of Respiration
The respiratory rate and the depth of inspiration are regulated by the medulla oblongata
and pons; however, these regions of the brain do so in response to systemic stimuli. It is a
dose-response, positive-feedback relationship in which the greater the stimulus, the
greater the response. Thus, increasing stimuli results in forced breathing. Multiple
systemic factors are involved in stimulating the brain to produce pulmonary ventilation.

DISORDERS OF THE RESPIRATORY SYSTEM: SLEEP APNEA

Sleep apnea is a chronic disorder that can occur in children or adults, and is characterized
by the cessation of breathing during sleep. These episodes may last for several seconds or
several minutes, and may differ in the frequency with which they are experienced. Sleep
apnea leads to poor sleep, which is reflected in the symptoms of fatigue, evening napping,
irritability, memory problems, and morning headaches. In addition, many individuals with
sleep apnea experience a dry throat in the morning after waking from sleep, which may be
due to excessive snoring.

There are two types of sleep apnea: obstructive sleep apnea and central sleep apnea.
Obstructive sleep apnea is caused by an obstruction of the airway during sleep, which can
occur at different points in the airway, depending on the underlying cause of the
obstruction. For example, the tongue and throat muscles of some individuals with
obstructive sleep apnea may relax excessively, causing the muscles to push into the
airway. Another example is obesity, which is a known risk factor for sleep apnea, as excess
adipose tissue in the neck region can push the soft tissues towards the lumen of the
airway, causing the trachea to narrow.

Gas Exchange

The purpose of the respiratory system is to perform gas exchange. Pulmonary ventilation
provides air to the alveoli for this gas exchange process. At the respiratory membrane,
where the alveolar and capillary walls meet, gases move across the membranes, with
oxygen entering the bloodstream and carbon dioxide exiting. It is through this mechanism
that blood is oxygenated and carbon dioxide, the waste product of cellular respiration, is
removed from the body.
External Respiration

The pulmonary artery carries deoxygenated blood into the lungs from the heart, where it
branches and eventually becomes the capillary network composed of pulmonary
capillaries.

These pulmonary capillaries create the respiratory membrane with the alveoli. As the
blood is pumped through this capillary network, gas exchange occurs.

Oxygenated hemoglobin is red, causing the overall appearance of bright red oxygenated
blood, which returns to the heart through the pulmonary veins. Carbon dioxide is released
in the opposite direction of oxygen, from the blood to the alveoli. Some of the carbon
dioxide is returned on hemoglobin, but can also be dissolved in plasma or is present as a
converted form, also explained in greater detail later in this chapter.

External respiration occurs as a function of partial pressure differences in oxygen and
carbon dioxide between the alveoli and the blood in the pulmonary capillaries.
 Internal Respiration

Internal respiration is gas exchange that occurs at the level of body tissues (Figure 3).
Similar to external respiration, internal respiration also occurs as simple diffusion due to a
partial pressure gradient. However, the partial pressure gradients are opposite of those
present at the respiratory membrane.

The partial pressure of oxygen in tissues is low, about 40 mm Hg, because oxygen is
continuously used for cellular respiration. In contrast, the partial pressure of oxygen in the
blood is about 100 mm Hg.

This creates a pressure gradient that causes oxygen to dissociate from hemoglobin, diffuse
out of the blood, cross the interstitial space, and enter the tissue. Hemoglobin that has
little oxygen bound to it loses much of its brightness, so that blood returning to the heart is
more burgundy in color.
Transport of Gases

· Oxygen Transport in the Blood

Even though oxygen is transported via the blood, you may recall that oxygen is not very
soluble in liquids. A small amount of oxygen does dissolve in the blood and is transported
in the bloodstream, but it is only about 1.5% of the total amount. The majority of oxygen
molecules are carried from the lungs to the body’s tissues by a specialized transport
system, which relies on the erythrocyte—the red blood cell. Erythrocytes contain a
metalloprotein, hemoglobin, which serves to bind oxygen molecules to the erythrocyte

Heme is the portion of hemoglobin that contains iron, and it is heme that binds oxygen.
One erythrocyte contains four iron ions, and because of this, each erythrocyte is capable
of carrying up to four molecules of oxygen.

The following reversible chemical reaction describes the production of the final product,
oxyhemoglobin (Hb–O2), which is formed when oxygen binds to hemoglobin.
Oxyhemoglobin is a bright red-colored molecule that contributes to the bright red color of
oxygenated blood.

Hemoglobin of the Fetus

The fetus has its own circulation with its own erythrocytes; however, it is dependent on the
mother for oxygen. Blood is supplied to the fetus by way of the umbilical cord, which is
connected to the placenta and separated from maternal blood by the chorion.

The mechanism of gas exchange at the chorion is similar to gas exchange at the respiratory
membrane. However, the partial pressure of oxygen is lower in the maternal blood in the
placenta, at about 35 to 50 mm Hg, than it is in maternal arterial blood.

The difference in partial pressures between maternal and fetal blood is not large, as the
partial pressure of oxygen in fetal blood at the placenta is about 20 mm Hg. Therefore,
there is not as much diffusion of oxygen into the fetal blood supply. The fetus’ hemoglobin
overcomes this problem by having a greater affinity for oxygen than maternal hemoglobin
(Figure 3).

Both fetal and adult hemoglobin have four subunits, but two of the subunits of fetal
hemoglobin have a different structure that causes fetal hemoglobin to have a greater
affinity for oxygen than does adult hemoglobin.
· Carbon Dioxide Transport in the Blood

Carbon dioxide is transported by three major mechanisms. The first mechanism of carbon
dioxide transport is by blood plasma, as some carbon dioxide molecules dissolve in the
blood.

The second mechanism is transport in the form of bicarbonate (HCO3–), which also
dissolves in plasma. The third mechanism of carbon dioxide transport is similar to the
transport of oxygen by erythrocytes.

· Dissolved Carbon Dioxide

Although carbon dioxide is not considered to be highly soluble in blood, a small fraction—
about 7 to 10 percent—of the carbon dioxide that diffuses into the blood from the tissues
dissolves in plasma.

The dissolved carbon dioxide then travels in the bloodstream and when the blood reaches
the pulmonary capillaries, the dissolved carbon dioxide diffuses across the respiratory
membrane into the alveoli, where it is then exhaled during pulmonary ventilation.

· Bicarbonate Buffer

A large fraction—about 70 percent—of the carbon dioxide molecules that diffuse into the
blood is transported to the lungs as bicarbonate. Most bicarbonate is produced in
erythrocytes after carbon dioxide diffuses into the capillaries, and subsequently into red
blood cells.

Carbonic anhydrase (CA) causes carbon dioxide and water to form carbonic acid (H2CO3),
which dissociates into two ions: bicarbonate (HCO 3–) and hydrogen (H+). The following
formula depicts this reaction:

Modifications in Respiratory Functions

· Hyperpnea

Hyperpnea is an increased depth and rate of ventilation to meet an increase in oxygen
demand as might be seen in exercise or disease, particularly diseases that target the
respiratory or digestive tracts.
This does not significantly alter blood oxygen or carbon dioxide levels, but merely
increases the depth and rate of ventilation to meet the demand of the cells.

In contrast, hyperventilation is an increased ventilation rate that is independent of the
cellular oxygen needs and leads to abnormally low blood carbon dioxide levels and high
(alkaline) blood pH.

High Altitude Effects

An increase in altitude results in a decrease in atmospheric pressure. Although the
proportion of oxygen relative to gases in the atmosphere remains at 21 percent, its partial
pressure decreases (see Table 1).

As a result, it is more difficult for a body to achieve the same level of oxygen saturation at
high altitude than at low altitude, due to lower atmospheric pressure.

In fact, hemoglobin saturation is lower at high altitudes compared to hemoglobin
saturation at sea level. For example, hemoglobin saturation is about 67 percent at 19,000
feet above sea level, whereas it reaches about 98 percent at sea level.

Acute mountain sickness (AMS), or altitude sickness, is a condition that results from
acute exposure to high altitudes due to a low partial pressure of oxygen at high altitudes.
AMS typically can occur at 2400 meters (8000 feet) above sea level.

· Acclimatization

Especially in situations where the ascent occurs too quickly, traveling to areas of high
altitude can cause AMS. Acclimatization is the process of adjustment that the respiratory
system makes due to chronic exposure to a high altitude.

Over a period of time, the body adjusts to accommodate the lower partial pressure of
oxygen. The low partial pressure of oxygen at high altitudes results in a lower oxygen
saturation level of hemoglobin in the blood. In turn, the tissue levels of oxygen are also
lower.

As a result, the kidneys are stimulated to produce the hormone erythropoietin (EPO), which
stimulates the production of erythrocytes, resulting in a greater number of circulating
erythrocytes in an individual at a high altitude over a long period.
Embryonic Development of the Respiratory System

Development of the respiratory system begins early in the fetus. It is a complex process
that includes many structures, most of which arise from the endoderm. Towards the end of
development, the fetus can be observed making breathing movements. Until birth,
however, the mother provides all of the oxygen to the fetus as well as removes all of the
fetal carbon dioxide via the placenta.

· Time Line

The development of the respiratory system begins at about week 4 of gestation. By week
28, enough alveoli have matured that a baby born prematurely at this time can usually
breathe on its own. The respiratory system, however, is not fully developed until early
childhood, when a full complement of mature alveoli is present.

Weeks 4–7

Respiratory development in the embryo begins around week 4. Ectodermal tissue from the
anterior head region invaginates posteriorly to form olfactory pits, which fuse with
endodermal tissue of the developing pharynx. An olfactory pit is one of a pair of structures
that will enlarge to become the nasal cavity. At about this same time, the lung bud forms.
The lung bud is a dome-shaped structure composed of tissue that bulges from the foregut.
The foregut is endoderm just inferior to the pharyngeal pouches. The laryngotracheal bud
is a structure that forms from the longitudinal extension of the lung bud as development
progresses. The portion of this structure nearest the pharynx becomes the trachea,
whereas the distal end becomes more bulbous, forming bronchial buds. A bronchial bud
is one of a pair of structures that will eventually become the bronchi and all other lower
respiratory structures (Figure 1).
Weeks 7–16

Bronchial buds continue to branch as development progresses until all of the segmental
bronchi have been formed. Beginning around week 13, the lumens of the bronchi begin to
expand in diameter. By week 16, respiratory bronchioles form. The fetus now has all major
lung structures involved in the airway.

Weeks 16–24

Once the respiratory bronchioles form, further development includes extensive
vascularization, or the development of the blood vessels, as well as the formation of
alveolar ducts and alveolar precursors. At about week 19, the respiratory bronchioles have
formed. In addition, cells lining the respiratory structures begin to differentiate to form type
I and type II pneumocytes. Once type II cells have differentiated, they begin to secrete
small amounts of pulmonary surfactant. Around week 20, fetal breathing movements may
begin.

Weeks 24–Term

Major growth and maturation of the respiratory system occurs from week 24 until term.
More alveolar precursors develop, and larger amounts of pulmonary surfactant are
produced. Surfactant levels are not generally adequate to create effective lung compliance
until about the eighth month of pregnancy. The respiratory system continues to expand,
and the surfaces that will form the respiratory membrane develop further. At this point,
pulmonary capillaries have formed and continue to expand, creating a large surface area
for gas exchange. The major milestone of respiratory development occurs at around week
28, when sufficient alveolar precursors have matured so that a baby born prematurely at
this time can usually breathe on its own. However, alveoli continue to develop and mature
into childhood. A full complement of functional alveoli does not appear until around 8
years of age.

Fetal “Breathing”

Although the function of fetal breathing movements is not entirely clear, they can be
observed starting at 20–21 weeks of development. Fetal breathing movements involve
muscle contractions that cause the inhalation of amniotic fluid and exhalation of the same
fluid, with pulmonary surfactant and mucus. Fetal breathing movements are not
continuous and may include periods of frequent movements and periods of no
movements.

Birth

Prior to birth, the lungs are filled with amniotic fluid, mucus, and surfactant. As the fetus is
squeezed through the birth canal, the fetal thoracic cavity is compressed, expelling much
of this fluid. Some fluid remains, however, but is rapidly absorbed by the body shortly after
birth.

The first inhalation occurs within 10 seconds after birth and not only serves as the first
inspiration, but also acts to inflate the lungs. Pulmonary surfactant is critical for inflation to
occur, as it reduces the surface tension of the alveoli.

Preterm birth around 26 weeks frequently results in severe respiratory distress, although
with current medical advancements, some babies may survive. Prior to 26 weeks,
sufficient pulmonary surfactant is not produced, and the surfaces for gas exchange have
not formed adequately; therefore, survival is low.

DISORDERS OF THE RESPIRATORY SYSTEM: RESPIRATORY DISTRESS SYNDROME

Respiratory distress syndrome (RDS) primarily occurs in infants born prematurely. Up to 50
percent of infants born between 26 and 28 weeks and fewer than 30 percent of infants born
between 30 and 31 weeks develop RDS. RDS results from insufficient production of
pulmonary surfactant, thereby preventing the lungs from properly inflating at birth. A small
amount of pulmonary surfactant is produced beginning at around 20 weeks; however, this
is not sufficient for inflation of the lungs. As a result, dyspnea occurs and gas exchange
cannot be performed properly. Blood oxygen levels are low, whereas blood carbon dioxide
levels and pH are high.

The primary cause of RDS is premature birth, which may be due to a variety of known or
unknown causes. Other risk factors include gestational diabetes, cesarean delivery,
second-born twins, and family history of RDS. The presence of RDS can lead to other
serious disorders, such as septicemia (infection of the blood) or pulmonary hemorrhage.
Therefore, it is important that RDS is immediately recognized and treated to prevent death
and reduce the risk of developing other disorders.