Respiratory System PDF

Summary

These notes cover the respiratory system. Topics discussed include the anatomy, histology, and physiology of the system.

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Respiratory System
Ariette Acevedo, O.D.
BMS 2

1

– Discussion of the Anatomy and Histology of the Respiratory
System

Objectives

– Discussion of the Physiology of Respiration
– Discussion of Respiratory Pathology
– Obstructive and Restrictive Disease
– Infectious Disease
– Neoplasms

2

Anatomy/Histology

3

tomoestesis

balance

– The respiratory system contributes to homeostasis by providing for
the exchange of gases (oxygen and carbon dioxide) between the
atmospheric air, blood and tissue cells.
– It also helps adjust the pH of body fluids

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– Blood pH: 7.35-7.45, avg. 7.40
– Above 7.45: Alkalemia
– Below 7.35: Acidemia

– Body's cells continually use O2 for metabolic reactions that release
energy from nutrient molecules and produce ATP.
– These reaction release CO2
– Large amounts of CO2 produce acidity
– CO2 must be eliminated quickly and efficiently

– The cardiovascular and respiratory systems cooperate to supply O2
and eliminate CO2.
– Respiratory system: gas exchange
– Cardiovascular system: transports blood containing gases between the
lungs and body cells.

4

– Respiratory system consists of:
–
–
–
–
–
–

Nose
Pharynx
Larynx
Trachea
Bronchi
Lungs

in addition to Parashed

– Can be classified according to function and structure:
– Structurally
– Upper Respiratory System
– Lower Respiratory System

– Functionally
– Conducting Zone
– Respiratory Zone

taking air
interchange

5

Respiratory
System
Anatomy

6

– Structurally (Anatomically)
– Upper Respiratory System

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– Nose, pharynx and associated structures

– Lower Respiratory System
– Larynx, trachea, bronchi, and lungs

– Functionally

Classification

– Conducting Zone: series of interconnecting cavities and tubes both
outside and within the lungs.
– Nose, pharynx, larynx, trachea, bronchi, bronchioles, and terminal
bronchioles.
– Function: filter, warm, and moisten air and conduct it into the lungs.

– Respiratory Zone: tissues within the lungs where gas exchange
occurs.
– Respiratory bronchioles, alveolar ducts, alveolar sacs, and alveoli.
– These are the main sites of gas exchange between air and blood.

7

Lateral Nasal
Cartilage

External Nose

Septal Cartilage

Alar Cartilage

External Nares

nostrils
8

38

Internal Nose

Floors

9

Nasal Meatuses

3had el

Internal Nose
subdivide

10

– Funnel-shaped tube, ~13cm (5 in.) long.
– Starts at the internal nares and extends to the level of the cricoid
cartilage.
– Lies just posterior to the nasal and oral cavities, superior to the
larynx and just anterior to the cervical vertebrae.

Pharynx

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TWO

function

– Its walls are composed of skeletal muscle and lined with mucous
membranes.
– Contraction of the muscles helps in deglutition

– Functions as a passageway for air and food, provides a resonating
chamber for speech sounds and houses the tonsils, which aid in
immunological reactions.

Air passage

swallow
11

cavity
nasal
post

Pharynx

soft pelde the
Belowthe

nyloidbone

12

– AKA Voice box

known

– Is a short passageway that connects the laryngopharynx with the
trachea.
– Lies in the midline of the neck, anterior to the esophagus and the
fourth-sixth cervical vertebrae (C4-C6)

Larynx

– Composed of nine pieces of cartilage:

IEEE

–
–
–
–
–
–

2 Arytenoid Cartilage
2 Cuneiform Cartilage
2 Corniculate Cartilage
Thyroid Cartilage (Adam’s Apple)
Cricoid Cartilage
Epiglottis

cartilage

13

immovable

Larynx

14

– Large, leaf-shaped piece of elastic cartilage, covered in
epithelium.

Epiglottis

– The “stem” of the epiglottis is the tapered inferior portion
attached to the anterior rim of the thyroid cartilage and hyoid
bone.
– The ”leaf” portion is unattached and free to move up and down,
like a trap door.
– During swallowing the pharynx and larynx rise, widening the
pharynx to receive food and the larynx elevates causing the
epiglottis to move down and form a lid over the glottis, preventing
food from entering the larynx.

Aspiration
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15

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16

– AKA “windpipe”
– Tubular passageway for air ~12cm (5in.) long and 2.5cm (1 in.) in
diameter.

Trachea

– Located anterior to the esophagus and extends from the larynx to
the superior border of T5 , when it divides into the right and left
primary bronchi.
– Has 16-20 incomplete “C”, staked one above the other, connected
by dense connective tissue.
noestan– The open part of the “C” faces posteriorly the esophagus

completemente
– The semi-solid cartilages provide support to prevent the tracheal

curveda wall from collapsing inward and obstructing the passage of air.

17

Cartilage of
Trachea

Anterior

Trachea

caring

Esophagus

0

Posterior

Trachea
18

– The trachea divides at the level of T5 into the primary
bronchus

Bronchi

– Right Primary Bronchus -> into the right lung
– Shorter, wider and more vertical
thinker– Left Primary Bronchus -> into the left lung

– At the point where the trachea divides into the right
and left primary bronchi an internal ridge is formed
called the carina.

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firstdivision

19

– After entering the lungs, the primary bronchi divide to form
smaller bronchi
– Secondary (lobar) Bronchi: one for each lobe of the lungs

Bronchi

– Right lung has 3 lobes
– Left lung has 2 lobes

– Tertiary (segmental) Bronchi
– Bronchioles
– Terminal Bronchioles

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20

Caring

Bronchi

Respiratory Tree
Branch

21

– As the branching becomes more extensive several structural
changes can be noted:
1.

eneddara

Mucous membrane changes from pseudostratified ciliated
columnar epithelium (primary, secondary and tertiary bronchi)
to ciliated simple columnar epithelium with goblet cells (larger
bronchioles) to ciliated simple cuboidal epithelium with no
goblet cells (smaller bronchioles) to nonciliated simple cuboidal
epithelium (terminal bronchioles)

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2.

Plates of cartilage gradually replace the incomplete rings of
cartilage in primary bronchi and finally disappear in the distal
bronchioles.

3.

As the amount of cartilage decreases, the amount of smooth
muscle increases.
– Since there is no supporting cartilage, muscle spasms can close of
the airways. (asthma)

22

Lungs

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systalticle

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– Paired, cone-shaped organs
in the thoracic cavity
– Each lung is enclosed and
protected by a doublelayered serous membrane,
known as the pleural
membrane
– Parietal Pleura: superficial
layer, lines the walls of the
thoracic cavity
– Visceral Pleura: covers the
lungs

separated

by heat

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idfortent
23

Right

Left

superior

inferior

Lobes/Fissures

24

Terminal Bronchiole

Respiratory
Bronchiole

Alveolar
Ducts

Alveoli
Alveolar
Sac

therefore
25

– The walls of the alveoli consist of 2 types of alveolar epithelial
cells:
– Type I Alveolar Cells: simple squamous epithelial cells that form a
nearly continuous lining of the alveolar wall.
– Considered the main site for gas exchange

– Type II Alveolar Cells: rounded cuboidal epithelial cells with free
surface microvilli.

Alveoli

– Secrete alveolar fluid, keep surface between cells and air moist. .

– Associated with alveolar walls there are also alveolar
macrophages: phagocytes that remove fine dust particles and
haen
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WASother debris from the alveolar space.
macrophages

Payyocytosis

– The exchange of O2 and CO2 between the air spaces in the
lungs and the blood takes place by diffusion across the alveolar
and capillary walls
– Which together form the respiratory membrane.

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diffused
26

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to lower concentration

Alveoli

27

– Very thin, only 0.5µm thick
– Consist of 4 layers:

Respiratory
Membrane

– Alveolar Wall: a layer of
type I and type II alveolar
cells and associated alveolar
macrophages.
– Epithelial Basement
Membrane: underlying the
alveolar wall.
– Capillary Basement
Membrane: fused to the
epithelial basement
membrane
– Capillary Endothelium

– The lungs contain ~300 million
alveoli (70m2) for gas
exchange

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28

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Pulmonary

– Arteries:

keen

– Pulmonary Arteries: deoxygenated blood enters the pulmonary
trunk, which divides into the left and right pulmonary arteries (2).
– The only arteries in the body to carry deoxygenated blood

Blood Supply

– Bronchial Arteries: branch from the aorta and deliver oxygenated
blood to the lungs.

Effey

– Mainly used to perfuse the muscular walls of the bronchi and
bronchioles

– Veins: return of the oxygenated blood to the heart.
– 4 pulmonary veins which drain into the left atrium.

9

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29

Pulmonary Ventilation

30

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– The process of gas exchange is called respiration.
– 3 basic steps:

Respiration

– Pulmonary ventilation (breathing): the inhalation (inflow) and
exhalation (outflow) of air and involves the exchange of air between
the atmosphere and the alveoli of the lungs.
– External (pulmonary) respiration: the exchange if gasses between
the alveoli of the lungs and the blood in pulmonary capillaries across
the respiratory membrane.
– Process in which capillaries gain O2 and lose CO2.

– Internal (tissue) respiration: the exchange of gases between blood
in systemic capillaries and tissue cells.
– Blood loses O2 and gains CO2
– Which cellular process is known to consume O2 and produce CO2?

31

Pressure
Changes
during
Pulmonary
Ventilation

– Air moves into the lungs when the air pressure inside the lungs is
less than the air pressure in the atmosphere.
– Air moves out of the lungs when the air pressure inside the lungs
is greater than the air pressure in the atmosphere.

partial pressure

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lowerpartial

pressure

32

– Just before inhalation, the air pressure inside the lungs is equal to
the air pressure of the atmosphere.

Inhalation

– For air to flow into the lungs, the pressure inside the alveoli must
become lower than the atmospheric pressure.
– Atmospheric pressure is 760 mmHg at sea level or 1 atmosphere
(atm)

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• The difference in pressure in respiration case is caused by
changes in lung volume.
• The lungs expand to increase in volume and decrease air pressure

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33

Inhalation
• Lung Expansion
• Contraction of the
main muscles of
inhalation, the
diaphragm and the
external intercostals
• Inhalation is
considered an active
process-there is
muscle contraction
involved.

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34

Pressure
Changes

35

– The pressure in the lungs is greater than the pressure in the
atmosphere.
– Normal quiet exhalation is considered a passive process, since no
muscle contraction is involved.

Exhalation

– It results from elastic recoil of the chest wall and lungs
– Natural tendency to spring back after they have been stretched

– Exhalation becomes active only during forceful breathing
– Playing a wind instrument or exercise

– Muscles of exhalation:
– Abdominals and internal intercostals

area
36

Pressure
Changes

37

Lung Volumes and
Capacities

38

– Tidal Volume (VT): the volume of one breath. The amount of air
that moves in and out of the airways during normal quiet
breathing.
– 70% reaches the respiratory bronchioles
– 30% remains in anatomic dead space (nose, larynx, pharynx, ect)

– Minute Ventilation (MV): the total volume of air inhaled and
exhaled each minute.
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es mucho

– A lower-than-normal MV is usually a sign of pulmonary
malfunction.

39

– Alveolar Ventilation Rate: the volume of air per minute that
actually reaches the respiratory zone.
– Inspiratory Reserve Volume (IRV): the additional amount of air
taken by a deep breath.
– Avg Adult Male: 3,100mL and Avg Adult Female: 1,900mL

– Expiratory Reserve Volume (ERV): the additional amount of air
exhaled after a normal inspiration.
– Avg Adult Male: 1,200mL and Avg Adult Female: 700mL

say

– FEV1: Forced Expiratory Volume in 1 second, the volume of air
that can be exhaled from the lungs in 1 second with maximal effort
following a maximal inhalation.
– Residual Volume: volume of air remaining in the lungs that cannot
be measured.
– Avg Adult Male: 1,200mL and Avg Adult Female: 1,100mL

40

– Inspiratory Capacity: the sum of tidal volume and inspiratory
reserve volume.
– Avg Adult Male: 3600mL and Avg Adult Female: 2400mL

– Functional Residual Capacity: the sum of residual volume and
expiratory reserve volume.
– Avg Adult Male: 2400mL and Avg Adult Female: 1800mL

Lung
Capacities

– Vital Capacity: the sum of inspiratory reserve volume, tidal
volume, and expiratory reserve volume.
– Avg Adult Male: 4800mL and Avg Adult Female: 3100mL

– Total Lung Capacity: the sum of vital capacity and residual
volume.
– Avg Adult Male: 6000mL and Avg Adult Female: 4200mL

41

Infestation

Spirogram
42

Nor

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se

dioxide

Gas Laws

– Dalton’s Law: each gas in a mixture of gases exerts its own
pressure as if no other gases are present.
– Atmospheric Air: 78.6 nitrogen, 20.9% oxygen, 0.04% carbon
dioxide, and 0.06% other gases in addition to water vapor (~0.4%)
– Compared to inhaled air, alveolar air has less O2 (13.6% vs 20.9%)
and more CO2 (5.25% vs. 0.04%) then

youratmosphere
f g – Henry’s Law: the quantity of a gas that will
dissolve in a liquid is
proportional to the partial pressure of the gas and its solubility.

– In body fluids the ability of a gas to stay in solution is greater when
its partial pressure is higher and when it has a high solubility in
water.
– The higher the partial pressure the more gas will stay in solution.
– In comparison to O2, much more CO2 is dissolved in blood plasma since
the solubility of CO2 is 24x greater than that of O2.

Sas
43

Boo
External Respiration
– AKA Pulmonary Gas Exchange
– The diffusion of O2 from air in the
alveoli of the lungs to blood in
pulmonary capillaries and diffusion of
CO2 in the opposite direction.

44

2

2

1

1

45

– AKA systemic gas exchange

Internal
Respiration

– The exchange of O2 and CO2 between systemic capillaries and
tissue cells.
– The left ventricle pumps oxygenated blood into the aorta and
through the systemic arteries to systemic capillaries.

46

1

47

Factors
Affecting
Pulmonary
and Systemic
Gas Exchange

– Partial Pressure differences of the gases: the rate of diffusion is
faster when the difference between Po2 in alveolar air and
pulmonary capillary blood is larger and diffusion is slower when
the difference is smaller.
– Surface area available for gas exchange: any pulmonary disorder
that decreases the functional surface area of the respiratory
membranes decreases the rate of external respiration.
– Diffusion Distance: increase in diffusion distance can slow the
rate of gas exchange.
– Molecular weight and solubility of the gases: when diffusion is
slower than normal, O2 insufficiency (hypoxia) typically occurs
before there is significant retention of CO2 (hypercapnia).

48

– O2 does not dissolve easily in
water

Oxygen
Transport

– 1.5% inhaled O2 is dissolved
in blood plasma
– 98.5% is bound to
hemoglobin in RBC

– Hemoglobin
– 4 chains (2⍺/2β)
– 1 heme ring
– 1 Fe2+

– O2 and Hemoglobin bind to
form oxyhemoglobin
– An easily reversible reaction

49

– The most important factor that determine how much O2 binds to
hemoglobin is the Partial Pressure of O2 (PO2)

Oxygen
Transport

– Higher PO2 = more O2 combines with Hb

– Fully Saturated: when reduced hemoglobin (Hb) is completely
converted to oxyhemoglobin (Hb-O2).
– Partially Saturated: when hemoglobin consist of a mix of Hb-O2
and Hb.

50

Oxygen Transport
-The relationship between the percent saturation of hemoglobin
and PO2 is illustrated in the Oxygen-hemoglobin dissociation
curve
-When PO2 is high, hemoglobin binds with large amounts of O2
and is almost 100% saturated.
- When PO2 is low, hemoglobin is only partially saturated.

51

Factors Affecting the Affinity of Hemoglobin for O2
– These factors are going to create a shift in the curve either to the left (higher
affinity) or right (lower affinity)
1.

Acidity (pH): as acidity increased (decrease in pH) the affinity of hemoglobin for
O2 decreases and O2 dissociated more readily from hemoglobin.

– This created a shift to the right. Thus, at any given PO2 Hb is less saturated with
O2.
– This is termed the Bohr effect, the relationship between pH and hemoglobin's
affinity for oxygen.
– The opposite effect happens when pH is elevated, increasing the affinity of
hemoglobin for O2 and shifting the curve to the left.

52

Basic

Acidic

53

2.

Partial Pressure of Carbon Dioxide (PCO2):

– As CO2 enter the blood much of it is temporarily converted to
carbonic acid (H2CO3), a reaction catalyzed by carbonic anhydrase
(CA)

Factors
Affecting the
Affinity of
Hemoglobin for
O2

– This reaction produces hydrogen ions (H+) and bicarbonate ions.
– As H+ concentration increases the pH decreases (more acidic)

– Thus, an increase in PCO2 created an increase in H+, creating a
more acidic pH, leading to more O2 being released from
hemoglobin.
– Shifting the curve to the right

– The opposite is true, a decreased PCO2 (elevated pH) shift the
saturation curve to the left.

54

55

3.

Factors
Affecting the
Affinity of
Hemoglobin
for O2

Temperature: heat is a by product of metabolic reactions of all
cells and the heat released by contracting muscle fibers tends
to raise body temperature.

– As temperature increases, the amount of O2 released from
hemoglobin also increases.
– Shift of the curve to the right.

– Metabolically active cells require more O2 and liberate more heat
and acids, this in turn promotes the release of O2 from
oxyhemoglobin.
– In contrast during hypothermia cellular metabolism slows, the
need for O2 is reduced and more O2 remains bound to
hemoglobin.
– Shift of the curve to the left.

56

57

4.

Factors
Affecting the
Affinity of
Hemoglobin
for O2

3-bisphosphoglycerate (BPG): a substrate found in RBC,
previously called diphosphoglycerate (DPG). BPG is formed in
RBC during glycolysis.

– Decreases the affinity of hemoglobin for O2 and helps unload O2
from hemoglobin.
– The greater the level of BPG, the more O2 is unloaded from
hemoglobin.
– Certain hormones and higher altitudes increase the level of BPG.
– Thyroxine, human growth hormone, epinephrine, norepinephrine,
and testosterone.

58

– CO2 is transported in blood in 3 main forms:

Carbon
Dioxide
Transport

1.

Dissolved CO2: 7% is dissolved in blood plasma.

2.

Carbamino compounds: 23% combines with hemoglobin to
form carbaminohemoglobin (Hb-CO2).

3.

Bicarbonate ions: 70% transported in blood plasma as
bicarbonate ions (HCO3-).

– Deoxygenated blood returning to the pulmonary capillaries
contain:
– CO2 dissolved in plasma
– Carbaminohemoglobin (Hb-CO2)
– CO2 incorporated into HCO3- within RBCs

59

60

Control of Respiration

61

Respiratory Center
– The size of the thorax is altered y the
action of the respiratory muscles,
which contract due to nerve
impulses transmitted from the
centers in the brain and relax in the
absence of nerve impulses.
– These impulses are sent from
clusters of neurons located
bilaterally in the medulla oblongata
and pons of the brain stem.

62

– Divided into 3 areas:
– Medullary rhythmicity area located in the medulla oblongata

Respiratory
Center

– In control of the basic rhythm of respiration
– Inspiratory and expiratory areas

– Pneumotaxic area located in the upper pons
– Helps in rhythm regulation of the inspiratory area

– Apneuristic area located in the pons
– Stimulates the inspiratory area to activate and prolong inhalation

63

– Cortical Influences on Respiration
– Voluntary control of respiratory pattern

Regulation of
Respiratory
Center

– Chemoreceptor Regulation of Respiration
–
–
–
–

Chemical stimuli to regulate breathing
Chemoreceptors monitor levels of CO2, O2 and H+
Central Chemoreceptors: central nervous system
Peripheral Chemoreceptors: aortic bodies and carotid bodies

– Proprioceptor Stimulation of Respiration
– Inflation (Hering-Breuer) Reflex
– Protective mechanism

64

65