1. The Respiratory System
Chapter 22:
The Respiratory System

2. Alexander Graham Bell – invented the respiratory jacket in 1882
Alexander Graham Bell – invented the respiratory jacket in This device was the precursor to the IRON LUNG developed by Philip Drinker in the 1920s.

3. Nasal cavity Nostril Pharynx Oral cavity Trachea Larynx Carina of
Figure 22.1: The major respiratory organs in relation to surrounding structures, p. 832.
Nasal cavity
Nostril
Pharynx
Oral cavity
Trachea
Larynx
Carina of
trachea
Right main
(primary)
bronchus
Left main
(primary)
bronchus
Right lung
Left lung
Diaphragm

4. Figure 22.2: The external nose, p. 833.
Epicranius,
frontal belly
Frontal bone
Nasal bone
Septal
cartilage
Root and
bridge
of nose
Maxillary
bone
(frontal
process)
Dorsum nasi
Ala of nose
Lateral
process of
septal cartilage
Minor alar
cartilages
Dense fibrous
connective
tissue
Apex of nose
Philtrum
Major alar
cartilages
Naris (nostril)
(a)
(b)

5. Figure 22.3a: The upper respiratory tract, p. 834.
Olfactory nerves
Olfactory
epithelium
Superior nasal
concha and superior
nasal meatus
Mucosa
of pharynx
Middle nasal concha
and middle nasal
meatus
Tubal
tonsil
Inferior nasal concha
and inferior nasal
meatus
Pharyngo-
tympanic
(auditory)
tube
Hard palate
Soft palate
Nasopharynx
Uvula
(a)

6. Figure 22.3b: The upper respiratory tract, p. 834.
Sphenoidal sinus
Frontal sinus
Nasal meatuses
(superior, middle,
and inferior)
Cribriform plate
of ethmoid bone
Nasal conchae
(superior, middle
and inferior)
Pharyngeal tonsil
Opening of
pharyngotympanic
(auditory) tube
Nasal vestibule
Nasopharynx
Nostril
Posterior nasal
aperture
Hard palate
Soft palate
Uvula
Tongue
Palatine tonsil
Lingual tonsil
Isthmus of the
fauces
Epiglottis
Oropharynx
Hyoid bone
Laryngopharynx
Thyroid cartilage
Vestibular fold
Laryngeal
Cricoid cartilage
cartilages
Vocal fold
Esophagus
Thyroid gland
Trachea
(b)

7. Figure 22.4a-b: The larynx, p. 836.
Epiglottis
Body of
hyoid bone
Thyrohyoid
membrane
Body of
hyoid bone
Thyrohyoid
membrane
Cuneiform
cartilage
Thyroid
cartilage
Fatty pad
Corniculate
cartilage
Vestibular fold
(false vocal cord)
Laryngeal
prominence
(Adam’s apple)
Arytenoid
cartilage
Thyroid cartilage
Vocal fold
(true vocal cord)
Arytenoid
muscles
Cricothyroid
ligament
Cricothyroid
ligament
Cricoid cartilage
Cricotracheal
ligament
Cricotracheal
ligament
Tracheal
cartilages
(a)
(b)

8. Figure 22.5: Movements of the vocal cords, p. 837.
Base of tongue
Epiglottis
False vocal cord
True vocal cord
Glottis
Inner lining of trachea
Corniculate
cartilage
(a)
(b)

9. Figure 22.6: Tissue composition of the tracheal wall, p. 839.
Posterior
Pseudostratified
ciliated columnar
epithelium
Esophagus
Trachealis
muscle
Seromucous
glands in
submucosa
Lumen of
trachea
Mucous membrane
Hyaline cartilage
Submucosa
Adventitia
(a)
Anterior
(b)
(c)

10. Figure 22.7: Conducting zone passages, p. 840.
Trachea
Superior lobe
of right lung
Superior lobe
of left lung
Right main
(primary)
bronchus
Lobar (secondary)
bronchus
Segmental (tertiary)
bronchus
Middle lobe
of right lung
Inferior lobe
of right lung
Inferior lobe
of left lung

11. Figure 22.8: Respiratory zone structures, p. 841.
Alveolar duct
Alveoli
Respiratory bronchioles
Alveolar duct
Terminal
bronchiole
Alveolar
sac
(a)
Respiratory
bronchiole
Alveolar
pores
Alveolar
duct
Alveoli
Alveolar
sac
(b)

12. Figure 22.9a-b: The respiratory membrane, p. 843.
Capillaries
Smooth
muscle
Elastic
fibers
Alveolus
(a)
(b)

13. Figure 22.9c-d: The respiratory membrane, p. 843.
Type II (surfactant-
secreting) cell
Type I cell
of alveolar wall
Red blood cell
Epithelial cell nucleus
Capillary
Endothelial cell
nucleus
Capillary O2
CO2
Alveolus
Alveolus
Nucleus of
type I
(squamous
epithelial)
cell
Macrophage
(d)
Respiratory
membrane
Alveolar epithelium
Fused basement membranes
of the alveolar epithelium
and the capillary endothelium
Capillary endothelium
Alveoli (gas-filled
air spaces)
Red blood cell
in capillary
Alveolar pores
(c)

14. Parietal pleura Apex of lung Trachea Rib Thymus Lung
Figure 22.10a: Anatomical relationships of organs in the thoracic cavity, p. 844.
Parietal pleura
Apex of lung
Trachea
Rib
Thymus
Lung
Intercostal muscle
Pleural
cavity
Visceral pleura
Right superior lobe
Left
superior lobe
Horizontal fissure
Right middle lobe
Cardiac notch
Oblique fissure
Oblique
fissure
Right inferior lobe
Left inferior
lobe
Heart
(in mediastinum)
Diaphragm
Base of lung
(a)

15. Figure 22.16a: Respiratory volumes and capacities, p. 852.
6000
5000
Inspiratory
reserve volume
3100 ml
Inspiratory capacity
3600 ml
4000
Vital capacity
4800 ml
Milliliters (ml)
3000
Total
lung
capacity
6000 ml
Tidal volume 500 ml
Expiratory
reserve volume
1200 ml
2000
Functional
residual capacity
2400 ml
1000
Residual volume
1200 ml
(a) Spirographic record for a male

16. Figure 22.16b: Respiratory volumes and capacities, p. 852.
Adult male
Adult female
average
average
Measurement
value
value
Description
Amount of air inhaled or exhaled with each breath under resting
conditions
Tidal volume (TV)
500 ml
500 ml
Inspiratory reserve
volume (IRV)
Amount of air that can be forcefully inhaled after a normal tidal
volume inhalation
3100 ml
1900 ml
Respiratory volumes
Expiratory reserve
volume (ERV)
Amount of air that can be forcefully exhaled after a normal tidal
volume exhalation
1200 ml
700 ml
Residual volume (RV)
1200 ml
1100 ml
Amount of air remaining in the lungs after a forced exhalation
Maximum amount of air contained in lungs after a maximum
inspiratory effort: TLC = TV + IRV + ERV + RV
Total lung capacity (TLC)
6000 ml
4200 ml
Maximum amount of air that can be expired after a maximum
inspiratory effort: VC = TV + IRV + ERV (should be 80% TLC)
Vital capacity (VC)
4800 ml
3100 ml
Respiratory capacities
Maximum amount of air that can be inspired after a normal
expiration: IC = TV + IRV
Inspiratory capacity (IC)
3600 ml
2400 ml
Functional residual
capacity (FRC)
Volume of air remaining in the lungs after a normal tidal volume
expiration: FRC = ERV + RV
2400 ml
1800 ml
(b)
Summary of respiratory volumes and capacities for males and females

17. alveolar capillaries: PO2 104 mm Hg PCO2 40 mm Hg Blood entering
Figure 22.17: Partial pressure gradients promoting gas movements in the body, p. 856.
Inspired air:
PO mm Hg
PCO mm Hg
Expired air:
PO mm Hg
PCO mm Hg
Alveoli of lungs:
PO mm Hg
PCO mm Hg
O2 CO2
O2 CO2
External
respiration
O2 CO2
Blood leaving
alveolar capillaries:
PO mm Hg
PCO mm Hg
Blood entering
alveolar capillaries:
PO mm Hg
PCO mm Hg
CO2 O2
O2 CO2
O2 CO2
Pulmonary
veins (PO2
100 mm Hg)
Pulmonary
arteries
Systemic
veins
Systemic
arteries
Heart
CO2 O2
Blood leaving
tissue capillaries:
PO mm Hg
PCO mm Hg
Blood entering
tissue capillaries:
PO mm Hg
PCO mm Hg
O2 CO2
O2 CO2
Internal
respiration
Tissues:
PO2 less than 40 mm Hg
PCO2 greater than 45 mm Hg
O2 CO2

18. Figure 22.28: The pathogenesis of COPD, p. 871.
• Tobacco smoke
• Air pollution
a-1 antitrypsin
deficiency
Continual bronchial
irritation and inflammation
Breakdown of elastin in
connective tissue of lungs
Chronic bronchitis
Bronchial edema,
chronic productive cough,
bronchospasm
Emphysema
Destruction of alveolar
walls, loss of lung
elasticity, air trapping
• Airway obstruction
or air trapping
• Dyspnea
• Frequent infections
• Abnormal ventilation-
perfusion ratio
• Hypoxemia
• Hypoventilation

19. Additional Items to Review About the Lymphatic System

20. tissue around capillaries Venule Arteriole Heart
Figure 20.1: Distribution and special structural features of lymphatic capillaries, p. 774.
Venous
system
Arterial
system
Loose connective
tissue around capillaries
Venule
Arteriole
Heart
Lymph duct
Lymph trunk
Lymph node
Lymphatic
system
Lymphatic
collecting
vessels,
with
valves
Lymphatic
capillary
Tissue fluid
Blood
capillaries
Lymphatic
capillary
Tissue cell
(a)
Blood
capillaries
Filaments
anchored to
connective
tissue
Endothelial
cell
Flaplike
minivalve
Fibroblast in loose
connective tissue
(b)

21. Figure 20.2a: The lymphatic system, p. 776.
Regional
lymph nodes:
Entrance of
right lymphatic
duct into right
subclavian vein
Cervical
nodes
Internal
jugular vein
Entrance of
thoracic
duct into left
subclavian vein
Axillary
nodes
Thoracic duct
Aorta
Cisterna chyli
Lymphatic
collecting
vessels
Inguinal
nodes
(a)

22. Please remember that the overall design of the lymphatic system is a slightly modified replication of the arterial and venous systems. Namely, the lymphatic vessels include the larger “lymphatic vessels” the “lymphatuoles” and the “lymphatic capillaries”.
From the lymphatic system, the fluids that are collected will be transported back into circulation via the veins in the blood vascular system. One specific entry point is the subclavian vein.
Peyer’s patches are significantly involved with aspects of immune response associated with the digestive system and last during our entire lifetime.
The way in which the lymphatic capillaries draws fluid into them is via the movment of the slit-like flaps through their attachment with filaments to the sidewalls of other tissues.
Lymphatic vessels have valves like seen in veins.
The cisterna chyli is a dialated part of the thorascic duct in the lymphatic system.

23. Afferent lymphatic vessels Cortex: • Lymphoid follicle
Figure 20.4: Lymph node, p. 778.
Afferent
lymphatic
vessels
Cortex:
• Lymphoid follicle
• Germinal center
• Subcapsular sinus
Efferent
lymphatic
vessels
Follicles
Trabecula
Subcapsular
sinus
Hilum
Medulla:
Capsule
• Medullary
cord
• Medullary
sinus
Medullary
cords
Medullary
sinuses
Trabeculae
(a)
Capsule
(b)

24. Figure 20.5: Lymphoid organs, p. 779.
Tonsils (in
pharyngeal
region)
Thymus (in
thorax; most
active during
youth)
Spleen (curves
around left side
of stomach)
Peyer’s patches
(in intestine)
Appendix