1. The Respiratory System Sonya Schuh-Huerta, Ph.D.
Human Anatomy
Sonya Schuh-Huerta, Ph.D.
Leonardo Da Vinci

2. The Upper Respiratory Tract
Cribriform plate
of ethmoid bone
Frontal sinus
Sphenoid sinus
Nasal cavity
Posterior nasal
aperture
Nasal conchae
(superior, middle
and inferior)
Nasopharynx
Pharyngeal tonsil
Nasal meatuses
(superior, middle,
and inferior)
Opening of
pharyngotympanic
tube
Nasal vestibule
Uvula
Nostril
Oropharynx
Hard palate
Palatine tonsil
Soft palate
Isthmus of the
fauces
Tongue
Lingual tonsil
Laryngopharynx
Hyoid bone
Larynx
Epiglottis
Esophagus
Vestibular fold
Thyroid cartilage
Vocal fold
Trachea
Cricoid cartilage
Thyroid gland

3. Organs of the Respiratory System
Nasal cavity
Oral cavity
Nostril
Pharynx
Larynx
Left main
(primary)
bronchus
Trachea
Bronchi
Carina of
trachea
Alveoli
Right main
(primary)
bronchus
Left lung
Right lung
Diaphragm
Parietal
pleura

4. Bronchi in the Conducting Zone
Superior lobe
of right lung
Trachea
Superior lobe
of left lung
Left main
(primary)
bronchus
Lobar
(secondary)
bronchus
Segmental
(tertiary)
bronchus
Inferior lobe
of left lung
Inferior lobe
of right lung
Middle lobe
of right lung
(a) The branching of the bronchial tree

5. Structures of the Respiratory Zone
Alveolar duct
Alveoli
Alveolar
sac
Respiratory
bronchioles
Terminal
bronchiole
(a)

6. Alveoli & the Respiratory Membrane
Terminal bronchiole
Respiratory bronchiole
Smooth
muscle
Elastic
fibers
Alveolus
Capillaries
(a) Diagrammatic view of capillary-alveoli relationships

7. Anatomy of Alveoli & the Respiratory Membrane
Red blood
cell
Nucleus of type I
(squamous
epithelial) cell
Alveolar pores
Capillary O2
Capillary
CO2
Macrophage
Alveolus
Endothelial cell nucleus
Alveolus
Alveolar epithelium
Respiratory
membrane
Fused basement
membranes of the
alveolar epithelium
and the capillary
endothelium
Red blood cell
in capillary
Type I cell
of alveolar wall
Capillary endothelium
Alveoli (gas-filled
air spaces)
Type II (surfactant-
secreting) cell
(c) Detailed anatomy of the respiratory membrane

8. The Respiratory System
Basic functions of the respiratory system
Supplies body with oxygen
Disposes of carbon dioxide
4 processes involved in respiration:
Pulmonary ventilation
External respiration
Transport of respiratory gases
Internal respiration

9. Functional Anatomy of the Respiratory System
Respiratory organs
Nose, nasal cavity, & paranasal sinuses
Pharynx, larynx, & trachea
Bronchi & smaller branches
Lungs & alveoli

10. Organs of the Respiratory System
Divided into
Conducting zone
Respiratory zone

11. The Nose Provides an airway for respiration
Moistens & warms air (humidifies air)
Filters inhaled air
Resonating chamber for speech
Houses olfactory receptors (olfaction)

12. The Nose Size variation due to differences in nasal cartilages
Skin is thin  contains many sebaceous glands
Frontal bone
Nasal bone
Septal cartilage
Maxillary bone
(frontal process)
Lateral process of
septal cartilage
Minor alar
cartilages
Major alar
Dense fibrous
connective tissue
(b) External skeletal framework
Epicranius,
frontal belly
Ala of nose
Root and bridge
of nose
Dorsum nasi
Apex of nose
Philtrum
Naris (nostril)
(a) Surface anatomy

13. The Nasal Cavity External nares  nostrils Divided by nasal septum
Continuous with nasopharynx

14. Nasal Cavity 2 types of mucous membrane: Olfactory mucosa
Near roof of nasal cavity
Houses olfactory receptors
Respiratory mucosa
Lines nasal cavity
Pseudostratified ciliated columnar epithelium

15. The Upper Respiratory Tract
Cribriform plate
of ethmoid bone
Frontal sinus
Sphenoid sinus
Nasal cavity
Posterior nasal
aperture
Nasal conchae
(superior, middle
and inferior)
Nasopharynx
Pharyngeal tonsil
Nasal meatuses
(superior, middle,
and inferior)
Opening of
pharyngotympanic
tube
Nasal vestibule
Uvula
Nostril
Oropharynx
Hard palate
Palatine tonsil
Soft palate
Isthmus of the
fauces
Tongue
Lingual tonsil
Laryngopharynx
Hyoid bone
Larynx
Epiglottis
Esophagus
Vestibular fold
Thyroid cartilage
Vocal fold
Trachea
Cricoid cartilage
Thyroid gland

16. Respiratory Mucosa Consists of:
Pseudostratified ciliated columnar epithelium
Goblet cells within epithelium
Underlying layer of lamina propria
Cilia move contaminated mucus posteriorly

17. Nasal Conchae Superior & middle nasal conchae Inferior nasal conchae
Part of the ethmoid bone
Inferior nasal conchae
Separate bone
Project medially from the lateral wall of the nasal cavity
Particulate matter:
Deflected to mucus-coated surfaces

18. The Pharynx Funnel-shaped passageway Connects nasal cavity & mouth
Divided into 3 sections by location:
Nasopharynx
Oropharynx
Laryngopharynx
Type of mucosal lining changes along its length

19. The Nasopharynx Superior to the point where food enters
Only an air passageway
Closed off during swallowing
Pharyngeal tonsil (adenoids)
Located on posterior wall
Destroys pathogens that enter
Contains the opening to the pharyngotympanic tube (auditory or eustachian tube)
Tubal tonsil
Provides some protection from infection

20. The Oropharynx Arch-like entrance-way  fauces Epithelium
Extends from soft palate to epiglottis
Epithelium
Stratified squamous epithelium
2 types of tonsils in the oropharynx
Palatine tonsils  in lateral walls of the fauces
Lingual tonsils  covers the posterior surface
of the tongue

21. The Laryngopharynx Passageway for both food & air Epithelium
Stratified squamous epithelium
Continuous with the esophagus & larynx

22. The Larynx 3 functions  Voice production Provides an open airway
Routes air & food into the proper channels
Superior opening (epiglotis) is:
Closed during swallowing
Open during breathing

23. 9 Cartilages of the Larynx
Thyroid cartilage
Shield-shaped, forms laryngeal prominence (= Adam’s apple)
3 pairs of small cartilages
Arytenoid cartilages
Corniculate cartilages
Cuneiform cartilages
Epiglottis
Tips inferiorly during swallowing

24. The Larynx Vocal ligaments of the larynx Epithelium of the larynx:
Vocal folds (= true vocal cords)
Function in sound production
Vestibular folds (= false vocal cords)
No role in sound production
Epithelium of the larynx:
Stratified squamous  superior portion
Pseudostratified ciliated columnar  inferior portion

25. Anatomy of the Larynx Body of hyoid bone Laryngeal prominence
(Adam’s apple)
Cricoid cartilage
Sternal head
Clavicular head
Sternocleidomastoid
Clavicle
Jugular notch
(a) Surface view
Epiglottis
Body of hyoid bone
Thyrohyoid
membrane
Thyroid cartilage
Laryngeal prominence
(Adam’s apple)
Cricothyroid ligament
Cricoid cartilage
Cricotracheal ligament
Tracheal
cartilages
(b) Anterior view

26. Anatomy of the Larynx Epiglottis Hyoid bone Thyrohyoid membrane
Corniculate cartilage
Thyroid
cartilage
Arytenoid cartilage
Cricoid cartilage
Glottis
Tracheal cartilages
(c) Photograph of cartilaginous framework of the larynx, posterior view
Epiglottis
Thyrohyoid
membrane
Body of hyoid bone
Thyrohyoid membrane
Cuneiform cartilage
Fatty pad
Corniculate cartilage
Vestibular fold
(false vocal cord)
Arytenoid cartilage
Thyroid cartilage
Arytenoid muscle
Vocal fold
(true vocal cord)
Cricoid cartilage
Cricothyroid ligament
Cricotracheal ligament
Tracheal cartilages
(d) Sagittal section (anterior on the right)

27. Movements of the Vocal Cords
Anterior
Thyroid cartilage
Cricoid cartilage
Vocal ligaments
of vocal cords
Glottis
Lateral
cricoarytenoid muscle
Arytenoid cartilage
Corniculate cartilage
Posterior
cricoarytenoid muscle
Posterior
Base of tongue
Epiglottis
Vestibular fold
(false vocal cord)
Vocal fold
(true vocal cord)
Glottis
Inner lining of trachea
Cuneiform cartilage
Corniculate cartilage
(a) Vocal folds in closed position; closed glottis
(b) Vocal folds in open position; open glottis

28. The Larynx Voice production Sphincter function of the larynx
Length of the vocal folds changes with pitch
Loudness depends on the force of air across the vocal folds
Sphincter function of the larynx
Valsalva’s maneuver  straining
Innervation of the larynx
Recurrent laryngeal nerves (branch of vagus)

29. The Trachea Descends into the mediastinum
C-shaped cartilage rings keep airway open!
Carina
Marks where trachea divides into 2 primary bronchi
Epithelium 
Pseudostratified ciliated columnar epithelium
~remember this?

30. The Trachea Mucosa Pseudostratified ciliated columnar epithelium
Lamina propria
(connective tissue)
Submucosa
Seromucous gland
in submucosa
Posterior
Hyaline cartilage
Mucosa
Esophagus
Submucosa
(b) Photomicrograph of the tracheal wall (250)
Trachealis
muscle
Lumen of
trachea
Seromucous gland
in submucosa
Hyaline cartilage
Adventitia
Anterior
(a) Cross section of the trachea and esophagus

31. Bronchi in the Conducting Zone
Bronchial tree
Extensively branching respiratory passageways
Primary bronchi (main bronchi)
Largest bronchi
Right main primary bronchi
Wider & shorter than the left
Right lung also bigger than the left

32. Bronchi in the Conducting Zone
Superior lobe
of right lung
Trachea
Superior lobe
of left lung
Left main
(primary)
bronchus
Lobar
(secondary)
bronchus
Segmental
(tertiary)
bronchus
Inferior lobe
of left lung
Inferior lobe
of right lung
Middle lobe
of right lung
(a) The branching of the bronchial tree

33. Bronchi in the Conducting Zone
Secondary (lobar) bronchi
Three on the right
Two on the left
Tertiary (segmental) bronchi
Branch into each lung segment
Bronchioles
Little bronchi, less than 1 mm in diameter
Terminal bronchioles
Less than 0.5 mm in diameter

34. Bronchi in the Conducting Zone
Mucosa
Pseudostratified
epithelium
Lamina propria
Fibromusculo-
cartilaginous
layer
Lumen
Cartilage plate
Smooth muscle
(b) Photomicrograph of a bronchus (13)

35. Changes in Tissue Along Conducting Pathways
Supportive connective tissues change
C-shaped rings replaced by cartilage plates
Epithelium changes
First, pseudostratified ciliated columnar
Replaced by simple columnar, then simple cuboidal epithelium
Smooth muscle becomes important:
Airways widen with sympathetic stimulation
Airways constrict with parasympathetic stim.

36. Structures of the Respiratory Zone
Consists of air-exchanging structures
Respiratory bronchioles  branch from terminal bronchioles
Lead to alveolar ducts
Lead to alveolar sacs

37. Structures of the Respiratory Zone
Alveolar duct
Alveoli
Alveolar
sac
Respiratory
bronchioles
Terminal
bronchiole
(a)

38. Structures of the Respiratory Zone
Alveolar
pores
duct
Respiratory
bronchiole
Alveoli
sac
(b)

39. Structures of the Respiratory Zone
Alveoli
~300 million alveoli account for tremendous surface area of the lungs!
Surface area of alveoli is ~140 square meters!!!
Why such a large surface area?

40. Structures of the Respiratory Zone
Structure of alveoli
Type I cells  single layer of simple squamous epithelial cells
Surrounded by basal lamina
Alveolar & capillary walls plus their basal lamina form
The Respiratory membrane

41. Anatomy of Alveoli & the Respiratory Membrane
Terminal bronchiole
Respiratory bronchiole
Smooth
muscle
Elastic
fibers
Alveolus
Capillaries
(a) Diagrammatic view of capillary-alveoli relationships

42. Structures of the Respiratory Zone
Structures of alveoli (cont.)
Type II cells  scattered among type I cells
Are cuboidal epithelial cells
Secrete  surfactant (very important!)
Detergent-like molecule, that reduces surface tension within alveoli (prevents them from collapsing)
Alveolar macrophages also present

43. Anatomy of Alveoli & the Respiratory Membrane
Red blood
cell
Nucleus of type I
(squamous
epithelial) cell
Alveolar pores
Capillary O2
Capillary
CO2
Macrophage
Alveolus
Endothelial cell nucleus
Alveolus
Alveolar epithelium
Respiratory
membrane
Fused basement
membranes of the
alveolar epithelium
and the capillary
endothelium
Red blood cell
in capillary
Type I cell
of alveolar wall
Capillary endothelium
Alveoli (gas-filled
air spaces)
Type II (surfactant-
secreting) cell
(c) Detailed anatomy of the respiratory membrane

44. The Respiratory Zone Features of alveoli Surrounded by elastic fibers
Interconnect by way of alveolar pores
Internal surfaces
A site for free movement of alveolar macrophages

45. Gross Anatomy of the Lungs
Major landmarks of the lungs
Apex, base, hilum, & root
Left lung
Superior & inferior lobes
Right lung
Superior, middle, & inferior lobes

46. Gross Anatomy of the Lungs
Anterior View of Thoracic Structures
Intercostal muscle
Rib
Parietal pleura
Apex of lung
Lung
Pleural cavity
Visceral pleura
Trachea
Pulmonary
artery
Thymus
Apex of lung
Left
superior lobe
Left
superior lobe
Left main
bronchus
Right superior lobe
Oblique
fissure
Oblique
fissure
Pulmonary
vein
Horizontal fissure
Right middle lobe
Left inferior
lobe
Left inferior
lobe
Impression
of heart
Oblique fissure
Right inferior lobe
Hilum
Oblique
fissure
Heart
(in mediastinum)
Diaphragm
Aortic
impression
Cardiac notch
Base of lung
Lobules
(a) Anterior view. The lungs flank mediastinal structures laterally.
(b) Photograph of medial view of the left lung

47. Bronchial Tree Right lung Left lung Right superior lobe (3 segments)
Left superior
lobe
(4 segments)
Right
middle
lobe (2
segments)
Right
inferior lobe
(5 segments)
Left inferior
lobe
(5 segments)

48. Blood Supply & Innervation of the Lungs
Pulmonary arteries
Deliver oxygen-poor blood to the lungs
Pulmonary veins
Carry oxygenated blood to the heart
Innervation
Sympathetic, parasympathetic, & visceral sensory fibers
Parasympathetic  constrict airways
Sympathetic  dilate airways

49. Transverse Cut Through Lungs
Posterior
Vertebra
Esophagus
(in mediastinum)
Root of lung
at hilum
Right lung
Left main bronchus
Left pulmonary
artery
Parietal pleura
Left pulmonary vein
Visceral pleura
Left lung
Pleural cavity
Thoracic wall
Pulmonary trunk
Pericardial
membranes
Heart (in mediastinum)
Anterior mediastinum
Sternum
Anterior
(d) Transverse section through the thorax, viewed from above. Lungs, pleural
membranes, and major organs in the mediastinum are shown.

50. The Pleurae (review) A double-layered sac surrounding each lung
Parietal pleura
Visceral pleura
Pleural cavity
Potential space between the visceral & parietal pleurae
Pleurae help divide the thoracic cavity
Central mediastinum
2 lateral pleural compartments

51. Diagram of the Pleurae & Pleural Cavities
Intercostal muscle
Rib
Parietal pleura
Lung
Pleural cavity
Visceral pleura
Trachea
Thymus
Apex of lung
Left
superior lobe
Right superior lobe
Oblique
fissure
Horizontal fissure
Left inferior
lobe
Right middle lobe
Oblique fissure
Right inferior lobe
Heart
(in mediastinum)
Diaphragm
Cardiac notch
Base of lung
(a) Anterior view. The lungs flank mediastinal structures laterally.

52. The Mechanisms of Ventilation
2 phases of pulmonary ventilation
Inspiration  inhalation
Expiration  exhalation

53. Inspiration Volume of thoracic cavity increases
Decreases internal gas pressure
Action of the diaphragm
Diaphragm flattens
Action of intercostal muscles
Contraction raises the ribs

54. Inspiration Deep inspiration requires Scalenes Sternocleidomastoid
Pectoralis minor
Erector spinae  extends the back

55. Expiration Quiet expiration  chiefly a passive process!
Inspiratory muscles relax
Diaphragm moves superiorly
Volume of thoracic cavity decreases
Forced expiration  an active process
Produced by contraction of
Internal & external oblique muscles
Transverse abdominis muscles

56. Changes in Thoracic Volume
Ribs are
elevated and
sternum flares
as external
intercostals
contract.
Diaphragm and intercostal muscles
contract (diaphragm descends and
rib cage rises). Thoracic cavity
volume increases.
Diaphragm moves
inferiorly during
contraction.
External
Changes in
superior-
inferior and
anterior-
posterior
dimensions
Changes
in lateral
(superior
view)
(a) Inspiration
Inspiratory muscles relax (diaphragm rises and
rib cage descends due to recoil of the costal
cartilages). Thoracic cavity volume decreases.
Ribs and
sternum are
depressed as
external
intercostals
relax.
External
Diaphragm moves
superiorly as it relaxes.
(b) Expiration

57. Changes in Thoracic Volume
At rest, no air
movement: Air
pressure in lungs is
equal to atmospheric
(air) pressure. Pressure
in the pleural cavity is
less than pressure in the
lungs. This pressure
difference keeps the
lungs inflated. 1
Trachea
Thoracic wall
Parietal
pleura
Main bronchi
Pleural
cavity
Visceral
pleura
Lung
Pleural
cavity
Thoracic
wall
Lung
Diaphragm
Air
Inspiration: Inspiratory
muscles contract and increase
the volume of the thoracic and
pleural cavities. Pleural fluid in
the pleural cavity holds the
parietal and visceral pleura close
together, causing the lungs to
expand. As volume increases,
pressure decreases and air flows
into the lungs.
At rest 2 V
Expanded P V P
Air flows in
Air 3
Expiration: Inspiratory
muscles relax, reducing thoracic
volume, and the lungs recoil.
Simultaneously, volumes of the
pleural cavity and the lungs
decrease, causing pressure to
increase in the lungs, and air
flows out. Resting state is
reestablished. V V P P
Air flows
out

58. Neural Control of Ventilation
Respiratory center
Generates baseline respiration rate
In the reticular formation of the medulla oblongata
Chemoreceptors
Sensitive to rising & falling oxygen levels
Central chemoreceptors  located in medulla
Peripheral chemoreceptors
Aortic bodies
Carotid bodies

59. Location of Peripheral Chemoreceptors
Brain
Sensory nerve fiber in cranial nerve
IX (pharyngeal branch
of glossopharyngeal)
External carotid artery
Internal carotid artery
Carotid body
Common carotid artery
Cranial nerve X (vagus nerve)
Sensory nerve fiber in
cranial nerve X
Aortic bodies in aortic arch
Aorta
Heart

60. Disorders of Lower Respiratory Structures
Bronchial asthma
A type of allergic inflammation
Hypersensitivity to irritants in the air or to stress
Asthma attacks characterized by
Contraction of bronchiole smooth muscle
Secretion of mucus in airways

61. Disorders of Lower Respiratory Structures
Cystic fibrosis (CF)  inherited disease
Exocrine gland function is disrupted
Respiratory system affected by
Oversecretion of viscous mucus
Pneumonia  infectious disease
Accumulation of fluid in alveoli
Interferes with gas exchange (drowning)

62. Disorders of Lower Respiratory Structures
Chronic obstructive pulmonary disease (COPD)
Airflow into & out of the lungs is difficult
Obstructive emphysema
Chronic bronchitis
History of smoking usually associated

63. Disorders of Lower Respiratory Structures
Figure 22.18

64. Alveolar Changes in Emphysema
Figure 22.19

65. Lung Cancer Most common cause of cancer-related death!
1.3 million deaths/year worldwide
Treated by surgery, radiation, and/or chemotherapy
Symptoms  shortness of breath, coughing (up blood), weight loss
History of smoking or 2nd hand smoke usually associated
14% survival rates

66. Aging of the Respiratory System
The number of glands in nasal mucosa declines
Nose dries
Produces thickened mucus
Thoracic wall becomes more rigid
Lungs lose elasticity
Oxygen levels in the blood may fall
Again…Exercise throughout life important for respiratory health!

67. Questions…. What’s Next. Wed Lecture: Lecture Exam 4
Questions…? What’s Next? Wed Lecture: Lecture Exam 4! Wed Lab: Start Digestive System Mon Lecture: Digestive Sys & class Potluck! ~We’ll eat while we learn about eating & digestion