Lecture 18: Introduction to Respiration PDF

Summary

This document is a lecture on introduction to respiration, covering the steps of external respiration, the role of the autonomic nervous system in controlling airway resistance, and factors influencing gas diffusion. It also discusses the functions of the conducting zone, and the related concepts of dead space, tidal volume, and alveolar ventilation volume.

Full Transcript

Lecture 18:
Introduction to Respiration

Dr. Ann Revill
[email protected]
Office: Dr. Arthur G.
Dobbelaere Science Hall 380E
 Lecture Objectives
By the end of this lecture, you will be able to:

1. Explain the steps of external respiration
2. Compare and contrast the components and role of the
conducting zone and respiratory zones of the lung
3. Discuss the role of the autonomic nervous system in
controlling airway resistance
4. Determine the factors that will influence diffusion of a gas
(Fick’s Law)
5. Describe dead space and the parameters that contribute
to dead space
6. Calculate tidal volume and alveolar ventilation volume
7. Define minute ventilation, alveolar minute ventilation
8. Calculate minute ventilation, alveolar minute ventilation
2
 Why do humans need a respiratory system?

Remember:
– glucose + O2 → CO2 +
H2O + ATP
Efficient delivery of O2
from air to tissues and
removal of CO2 from
tissues to air

3
What else does the respiratory system do?

Regulate pH
Vocalization
Defense against airborne pathogens
– Removal of inhaled particles

Lungs process certain blood-borne substances
– angiotensin converting enzyme converts angiotensin I to angiotensin II
– enzymes inactivate bradykinin and some prostaglandins
– certain immunoglobulins (IgA) are released

4
 Steps of external respiration
Atmosphere
1. Ventilation between atmosphere and
alveoli

2. Exchange of O2 and CO2 between air
in alveoli and blood

3. Transport of O2 and CO2 between
lungs and tissue

4. Exchange of O2 and CO2
between blood and tissue
Sherwood 13-1
5. Internal respiration 5
 Steps of external respiration
Atmosphere
1. Ventilation
Is ventilation rate constant?
No – can be adjusted to meet body’s
need for O2 uptake, CO2 removal
2. Gas exchange
By which process is gas exchanged?
diffusion
3. Transport of O2 and CO2
How is O2 transported?
Primarily bound to hemoglobin
How is CO2 transported?
Primarily as bicarbonate
4. Gas exchange
5. Internal respiration

Sherwood 13-1
Where does this occur? mitochondria 6
 Organization of the respiratory system
Respiratory system structures:
Upper Airways
– Nasal and oral cavities
– Pharynx
– Larynx (vocal cords)
Trachea
Lungs
– Bronchi ➔ bronchioles ➔ alveoli
– Smooth muscle & connective tissue
– Pulmonary circulation
Muscles of respiration
Rib cage and pleura
Parts of CNS that regulate respiration
7
Sherwood 13-2
 Functional Anatomy
Gen #

Conducting zone
(anatomical dead
space, ~150 ml)

Respiratory zone
(exchange zone, alveolar
ventilation volume)

West 1-4 (c.f. Costanzo 5-1)
8
 Conducting zone
Role is to move air into/out of
respiratory zone for gas
exchange

Functions:
humidification and
warming of air stream
removal of dust
– Cilia and mucous
secreting cells
decreases velocity of
airflow

9
How does the ANS control conducting
airway tone?
Smooth muscle of bronchi and bronchioles is controlled
by the ANS
– SNS → adrenergic 2 receptor activation on bronchial
smooth muscle
airway dilation
What happens to airway resistance?
decreases
– PNS → cholinergic M3 receptor activation on bronchial
smooth muscle
Airway constriction
What happens to airway resistance?
increases

10
Which disease is caused by inappropriate
airway muscle tone? What are treatment
options?
Asthma
Asthma attacks due to broncoconstriction
Associated with chronic inflammatory condition
commonly treated with albuterol (2 adrenergic receptor agonist)

West 4-13 11
 Pulmonary vasculature
Pulmonary artery receives all of
the right heart output
– Pulmonary blood pressure is low
(arterial pressure ~15 mmHg)
– Since cardiac output is still 5-
6L/min, what does this mean for
surface area of entire pulmonary
circulation?
Large surface area, low resistance
Pulmonary blood flow not
distributed evenly when we’re
standing
– Due to gravity
– Lowest at top of lung and highest at
bottom of lung

12
 13
Sherwood 13-2
 Respiratory zone =
Respiratory bronchioles + alveoli
Movement of gas
mainly via diffusion
– From high pressure
to low pressure
– CO2 into alveoli
– O2 out of alveoli

Design feature:
increase surface area
for diffusion
14
Sherwood 13-2
 What makes up
an alveolus?
Type I alveolar cell
– Alveolar epithelium
Type II alveolar cell
– Synthesize pulmonary
surfactant
Alveolar macrophages
– Instead of cilia

300 million alveoli/lung
Alveolar diameter ~200 μm
Total alveolar surface area?
~50-100 m2 (aka tennis
court!)
15
Sherwood 13-4
Blood gas diffusion across alveolar-capillary
interface

Red blood cells spend ~0.75 s in capillary,
traversing 2-3 alveoli
Diffusion distance is small (0.5 μm)
– Three layers: alveolar epithelium, interstitial fluid,
capillary endothelium
16
Sherwood 13-4
 Diffusion of gases: Fick’s Law
Vx = volume of gas diffused per unit time
Vx = D x A x ΔP D = diffusion coefficient of the gas
A = surface area
ΔX ΔP = partial pressure difference of the gas
ΔX = membrane thickness
Diffusion directly proportional to:

Diffusion coefficient
Surface area
Pressure gradient

Diffusion inversely proportional to:
Membrane thickness
(diffusion distance)

How does this relate to the alveolar-
capillary barrier?

Thin walls and huge surface area 17
Clinical connection: factors that
affect gas diffusion rate
What do you think would happen to the rate of gas diffusion
for the following conditions and why?

1. Increased fibrotic tissue in the respiratory zone of the lung
due to restrictive lung disease?
Decreased, due to increased diffusion distance
2. A lung resection due to removal of a cancerous lung lobe?
Decreased, due to decreased surface area
3. A person visits Cuzco, Peru?
Decreased, due to decreased pressure gradient
4. Your friend goes for a run?
Increased, due to increased surface area

18
 Tidal volume
Humans use tidal How do we adjust for
ventilation increased metabolic demand
– air moves bidirectionally into during exercise?
and out of lungs by same We can adjust breathing rate,
path
or tidal volume
Tidal volume = amount of
air that moves in and out
per breath during normal
breathing
What’s the challenge with tidal breathing?
Dead space!
Inspired breath (500 ml) Expired breath (500 ml)

Airway
(150 ml)

Lung

End-expiration Inspiration End-inspiration End-expiration
20
 What is dead space?
Volume of airways and lungs not involved
in gas exchange

Anatomical dead space Physiological dead space

21
 Anatomical dead space
What makes up anatomical dead space?
Nasal cavity, trachea, bronchi, bronchioles (branches 0-16)

In other words: volume of gas in conducting airways

Typically estimate dead space as 1 ml per 1b
weight
– Therefore, ~150 ml for a 150 lb person

22
 Physiological dead space
Total volume of lungs not participating in gas exchange

Physiological = Anatomical Alveolar
dead space dead space + dead space

Alveolar Dead Space
– alveoli that are ventilated but not perfused
– pulmonary capillaries are not all open at a given time
– some pathologies increase alveolar dead space (e.g. pulmonary
emboli)

Normally:

– physiological dead space ≈ anatomical dead space

23
 Tidal volume (VT) and alveolar
ventilation volume (VA)
VT = VD + VA

Dead space volume (VD):
– amount of VT not available for gas exchange

Alveolar ventilation volume (VA): VA = VT - VD
– amount of VT available for gas exchange

24
 Ventilation rates
Minute ventilation (V)
– Total volume moved into and out of lung per minute
– V a poor estimate of gas exchange because of dead
space (VD)

V = VT x (breaths/min)
Alveolar (functional) minute ventilation (VA):
– Corrects for physiologic dead space
– Provides a better estimate of gas exchange

VA = VA x (breaths/min)
25
 Example ventilation calculations
During a routine medical exam, the following ventilation parameters
were obtained for a pharmacy student:

Respiratory rate: 12 breaths/min
Tidal volume (VT): 500 ml
Dead space volume (V D): 150 ml

Calculate:
minute ventilation alveolar minute ventilation
V = VT x (breaths/min) VA = VT - VD VA = 500-150 ml
= 350 ml
Minute ventilation
= 500 ml x 12 breaths/min
V = 6000 ml/min
VA = VA x (breaths/min)

Alveolar minute ventilation:
= 350 ml x 12 breaths/min
VA = 4200 ml/min 26