HUBS192 Lecture 17: The Work of Breathing (2024) Lecture Notes PDF

Summary

These lecture notes cover the work of breathing, including Boyle's Law, pulmonary function, and different breathing issues. Study guides, objectives, and illustrations are included, suitable for undergraduate-level physiology courses.

Full Transcript

HUBS192 Lecture Material

This pre-lecture material is to help you prepare for the
lecture and to assist your note-taking within the lecture,
it is NOT a substitute for the lecture !

Please note that although every effort is made to ensure this pre-lecture
material corresponds to the live-lecture there may be differences / additions.
 HUBS 192
Jeff Erickson – Department of Physiology

Lecture 17
The Work of Breathing
 GET IT IN
KEEP IT GOING

GET IT ACROSS

GET IT AROUND

Patton & Thibodeau, Anatomy and Physiology (8th ed), Figure 27-1, pg 825.
2
 Objectives and Study Guide
After this lecture you should be able to:

Use Boyle’s Law to describe how we are able to inhale
and exhale.
Describe the two opposing forces that must be
overcome to take a breath.
Identify the volumes and capacities on a spirometry
trace.

Related reading: Martini et al. Modules 21.9-21.11
(p. 854-859)

3
 Quantifying liquids vs. gases
Liquids are usually quantified Gases are usually quantified
in terms of volume in terms of pressure

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.9, pg 854.
4
 Boyle’s Law
The pressure of a gas is inversely related to it’s volume

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.9, pg 854.
5
 Creating a pressure gradient

Gas will move from high pressure to low pressure
Right before a breath, the pressure outside the body
and inside the lungs are equal, so no air is moving
Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.9, pg 854.
6
 Creating a pressure gradient

As you inhale, your diaphragm drops while
your rib cage expands

This increases the volume in your chest, which
lowers the pressure

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.9, pg 854.
7
 Creating a pressure gradient

Inhalation Exhalation

Volume is increasing Volume is decreasing
Pressure inside the lungs is Pressure inside the lungs is
decreasing increasing
Pressure outside is now greater Pressure outside is now lower
than inside, so air rushes in than inside, so air rushes out

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.9, pg 855.
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 The Work of Breathing

Two opposing forces that must be overcome to take a breath:

1. Stiffness of the lungs
Lungs must expand to take in air
How compliant are the lungs?
Surface tension holds lungs in place

2. Resistance of the airways to the lungs
Need to move the air from outside to the alveoli
How much resistance is the respiratory tract putting on
the movement of air?

9
 Lung stiffness is related to Compliance
Compliance = V/P
Lung Volume (L)

10
 Lung stiffness is related to Compliance

Pulmonary Fibrosis

Thickening and scarring of the alveolar membranes
Can arise from chronic inflammation or exposure to
industrial chemicals 11
 Lung stiffness is related to Compliance
Compliance = V/P
Lung Volume (L)

12
 Fluids surrounding the lungs exert surface tension

Alveoli are lined with fluid that exert surface tension

Walls of alveoli are very thin, enhancing this effect

Must overcome surface tension to expand the lungs

13
 Alveoli produce surfactant to disrupt surface tension

Relieves surface tension and allows the alveoli to expand
during a breath
Failure to produce adequate surfactant results in difficulty
in expanding the lungs and reduced oxygen intake
Premature infants don’t produce surfactant, resulting in
respiratory distress syndrome (RDS)
14
 Example exam question

Which of the following statements about the work of
breathing is NOT CORRECT?

A. The chest and lungs expand during inhalation.
B. The alveoli release surfactant to overcome surface
tension from the surrounding fluid.
C. Low compliance of the lungs allows them to more
easily fill with air.
D. Thickening and scarring of the alveolar membranes
can lead to a reduction in lung compliance.

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 The Work of Breathing

Two opposing forces that must be overcome to take a breath:

1. Stiffness of the lungs
Lungs must expand to take in air
How compliant are the lungs?
Surface tension holds lungs in place

2. Resistance of the airways to the lungs
Need to move the air from outside to the alveoli
How much resistance is the respiratory tract putting on
the movement of air?

16
 Airway resistance through the respiratory tract

Need to move air from
outside to the alveoli

Air is conducted through
the bronchi and
bronchioles

Exert force (friction) on
the air that must be
overcome

17
18
 Resistance to blood flow and vessel radius
Luminal radius

1 1
R = r = (0.5d) 4 4
d
r r
d

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 19.6, pg 748.
19
 Resistance to air flow and bronchial radius
Luminal radius

1 1
R = r = (0.5d) 4 4
d
r r
d

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 19.6, pg 748.
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Obstructive versus restrictive issues with breathing

Reduced lung compliance (e.g. fibrosis)
Insufficient surfactant release

REDUCED LUNG CAPACITY

Obstructive vs. Restrictive
RESISTANCE TO AIRFLOW

Asthma
Chronic bronchitis
21
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 Spirometry: The Pulmonary Function Test

A spirometer measures
volume inspired / exhaled

Common, simple test

Can measure how much
and how fast you breathe

Test response to therapy

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 Spirometry Trace

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.10, pg 857.
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 Spirometry Trace Volumes
Tidal volume (VT)
Volume of air moved in and out during normal quiet breath

Inspiratory reserve volume (IRV)
Extra volume that can be inspired with maximal inhalation

Expiratory reserve volume (ERV)
Extra volume that can be exhaled with maximal effort

Residual volume
Volume remaining in lungs after maximal exhalation

Minimal volume
Volume remaining in lungs if they collapsed
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 Spirometry Trace
Inspiratory Reserve
Volume (IRV)

Tidal volume
(VT)

Expiratory
Reserve Volume
(ERV)

Residual
Minimal Volume Volume

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.10, pg 857.
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 Spirometry Trace Capacities
Vital capacity
Inspiratory reserve + Expiratory reserve + Tidal volume
Volume of air you can shift in and out of your lungs

Total lung capacity
Vital capacity + Residual volume
Total volume in lungs when you’ve filled them to max

Inspiratory capacity
Inspiratory reserve + Tidal volume
Total volume of air you can inspire from rest

Functional residual capacity
Expiratory reserve + Residual volume
Volume remaining in lungs after normal exhalation
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 Spirometry Trace
Inspiratory Capacity
Inspiratory Reserve
Volume (IRV)

Vital
Tidal volume Capacity
(VT)

Expiratory
Reserve Volume Functional
(ERV) residual
capacity

Residual
Minimal Volume Total Lung Volume
Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.10, pg 857.
Capacity
27
 Spirometry Trace – Both volume and rate matter!

Forced expiratory volume in one second FEV1
i.e How much of the vital capacity (VC) comes out in first second

Reduced with diseases causing resistance to airflow (ex. asthma)

FEV1/VC ratio
Normal ~ 80% < 0.70 indicates airways obstruction

28
28
 Spirometry Trace Worksheet – Match the term on the left to the
definition on the right
Volume remaining in lungs if they
Tidal volume collapsed

Extra volume that can be exhaled with
Inspiratory reserve volume maximal effort

Volume of air you can shift in and out of
Expiratory reserve volume your lungs

Residual volume Volume of air moved in and out during
normal quiet breath

Minimal volume Total volume of air you can inspire from
rest
Inspiratory capacity Volume remaining in lungs after normal
exhalation
Total lung capacity
Extra volume that can be inspired with
maximal inhalation
Vital capacity
Total volume in lungs when you’ve filled
them to max
Functional residual capacity
Volume remaining in lungs after maximal
exhalation 29
Spirometry Trace Worksheet – Fill in the Leaders with the correct Volume
or Capacity

Martini et al., Visual Anatomy and Physiology (3rd ed), Module 21.10, pg 857.
30
 Summary
Changes in chest volume create a pressure differential
that drives air in and out of the lungs during breathing.

The stiffness of the lungs and the resistance of the
airways must be overcome to breathe.

Spirometry is a test to measure pulmonary function and
yields a complex trace with a number of volumes and
capacities.

Because spirometry measures both volume and rate of
inhalation/exhalation, it can discern between
obstructive and restrictive issues.

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 Example exam question

Which of the following best describes the vital capacity?

A. Volume remaining in lungs if they collapsed
B. Volume of air moved in and out during normal quiet
breath
C. Total volume in lungs when you’ve filled them to max
D. Volume of air you can shift in and out of your lungs

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 HUBS192

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