Lung Volumes Lecture Note PDF

Summary

Presentation covering lung volumes and their different subdivisions (tidal volume, inspiratory reserve volume, expiratory reserve volume, and residual volume). It also introduces some basic lung capacities and explores both restrictive and obstructive respiratory diseases.

Full Transcript

OVERVIEW
ANATOMY AND PHYSIOLOGY
OF THE
PULMONARY SYSTEM
AND THORACIC CAGE.

Prof. Dr./ Mona Abdel Khalek
Dr. Ahmed Abd Elhalim
Anatomy of Respiratory System
The respiratory system consists of organs:
1. Nose

2. Mouth (oral cavity)

3. Pharynx (throat)

4. Larynx (voice box)

5. Trachea (windpipe)

6. Bronchi

7. Lungs
Organs of the Respiratory System

Divided into:
Conducting zone
Respiratory zone
 Nose

Provides an airway for respiration

Moistens and warms air

Filters inhaled air

Resonating chamber for speech
 The Trachea
Descends into the
mediastinum
C-shaped cartilage rings
keep airway open
Carina
Marks where trachea
divides into two primary
bronchi
 Bronchi
Bronchial tree:
Primary bronchi (main bronchi)
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
 Structures of the Respiratory Zone
Consists of air-exchanging structures

Respiratory bronchioles

branched from terminal bronchioles
Lead to alveolar ducts

Lead to alveolar sacs
Gross Anatomy of the Lungs
Major landmarks of the lungs

Apex, Base, Hilum, and Root

Left lung

Superior and inferior lobes
Fissure – oblique

Right lung

Superior, middle, and inferior lobes
Fissures – oblique and horizontal
Anterior View of Thoracic Structures
 The Pleurae
A double-layered sac

surrounding each lung
Parietal pleura

Visceral pleura

Pleural cavity

Potential space between the

visceral and parietal pleurae
The Mechanisms of Ventilation
Two phases of pulmonary ventilation
Inspiration – inhalation

Expiration – exhalation
 Inspiration
The principal muscles are:
1. The diaphragm
2. Intercostal muscles
- Volume of thoracic cavity increases
- Decreases internal gas pressure
-Action of the diaphragm
Diaphragm flattens
-Action of intercoastal muscles
Contraction raises the ribs
 Inspiration
Accessory muscles are typically only used when the body needs to
process energy quickly (e.g. during strenuous exercise, during the
stress response, or during an asthma attack):
Scalenes

Sternocleidomastoid

Pectoralis major

Pectoralis minor

Erector spinae – extends the back
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 and external oblique muscles

Transverse abdominal muscles
 Neural Control of Ventilation
Most important respiratory center

Ventral respiratory group

Located in reticular formation in the medulla oblongata

Neurons generate respiratory rhythm
Lung Volumes and Capacities
6000

IRV

IC
Volume (ml)

VC
VT
TLC

ERV
FRC

RV

0
Primary Lung
Lung Capacities
Volumes
Basic Lung Volumes
There are 4 volume subdivisions:

1. Tidal Volume: TV
2. Inspiratory Reserve Volume: IRV
3. Expiratory Reserve Volume: ERV
4. Residual Volume: RV
Basic Lung Volumes
There are 4 volume subdivisions:

They do not overlap
They can not be further divided
When added together equal total lung capacity
Basic Lung Volumes

Tidal Volume: TV
The amount of gas inspired or

expired with each normal breath.
About 500 ml
Basic Lung Volumes

Inspiratory Reserve Volume: IRV
Maximum amount of additional air that

can be inspired from the end of a normal
inspiration.
Basic Lung Volumes
Expiratory Reserve Volume: ERV
The maximum volume of additional air that

can be expired from the end of a normal
expiration.
 Basic Lung Volumes
Residual Volume: RV
The volume of air remaining in the lung

after a maximal expiration. This is the only
lung volume which cannot be measured
with a spirometer.
 Lung Capacities

Are subdivisions of the total volume

that include two or more of the 4 basic
lung volumes
Lung Capacities

Total Lung Capacity: TLC

Vital Capacity: VC

Functional Residual Capacity: FRC

Inspiratory Capacity: IC
Lung Capacities
Total Lung Capacity: TLC

The volume of air contained in the lungs

at the end of a maximal inspiration.
Called a capacity because it is the sum
of the 4 basic lung volumes
TLC= RV+IRV+TV+ERV
 Lung Capacities
Vital Capacity: VC

The maximum volume of air that can be forcefully
expelled from the lungs following a maximal
inspiration.
Called a capacity because it is the sum of
inspiratory reserve volume, tidal volume and
expiratory reserve volume.
VC= IRV+TV+ERV = TLC - RV
Lung Capacities
Functional Residual Capacity: FRC

The volume of air remaining in the lung
at the end of a normal expiration.
Called a capacity because it equal
residual volume plus expiratory reserve
volume.
FRC= RV+ERV
Lung Capacities
Inspiratory Capacity: IC
Maximum volume of air that can be inspired from
end expiratory position.
Called a capacity because it is the sum of tidal
volume and inspiratory reserve volume.
This capacity is of less clinical significance than the
other three.
IC= TV+IRV
Respiratory Diseases
Restrictive Disease:
Makes it more difficult to get air in to the lungs.

They “restrict” inspiration.

Decreased VC; Decreased TLC, RV, FRC

Includes:

Fibrosis.Sarcoidosis

Muscular diseases

Chest wall deformities.Tumors

Pleural Effusion, Pneumothorax
Respiratory Diseases

Obstructive Disease

Make it more difficult to get air out of the lungs.

Decrease VC; Increased TLC, RV, and FRC

Includes:

Emphysema

Chronic bronchitis

Asthma
 Respiratory Muscles

Primary Accessory

Inspiratory
Primary inspiratory Forced expiration
)any muscle attached Expiratory
)Diaphragm and )Abdominal ms and
to the upper limb and )Abdominal muscles(
external intercostal( internal intercostal (
the thoracic cage (

Scm / scalenii / Pectoralis / Serratus
 Sternal Part: Costal Part:
Narrow Slips Arise From Arise From The Inner
The Back Of The Xiphoid Surfaces Of The Lower 6
Costal Cartilages &Lower
Process As TwoHorizontal
4 Ribs.
Bundle And Then
They Interdigitate With The
Descends To The Central
Transversus Abdominis
Tendon

Lumbar or Vertebral Part:
Each Part Arises From TwoFibrous Arches &
From The Bodies Of The Upper 2-3 Lumbar
Vertebral Bodies & Disc.
Extend to the tip of transverse process of the
same vertebra.
These Arches Are The Medial And Lateral
Arcuate Ligaments.
The diaphragm is the major muscle of

respiration It is a curved, modified
half-dome, muscluofibrous sheet

that separates the thoracic cavity
from the abdominal cavity. The
word diaphragm literally
means, dia that is across, and
phragm means wall.
 The Diaphragm

The body relies on the
diaphragm for normal
respiratory function.
It is accounting for 75% of
the tidal volume which is
achieved by its excursion
during respiration.
 The Diaphragm

Contraction of the diaphragm has
following functions:
▪ Decreasing intrapleural pressure,
▪ Expanding the rib cage through its zone
of apposition by generating positive
intra-abdominal pressure,
▪ Expanding the rib cage using the
abdomen as a fulcrum.
 The Diaphragm

The diaphragm is also
important in performing such
actions as:
blowing out the air, laughing,
singing, whistling, crying,
yawning, coughing, sneezing,
vomiting, defecating, urinating,
and in delivering a baby or
giving birth.
 TheDiaphragmaticTone:

It was revealed that the muscle
spindles definitely present in
the human diaphragm in the
area adjacent to the central
tendon.
 The DiaphragmaticTone:

The natural stimulus for the stretch reflex is the abdominal content
weight in the supine position.

The resultant tonic activity in the diaphragm has a considerable
significance in the maintenance of functional residual capacity and
preventing the viscera from being pushed into the thorax.
Diaphragmlength, velocity of shorteningandpower
Diaphragmatic length is determined by:

Lung volume

Chest wall configuration.

Pre-inspiratory changes in diaphragmatic length are
uniquely determined by abdominal volume. The
diaphragm's main role during exercise is to generate flow
rather than pressure and that its 13% increase in power
from quiet breathing to 70% of maximal workload is due
to mainly an increase in velocity of shortening.
The diaphragm is composed of 55 ± 5% type I fibers (high oxidative, slow
twitch fibers), 20 ± 6% type IIa fibers (high oxidative fast twitch fibers),
and 25% type IIb (low oxidative fast twitch fibers).

These findings might be responsible for the diaphragmatic
endurance capacity and its unique function characteristics.

The increase in the respiratory load results in adaptation in both
endurance and strength

The natural stimulus for the stretch reflex is the abdominal
content weight in the supine position
 The phrenic nerve is the sole motor supply
Phrenic Nerve to the diaphragm. It arises chiefly from the
fourth cervical ramus, so it is formally
considered part of the cervical plexus.
An accessory phrenic nerve may arise
from roots C5 and C6 or from the nerve
to the subclavius muscle
Originating around the level of
the scalenus anterior muscle,
the phrenic nerve courses
inferiorly through the neck
and thorax before reaching
its end point, the diaphragm.
Thus, the phrenic nerve has a
relatively long course before
reaching its final destination.
Phrenic Nerve

The successful impulse of respiratory
stimulus from the brain to the
diaphragm can be compromised by
an interruption of the phrenic nerve
at any point along this course.
 diaphragmatic dysfunction

Mechanical diaphragmatic dysfunction can be caused
by many disorders which can affect the transmission
of the respiratory stimulus from the brain down to

the diaphragm through the phrenic nerve.

If the diaphragm is fatigued due to accumulation of

lactic acid, the result is breathlessness
Fatigue develops when the diaphragm is made to generate
a pressure with each inspiration greater than 40% of the
maximal transdiaphragmatic pressure.

The time limit of human diaphragm was shorter than 60 min.

About 55% of the fibers of human diaphragm were of the
slow twitch high oxidative type I which are fatigue resistant.

Diaphragmatic blood flow increased as the work of
breathing increased.
Respiratory muscle fatigue play a role in the sensation of
Dyspnea.

Dyspnea might occur as a result of either hyperventilation at
a given exercise load or weakness of respiratory muscles

Limitation of exercise capacity in normal subjects might be
due to respiratory muscle fatigue; levels of ventilation
greater than 55% of maximal breathing capacity