[PHYSIO]LEC_201_VENTILATION.pdf

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(001) VENTILATION
DR. DOMINETTA S. GONZALO | 11/30/20

OUTLINE
I. VENTILATION
A. Elements
B. Minute Ventilation
C. Goals of Ventilation
II. LUNG VOLUMES AND CAPACITIES
III. PATTERNS OF VENTILATORY DYSFUNCTION
A. Obstructive Defect
B. Restrictive Defect
IV. INGREDIENTS FOR PROPER VENTILATION
V. VENTILATION AND DISORDERS IN
VENTILATION
VI. LABORATORY WORKSHEET & SAMPLE CASE

I. VENTILATION
Ventilation is the process by which atmospheric air moves Figure 1. Relationship between the frequency of breathing or
into the lungs and out of the alveoli respiratory rate and the tidal volume
More specifically, oxygen from the mixture of gases in the
atmosphere enters the alveolar circulation and carbon Tidal volume affects the minute ventilation
dioxide as a result of cellular metabolism gets removed More emphasis in CO2 elimination than Alveolar
from the lungs in the same process. Oxygenation (more discussed in the process of gas
Ventilation happens in two processes: INHALATION AND exchange).
EXHALATION, a complex function that involves an Tidal volume, I:E Ratio and Exp time affects
interplay of the ventilatory organs driven by pressure FREQUENCY. And the resultant changes affect the
gradient. MINUTE VENTILATION.
Disorders in ventilation results in the inability of the body Pressure gradient, Time constant, Compliance and
to remove carbon dioxide thereby accumulating in the Resistance affects the TIDAL VOLUME.
blood in a condition known as HYPERCARBIA. Any changes involving the Tidal volume and the
Frequency will affect and alter the MINUTE
A. ELEMENTS VENTILATION.
4 elements are needed for the respiration to commence If there is a decrease or ineffectivity of Minute Ventilation,
o Atmospheric/ambient air then, CO2 Elimination will be affected.
o Thoracic pump
- Ventilatory organs/organs of respiration C. GOALS OF VENTILATION
o Air conduit
- Refers to process or passages of the respiratory
tract that are responsible for air to go in and out the
lungs (Nostrils down to the respiratory
bronchioles).
o Alveoli
- Where the gas exchange occurs

B. MINUTE VENTILATION
Also known as alveolar equation
Product of tidal volume (TV) and respiratory rate (RR)
MV = TV x RR
o Where:
MV– minute ventilation Figure 2. Main goal of ventilation and the relationship of frequency
TV– Tidal volume of breathing
RR – Respiratory rate
Alveolar oxygenation
In a 60 kg man, NORMAL VOLUME (NV) is equivalent to
CO2 elimination
6-8 liters per minute
The relationship of frequency of breathing/respiratory rate
and the tidal volume, affects the minute ventilation.
Moreover, in ventilation, CO2 elimination is more
emphasized rather than alveolar oxygenation, because
alveolar oxygenation is more discussed in the process of
gas exchange compared to ventilation.
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II. LUNG VOLUMES AND CAPACITIES Diseased/ abnormal/ obstructed airway → OBSTRUCTIVE
DEFECT → ↓AIRFLOW (volume/time)

A. RESTRICTIVE DEFECTS
If the removal of CO2 is due to an impediment in the
normal expansion of the ventilatory organs.
P Pleura*
A Alveoli
I Interstitium
N Neuromuscular*
T Thoracic Cage*
Table 1. Thoracic pump* / lungs. Any disorder affecting the
(THORACIC PUMP: PAINT) will present a ventilatory dysfunction
Figure 3. Interpretation of lung volumes and capacities
TOTAL LUNG CAPACITY (TLC) Affected thoracic pump → Inability to expand alveoli →
o The entirety of gas in the lungs or air in the lungs at RESTRICTIVE DEFECT → ↓ LUNG VOLUME
any given time
o Subdivided into: *memorize structure Included/classified as the thoracic pump
- VITAL CAPACITY (VC) (acronym: PAINT)
- RESIDUAL VOLUME (RV)
TIDAL VOLUME (TV) IV. INGREDIENTS FOR PROPER VENTILATION
o Refers to the volume of air that goes in and out of the Thoracic pump must be efficient, effective in expanding
lungs in a normal, relax/quiet breathing. the alveoli and that the airway should also be unobstructed
INSPIRATORY RESERVE VOLUME (IRV) for the passage of air from the atmosphere down into the
o Inhaling beyond the Tidal Volume. alveoli.
EXPIRATORY RESERVE VOLUME (ERV)
o Exhaling beyond the Tidal Volume. V. VENTILATION AND DISORDERS IN
RESIDUAL VOLUME (RV) VENTILATION
o Remaining air that stays in the alveoli after a forceful We look particularly in CO2 elimination rather than
exhalation or expiration (remember that the lungs or oxygenation.
alveolar sacs are not completely emptied after each We can determine that there are 2 patterns of ventilation
exhalation). base on which ingredient is affected.
o It is remaining amount of air to maintain alveolar
inflatability. VI. LABORATORY WORKSHEET & CASE
o It cannot be measured. 1. Fill up the table below based on your observations.
Capacities are combination of volumes.
INSPIRATORY CAPACITY (IC) – IRV and TV. Open Straw Tied Straw
FUNCTIONAL RESIDUAL CAPACITY (FRC) – ERV and 1.Ease of Laminar airflow Turbulent airflow
RV. airflow
All the lung volumes and capacities can be measured
directly or indirectly. 2.Movement Smooth, stable/ steady Unsteady/ unstable
of balls
The capacities or lung volumes that cannot be measured
are those that are involved in RV. The RV can only be
3.Effort of Effortless Exerts greater effort
surmised by inference. The FRC, VC and TLC are blowing
measured by inferences.
Comments The lower the The higher the
pressure/ effort pressure/ effort
III. PATTERNS OF VENTILATORY DYSFUNCTION needed to move air, needed to move air,
A. OBSTRUCTIVE DEFECTS the lesser the airway the greater the airway
When the removal of CO2 from the body is limited by resistance. resistance.
narrowing of the airways by way of mechanical and
2. In a hypothetical situation, with regards to lung volumes,
dynamic obstruction
which portion of the total lung capacity contributed largely
o AIRWAYS with the movement of ping pong balls when the straw is
- nostrils → nasal passages → trachea → tracheal open? How about when the straw is tied? Explain your
bronchi tree → bronchioles → alveoli answer briefly.
- so, if there is an obstruction in any form, along these Movement of ping pong balls- Vital Capacity (IRV, TV,
structures, then we expect a hindrance to free ERV) Tied straw- Increased Vital capacity (IRV, TV, ERV)
passage of air. and Functional Residual volume (ERV, RV) because of
increased effort in blowing air, thus maximizing expiration.

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3. List the lung functions measured in a spirometry and 2. Expiratory Reserve Volume (ERV):
their significance. A. is the maximal amount of air that can be exhaled from
Forced vital capacity (FVC) the lungs after a normal expiration.
- The total volume and largest amount of air that you B. is very small and unimportant in normal respiration.
can forcefully exhale after breathing in as deeply as C. is kept at a low volume so that the vast bulk of the
you can. alveolar gas can be replaced with fresh air during the next
- A lower than normal FVC reading indicates restricted inspiration.
breathing. 3. Residual Volume (RV):
Forced expiratory volume (FEV) A. is mostly found in the anatomical dead space.
- This is how much air you can force from your lungs in B. is the volume of gas left in the respiratory system after
one second. exhaling maximally.
- Lower FEV-1 readings indicate more significant C. makes no contribution to maintaining the patency of the
obstruction. alveoli and terminal airways.
4. Vital Capacity (VC):
SAMPLE CASE: A. is a measure of the maximum volume of gas in the
A 26-year-old female came to the ER with cough and shortness of respiratory system that can be exchanged with each
breath. She has been nursing a cold for the past 3 days and she breath.
took nasal decongestants to relieve her symptoms. She had B. is a measure of the volume of gas normally exchanged
childhood asthma and her last attack was during high school. She with each breath.
is allergic to penicillin. On PE, she prefers to sit up on the bed. She C. is a measure of the amount of gas that it is vital to retain
is speaking in phrases and is agitated. She has generalized in the respiratory system at the end of expiration.
expiratory wheezing upon auscultation. 5. Total Lung Capacity (TLC):
A. is a measure of the volume of gas in the respiratory
4. Explain why there is wheezing during exhalation. system at the end of a maximal inspiration.
Airflow through a narrowed or compressed segment of a B. Increases as the frequency of breathing increases.
small airway becomes turbulent, causing vibration of airway C. is constant in amount from person to person.
walls; this vibration produces the sound of wheezing. 6. In the respiratory system, the major difference
Wheezing is more common during expiration because between a volume and a capacity is that:
increased intrathoracic pressure during this phase narrows A. a capacity is the sum of at least two volumes.
the airways and airways narrow as lung volume decreases. B. a volume is the sum of at least two capacities.
5. Which type of ventilation dysfunction is exhibited by the C. Their units are different.
patient? 7. Forced Expired Volume in one second (FEV1):
Asthma causes severe airway obstruction. The patient A. has the units of liters per minute.
has difficulty to expire than to inspire because the closing B. is the same whatever the starting volume in the airways.
tendency of the airways is greatly increased by the extra C. Provides a measure of the resistance of the airways to
positive pressure required in the chest to cause expiration. flow.
6. What is expected in the blood gas analysis of the patient? 8. During normal resting respiration, in the same breath:
By observing the patient, the expected blood gas analysis A. The volume of the exhaled gas exceeds that of the
of the patient is Respiratory alkalosis because hyperventilation inhaled gas.
thru shortness of breath causes the patient to blow off extra B. The temperature of the exhaled gas is the same as that
CO2. of the inhaled gas.
Expected blood gas laboratory results are: C. The water content of the exhaled gas is that same as
pH: >7.45 that of the inhaled gas.
pO2: >80-100mmHg
pCO2: 22-26 meq/L (may depend on

7.
compensation status)
If spirometry is performed at this state, what parameters
REFERENCES
will be affected and how? 1. Berne, R. M., Koeppen, B. M., & Stanton, B. A.
In an obstructive disease, such as asthma, both forced (2010). Berne & Levy Physiology. Philadelphia, PA:
expiratory volume (FEV1) and forced vital capacity (FVC) are Mosby/Elsevier.
decreased, with the larger decrease occurring in FEV1. 2. Costanzo, L. S. (2014). Physiology (Fifth edition.).
Therefore, the FEV1/FVC ratio is decreased. Poor ventilation Philadelphia, PA: Saunders/Elsevier.
of the affected areas decreases the ventilation/perfusion (V/Q) 3. Guyton, A.C., Hall, J. E. Guyton and Hall Textbook
ratio and causes hypoxemia. The patient’s residual volume of Medical Physiology. 13th ed., W B Saunders, 2015.
(RV) will be increased because of breathing at a higher lung 4. https://www.msdmanuals.com/professional/pulmonary-
volume to offset the increased resistance of his airways. disorders/symptoms-of-pulmonary-disorders/wheezing
5. https://oxfordmedicine.com/view/10.1093/med/97801996
00830.001.0001/med-9780199600830-chapter 114
TEST YOUR KNOWLEDGE
1. Tidal volume (VT):
A. is the volume breathed in each minute.
B. is the volume breathed in each breath.
C. is unaffected by the frequency of breathing.

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READING ASSIGNMENT (CHAPTER 22) Patterns Laminar Turbulent
DYNAMIC LUNG AND CHEST WALL MECHANICS Flow Flow
Gas Parallel to airway Parallel &
OUTLINE movements walls perpendicular to the
I. AIRFLOW IN AIRWAYS axis of tube
A. 2 Major Patterns of Gas Flow in the Flow rates in Low and steady High
which they flow rates flow rates
Airways
are present
B. Reynolds Number Characteristic Streamlined Disorganize/Disordered
II. AIRWAY RESISTANCE of Flow (from eddy currents)
A. Factors that Contribute to Airway streams
Resistance Airways in Smaller airways Larger airways
which they (e.g. nose, mouth,
B. Other Factors that Affects Airway flow glottis, bronchi,
Resistance trachea)
III. NUEROHUMORAL REGULATION OF AIRWAY Table 2. Difference between the 2 major patterns of gas flow in the
RESISTANCE airways.
A. Pathway The pressure-flow characteristics of laminar flow (applied
B. Reflex Stimulation of the Vagus Nerve to both liquid and air):
IV. MEASUREMENT OF EXPIRATORY FLOW o Flow Rate (V̇) – defined by the following equation:
A. The Spirogram
B. Flow-Volume Loop
V. DETERMINANTS OF MAXIMAL FLOW
VI. FLOW LIMITATION AND THE EQUAL o P = driving pressure
PRESSURE POINT o r = radius of tube
o η = viscosity of fluid
VII. DYNAMIC COMPLIANCE o l = length of tube
VIII. WORK OF BREATHING P is proportional to the V̇, thus the greater the pressure,
the greater the flow
I. AIRFLOW IN AIRWAYS Flow resistance (R) = change in driving pressure (ΔP)
divided by the V̇
Air flows in & out when there is a pressure difference at
the two ends of the airway
Inspiration = diaphragm contracts > pleural pressure
becomes more negative > gas flows into the lung
gas exchange depends on the speed at which fresh gas is η increases with increasing gas density, therefore the
brought to the alveoli and the rapidity with which the CO2 pressure drop will increase for a given flow
(metabolic pact of respiration) are removed to meet the Higher P is needed to support a given Turbulent flow
metabolic needs of body than to support a similar Laminar flow
2 major factors that determines speed of gas flows into
the airways (with pressure changes): A. REYNOLDS NUMBER
o Gas flow pattern
A dimensionless value that expresses the ratio of two
o Airway resistance to airflow
dimensionally equivalent terms
Whether flow through a tube is laminar or turbulent,
A. 2 MAJOR PATTERNS OF GAS FLOW IN THE depends on the Re
AIRWAYS
LAMINAR FLOW– it is silent which makes small airway
disease difficult to hear with a stethoscope
TURBULENT FLOW– breath sounds heard with a
stethoscope reflect this turbulent airflow

o d = fluid density
o v = average velocity
o r = radius
o η = viscosity
In straight tubes, turbulence occurs when Re is >2000
From this relationship, turbulence is most likely to occur
when the v of the GAS FLOW is HIGH and the RADIUS is
LARGE
In contrast, a LOW-DENSITY GAS (helium) is less likely
to cause turbulent flow

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clinically relevant in states of increased airway resistance B. OTHER FACTORS THAT AFFECTS AIRWAY
where a DECREASE in gas DENSITY can improve airflow RESISTANCE
(e.g., substituting helium for nitrogen in inspired air)
INCREASES AIRWAY RESISTANCE
o airway mucus
II. AIWAY RESISTANCE o Edema
is regulated by various neural and humoral agents o bronchial smooth muscle contraction
2nd major factor that determines rates of airflow in the -all of which ↓. the caliber of the airways
airways o ↑ density and viscosity of the inspired gas
Airflow resistance in the airways (Raw) differs in airways of -can exacerbate asthma and COPD
different size DECREASES AIRWAY RESISTANCE
o Trachea to Alveolus – individual airways become o Breathing a low-density gas (oxygen-helium mixture)
smaller + number of airway branches increases -exploited in the treatment of Status
dramatically Asthmaticus (a condition that ↑ airway
o Raw is equal to the sum of the resistance of each of resistance due to bronchospasm, airway
these airways (Raw = Rlarge + Rmedium + Rsmall) inflammation, and hypersecretion of mucus)
The Major site of resistance along bronchial tree:
o FIRST EIGHT GENERATIONS OF AIRWAYS III. NEUROHUMORAL REGULATION OF AIRWAY
RESISTANCE
A. PATHWAY
Stimulation of efferent Vagal Fibers (either directly or
reflexively)
↑ airway resistance and ↓ anatomic dead space (see
Chapter 23)
secondary to airway constriction (recall that the vagus
nerve innervates airway smooth muscle).
Stimulation of Sympathetic Nerves
Release of the postganglionic neurotransmitter,
NOREPINEPHRINE
o Inhibits airway constriction = BRONCHODILATION
Note: Vagus Nerve stimulation causes airway constriction
(bronchoconstriction) while Norepinephrine causes airway
dilation (bronchodilation)

B. REFLEX STIMULATION OF THE VAGUS NERVE
Results in AIRWAY CONSTRICTION AND COUGHING
Trigger factors:
o inhalation of smoke, dust, cold air, or other irritants
o Agents (which act directly on airway smooth muscle
to cause constriction) released by resident cells (e.g.,
Figure 4. Airway resistance as a function of the airway generation. mast cells, airway epithelial cells) and recruited cells
In a normal lung, most of the resistance to airflow occurs in the first (e.g., neutrophils, eosinophils)
eight airway generations. -Histamine
-Acetylcholine
The smallest airways (towards the respiratory zone) -thromboxane A2
contribute very little to the overall total resistance of the -prostaglandin F2
bronchial tree (Fig. 2). -leukotrienes (LTB4, LTC4, and LTD4)
o Methacholine inhalation (acetylcholine derivative)
A. FACTORS THAT CONTRIBUTE TO AIRWAY - used to diagnose airway hyperresponsiveness
RESISTANCE in asthmatic patients
Healthy individuals’ airway resistance
o = approximately 1 cm H2O/L sec IV. MEASUREMENT OF EXPIRATORY FLOW
LUNG VOLUME (LV) - one of the most important factors Measurement of Expiratory Flow Rates and Expiratory
affecting resistance Volumes is an important clinical tool for evaluating and
o Increasing LV increases caliber of the airways as it monitoring respiratory diseases.
creates a positive trans airway pressure Commonly used clinical tests
o Hence, RESISTANCE TO AIRFLOW ↓ (decrease) o the patient INHALE maximally to TLC
WHILE LV ↑ (increase) o then EXHALE as rapidly and completely as possible
o Or RESISTANCE TO AIRFLOW ↑ WHILE LV ↓. to RV

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o test results are displayed either as a SPIROGRAM or A. THE SPIROGRAM
as FLOW-VOLUME CURVE/ LOOP displays the volume of gas EXHALED as a function of time
o Results from individuals with suspected lung disease it measures:
are compared with results predicted from normal o forced vital capacity (FVC)
healthy volunteers o forced expiratory volume in 1 second (FEV1)
o Predicted or normal values vary with age, sex, o ratio of FEV1 to FVC (FEV1/ FVC)
ethnicity, height, and to a lesser extent, weight o the average mid maximal expiratory flow (FEF25-75)
o Abnormalities in values: o total volume of air that is exhaled during a maximal
-Indicates abnormal pulmonary function forced exhalation from TLC to RV is called the FVC.
-predict abnormalities in gas exchange o volume of air that is exhaled in the first
-can detect the presence of abnormal lung second during the maneuver is called the
function long before respiratory symptoms FEV1.
develop
In normal individuals, 70% to 85% (depending on age) of
-used to determine disease severity and the
the FVC can be exhaled in the first second. Thus, the
response to therapy
normal FEV1/FVC ratio is greater than 70% in healthy
adults.
A ratio < 70% suggests difficulty exhaling because of
OBSTRUCTION (a hallmark of obstructive pulmonary
disease)
One expiratory flow rate—the average flow rate over the
middle section of the VC—can be calculated from the
spirogram.
o This expiratory flow rate has several names:
-MMEF (mid-maximal expiratory flow)
-FEF25-75 (forced expiratory flow from 25%–
75% of VC)
o Although it can be calculated from the spirogram,
TODAY’S SPIROMETERS AUTOMATICALLY
CALCULATE FEF25-75

B. FLOW-VOLUME LOOP
Flow-volume curve or loop is another way of measuring
lung function clinically
It is created by displaying the instantaneous flow rate
during a forced maneuver
This instantaneous flow rate can be displayed both during:
o Exhalation (expiratory flow-volume curve)
o Inspiration (inspiratory flow-volume curve) (see Fig.
22.3B).
The flow-volume loop measures:
o FVC
o Peak Expiratory Flow Rate (PEFR) – the greatest
flow rate achieved during the expiratory maneuver,
o multiple expiratory flow rates at various LV
When the expiratory flow-volume curve is divided into
quarters, the instantaneous flow rate at which 50% of the
VC remains to be exhaled is called the FEF50 (also known
as the V̇ max50)
the instantaneous flow rate at which 75% of the VC has
been exhaled is called the FEF75 (V̇ max75)
the instantaneous flow rate at which 25% of the VC has
been exhaled is called the FEF25 (V̇ max25).

V. DETERMINANTS OF MAXIMAL FLOW
shape of the flow-volume loop reveals important
information about normal lung physiology that can be
altered by disease
Inspection of the flow-volume loop reveals that the
Maximum Inspiratory Flow is the same or slightly greater
than the Maximum Expiratory Flow

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3 factors responsible for Maximum Inspiratory Flow Energy is expanded during breathing to overcome the
o the force generated by the inspiratory muscles ↓ as inherent mechanical properties of the lung.
lung volume ↑ above RV
o recoil pressure of the lung ↑ as the lung volume ↑ VII. DYNAMIC COMPLIANCE
above RV One additional measurement of dynamic lung mechanics
o This opposes the force generated by the inspiratory A dynamic pressure-volume curve can be created by
muscles and ↓ maximum inspiratory flow having an individual breathe over a normal LV range
The combination of inspiratory muscle force, recoil of the (usually from FRC to FRC +1 L).
lung, and changes in airway resistance causes Maximal The Mean Dynamic Compliance Of The Lung (dyn CL)
Inspiratory Flow to occur about halfway between TLC and o calculated as the slope of the line that joins the end-
RV. inspiratory and end-expiratory points of no flow (Fig.
Expiratory Flow Limitation – demonstrated by asking an 22.7).
individual to perform 3 forced expiratory maneuvers Dynamic compliance is always less than static
with increasing effort. Fig. 22.4 shows the results of these compliance, and it increases during exercise.
3 maneuvers. During TIDAL VOLUME BREATHING, a SMALL change
As effort increases, peak expiratory flow increases. in alveolar surface area is insufficient to bring additional
Expiratory flow rates at lower lung volumes are said to be surfactant molecules to the surface = lung is LESS
effort independent and flow limited because maximal COMPLIANT
flow is achieved with modest effort, and no amount of During EXERCISE the opposite occurs; there are LARGE
additional effort can increase the flow rate beyond this changes in tidal volume, and more surfactant material is
limit. incorporated into the air-liquid interface = lung is MORE
Events early in the expiratory maneuver are said to be COMPLIANT
effort dependent; that is, increasing effort generates SIGHING and YAWNING increase dynamic compliance
increasing flow rates. by increasing tidal volume and restoring the normal
surfactant layer
o both of these respiratory activities are important for
maintaining normal lung compliance

VI. FLOW LIMITATION AND THE EQUAL
PRESSURE POINT
Equal Pressure Point - point at which the pressure inside
and surrounding the airway is the same.
o Location: dynamic
o Specifically, as lung volume and elastic recoil
decrease, the equal pressure point moves toward the
alveolus in normal individuals.
In individuals with COPD, the equal pressure point at any
lung volume is closer to the alveolus.
Expiratory flow limitation occurs at the equal pressure
point.
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VIII. WORK OF BREATHING
Breathing requires the use of respiratory muscles
(diaphragm, intercostals, etc.), which expends energy.
Work of breathing – required to overcome the inherent
mechanical properties of the lung (i.e., elastic and flow-
resistive forces) and to move both the lungs and the chest
wall.
FACTORS THAT INCREASE WORK OF BREATHING:
o Changes in mechanical properties of lungs or chest
wall (or both)
o presence of disease
Respiratory muscle fatigue is the most common cause
of respiratory failure
o A process in which gas exchange is inadequate to
meet the metabolic needs of the body
Work of breathing is calculated by:
o multiplying the change in volume by the pressure
exerted across the respiratory system:
o Work of breathing (W) = Pressure (P) x Change in
volume = (∆ V)
Methods are not available to measure the total amount of
work involved in breathing but it can be estimated by
measuring the volume and pressure changes during a
respiratory cycle.
Analysis of pressure volume curves can be used to
illustrate these points. Fig. 22.8A represents a respiratory
cycle of a normal lung.
The static inflation-deflation curve is represented by line
ABC. The total mechanical workload is represented by the
trapezoidal area OAECD.
In restrictive lung diseases, such as pulmonary
fibrosis, lung compliance is decreased, and the pressure-
volume curve is shifted to the right.
This results in a significant increase in the work of
breathing (see Fig. 22.8B), as indicated by the increase in
the trapezoidal area of OAECD.
In obstructive lung diseases, such as asthma during an
exacerbation or chronic bronchitis, airway resistance is
elevated (see Fig. 22.8C) and greater negative pleural
pressure is needed to maintain normal inspiratory flow
rates.
In addition to the increase in total inspiratory work
(OAECD), individuals with obstructive lung disease have
an increase in positive pleural pressure during exhalation
because of the increase in resistance and the increased
expiratory workload, which is visualized as area DFO.
The stored elastic energy, represented by area ABCF of
Fig. 22.8A, is not sufficient, and additional energy is
needed for exhalation.
Work of breathing is also increased when deeper breaths
are taken (an increase in tidal volume requires more
elastic work to overcome)
People with or without lung disease adopt respiratory REFERENCE
patterns that minimize the work of breathing. 1. Koeppen, B. M., Stanton, B.A. (2014). Berne and Levy
Pulmonary fibrosis (increased elastic work) results in Physiology (Seventh edition). Philadelphia, 2018.
more shallow and rapid breathing
Obstructive Lung Disease (normal elastic work but
increased resistive work) breathe more slowly and deeply.

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READING ASSIGNMENT (CHAPTER 23) II. DEAD SPACE VENTILATION: ANATOMICAL
VENTILATION, PERFUSION, AND AND PHYSIOLOGICAL
VENTILATION/PERFUSION RELATIONSHIP
Ventilation to airways that do not participate in gas
OUTLINE exchange
I. VENTILATION
II. DEAD SPACE VENTILATION: ANATOMICAL A. ANATOMICAL DEAD SPACE
AND PHYSIOLOGICAL Composed of volume of gas that fills the conducting
airways.
C. Anatomical Dead Space
D. Physiological Dead Space VT = VD + VA
III. ALVEOLAR VENTILATION
o V refers to volume
C. Composition of Air
o Subscripts T, D, A refers to Tidal, Dead space,
D. Alveolar Gas Composition Alveolar
E. Arterial Gas Composition
F. Distribution of Ventilation VT x n = (VD x n) + (VA x n) OR VE = VD = VA
IV. PULMONARY VASCULAR RESISTANCE o “dot” above the V denotes volume per unit of time (n)
V. DISTRIBUTION OF PULMONARY BLOOD o VE is the total volume of gas in liters expelled from
FLOW the lungs per minute aka Exhaled per minute
A. Gravity o VD is the dead space ventilation per minute
B. Arterial and Venous Pressure o VA is the alveolar ventilation per minute
In healthy adult, gas contained in conducting airways at
C. Pulmonary Alveolar Pressure
FRC or functional residual capacity is 100 to 200 mL
D. Three Functional Zones of Lungs (compared to the 3L of gas in an entire lung).
VI. ACTIVE REGULATION OF BLOOD FLOW
VII. VENTILATION/PERFUSION RELATIONSHIPS VD = VD / VT x VE
A. Regional Differences in o VD varies inversely with VT, the larger the VT, the
Ventilation/Perfusion Ratios smaller the VD
o Normally, VD/VT is 20% to 30% of exhaled minute
B. Alveolar-Arterial Difference for
ventilation or VE
Oxygen Changes in dead space is important contributors to
VIII. ARTERIAL BLOOD HYPOXEMIA, HYPOXIA breathing.
AND HYPERCARBIA o If dead space is increased, individual must inspire
IX. VENTILATION/PERFUSION ABNORMALITIES larger VT to maintain normal levels of blood gases
AND SHUNTS (ex. Muscle fatigue, Respiratory failure)
X. LOW VENTILATION/PERFUSION o If metabolic demands increase, people with lung
disease cannot increase the VT
XI. ALVEOLAR HYPOVENTILATION
XII. DIFFUSION ABNORMALITIES B. PHYSIOLOGICAL DEAD SPACE
XIII. MECHANISMS OF HYPERCAPNIA Total volume of gas in each breath that does not
XIV. EFFECT OF 100% OXYGEN ON ARTERIAL participate in gas exchange.
BLOOD GAS ABNORMALITIES In diseased lungs, some alveoli are perfused but not
XV. REGIONAL DIFFERENCES ventilated.
Large as anatomical dead space (larger in diseased lungs)

I. VENTILATION III. ALVEOLAR VENTILATION
Air that moves in composed of:
o Volume that fills the conducting airways (dead space
A. COMPOSITION OF AIR
ventilation) Inspiration brings ambient/atmospheric air to the alveoli
o Portion that fills the alveoli (alveolar ventilation) AMBIENT AIR
o N2 and O2 plus minute quantities of carbon dioxide,
VE = f x VT argon, and inert gases
o because this is a gas mixture, GAS LAWS can be
Minute/Total Ventilation (VE)- volume of air that enters or applied
leave the lung per minute 2 PRINCIPLES OF GAS LAW:
Frequency (f)- number of breaths per minute o When the components are viewed in terms of gas
Tidal volume or volume of air inspired or expired per fractions (F), the sum of the individual gas fractions
breath (VT) must equal one
o varies with age, sex, body position, metabolic activity
o average-sized adult at rest, VT= 500mL
o children, VT= 3 to 5 mL/kg

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o Partial pressure of a gas (Pgas) is equal to the D. DISTRIBUTION OF VENTILATION
fraction of that gas in the gas mixture (Fgas) ▪ Upright position, at most lung volume, alveoli near apex
multiplied by the atmospheric (barometric) pressure are most expanded than alveoli at base
▪ Gravity pulls lung downward and away from chest wall, as
3 IMPORTANT GAS LAWS that govern ambient air and a result pleural pressure is lower (more negative) at apex
alveolar ventilation
▪ Ventilation of alveoli is not uniform because, variable
o BOYLE’S LAW
airway resistance (R) or compliance (C) is quantitatively
-When TEMPERATURE is constant, PRESSURE (P)
and VOLUME (V) are inversely related described by time constant (t)
-Used to measure lung volume. t=RxC
P1V1 = P2V2 ▪ Adult normal respiratory rate = 12 breaths per minute
o Inspiratory time is 2 seconds
o DALTON’S LAW o Expiratory time is 3 seconds
-Partial pressure of a gas in a gas mixture is the
pressure that gas would exert if it occupied the total IV. PULMONARY VASCULAR RESISTANCE
volume of mixture in the ABSENCE of other Blood flow in pulmonary circulation is pulsative and
components.
influenced by:
o HENRY’S LAW
o Pulmonary vascular resistance (PVR)
-The concentration of a gas dissolved in liquid is
o Gravity
proportional to its partial pressure
-Ambient air = 21% oxygen and 79% N2 o Alveolar pressure
Oxygen tension at the mouth is altered in 2 ways. o Atrial – to – venous pressure gradient
Changing the fraction of O2 and FiO2; Changing the Pb PVR = PPA – PLA
Ambient oxygen can increase with supplemental oxygen
and decrease at high altitude. QT
Inspired air becomes saturated with water vapor in glottis
o PPA is the change in pulmonary artery pressure
Water vapor exerts partial pressure and dilutes total
(NORMAL = 14mmHg)
pressure
o PLA is the change in left atrium pressure (NORMAL=
Water vapor pressure at body temperature is 47 mmHg
8mmHg)
Water vapor pressure reduces partial pressure of O2 and
o QT is the flow or cardiac output (NORMAL = 6L/min)
N2
o PVR = 1.00 mmHg/minute (NORMAL)
In calculation of partial pressure of ambient air, water
Pulmonary circulation has 2 features that increase the
vapor pressure is ignored because ambient air is dry
blood flow without increased in pressure
Conducting airways do not participate in gas exchange so o High demand (ex. In exercise), pulmonary vessels
partial pressure of O2 and N2 are unchanged until it that are normally closed are recruited
reaches alveoli o Blood vessels are distensible, and diameter
increases
B. ALVEOLAR GAS COMPOSITION At the end of the inspiration, air filled alveoli compresses
At the end of inspiration (glottis is open), total pressure in alveolar capillaries and increased the PVR (except larger
the alveolus is atmospheric vessels, their PVR is decreased)
Composition of gas mixture is changed Capillary beds in lungs account for 40% PVR
ALVEOLAR VENTILATION– process of elimination of In exhalation, deflated alveoli apply respiratory resistance
carbon dioxide to capillaries and PVR decreases (larger vessels PVR
ALVEOLAR CARBON DIOXIDE EQUATION– defines increases)
the relationship between carbon dioxide production and
TOTAL PVR IN THE LUNGS IS LOWEST AT FRC
alveolar ventilation
(FUNCTIONAL RESIDUAL CAPACITY

C. ARTERIAL GAS COMPOSITION
▪ Acute increased in PACO2 = respiratory acidosis
V. DISTRIBUTION OF PULMONARY BLOOD
▪ Acute decreased in PACO2 = respiratory alkalosis FLOW
▪ Hypercapnia = elevation in PACO2 Pulmonary circulation
o when CO2 production exceeds alveolar ventilation o low-pressure/low resistance system, influenced by
(hypoventilation) the following:
Hypocapnia = decreased PACO2
A. GRAVITY
o when alveolar ventilation exceeds CO2 production
On leaving the pulmonary artery, blood must travel against
gravity to the apex of the lung in upright people.

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This gravitational effect contributes to an uneven VII. VENTILATION/PERFUSION RELATIONSHIPS
distribution of blood flow in the lungs. Both ventilation (V̇) and lung perfusion (Q̇) are essential
components of normal gas exchange, but a normal
B. ARTERIAL AND VENOUS PRESSURE relationship between the two components is insufficient to
The effect of gravity on blood flow affects arteries and ensure normal gas exchange.
veins equally and results in wide variations in arterial (Pa) Ventilation/perfusion ratio
and venous pressure (Pv) from the apex to the base of the o also referred to as the V̇/Q̇ ratio is the ratio of
lung. ventilation to blood flow.
These variations influence both flow and - this ratio can be defined for a single alveolus,
ventilation/perfusion relationships. for a group of alveoli, or for the entire lung.
In normal lungs:
C. PULMONARY ALVEOLAR PRESSURE o Alveolar ventilation = 4.0 L/min
Differences in pulmonary alveolar pressure (PA) also o Pulmonary blood flow = 5.0 L/min.
influence blood flow in the lung. o Overall ventilation/perfusion ratio = 0.8
The range of V̇/Q̇ ratios varies widely in different lung
THREE FUNCTIONAL ZONES OF LUNGS units.
ZONE 1 When ventilation exceeds perfusion, the V/Q ratio is
o represents the lung apex, where Pa is so low that it greater than 1 (V̇/Q̇ > 1), and when perfusion exceeds
can be exceeded by PA. ventilation, the V/Q ratio is less than 1 (V̇/Q̇ < 1).
-The capillaries collapse because of the greater Mismatching of pulmonary blood flow and ventilation
external PA, and blood flow ceases. results in impaired O2 and CO2 transfer.
-Under normal conditions, this zone does not
In individuals with cardiopulmonary disease, mismatching
exist; however, this state could be reached
of pulmonary blood flow and alveolar ventilation is the
during positive-pressure mechanical ventilation
most frequent cause of systemic arterial hypoxemia
or if Pa decreases sufficiently (such as might
(reduced PaO2).
occur with a marked decrease in blood volume).
In general, V̇/Q̇ ratios greater than 1 are not associated
ZONE 2
with hypoxemia.
o The upper third of the lung, Pa is greater than PA,
which is in turn is greater than Pv.
A. REGIONAL DIFFERENCES IN
-Because PA is greater than Pv, the greater
external PA partially collapses the capillaries
VENTILATION/PERFUSION RATIOS
and causes a “damming” effect. This The ventilation/perfusion ratio varies in different areas of
phenomenon is often referred to as the waterfall the lung.
effect. In an upright individual, although both ventilation and
ZONE 3 perfusion increase from the apex to the base of the lung,
o Pa is greater than Pv, which is greater than PA, and the increase in ventilation is less than the increase in blood
blood flows in this area in accordance with the flow.
pressure gradients.
Thus, pulmonary blood flow is greater in the base of the B. ALVEOLAR-ARTERIAL DIFFERENCE FOR OXYGEN
lung because the increased transmural pressure distends The difference between PAO2 and PaO2 is called the
the vessels and lowers the resistance. alveolar-arterial difference for oxygen (AaDO2).
An increase in the AaDO2 is a hallmark of abnormal O2
VI. ACTIVE REGULATION OF BLOOD FLOW exchange.
Oxygen levels have a major effect on blood flow. Abnormalities in PaO2 can occur with or without an
elevation in AaDO2.
Hypoxic vasoconstriction
o occurs in arterioles in response to decreased PAO2. Hence, the relationship between PaO2 and AaDO2 is
- the response is local, result to shifting of blood useful in determining the cause of an abnormal PaO2 and
flow from hypoxic areas to well-perfused areas in predicting the response to therapy particularly to
to enhance gas exchange. supplemental O2 administration.
Isolated, local hypoxia does not alter pulmonary vascular
resistance (PVR) unless 20% of the vessels is hypoxic. VIII. ARTERIAL BLOOD HYPOXEMIA, HYPOXIA,
Low inspired O2 levels as a result of high altitude have a AND HYPERCARBIA
greater effect on PVR because all vessels are affected. ARTERIAL HYPOXEMIA
High levels of inspired O2 can dilate pulmonary vessels o PaO2 lower than 80 mm Hg in an adult who is
and decrease PVR. breathing room air at sea level.
Pulmonary Artery hypertension HYPOXIA
o pulmonary artery pressures rise o insufficient O2 to carry out normal metabolic
- consequence of chronic hypoxia or collagen functions hypoxia often occurs when the PaO2 is less
vascular disease. than 60 mm Hg.
4 major categories of hypoxia.

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o HYPOXIC HYPOXIA X. LOW VENTILATION/PERFUSION
- most common and six main pulmonary
When alveolar ventilation is distributed unevenly between
conditions associated with hypoxic hypoxia are
the two gas-exchange units and blood flow is equally
anatomical shunt, physiological shunt,
distributed, the unit with decreased ventilation has a V̇ /Q̇
decreased FiO2, V̇ /Q̇ mismatching, diffusion
ratio of less than 1, whereas the unit with the increased
abnormalities, and hypoventilation.
ventilation has a V̇ /Q̇ of greater than 1.
o ANEMIC HYPOXIA
This causes the alveolar and end-capillary gas
- caused by a decrease in the amount of
compositions to vary.
functioning hemoglobin as a result of too little
hemoglobin, abnormal hemoglobin, or
interference with the chemical combination of
XI. ALVEOLAR HYPOVENTILATION
oxygen and hemoglobin (e.g., carbon Determination of PAO2 - balance between the rate of O2
monoxide poisoning). uptake and the rate of O2 replenishment by ventilation.
o HYPOPERFUSION HYPOXIA If ventilation decreases, PAO2 decreases.
- results from low blood flow (e.g., decreased When ventilation is halved, the PACO2 and PaCO2
cardiac output) and reduced oxygen delivery to doubles.
the tissues. HYPOVENTILATION
o HISTOTOXIC HYPOXIA o ventilation insufficient to maintain normal levels of CO
- occurs when the cellular machinery that uses o normal AaDO2 because gas exchange is normal; if
oxygen to produce energy is poisoned, as in AaDO2 rises, atelectasis develops rapidly by creating
cyanide poisoning. In this situation, arterial and regions with V/Q ratios of 0
venous PO2 are normal or increased because o decreases PaO2 and increases PaCO2.
oxygen is not being utilized.
XII. DIFFUSION ABNORMALITIES
IX. VENTILATION/PERFUSION ABNORMALITIES Diffusion Disequilibrium
AND SHUNTS o incomplete diffusion; increased AaDO2; observed in
Anatomical Shunts normal exercising persons at high altitude
o An anatomical shunt occurs when mixed venous Alveolar capillary block
blood bypasses the gas-exchange unit and goes o thickening of the ai-blood barrier
directly into the arterial circulation distribution of o uncommon cause of hypoxemia
cardiac output is changed.
o The blood that bypasses the gas-exchange unit is XIII. MECHANISMS OF HYPERCAPNIA
thus shunted, and because the blood is Hypercapnia - elevated PCO2
deoxygenated, this type of bypass is called a right- 2 major mechanisms:
to-left shunt. o HYPOVENTILATION
o Most anatomical shunts develop within the heart, and - Hypoventilation always decreases PaO2 and
the effect of this right-to-left shunt is to mix increases PaCO2 resulting to hypoxemia that
deoxygenated blood with oxygenated blood, and it responds to an enriched source of O2.
results in varying degrees of arterial hypoxemia. o WASTED OR INCREASED DEAD SPACE
o An important feature of an anatomical shunt is that if VENTILATION
an affected individual is given 100% O2 to breathe, - when pulmonary blood flow is interrupted in the
the response is blunted severely. presence of normal ventilation.
o The PaCO2 in an anatomical shunt is not usually -most often caused by a pulmonary embolus that
increased even though the shunted blood has an obstructs blood flow.
elevated level of CO2. - the embolus halts blood flow to pulmonary
Physiological Shunts areas with normal ventilation (V/Q = ∞)
o also known as venous admixture can develop when - fails to oxygenate any of the mixed venous
ventilation to lung units is absent in the presence of blood.
continuing perfusion. Compensation after embolus begins immediately by
o The effect of a physiological shunt on oxygenation is o local bronchoconstriction
like the effect of an anatomical shunt, deoxygenated o Distribution of ventilation shifts to the areas being
blood bypasses a gas-exchanging unit and admixes perfused
with arterial blood. If no compensation occur, PaCO2 increases and PaO2
o ATELECTASIS decreases.
-obstruction to ventilation of a gas-exchanging
unit with subsequent loss of volume XIV. EFFECT OF 100% OXYGEN ON ARTERIAL
-is an example of a situation in which the lung BLOOD GAS ABNORMALITIES
region has a V̇ /Q̇ of 0.
Breath 100% O2 through a non-rebreathing face mask
-Causes: mucous plugs, airway edema, foreign
(15min) to distinguish a right-to-left shunt from other
bodies, and tumors in the airway.
causes of hypoxemia.

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When one breathes 100% O2, all N2 in the alveolus is
replaced by O2; even areas with very low V/Q ratios
develop high alveolar pressure as N2 is being replaced.
PAO2 is calculated according to alveolar air equation:

PAO2 = [1.0 X (Pb - PH2O)] - PaCO2/0.8
= [1.0 X (760 - 47)] - 40/0.8
= 663 mm Hg

Presence of right-to-left shunt, oxygenation is not
corrected because mixed venous blood continues to flow
through the shunt and mix with blood that has perfused
normal units.
The poorly oxygenated blood from shunt lowers the
arterial O2 content and maintains AaDO2.
Elevated AaDO2 with 100% O2 = presence of shunt

XV. REGIONAL DIFFERENCES
The volume of the lung at the apex is less than the volume
at the base.
Ventilation and perfusion are less at the apex than at the
base, but the differences in perfusion are greater than the
differences in ventilation.
V/Q ratio is high at the apex and low at the base.
PAO2 is higher and PACO2 is lower in the apex than in
the base.
End-capillary PO2 is lower, and the O2 content becomes
lower in end-capillary blood at the lung base than at the
apex.
During exercise, the difference between the content of
gases in the apex and in the base of the lung diminishes
due to increase of blood flow to the apex and becoming
uniform in the lung.

REFERENCE
2. Koeppen, B. M., Stanton, B.A. (2014). Berne and Levy
Physiology (Seventh edition). Philadelphia, 2018.

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