Egan Chapter 11 Ventilation PDF

Summary

This document contains information about ventilation in the human respiratory system. It explains the process of moving air in and out of the lungs and detailing different forms of diseases and issues that affect ventilation.

Full Transcript

Egan
Chapter 11

Ventilation
 Introduction to Ventilation
◦ The primary function of the lungs are to supply the
body with oxygen (O2) and remove the waste, carbon
dioxide (CO2).
 In order to perform these functions, the lungs must be
adequately ventilated. WITHOUTVENTILATION WE DON'T ACHIEVE
OXYGENATION

VENTILATION CARBON DIOXIDE

2
 Introduction to Ventilation
02_FOOD CO2 WASTE
FORTISSUES
 Ventilation is the process of moving gas (usually air)
in and out of the lungs
 Ventilation is to be distinguished from respiration,
which refers to the physiologic processes of oxygen
use at the cellular level.
 In health BE IMPAIRED IN SOME
VENTYIETS.CN
Ventilation is regulated to meet the body’s needs under a
wide range of conditions
 In disease
When the process of ventilation is impaired it can create
more work for the patient to breathe in attempt to ventilate

Copyright © 2017 Elsevier Inc. All Rights Reserved. 3
 Mechanics of Ventilation
IEFRFIE.in andout

wWBreEemi
Ventilation is cyclic: inspiration and expiration
Tidal volume (VT): gas moved per phase AWAYS WTH T
Volume measured during either inspiration or expiration
Facilitates removal of CO2, replenishes O2 Exhale

 To ventilate, the respiratory muscles have to
generate changes in a pressure gradient so that
gas will flow in and out of the lungs.
 Lung and thorax compliance and resistance have
an affect on ventilation
The load respiratory muscles overcome to produce
ventilation NOTLABOREDBREATHING
NO
Healthy lungs at rest, inspiratory load is minimal, while
expiration is passive
GENERATE NEGATIVEPRESSURE
WE
Copyright © 2017 Elsevier Inc. All Rights Reserved. 4
 Pressure Differences During
Breathing
 Gases move due to pressure gradients
Produced by thoracic expansion/contraction
Due to elastic properties of airways, alveoli, and chest wall
IN OUTOFTHEWNGS
 Transrespiratory pressure (PTR) COMPARING ANYWHERE IN PAOAND
OUTSIDE ATMOSPHERE
Everything that exists between pressure measured at airway
opening (PAO) and pressure measured at body surface (PBS)
PTR = PAO – PBS THE LUNGS ARE WHEN
Equation follows direction of flow PRESSURE
FILED NEGATIVE
PAO is higher than PBS
Components of transrespiratory pressure include:
Airway, lungs, and chest wall
This gradient causes gas flow in and out of lungs
GENERATED GRADIENT BETWEENTHEHIGH THE
LOW DG
Copyright © 2017 Elsevier Inc. All Rights Reserved. 5
 Pressure Gradients (Pressure
Differences)
 Gas or liquid will move from areas of high
pressure to areas of low pressure
 In pulmonary physiology, pressure difference
called “pressure gradient”
Gases move “down” its pressure gradient
From high-pressure area to low-pressure area
 Pressure Differences During
Breathing (Cont.)
 Transairway pressure (PTAW)
PTAW = PAO– PA
Whatever exists between pressure measured at airway
opening and pressure measured in alveoli of lungs
 Transalveolar pressure (PTA)
PTA = PA– Ppl
Whatever exists between pressure measured in model
alveolus and pressure measured in pleural space (Ppl).
 Transchestwall pressure (PTCW)
Chest wall exists between pressure measured in
pleural space and pressure on body surface
PTCW = Ppl – PBS

Copyright © 2017 Elsevier Inc. All Rights Reserved. 7
 Pressure Differences During
Breathing (Cont.)
HOWTHEALVEOLI STAYINFLATED SHOULDNOTOCCUR ATELECTASIS
 Transpulmonary pressure difference (PTP) –
Maintains alveolar inflation
Pulmonary system (airways and alveolar region),
defined:
PTP = PAO – Ppl
Pressures must be measured to derive mechanical
properties of pulmonary system
 Under either static or dynamic (breathing) conditions (static
– no flow, dynamic – air flow)

WHYTHEYSTAY INFLATED MAINTAINS IT
NEGATEPEURE
PLEURALPRESSURE NEGATIVE 10 Exhale 20
WHENYOUEXHALE THE PRESSURE GOESMORE
Copyright © 2017 Elsevier Inc. All Rights Reserved.
NEGATIVE 8
 Pressure Differences During
Dottiquent Breathing (Cont.)
 Transthoracic pressure difference (PTT)
PTT = PA – PBS
Causes gas to flow into and out of alveoli during
breathing
Beginning of inspiration in spontaneous breathing
subject, PA is subatmospheric compared to PAO
Causes air to flow into alveoli
Beginning of exhalation is opposite
PA is higher than PAO
Causing air to flow out of airway

Copyright © 2017 Elsevier Inc. All Rights Reserved. 9
 Pressure Differences During
Breathing (Cont.)
Remember CAUSING THE LUNGS
 Inspiration begins β TO EX
PALP
When muscular effort expands the thorax
Thoracic expansion causes a decrease in Ppl OFFEGS
Causes positive change on expiratory PTP and PTA, which
induces flow into lungs
Inspiratory flow is proportional to (+) change in
transairway pressure difference
The higher the change in PTA, the higher the flow CAUSE IT
Ppl continues to decrease until the end of Ea
inspiration
Alveolar filling slows when alveolar pressure
approaches equilibrium with the atmosphere and
Relatives inspiratory flow decreases to zero ASWE Approach
ptrons
f
DECREASE
Copyright © 2017 Elsevier Inc. All Rights Reserved. FLOW WILL 10
REACH Flow 0
 Pressure Differences During
Breathing (Cont.)
 Beginning of expiration
Thoracic recoil causes Ppl to start to rise
Thus, transpulmonary pressure difference starts to
decrease GASWILL BE ENCOURAGE TOGOOUTOFTHE
PTP is decreasing; opposite of inspiration LUNGS
So flow is in opposite (negative) direction
Driving force for expiratory flow is energy stored in combined
elastances of lungs and chest wall
Pleural pressures: always negative (subatmospheric)
during normal inspiration and exhalation
During forced inspiration (big downward movement of
diaphragm), pleural pressure can drop up to –50 cm
H2O

Copyright © 2017 Elsevier Inc. All Rights Reserved. 11
In this picture the Pao is 10 due to positive pressure
ventilation. The pleural pressure is 0 yet the patient still
has a 500 Vt (same volume as spontaneous breathing
patient but achieved differently)
AIRWAY
LAPPV POSITIVEPRESS
BREATHING

Copyright © 2017 Elsevier Inc. All Rights Reserved. 12
 Spontaneous versus Positive
IF WE INTRODUCE
DECREASING Pressure Breathing PRESS
MOREPOSITIVE
THERE'S A POSSIBILITY
 Two important points to remember are CODING
OFPATIENT
top so RT
◦ (1) both SB and PPV accomplish inspiration by
SHEPSTE
mommy
increasing PL, the pressure distending the lungs, and
◦ (2) because PPV raises the Ppl, it tends to compress
the veins that bring blood back to the heart, ultimately
impeding cardiac output. Spontaneous breathing has
the opposite effect because inspiration lowers Ppl
further, augmenting venous blood return to the heart.
Beachey, Will. Respiratory Care Anatomy and Physiology: Foundations for Clinical Practice, 3rd
Edition. Mosby, 2013. VitalBook file.
WHYDOESINCREASINGPOSITIVE
PleuralPressure PRESSUREONVENTILATIONCAUSE
IMPEDE
SUDDEN CARDIAC PATIENTTOCODE ITCAN
VENOUS RETURN DIETOINCREASE
ARREST PRESSURE
13
THORACIC
 7

INHALATION
 https://youtu.be/NB1aCBId6qA
 When we inhale in we expand our thoracic cavity and expand the
lungs to take in more volume which decreases pleural pressure
(Boyle’s Law) 130
Increasing thoracic volume causes fewer collisions between gas
molecules and between gas molecules and the thorax. The
lower number of collisions decreases the pressure exerted by
the gas, which reduces PA below PB so air flows into the lungs
until PA again equals PB at end inspiration.
 To look at it another way: this increases the transpulmonary
pressure gradient which maintains alveolar inflation.
Transpulmonary Pressure Gradient PTP = Alveolar pressure PA –
pleural pressure PPL)
 This causes the alveolar pressure to fall below the airway opening
pressure and this pressure gradient causes air to flow into the lungs

14
 INHALATION
 Inhalation stops when alveolar pressure
equals the airway opening pressure.
 The higher the pressure gradient the higher
the flow.
 https://youtu.be/lr5dDmTASos
NOTES
TAKE ON
AND
WATCH NICHE
FORINSPIRATION IS A
THIS
DOWNWARDMOVEMENT
OF DIAGHPRAM
15
 Balloon Model of Ventilation
A. Inspiration caused
by downward
movement of
rubber sheet
(diaphragm)
Atmospheric pressure
is greater than
pressure in side of
balloon
 When we pull down in the diaphragm it increases
the size of the thoracic cavity and increases
volume which in turn causes the pleural pressure
to decrease.
Because the lung is elastic, the decrease in
pleural pressure gets transmitted to inside the
alveoli which in turn causes the intra-alveolar
pressure to decrease
This creates a pressure gradient to between the

intra-alveoli pressure and atmospheric pressure
Because atmospheric pressure is higher than

intralveolar pressure then gas will move from
higher pressure to lower pressure
Copyright © 2017 Elsevier Inc. All Rights Reserved. 17
 Balloon Model of Ventilation
WHENWE REACH EQUILIBRIUM
GB. End-inspiration
(equilibrium point,
no gas flow). Gas
flows until
equillibrium
Atmospheric pressure
is equal to pressure
inside balloon

DIAGPHRAMCONTRACTS LUNGS RELAY
VICE VERSA
NEGATIVE PRESSURE
PL ALWAYS
 To Summarize
The atmospheric pressure is more positive and
as muscles contract it increases space in the
thoracic cavity and per Boyle’s Law the
decrease in pressure will increase the volume.
It does this because expanding the lungs
causes gas molecules to have more room to
move around. When there is more room to
move around there is less pressure. Less
pressure = more volume. Then as gas flows
until alveolar pressure equals the atmospheric
pressure.
19
 EXHALATION
Once air enters the lungs, how does air get out
of the lungs?
AP AT PRESSURE
 The lung is stretched during inspiration, so

when the inspiratory muscles relax, the lung
recoils to compress the alveolar gas volume.
 Exhalation should normally be passive

 This causes alveolar pressure to be higher
than atmospheric pressure which will then
cause air to flow from the higher pressure to
the lower pressure
20
 EXHALATION
 Specifically, when the diaphragm relaxes, its
elasticity causes it to return to its dome
shape, decreasing the vertical dimension of
the thoracic cavity. THORACIC RECOIL
 Again, the lung is stretched during inspiration,
so when the inspiratory muscles relax, the
lung recoils to compress the alveolar gas
volume.

21
 Balloon Model of Ventilation
C. Expiration caused
by elastic recoil of
diaphragm
upward movement
Pressure inside balloon
is greater than
atmospheric pressure

9

DROPS PLEURAL PRESSURE
UNTIL ITREACHESEQUILIBRIUM
 On exhalation, diaphragm relaxes and moves
upward causing size of the thoracic cavity to
decrease which decreases the volume
This causes pleural pressure to increase

Because lungs are elastic the increase in the
pleural pressure is transmitted to the alveoli
which causes the intra-alveolar pressure to
increase
Now the intra-alveolar pressure is higher than
atmospheric the gas will flow from higher
pressure to lower pressure

Copyright © 2017 Elsevier Inc. All Rights Reserved. 23
 Balloon Model of Ventilation
D. End-expiration
(equilibrium point,
no gas flow)
Atmospheric pressure
is equal to pressure
inside balloon
 To Summarize Exhalation
On exhalation, diaphragm relaxes and moves
upward causing size of the thoracic cavity to
decrease which decreases the volume
This causes pleural pressure to increase STILL NEG

Because lungs are elastic the increase in the
pleural pressure is transmitted to the alveoli
which causes the intra-alveolar pressure to
increase
Now the intra-alveolar pressure is higher than

atmospheric the gas will flow from higher
pressure to lower pressure
25
Which of the following statements about
alveolar pressure (Palv) during normal quiet
breathing is true?
A. It is positive during inspiration and negative
during expiration
B. It is the same as intrapleural pressure

C. It is negative during inspiration and positive
during expiration
D. It always remains less than atmospheric
pressure

Copyright © 2017 Elsevier Inc. All Rights Reserved. 26
What happens during normal inspiration?
1. The Ppl increases further below atmospheric
2. Transpulmonary pressure gradient widens
3. Palv drops below that at the airway opening
THIGH to
A. 1 and 2 only
GAS FROM
flow
B. 2 and 3 only

C. 1 only

Copyright © 2017 Elsevier Inc. All Rights Reserved. 27
During expiration, why does gas flow out from
the lungs to the atmosphere?
A. Palv is less than at the airway opening

B. Palv is the same as at the airway opening

C. Palv is greater than at the airway opening

D. Airway pressure is greater than Palv

Changein pressure
7 HIGHERTHAN ATMOSPHERIC
PRESSURE

Copyright © 2017 Elsevier Inc. All Rights Reserved. 28
Break into assigned groups
and take turns teaching and
explaining the process of of
inhalation and exhalation
discussing the atmospheric and
subatmospheric pressures

Some students will be called at
random to explain to the class 29
 Why is this important?
BETWEEN THE RIBS

β
Newborn infant showing
intercostal and subcostal
retractions GETTINGMOREVOLUMESTO EXPANDMORE
 The muscles of inspiration

contract forcefully in an
effort to generate a greater
negative intrapleural and
intra-alveolar pressure to
draw in more air.
 Inspiratory retractions
overlying the chest wall are
a direct result of increased
negative intra-pleural
pressure
(Used with permission from the author: T. Des Jardins, WindMist LLC)
 Where else will these concepts apply?.

An RT called to assist in care of 22-year-old male
motorcycle crash victim who presents in emergency
room with numerous abrasions, lacerations, and
very serious chest injury (multiple broken ribs over
right anterior chest)
 In this case, RT must be aware of how the

following items profoundly affect patient’s ability
to breathe when chest wall is unstable:
◦ Negative intrapleural pressure
◦ Transpulmonary pressure ALVEOLAR
◦ Transthoracic pressure
 Flail Chest
 Right-sided flail chest
 http://youtu.be/mJ_FYwUqzsM
When this patient inhales the transpulmonary

(PAO-Ppl) and transthoracic (PA-PB)pressure
gradients cause his lung to sink in. This is called
flail chest
This causes the patient’s inspiratory volume
to decrease
When he exhales, the pressure gradients cause
the broken ribs to bulge outward
This causes some of the air from the
unaffected lung to move into the affected
lung – directly under the broken rib rather
than be exhaled out
Putting the patient on the positive pressure

ventilator eliminates the negative intrapleural
pressures changes during inspiration. So this
stops the adverse effects of transpulmonary and
(Used with permission from the author: T. Des Jardins, WindMist LLC)

transthoracic pressure gradients during
inspiration. Figure 2-12.
 Forces Opposing Lung Inflation
 Lungs have tendency to recoil inward, while
chest wall has tendency to move outwards
Those opposing forces keep lung at its resting
volumes (FRC) Functional Residual Capacity
 Opposition to lung inflation can be put into
either
elastic forces: tissues of the lungs, thorax, and
abdomen, along with surface tension in the alveoli
frictional forces: resistance caused by gas flow
through the airways (natural and artificial), and
tissues moved during breathing
Copyright © 2017 Elsevier Inc. All Rights Reserved. 33
Forces Opposing Lung Inflation
 Elastic opposition to ventilation
Elastic and collagen fibers provide resistance to
lung stretch.
Application of air pressure into lungs causes
stretch. THINKOFTHERUBBERBANDSTRETCH
Greater pressure causes greater stretch until it just
can’t stretch anymore.
Deflation is passive recoil and less force is required
to maintain same volume.

34
 Forces Opposing Lung Inflation (Cont.)
 Elastic opposition to ventilation
During deflation, lung volume at any given
b
pressure is slightly greater than during inflation.
Difference between inflation and deflation curves
is hysteresis

GEETE

Copyright © 2017 Elsevier Inc. All Rights Reserved. 35
 Surface Tension Forces
 Hysteresis partly caused by surface tension
Surface tension opposes lung inflation
 Hysteresis tells the clinician if something
other than simple elastic tissue forces are
present
 Lung recoil occurs due to tissue elasticity and surface
tension
 Pulmonary surfactant reduces lung surface tension
Produced in alveolar type II pneumocytes ONLYFOUNDINALVEOLI
Surfactant stabilizes alveoli by preventing collapse
When surface area decreases, ability of pulmonary
surfactant to lower surface tension increases
 Read mini clini on page 230
Copyright © 2017 Elsevier Inc. All Rights Reserved. 36
 Hooke’s Law
 Elastance is the natural ability of matter to
responds directly to force and return to it’s
original shape (like a rubber band)
 In respiratory, inflation stretches tissue. The
elastic properties of the lungs and chest wall
oppose inflation so to increase the volume,
pressure must be applied.
 In pulmonary physiology, elastance is defined
as change in pressure per change in volume

Piv
WHEN PRESELEYES
 Hooke’s Law

Applying one unit
of force the elastic
body will stretch
one unit length
Same applies with
2 or 3 units of force
If it keeps
stretching it can’t
stretch any further

Figure 2-15.
 Hooke’s Law

 When applied to the lungs, volume is substituted for
length, and pressure is substituted for force.
 Volume varies directly with pressure until the elastic limit
of the lung unit is reached. At this point little or no

viii volume occurs. If the pressure continues to rise, the
lung unit will rupture.
 Hooke’s Law helps explain why hazards such as
pneumothorax (resulting from the rupture of alveolar
sacs) can occur with the increased pressure of
mechanical ventilation.
 PRESSURE
POSITIVE EXPIRATORY
IfTHEIR02
TO
CAPILLARIES

Hooke’s
Law Gmsn
 OBSTRUCTIVE

Lung Compliance CBABE CL
NOT
Gregston
 Compliance is a measure of the lung's ability to stretch
and expand INC COMPLIANCE GOOD WNG DEC COMPLIANCE
 CL defined as change in volume (ΔV) per unit of change in
pressure (ΔP) difference across structure or
CL = ΔV L (normal 0.2 L/cm H2O)
ΔP cm H2O BEN6 K
 Pulmonary pathology alters CL CASTHELUNGSDOESN
WANT
Emphysema , obstructive lung disease, increases CL (loss EXPAND
elastic tissue, lungs more distensible)
BABE Large changes in volume for small pressure changes
(see next slide)
NOLUNGS Fibrosis, restrictive lung disease, decreases CL (↑ elastic
tissue)
Elasticity Smaller volume change for any change in pressure
Stiffer lungs, usually with reduced volume (see next
slide) ELASTICITY
INCREASE
COMPLIANCE DECREASE
STRETCH COMESFROM DISEASE WZ IT
THE
Stretchessomuch
Copyright © 2017 Elsevier Inc. All Rights Reserved. 41
Lung Compliance (Cont.)
CHANGES IN PRESSURE VOLUME

RESPONDSWEU C

DENSE
TEEAYE

Copyright © 2017 Elsevier Inc. All Rights Reserved. 42
 Compliance
 Increase compliance caused by loss of elastic
fibers (like in emphysema).
The lungs are more stretched out so that a normal
transpulmonary pressure gradient results in a
larger lung volume INCREASE COMPLIANCE
Hyperinflation is used to describe an abnormally
increased lung volume
 Decrease in compliance may be caused by
pulmonary fibrosis which affects the
connective tissue making them stiff so they
are unable to take in more volume

Copyright © 2017 Elsevier Inc. All Rights Reserved. 43
 Relationship Between
Chest Wall and Lung
 Lungs and chest wall recoil in opposite
directions
Compliance in both is ~0.2 L/cm H2O
Each oppose other, resulting in system
compliance of ~0.1 L/cmIF H2O
FRC (Functional Residual Capacity) established at
resting lung level where tendency of chest wall to
expand equals that of lungs to collapse
Occurs at ~40% TLC (total lung capacity)

Copyright © 2017 Elsevier Inc. All Rights Reserved. 44
 Chest Wall

Ankylosing spondylitis

Severe kyphoscoliosis

ANATOMICMALFORMITIES
CANCAUSE LUNGS COMPU
BECAUSE IT CANTSTRETCH
 Frictional Resistance to Ventilation
 Friction opposition occurs
only when the system is in
motion.
Tissue viscous
resistance
Impeded motion caused by
tissue displacement (lungs,
rib cage, diaphragm,
abdominal organs)
Obesity fibrosis, ascites
can also increase
impedance
TISSUES OBESITY
Accounts for approx. 20% CAUSES
of total resistance

46
 Frictional Resistance to
Ventilation NEEDSTUBETO
ENDOTRACH
COMEUP
 Airway resistance (~80% of of the frictional
resistance to ventilation)
Basically, when gas is trying to flow into the airways
but it is being impeded, we call that airway resistance.
ENDOTRACHEALTUBE
Gas flow causes frictional resistance, hence part of the
reason we would give heliox (mini clinic page 234)
Airway radius exponential effect (r4) on resistance
Artificial airway size or bronchospasm
Resistance is highest at nose (50% of total resistance)
falls to ~20% of total resistance at small airways
Resistance in nonventilated patient is measured in a
pulmonary function laboratory

Copyright © 2017 Elsevier Inc. All Rights Reserved. 47
 Factors that affect resistance
 Laminar flow requires less driving pressure
than turbulent flow.
Driving pressure is the difference between
inspiratory and expiratory pressure, could also be
the difference between PEEP and plateau
pressures (Mech Vent class)

Copyright © 2017 Elsevier Inc. All Rights Reserved. 48
 Airway Resistance
POLESEINE'S LAW
 Reducing the radius of a tube by half
requires a 16-fold increase in pressure to
maintain a constant flow.
 Larger driving pressures may be needed
Driving pressure is the difference in
pressure from point A to point B
 Coffee stirrer or straw? Which one would
you like to breathe through and why?
 When we use smaller endotracheal tubes it
increases WOB for the patients because of
the reduced radius.
 Refer to rule of thumb on page 234

49
 During inspiration the stretch of
surrounding lung tissue and
widening of the transpulmonary
pressure gradient increases the
diameter of the airways
PIEEELE.IE AIRWAYS

This increase with increasing
lung volumes decreases
airway resistance
 As lung volume decreases
toward residual volume, airway
diameters also decrease and
airway resistance dramatically
increases
This explains why wheezing
is most often heard during
exhalation. DIAMETERCLOSING
Copyright © 2017 Elsevier Inc. All Rights Reserved. 50
 Rule of Thumb page 236
 Patients who have emphysema can directly
influence the EPP in their airways to reduce airway
collapse and closure
 Airway collapse may occur in patients who have
emphysema because the normal support structure
for small airways has been destroyed.
 By exhaling through “pursed lips”, a patient with
emphysema change the pressure at the airway
opening.
 The gentle back pressure created counters the
tendency for small airways to collapse by moving
EPP toward the larger airways
TO INCREASE Smell the roses blow the
candle
Copyright © 2017 Elsevier Inc. All Rights Reserved. 51
 Work of Breathing (WOB)
 Respiratory muscles perform
work.
Inhalation is active
Exhalation is passive
Forced exhalation requires
work.
 Pulmonary disease can
dramatically increase WOB.
Restrictive disease work is
greater due to elastic tissue
recoil. CANNOTBREATHEWER
HARDER FOR PATIENTSWHO
Obstructive disease work is
greater due to increased Raw.

AIRWAY RESISTANCE 52
 Pathology’s Affect on WOB
Change

6
1TEA.ae
fr

A, Normal
B, Restrictive disease: slope of the volume-pressure
curve is less, showing increased elastic work
C, Obstructive disease: Frictional resistance increases RFilm
dramatically, noted as bulging inspired and expired
curves THEYWILLBREATH FASTER ISSUEGETTINGAIR IN
Copyright © 2017 Elsevier Inc. All Rights Reserved. 53
 Patient’s with stiff lungs will breathe faster
because of the increased elastic WOB.
This pattern of breathing minimizes the BREATHINGSLOWER
mechanical work of distending the lungs but at the
expense of more energy to increase the RR
 Patient’s with airway obstruction will take on a
different pattern to reduce frictional WOB.
These patients may breathe more slowly using
pursed lip breathing on exhalation to minimize
airway resistance
Copyright © 2017 Elsevier Inc. All Rights Reserved. 54
 Metabolic Impact of
Increased WOB
 Respiratory muscles consume O2 to perform work
 The rate of O2 consumption (VO2) reflects energy Hope
requirements, and can indirectly measure WOB
 O2 cost of breathing (OCB) is indirect measurement
of WOB
Normal OCB 30%
Limits exercise tolerance
Impacts ability to wean from mechanical ventilation
 In shock, intubation and mechanical ventilation may
be indicated to decrease excess oxygen consumption
of respiratory muscles
Preserves oxygen delivery for vital organs ICU PATENTS

Copyright © 2017 Elsevier Inc. All Rights Reserved. 55
 WOB
 Patients who already have muscle weakness
are at higher risk for muscle fatigue. IFTHELUNGS MUSCLE
WEAKENS ITCANCAUS
 Things like: electrolyte imbalance, shock, RESPIRATORY
ARREST
sepsis, or disease that causes muscle
weakness also play a role in WOB
 VT decreases, RR increases, muscle fatigue,
gas exchange does not function well

56
 Distribution of Ventilation
 In upright lung ventilation and perfusion.. (V/Q) are
matched best at bases ( called the dependent area).
Ventilation – air movement in & out of lungs v
V1 Perfusion – Circulation of blood through tissues

HEALTHY PATIENT UQ MATCHED

57
 Distribution of Ventilation
 ሶ or
In healthy lungs, neither ventilation (V)
perfusion (Q)ሶ are distributed evenly
Result: uneven ventilation to perfusion ratio PARTOF THE
ሶ Qሶ ratio of 0.8 BOARDS
V/

 ሶ
In upright lung, ventilation and perfusion (V/ሶ Q)
are matched best at bases (dependent area)
Apical alveoli are larger but harder to ventilate

compared to those at bases
Gravity pulls more blood to bases
In local disease, place good lung down for better V/ ሶ Qሶ
matching. (example is lobar pneumonia)
PNEUMONIA POSITIONTHE PATIENTLAYINGON
PATIENTS WITH SEVERE
THE SIDE SOTHATTHEBLOODWIU PERFUSEONTHE
Copyright © 2017 Elsevier Inc. All Rights Reserved. 58
OTHERLUNG
ROTO BEDS 59
 Factors Affecting Distribution
of Ventilation
 Because of varying transpulmonary pressure
gradients
Alveoli at the apexes have larger resting volumes
than the bases THEYWU EXPAND LESS
Because of these larger volumes, the apexes will
expand less during inspiration than alveoli at
bases
 Alveoli at the bases expand more than the
alveoli at the apexes
Therefore in an upright patient the base of the
lungs will receive approximately 4 times as
much ventilation! Without ventilation there is
no oxygenation
Copyright © 2017 Elsevier Inc. All Rights Reserved. 60
When your patient is in distress
sit the patient upright if it is safe
to do so IF DYPSNEA

Copyright © 2017 Elsevier Inc. All Rights Reserved. 61
 Time Constants
 Time (in seconds) necessary to inflate a
particular lung region to approximately 60%
of its potential filling capacity
 Lung regions that have either increased Raw
CONSTANCE
or increased CL require more time to inflate
Alveoli said to have long time constant
 Lung regions that have either decreased Raw
CONSTANT
or decreased CL require less timeTO
to inflate
Alveoli said to have short time constant
Factors Affecting Distribution
of Ventilation (Cont.)
Lung unit has long time constant (TC) if CL and Raw is high
Lung unit has short time TC if CL and Raw is low
Effects of unequal lung TCs are different for different
ventilator modes

Copyright © 2017 Elsevier Inc. All Rights Reserved. 63
 Efficiency of Ventilation
 To be EFFECTIVE ventilation the body must meet the needs
for O2 uptake and CO2 removal.
 To be EFFICIENT, ventilation should consume little O2 and
produce maximum amount of CO2
 Healthy lungs waste some gas due to
Anatomic deadspace of conducting airways
Alveoli that are ventilated but have little or no perfusion (alveolar
deadspace) OPPOSITE
INVERSE

cnn FM
INVERSE
pÑ Yao
Palor

militia iii
mNgLttEBringin6more
02
64.
 Minute and Alveolar Ventilation
 Ventilation = expressed in liters per minute of
fresh gas entering the lungs
 Total volume moved in and out per minute =
Minute ventilation (Vሶ E)
615 7 tt
 Normal Vሶ E = 5-10 L/min 12X
Vሶ E = fB  VT
mi VT
6 L/min = 12 breaths/min  0.5 L (500 mL)
Vሶ E driven by CO2 production (metabolic rate) and subject
size TIDALVOLUME 480 THORN INTODECIMAL
FEE RR x V or FREQ OF
BREATHING

minuteventilation
MP VE 16 48
7.74min
Copyright © 2017 Elsevier Inc. All Rights Reserved.
ftp 22x 3
74min 65
 Dead Space Ventilation
WASTE OF SPACE
 Alveolar dead space (VDalv) PULMONARY
EMBOLISM
Volume of gas ventilating unperfused alveoli
Alveoli receive gas, but no perfusion or:
have ventilation exceeding perfusion (high V/ሶ Qሶ ratios)
excess ventilation, more than necessary to arterialize
alveolar blood is wasted ventilation

HAPPENING BUT NO
VENTILATION
IS HAPPENING
PERFUSION
ON PULMONARY EMBOLISM
DEFECT PULMONARY
Blood clot
Copyright © 2017 Elsevier Inc. All Rights Reserved. 66
 Dead Space Ventilation (Cont.)
 Usually related to defects in pulmonary
circulation
e.g., pulmonary embolism
Blocks portion of pulmonary circulation
 Apical alveoli have minimal or no perfusion in
normal upright subject at rest, contributing to
dead space

Copyright © 2017 Elsevier Inc. All Rights Reserved. 67
Dead Space Ventilation (Cont.)

Copyright © 2017 Elsevier Inc. All Rights Reserved. 68
69