seminar on hfv - high frequency ventilation
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Apr 28, 2021
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About This Presentation
seminar on hfv - high frequency ventilation
Slide Content
Case scenario 1
B/OTahmina18hoursolddiagnosedaspreterm(32week)with
verylowbirthweight(1420g)respiratorydistresssyndrome.baby
onmechanicalventilationforlast12hourswiththefollowingset
up-modeSIMV,Rate55,pressure20/6,FiO
2100%.Babyhas
persistentrespiratorydistress,notmaintainingsaturationon
conventionalmechanicalventilationwiththatsetup.ABGreveals
severerespiratoryacidosis.pH7.03,PCO2120,PO265,HCO3
30.8
Whatshouldbethefurtherrespiratorymanagement?
B/OTahmina18hoursolddiagnosedaspreterm(32week)with
verylowbirthweight(1420g)respiratorydistresssyndrome.baby
onmechanicalventilationforlast12hourswiththefollowingset
up-modeSIMV,Rate55,pressure20/6,FiO
2100%.Babyhas
persistentrespiratorydistress,notmaintainingsaturationon
conventionalmechanicalventilationwiththatsetup.ABGreveals
severerespiratoryacidosis.pH7.03,PCO2120,PO265,HCO3
30.8
Whatshouldbethefurtherrespiratorymanagement?
Case scenario 2
Ababy36weeker2400gbornbyemergencyLucsdueto
antenatalydiagnosedCongenitaldiaphragmaticherniaonUSG.
Justafterdeliverybabyhadsevererespiratorydistress.On
examinationbabywastachypnic,cyanosispresent,chestbulged
moreinleftside,Onauscultationbreathsounddiminishedin
leftsidebutbowelsoundpresentinleftsideoflung.OnX-Ray
showsMediastinumshiftedtorightandCoilsofintestinefound
inleftsideoflung.
Whatwouldbetherespiratorysupportofthis
condition?
Ababy36weeker2400gbornbyemergencyLucsdueto
antenatalydiagnosedCongenitaldiaphragmaticherniaonUSG.
Justafterdeliverybabyhadsevererespiratorydistress.On
examinationbabywastachypnic,cyanosispresent,chestbulged
moreinleftside,Onauscultationbreathsounddiminishedin
leftsidebutbowelsoundpresentinleftsideoflung.OnX-Ray
showsMediastinumshiftedtorightandCoilsofintestinefound
inleftsideoflung.
Whatwouldbetherespiratorysupportofthis
condition?
HIGH FREQUENCY VENTILATION
Outline
Introduction
Why HFV
Types of HFV
Indications
Mechanism of ventilation
Settings( Initiation and weaning)
Monitoring and routine care on HFV
Complications
Evidences
Outline
Introduction
Why HFV
Types of HFV
Indications
Mechanism of ventilation
Settings( Initiation and weaning)
Monitoring and routine care on HFV
Complications
Evidences
High frequency ventilation
Definition-High frequency ventilation is a form of
mechanical ventilation that uses small tidal volume
sometimes less than anatomic dead space and very rapid
ventilatory rates (2 to 20 Hz or 120 to 1200 cycles/min).
•Tidal volume 1-3 ml/kg.
Assisted ventiltion of the neonate, Goldsmith 6th edition
Definition-High frequency ventilation is a form of
mechanical ventilation that uses small tidal volume
sometimes less than anatomic dead space and very rapid
ventilatory rates (2 to 20 Hz or 120 to 1200 cycles/min).
•Tidal volume 1-3 ml/kg.
Assisted ventiltion of the neonate, Goldsmith 6th edition
1915,
Dr. Henderson studied
small tidal volumes and
rapid rates
1950-1970
Dr. Emerson,
Dr. Bird, Dr. Bunnellstudied
HFV
1970’s
Success with animal
studies
1980’s
Four received FDA
approval
1990’s
HFOV
emerged
2000’s
HFOV for Adults
1991
1995 2001
???
History of High Frequency Ventilation
Dr. Henderson studied
small tidal volumes and
rapid rates
1950-1970
Dr. Emerson,
Dr. Bird, Dr. Bunnellstudied
HFV
1970’s
Success with animal
studies
1980’s
Four received FDA
approval
1990’s
HFOV
emerged
2000’s
HFOV for Adults
1991
1995 2001
???
History of High Frequency Ventilation
Types of high frequency ventilation
1.High frequency flow interruption
(HFFI)
2.High frequency jet ventilation
(HFJV)
3.High frequency oscillator ventilation
(HFOV)
Assisted ventiltion of the neonate, Goldsmith 6th edition
1.High frequency flow interruption
(HFFI)
2.High frequency jet ventilation
(HFJV)
3.High frequency oscillator ventilation
(HFOV)
Assisted ventiltion of the neonate, Goldsmith 6th edition
HFOV HFJV HFFI
High flow
generated by
Electromagnet
ic piston or
diaphragm
oscillator
Pincevalve or
injector
cannula
Solenoid valve
ExpirationActive passive passive
InspirationActive Active Active
Frequency 5 to15HZ 5 to 10HZ 8 to 12 HZ
Sigh
superimpose
yes yes yes
Basic differences
High flow
generated by
Electromagnet
ic piston or
diaphragm
oscillator
Pincevalve or
injector
cannula
Solenoid valve
ExpirationActive passive passive
InspirationActive Active Active
Frequency 5 to15HZ 5 to 10HZ 8 to 12 HZ
Sigh
superimpose
yes yes yes
Basic differences
High frequency oscillatory ventilation
HFOV in BSMMU,NICU
Dragger babylog 8000
Dragger babylog 8000
Why HFV?
Small tidal volumes limits alveolar over
distension .
Higher MAPBetter alveolar
recruitment.
Constant P
awduring inspiration and
expirationpreventing end alveolar
collapse.
Small tidal volumes limits alveolar over
distension .
Higher MAPBetter alveolar
recruitment.
Constant P
awduring inspiration and
expirationpreventing end alveolar
collapse.
What is VILI
?
Ventilator Initiated Lung
Injury
1.Barotrauma
2.Volutrauma
3.Atelectrauma
4.Biotrauma
Slutsky, Chest, 1999
?
Ventilator Initiated Lung
Injury
1.Barotrauma
2.Volutrauma
3.Atelectrauma
4.Biotrauma
Slutsky, Chest, 1999
Barotrauma
Slutsky, Chest, 1999
Slutsky, Chest, 1999
Volutrauma
Excessive end-
inspiratory alveolar
volumes are the
major determinant
of volutrauma.
Excessive end-
inspiratory alveolar
volumes are the
major determinant
of volutrauma.
Atelectrauma
Biotrauma
•This biological form of trauma is known as biotrauma.
•This biological form of trauma is known as biotrauma.
HFOV is used to prevent
ventilator induced lung
injury
Critical opening
pressure
Critical maximum
pressure
Critical closing
pressure
ventilator induced lung
injury
Critical opening
pressure
Critical maximum
pressure
Critical closing
pressure
PressureandVolumeSwings
•DuringCMV,thereareswings
betweenthezonesofinjuryfrom
inspirationtoexpiration.
•DuringHFOV,theentirecycle
operatesinthe“safewindow”and
avoidstheinjuryzones.
•DuringCMV,thereareswings
betweenthezonesofinjuryfrom
inspirationtoexpiration.
•DuringHFOV,theentirecycle
operatesinthe“safewindow”and
avoidstheinjuryzones.
Advantages of HFV
•Small tidal volumes prevents alveolar over distension and
Volutrauma .
•Higher mean airway pressure (MAP )-improved alveolar
recruitment leading to better oxygenation.
•Smaller gradient between inspiratory and expiratory
pressure-prevent cyclical distention and alveolar collapse—
hence less atelectrauma
•Low peak pressure –reduce barotrauma
•Small tidal volumes prevents alveolar over distension and
Volutrauma .
•Higher mean airway pressure (MAP )-improved alveolar
recruitment leading to better oxygenation.
•Smaller gradient between inspiratory and expiratory
pressure-prevent cyclical distention and alveolar collapse—
hence less atelectrauma
•Low peak pressure –reduce barotrauma
Indications of HFV
1.When conventional ventilation fails
–reduced compliance,RDS/ARDS,meconium aspiration ,BPD
,pneumonia,atelectasis,lung hypoplasia
Other: PPHN
2.Primary mode of ventilation in extreme prematurity.
3.Air leak syndromes (pneumothorax, PIE)
4.Congenital diaphragmatic hernia.
Assisted ventiltion of the neonate, Goldsmith 6th edition
Dragger manuals –high frequency ventilation basics and
practical application
1.When conventional ventilation fails
–reduced compliance,RDS/ARDS,meconium aspiration ,BPD
,pneumonia,atelectasis,lung hypoplasia
Other: PPHN
2.Primary mode of ventilation in extreme prematurity.
3.Air leak syndromes (pneumothorax, PIE)
4.Congenital diaphragmatic hernia.
Assisted ventiltion of the neonate, Goldsmith 6th edition
Dragger manuals –high frequency ventilation basics and
practical application
Contraindications
•Relative contraindications for the use of HFV is
pulmonary obstruction.
•Relative contraindications for the use of HFV is
pulmonary obstruction.
Mechanism of gas exchange
•HFV Provides augmented gas distribution by means of
numerous gas transport mechanisms.
Assisted ventiltion of the neonate, Goldsmith 6th edition
Convection ventilation( bulk flow)
Taylor dispersion
Pendelluft effect
Asymmetric velocity profiles
Cardiogenic Mixing
Molecular diffusion
Collateral Ventilation
•HFV Provides augmented gas distribution by means of
numerous gas transport mechanisms.
Assisted ventiltion of the neonate, Goldsmith 6th edition
Convection ventilation( bulk flow)
Taylor dispersion
Pendelluft effect
Asymmetric velocity profiles
Cardiogenic Mixing
Molecular diffusion
Collateral Ventilation
Convection ventilation( bulk flow)
Mechanism of gas exchange
In HFOV, where the "tidal volume" is negligible, bulk convection is represented
by the continual entrainment of fresh gas, as oxygen is absorbed at the
alveolus. The decreased pressure generated by continual gas removal makes
space for more gas.
Mechanism of gas exchange
In HFOV, where the "tidal volume" is negligible, bulk convection is represented
by the continual entrainment of fresh gas, as oxygen is absorbed at the
alveolus. The decreased pressure generated by continual gas removal makes
space for more gas.
Mechanism of gas exchange
•Taylor dispersion-in which augmented diffusionoccurs because of turbulant air
currents that results from interection between axial velocity and the radial
concentration gradient.
High frequency ventilation:current status, AAP ,Drager
•Taylor dispersion-in which augmented diffusionoccurs because of turbulant air
currents that results from interection between axial velocity and the radial
concentration gradient.
High frequency ventilation:current status, AAP ,Drager
Taylor dispersion
Secondary gas movements occur at airway bends and bifurcations creating
turbulent eddies that enhance radial gas mixing(movement of gas particles
from the centre of flow to the stationary boundary layer along the wall) at the
expense of longitudinal gas transport
Secondary gas movements occur at airway bends and bifurcations creating
turbulent eddies that enhance radial gas mixing(movement of gas particles
from the centre of flow to the stationary boundary layer along the wall) at the
expense of longitudinal gas transport
Mechanism of gas exchange
Pendellufteffect
Notallregionsofthelunghavethe
samecomplianceandresistance.
Therefore,neighboringunitswith
differenttimeconstantsareventilated
outofphase,fillingandemptyingat
differentrates.Duetothisasynchrony
theseunitscanmutuallyexchangeby
blowinggasintoeachotherwhenone
iscollapsingandtheotherstill
remainsopen,aneffectknownas
pendelluft.Bywayofthismechanism
evenverysmallfresh-gasvolumescan
reachalargenumberofalveoliand
regions.
Pendelluft effect -in which regional
differences in time constants for inflation
and deflation cause gas to recirculate
among lung units and improve gas
exchange.
Pendellufteffect
Notallregionsofthelunghavethe
samecomplianceandresistance.
Therefore,neighboringunitswith
differenttimeconstantsareventilated
outofphase,fillingandemptyingat
differentrates.Duetothisasynchrony
theseunitscanmutuallyexchangeby
blowinggasintoeachotherwhenone
iscollapsingandtheotherstill
remainsopen,aneffectknownas
pendelluft.Bywayofthismechanism
evenverysmallfresh-gasvolumescan
reachalargenumberofalveoliand
regions.
Pendelluft effect -in which regional
differences in time constants for inflation
and deflation cause gas to recirculate
among lung units and improve gas
exchange.
Asymmetrical velocity
Airflow moving through the airways moves in a u-shape formation. At the
center of the lumen air will move at a faster velocity, than air that is closest
to the wall.
Airflow moving through the airways moves in a u-shape formation. At the
center of the lumen air will move at a faster velocity, than air that is closest
to the wall.
Mechanism of gas exchange
As the heart beats the heart provides additional peripheral mixing
by exerting pressure against the lungs during contraction of the
heart. This pressure promotes the movement of gas flow through
the neighboring parenchymal regions.
As the heart beats the heart provides additional peripheral mixing
by exerting pressure against the lungs during contraction of the
heart. This pressure promotes the movement of gas flow through
the neighboring parenchymal regions.
Molecular diffusion
Maintaining a constant
distending pressure with
HFV within the lungs
along with movement of
gas molecules promotes
gas diffusion across the
alveolar membrane, at a
faster rate.
Maintaining a constant
distending pressure with
HFV within the lungs
along with movement of
gas molecules promotes
gas diffusion across the
alveolar membrane, at a
faster rate.
Oscillatory pressure
apply at the airway
opening
Tyler
dispersion
occurs
apply at the airway
opening
Tyler
dispersion
occurs
Control variables of HFV
1.Mean airway pressure
(P
aw)/ MAP
2.Amplitude /
oscillatory volume (∆P)
3.Oscillatory frequency
4.The gas transport
coefficient (DCO2)
1.Mean airway pressure
(P
aw)/ MAP
2.Amplitude /
oscillatory volume (∆P)
3.Oscillatory frequency
4.The gas transport
coefficient (DCO2)
Variables
1.Mean airway pressure (P
aw)-.MAP is used to
optimize the lung volume and thus alveolar surface for
gas exchange Better oxygenation
Range of Paw are 3-25 mbar/25-30 cm of H20
Paw should be 2-5 cm H2O higher than the previous
conventional ventilation(As high lung volume strategy)
In case of air -leaks syndrome –MAP should be 2 cm
bellow the CMV(Low lung strategy)
1.Mean airway pressure (P
aw)-.MAP is used to
optimize the lung volume and thus alveolar surface for
gas exchange Better oxygenation
Range of Paw are 3-25 mbar/25-30 cm of H20
Paw should be 2-5 cm H2O higher than the previous
conventional ventilation(As high lung volume strategy)
In case of air -leaks syndrome –MAP should be 2 cm
bellow the CMV(Low lung strategy)
2. Amplitude -oscilatory volume (∆P)
Amplitude is the maximum extent of a vibration or
oscillation. Referred as delta p. The degree of deflection of
the piston (amplitude) determines the tidal volume .Average
newborn Amplitude 20-30 cm of H20.
Amplitude is increased until there is visible chest wall
vibration(wiggle).
If amplitude ↑ → ↑ oscillatory volume → ↑TV →
↓PCo
2→improve ventilation.
If baby is under-ventilated what will do?
Ans: ↑ Amplitude
Amplitude is the maximum extent of a vibration or
oscillation. Referred as delta p. The degree of deflection of
the piston (amplitude) determines the tidal volume .Average
newborn Amplitude 20-30 cm of H20.
Amplitude is increased until there is visible chest wall
vibration(wiggle).
If amplitude ↑ → ↑ oscillatory volume → ↑TV →
↓PCo
2→improve ventilation.
If baby is under-ventilated what will do?
Ans: ↑ Amplitude
3.Frequency-Number of cycles per unit of time.
measured in units of Hertz. ( 1 Hz = 60 breaths/min)
Usually start as 10 -12 HZ but set as 15 Hz for
premature infants with RDS.
↓ Oscillatory frequency → ↑ oscillatory amplitude,
↑oscillatory volume → ↑TV → ↓ Pco
2
and vice versa
measured in units of Hertz. ( 1 Hz = 60 breaths/min)
Usually start as 10 -12 HZ but set as 15 Hz for
premature infants with RDS.
↓ Oscillatory frequency → ↑ oscillatory amplitude,
↑oscillatory volume → ↑TV → ↓ Pco
2
and vice versa
4.Gas transport co efficient (DCo
2)
In conventional ventilation the product of tidal volume and
frequency, known as minute volume or minute ventilation, aptly
describes pulmonary gas exchange. Different study groups have
found that CO
2 elimination in HFO however correlates well with
VT
2
x f
Here, VT andfstand for oscillatory volume and frequency, re
spectively. This parameter is called ‘gas transport coefficient’,
DCO2.
An increase in DCO
2 will decrease pCO
2
2)
In conventional ventilation the product of tidal volume and
frequency, known as minute volume or minute ventilation, aptly
describes pulmonary gas exchange. Different study groups have
found that CO
2 elimination in HFO however correlates well with
VT
2
x f
Here, VT andfstand for oscillatory volume and frequency, re
spectively. This parameter is called ‘gas transport coefficient’,
DCO2.
An increase in DCO
2 will decrease pCO
2
Variables in oxygenation
•The two primarily variables that control oxygenation are:
–F
iO
2
–Mean airway pressure (P
aw)
•The two primarily variables that control oxygenation are:
–F
iO
2
–Mean airway pressure (P
aw)
Variables in ventilation
•The two primarily variables that control ventilation are:
–Tidal volume(P or amplitude)
•Controlled by the force with which the oscillatory
piston moves. (represented as stroke volume or P)
–Frequency()
•Referenced in Hertz (1 Hz = 60 breaths/second)
•Range: 3 -15 Hz
•The two primarily variables that control ventilation are:
–Tidal volume(P or amplitude)
•Controlled by the force with which the oscillatory
piston moves. (represented as stroke volume or P)
–Frequency()
•Referenced in Hertz (1 Hz = 60 breaths/second)
•Range: 3 -15 Hz
Initial settings
Dependsonpathology
•Optimallungvolumestrategy-
maximizerecruitmentofalveoli.
•Lowvolumestrategy-
minimizelungtrauma.
Dependsonpathology
•Optimallungvolumestrategy-
maximizerecruitmentofalveoli.
•Lowvolumestrategy-
minimizelungtrauma.
MAP: 2-5mbar above MAP of CMV
Frequency: 10 Hz
Amplitude: 50-100% watch thorax
vibrations
Volume: about 2 to 2.5 ml/kg
Fi02:100%
Start HFV
Frequency: 10 Hz
Amplitude: 50-100% watch thorax
vibrations
Volume: about 2 to 2.5 ml/kg
Fi02:100%
Start HFV
Oxygenation
Initiate Fio2 100% and Set MAP 2 cm above or bellow (air leak syndrome) than
CMV to give spo2 90-95%
Increase MAP 1-2 cm of H20 in every 2-5 minutes and reduce Fio2 stepwise 5-
10% to maintain Spo2 90-95% ( MAP increased until Fio2 less than 0.3)
Once baby Stable in an Fio2 less than 0.3 then MAP should be cautiously
reduced 1-2 cm H20 as allowed the oxygenation
Dragger manuals –high frequency ventilation basics and practical application
RPA Newborn Care Guidelines
Initiate Fio2 100% and Set MAP 2 cm above or bellow (air leak syndrome) than
CMV to give spo2 90-95%
Increase MAP 1-2 cm of H20 in every 2-5 minutes and reduce Fio2 stepwise 5-
10% to maintain Spo2 90-95% ( MAP increased until Fio2 less than 0.3)
Once baby Stable in an Fio2 less than 0.3 then MAP should be cautiously
reduced 1-2 cm H20 as allowed the oxygenation
Dragger manuals –high frequency ventilation basics and practical application
RPA Newborn Care Guidelines
Ventilation
Set Amplitude (ďP) 50%
observe good wiggle and adjust Amplitude accordingly
Adjust Amplitude increment 10%(3-5 cm of H20) for optimum PaCo2
If PaCo2 fails to fall even after increased Amplitude then decrease
Frequency 0.5-1 HZ
Set Amplitude (ďP) 50%
observe good wiggle and adjust Amplitude accordingly
Adjust Amplitude increment 10%(3-5 cm of H20) for optimum PaCo2
If PaCo2 fails to fall even after increased Amplitude then decrease
Frequency 0.5-1 HZ
Troubleshooting and adjustment during HFOV
Hypoxia Hyperoxia Hypercapnia Hypocapnia
IncreaseFi02 Decrease Fi02 Increase AmplitudeDecrease
Ampiltude
Increase MAP (1-2
cm H20)
Decrease MAP(1-2
cm H20)
Decrease
Frequency (1-2 cm
H20) if MAP max
Increase
Frequency(1-2 cm
H20) if MAP max
Alternatively(ifHypoxia):applysustainedinflationatlow
lungvolume,applysighmanoeuvreevery20minutesfor
10to20secondsat10to15mbaraboveMAP
Hypoxia Hyperoxia Hypercapnia Hypocapnia
IncreaseFi02 Decrease Fi02 Increase AmplitudeDecrease
Ampiltude
Increase MAP (1-2
cm H20)
Decrease MAP(1-2
cm H20)
Decrease
Frequency (1-2 cm
H20) if MAP max
Increase
Frequency(1-2 cm
H20) if MAP max
Alternatively(ifHypoxia):applysustainedinflationatlow
lungvolume,applysighmanoeuvreevery20minutesfor
10to20secondsat10to15mbaraboveMAP
Others
Suboptimallungvolumerecruitment:
IncrementMAP
ConsiderCXR
Overinflation:reduceMAP
decreasefrequency
ConsiderCXR
Hypotension:volumeexpansion
Dopamine/Dobutamine
reduceMAP
discontinueHFO
Suboptimallungvolumerecruitment:
IncrementMAP
ConsiderCXR
Overinflation:reduceMAP
decreasefrequency
ConsiderCXR
Hypotension:volumeexpansion
Dopamine/Dobutamine
reduceMAP
discontinueHFO
Monitoring during HFV
1.Visualassessment:Activity,chestwallvibrationand
symmetry
2.Wigglefactor
3.ChestAuscultationforOscillator
4.Ventilatoryparameter
5.Bloodgasanalysis
6.Lungvolume:CXR
7.MonitorHemodynamics:Heartrate,BP,CRT,CVP,Echo
8.Organperfusion:Urineoutput,Renalfunction
1.Visualassessment:Activity,chestwallvibrationand
symmetry
2.Wigglefactor
3.ChestAuscultationforOscillator
4.Ventilatoryparameter
5.Bloodgasanalysis
6.Lungvolume:CXR
7.MonitorHemodynamics:Heartrate,BP,CRT,CVP,Echo
8.Organperfusion:Urineoutput,Renalfunction
“Wiggle Factor”
•Chest movement after initiation of HFOV indicates good
ventilation.
•If chest oscillation is diminished or absent consider:
1.Decreased pulmonary compliance
2.ETT disconnect
3.ETT obstruction
4.Severe bronchospasm
•If the chest oscillation is unilateral, consider:
1.ETT displacement (right mainstem)
2.Pneumothorax
•Chest movement after initiation of HFOV indicates good
ventilation.
•If chest oscillation is diminished or absent consider:
1.Decreased pulmonary compliance
2.ETT disconnect
3.ETT obstruction
4.Severe bronchospasm
•If the chest oscillation is unilateral, consider:
1.ETT displacement (right mainstem)
2.Pneumothorax
Humidification
It is essential to adequately humidify (90%) the breathing
gas. Otherwise severe irreversible damage to the trachea
may result. Viscous secretion could obstruct bronchi and
deteriorate the pulmonary situation. Excessive
humidification on the other hand can lead to
condensation in the patient circuit, the ET tube and the
airways, completely undoing the effect of HFV.
It is essential to adequately humidify (90%) the breathing
gas. Otherwise severe irreversible damage to the trachea
may result. Viscous secretion could obstruct bronchi and
deteriorate the pulmonary situation. Excessive
humidification on the other hand can lead to
condensation in the patient circuit, the ET tube and the
airways, completely undoing the effect of HFV.
Weaning
HFV:Weaning
1.ReduceFiO
2to0.3–0.5
2.ReduceMAPby1to2mbarperhouruntil(8)to9mbar;
thenincreaseIMVrate
3.Reduceamplitude
4.ContinueventilationwithIMV/SIMVandweaning
5.ExtubationfromHFVisalsopossibleifrespiratory
activityissufficient
HFV:Weaning
1.ReduceFiO
2to0.3–0.5
2.ReduceMAPby1to2mbarperhouruntil(8)to9mbar;
thenincreaseIMVrate
3.Reduceamplitude
4.ContinueventilationwithIMV/SIMVandweaning
5.ExtubationfromHFVisalsopossibleifrespiratory
activityissufficient
Points Diffuse homogeneous lung
diseases
Inhomogeneous lung
diseases
Goals lung expansion less barotrauma improvedoxygenation
andventilationat
minimumMAP
Starts/initiationMAP 2 to 5 mbar above that of
CMV
MAP like or below that of
CMV and low
frequency(7HZ)
Changes & weaningincrease MAP until pO
2rises by 20
to 30 mmHg, or signs of over-
inflation appear then reduce FiO
2
to 0.3 –0.5 then continue weaning
increaseMAPuntilPO
2
slightlyrises;keep
MAP constant;if
respiratorysituation
failstoimprovereturn
toCMV.
Risk Overinflation partial overexpansion
Assesment Clinical and CXR Clinical and CXR
Strategies for various lung diseases
diseases
Inhomogeneous lung
diseases
Goals lung expansion less barotrauma improvedoxygenation
andventilationat
minimumMAP
Starts/initiationMAP 2 to 5 mbar above that of
CMV
MAP like or below that of
CMV and low
frequency(7HZ)
Changes & weaningincrease MAP until pO
2rises by 20
to 30 mmHg, or signs of over-
inflation appear then reduce FiO
2
to 0.3 –0.5 then continue weaning
increaseMAPuntilPO
2
slightlyrises;keep
MAP constant;if
respiratorysituation
failstoimprovereturn
toCMV.
Risk Overinflation partial overexpansion
Assesment Clinical and CXR Clinical and CXR
Strategies for various lung diseases
Points Air leaks diseases Pulmonary hypertension of
the newborn (PPHN)
Goals improved oxygenation and
ventilation at minimum MAP;
(accept lower pO
2and higher pCO
2)
tooptimizelung
volumeandperfusion
toimprovehypoxia
andhypercapnia
Starts/initiationMAP like or below that of CMV and
low frequency(7HZ)
-Frequency:<10Hz
–amplitude:100%
–MAP:onthelevelof
CMV
Changes & weaning ReducepressurepriortoFiO
2
–ContinueHFVfor24to48
hoursafterimprovement
reduceO2priorto
MAPandMaintain
HFVfor24to48hours
afterrecovery
Risk Over-distention Avoidhypovolemia
Assesment Clinical and CXR Clinical and CVP
the newborn (PPHN)
Goals improved oxygenation and
ventilation at minimum MAP;
(accept lower pO
2and higher pCO
2)
tooptimizelung
volumeandperfusion
toimprovehypoxia
andhypercapnia
Starts/initiationMAP like or below that of CMV and
low frequency(7HZ)
-Frequency:<10Hz
–amplitude:100%
–MAP:onthelevelof
CMV
Changes & weaning ReducepressurepriortoFiO
2
–ContinueHFVfor24to48
hoursafterimprovement
reduceO2priorto
MAPandMaintain
HFVfor24to48hours
afterrecovery
Risk Over-distention Avoidhypovolemia
Assesment Clinical and CXR Clinical and CVP
Complications
1.Irritation-requiremoresedation.
2.hemodynamics-highMAPcanjeopardiesvenous
returnandcardiacoutputandalsoincrease
puolmonaryvascularresistance,Hypotension
3.Airtrapping
4.Overinflation
5.Necrotizingtracheobronchitis
6.Intracranialhaemorrhages.
1.Irritation-requiremoresedation.
2.hemodynamics-highMAPcanjeopardiesvenous
returnandcardiacoutputandalsoincrease
puolmonaryvascularresistance,Hypotension
3.Airtrapping
4.Overinflation
5.Necrotizingtracheobronchitis
6.Intracranialhaemorrhages.
Evidences
High-frequency oscillatory ventilation versus conventional
mechanical ventilation for very-low-birth-weight infants.
N Engl J Med. 2002 Aug 29;347(9):643-52.
Courtney SE, Durand DJ, Asselin JM, Hudak ML, Aschner JL, Shoemaker
CT; Neonatal Ventilation Study Group.
Here was a small but significant benefit of high-frequency oscillatory
ventilation in terms of the pulmonary outcome for very-low-birth-weight
infants without an increase in the occurrence of other complications of
premature birth.
High-frequency oscillatory ventilation versus conventional
mechanical ventilation for very-low-birth-weight infants.
N Engl J Med. 2002 Aug 29;347(9):643-52.
Courtney SE, Durand DJ, Asselin JM, Hudak ML, Aschner JL, Shoemaker
CT; Neonatal Ventilation Study Group.
Here was a small but significant benefit of high-frequency oscillatory
ventilation in terms of the pulmonary outcome for very-low-birth-weight
infants without an increase in the occurrence of other complications of
premature birth.
Evidence
Asaprimarymode
Electivehighfrequencyventilationcomparedto
conventionalmechanicalventilationintheearlystabilization
ofinfantswithrespiratorydistress-Cochrane-March2015
Insufficientevidenceexiststosupporttheroutineuseofhigh
frequencyoscillatoryventilationinsteadofconventionalventilation
forpreterminfants.
Asaprimarymode
Electivehighfrequencyventilationcomparedto
conventionalmechanicalventilationintheearlystabilization
ofinfantswithrespiratorydistress-Cochrane-March2015
Insufficientevidenceexiststosupporttheroutineuseofhigh
frequencyoscillatoryventilationinsteadofconventionalventilation
forpreterminfants.
•High frequency oscillatory ventilation is a way of providing
artificial ventilation of the lungs that theoretically may produce
less injury to the lungs and therefore reduce the rate of chronic
lung disease. This review of the evidence from 19 randomized
controlled trials showed that although a small protective effect
towards the lungs can be seen, this moderate benefit is highly
variable between studies and should be weighed against
possible harm.
artificial ventilation of the lungs that theoretically may produce
less injury to the lungs and therefore reduce the rate of chronic
lung disease. This review of the evidence from 19 randomized
controlled trials showed that although a small protective effect
towards the lungs can be seen, this moderate benefit is highly
variable between studies and should be weighed against
possible harm.
Authors’ conclusions :There are no data from randomized controlled trials
supporting the routine use of rescue HFOV in term or near term infants with
severe pulmonary dysfunction. The area is complicated by diverse pathology in
such infants and by the occurrence of other interventions (surfactant, inhaled
nitric oxide, inotropes). Randomized controlled trials are needed to establish the
role of rescue HFOV in near term and term infants with pulmonary dysfunction
before widespread use of this mode of ventilation in such infants.
supporting the routine use of rescue HFOV in term or near term infants with
severe pulmonary dysfunction. The area is complicated by diverse pathology in
such infants and by the occurrence of other interventions (surfactant, inhaled
nitric oxide, inotropes). Randomized controlled trials are needed to establish the
role of rescue HFOV in near term and term infants with pulmonary dysfunction
before widespread use of this mode of ventilation in such infants.
•Conclusions. The results of this study support the idea that rescue
HFOV may increase survival of CDH patients, when conventional
mechanical ventilation fails .We suggest that all deceased CDH patients
should have a necropsy study in order to identify other congenital
malformations that may pass undetected on prenatal and postnatal
evaluation, and the lung histological findings that may explain the failure
of the respiratory mode.
HFOV may increase survival of CDH patients, when conventional
mechanical ventilation fails .We suggest that all deceased CDH patients
should have a necropsy study in order to identify other congenital
malformations that may pass undetected on prenatal and postnatal
evaluation, and the lung histological findings that may explain the failure
of the respiratory mode.
Looking towards the future
•A great deal remains unknown about HFOV:
–the exact mechanism of gas exchange
–the most effective strategy to manipulate ventilator settings
–the safest approach to manipulate ventilator settings
–a reliable method to measure tidal volume
–the appropriate use of sedation and neuromuscular blockade
to optimize patient-ventilator interactions
•Additional research in these and other issues related to HFOV
are necessary to maximize the benefit and minimize the
potential risks associated with HFOV.
•A great deal remains unknown about HFOV:
–the exact mechanism of gas exchange
–the most effective strategy to manipulate ventilator settings
–the safest approach to manipulate ventilator settings
–a reliable method to measure tidal volume
–the appropriate use of sedation and neuromuscular blockade
to optimize patient-ventilator interactions
•Additional research in these and other issues related to HFOV
are necessary to maximize the benefit and minimize the
potential risks associated with HFOV.
References
•Goldsmith: Assisted ventilation of the neonate
•Dragger manuals –high frequency ventilation basics and practical
application
•High frequency ventilation: current status, pediatrics in review
•Priebe GP, Arnold JH: High-frequency oscillatory ventilation in
pediatric patients. Respir Care Clin N Am 2001; 7(4):633-645
•RPA newborn care guideline
•Arnold JH: High-frequency ventilation in the pediatric intensive
care unit. Pediatr Crit Care Med 2000; 1(2):93-99
•Goldsmith: Assisted ventilation of the neonate
•Dragger manuals –high frequency ventilation basics and practical
application
•High frequency ventilation: current status, pediatrics in review
•Priebe GP, Arnold JH: High-frequency oscillatory ventilation in
pediatric patients. Respir Care Clin N Am 2001; 7(4):633-645
•RPA newborn care guideline
•Arnold JH: High-frequency ventilation in the pediatric intensive
care unit. Pediatr Crit Care Med 2000; 1(2):93-99
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