ventilator mode classification
DESCRIPTION
3 level classification of mechanical ventilator modesTRANSCRIPT
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Ventilator modes classification
JEEVANLAL RESPIRATORY THERAPIST
AIMS
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KEY POINTS
1. CONTROL
To describe how the ventilator manages p v and flow delivery within a breath
Sequence of mandatory and spontns brth to create specific breathing patterns
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Equation of motion for respiratory system
equation of
motion
Pvent
+Pmus
= P E+ PR
Pvent =
pressure
generated by
the vent @
Airway
opening
Pmus
=
presur
e generated by
the vent mus
PE = the
elastic load
PR =
the resistive load
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Two main functions in mech .vent
1. To calculate the lung mechanic parameters of R, C given information about p, v and flow.
2. To predict p, v, flow given values for R & C
“For any mode only one variable can be controlled at a time” ( p v &flow)
Flow is the derivative of volume as a function of tme, and volume is the integral of flow
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MODE
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Continue….
Thus a mode description reduces a
specification of how the ventilator controls
P, V, flow within a breath .
Along with a description of how
the breaths are sequenced.
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3 componentsA description of the breathing sequence & control
variables within brths.
A description of control
type used within & between brths.
A detailed description of adjunctive contr
ol algorithms.
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CLASSIFICATION
1. Breathing pattern
a. Primary breath-control variable Volume Pressure Dual b. Breath sequence Continuous mandatory ventilation (CMV) Intermittent mandatory ventilation (IMV) Continuous spontaneous ventilation (CSV)
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2. CONTROLL TYPE
a. Tactical control (within breaths) Set point Auto-set-point Servo b. Strategic control (between breaths) Adaptive Optimal C. Intelligent control (between patients) Knowledge-based Artificial neural network
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3. operational algorithms
a. Phase variables Trigger Limit Cycle Baseline b. Conditional variables c. Computational logic
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BREATHING PATTERN
a). Primary Breath Control Variable
V, P & Dual Control
b). Breath Sequence
CMV, IMV and CSV
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1.Breathing pattern
1a. Control variable.
The control variable is the variable that the ventilator uses as a feedback signal to control inspiration
(ie, pressure, volume, or flow).
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Continue….
The control variable can be identified as follows: If the peak inspiratory pressure remains constant
as the load experienced by the ventilator changes,
then the control variable is pressure.
If the peak pressure changes as the load changes but VT remains constant, then the control variable is volume.
Volume control implies flow control and vice versa,
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Dual control
‘’ Inspiration starts out as VCV and then switches to PCV before the end of breath
or vice versa ”
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BREATH SEQUENCE
CMV
IMV
CSV
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8 breathing patterns…
Volume Continuous mandato
ry ventilation
VC-CMV
Intermittent
mandato
ry ventilation VC-IMV
Pressur
e Continuous mandato
ry ventilation
PC-CMV
Intermittent
mandato
ry ventilation
PC-IMV
Continuous spontaneou
s ventilation
PC-CSV
Dual
Continuous mandato
ry ventilation
DC-CMV
Intermittent
mandato
ry ventilation
DC-IMV
Continuous spontaneou
s ventilation
DC-CSV
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Why not VC-CSV
Volume control implies that the ventilator determines the
tidal volume [VT], whereas in a spontaneous breath the
patient determines the VT.
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CMV VS IMV
The key difference now between CMV and IMV is that
with CMV the clinical intent is to make every inspiration a mandatory breath,
Whereas with IMV the clinical intent is to partition ventilatory support between mandatory and spontaneous breaths.
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Continue..
CMV is normally considered a method of full ventilatory support,
whereas IMV is usually viewed as a method of partial ventilatory support (eg, for weaning).
“Thus for classification purposes, if spontaneous breaths are not allowed between mandatory breaths, the breath sequence is CMV; otherwise the sequence is IMV ”
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CONTROL TYPE
Control type is a categorization of the ventilators feedback control function .
At the most basic level control is focused on what happens within a breath
Tactical Control – within breath (set point, auto set point , servo )
Strategic Control – between breaths ( adaptive , optimal ) Intelligent Control – between patients ( knowledge based , artificial neural network)
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Basic types of control used
Set point The output of the ventilator matches a
constant operator preset input value . Mandatory breaths are pressure limited and
time cycled, according to the operator set values for peak inspiratory pressure and frequency
Eg : PC-IMV
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Auto set point
The ventilator Selects which operator adjusted set points are enforced at the moment
Inspiration starts in PCV and switches to VCV
Eg ; volume assured pressure support
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Servo
The ventilator output automatically follows a varying input
The instantaneous value of pressure is proportional to the instantaneous volume or flow generated by the patient .
Eg; PAV & ATC
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Adaptive
One ventilator set point is automatically adjusted to achieve another set point as the patient condition changes .
Mandatory breaths are pressure limited , and the pressure limit is automatically adjusted between breaths to achieve the preset tidal volume
Eg ; PRVC
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OPTIMAL
One ventilator set point is automatically adjusted to optimize another set point according to some model of system behavior, whose output can be maximized or minimized dynamically.
Each breath is pressure limited , and the pressure limit is automatically adjusted between breaths ( using ventilator mechanics measurements ) to minimize WOB
Eg ; adaptive support ventilation
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KNOWLEDGE BASED
Set points are automatically adjusted according to a rule based expert system.
pressure support level for spontaneous breath is automatically adjusted to maintain appropriate breathing frequency, TV, ETCO2, depending on the type of patient .
Eg : smart care
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Artificial neural network
Auto adjusted set points by artificial neural network. The relation b/w inputs & outputs determined by
weighting factors at neural nodes that change with learning.
The network inputs are the current ventilator settings and partial pressure of ABG and PH
Network outputs are the most appropriate ventilator settings projected to maintain blood gases within an acceptable range
Eg ; experimental
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Scheme
VentilatorOperator Patient
Tactical Control
Stategic Control
VentilatorModelOperator Patient
Intelligent Control
ModelVentilator
Patient
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Operating algorithm
PHASE VARIABLES
a. Phase variables Trigger Limit Cycle Baselineb. Conditional variablesc. Computational logic
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T - Trigger
L - Limit
C - Cycle
B - Baseline
Time
Pre
ssu
re
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Phase variable
The phase variable begins, sustains, and ends each of the four phases of a breath .
The four phases are ;
1. Change from exhalation to inhalation
2. inspiration
3. Change from inspiration to expiration
4. Exhalation
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Triggering
The mechanism the ventilator uses to end exhalation and begin inspiration is the triggering mechanism .
Time trigger ; the ventilator can trigger itself, the rate of breathing is controlled by the
ventilator . So this mode sometimes is called controlled
ventilation
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PRESSURE TRIGGERVentilator initiates a breath according to a predetermined time interval
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•Patient trigger ;#. when the ventilator detects changes in P, F or V pt triggered breath occurs .#. P & flow are common patient triggering mechanisms. #. The operator must set the sensitivity level to fit the patients needs. (auto trigger,WOB)
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PRESSURE TRIGGER
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Flow trigger $. flow triggering occurs the ventilator detects a drop in flow through the patient circuit during exhalation Volume trigger $. Volume triggering occurs when the ventilator detects a small drop in volume in the pt circuit during exhalation
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FLOW TRIGGER
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Limit variable
A limit variable is the maximum value a variable ( p, v, v; t) can attain .
1. Pressure limiting; allows pressure to rise to a certain value but not exceed it .
To prevent excessive pressure from entering the patients lungs , the operator set a control sometimes labeled a high pressure limit.
when the vent reaches the high p limit excess pressure will vented through a spring loaded pressure release or valve.
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2.Volume limiting
A volume limited breath is controlled by an electronically operated valve that measures the flow passing through during a specific interval .
The volume may be set by the operator, or the ventilator may have a bag, or piston cylinder that contains a fixed volume .
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3. Flow limiting
If ventilator flow to the patient reaches but does not exceed a maximum value before the end of inspiration , the ventilator is flow limited .
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Cycle variable
The variable a ventilator measures to determine the end of inspiration is called the cycling mechanism .
Volume cycling ; the inspiratory phase of a volume cycled breath is terminated when the set volume has been delivered .
Time cycling ; a breath is considered time cycled if the inspiratory phase ends when a predetermined time has elapsed (PCV)
Flow cycling ; the ventilator cycles into the expiratory phase once the flow has decreased to a pre determined value during inspiration (ps)
pressure cycling ; when a preset pressure threshold is reached@ the mouth or upper airway , a ventilator set to pressure cycle ends to inspiration .
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Baseline variable
Baseline variable is the parameter that generally controlled during exhalation .
Although either V or flow could serve as a baseline variable , P is the most practical choice and is used by all modern ventilators.
The pressure level from which a ventilator breath begins is called the baseline pressure
It can be zero , which is also called (ZEEP) or (PEEP).
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PEEP WITH MANDATORY BREATHS
5
P A
0 Time
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Conditional Variables
Any unique combination of breathing pattern, control type, and operational
algorithms is technically a mode.
It can be described in terms of “if then” statements
Eg ; if spontaneous minute ventilation falls below a preset threshold , then deliver enough mandatory breaths to raise MV above the threshold .
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Computational Logic
Description of the relationship between the inputs, feedback signals, and outputs, adding detail about how the mode operates that does not given in the
other components of mode specification.
Eg ; ASV mode of Hamilton Galileo uses WOB as the performance function , and it is related to lung
mechanics, alveolar ventilation , dead space volume
And breathing frequency. As lung mechanics change, the ventilator finds the optimum frequency ( to
minimize wob) and then sets the VT to meet the MV
requirement .(Smartcare mode on dragger)
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Model delivery
Pt-triggered
No inspiratory effortSmall inspiratory effort
Large Insp effort
Machine Triggered
Reduced pressure indicates patient effort during inspirations
Set Tidal Volume
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No inspiratory effort
Large Insp effort
Machine Triggered
Reduced pressure
Set Tidal VolumeVolume
Target
Volume overshoot
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A machine that produces breathing patterns that mimic the humans normally breathe at rates and tidal volumes our bodies produces during the normal activities.
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”I am caring and guarding your breaths…..”
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THANK YOU