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Modes of mechanical ventilation

January 25, 2023

Modes of mechanical ventilation are one of the most important aspects of the usage of mechanical ventilation. The mode refers to the method of inspiratory support. In general, mode selection is based on clinician familiarity and institutional preferences, since there is a paucity of evidence indicating that the mode affects clinical outcome. The most frequently used forms of volume-limited mechanical ventilation are intermittent mandatory ventilation (IMV) and continuous mandatory ventilation (CMV).[1] There have been substantial changes in the nomenclature of mechanical ventilation over the years, but more recently it has become standardized by many respirology and pulmonology groups.[2][3] Writing a mode is most proper in all capital letters with a dash between the control variable and the strategy (i.e. PC-IMV, or VC-MMV etc.).

Taxonomy for mechanical ventilation

The taxonomy is a logical classification system based on 10 maxims of ventilator design[4]

10 maxims

  1. A breath is one cycle of positive flow (inspiration) and negative flow (expiration) defined in terms of the flow-time curve. Inspiratory time is defined as the period from the start of positive flow to the start of negative flow. Expiratory time is defined as the period from the start of expiratory flow to the start of inspiratory flow. The flow-time curve is the basis for many variables related to ventilator settings.
  2. A breath is assisted if the ventilator does work on the patient. An assisted breath is one for which the ventilator does some portion of the work of breathing. For constant flow inflation, work is defined as inspiratory pressure multiplied by tidal volume. Therefore, an assisted breath is identified as a breath for which airway pressure (displayed on the ventilator) rises above baseline during inspiration. An unassisted breath is one for which the ventilator simply provides the inspiratory flow demanded by the patient and pressure stays constant throughout the breath.
  3. A ventilator assists breathing using either pressure control or volume control based on the equation of motion for the respiratory system. Providing assistance means doing work on the patient, which is accomplished by controlling either pressure or volume. A simple mathematical model describing this fact is known as the equation of motion for the passive respiratory system:

    Pressure = (Elastance × Volume) + (Resistance × Flow)

    In this equation, pressure, volume, and flow are all continuous functions of time. Pressure is actually a pressure difference across the system (e.g., transrespiratory pressure defined as pressure at the airway opening minus pressure on the body surface). Elastance (defined as the change in pressure divided by the associated change in volume; the reciprocal of compliance) and resistance (defined as a change in pressure divided by the associated change in flow) are parameters assumed to remain constant during a breath.

    Volume control (VC) means that both volume and flow are preset prior to inspiration. In other words, the right hand side of the equation of motion remains constant while pressure changes with changes in elastance and resistance.
    Pressure control (PC) means that inspiratory pressure is preset as either a constant value or it is proportional to the patient's inspiratory effort. In other words, the left-hand side of the equation of motion remains constant while volume and flow change with changes in elastance and resistance.
    Time control (TC) means that, in some rare situations, none of the main variables (pressure, volume, or flow) are preset. In this case only the inspiratory and expiratory times are preset.

  4. Breaths are classified by the criteria that trigger (start) and cycle (stop) inspiration. The start of inspiration is called the trigger event. The end of inspiration is called the cycle event.
  5. Trigger and cycle events can be initiated by the patient or the machine. Inspiration can be patient triggered or patient cycled by a signal representing inspiratory effort. Inspiration may also be machine triggered or machine cycled by preset ventilator thresholds.

    Patient triggering means starting inspiration based on a patient signal independent of a machine trigger signal. Machine triggering means starting inspiratory flow based on a signal from the ventilator, independent of a patient trigger signal. Patient cycling means ending inspiratory time based on signals representing the patient determined components of the equation of motion, (ie, elastance or resistance and including effects due to inspiratory effort). Flow cycling is a form of patient cycling because the rate of flow decay to the cycle threshold is determined by patient mechanics. Machine cycling means ending inspiratory time independent of signals representing the patient determined components of the equation of motion.

  6. Breaths are classified as spontaneous or mandatory based on both the trigger and cycle events. A spontaneous breath is a breath for which the patient both triggers and cycles the breath. A spontaneous breath may occur during a mandatory breath (e.g. Airway Pressure Release Ventilation). A spontaneous breath may be assisted or unassisted. A mandatory breath is a breath for which the machine triggers and/or cycles the breath. A mandatory breath can occur during a spontaneous breath (e.g., High Frequency Jet Ventilation). A mandatory breath is, by definition, assisted.
  7. There are 3 breath sequences: Continuous mandatory ventilation (CMV), Intermittent Mandatory Ventilation (IMV), and Continuous Spontaneous Ventilation (CSV). A breath sequence is a particular pattern of spontaneous and/or mandatory breaths. The 3 possible breath sequences are: continuous mandatory ventilation, (CMV, spontaneous breaths are not allowed between mandatory breaths), intermittent mandatory ventilation (IMV, spontaneous breaths may occur between mandatory breaths), and continuous spontaneous ventilation (CSV, all breaths are spontaneous).
  8. There are 5 basic ventilatory patterns: VC-CMV, VC-IMV, PC-CMV, PC-IMV, and PC-CSV. The combination VC-CSV is not possible because volume control implies machine cycling and machine cycling makes every breath mandatory, not spontaneous. A sixth pattern, TC-IMV is possible but rare.
  9. Within each ventilatory pattern there are several variations that can be distinguished by their targeting scheme(s). A targeting scheme is a description of how the ventilator achieves preset targets. A target is a predetermined goal of ventilator output. Examples of within-breath targets include inspiratory flow or pressure and rise time (set-point targeting), tidal volume (dual targeting) and constant of proportionality between inspiratory pressure and patient effort (servo targeting). Examples of between-breath targets and targeting schemes include average tidal volume (for adaptive targeting), percent minute ventilation (for optimal targeting) and combined PCO2, volume, and frequency values describing a "zone of comfort" (for intelligent targeting, e.g., SmartCarePS or IntelliVent-ASV). The targeting scheme (or combination of targeting schemes) is what distinguishes one ventilatory pattern from another. There are 7 basic targeting schemes that comprise the wide variety seen in different modes of ventilation:

    Set-point: A targeting scheme for which the operator sets all the parameters of the pressure waveform (pressure control modes) or volume and flow waveforms (volume control modes).
    Dual: A targeting scheme that allows the ventilator to switch between volume control and pressure control during a single inspiration.
    Bio-variable: A targeting scheme that allows the ventilator to automatically set the inspiratory pressure or tidal volume randomly to mimic the variability observed during normal breathing.
    Servo: A targeting scheme for which inspiratory pressure is proportional to inspiratory effort.
    Adaptive: A targeting scheme that allows the ventilator to automatically set one target (eg, pressure within a breath) to achieve another target (eg, average tidal volume over several breaths).
    Optimal: A targeting scheme that automatically adjusts the targets of the ventilatory pattern to either minimize or maximize some overall performance characteristic (eg, minimize the work rate done by the ventilatory pattern).
    Intelligent: A targeting scheme that uses artificial intelligence programs such as fuzzy logic, rule based expert systems, and artificial neural networks.

  10. A mode of ventilation is classified according to its control variable, breath sequence, and targeting scheme(s). The preceding 9 maxims create a theoretical foundation for a taxonomy of mechanical ventilation. The taxonomy is based on these theoretical constructs and has 4 hierarchical levels:
  • Control Variable (Pressure or Volume, for the primary breath)
  • Breath Sequence (CMV, IMV, or CSV)
  • Primary Breath Targeting Scheme (for CMV or CSV)
  • Secondary Breath Targeting Scheme (for IMV)

The "primary breath" is either the only breath there is (mandatory for CMV and spontaneous for CSV) or it is the mandatory breath in IMV. The targeting schemes can be represented by single, lower case letters: set-point = s, dual = d, servo = r, bio-variable = b, adaptive = a, optimal = o, intelligent = i. A tag is an abbreviation for a mode classification, such as PC-IMVs,s. Compound tags are possible, eg, PC-IMVoi,oi.

How modes are classified

Step 1: Identify the primary breath control variable. If inspiration starts with a preset inspiratory pressure, or if pressure is proportional to inspiratory effort, then the control variable is pressure. If inspiration starts with a preset tidal volume and inspiratory flow, then the control variable is volume. If neither is true, the control variable is time.

Step 2: Identify the breath sequence. Determine whether trigger and cycle events are patient or machine determined. Then, use this information to determine the breath sequence.

Step 3: Identify the targeting schemes for the primary breaths and (if applicable) secondary breaths.

Example mode classification is given below

Mode Name: A/C Volume Control (Covidien PB 840):[citation needed]

  1. Inspiratory volume and flow are preset, so the control variable is volume.
  2. Every breath is volume cycled, which is a form of machine cycling. Any breath for which inspiration is machine cycled is classified as a mandatory breath. Hence, the breath sequence is continuous mandatory ventilation.
  3. The operator sets all the parameters of the volume and flow waveforms so the targeting scheme is set-point. Thus, the mode is classified as volume control continuous mandatory ventilation with set-point targeting (VC-CMVs).

Mode Name: SIMV Volume Control Plus (Covidien PB 840):[citation needed]

  1. The operator sets the tidal volume but not the inspiratory flow. Because setting volume alone (like setting flow alone) is a necessary but not sufficient criterion for volume control, the control variable is pressure.
  2. Spontaneous breaths are allowed between mandatory breaths so the breath sequence is IMV[clarification needed].
  3. The ventilator adjusts inspiratory pressure between breaths to achieve an average preset tidal volume, so the targeting scheme is adaptive. The mode tag is PC-IMVa,s.

Descriptions of common modes

Mechanical ventilation machines are available with both invasive modes (such as intubation) and non-invasive modes (such as BPAP). Invasive has to do with the insertion of medical devices or tubes internal to the patient, while non-invasive is completely external to the patient, as for example in using a tightly fitting mask or other device that covers the patient's nose and mouth.

Assist mode, control mode, and assist-control mode

A basic distinction in mechanical ventilation is whether each breath is initiated by the patient (assist mode) or by the machine (control mode). Dynamic hybrids of the two (assist-control modes) are also possible, and control mode without assist is now mostly obsolete.

Airway pressure release ventilation

 
Airway pressure release ventilation graph

Airway pressure release ventilation is a time-cycled alternant between two levels of positive airway pressure, with the main time on the high level and a brief expiratory release to facilitate ventilation.[5]

Airway pressure release ventilation is usually utilized as a type of inverse ratio ventilation. The exhalation time (Tlow) is shortened to usually less than one second to maintain alveoli inflation. In the basic sense, this is a continuous pressure with a brief release. APRV currently the most efficient conventional mode for lung protective ventilation.[6]

Different perceptions of this mode may exist around the globe. While 'APRV' is common to users in North America, a very similar mode, biphasic positive airway pressure (BIPAP), was introduced in Europe.[7] The term APRV has also been used in American journals where, from the ventilation characteristics, BIPAP would have been perfectly good terminology.[8] But BiPAP(tm) is a trademark for a noninvasive ventilation mode in a specific ventilator (Respironics Inc.).

Other manufacturers have followed with their own brand names (BILEVEL, DUOPAP, BIVENT). Although similar in modality, these terms describe how a mode is intended to inflate the lung, rather than defining the characteristics of synchronization or the way spontaneous breathing efforts are supported.

Intermittent mandatory ventilation has not always had the synchronized feature, so the division of modes were understood to be SIMV (synchronized) vs IMV (not-synchronized). Since the American Association for Respiratory Care established a nomenclature of mechanical ventilation the "synchronized" part of the title has been dropped and now there is only IMV.

Mandatory minute ventilation

Mandatory minute ventilation (MMV) allows spontaneous breathing with automatic adjustments of mandatory ventilation to the meet the patient's preset minimum minute volume requirement. If the patient maintains the minute volume settings for VT x f, no mandatory breaths are delivered.[citation needed]

If the patient's minute volume is insufficient, mandatory delivery of the preset tidal volume will occur until the minute volume is achieved. The method for monitoring whether or not the patient is meeting the required minute ventilation (VE) differs by ventilator brand and model, but, in general, there is a window of monitored time, and a smaller window checked against the larger window (i.e., in the Dräger Evita® line of mechanical ventilators there is a moving 20-second window, and every 7 seconds the current tidal volume and rate are measured) to decide whether a mechanical breath is needed to maintain the minute ventilation.[citation needed]

MMV is an optimal mode for weaning in neonatal and pediatric populations and has been shown to reduce long-term complications related to mechanical ventilation.[9]

Pressure-regulated volume control

Pressure-regulated volume control is an IMV based mode. Pressure-regulated volume control utilizes pressure-limited, volume-targeted, time-cycled breaths that can be either ventilator- or patient-initiated.

The peak inspiratory pressure delivered by the ventilator is varied on a breath-to-breath basis to achieve a target tidal volume that is set by the clinician.

For example, if a target tidal volume of 500 mL is set but the ventilator delivers 600 mL, the next breath will be delivered with a lower inspiratory pressure to achieve a lower tidal volume. Though PRVC is regarded as a hybrid mode because of its tidal-volume (VC) settings and pressure-limiting (PC) settings fundamentally PRVC is a pressure-control mode with adaptive targeting.

Continuous positive airway pressure

Continuous positive airway pressure (CPAP) is a non-invasive positive pressure mode of respiratory support. CPAP is a pressure applied at the end of exhalation to keep the alveoli open and not fully deflate. This mechanism for maintaining inflated alveoli helps increase partial pressure of oxygen in arterial blood, an appropriate increase in CPAP increases the PaO2.

Automatic positive airway pressure

Automatic positive airway pressure (APAP) is a form of CPAP that automatically tunes the amount of pressure delivered to the patient to the minimum required to maintain an unobstructed airway on a breath-by-breath basis by measuring the resistance in the patient's breathing.

Bilevel positive airway pressure

Bilevel positive airway pressure (BPAP) is a mode used during non-invasive ventilation (NIV). First used in 1988 by Professor Benzer in Austria,[10] it delivers a preset inspiratory positive airway pressure (IPAP) and expiratory positive airway pressure (EPAP). BPAP can be described as a Continuous Positive Airway Pressure system with a time-cycle change of the applied CPAP level.[11]

CPAP/APAP, BPAP, and other non-invasive ventilation modes have been shown to be effective management tools for chronic obstructive pulmonary disease, acute respiratory failure, sleep apnea, etc.[12]

Often BPAP is incorrectly referred to as "BiPAP". BiPAP is the name of a portable ventilator manufactured by Respironics Corporation; it is just one of many ventilators that can deliver BPAP.

Medical uses

BPAP has been shown to be useful in reducing mortality and reducing the need for endotracheal intubation when used in people with chronic obstructive pulmonary disease (COPD).[13][14]

High-frequency ventilation (Active)

The term active refers to the ventilator's forced expiratory system. In a HFV-A scenario, the ventilator uses pressure to apply an inspiratory breath and then applies an opposite pressure to force an expiratory breath. In high-frequency oscillatory ventilation (sometimes abbreviated HFOV) the oscillation bellows and piston force positive pressure in and apply negative pressure to force an expiration.[15]

High-frequency ventilation (Passive)

The term passive refers to the ventilator's non-forced expiratory system. In a HFV-P scenario, the ventilator uses pressure to apply an inspiratory breath and then returns to atmospheric pressure to allow for a passive expiration. This is seen in High-Frequency Jet Ventilation, sometimes abbreviated HFJV. Also categorized under High Frequency Ventilation is High Frequency Percussive Ventilation, sometimes abbreviated HFPV. With HFPV it utilizes an open circuit to deliver its subtidal volumes by way of the patient interface known as the Phasitron.

Volume guarantee

Volume guarantee an additional parameter available in many types of ventilators that allows the ventilator to change its inspiratory pressure setting to achieve a minimum tidal volume. This is utilized most often in neonatal patients who need a pressure controlled mode with a consideration for volume control to minimize volutrauma.

Spontaneous breathing and support settings

Positive end-expiratory pressure

Positive end expiratory pressure (PEEP) is pressure applied upon expiration. PEEP is applied using either a valve that is connected to the expiratory port and set manually or a valve managed internally by a mechanical ventilator.

PEEP is a pressure that an exhalation has to bypass, in effect causing alveoli to remain open and not fully deflate. This mechanism for maintaining inflated alveoli helps increase partial pressure of oxygen in arterial blood, and an increase in PEEP increases the PaO2.[16]

Pressure support

Pressure support is a spontaneous mode of ventilation also named Pressure Support Ventilation (PSV). The patient initiates every breath and the ventilator delivers support with the preset pressure value. With support from the ventilator, the patient also regulates their own respiratory rate and their tidal volume.

In Pressure Support, the set inspiratory pressure support level is kept constant and there is a decelerating flow. The patient triggers all breaths. If there is a change in the mechanical properties of the lung/thorax and patient effort, the delivered tidal volume will be affected. The user must then regulate the pressure support level to obtain desired ventilation.[17][18]

Pressure support improves oxygenation,[19] ventilation and decreases work of breathing.

Also see adaptive support ventilation.

Other ventilation modes and strategies

Negative pressure ventilation

Main article: Negative pressure ventilator

Negative-pressure ventilation stimulates (or forces) breathing by periodic application of partial vacuum (air pressure reduced below ambient pressure), applied externally to the patient's torso—specifically, chest and abdomen—to assist (or force) the chest to expand, expanding the lungs, resulting in voluntary (or involuntary) inhalation through the patient's airway.[20][21][22][23][24]

Various "negative pressure ventilators" (NPVs) have been developed to serve this function—most famously the "Iron lung," a tank in which the patient lays, with only their head exposed to ambient air, while air pressure on the remainder of their body, inside the tank, is varied by pumping, to stimulate chest and lung expansion and contraction. Though not in wide use today, NPVs were the principal forms of hospital and long-term mechanical ventilation in the first half of the 20th century, and remain in limited use today.[20][21][22][23][24]

Closed loop systems

Adaptive Support Ventilation

Adaptive Support Ventilation (ASV) is the only commercially available mode that uses optimal targeting. This ventilation mode was invented and subsequently patented in 1991 by Tehrani[25][26][27] In this positive pressure mode of ventilation, the frequency and tidal volume of breaths of a patient on the ventilator are automatically adjusted and optimized to mimic natural breathing, stimulate spontaneous breathing, and reduce weaning time. In the ASV mode, every breath is synchronized with patient effort if such an effort exists, and otherwise, full mechanical ventilation is provided to the patient.[28][29]

Automatic Tube Compensation

Automatic Tube Compensation (ATC) is the simplest example of a computer-controlled targeting system on a ventilator. It is a form of servo targeting.

The goal of ATC is to support the resistive work of breathing through the artificial airway

Neurally Adjusted Ventilatory Assist

Neurally Adjusted Ventilatory Assist (NAVA) is adjusted by a computer (servo) and is similar to ATC but with more complex requirements for implementation.

In terms of patient-ventilator synchrony, NAVA supports both resistive and elastic work of breathing in proportion to the patient's inspiratory effort

Proportional Assist Ventilation

Proportional assist ventilation (PAV) is another servo targeting based mode in which the ventilator guarantees the percentage of work regardless of changes in pulmonary compliance and resistance.[30]

The ventilator varies the tidal volume and pressure based on the patient's work of breathing. The amount it delivers is proportional to the percentage of assistance it is set to give.

PAV, like NAVA, supports both restrictive and elastic work of breathing in proportion to the patient's inspiratory effort.

Liquid ventilation

Liquid ventilation is a technique of mechanical ventilation in which the lungs are insufflated with an oxygenated perfluorochemical liquid rather than an oxygen-containing gas mixture. The use of perfluorochemicals, rather than nitrogen, as the inert carrier of oxygen and carbon dioxide offers a number of theoretical advantages for the treatment of acute lung injury, including:

  • Reducing surface tension by maintaining a fluid interface with alveoli
  • Opening of collapsed alveoli by hydraulic pressure with a lower risk of barotrauma
  • Providing a reservoir in which oxygen and carbon dioxide can be exchanged with pulmonary capillary blood
  • Functioning as a high-efficiency heat exchanger

Despite its theoretical advantages, efficacy studies have been disappointing and the optimal clinical use of LV has yet to be defined.[31]

Total liquid ventilation

In total liquid ventilation (TLV), the entire lung is filled with an oxygenated PFC liquid, and a liquid tidal volume of PFC is actively pumped into and out of the lungs. A specialized apparatus is required to deliver and remove the relatively dense, viscous PFC tidal volumes, and to extracorporeally oxygenate and remove carbon dioxide from the liquid.[32][33][34]

Partial liquid ventilation

In partial liquid ventilation (PLV), the lungs are slowly filled with a volume of PFC equivalent or close to the FRC during gas ventilation. The PFC within the lungs is oxygenated and carbon dioxide is removed by means of gas breaths cycling in the lungs by a conventional gas ventilator.[35]

See also

References

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January 25, 2023
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This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Modes of mechanical ventilation news newspapers books scholar JSTOR April 2020 Learn how and when to remove this template message Modes of mechanical ventilation are one of the most important aspects of the usage of mechanical ventilation The mode refers to the method of inspiratory support In general mode selection is based on clinician familiarity and institutional preferences since there is a paucity of evidence indicating that the mode affects clinical outcome The most frequently used forms of volume limited mechanical ventilation are intermittent mandatory ventilation IMV and continuous mandatory ventilation CMV 1 There have been substantial changes in the nomenclature of mechanical ventilation over the years but more recently it has become standardized by many respirology and pulmonology groups 2 3 Writing a mode is most proper in all capital letters with a dash between the control variable and the strategy i e PC IMV or VC MMV etc Contents 1 Taxonomy for mechanical ventilation 1 1 10 maxims 1 2 How modes are classified 1 3 Example mode classification is given below 2 Descriptions of common modes 2 1 Assist mode control mode and assist control mode 2 2 Airway pressure release ventilation 2 3 Mandatory minute ventilation 2 4 Pressure regulated volume control 2 5 Continuous positive airway pressure 2 5 1 Automatic positive airway pressure 2 6 Bilevel positive airway pressure 2 6 1 Medical uses 2 7 High frequency ventilation Active 2 8 High frequency ventilation Passive 2 9 Volume guarantee 3 Spontaneous breathing and support settings 3 1 Positive end expiratory pressure 3 2 Pressure support 4 Other ventilation modes and strategies 4 1 Negative pressure ventilation 4 2 Closed loop systems 4 2 1 Adaptive Support Ventilation 4 2 2 Automatic Tube Compensation 4 2 3 Neurally Adjusted Ventilatory Assist 4 2 4 Proportional Assist Ventilation 4 3 Liquid ventilation 4 3 1 Total liquid ventilation 4 3 2 Partial liquid ventilation 5 See also 6 ReferencesTaxonomy for mechanical ventilation EditThe taxonomy is a logical classification system based on 10 maxims of ventilator design 4 10 maxims Edit A breath is one cycle of positive flow inspiration and negative flow expiration defined in terms of the flow time curve Inspiratory time is defined as the period from the start of positive flow to the start of negative flow Expiratory time is defined as the period from the start of expiratory flow to the start of inspiratory flow The flow time curve is the basis for many variables related to ventilator settings A breath is assisted if the ventilator does work on the patient An assisted breath is one for which the ventilator does some portion of the work of breathing For constant flow inflation work is defined as inspiratory pressure multiplied by tidal volume Therefore an assisted breath is identified as a breath for which airway pressure displayed on the ventilator rises above baseline during inspiration An unassisted breath is one for which the ventilator simply provides the inspiratory flow demanded by the patient and pressure stays constant throughout the breath A ventilator assists breathing using either pressure control or volume control based on the equation of motion for the respiratory system Providing assistance means doing work on the patient which is accomplished by controlling either pressure or volume A simple mathematical model describing this fact is known as the equation of motion for the passive respiratory system Pressure Elastance Volume Resistance Flow In this equation pressure volume and flow are all continuous functions of time Pressure is actually a pressure difference across the system e g transrespiratory pressure defined as pressure at the airway opening minus pressure on the body surface Elastance defined as the change in pressure divided by the associated change in volume the reciprocal of compliance and resistance defined as a change in pressure divided by the associated change in flow are parameters assumed to remain constant during a breath Volume control VC means that both volume and flow are preset prior to inspiration In other words the right hand side of the equation of motion remains constant while pressure changes with changes in elastance and resistance Pressure control PC means that inspiratory pressure is preset as either a constant value or it is proportional to the patient s inspiratory effort In other words the left hand side of the equation of motion remains constant while volume and flow change with changes in elastance and resistance Time control TC means that in some rare situations none of the main variables pressure volume or flow are preset In this case only the inspiratory and expiratory times are preset Breaths are classified by the criteria that trigger start and cycle stop inspiration The start of inspiration is called the trigger event The end of inspiration is called the cycle event Trigger and cycle events can be initiated by the patient or the machine Inspiration can be patient triggered or patient cycled by a signal representing inspiratory effort Inspiration may also be machine triggered or machine cycled by preset ventilator thresholds Patient triggering means starting inspiration based on a patient signal independent of a machine trigger signal Machine triggering means starting inspiratory flow based on a signal from the ventilator independent of a patient trigger signal Patient cycling means ending inspiratory time based on signals representing the patient determined components of the equation of motion ie elastance or resistance and including effects due to inspiratory effort Flow cycling is a form of patient cycling because the rate of flow decay to the cycle threshold is determined by patient mechanics Machine cycling means ending inspiratory time independent of signals representing the patient determined components of the equation of motion Breaths are classified as spontaneous or mandatory based on both the trigger and cycle events A spontaneous breath is a breath for which the patient both triggers and cycles the breath A spontaneous breath may occur during a mandatory breath e g Airway Pressure Release Ventilation A spontaneous breath may be assisted or unassisted A mandatory breath is a breath for which the machine triggers and or cycles the breath A mandatory breath can occur during a spontaneous breath e g High Frequency Jet Ventilation A mandatory breath is by definition assisted There are 3 breath sequences Continuous mandatory ventilation CMV Intermittent Mandatory Ventilation IMV and Continuous Spontaneous Ventilation CSV A breath sequence is a particular pattern of spontaneous and or mandatory breaths The 3 possible breath sequences are continuous mandatory ventilation CMV spontaneous breaths are not allowed between mandatory breaths intermittent mandatory ventilation IMV spontaneous breaths may occur between mandatory breaths and continuous spontaneous ventilation CSV all breaths are spontaneous There are 5 basic ventilatory patterns VC CMV VC IMV PC CMV PC IMV and PC CSV The combination VC CSV is not possible because volume control implies machine cycling and machine cycling makes every breath mandatory not spontaneous A sixth pattern TC IMV is possible but rare Within each ventilatory pattern there are several variations that can be distinguished by their targeting scheme s A targeting scheme is a description of how the ventilator achieves preset targets A target is a predetermined goal of ventilator output Examples of within breath targets include inspiratory flow or pressure and rise time set point targeting tidal volume dual targeting and constant of proportionality between inspiratory pressure and patient effort servo targeting Examples of between breath targets and targeting schemes include average tidal volume for adaptive targeting percent minute ventilation for optimal targeting and combined PCO2 volume and frequency values describing a zone of comfort for intelligent targeting e g SmartCarePS or IntelliVent ASV The targeting scheme or combination of targeting schemes is what distinguishes one ventilatory pattern from another There are 7 basic targeting schemes that comprise the wide variety seen in different modes of ventilation Set point A targeting scheme for which the operator sets all the parameters of the pressure waveform pressure control modes or volume and flow waveforms volume control modes Dual A targeting scheme that allows the ventilator to switch between volume control and pressure control during a single inspiration Bio variable A targeting scheme that allows the ventilator to automatically set the inspiratory pressure or tidal volume randomly to mimic the variability observed during normal breathing Servo A targeting scheme for which inspiratory pressure is proportional to inspiratory effort Adaptive A targeting scheme that allows the ventilator to automatically set one target eg pressure within a breath to achieve another target eg average tidal volume over several breaths Optimal A targeting scheme that automatically adjusts the targets of the ventilatory pattern to either minimize or maximize some overall performance characteristic eg minimize the work rate done by the ventilatory pattern Intelligent A targeting scheme that uses artificial intelligence programs such as fuzzy logic rule based expert systems and artificial neural networks A mode of ventilation is classified according to its control variable breath sequence and targeting scheme s The preceding 9 maxims create a theoretical foundation for a taxonomy of mechanical ventilation The taxonomy is based on these theoretical constructs and has 4 hierarchical levels Control Variable Pressure or Volume for the primary breath Breath Sequence CMV IMV or CSV Primary Breath Targeting Scheme for CMV or CSV Secondary Breath Targeting Scheme for IMV The primary breath is either the only breath there is mandatory for CMV and spontaneous for CSV or it is the mandatory breath in IMV The targeting schemes can be represented by single lower case letters set point s dual d servo r bio variable b adaptive a optimal o intelligent i A tag is an abbreviation for a mode classification such as PC IMVs s Compound tags are possible eg PC IMVoi oi How modes are classified Edit Step 1 Identify the primary breath control variable If inspiration starts with a preset inspiratory pressure or if pressure is proportional to inspiratory effort then the control variable is pressure If inspiration starts with a preset tidal volume and inspiratory flow then the control variable is volume If neither is true the control variable is time Step 2 Identify the breath sequence Determine whether trigger and cycle events are patient or machine determined Then use this information to determine the breath sequence Step 3 Identify the targeting schemes for the primary breaths and if applicable secondary breaths Example mode classification is given below Edit Mode Name A C Volume Control Covidien PB 840 citation needed Inspiratory volume and flow are preset so the control variable is volume Every breath is volume cycled which is a form of machine cycling Any breath for which inspiration is machine cycled is classified as a mandatory breath Hence the breath sequence is continuous mandatory ventilation The operator sets all the parameters of the volume and flow waveforms so the targeting scheme is set point Thus the mode is classified as volume control continuous mandatory ventilation with set point targeting VC CMVs Mode Name SIMV Volume Control Plus Covidien PB 840 citation needed The operator sets the tidal volume but not the inspiratory flow Because setting volume alone like setting flow alone is a necessary but not sufficient criterion for volume control the control variable is pressure Spontaneous breaths are allowed between mandatory breaths so the breath sequence is IMV clarification needed The ventilator adjusts inspiratory pressure between breaths to achieve an average preset tidal volume so the targeting scheme is adaptive The mode tag is PC IMVa s Descriptions of common modes EditMechanical ventilation machines are available with both invasive modes such as intubation and non invasive modes such as BPAP Invasive has to do with the insertion of medical devices or tubes internal to the patient while non invasive is completely external to the patient as for example in using a tightly fitting mask or other device that covers the patient s nose and mouth Assist mode control mode and assist control mode Edit A basic distinction in mechanical ventilation is whether each breath is initiated by the patient assist mode or by the machine control mode Dynamic hybrids of the two assist control modes are also possible and control mode without assist is now mostly obsolete Airway pressure release ventilation Edit Airway pressure release ventilation graph Airway pressure release ventilation is a time cycled alternant between two levels of positive airway pressure with the main time on the high level and a brief expiratory release to facilitate ventilation 5 Airway pressure release ventilation is usually utilized as a type of inverse ratio ventilation The exhalation time Tlow is shortened to usually less than one second to maintain alveoli inflation In the basic sense this is a continuous pressure with a brief release APRV currently the most efficient conventional mode for lung protective ventilation 6 Different perceptions of this mode may exist around the globe While APRV is common to users in North America a very similar mode biphasic positive airway pressure BIPAP was introduced in Europe 7 The term APRV has also been used in American journals where from the ventilation characteristics BIPAP would have been perfectly good terminology 8 But BiPAP tm is a trademark for a noninvasive ventilation mode in a specific ventilator Respironics Inc Other manufacturers have followed with their own brand names BILEVEL DUOPAP BIVENT Although similar in modality these terms describe how a mode is intended to inflate the lung rather than defining the characteristics of synchronization or the way spontaneous breathing efforts are supported Intermittent mandatory ventilation has not always had the synchronized feature so the division of modes were understood to be SIMV synchronized vs IMV not synchronized Since the American Association for Respiratory Care established a nomenclature of mechanical ventilation the synchronized part of the title has been dropped and now there is only IMV Mandatory minute ventilation Edit Mandatory minute ventilation MMV allows spontaneous breathing with automatic adjustments of mandatory ventilation to the meet the patient s preset minimum minute volume requirement If the patient maintains the minute volume settings for VT x f no mandatory breaths are delivered citation needed If the patient s minute volume is insufficient mandatory delivery of the preset tidal volume will occur until the minute volume is achieved The method for monitoring whether or not the patient is meeting the required minute ventilation VE differs by ventilator brand and model but in general there is a window of monitored time and a smaller window checked against the larger window i e in the Drager Evita line of mechanical ventilators there is a moving 20 second window and every 7 seconds the current tidal volume and rate are measured to decide whether a mechanical breath is needed to maintain the minute ventilation citation needed MMV is an optimal mode for weaning in neonatal and pediatric populations and has been shown to reduce long term complications related to mechanical ventilation 9 Pressure regulated volume control Edit Pressure regulated volume control is an IMV based mode Pressure regulated volume control utilizes pressure limited volume targeted time cycled breaths that can be either ventilator or patient initiated The peak inspiratory pressure delivered by the ventilator is varied on a breath to breath basis to achieve a target tidal volume that is set by the clinician For example if a target tidal volume of 500 mL is set but the ventilator delivers 600 mL the next breath will be delivered with a lower inspiratory pressure to achieve a lower tidal volume Though PRVC is regarded as a hybrid mode because of its tidal volume VC settings and pressure limiting PC settings fundamentally PRVC is a pressure control mode with adaptive targeting Continuous positive airway pressure Edit Continuous positive airway pressure CPAP is a non invasive positive pressure mode of respiratory support CPAP is a pressure applied at the end of exhalation to keep the alveoli open and not fully deflate This mechanism for maintaining inflated alveoli helps increase partial pressure of oxygen in arterial blood an appropriate increase in CPAP increases the PaO2 Automatic positive airway pressure Edit Automatic positive airway pressure APAP is a form of CPAP that automatically tunes the amount of pressure delivered to the patient to the minimum required to maintain an unobstructed airway on a breath by breath basis by measuring the resistance in the patient s breathing Bilevel positive airway pressure Edit Bilevel positive airway pressure BPAP is a mode used during non invasive ventilation NIV First used in 1988 by Professor Benzer in Austria 10 it delivers a preset inspiratory positive airway pressure IPAP and expiratory positive airway pressure EPAP BPAP can be described as a Continuous Positive Airway Pressure system with a time cycle change of the applied CPAP level 11 CPAP APAP BPAP and other non invasive ventilation modes have been shown to be effective management tools for chronic obstructive pulmonary disease acute respiratory failure sleep apnea etc 12 Often BPAP is incorrectly referred to as BiPAP BiPAP is the name of a portable ventilator manufactured by Respironics Corporation it is just one of many ventilators that can deliver BPAP Medical uses Edit BPAP has been shown to be useful in reducing mortality and reducing the need for endotracheal intubation when used in people with chronic obstructive pulmonary disease COPD 13 14 High frequency ventilation Active Edit The term active refers to the ventilator s forced expiratory system In a HFV A scenario the ventilator uses pressure to apply an inspiratory breath and then applies an opposite pressure to force an expiratory breath In high frequency oscillatory ventilation sometimes abbreviated HFOV the oscillation bellows and piston force positive pressure in and apply negative pressure to force an expiration 15 High frequency ventilation Passive Edit The term passive refers to the ventilator s non forced expiratory system In a HFV P scenario the ventilator uses pressure to apply an inspiratory breath and then returns to atmospheric pressure to allow for a passive expiration This is seen in High Frequency Jet Ventilation sometimes abbreviated HFJV Also categorized under High Frequency Ventilation is High Frequency Percussive Ventilation sometimes abbreviated HFPV With HFPV it utilizes an open circuit to deliver its subtidal volumes by way of the patient interface known as the Phasitron Volume guarantee Edit Volume guarantee an additional parameter available in many types of ventilators that allows the ventilator to change its inspiratory pressure setting to achieve a minimum tidal volume This is utilized most often in neonatal patients who need a pressure controlled mode with a consideration for volume control to minimize volutrauma Spontaneous breathing and support settings EditPositive end expiratory pressure Edit Positive end expiratory pressure PEEP is pressure applied upon expiration PEEP is applied using either a valve that is connected to the expiratory port and set manually or a valve managed internally by a mechanical ventilator PEEP is a pressure that an exhalation has to bypass in effect causing alveoli to remain open and not fully deflate This mechanism for maintaining inflated alveoli helps increase partial pressure of oxygen in arterial blood and an increase in PEEP increases the PaO2 16 Pressure support Edit Pressure support is a spontaneous mode of ventilation also named Pressure Support Ventilation PSV The patient initiates every breath and the ventilator delivers support with the preset pressure value With support from the ventilator the patient also regulates their own respiratory rate and their tidal volume In Pressure Support the set inspiratory pressure support level is kept constant and there is a decelerating flow The patient triggers all breaths If there is a change in the mechanical properties of the lung thorax and patient effort the delivered tidal volume will be affected The user must then regulate the pressure support level to obtain desired ventilation 17 18 Pressure support improves oxygenation 19 ventilation and decreases work of breathing Also see adaptive support ventilation Other ventilation modes and strategies EditNegative pressure ventilation Edit Main article Negative pressure ventilatorNegative pressure ventilation stimulates or forces breathing by periodic application of partial vacuum air pressure reduced below ambient pressure applied externally to the patient s torso specifically chest and abdomen to assist or force the chest to expand expanding the lungs resulting in voluntary or involuntary inhalation through the patient s airway 20 21 22 23 24 Various negative pressure ventilators NPVs have been developed to serve this function most famously the Iron lung a tank in which the patient lays with only their head exposed to ambient air while air pressure on the remainder of their body inside the tank is varied by pumping to stimulate chest and lung expansion and contraction Though not in wide use today NPVs were the principal forms of hospital and long term mechanical ventilation in the first half of the 20th century and remain in limited use today 20 21 22 23 24 Closed loop systems Edit Adaptive Support Ventilation Edit Adaptive Support Ventilation ASV is the only commercially available mode that uses optimal targeting This ventilation mode was invented and subsequently patented in 1991 by Tehrani 25 26 27 In this positive pressure mode of ventilation the frequency and tidal volume of breaths of a patient on the ventilator are automatically adjusted and optimized to mimic natural breathing stimulate spontaneous breathing and reduce weaning time In the ASV mode every breath is synchronized with patient effort if such an effort exists and otherwise full mechanical ventilation is provided to the patient 28 29 Automatic Tube Compensation Edit Automatic Tube Compensation ATC is the simplest example of a computer controlled targeting system on a ventilator It is a form of servo targeting The goal of ATC is to support the resistive work of breathing through the artificial airway Neurally Adjusted Ventilatory Assist Edit Neurally Adjusted Ventilatory Assist NAVA is adjusted by a computer servo and is similar to ATC but with more complex requirements for implementation In terms of patient ventilator synchrony NAVA supports both resistive and elastic work of breathing in proportion to the patient s inspiratory effort Proportional Assist Ventilation Edit Proportional assist ventilation PAV is another servo targeting based mode in which the ventilator guarantees the percentage of work regardless of changes in pulmonary compliance and resistance 30 The ventilator varies the tidal volume and pressure based on the patient s work of breathing The amount it delivers is proportional to the percentage of assistance it is set to give PAV like NAVA supports both restrictive and elastic work of breathing in proportion to the patient s inspiratory effort Liquid ventilation Edit Liquid ventilation is a technique of mechanical ventilation in which the lungs are insufflated with an oxygenated perfluorochemical liquid rather than an oxygen containing gas mixture The use of perfluorochemicals rather than nitrogen as the inert carrier of oxygen and carbon dioxide offers a number of theoretical advantages for the treatment of acute lung injury including Reducing surface tension by maintaining a fluid interface with alveoli Opening of collapsed alveoli by hydraulic pressure with a lower risk of barotrauma Providing a reservoir in which oxygen and carbon dioxide can be exchanged with pulmonary capillary blood Functioning as a high efficiency heat exchangerDespite its theoretical advantages efficacy studies have been disappointing and the optimal clinical use of LV has yet to be defined 31 Total liquid ventilation Edit In total liquid ventilation TLV the entire lung is filled with an oxygenated PFC liquid and a liquid tidal volume of PFC is actively pumped into and out of the lungs A specialized apparatus is required to deliver and remove the relatively dense viscous PFC tidal volumes and to extracorporeally oxygenate and remove carbon dioxide from the liquid 32 33 34 Partial liquid ventilation Edit In partial liquid ventilation PLV the lungs are slowly filled with a volume of PFC equivalent or close to the FRC during gas ventilation The PFC within the lungs is oxygenated and carbon dioxide is removed by means of gas breaths cycling in the lungs by a conventional gas ventilator 35 See also Edit Medicine portalTable of modes of mechanical ventilation Mechanical ventilation Method to mechanically assist or replace spontaneous breathing Respiratory therapist Practitioner in cardio pulmonary medicine Bubble CPAPReferences Edit Esteban A Anzueto A Alia I Gordo F Apezteguia C Palizas F Cide D Goldwaser R Soto L Bugedo G Rodrigo C Pimentel J Raimondi G Tobin MJ 2000 How is mechanical ventilation employed in the intensive care unit An international utilization review Am J Respir Crit Care Med 161 5 1450 8 doi 10 1164 ajrccm 161 5 9902018 PMID 10806138 Donn SM 2009 Neonatal ventilators how do they differ J Perinatol 29 Suppl 2 S73 8 doi 10 1038 jp 2009 23 PMID 19399015 Chatburn RL Volsko TA Hazy J Harris LN Sanders S 2011 Determining the Basis for a Taxonomy of Mechanical Ventilation Respir Care 57 4 514 24 doi 10 4187 respcare 01327 PMID 22004898 S2CID 27417478 Chatburn RL El Khatib M Mireles Cabodevila E 2014 A taxonomy for mechanical ventilation 10 fundamental maxims Respir Care 59 11 1747 63 doi 10 4187 respcare 03057 PMID 25118309 Dietrich Henzler 2011 What on earth is APRV Critical Care London England 15 1 115 doi 10 1186 cc9419 PMC 3222047 PMID 21345265 Adrian A Maung amp Lewis J Kaplan July 2011 Airway pressure release ventilation in acute respiratory distress syndrome Critical Care Clinics 27 3 501 509 doi 10 1016 j ccc 2011 05 003 PMID 21742214 M Baum H Benzer C Putensen W Koller amp G Putz September 1989 Biphasic positive airway pressure BIPAP a new form of augmented ventilation Der Anaesthesist 38 9 452 458 PMID 2686487 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link C Putensen S Zech H Wrigge J Zinserling F Stuber T Von Spiegel amp N Mutz July 2001 Long term effects of spontaneous breathing during ventilatory support in patients with acute lung injury American Journal of Respiratory and Critical Care Medicine 164 1 43 49 doi 10 1164 ajrccm 164 1 2001078 PMID 11435237 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Scott O Guthrie Chris Lynn Bonnie J Lafleur Steven M Donn amp William F Walsh October 2005 A crossover analysis of mandatory minute ventilation compared to synchronized intermittent mandatory ventilation in neonates Journal of Perinatology 25 10 643 646 doi 10 1038 sj jp 7211371 PMID 16079905 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Benzer H 1988 Ventilatory support by intermittent changes in PEEP levels 4th European Congress on Intensive Care Medicine Baveno Stresa C Hormann M Baum C Putensen N J Mutz amp H Benzer January 1994 Biphasic positive airway pressure BIPAP a new mode of ventilatory support European Journal of Anaesthesiology 11 1 37 42 PMID 8143712 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link M A Levitt November 2001 A prospective randomized trial of BiPAP in severe acute congestive heart failure The Journal of Emergency Medicine 21 4 363 9 doi 10 1016 s0736 4679 01 00385 7 PMID 11728761 Osadnik CR Tee VS Carson Chahhoud KV Picot J Wedzicha JA Smith BJ 13 July 2017 Non invasive ventilation for the management of acute hypercapnic respiratory failure due to exacerbation of chronic obstructive pulmonary disease PDF The Cochrane Database of Systematic Reviews 2017 7 CD004104 doi 10 1002 14651858 CD004104 pub4 hdl 10044 1 53458 PMC 6483555 PMID 28702957 Yanez LJ Yunge M Emilfork M Lapadula M Alcantara A Fernandez C Lozano J Contreras M Conto L Arevalo C Gayan A Hernandez F Pedraza M Feddersen M Bejares M Morales M Mallea F Glasinovic M Cavada G September 2008 A prospective randomized controlled trial of noninvasive ventilation in pediatric acute respiratory failure Pediatric Critical Care Medicine 9 5 484 9 doi 10 1097 PCC 0b013e318184989f PMID 18679148 S2CID 20821767 Allardet Servent J 2011 High frequency oscillatory ventilation in adult patients with acute respiratory distress syndrome Where do we stand and where should we go Crit Care Med 39 12 2761 2 doi 10 1097 CCM 0b013e31822a5c35 PMID 22094505 D P Schuster M Klain amp J V Snyder October 1982 Comparison of high frequency jet ventilation to conventional ventilation during severe acute respiratory failure in humans Critical Care Medicine 10 10 625 630 doi 10 1097 00003246 198210000 00001 PMID 6749433 MAQUET Modes of ventilation in SERVO i invasive and non invasive 2008 MAQUET Critical Care AB Order No 66 14 692 MAQUET Modes of ventilation in SERVO s invasive and non invasive 2009 MAQUET Critical Care AB Order No 66 61 131 Spieth PM Carvalho AR Guldner A et al April 2011 Pressure support improves oxygenation and lung protection compared to pressure controlled ventilation and is further improved by random variation of pressure support Critical Care Medicine 39 4 746 55 doi 10 1097 CCM 0b013e318206bda6 PMID 21263322 S2CID 35876431 a b Shneerson Dr John M Newmarket General Hospital Newmarket Suffolk U K Non invasive and domiciliary ventilation negative pressure techniques 5 of series Assisted ventilation in Thorax 1991 46 pp 131 135 retrieved April 12 2020 a b Matioc Adrian A M D University of Wisconsin School of Medicine amp Public Health William S Middleton Memorial Veterans Hospital Madison Wisconsin Early Positive and Alternate Pressure Machines in An Anesthesiologist s Perspective on the History of Basic Airway Management The Progressive Era 1904 to 1960 submitted May 27 2017 published February 2018 Anesthesiology Vol 128 No 2 a b Grum Cyril M MD and Melvin L Morganroth MD Initiating Mechanical Ventilation in Intensive Care Medicine 1988 3 6 20 retrieved April 12 2020 a b Rockoff Mark M D The Iron Lung and Polio video 8 minutes January 11 2016 OPENPediatrics and Boston Children s Hospital on YouTube retrieved April 11 2020 historical background and images explanatory diagrams and live demonstrations a b Walkey Allan M D and Ross Summer M D Negative pressure in E Noninvasive Mechanical Ventilation in Boston Medical Center ICU Manual 2008 2008 Boston University p 17 retrieved April 12 2020 Tehrani FT Method and apparatus for controlling an artificial respiratory US patent 4 986 268 issued January 22 1991 Tehrani FT 1991 Automatic control of an artificial respirator Proc IEEE EMBS Conf Vol 13 pp 1738 9 doi 10 1109 IEMBS 1991 684729 ISBN 0 7803 0216 8 S2CID 63221714 Chatburn Robert L Mireles Cabodevila E Closed loop control of mechanical ventilation description and classification of targeting schemes Respiratory Care 56 1 85 102 2011 Tehrani Fleur T Automatic control of mechanical ventilation Part 1 theory and history of the technology Journal of Clinical Monitoring and Computing 22 2008 409 415 Tehrani Fleur T Automatic control of mechanical ventilation Part 2 the existing techniques and future trends Journal of Clinical Monitoring and Computing 22 2008 417 424 Younes M 1992 Proportional assist ventilation a new approach to ventilatory support Theory Am Rev Respir Dis 145 1 114 120 doi 10 1164 ajrccm 145 1 114 PMID 1731573 Degraeuwe PL Vos GD Blanco CE 1995 Perfluorochemical liquid ventilation from the animal laboratory to the intensive care unit Int J Artif Organs 18 10 674 83 doi 10 1177 039139889501801020 PMID 8647601 S2CID 13038566 Norris MK Fuhrman BP Leach CL 1994 Liquid ventilation it s not science fiction anymore AACN Clin Issues Crit Care Nurs 5 3 246 54 doi 10 4037 15597768 1994 3004 PMID 7780839 Greenspan JS 1996 Physiology and clinical role of liquid ventilation therapy J Perinatol 16 2 Pt 2 Su S47 52 PMID 8732549 Dirkes S 1996 Liquid ventilation new frontiers in the treatment of ARDS Crit Care Nurse 16 3 53 8 doi 10 4037 ccn1996 16 3 53 PMID 8852261 Cox CA Wolfson MR Shaffer TH 1996 Liquid ventilation a comprehensive overview Neonatal Netw 15 3 31 43 PMID 8715647 Retrieved from https en wikipedia org w index php title Modes of mechanical ventilation amp oldid 1110801275, wikipedia, wiki, book, books, library,

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