Ventilator Classification & Modes of Ventilation

Objectives — Identify the design features and classification of mechanical ventilators and apply classification to modes of ventilation.

The Equation of Motion

All ventilator function is governed by Newton's equation of motion:

Pressure = Raw × Flow + Volume / Compliance

Raw = airway resistance
Flow = gas flow rate
Volume = tidal volume delivered
Compliance = lung and chest wall distensibility

Every ventilator setting and every monitored value relates back to this equation.

Classification of Ventilators

Ventilators are classified based on five components.

1. Input Power

Type	Description	Examples
Pneumatic	Requires only a 50 psi gas source	Bird ventilators, IPPB units, transport and MRI vents
Electric	Requires only an electrical source	Transport vents, home ventilators
Combination	Requires both gas and electric	Most ICU ventilators

2. Power Conversion & Transmission

How the ventilator converts input power into pressurized gas flow delivered to the patient.

Drive Mechanisms:

Bellows
Piston
Turbine

Output Control Valve (Demand Valve / Inspiratory Valve):

Controls gas delivery to the patient
Can "shape" the flow waveform (square, sine, descending ramp)

3. Control Circuit

The system that governs ventilator operation:

Mechanical
Pneumatic
Fluidic
Electric
Electronic (most modern ICU vents)

4. Control Variables

The primary variable the ventilator controls during inspiration. Only one variable can be controlled at a time.

Control Variable	What stays constant	What changes
Pressure	Pressure	Volume (variable based on compliance and resistance)
Volume	Volume	Pressure (variable based on compliance and resistance)
Flow	Flow	Rarely used as primary control
Time	Time	Neonatal ventilation primarily

Pressure Control

Inspiration ends when preset pressure is reached
Pressure is constant; volume is variable
Volume decreases with decreased compliance or increased resistance
Volume increases with increased compliance or decreased resistance

Volume Control

Inspiration ends when preset volume is reached
Volume is constant; pressure is variable
Pressure increases with decreased compliance or increased resistance
Pressure decreases with increased compliance or decreased resistance

5. Phase Variables

Phase variables define what happens at each phase of the respiratory cycle.

Phase	Variable	Description
Trigger	Starts inspiration	Time, pressure drop, or flow change
Target (limit)	Controls inspiratory phase	Volume, pressure, flow, or time
Cycle	Starts exhalation	Volume, pressure, flow, or time
Baseline	What occurs during exhalation	Usually pressure = PEEP

Trigger

Time trigger: Breath begins based on set respiratory rate (e.g., RR = 10 = one breath every 6 sec)
Pressure trigger: Ventilator senses a drop in baseline pressure (patient effort) — measured in cmH₂O
Flow trigger: Ventilator senses a drop in bias flow — measured in L/min; requires less patient effort than pressure trigger

Target

The variable controlled during inspiration — also called a "limit" if an alarm condition is met.

Cycle

The variable that causes inspiration to end:

Volume (most common)
Pressure (2nd most common)
Flow (PSV — flow cycled at 25% of peak flow)
Time (neonatal ventilation)

Baseline

The period from the start of exhalation to the start of the next breath. Pressure is the most common baseline variable — set as PEEP.

Breath Types

The combination of phase variables defines the breath type.

Breath Type	Triggered By	Targeted By	Cycled By	Patient WOB
Mandatory (Controlled)	Ventilator (time)	Volume / Pressure / Time	Ventilator	None — vent does all WOB
Assisted	Patient	Volume / Pressure / Time	Ventilator	Only effort to trigger
Spontaneous	Patient	Baseline (PEEP)	Patient	Patient does all WOB
Supported	Patient	Pressure	Flow (25% peak)	Shared — vent assists

Spontaneous unsupported breaths show a negative deflection on inspiration and positive on expiration on the pressure-time scalar — the opposite of mandatory breaths.

Modes of Ventilation

A mode is the method of inspiratory support and breath delivery. Modes combine breath types and timing algorithms to distribute WOB between the patient and the ventilator.

CMV — Continuous Mandatory Ventilation (A/C)

Also called Assist/Control (A/C).

Trigger: Patient or time (whichever comes first)
Target: Pressure or Volume
Cycle: Ventilator
All breaths are mandatory or assisted — every breath is ventilator-cycled
The initial "rest" mode — ventilator assumes all or most WOB
Available as Volume A/C or Pressure A/C

SIMV — Synchronized Intermittent Mandatory Ventilation

Trigger: Patient or ventilator
Target: Volume, Pressure, Time, or Flow
Cycle: Volume, Pressure, Time, or Flow
Breath types: Controlled, assisted, and spontaneous
Demand valves sense patient effort; timing algorithm synchronizes mandatory breaths with patient effort
Used for both resting and weaning
SIMV + PS: Spontaneous breaths are augmented with pressure support
- Overcomes RAW from the ET tube
- Improves patient-ventilator synchrony
- Prevents respiratory muscle atrophy

CSV — Continuous Spontaneous Ventilation (CPAP)

Also called CPAP in the ventilator context.

Spontaneous breathing at or above atmospheric pressure
Trigger: Patient
Limit: Pressure alarm
Cycle: Patient
Used to evaluate patients for weaning and ventilator discontinuation

PSV — Pressure Support Ventilation (CPAP + PS)

Trigger: Patient
Target: Pressure (above baseline)
Cycle: Flow — inspiration ends when inspiratory flow decelerates to 25% of peak flow
Reduces WOB, increases spontaneous Vt, improves synchrony
Used as a weaning mode or combined with SIMV

APRV — Airway Pressure Release Ventilation

Also known as: BiLevel, BiVent, BiPhasic, PCV+, DuoPAP.

Time-cycled, pressure-controlled (dual)
Patient can breathe spontaneously throughout the cycle
Uses two pressure levels:
- P-High: elevated baseline pressure (like high CPAP)
- P-Low: brief pressure release to allow exhalation
Inverse ratio: Time-High is much longer than Time-Low (e.g., 4–5 sec : 0.4–0.8 sec)
Used to treat refractory hypoxemia (ARDS)

Setting	Effect
P-High	Controls oxygenation (like PEEP)
P-Low	Controls CO₂ clearance during release
T-High	Long — recruits alveoli
T-Low	Short — just enough to release CO₂

Additional Modes (Overview)

These advanced modes are covered in Phase II but worth recognizing by name:

PRVC — Pressure-Regulated Volume Control
PCIRV — Pressure-Controlled Inverse Ratio Ventilation
NAVA — Neurally Adjusted Ventilatory Assist
PAV — Proportional Assist Ventilation
ASV — Adaptive Support Ventilation
HFOV — High-Frequency Oscillatory Ventilation
HFV-A / HFV-P — High-Frequency Ventilation variants
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