5.8: 5.8 Conclusion

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Volume and pressure have a direct relationship. Whichever parameter you adjust will affect the opposite value. When all other settings are kept the same and the lungs are the same, the following statements are true:

Table 5.8.1: Adjusting Volume and Pressure (Other Settings are Kept the Same; Lungs are the Same)
In Volume Control	In Pressure Control
As the volume set is increased, the pressure increases.	As the set pressure is increased, the volume will increase.
If the Pressure reached in the lungs is too high $\small{(\text{>30 - 35cmH}_2\text{O})}$ , dropping the volume will help.	If the volume in the lungs is too high, dropping the pressure will help.
If more volume is needed, increase the volume and expect the pressures to climb.	If more volume is needed, increasing the pressure will increase the volume delivered.

Inspiratory time and flow can also impact the pressure and volumes experienced by the lungs. When all other settings are kept the same, the following statements are true:

Table 5.8.2: The Effects of Inspiratory Time and Flow on Volume and Pressure (Other Settings are Kept the Same)
In Volume Control (constant volume to be delivered)	In Pressure Control (constant pressure and/or same target volume)
If the flow is increased, the time to deliver the breath is shorter.	If the inspiratory time is increased, the volume delivered will increase.
If the flow is decreased, the time to deliver the breath is longer.	If the inspiratory time is decreased, the volume delivered will decrease.
If the flow is increased and the inspiratory time is shorter, the pressure needed to hit the same volume will be higher.	If the inspiratory time is increased, the set pressure can be decreased to hit the same volume.
If the flow is decreased and the inspiratory time is longer, the pressure needed to hit the same volume will be lower.	If the inspiratory time is decreased, the set pressure will need to be increased to hit the same volume.

And if the settings on the ventilator do not change, but the lung compliance or resistance in the lungs changes:

Table 5.8.3: The Effect of Changing Lung Compliance and Resistance on Volume and Pressure (No Change in Ventilator Settings)
In Volume Control (no change to settings)	In Pressure Control (no change to settings)
If the compliance of the lungs increases (more stretchy), the pressure used to hit the volume decreases.	If the compliance of the lungs increases (more stretchy), the volume delivered with the set pressure will increase.
If the compliance of the lungs decreases (less stretchy), the pressure used to hit the volume increases.	If the compliance of the lungs decreases (less stretchy), the volume delivered with the set pressure will increase.
If the resistance of the lungs increases, the pressure used to hit the volume increases.	If the resistance of the lungs increases, the volume delivered with the set pressure will decrease.
If the resistance of the lungs decreases, the pressure used to hit the volume decreases.	If the resistance of the lungs decreases, the volume delivered with the set pressure will increase.

“Chapter 4 Conclusion” from Basic Principles of Mechanical Ventilation by Sault College is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License, except where otherwise noted.

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