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mechanical ventilation

Image: “mechanical ventilation” by ISAF Headquarters Public Affairs Office. License: CC BY 2.0

What is Mechanical Ventilation?

Respirator Evita4 on an ICU

Image: “Respirator “Evita4” on an ICU” by Blogotron. License: CC0 BY 1.0

Mechanical ventilation, involving a ventilator pushing a mixture of warm, humidified oxygen and air into lungs, is used to treat patients suffering from respiratory failure. While ventilatory support may be required before these values are reached, according to 50/50 rule it is indicated when:

  • Partial pressure of oxygen < 50mmHg
  • Partial pressure of carbon dioxide > 50mmHg

Mechanical ventilation is fundamentally different from spontaneous breathing as it involves pushing a warm, humidified mixture of air and oxygen into the lungs under positive pressure, whereas, during normal breathing, there is negative pressure formation.

This form of ventilation may be invasive requiring intubation or non-invasive, making use of masks and tubes. When discussing ventilation, there are certain terms you need to be familiar with:

  • Respiratory rate: Rate of breaths: could be a ventilator setting or the actual respiratory status of the individual being tracked by the ventilator
  • The volume of breaths: Frequently known as tidal volume;: again could be a ventilator setting or patient’s status being tracked
  • Breathing sensitivity: Related to the inspiratory effort required from the ventilator to identify the patient’s effort of inhaling
  • The flow of breaths: Peak flow

Modes of Ventilation

There are various combinations of modes and breath types offered by manufacturers of ventilators to determine the breath delivered to a patient. Some common ventilator modes are as follows.

Assist/Control (A/C)

This is the mode where every breath is supported by the ventilator, whether initiated by the patient or the ventilator itself. Often the patient rests and ventilator does the work. This type of support is required in:

  • Resuscitated patients
  • Patients with acute respiratory distress syndrome
  • Paralyzed patients
  • Sedated patients
Risk: Barotrauma risk is there due to the highest level of positive pressure in the chest.

Synchronized Intermittent Mandatory Ventilation (SIMV)

This mode assures a certain number of breaths and reduces the risk of hyperinflation and alkalosis. Mandatory breaths are synchronized such that they coincide with spontaneous respirations. SIMV in patients with LV dysfunction has shown to reduce cardiac output.

Disadvantages: An increased work of breathing and reduced cardiac output prolonging ventilator dependency.

While deciding between SIMV and A/C, personal choice is seen, however, SIMV is preferred in patients who breathe rapidly and A/C is the choice is patients with:

  • Respiratory weakness
  • Left ventricular dysfunction

Continuous Positive Airway Pressure (CPAP)

This is the mode where the patient is responsible for initiating and sustaining the breathing process. The ventilator:

  • Controls delivered oxygen concentration
  • Delivers required flow and volume meeting the patient’s inspiratory demands

This mode lets the patient breath at a continuous rate and the elevated pressure improves oxygenation.

Pressure Controlled Ventilation (PCV)

PCV can be used in both SIMV and A/C modes and targets a particular pressure during inspiration. In simple words, pressure controls the endpoint instead of volume. The flow rate being delivered depends on the following characteristics, which also determine the tidal volume:

  • The patient’s demands
  • Lung compliance
  • Airway resistance

There is a lesser risk of barotraumas as compared to volume-controlled modes (A/C and SIMV). It is preferred in patients with the neuromuscular disease, but otherwise normal lungs.

Pressure Support Ventilation (PSV)

A kind of spontaneous breath that can be used in either CPAP or SIMV mode is basically like PCV targeting specific inspiratory pressure. However, the difference here is that the inspiration ends as the lungs get full and the flow delivered reduces to a value set by the clinician. PSV can be delivered through special face masks. In this mode, the patient gets to decide:

  • Respiratory rate
  • Inspiratory time
  • Tidal volume
  • Flow rate

Positive End-Expiratory Pressure (PEEP)

This involves applying mechanical positive pressure at the end of expiration so that complete emptying of lungs is prevented. The plus point of this type of mode is the increased lung volume and improvement in oxygenation.

The effect of PEEP can be very well measured by looking at the peak inspiratory pressure (PIP). If PIP increases less than added positive end-expiratory pressure then lung compliance has improved. PEEP is clinically indicated for:

Positive end-expiratory pressure should not be applied in patients with pneumonia as it will affect healthy tissue and worsen the state of oxygenation.

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